ABC’s of Spray Finishing - ABsupply.netsSprayFinishing.pdf · While this book examines the spray finishing operation and its equipment from many viewpoints, ... painting equipment

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ABC’s of SprayFinishing

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While this book examines the sprayfinishing operation and itsequipment from many viewpoints,there is still much more to belearned to become truly proficient atspray finishing.

The best way to become proficientat spray finishing is to just do it!Many trade technical andcommunity colleges offer courses inspray finishing, a great way toimprove your skills.

Many of the “tricks” of theprofessional spray finisher involvepaints and coatings. Themanufacturers of these materialsroutinely publish complete books onthese subjects. These publicationsare available in specialty paintstores and will provide you withconsiderable detail. Many of thesebooks also contain information ontechniques for surface preparation.

Another important source ofinformation, particularly onequipment use and selection is yourlocal spray finishing equipmentdistributor. No book could evercompletely cover a specialist’s in-depth knowledge of the equipment,the techniques, the maintenanceand troubleshooting.

Information is available from manyresources on the subject of sprayfinishing. It is our hope that this bookprovides you with a start towardperfecting your finishing skills.

A recent addition to resourcesavailable to the spray finisher isthe World Wide Web. Manymanufactures are representedand question and answer forumsare available. Please visit ourwebsites at www.devilbiss.comor www.binks.com or www.ransburg.com.

About this book…..

This book has been updated severaltimes from “The ABC’s of SprayEquipment,” originally published byThe DeVilbiss Company in 1954. Itfocuses on equipment andtechniques for spray finishing.

The format of the original book wasquestion-and-answer. We haveretained that format in this edition.

This book is organized around themajor components of an air spraysystem…spray guns, electrostaticapplicators, material containers, hose,air control equipment, compressors,spray booths, respirators and a short section on general cleanlines and other sources of information. A thorough understanding of the material in this book—plus a lot of actual spray painting practice— should enable you to handle just about any spray painting situation.

Although we have made an effort tomake this book as detailed and ascomplete as possible, be aware thatthe equipment and product systemsused to illustrate points are entirelybased on DeVilbiss, Ransburg and Binks technology. DeVilbiss, Ransburg,and Binks are three of the world’soldest and largest manufacturer ofspray paint equipment, and havemaintained this leadership since itsfounding in 1888.

Table of ContentsForward …..…………………..….2

1. Introduction ........................3 Surface Preparation..............3 Paint Preparation..................3 Solvent Selection ..................3

2. Air Atomizing Spray Guns 5 Spray Gun Types..................5 Part Identification and Function ................................7 Operation ............................10 Maintenance ......................12 Troubleshooting ..................14

3. Electrostatic Spray Process..............................17Definition ............................17Electrostatic Processes/Equipment ..........................18Operating Safely.................20

4. Material Containers ..........23

5. Hose and Connections ....25

6. Air Control Equipment .....27

7. Respirators ......................29

8. Air Compressors ..............30

9. Spray Booths ..................31

10. Diaphragm Pumps............34

11. High Pressure Spraying ..36

12. H.P. Spray Guns................37

13. Two Ball Piston Pumps....38

14. H.P. Equipment Setup ......39

15. Four Ball Piston Pumps ..40

16. Circulating Systems ........41

17. H.P. Troubleshooting ......43

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This book is about the selection, useand maintenance of finishingequipment: spray guns, tanks, cups,hoses, compressors, regulators,spray booths, respirators, etc. Itpresumes that you are familiar withstandard surface preparationtechniques that may be requiredbefore finishing actually begins. Italso presumes a basic knowledge ofthe many different types of paintsand coatings available.

Creating a perfect finish requires asolid knowledge of surfacepreparation, finishes and spraypainting equipment. The first two areextensively covered in many otherbooks. The manufacturers of paintsand coatings have gone to greatlength to publish information on theirnew and existing products.

But, even an extensive knowledgeof surface preparation techniquesand paint chemistry is not enough toassure a professional finish. Thefinish must be applied by a spraygun, and all the variables of its usemust be mastered.

The equipment necessary to applythe finish – the spray gun, tank, cup,regulator, hoses, compressor, etc. –must all be matched to the job aswell as to each other. Thatequipment must be used andmaintained properly, with anappreciation of how and why itworks the way it does.

The moment of truth for any finishhappens when the trigger is pulled.This book focuses on that moment.

Surface Preparation

The surface to be finished should bewell cleaned before painting. If thepaint manufacturer’s instructions callfor it, the surface should bechemically treated. Use a blow-offgun and tack rag to remove all dustand dirt. No amount of primer orpaint will cover up a badly preparedsurface.

Plastic parts may contain staticelectricity from the molding process.

This static attracts particles of dustand dirt. Eliminate them by treatingwith “destatisizing” air using aspecial blow-off gun that imparts aneutral charge to the airflow.

Paint Preparation

Today’s finishes are extremely

Solvent Selection – Electrostatic Finishing

Research engineers have been working for more than thirty years on a continuing development of electro-static coating processes and equipment, as well as techniques and service to further improve the high efficiency of this process. These techniques can be quite useful for paint formulators by providing better wraparound; higher quality finishes requiring less touch-up and, increasing paint film build. This information is a guide to solvent selection to improve electrostatic sprayability.

Controlled Paint Resistivity - A Factor in FormulationIt has been determined that coating formulations for electrostatic application, in addition to meeting customer requirements for durability, drying time, gloss, etc., should have an electrical resistance within a specified range for best atomizing characteristics and electrical deposition.

Electrical resistivity is a characteristic which must be built into the paint formulation. It has generally been found that most materials can be adjusted to have suitable resistance and still meet other requirements.We have found that no single, simple characteristic or adjustment provides optimum sprayability for any given coating. However, adjustment of paint resistivity through appropriate selection of solvents improves many paints that otherwise could not be sprayed efficiently by the electrostatic process.

complex chemical formulations.They include both solvent andwaterborne types. Some mayrequire the addition of solvents toform the proper spraying viscosity.Others may simply require theaddition of a second component at aprescribed ratio to obtain sprayableconsistency. Many of them alsohave hardeners or other chemicals,added to them to insure correctcolor match, gloss, hardness, dryingtime or other characteristicsnecessary to produce a first classfinish. Make sure you are familiarwith the specific finish material datasheets accompanying eachmaterial. Do not mix materials fromvarious manufacturers. Read andfollow directions carefully.

All finish materials must also besupplied with material Safety Datasheets (MSDS). This data providesinformation on proper handling anddisposal of materials. Many statesrequire that MSDS be kept on file bythe user.

The first step is knowing the typeand color of paint the projectrequires.

With these determined, follow themanufacturer’s instruction forpreparing it exactly. If you have anydoubts about how to proceed, don’tguess! Contact your paint supplierfor help. Improperly prepared paintwill never produce a good finish!

The chief characteristic thatdetermines the sprayablility of paintand how much film may be applied,is its viscosity … or consistency.Following the paint manufacturer’sinstructions will get you close, butfor professional results, use aviscosity cup. It is a simple but veryaccurate, way to measure thethickness of paint. With the cup, youcan thin or reduce the paint to the

precise consistency required by themanufacturer.

Always prepare paint in a clean,dust-free environment. Paint has aremarkable ability to pick up dirt.Dirty paint will not only clog yourspray gun, but it will also ruin yourpaint job. Get in the habit of alwayspouring paint into the cup or tankthrough a paint strainer. Paint isnever as clean as it looks.

Solvent Classification for Electrostatic UsageSolvents may be classified as POLAR or NONPOLAR. For our purposes, the differences in polarity between different solvents provides a means to adjust the total resistivity of a paint mixture.

NONPOLAR Solvents normally do not improve sprayability. These solvents include the aliphatic and aromatic hydrocarbons, chlorinated solvents, and the turpentines.

The addition of POLAR Solvents compatible with the basic coating material often improves electrostatic sprayability. Polar solvents include the ketones, alcohols, glycol ethers, esters, and nitroparaffins.

Viscosity GuideThe initial trial paint formulation should be of high viscosity (preferably exceeding 50 seconds on a No. 4 Ford cup) so that the reduced formula will have satisfactorily high solidscontent after solvent additions. It is usually best to adjust viscosity after resistivity, since viscosity is a less critical factor for electrostatic sprayability.

formulations than normally used for conventional hand air guns. The larger disk diameter and higher the speed of rotation, the slower the evaporation rates should be made. No. 2 Process bells require paints in about the same evaporation range as for conventional air guns, while the No. 2 Process handguns require still faster solvents.

Because of complex interactions of solvents, resins, and binders, it may happen that a solvent of a certain polarity will reduce the mixture resistance more than an equal amount of a second solvent which has a higher polarity. As these reactions are not always predictable, the adjustment of resistivity is necessarily a guide trial-and-error procedure.

Coating Material GuideShort oil length alkyd vehicles, with small amounts of high polarity modifying resins like amino resins, epoxy, or phenolic, respond well to the adjustment of resistivity by solvent addition.

Air-dry lacquers and similar fast drying materials usually contain so much polar solvent that their resistivity is below the desired range. In such cases, incorporating the maximum allowable quantity of nonpolar dilutant (example: the substitution of esters for ketones) will improve sprayability.

Organosols dispersed in hydrocarbons can be improved by thinning just before use with the polar solvents of high solvency. Reduction long before use with polar solvents of low solvency and swellability for the

dispersed resin is also beneficial.

Most paints of high pigment volume concentration and paints where the binder is highly nonpolar, such as bodied linseed oil, styrenated alkyds, lacquers based on hydrocarbon resins (like cyclized rubber or butylene copolymers), and long oil alkyds, may be improved by solvent adjustment, but the possible upgrading of these materials by this method is limited. Preliminary Ransburg research seems to indicate that the use of concentrated additives with paints of these types offers a better prospect for sprayability improvement.

Resistance Adjustment by Solvent SelectionNonpolar solvents may be used as extenders to vary paint viscosity or flow properties without seriously changing the electrical resistance of the mixture. An exception occurs with paints that are of low resistivity, for example vinyl solutions or nitro-cellulose materials. The conductivity of these special mixtures may some-times be reduced to a usable factor by the addition of nonpolar solvents.

Generally, the additions of solvent of highest polarity will give the greatest electrical resistance reduction to a mixture’ solvents of intermediate polarity provide intermediate resist-ance reductions, etc. The adjustment of paint resistivity to the specified

optimum ranges will usually improve its sprayability.

A specific selection should be based on the best compromise to obtain the desired resistivity, viscosity, flow rate, evaporation rate, cost, and other conventionally considered factors.

Evaporation Rates vs. Electrostatic Equipment UsedAll Ransburg No. 2 Process disk equipment requires slower

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2. Air Atomizing Spray Guns

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I 2. What are the types of air sprayguns?

ntroduction

The spray gun is the key componentin a finishing system. It is a precisionengineered and manufacturedinstrument. Each type and size isspecifically designed to perform acertain, defined range of tasks.

As in most other areas of finishingwork, having the right tool for the jobgoes a long way toward gettingprofessional results.

This chapter will help you knowwhich is the proper gun by reviewingthe Conventional Air LVMP (TransTech) and High Volume/Low Pressure spray gun designs commonly used in finishing—siphon feed, gravity feed and pressure feed. It will also review the different types of guns and components within each design.

A thorough understanding of thedifferences between systems willallow you to select the right gun, touse it properly to produce a highquality finish and to contributetoward a profitable finishingoperation.

SPRAY GUN TYPES

1. What is an air atomizing spraygun?

Air atomizing spray guns areavailable in three types: Conventional, Low Volume Medium Pressure [LVMP (TransTech)] and High Volume Low Pressure (HVLP). Conventional air spray guns pass virtually all the input pressure to the air cap. HVLP reduces the air pressure internallyto a much lower pressure (10 PSI atomizing pressure). LVMP is higher pressures than HVLP but substantially lower than conventional. LVMP is nearly as efficient as HVLP but will render a finish much closer to conventional.

Air and material enter the spray gunthrough separate passages, and are mixed at the air cap in a controlled pattern.

Air spray guns may be classified invarious ways. One way is by thelocation of the material container:

Figure 1 shows a gun with a cupattached below it.

Figure 3 shows a gun with a cupattached above it.

Figure 4 shows a material containersome distance away from itspressure feed gun.

The type of material feed system isalso a way of classifying guns:

Siphon Feed... draws material to thegun by siphoning as in Figure 1.

Gravity Feed... the material travelsdown, carried by its own weight andgravity as in Figure 3.

Pressure Feed... the material is fedby positive pressure as in Figure 4.

Guns may also be classified aseither external or internal mix.

3. What is a siphon feed gun?

A spray gun design in which astream of compressed air creates avacuum at the air cap, providing asiphoning action. Atmosphericpressure on the material in the siphoncup forces it up the pickup tube,into the gun and out the fluid tip,where it is atomized by the air cap.The vent holes in the cup lid must beopen. This type gun is usually limitedto a one-quart, or smaller, capacitycontainer.

Figure 1- Siphon Feed Gun withattached cup

Siphon feed is easily identified bythe fluid tip extending slightly beyondthe face of the air cap, as shown inFigure 2.

Figure 2 - Siphon Feed Air Cap

Siphon feed guns are suited tomany color changes and to smallamounts of material, such as intouchup or lower production oper-ations.

4. What is a gravity feed gun?

This design uses gravity to flow thematerial from the cup, which ismounted above the gun, into the gunfor spraying. No fluid pickup tube isused, since the fluid outlet is at thebottom of the cup.

This cup has a vent hole at the topof the cup which must remain open.It is limited to 32 ounce capacitiesdue to weight and balance.

Gravity feed guns are ideal for smallapplications such as spot repair,detail finishing or for finishing in alimited space. They require less airthan a siphon feed gun, and usuallyhave less overspray.

Figure 3- Gravity Feed Gun withattached cup


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5. What is a pressure feed gun?

In this design, the fluid tip is flushwith the face of the air cap (see Fig-ure 5). The material is pressurized ina separate cup, tank or pump. Theair pressure forces the materialthrough the fluid tip and to the aircap for atomization.

Figure 4 - Typical Pressure Feed Gunwith remote tank

This system is normally used whenlarge quantities of material are to beapplied, when the material is tooheavy to be siphoned from acontainer or when fast application isrequired. Production spraying in amanufacturing plant is a typical useof a pressure feed system

Figure 5 - Pressure Feed Air Cap

Type Viscosity Fluid Atomizing TypeFeed (#2 Zahn) Oz/Minute Pressure Production

Siphon up to 24 10-12 40-50 Low

Gravity up to 24 10-12 30-40 Low

Pressure up to 29 20-24 50-60 High

HVLP up to 29 14-16 10 High

Table 1

6. What is an external mix gun?

This gun mixes and atomizes air andfluid outside the air cap.

It can be used for applying all typesof materials, and it is particularlydesirable when spraying fast dryingpaints such as lacquer. It is alsoused when a higher quality finish isdesired.

Figure 6 - External Mix Gun

7. What is an internal mix cap?

This gun mixes air and materialinside the air cap, before expellingthem.

It is usually used where low airpressures and volumes areavailable, or where slow-dryingmaterials are being sprayed.

A typical example is spraying flatwall paint, or outside house paint,with a small compressor.

Internal mix guns are rarely used forfinishing when a fast-drying materialis being sprayed, or when a highquality finish is required.

Figure 7 - Internal Mix Gun

8. What is HVLP?

HVLP, or High-Volume/LowPressure, uses a high volume of air(typically between 15-26 CFM)delivered at low pressure (10 PSI orless at the air cap) to atomize paintinto a soft, low-velocity pattern ofparticles.

In most cases, less than 10 psi isneeded in order to atomize.

Proper setup utilizes no more fluidand air pressure than is needed toproduce the required quality and aflow rate that will meet productionrequirements.As a result, far less material is lost inoverspray, bounceback andblowback than with conventional airspray. This is why HVLP delivers adramatically higher transferefficiency (the amount of solidsapplied as a percent of solidssprayed) than spray systems using ahigher atomizing pressure.

The HVLP spray gun resembles astandard spray gun in shape andoperation. Models that use highinlet pressure (20-80 psi) andconvert to low pressure internallywithin the spray gun are calledHVLP conversion guns.

Some HVLP models, particularlythose using turbines to generateair, bleed air continuously tominimize back-pressure againstthe air flow of the turbine.

The air cap design is similar to thatof a standard spray gun, with avariety of air jets directing theatomizing air into the fluid stream,atomizing it as it leaves the tip.

HVLP is growing in popularity andnew environmental regulations arerequiring it for many applications.

HVLP can be used with anylow-to-medium solids materials thatcan be atomized by the gun,including two-component paints,urethanes, acrylics, epoxies,enamels, lacquers, stains, primers,etc.

Pro Tip:When using a gravity feed system,downsize the tip one size from siphon.If the siphon system calls for a .070”,use a .055 or .062””


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Figure 8 - The Anatomy of a Spray Gun

10. What happens when thetrigger is pulled?

The trigger operates in two stages.Initial trigger movement opens theair valve, allowing atomizing air toflow through the gun.

Further movement of the triggeropens the fluid needle, allowing fluidmaterial to flow. When the trigger isreleased, the fluid flow stops beforethe atomizing air flow.

This lead/lag time in the triggeroperation, assures a full spraypattern when the fluid flow starts. Italso assures a full pattern until thefluid flow stops, so there is nocoarse atomization.

11. What is the function of the aircap?

The air cap (see Figure 10) directscompressed air into the fluid streamto atomize it and form the spraypattern. (see Figure 9)

Round Tapered Blunt

Figure 9 - Types of Spray Patterns

There are various styles of caps toproduce different sizes and shapesof patterns for many applications.

12. What are the advantages ofthe multiple jet cap?

This cap design provides betteratomization of more viscousmaterials.

It allows higher atomizationpressures to be used on moreviscous materials with less danger ofsplit spray pattern.

It provides greater uniformity inpattern due to better equalization ofair volume and pressure from thecap.

It also provides better atomizationfor materials that can be sprayedwith lower pressures.

Figure 10 - External Mix Air Cap

13. How should an air cap beselected?

The following factors must be con-sidered:

a) Type, viscosity and volume ofmaterial to be sprayed

b) size and nature of object, orsurface, to be sprayed (Multiple, orlarger, orifices increase ability toatomize more material for fasterpainting of large objects.

Fewer, or smaller, orifices usuallyrequire less air, produce smallerspray patterns and deliver lessmaterial. These caps are designedfor painting smaller objects and/orusing slower speeds.

c) material feed system used -pressure, siphon or gravity

d) size of fluid tip to be used (Mostair caps work best with certain fluidtip/needle combinations.)

e) volume of air in cubic feet perminute (cfm) and pressure in poundsper square inch (psi) available

See the DeVilbiss or Binks spraygun catalog for the proper selectionof air cap / fluid tip / needlecombinations and typical uses.

14. What is the function of thefluid tip and needle?

They restrict and direct the flow ofmaterial from the gun into the airstream. The fluid tip forms aninternal seat for the tapered fluidneedle, which reduces the flow ofmaterial as it closes. (see Figure 11)

The amount of material that leavesthe front of the gun depends uponthe viscosity of the material, thematerial fluid pressure and the sizeof the fluid tip opening providedwhen the needle is unseated fromthe tip.

Fluid tips are available in a variety ofsizes to properly handle materials ofvarious types, flow rates andviscosity’s.

Figure 11 - The Fluid Tip and Needle

15. What is the nozzlecombination?

In practice, the air cap, fluid tip,needle and baffle are selected as aunit, since they all work together toproduce the quality of the spraypattern and finish. These four items,as a unit, are referred to as thenozzle combination.

PART IDENTIFICATION FUNCTION

9. What are the principal parts of aspray gun?


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16. What are the standard fluid tipsizes and flow rates?

The standard sizes, correspondingfluid tip opening dimensions and flowrates are:

Conventional Air Spray

Fluid Tip Flow Rate/I.D. Material

Pressure Feed Systems.028"/.7mm up to 12 oz/min.0425"/1.1mm up to 20 oz/min.055"/1.4mm up to 30 oz/min.070"/1.8mm over 30 oz/min.070"/1.8mm porcelain enamel.086"/2.2mm heavy body materials.110"/2.75mm heavy body materialsSiphon Feed Systems.070"/1.8mm up to 12 oz/min.062"/1.6mm up to 10 oz/minGravity Feed Systems.055"/1.4mm up to 30 oz/min.062/1.6mm up to 30 oz/minTable 2

HVLP / LVMP

Fluid Tip Flow Rate/I.D. Material

Pressure Feed Systems.0425"/1.1mm up to 10 oz/min.055"/1.4mm up to 14 oz/min.070"/1.8mm up to 20 oz/min.086"/2.2mm over 20 oz/minSiphon Feed Systems.086"/2.2mm up to 9 oz/min.070"/1.8mm up to 8 oz/minGravity Feed Systems.055"/1.4mm up to 12 oz/min.062"/1.6mm up to 12 oz/minTable 3

Rule of thumbOptimum fluid pressures are 8-20psi. Pressures greater than thisgenerally indicate the need for alarger fluid tip size.

17. How are fluid tip and needlesizes identified?

DeVilbiss and Binks fluid tips andneedles are identified by the lettersor numbers stamped on the tip andthe needle.

The identification letters on thesecomponents should match. See theappropriate DeVilbiss/Binks spraygun catalog for the proper selectionof fluid tip and needle combinations.

18. What fluid tip and needlecombination sizes are mostcommon?

.042/1.1mm, .055/1.4mm and

.070/1.8mm are most commonlyused. The .070/1.8mm size is usedfor siphon feed, while .055/1.4mmand .062/1/6 are used for gravityFeed. For pressure feed the mostcommon tips are .042/1.1mm,.055/1.4mm and .070/1.8mm,

19. How are nozzle combinationsselected?

Five basic considerations are in-volved in selecting the nozzle com-bination:

type and viscosity of materialbeing sprayed

physical size of object beingfinished

desired speed/finish quality

gun model being used

available air volume (cfm) andpressure (psi) from compressor

(1) The type and viscosity of thematerial being sprayed is thefirst factor to consider.

Rule of thumbThe lower the viscosity of thematerial, the smaller the I.D. of thefluid tip.

Material Flow TipViscosity Rate Size#2 Zahn

up to 23 sec Low .0425"/1.1mm23-28 sec Med .055"/1.4mm

28-48 sec High .070"/1.8mm

over 48 sec High .086"/2.2mmTable 4

NOTE: Viscosity conversion chartsare available to convert one viscositycup reading to another from anymaterial or equipment supplier.

(2) The physical size of the object tobe painted must also be considered.As a general rule, use the largestpossible spray pattern consistentwith the object size. Remember thatdifferent air caps deliver variouspattern characteristics. This canreduce both spraying time and thenumber of gun passes.

(3) The next consideration inevaluating nozzle combinations isthe speed with which the finish willbe applied, and the desired level ofquality.

For speed and uniform coverage,choose a nozzle combination whichproduces a pattern as wide aspossible.

For finish coat work, quality is thedeciding factor. Choose a nozzlecombination which produces a fineatomization and a smaller patternsize, thereby giving greaterapplication control.

(4) The model of the gun itself willlimit the selection of nozzlecombination.

For a siphon feed gun, there are twonozzle types available which aresuitable for finishing operations.These nozzles have fluid tipopenings of .070"/1.8mm to.086"/2.2mm, and are designed tohandle viscosities up to 28 secondsin a No. 2 Zahn Viscosity Cup.

For a pressure feed gun, the amountof material discharged dependsupon material viscosity, the insidediameter of the fluid tip, the lengthand size of hose and the pressureon the material container or pump.

Pressure Feed


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If the fluid tip opening is too small,the paint stream will be too high. Ifthe fluid tip opening is too large, youwill lose control over the materialdischarging from the gun.

For most HVLP guns, the paint flowshouldn't exceed 16 oz. per minute.For recommended flow rates foreach fluid tip size, consult theDeVilbiss or Binks catalog.

(5) Available air supply is the lastfactor to consider.

Pressure feed air caps consumebetween 7.0 and 26.0 CFM,depending on air pressure applied. Ifyour air supply is limited, because ofan undersized compressor, or manyother air tools are in use at once, thegun will be starved for air, producingincomplete atomization and a poorfinish.

20. What are the criteria forselecting a pressure feed nozzle?

While the fluid discharge in ouncesper minute from a siphon feed gunis relatively stable (largely because itis determined by atmosphericpressure), the fluid discharge from apressure feed gun depends moreupon the size of the inside diameterof the fluid tip and the pressure onthe paint container or pump. Thelarger the opening, the more fluid isdischarged at a given pressure.

If the fluid tip ID is too small for theamount of material flowing from thegun, the discharge velocity will betoo high. The air, coming from the aircap, will not be able to atomize itproperly causing a center-heavypattern.

If the fluid tip opening is too large,material discharge control will belost, often resulting in a split pattern.

The fluid tip/air cap combinationmust be matched to each other andto the job at hand. Spray guncatalogs include charts to help youmatch them properly.

21. Of what metals are fluid tipsmade?

Tips are made of the followingmetals:

a) 300-400 grade stainless steel forboth non-corrosive and corrosivematerials b) Carboloy inserts forextremely abrasive materials

23. What is viscosity?

The viscosity of a liquid is its body,or thickness, and it is a measure ofits internal resistance to flow. Vis-cosity varies with the type andtemperature of the liquid. Anyreference to a specific viscositymeasurement must be accompaniedby a corresponding temperaturespecification.

Viscosity is usually measured inpoise and centipoise (1 poise=100centipoise). The most commonmeasurement used to determineviscosity in finishing is flow rate(measured in seconds from a Zahn,Ford or Fisher Viscosity Cup).

Viscosity conversion may beaccomplished by consulting aviscosity conversion chart.

Different viscosity cup sizes areused for different thicknesses ofmaterials. Each cup has a precisionhole at the bottom of the cup. Use asmaller or larger hole in the cupdepending on the thickness of thematerial.

Viscosity control is an extremelyimportant and effective method tomaintain application efficiency andquality consistency. Always measureviscosity after each batch of materialis mixed and make sure materialtemperature is the same, normally70° to 90° F.

Consult your coatings TechnicalData Sheet for temperaturerecommendations.

23. What is the spreader adjust-ment valve?

A valve for controlling the air to thehorn holes which regulate the spraypattern from maximum width downto a narrow or round pattern.(See Figure 8)

24. What is the fluid needleadjustment?

This adjustment controls the travel ofthe fluid needle, which allows moreor less material through the fluid tip.See Figure 8.

With pressure feed systems, thefluid delivery rate should be adjustedby varying the fluid pressure at thepressure pot. Use the fluidadjustment knob for minor and/ortemporary flow control. This willextend the life of the fluid needle andtip.

25. What are the components ofsiphon and gravity feed systems?

Typical siphon and gravity feedsystems consist of; a siphon feed orgravity feed spray gun with cup, anair compressor (not shown), acombination filter/air regulator andair hoses. (See Figure 12)

Figure 12 - Siphon Feed and GravityFeed System Components

OPERATION

26. How is siphon and gravityfeed equipment hooked up foroperation?

Connect the air supply from thecompressor outlet to the filter/airregulator inlet.

Connect the air supply hose from theair regulator outlet to the air inlet onthe spray gun.


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After the material has been reducedto proper consistency, thoroughlymixed and strained, pour it into thecup and attach the cup (siphonfeed) or attach the cup and fill withthe coating (gravity feed).

29. How are siphon and gravityfeed systems initially adjusted forspraying?

(1) Spray a horizontal test pattern(air cap horns in a vertical position).Hold the trigger open until the paintbegins to run. There should be evendistribution of the paint across thefull width of the pattern. (see Figure13). The fan control knob is normallyadjusted fully counter-clockwise. Ifthe distribution is not even but issymmetrical a different fluid tip mayhelp. If the pattern is notsymmetrical, there is a problem witheither the air cap or the fluidtip/needle that must be corrected.Refer to the Troubleshooting Sectionfor examples of faulty patterns tohelp diagnose your problem.

Figure 13 - Horizontal Test Pattern

(2) If the pattern produced by theabove test appears normal, rotatethe air cap back to a normalspraying position and begin spray-ing. (Example - a normal pattern witha #30 air cap will be about 9" long

when the gun is held 8" from thesurface).

Figure 14 – Fluid Adjustment Screw

(3) With the fluid adjusting screwopen to the first thread, and the airpressure set at approximately 30 psi,make a few test passes with the gunon some clean paper. If there arevariations in particle size- specksand/or large globs - the paint is notatomizing properly (see Figure 19).

(4) If the paint is not atomizingproperly, increase the air pressureslightly and make another test pass.Continue this sequence until thepaint particle size is uniform

Even Distribution

Figure 15- Test Patterns

(5) If the pattern seems starved formaterial, and the fluid adjustingscrew is open wide (to the firstthread), the atomization air pressuremay be too high, or the material maybe too heavy. Recheck the viscosityor reduce the air pressure.

(6) If the material is spraying tooheavily and sagging, reduce thematerial flow by turning in the fluidadjusting screw (clockwise).

Remember, proper setup utilizes nomore fluid and air pressure than isneeded to produce the requiredquality and a flow rate that will meetproduction requirements.

28. What are the components of apressure feed system?

A pressure feed system consists of;a pressure feed spray gun, a pres-sure feed tank, cup or pump, an airfilter/regulator, appropriate air andfluid hoses and an air compressor.See Figure 16

Figure 16 - Pressure Feed SystemComponents

29. How is equipment hooked upfor pressure feed spraying?

Connect the air hose from the airregulator to the air inlet on the gun.

Connect the mainline air hose to theair inlet on the tank, cup or pump.CAUTION: Do not exceed thecontainer's maximum workingpressure.

Connect the fluid hose from the fluidoutlet on the tank to the fluid inlet onthe gun.


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30. How is the pressure feed gunadjusted for spraying?

Open spreader adjustment valve formaximum pattern size. (see figure 8)

Open fluid adjustment screw(counter clockwise) until maximumneedle travel is achieved. Openingbeyond that point will lessen theinternal spring tension and leakageat the fluid tip may result.

31. How is the pressure feed gunbalanced for spraying?

1 Using control knob on fluidregulator, set fluid pressure at 5 to10 psi.

2 Using control knob on airregulator, set air atomizationpressure at 30-35 psi.

3 Spray a test pattern (fast pass) ona piece of paper, cardboard, orwood. From that test pattern,determine if the particle size is smallenough and uniform throughout thepattern to achieve the required finishquality. If particle size is too large oris giving too much texture in thefinish, turn the atomization pressureup in 3 to 5 psi increments untilparticle size and texture of finish isacceptable.

4 Spray a part with these settings. Ifyou are not able to keep up with theproduction rate required or if thefinish is starved for material,increase the fluid pressure (or use alarger capacity fluid tip) with the fluidregulator control knob in 2 to 4 psiincrements until required wetcoverage is accomplished.

5 Remember, as you turn up thefluid pressure the particle size willincrease. Once the coveragerequired is obtained, it will benecessary to re-adjust theatomization pressure in 3 to 5 psiincrements as explained in step 3 toinsure required particle size andfinish texture is achieved.

6 If using HVLP, using an “Air CapTest Kit”, verify that the air cappressure in not above 10 psi ifrequired by a regulatory agency.

Figure 17 – Air Cap Test Kit

After establishing the operatingpressures required for productionand finish quality, develop aPressure Standardization programfor your finish room to follow.

32. What is a pressurestandardization program?

After establishing air and fluidpressures that meet required qualityand production, record the data tobe used for that application for futurereference. (see figure 18)

Figure 18 – PressureStandardization Chart

33. How should the spray gun beheld?

It should be held so the pattern isperpendicular to the surface at alltimes.

Keep the gun tip 8-10 inches (airspray guns) or 6-8 inches (HVLP

guns) from the surface beingsprayed.

34. What is the proper techniquefor spray gun stroke andtriggering?

The stroke is made with a free armmotion, keeping the gun at a rightangle to the surface at all points ofthe stroke.

Triggering should begin just beforethe edge of the surface to besprayed is in line with the gunnozzle. The trigger should be heldfully depressed, and the gun movedin one continuous motion, until theother edge of the object is reached.The trigger is then released, shuttingoff the fluid flow, but the motion iscontinued for a few inches until it isreversed for the return stroke.

When the edge of the sprayed objectis reached on the return stroke, thetrigger is again fully depressed andthe motion continued across theobject.

Lap each stroke 50% over thepreceding one. Less than 50%overlap will result in streaks on thefinished surface. Move the gun at aconstant speed while the trigger ispulled, since the material flows at aconstant rate.

Another technique of triggering isreferred to as "feathering."Feathering allows the operator tolimit fluid flow by applying onlypartial trigger travel.

35. What happens when the gun isarced?

Arcing the stroke results in unevenapplication and excessive oversprayat each end of the stroke. When thetip is arced at an angle 45 degreesfrom the surface (see figure 19),approximately 65% of the sprayedmaterial is lost.

Booth # __________________Material Sprayed __________Application _______________Viscosity _________________Fluid Temperature _________Spray Gun Model __________Air Cap _____ Fluid Tip ____Air Pressure ______________Fluid Pressure ____________


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Figure 19 - Spray Techniques

36. What is the proper sprayingsequence and technique forfinishing applications?

Difficult areas, such as corners andedges, should be sprayed first. Aimdirectly at the area so that half of thespray covers each side of the edgeor corner.

Hold the gun an inch or two closerthan normal, or screw the spreaderadjustment control in a few turns.Needle travel should be only partialby utilizing the "feathering"technique. Either technique willreduce the pattern size.

If the gun is just held closer, thestroke will have to be faster to com-pensate for a normal amount ofmaterial being applied to smallerareas.

When spraying a curved surface,keep the gun at a right angle to thatsurface at all times. Follow thecurve. While not always physicallypossible, this is the ideal techniqueto produce a better, more uniform,finish.

After the edges, flanges and cornershave been sprayed, the flat, or

nearly flat, surfaces should besprayed.

Remember to overlap the previouslysprayed areas by 50% to avoidstreaking.

When painting very narrow surfaces,you can switch to a smaller gun, orcap with a smaller spray pattern, toavoid readjusting the full size gun.The smaller guns are usually easierto handle in restricted areas.

A full size gun could be used,however, by reducing the air pres-sure and fluid delivery and triggeringproperly.

MAINTENANCE

37. How should the air cap becleaned?

Remove the air cap from the gunand immerse it in clean solvent.Blow it dry with compressed air.

If the small holes become clogged,soak the cap in clean solvent. Ifreaming the holes is necessary, usea toothpick, a broom straw, or someother soft implement. (see figure 20)

Cleaning holes with a wire, a nail ora similar hard object couldpermanently damage the cap byenlarging the jets, resulting in adefective spray pattern.

Figure 20 - Cleaning the Air Cap

38. How should guns be cleaned?A siphon or pressure feed gun withattached cup should be cleaned asfollows:

Turn off the air to the gun, loosenthe cup cover and remove the fluidtube from the paint. Holding the tubeover the cup, pull the trigger to allowthe paint to drain back into the cup.

Empty the cup and wash it withclean solvent and a clean cloth. Fill ithalfway with clean solvent and sprayit through the gun to flush out the

fluid passages by directing streaminto an approved, closed container.All containers used to transferflammable materials should begrounded. (Be sure to comply withlocal codes regarding solventdisposal.)

Then, remove the air cap, clean it aspreviously explained and replace iton the gun.

Wipe off the gun with a solvent-soaked rag, or if necessary, brushthe air cap and gun with a fiberbrush using clean-up liquid orthinner.

To clean a pressure feed gun withremote cup or tank, turn off air sup-ply to cup or tank. Release materialpressure from the system byopening relief valve.

Material in hoses may be blownback. Lid must be loose and all airpressure off. Keep gun higher thancontainer, loosen air cap and triggergun until atomizing air forces allmaterial back into the pressurevessel.

A gun cleaner may be used foreither type of gun. This is an en-closed box-like structure (vented)with an array of cleaning nozzlesinside.

Guns and cups are placed over thenozzles, the lid is closed, the valve isenergized, and the pneumaticallycontrolled solvent sprays through thenozzles to clean the equipment.

The solvent is contained, and mustbe disposed of properly.

Some states' codes require the useof a gun cleaner, and it is unlawful todischarge solvent into theatmosphere.

After cleaning a spray gun in a guncleaner, be sure to lubricate asindicated in Figure 22.


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Figure 21` - Using a Hose Cleaner

Use a hose cleaner to clean internalpassages of spray guns and fluidhose. This device incorporates ahighly efficient fluid header, whichmeters a precise solvent/air mixture.The cleaner operates withcompressed air and sends a finely -atomized blast of solvent through thefluid passages of the hose, the spraygun, etc.

This simple, easy to use cleanerspeeds up equipment cleaning andsaves solvent. Savings may be asmuch as 80%. It also reduces VOCemissions.

(Be sure that both the hosecleaner and gun are properlygrounded.)

Where local codes prohibit the useof a hose cleaner, manuallybackflush the hose into the cup ortank with solvent and dry withcompressed air.

Clean the container and add cleansolvent. Atomization air should beturned off during this procedure.Pressurize the system and run thesolvent through until clean. (Be sureto comply with local codes regardingsolvent dispersion and disposal.)

Clean the air cap, fluid tip and tank.Reassemble for future use.

40. What parts of the gun requirelubrication? (Figure 22)

The A fluid needle packing, the B airvalve packing and the C triggerbearing screw require dailylubrication with a non-silicone gunlube.

The D fluid needle spring should becoated lightly with petroleum jelly ora non-silicone grease (ie. Lithium).

Lubricate each of these points afterevery cleaning in a gun washer!

Figure 22 - Lubrication Points


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ProblemFluid leaking from packing nut

Air leaking from front of gun

Fluid leaking or dripping fromfront of pressure feed gun

Jerky, fluttering spray

Cause

1. Packing nut loose2. Packing worn or dry

1. Sticking air valve stem2. Foreign matter on air valve or

seat3. Worn or damaged air valve or

seat4. Broken air valve spring5. Bent valve stem6. Air valve gasket damaged or

missing

1. Packing nut too tight2. Fluid tip or needle worn or

damaged3. Foreign matter in tip4. Fluid needle spring broken5. Wrong size needle or tip6. Dry packing

Siphon and Pressure Feed1. Material level too low2. Container tipped too far3. Obstruction in fluid passage4. Loose or broken fluid tube or

fluid inlet nipple5. Loose or damaged fluid tip/seat6. Dry or loose fluid needle packing

nutSiphon Feed Only7. Material too heavy8. Contained tipped too far9. Air vent clogged10. Loose, damaged or dirty lid

11. Dry or loose fluid needle packing12. Fluid tube resting on cup bottom13. Damaged gasket behind fluid tip

Correction

1. Tighten, do not bind needle2. Replace or lubricate

1. Lubricate2. Replace or lubricate

3. Replace

4. Replace5. Replace6. Replace

1. Adjust2. Replace tip and needle with

lapped or matched sets3. Clean4. Replace5. Replace6. Lubricate

1. Refill2. Hold more upright3. Backflush with solvent4. Tighten or replace

5. Adjust or replace6. Lubricate or tighten

7. Thin or replace8. Hold more upright9. Clear vent passage10. Tighten, replace or clean

coupling nut11. Lubricate or tighten packing nut12. Tighten or shorten

13. Replace gasket


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ProblemTop or bottom-heavy spraypattern*

Right or left-heavy spray pattern*

Center-heavy spray pattern

Split spray pattern

Cause1. Horn holes plugged2. Obstruction on top or bottom of

fluid tip3. Cap and/or tip seat dirty

1. Left or right side horn holesplugged

2. 2. Dirt on left or right side of fluidtip

*Remedies for the top, bottom,right, left heavy patterns are:1. Determine if the obstruction is on the aircap or fluid tip. Do this by making a solid testspray pattern. Then, rotate the cap one-halfturn and spray another pattern. If the defect isinverted, obstruction is on the air cap.Clean the air cap as previously instructed.2. If the defect is not inverted, it is on thefluid tip. Check for a fine burr on the edge ofthe fluid tip.Remove with #600 wet or dry sand paper.3. Check for dried paint just inside theopening.Remove paint by washing with solvent.

1. Fluid pressure too high foratomization air (pressure feed)

2. Material flow exceeds air cap’scapacity

3. Spreader adjustment valve settoo low

4. Atomizing pressure too low5. Material too thick

1. Fluid adjusting knob turned intoo far

2. Atomization air pressure toohigh

3. Fluid pressure too low (pressurefeed)

Correction1. Clean, ream with non-metallic

point (ie. Toothpick)2. Clean3. Clean

1.2. Clean, ream with non-metallic

point (ie. Toothpick)3. Clean

1. Balance air and fluid pressureReduce spray pattern width

2. Thin or reduce fluid flow

3. Adjust

4. Increase pressure5. Thin to proper consistency

1. Back out counter clockwise toachieve proper flow

2. Reduce at regulator

3. Increase fluid pressure

4. Change to a larger tip


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ProblemStarved spray pattern

Unable to form round spraypattern

Dry spray

Excessive overspray

Excessive fog

Will not spray

Cause1. Inadequate material flow

2. Low atomization air pressure(siphon feed)

1. Fan adjustment stem notseating properly

1. Air pressure too high2. Material not properly reduced

(siphon feed)3. Gun tip too far from work

surface4. Gun motion too fast

1. Too much atomization airpressure

2. Gun too far from surface3. Improper technique (arcing,

gun speed too fast)

1. Too much, or too fast-dryingthinner

2. Too much atomization airpressure

1. No pressure at gun2. Fluid pressure too low

(internal mix cap withpressure tank)

3. Fluid tip not open enough4. Fluid too heavy (siphon feed)

5. Internal mix cap used withsiphon feed

6. Pressure feed cap/tip usedwith siphon feed

Correction1. Back fluid adjusting screw out

to first thread or increase fluidpressure

2. Increase air pressure andrebalance gun

1. Clean or replace

1. Lower air pressure2. Reduce to proper consistency

3. Adjust to proper distance

4. Slow down

1. Reduce pressure

2. Use proper gun distance3. Use moderate pace, parallel

to work surface

1. Remix properly

2. Reduce pressure

1. Check air lines2. Increase fluid pressure at tank

3. Open fluid adjusting screw4. Reduce fluid or change to

pressure feed5. Change to external mix air

cap6. Use suction feed cap/tip

PRINCIPLES OF ELECTROSTATICS

IntroductionElectrostatic spray finishing combines the mechanical process of atomization with the distributive effects of electrical attraction and repulsion to achieve a highly efficient product finishing operation.

Atomization is achieved in liquid systems by air, airless, air-assisted, and rotary apparatus. The coating material is brought into contact with or through the immediate vicinity of highly charged electrodes. As this occurs, a considerable level of electrical charge is transferred either by direct contact or by passage through a highly ionized zone near the applicator tip (which can be used up to 100 kV), to the particles or droplets of coating material. Since all the particles or droplets are similarly charged and since like charges repel one another. Pattern in an electrostatic spray process tends to be larger and more evenly distrib-uted than that of a non-electrostatic process. This increases the ease and efficiency.

When a metallic object, which is electrically neutral or grounded is present, the electric field is established between the charging electrodes of the applicator and the grounded object which, in this case, is the item we wish to coat. The electrically charged particles or droplets of coating material are attracted via the electric field toward the grounded object in much the same way that iron filings are attracted to a magnet. As the particles or droplets come in contact with the grounded object, they begin to dissipate their electrical charges with the metal of the object.

With a typical electrostatic spray gun, a charging electrode is located at the tip of the atomizer. The electrode receives an electrical charge from a power supply. The paint is atomized as it exits past the electrode, and the paint particles become ionized (pick up additional electrons to become negatively charged)

The degree to which electrostatic force influences the path of paint particles depends on how big they are, how fast they move, and other forces within the spray booth such as gravity and air currents. Large particles sprayed at high speeds have great momentum, reducing the influence of the electrostatic force. A particle’s directional force inertia can be greater than the electrostatic field. Increased particle momentum can be advantageous when painting a complicated surface, because the momentum can overcome the Faraday cage effect — the tendency for charged paint particles to deposit only around the entrance of a cavity.

On the other hand, small paint particles sprayed at low velocities have low momentum, allowing the electrostatic force to take over and attract the paint onto the workpiece. This condition is acceptable for simple surfaces but is highly susceptible to Faraday cage problems. An electrostatic system should balance paint particle velocity and electrostatic voltage to optimize coating transfer efficiency.

Since the object is grounded through its hanger and conveyor back to electrically neutral earth, the charge does not accumulate in the metal of the object, allowing it to continue to accept more charges from newly arriving particles or droplets of coating material. Since the particles or droplets do not shed all of their

charge immediately, and since like charges repel each other, newly driving charged particles or droplets will tend to be repelled from spots that are already coated and attracted to the remaining areas of bare metal. Similarly, particles and droplets that were propelled beyond the grounded object will tend to curve in around be-hind it, thus giving the “wrap-around” and recess penetration effects associ-ated with electrostatic spray finishing.

If, however, a metallic or otherwise electrically conductive object is in the vicinity which is NOT properly electrically grounded, an entirely different process can occur. Initially, because it is an electrically neutral condition, it will attract the charged particles or droplets of coating material. However, as more and more coating material arrives and shares its charge with the object, the electrical charge will build up in the object because there is no pathway to ground, turning the object into a static electricity “battery”. Eventually, and in many cases, this can mean just a few seconds, enough electrical charge can accumulate in the object that a spark can be generated between it and the nearest ground surface. Or, similarly, an ungrounded metallic object can simply retain its electrical charge for an indefinite time until a grounded surface is brought near enough for a spark to occur. This grounded surface can be a swinging conveyor hook or an operator reaching out to touch the charged object. Likewise, a spark can occur between the electrostatic device and itself and a grounded object if the electrodes or other high voltage portion of the device are placed or brought too close to ground.

3. Electrostatic Spray Processes

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Faraday Cage Effect

Electrostatic AdvantagesThe main benefit offered by an electrostatic painting system is transfer efficiency. In certain applications electrostatic bells can achieve a high transfer efficiency exceeding 90%. This high efficiency translates into significant cost savings due to reduced overspray. A phenomenon of electrostatic finishing known as “wrap” causes some paint particles that go past this workpiece to be attracted to the back of the piece, further increasing transfer efficiency.

Increased transfer efficiency also reduces VOC emissions and lowers hazardous waste disposal costs. Spray booth cleanup and maintenance are reduced.

Coating ApplicationAny material that can be atomized can accept an electrostatic charge. Low-, medium-, and high-solids solvent borne coatings, enamels, lacquers, and two-component coatings can be applied electrostatically.

The various types of electrostatic systems can apply coatings regard-less of their conductivity. Waterborne and metallic coatings can be highly conductive. Solvent-borne coatings tend to be nonconductive. Any metallic coatings can contain conductive metal particles. These metallic coatings must be kept in circulation to prevent a short circuit in the feed line. As high volt-age is introduced into the system, the metal particles can line up to form a conductive path. System modifications may be required because of coating

conductivity to prevent the charge from shorting to ground. Operating Electrostatics SafelyElectrostatic finishing is safe if the equipment is maintained properly and safety procedures are followed. All items in the work area must be grounded, including the spray booth, conveyor, parts hangers, application equipment (unless using conductive/waterborne coatings), and the spray operator.

As electrical charges come in contact with ungrounded components, the charges can be absorbed and stored. This is known as a capacitive charge build up. Eventually, enough charge is built up so that when the ungrounded item comes within sparking distance of a ground, and is charge as a spark. Such a spark may have enough energy to ignite the flammable vapors and mists that are present in the spray area.

An ungrounded worker will not know that the capacitive charge has been absorbed until it is too late. Workers should never wear rubber- or cork-soled shoes, which can turn them into ungrounded capacitors. Special shoe-grounding devices are available. If workers are using hand-held guns, they should grasp them with bare hands or with gloves with cut-outs for fingertips and palms that allow adequate skin contact.

Proper grounding of all equipment that is not used for the high-voltage process is essential. Grounding straps should be attached to equipment and connected to a known ground. A quick inspection of all equipment, includ-ing conveyors and part hangers, can reveal improper grounding.

Good housekeeping can pay divi-dends. Removing paint build up from parts hangers can help ensure that workpieces are grounded. Unground-ed objects, such as tools and con-tainers, should be removed from the finishing area.

ELECTROSTATIC PROCESSES/EQUIPMENT

The electrostatic application of atomized materials was developed to enhance finish quality and improve transfer efficiency.

Presently, there are seven types of electrostatic processes for spray application: • Electrostaticairsprayatomization • Electrostatichigh-volume, low-pressure (HVLP) atomization • Electrostaticairlessatomization • Electrostaticair-assisted airless atomization • Electrostaticelectricalatomization • Electrostaticrotary-type bell atomization • Electrostaticrotary-type disk atomization

Regardless of the electrostatic finish-ing systems, each has its advantages and limitations. What may be suitable for one situation may not be suitable in another.

What is Electrostatic Air Spray AtomizationElectrostatic air spray uses an air cap with small precision openings that allows compressed air to be directed into the paint for optimum atomiza-tion. Electrostatic air spray is the most widely used type of atomization in the industry today due to its control and versatility. Electrostatic air spray provides very high transfer efficiency by utilizing the electrostatic charge to wrap paint around edges and capture overspray that would have been un-usable waste. Standard electrostatic air spray provides transfer efficiencies in the 40 to 75% range depending on the type of material and application.

What is Electrostatic HVLP Spray AtomizationElectrostatic HVLP spray utilizes the same atomization characteristics as electrostatic air spray technol-ogy with slight modifications. When using air HVLP, the pressure of the compressed air at the air cap must be reduced to a range of 0.1 to 10 psi.


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Transfer efficiency is greater when using HVLP spray to lower the particle velocity and atomize the material thus causing less waste and blow-by of material. Some electrostatic equipment can be easily converted or transformed between air spray and HVLP spray technology by simply changing four parts. HVLP spray technology helps meet stringent EPA codes requiring reduced VOCs and waste. Electrostatic HVLP spray provides transfer efficiencies in the 40 to 80% range depending on the type of material and application.

Air Spray Atomization Technology

What is Electrostatic Airless Spray AtomizationElectrostatic airless spray technology utilizes the principle of fluid at high pressures (500-5,000 psi) atomizing through a very small fluid nozzle orifice. Size and shape of the spray pattern, along with fluid quality is controlled by the nozzle orifice. Airless spray technology evolved after air spray to aid in faster application rates using higher delivery and heavier viscosities on larger parts.

Electrostatic Air-Assisted Airless AtomizationElectrostatic air-assisted airless spray technology uses the airless spray principle to atomize the fluid at reduced fluid pressure with assisted atomizing air to aid in reducing pattern tailing and affect pattern shape. Air-assisted airless spray technology offers some of the desirable characteristics of both airless spray and air spray; the desirable characteristics being medium to high delivery rates, ability to spray heavy viscosities at low velocities, and high transfer efficiency.

This is where atomization takes place! Air cap and fluid tip design are the key factors

in atomization and transfer efficiency.

Electrostatic Electrical AtomizationElectrostatic electrical atomization is accomplished by using a rotary bell on the end of a gun to evenly dispense paint to the edge of the bell. Once the coating material reaches the edge of the bell it is introduced to an electrical charge. The electrical charge at the sharp edge (approximately 100 kV) causes paint of a medium electrical resistance range (0.1 to 1 megohms) to disperse onto the product. The pure electrical application is a slightly slower process than an air spray or air-assisted airless technology and requires a rotational type spray paint technique, due to the bells spray pattern, but is the most

transfer efficient spray gun process in the industry today. The ultrasoft forward velocity of the spray pattern achieves transfer efficiencies of nearly 100% on most products. This high transfer efficiency spawned the industry of painting and refurbishing machinery and furniture in place.

Electrostatic Rotary- Bell-Type AtomizationAn electrostatic bell atomizer is a high-speed rotary bell that uses centrifugal force and mechanical shearing to atomize material and efficiently transfer material from the bell edge to the target being painted. The bell is used on a turbine motor where the pattern is carefully directed by the use of compressed air, introduced to the pattern at the edge of the bell cup. The compressed air gives the material forward velocity to aid in penetrating recessed areas. The bells are usually mounted stationary, reciprocated or on robots to coat products on straight line conveyors. The bells may also be positioned on both sides of the conveyor. Rotary-bell-type atomiza-tion provides transfer efficiencies in the 60 to 85% range.

Electrostatic Rotary- Disk-Type AtomizationAn electrostatic rotary-disk atomizer is a high-speed rotary atomizer that uses centrifugal force along with mechanical shearing to atomize coating material and efficiently transfer the material from the disk edge to the target being painted. The disk is used in an omega shape loop conveyor to coat the product. Disks may be mounted stationary and tilted (up to 45°) to coat small parts of 12 in. or less, or mounted on reciprocating arms to coat parts up to 40 ft. in height but generally no wider than 4 ft. in width. The disk produces transfer efficiencies in the 70 to 95% range.


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OPERATINg ELECTROSTATIC COATINg SySTEMS SAFELy

Personnel grounding

general*The integrity of the system ground MUST be inspected regularly and maintained.

It is simple, but VITAL to be sure that all objects in an electrostatic coating area are grounded (reference NFPA-33).

1. Inspect all grounded wires daily. Look for good, firm joints at all points of connection (paint pots, flow regulators, booth wall, power supply, etc.). Look for breaks in the ground wire. Repair any defect IMMEDIATELY!

2. Inspect all conveyor apparatus (hooks, hangers, etc.) daily. If there is any accumulation of dried coating material on any of these objects, remove it before using them!

3. Inspect the floor daily for excessive accumulation of dried coating material (or other residue). If there is any, remove it!

Safe grounding is a matter of proper equipment maintenance, proper spray technique, and good housekeeping.

Daily inspection of grounding apparatus and conditions, however, will help prevent hazards that are caused by normal, daily operations.

Personnel grounding is the most difficult area of electrical hazard control. Most people do not realize what excellent capacitors they are. In a very short time, without proper grounding, the human body can build enough static charge to cause dangerous spark discharge. Therefore, ALL persons in an electrostatic coating area MUST be grounded at ALL times!

Manual equipment operators will be grounded through the equipment as long as it is being held in contact with the bare skin. As soon as the equipment is released from direct (skin) contact with the operator, other grounding methods becomes necessary.

The operator SHOULD NOT wear insulating gloves! Special conductive gloves may be used and are recommended.

* If insulating (cloth or rubber) gloves are worn, both palms MUST be cut out to allow bare skin contact with the equipment! This allows the operator to change the equipment from one hand to the other.

* If gloves are worn for chemical safety, grounding wrist straps may be connected from the operator’s wrist to the applicator assembly.

All persons in the spray area must be grounded at ALL times!

This may be accomplished safely by the use of conductive soled shoes, disposable conductive boots, or personnel grounding straps.

Equipment grounding

general In electrostatic coating systems, the flow of high voltage power from the power supply to the atomizing head of the applicator is insulated from ground and isolated from all other functions and equipment. When the voltage reaches the atomizer, it is transferred to the coating material where, by introducing a (normally) negative charge, it causes the atomized fluid to seek the nearest (normally) positive ground. In a properly constructed and operated system, that ground will be the target object.

The directed conduction of the electric charge through its array of wires, cables, and equipment is accompanied by a variety of stray electrical charges passing through the air by various means such as air ionization; charged particles in the air and radiated energy. Such stray charges may be attracted to any conductive material in the spray area. If the conductive material does not provide a safe drain to electrical ground, which will allow the charge to dissipate as fast as it accumulates, it may store the charge. When its electrical storage limit is reached, or when it is breached by external circumstances (such as the approach of a grounded object or person, or one at lower potential), it may discharge its stored charge to the nearest ground. If there is no safe path to ground (such as a ground wire) it may discharge through the air as a spark. A spark may ignite the flammable atmosphere of a spray area. The hazard area extends from the point of origin up to as much as a twenty foot radius. See the NFPA-33 for definition and limitations of “hazard area”.

It is a simple, but vital matter to be sure that ALL conductive objects within the spray area are grounded. This will include such items as, but are not limited to: cabinets, benches, housings, ladders, bases, containers, stands, people, and product.

ALL of which are not by design, insulated from ground MUST be connected directly and INDIVIDUALLy to true earth ground. Resting on a concrete floor or being attached to a building column may not always be sufficient ground. In order to provide the best ground connection possible, always attach a ground wire to the terminal indicated by the ground symbol and then to a proven, true earth ground. Always check ground connections for integrity. Some items, such as rotators and paint stands, may be


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supported on insulators, but all components of the system up to the insulator MUST be grounded. It is recommended that ground wires be made of No. 18, bare, stranded wire (minimum). Where possible, use larger wire.

Where items are mounted directly on structural components such as building columns, the ground connection MUST still be made. In many cases the structural component may be painted or coated with an insulating material, and in many cases the equipment will be painted. These coatings are insulating. The ground connection must be as perfect as possible.

Applicator groundinggeneral

WARNING: The high voltage MUST be OFF and GROUNDED before any direct personal contact is made with equipment.

Procedures to be followed for safely conducting electrostatic coating operations are outlined in “Operating Your Electrostatic Coating System Safely” section in this Service Manual.

Electrostatic systems depend on high voltage to atomize coating material and deposit it on the target object. During operation, the system is at high voltage. Personnel must NEVER attempt any direct contact with the equipment UNTIL the high voltage is OFF, the atomizer has STOPPED rotating and the ground hook has been attached to the applicator or paint supply as indicated. The ground hook cable MUST be secured to a proven, true earth ground and readily accessible to the applicator or paint supply.

A ground hook is designed to be used with disk or bell atomizers or with insulated fluid suppliers. In addition

to the aluminium hook, the standard assembly has 15 feet of aircraft cable and a solderless connecter for mounting. One assembly should be conveniently located at each station. After the high voltage is off and the atomizer has stopped, the hook should be touched to the atomizer hub or applicator housing momentarily to dissipate any residual charge. It should then be hooked to the applicator housing.

DO NOT allow the hook or its cable to touch the working edge of a disk or bell atomizer. This edge is critical to good atomization and should ALWAYS be protected from any contact that might cause even the slightest damage. For overhead applicators it may be necessary to suspend the cable with a spring or other elastic material in order to prevent edge contact. Most Waterborne Fluid Supply Enclosures include an insulated paint stand plus a grounded chain link enclosure, and a gate that is equipped with a limit switch, switch trip, warning light and control box. The enclosure is also equipped with a standard ground hook assembly to ground the paint supply when personnel are inside of the enclosure.

Personnel entering an insulated fluid supply enclosure MUST FIRST be sure that the system is NOT operating and that the Warning Light is OFF! After entering the enclosure, the ground hook must be attached to the paint supply BEFORE any personal contact is made. The ground hook MUST be attached during all service and above all, during the addition of fluid to the supply container! When leaving the enclosure remove the ground hook and close and secure the gate. The warning light MUST be ON whenever the system is operating.

Ground MUST be maintained during the addition of fluid to any supply container! Whenever transferring

flammable fluid from one container to another, both containers MUST be properly connected to a proven ground first and then to each other. Personnel executing such a transfer must also be grounded. An appropri-ate number of ground hook assem-blies are included with systems that require them. If your installation is no longer equipped with the device, replacements may be purchased (15946) or fabricated according to.

NO. 2 Hand Applicator On-Site Painting

For over 50 years the No. 2 Process hand applicator has been the most widely used tool by on-site painting industry for the refinishing of office furniture, office panels, lockers, school furniture, and dozens of other items. Quite often we are asked about the dangers and possible damage to computers, phone systems, or electronically keyed security systems when electrostatic painting is done nearby.

Concerning those types of applications, the following facts should be noted:

1. The No. 2 Process hand applicator is not electromagnetic. It is electrostatic (much like the static from carpets or wool and synthetic clothing), and works at an output of 100 kilovolts at 30-50 microamperes current draw (100 microamperes maximum short circuit current).

*Grounding of all conductive objects near an electrostatic spray applicator is of utmost importance.

2. Unlike x-rays, “electrostatics” does not go “through” objects.

3. Some computers and phone systems are now shielded by the manufacturer against outside static.


21

4. If the static shielding of the unit is unknown, the keyboard, CPU (central processing unit) and its cable preferably should be removed from the immediate painting area for protection of the device. If this is not feasible they should be completely wrapped in aluminum foil that is grounded to an earth ground. This will create a “Faraday cage” around the computerized device.

5 Electrical sparks of all types create an R.F. energy (radio frequency) that may radiate through the air and enter into electronic circuits. The resulting damage is unpredictable.

6. Computer software such as tapes, disks, diskettes, etc., should be removed from inside and the immediate surrounding area of any enclosures that are to be painted.

7. Lightning or electrostatic voltage sparking into an A.C. circuit can create “spikes” or electromagnetic pulse (EMP) that can cause unpredictable damage to electronic hardware.

8. Surge suppressors are available that may help protect appliances from “spikes” of current if the suppressor is in the A.C. line supplying the appliance.

9. When painting any type of electrical control panel or console it is generally not known if all pushbuttons, switches, meters or pilot lights are properly grounded. In view of this, it is desirable to cover all of these items with aluminum foil, which is grounded to the panel or another earth ground.

10. All on-site painting companies should have adequate liability insurance to protect them in the event or any real or perceived damage as a result of their operations.

In view of the above unknown and possible uncontrolled conditions, Ransburg does not recommend the electrostatic painting of computer cabinets, consoles or painting in close proximity to these devices.


22

4. Material Containers

23

Introduction

All spray painting systems - fromthe smallest brush to the mostsophisticated finishing system-must have containers to hold thematerial being applied.

Material container types and sizesvary considerably, depending onthe kind of spraying system beingused.

This chapter will discuss thesecontainers, their particular applica-tions, their construction and main-tenance.

1. What are materialcontainers?

Any container which serves as amaterial supply reservoir for thespray gun. These containers areusually made of metal or plasticwith capacities of 1/2 pint or more.

2. What are the types of materialcontainers?

There are three common types ofcups which attach to the gun itself:Siphon, Gravity and Pressure.

There are also remote pressurecups and tanks, which are locatedaway from the gun. See Page 4for types of guns and systems.

3. Where are cup containerused?

Cup containers are typically onequart or less, and are used whererelatively small quantities ofmaterial are being sprayed.

4. How are material feed cupsattached to lid assemblies?

Cups are attached using a lidassembly (sometimes called a cupattachment) that either clamps Aor screws B onto the cupcontainer. (see Figure 1) Some lidassemblies are detachable fromthe gun, while others are integralparts and do not detach from lessexpensive models.

A B

Figure 1 - Cup Attachment Styles

5. What capacity does apressure feed cup have?

A pressure feed cup can have aone or two quart capacity.

Anything larger is considered apressure feed tank, which may bepositioned some distance from thegun.

Figure 2 - Regulated 2 Qt.Pressure Cup

6. How do pressure feed tankswork?

Pressure feed tanks are closedcontainers, ranging in size fromabout two gallons to 60 gallons.They provide a constant flow ofmaterial, under constant pressure,to the spray gun.

The tank is pressurized with clean,regulated, compressed air, whichforces the fluid out of the tankthrough the fluid hose to the gun.

The rate of fluid flow is controlledby increasing or decreasing the airpressure in the tank.

A typical pressure feed tankconsists of; A the shell, B aclamp-on lid, C the fluid tube, Dthe fluid header, E regulator, Fgauge, G a safety relief valve, andH agitator.

Pressure feed tanks are availablewith either top or bottom fluidoutlets, and with variousaccessories.

Figure 3 - Pressure Feed Tank

7. Where are pressure feedtanks recommended?

Pressure feed tanks provide apractical, economical method ofmaterial feed to the gun overextended periods of time.

They are mostly used incontinuous production situations,because the material flow ispositive, uniform and constant.

Tanks can be equipped withagitators (see Figure 3) that keepthe material mixed and insuspension.

4. Material Containers

24

8. When is an agitator used in apressure feed tank?

When the material being used hasfiller or pigment that must be keptin motion to keep its particles inproper suspension. An agitatorcan be hand, air or electricallydriver

9. What is a single regulatedtank?

This is a pressure feed tank withone air regulator controlling onlythe pressure on the material in thetank.

An extra-sensitive regulator isavailable for use with lower fluidflow and/or lower viscositymaterial where precise control isneeded.

Figure 4 - Single Regulated Tank

10. What is a double regulatedtank?

This is a pressure feed tankequipped with two air regulators.

One provides regulation for the airpressure on the material in thetank (thereby controlling fluidflow). The other controlsatomization air pressure to thespray gun.

Figure 5 - Double Regulated Tank

11. What are code and non-codepressure tanks?

Code tanks are manufactured torigid standards as specified by theAmerican Society of MechanicalEngineers. (ASME) Each step ofmanufacture is closely controlled,and welding of the shell iscertified. Code tanks are designedto withstand pressures up to 80 or110 psi.

Non-code tanks are normallyrestricted to 3 gallons in size orless. Due to the type ofconstruction, non-code tanks arerated at 80 psi or less.

12. What materials are used toconstruct pressure feed tanks?

The smaller, non-code, light-dutytanks are made of plated steel andhave lower inlet pressurerestrictions.

The heavy-duty, ASME-codetanks are made of galvanized or300 series stainless steel. Theyalso have pressed or stainlesssteel lids with forged steel clamps.

When abrasive or corrosivematerials are being sprayed, thetank shell is coated or lined with aspecial material, or a containerinsert is used.

13. What are container inserts?

They are liners that are placedinside the tank to hold thematerial, keeping it from directcontact with the tank walls. Theyare made of disposablepolyethylene.

Using inserts reduces tankcleaning time and makes colorchangeover easier. They alsoallow multiple batches of materialto be mixed in advance.

You may want to considerstainless steel “Inner containers”when using ceramics or corrosivematerials.

Another option to consider isputting the coating containerdirectly into the tank if roomallows. Be sure that the tank“pickup tube” does not touch thebottom of the coating containerinserted into the tank.

14. When would you use abottom outlet tank?

(1) When you are using moreviscous materials.

(2) When continuous, steadypressure is required, such aswhen feeding plural componentproportioning equipment.

(3) When you wish to use all thematerial in the tank and you arenot using an insert.

15. What would I use if I havedifficulty accurately settinglower fluid pressures?

An extra-sensitive regulator isavailable for use with lower fluidflow and/or lower viscositymaterials where precise controlis needed.

5. Hoses & Connections

25

Introduction

The various types of hose used tocarry compressed air and fluidmaterial to the spray gun areimportant parts of the system.Improperly selected or maintainedhose can create a number ofproblems. This chapter will reviewthe different kinds of hose andfittings in use, provide guidance inselecting the proper types for thejob and cover the maintenance ofhose.

1. What types of hose are usedin spray painting?

There are two types; air hose -used to transfer compressed airfrom the air source to the gun, andfluid hose - used only in pressurefeed systems to transfer thematerial from its container to thespray gun.

(NOTE: Do not use air hose forsolvent-based materials.)

Figure 1 - Basic HoseConstruction

2. How is hose constructed?

Binks/DeVilbiss hose is aperformance designedcombination of three components;A Tube, B Reinforcement and CCover.

The tube is the interior flexibleartery that carries air or fluidmaterial from one end of the hoseto the other.

The reinforcement adds strengthto the hose. It is located betweenthe tube and cover, and it can bemany combinations of materialsand reinforcement design. Itsdesign determines pressurerating, flexibility, kink and stretchresistance and coupling retention.

The cover is the outer skin of thehose. It protects the reinforcementfrom contact with oils, moisture,chemicals and abrasive objects.The cover protects thereinforcement, but does notcontribute to hose performance.

Hose color coding

RED or TAN .....air and water

GREY ...............air w/static ground

BLACK ............low pressure fluid

TAN .................conductive

3. What type of tube is used influid hose?

Since the solvents in coatingswould readily attack and destroyordinary rubber compounds, fluidhose is lined with special nylonsolvent-resistant material that isimpervious to common solvents.

4. What sizes of fluid hose arerecommended?

Type Length Size

General 0' - 20' 1/4" ID

Purpose 10' - 35' 3/8" ID

35' - 100' 1/2" ID

100' - 200' 3/4" ID

Figure 2 - Recommended fluidhose sizes

5. What sizes of air hose arerecommended?

The hose from the regulator to agun or tank should be a minimumof 5/16" ID. Tools requiring moreair may need 3/8" ID hose orlarger.

Type Length Size

Air Tools 0' - 10' 1/4" ID

General 10' - 20' 5/16" ID

Purpose 20' - 50' 3/8" ID

50' - 100' 1/2" ID

0' to 20' 5/16" ID

HVLP 20' - 50' 3/8" ID

50' - 100' 1/2" ID

Figure 3 - Recommended airhose sizes

6. What is pressure drop?

This is the loss of air pressure dueto friction (caused by air flow)between the source of the air andthe point of use. As the air travelsthrough the hose or pipe, it rubsagainst the walls. It loses energy,pressure and volume as it goes.

7. How can this pressure dropbe determined?

At low pressure, with short lengthsof hose, pressure drop is notparticularly significant. Aspressure increases, and hose islengthened, the pressure rapidlydrops and must be adjusted.

All air hose is subject to pressureloss or drop. For example, 1/4"pressure drop is 1 psi per foot and5/16" is 1/2 psi per foot. Thispressure loss may result in pooratomization.

Too often, a tool is blamed formalfunctioning, when the realcause is an inadequate supply ofcompressed air due to anundersized ID hose.

For optimum spray gun results,the following is recommended: upto 20 ft - 5/16" I.D. only over 20 ft -3/8" I.D.

5. Hoses & Connections

26

8. How are hoses maintained?

Hoses will last a long time if theyare properly maintained.

Be careful when dragging hoseacross the floor. It should never bepulled around sharp objects, runover by vehicles, kinked orotherwise abused. Hose thatruptures in the middle of a job canruin or delay the work.

Proper hose cleaning techniquesare covered on Pages 11 and 12.

The outside of both air and fluidhose should be occasionallywiped down with solvent. At theend of every job, they should bestored by hanging up in coils.

9. What kinds of hose fittings areavailable?

Permanent, crimp type or reusablefittings are used to connect hosesto air sources or to sprayequipment.

10. What kinds of hoseconnections are available?

Although there are many differentstyles, the two most common arethe threaded and thequick-disconnect types.

Remember that elements addedto any hose, such as elbows,connectors, extra lengths of hose,etc., will cause a pressure drop.

On HVLP systems,quick-disconnects must havelarger, ported openings to deliverproper pressure for atomization.Because of normal pressure dropin the devices, they are notrecommended for use with HVLP.

11. What is a threaded- typeconnection?

This is a common swivel-fittingtype that is tightened with awrench.

Figure 4 - Threaded-TypeConnection

12. What is a quick-disconnecttype connection?

This is a spring-loaded,male/female connection systemthat readily attaches and detachesby hand. No tools are required.

Figure 5 - Quick-Disconnect TypeConnection

Care should be taken whenselecting a quick, detachable airconnection. Due to design, mostQ.D. connections result insignificant pressure drop. This canadversely affect spray guns withhigher consumption air caps suchas HVLP.

6. Air Control Equipment

27

Introduction

The control of the volume, thepressure and the cleanliness ofthe air entering the spray gun areof critical importance to theperformance of the system.

Following some key installationprinciples will help decrease therisk of contaminants. For example,it’s important to use the right sizeair compressor for yourapplication. An overworked aircompressor can produce asignificant amount of dirt and oil.Additionally, proper piping is veryimportant to help preventcondensation from forming withinthe line and contaminating the airsupply.

This chapter examines the varioustypes of equipment available toperform these control functions.

1. What is air controlequipment?

Any piece of equipment installedbetween the air source and thepoint of use that modifies thenature of the air stream.

2. Why is air control equipmentnecessary?

Raw air, piped directly from an airsource to a spray gun, is of littleuse in spray finishing. Raw aircontains small, but harmful,quantities of water, oil, dirt andother contaminants that will alterthe quality of the sprayed finish.Raw air will likely vary in pressureand volume during the job.

There will probably be a need formultiple compressed air outlets torun various pieces of equipment.

Any device, installed in the air line,which performs one or more ofthese functions, is considered tobe air control equipment.

3. What are the types of aircontrol equipment?

Air control equipment comes in awide variety of types, but itbasically all performs one or moreof the following functions; airfiltering/cleaning, air pressureregulation/indication and airdistribution through multipleoutlets.

4. How does an air filter work?

It filters out water, oil, dust and dirtbefore they get on your paint job.Air entering the filter is swirled toremove moisture that collects inthe baffled quiet zone.

Smaller impurities are filtered outby a filter. Accumulated liquid iscarried away through either amanual or automatic drain.

Figure 1 - Air Filter

5. What is an air regulator?

This is a device for reducing themain line air pressure as it comesfrom the compressor. Once set, itmaintains the required airpressure with minimumfluctuations.

Regulators are used in linesalready equipped with an airfiltration device.

Air regulators are available in awide range of cfm and psicapacities, with and withoutpressure gauges and in differentdegrees of sensitivity andaccuracy.

They have main line air inlets andregulated or non-regulated airoutlets.

6. How is an air filter/regulatorinstalled?

Bolt A the air filter/regulatorsecurely to the spray booth. (seeFigure 2)

This location makes it convenientto read the gauges and operatethe valves. Install the filter/regulator at least 25 feet from the(B) compressed air source. Installthe (C) takeoff elbow on top of the(D) main air supply line.

Piping should slope back towardthe compressor, and a (E) drainleg should be installed at the endeach branch, to drain moisturefrom the main air line.

Use piping of sufficient I.D. for thevolume of air being passed, andthe length of pipe being used.

Minimum Pipe Size Recommendations*

Compressor Main Air Line

HP CFM LENGTH SIZE

1 1/2 - 2 6-9 Over 50' 3/4"

3-5 12-20 Up to 200' 3/4"

Over 200' 1"

5-10 20-40 Up to 100' 3/4"

100' - 200' 1"

Over 200' 1 1/4"

10-15 40-60 Up to 100' 1"

100' - 200' 1 1/4"

Over 200' 1 1/2"

Table 1

6. Air Control Equipment

28

*Piping should be as direct aspossible. If a large number offittings are used, larger I.D. pipeshould be installed to helpovercome excessive pressuredrop.

Figure 2 – Air/Filter RegulatorInstallation

7. How often should thefilter/regulator be drained ofaccumulated moisture and dirt?

It depends largely on the level ofsystem use, the type of filtration inthe air system, and the amount ofhumidity in the air.

For average use, once-a-daydrainage is probably sufficient.

For heavily-used systems, or inhigh humidity, drainage shouldoccur several times daily.

Some units drain automaticallywhen moisture reaches apredetermined level.

8. What steps should be taken ifmoisture passes through thefilter/regulator?

Since moisture in the spray gunatomization air will ruin a paint job,it must be removed from the airsupply.

When the compressed airtemperature is above its dew pointtemperature, oil and water vapor

will not condense out into solidparticles.

Check the following:

a) Drain filter, air receiver and airline of accumulated moisture.

b) Be sure the filter is located atleast 25 feet from the air source.

c) Main air line should not runadjacent to steam or hot waterpiping.

d) Compressor air intake shouldnot be located near steam outletsor other moisture-producing areas.

e) Outlet on the air receiver shouldbe near the top of the tank.

f) Check for damaged cylinderhead or leaking head gasket, if theair compressor is water cooled.

g) Intake air should be as cool aspossible.

9. What causes excessive pres-sure drop on the main linegauge of the filter/regulator?

a) The compressor is too smallto deliver the required airvolume and pressure for alltools in use.

b) The compressor is notfunctioning properly.

c) There is leakage in the air lineor fittings.

d) Valves are partially opened.

e) The air line, or piping system,is too small for the volume ofair required. Refer to Table 1,Page 20.

7. Respirators

29

Introduction

Spray finishing creates a certainamount of overspray, hazardousvapors and toxic fumes. This istrue, even under ideal conditions,and there is no way to avoid itentirely.

Anyone near a spray finishingoperation should use some type ofrespirator, or breathing apparatus.This chapter covers various typesof equipment for this use.

1. What is a respirator?

A respirator is a mask that is wornover the mouth and nose toprevent the inhalation of oversprayfumes and vapor.

2. Why is a respiratornecessary?

For two reasons:

First...some type of respiratoryprotection is required by OSHA/NIOSH regulations.

Second...even if it wasn't arequirement, common sense tellsyou that inhaling overspray is nothealthy.

Overspray contains toxic particlesof paint pigments, harmful dustand vapor. Exposure to any of theabove is a potential health risk.

Depending on design, a respiratorcan remove some, or all, of thesedangerous elements from the airaround a spray finishing operator.

3. What types of respirators areused by spray finishingoperators?

There are three primary types; theair-supplied respirator, the organicvapor respirator and the dustrespirator.

4. What is an air-suppliedrespirator?

This type is available in bothmask and visor/hood styles. Both

provide the necessary respiratoryprotection when using materialsthat are not suitable for organicvapor respirators.

The visor/hood style provides agreater degree of coverage to thehead and neck of the operator.

Both styles require a positivesupply of clean, breathable air asdefined by OSHA (Grade D).

Figure 1 – Positive PressureVisor/Hood

Figure 2 – Positive Pressure MaskRespirator

5. What is an organic vaporrespirator and where is it used?

This type of respirator, whichcovers the nose and mouth, (seeFigure 3) is equipped with areplacement cartridge thatremoves the organic vapors bychemical absorption.

Some are designed with a prefilterto remove solid particles from theair before it passes through thechemical cartridge.The organic vapor respirator is

usually used in finishingoperations with standardmaterials. (not suited for paintscontaining isocyanates).

Figure 3 - Organic VaporRespirator

6. What is a dust respirator andwhere is it used?

Dust respirators are sometimesused in spray finishing but, in mostapplications, they areunsatisfactory. (see Figure 4)

Figure 4 - Dust Respirator

These respirators are equippedwith cartridges that remove onlysolid particles from the air. Theyhave no ability to remove vapors.

They are effective, however, inpreliminary operations such assanding, grinding and buffing.

NOTE:

Before using any respirator,carefully read the manufacturer’sSafety Precautions, Warnings andInstructions. Many respirators arenot suitable for use withisocyanates, asbestos, ammonia,pesticides, etc.

8. Air Compressors

30

Introduction

All air tools, spray guns, sanders,etc., must be supplied with airwhich is elevated to the higherpressures and is delivered insufficient volume. The aircompressor compresses air foruse in this equipment and is amajor component of a spraypainting system. This chapter willexamine the various typesavailable.

Compressed air is measured onthe basis of the volume suppliedper unit of time (cubic feet perminute, or cfm) at a givenpressure per square inch (psi),referred to as delivery.

Displacement is the output of airby a compressor at zero pressure,or free air delivery.

1. What is an air compressor?

An air compressor is a machinedesigned to raise the pressure ofair from normal atmosphericpressure to some higher pressure,as measured in pounds persquare inch (psi). While normalatmospheric pressure is about14.7 pounds per square inch, acompressor will typically deliver airat pressures up to 175 psi.

When selecting a compressor:

Rule of thumbThe cubic feet per minutedelivered by an electricallypowered 2 stage industrial aircompressor is 4 times the motor'shorse power rating. (CFM=4xHP)

2. What types of compressorsare most common in sprayfinishing operations?

There are two common types; thepiston-type design and the rotaryscrew design.

Because most commercial sprayfinishing operations consumelarge quantities of compressed airat relatively high pressures, the

piston type compressor is themore commonly used.

3. How does a piston-typecompressor work?

This design elevates air pressurethrough the action of areciprocating piston. As the pistonmoves down, air is drawn inthrough an intake valve. As thepiston travels upward, that air iscompressed. Then, thenow-compressed air is dischargedthrough an exhaust valve into theair tank or regulator.

Piston type compressors areavailable with single or multiplecylinders in one or two-stagemodels, depending on the volumeand pressure required.

Figure 1 - Piston Type AirCompressor

4. How does a rotary screwcompressor work?

Rotary screw compressors utilizetwo intermeshing helical rotors ina twin bore case. Air iscompressed between one convexand one concave rotor. Trappedvolume of air is decreased and thepressure is increased.

Figure 2 – Rotary Screw AirCompressor

5. What is a single stagecompressor?

This is a piston-type compressorwith one or more cylinders, inwhich air is drawn from theatmosphere and compressed to itsfinal pressure with a single stroke.

All pistons are the same size, andthey can produce up to 125 psi.

6. Where are single stagecompressors used?

The application of this compressoris usually limited to a maximumpressure of 100 psi. It can be usedabove 100 psi, but above thispressure, two stage compressorsare more efficient.

7. What is a two-stagecompressor?

A compressor with two or morecylinders of unequal size in whichair is compressed in two separatesteps.

The first (the largest) cylindercompresses the air to anintermediate pressure. It thenexhausts it into a connecting tubecalled an intercooler.

From there, the intermediatepressurized air enters the smallercylinder, is compressed evenmore and is delivered to a storagetank or to the main air line.

Two stage compressors candeliver air to over 175 psi.

They are normally found inoperations requiring compressedair of 125 psi or greater.

8. What are the benefits of twostage compressors?

Two stage compressors areusually more efficient. They runcooler and deliver more air for thepower consumed, particularly inthe over-100 psi pressure range.

9. Spray Booths

31

Introduction

Containing the overspray andkeeping it out of the air and offother objects is an importantconsideration in a spray finishingoperation. This chapter looks atthe primary method of controllingoverspray in the spray booth. Itdiscusses various types of boothsand details periodic maintenance.

1. What is a spray booth?

A compartment, room orenclosure of fireproof construction;built to confine and exhaustoverspray and fumes from theoperator and finishing system.

There are various modelsavailable, designed for particularspray applications.

Consult the National FireProtection Association (NFPA)pamphlet #33 and the O.S.H.A.requirements for constructionspecifications.

2. What are the benefits of aspray booth?

A well-designed and maintainedspray booth provides importantadvantages:

It separates the sprayingoperation from other shopactivities, making the spraying, aswell as the other operations,cleaner and safer.

It reduces fire and health hazardsby containing the overspray.

It provides an area that containsresidue, making it easier to keepclean. It also keeps both theoperator and the object beingsprayed cleaner.

In a booth equipped with adequateand approved lighting, it providesbetter control of the finish quality.

3. What types of spray booths arethere?

There are two; the dry filter typeand the waterwash type.

4. What is a dry filter type spraybooth?

This booth draws overspray-contaminated air throughreplaceable filters and vents thefiltered air to the outside.

It is the most common type ofbooth for most industrialapplications.

It is used for spraying low-volume,slower-drying materials, and is notaffected by color changes.

Figure 1 - Dry Filter Type Booth

5. What is a waterwash type booth?

A waterwash booth (see figure 2)actually washes the -contaminatedoverspray air with a cascade ofwater, and traps the paint solids.Fewer paint particles reach theoutside atmosphere to harm theenvironment.

Waterwash booths are generallyused when spraying more than 15gallons of material a day.

Figure 2 - Waterwash Type SprayBooth

Figure 3 - Automotive Downdraft DryFilter Booth

6. What is an exhaust fan?

A typical exhaust fan (see figure4) consists of a motor, a multipleblade fan, pulleys and belts. Itremoves overspray from the spraybooth area.

Contemporary exhaust fans arecarefully designed to preventoverspray from coming intocontact with the drive mechanism.

Blades are made of non-sparkingmetal, and they move themaximum volume ofair-per-horsepower againstresistance such as exhauststacks, filters, etc. (See NFPApamphlet #33.)

9. Spray Booths

32

Figure 4 – Exhaust fan

7. What is air velocity?

Air velocity in a finishing operationis the term used to describe thespeed of air moving through theempty spray booth.

8. What effect has air velocity onspray booth efficiency?

Air must move through the boothwith sufficient velocity to carryaway overspray.

Too low a velocity causes poor,even potentially dangerousworking conditions, especiallywhen the material contains toxicelements. It also increasesmaintenance costs.

Too high a velocity wastes powerand the energy required to heatmake-up air

9. What is a manometer?

It is a draft gauge which indicateswhen paint arrestor filters or intakefilters are overloaded.

Some states and local codesrequire a manometer gauge oneach bank of filters to comply withOSHA regulations.

Figure 5 - Manometer

10. What does an airreplacement unit do?

The volume of air exhausted froma spray booth is often equal tothree or more complete airchanges per hour.

Under such conditions, thetemperature may become irregularand uncomfortable. Excessivedust may become a problem.

To prevent these conditions,sufficient "make-up" air must beintroduced to compensate for theexhausted air.

The air replacement unitautomatically supplies this"makeup" air - both filtered andheated - to eliminate the problemsof air deficiency.

Figure 5 - Air Replacement Unit

11. What routine maintenancedoes a dry type spray boothrequire?

(a) The continuous flow of airthrough the booth eventuallyloads the filters with dirt andoverspray. Periodically, inspectand replace them withmultistage filters, designed forspray booth use. Single-stagefurnace filters will not do the job

(b) Monitor the manometerreadings daily, and know whata normal reading should be.

(c) Keep the booth free of dirt andoverspray. Floors and wallsshould be wiped down afterevery job. Pick up scrap,newspapers, rags, etc.

(d) Coat the inside of the boothwith a strippable, spray-oncovering. When the oversprayon it becomes too thick, stripand recoat.

(e) Periodically check the lightinginside the booth, and replaceweak or burned out bulbs.Improper lighting can cause theoperator to apply a poor finish.

12. What routine maintenancedoes a waterwash type boothrequire?

(a) Compounding of the water inthis type unit is essential.Employ only booth treatmentchemicals in accordance withsuppliers' recommendations.The ph of the water should bebetween 8 and 9.

(b) Maintain the water level at theproper setting permanufacturers' specifications.

(c) Check the tank for paintbuildup on the bottom, checkthe pump strainer to keep itclean and clear, check the airwasher chamber and thenozzles in the header pipe. Ifthe nozzles are plugged, theoverspray will encroach on thewash baffle section, fan andstack.

(d) Periodically check the floatvalve for proper operation.Flood the sheet to be surethere is a uniform flow over theentire surface.

(e) Keep the booth interior andexhaust stack free from.overspray and dirtaccumulation.

9. Spray Booths

33

13. What checks can be used toassure good results from aspray booth? .

a) Keep the interior of the boothclean

b) Maintain and replace intake andexhaust filters when necessary.

c) Caulk all seams and crackswhere dirt might enter

d) Maintain and clean all equipmentused in the booth

e) Keep operators' clothing clean andlint-free.

f) Perform routine maintenanceabove on a scheduled basis

10. Diaphragm Pumps

34

Introduction

Diaphragm pumps can serveseveral purposes in a spraysystem. The can be used as atransfer pump to move coatingsfrom one container to another(ie. drum to a pressure pot).

In many cases larger diaphragmpumps can be used in a paintsupply room to supply pressureto low pressure spray gunseither in a dead-end system or acirculating system.

They may also be used in thespray booth to siphon directlyout of a container supplying lowpressure coatings to the spraygun. If required the coating couldbe returned to the source in acirculating system.

Figure 1

1. How are diaphragm pumppressures determined?

Diaphragm pumps are normallya 1:1 ratio. The maximumpressure would be limited by thepump design (ie. 100 psi) or bythe available pressure to thepump.

2. What is meant by primingthe pump?

Before setting working fluidpressures, start an empty pumpby slowly opening the airpressure valve (or regulator) tothe air motor. When the pump nolonger cycles (full of coating), setthe fluid pressure to the workingpressure.

If the air motor receives fullworking pressure with an emptyfluid section, the fluid sectioncontains air and will initially runat high speed with no lubrication.This will increase the risk ofdamaging the fluid section.

3. How does a diaphragmpump work?

Refer to Figure 2

Figure 2

We will assume the pump infigure 2 is primed and theconnecting rod at its maximumleftward movement and thepump is ready to move to theright. When fluid is called for,both diaphragms begin to moveto the right via the rodconnecting them. The fourball/seat valves behave asfollows:

Ball Check ARemains closed due to pressurein the right hand chamber.

Ball Check BOpens to allow fluid in the righthand chamber to exit the pump

Ball Check CRemains closed due to pressurein the upper portion of the pump

Ball Check DOpens to allow fluid to besiphoned from the materialcontainer.

When the connecting rod causesboth diaphragms to move to theleft, the four ball check behave ina direction opposite to theabove.

4. How do I troubleshoot adiaphragm pump air motor?

Freezing Motor� Air exhausting from the

pump tends to freeze (stall)motor

� High humidity and/or cyclerate

� Fix: Pipe exhaust away frompump

Dirt or debris in air supply� Dirt can plug internal ports &

shear air motor o-rings� Fix: Install air filtration

Oils in air supply� Improper or excess

lubrication can cause airmotor o-rings to swell andstall the pump

� Fix: Following manufacturersrecommendation forlubrication

Water in air supply� Water can wash out factory

installed lubricant, leading topump failure

� Fix: Install proper filtration

10. Diaphragm Pumps

35

Product discharged from airexhaust when idleCheck for diaphragm rupture� Check tightness of

diaphragm nut

Pump blows air out main airexhaust when idle� Check “U” cups on spool in

major valve� Check valve plate and insert

for wear� Check sleeve and “O” ring

on diaphragmconnecting rod

� Check “O” ring on piston forwear

6. How do I troubleshoot adiaphragm pump wet section?

Leaking Clamps� Old/worn clamps do not

produce a good seal� Leaking material can be an

environmental issue� Note: Most pumps use

bolted construction ratherthan clamps and are lessprone to leakage

Clogged Checks� Checks cannot seat

properly. Fluid will bereduced or eliminated

� Fix: Clean or replace checkassembly

Fluid Compatibility� Incompatibility can reduce

life of pump� Danger: Aluminum pumps

may violently react withmaterials containing HHC(Hologenated Hydrocarbon)solvents, ie. CarbonTetrachloride.

Under Sizing� Pump cannot meet

application requirements -shorter pump life.Undersizing typically causeshigh cycle rates.

Pump will not prime or meetdelivery requirements� Suction line blocked or

undersized, clogged ballseats

� Suction line too long� Suction line pulling material

too far above top of fluidlevel

Air bubbles in product discharge� Check connections of

suction plumbing� Check “O” rings between

intake manifold and fluidcaps

� Check tightness ofdiaphragm nut

Low output volume� Check air supply� Check for plugged outlet

hose� Pump mounted in vertical

position?� Check for pump cavitation -

Suction pipe minimum 1/2”and non-collapsible.Cavitation will occur whenthe material is exiting thepump faster than it can bedrawn in.

� Check all intake & suctionjoints - Must be airtightUse Teflon tape or sealant ifnecessary

� Check for sticking orimproperly seating checkvalves.

11. High Pressure Spraying

36

Introduction

High pressure spray equipmentwill typically use between 300 and4000 psi of fluid pressure. Lowpressure equipment (air spray andHVLP) typically use 5-30 psi.When high volume applicationsand heavy film builds are calledfor, high pressure equipmentexcels.

Airless and air assist airless sprayguns are used in high pressurefinishing. Also required is a pumpcapable of delivering thepressures required for highpressure guns.

Other equipment concerns arehoses, regulators, filters, heatersand any other equipment that issubjected to the pressures beingused and must be rated to handlethe pressure.

1. What are the advantages ofHigh Pressure Finishing?

� Speed of ApplicationDue to the high flow rates, H.P.equipment will be considerablyfaster than L.P. equipment� Improved Transfer Efficiency� Little or no air in the spray

pattern� Sprays Most Coatings� Cost for high volume and high

film build applications

2. What are the disadvantagesof High Pressure Finishing?

Safety issues must be addressed.More training is required.Limited equipment flexibility.Unlike low pressure equipment,cup guns, feathering the triggerand pattern adjustment are notavailable� Higher Initial CostsH.P equipment must be able tohandle the higher pressures used.In addition, pumps are required togenerate the pressures.� Not For Small QuantitiesH.P. equipment flow rates aregenerally rated in gallons per

minute, L.P. equipment in ouncesper minute.� Plugging TipsDue to the small opening in thefluid tip, plugging is notuncommon in H.P. equipment.Treatment and prevention forplugging may be found in thetroubleshooting section of thismanual.� Heat may be required for high

solids coatingsWhen using today’s higher solidmaterials, heating of the materialto lower the viscosity may berequired to achieve theatomization required.

� Not For Fine FinishThe atomization capabilities ofH.P. equipment will not allow it toobtain an automotive finish.Acceptability will depend on thefinish standards of the productbeing sprayed as well as thecharacteristics of the coating.

Safety

3. What are the safetyconcerns with H.P.equipment

� Skin InjectionH.P. equipment has the capabilityof injecting coating into fingers,hands, etc.

Follow all safety instructionsincluded with the equipment. Usetip guards and trigger locks whereappropriate

� Supporting EquipmentInsure that all supportingequipment is rated for thepressures that could begenerated. Use the maximumpump pressure as a guide.

� Respirators

Figure 1

Use the appropriate protectiondevice as listed in the coating’sMaterial Safety Data Sheet(MSDS)

Warning:

INJECTION HAZARD

Spray from the gun, hose leaks, orruptured components can injectfluid into your body and causeextremely serious injury, includingpoisoning or the need foramputation.

Splashing fluid in eyes or on skincan also cause a serious injury.

Fluid injected into the skin mightlook like just a cut, but is a seriousinjury and should be treated assuch.

GET IMMEDIATE MEDICALATTENTION. INFORM THEPHYSICIAN WHAT TYPE OFMATERIAL WAS INJECTED.

Do not point the spray gun atanyone or any part of the body.

Do not put fingers or hand overthe spray tip.

Do not stop or detect fluid leakswith a rag, hand, body or glove.

Do not use a rag to blow backfluid. THIS IS NOT AN AIRSPRAY GUN.

Be sure the trigger operates safelybefore spraying.

Engage the gun safety when notspraying.

ALWAYS RELIEVE THEPRESSURE WHENEVERWORKING ON THE SPRAYGUN.

Tighten all fluid connectionsbefore operating equipment.

Check all hoses, tubes, andcouplings daily. Replace all worn,damaged, or loose partsimmediately.

12. Airless and Air Assist Airless Guns

37

IntroductionHigh pressure spraying requiresthe use of spray guns that canwithstand the pressuresassociated with the pressuresdelivered via piston pumps.

Airless and Air Assisted Airlessare currently available in bothmanual and automatic models.

Some models may have maximumpressures below the pressures thepumping system may deliver.Consult your distributor todetermine your pump

1. What is an airless gun?

An airless gun uses high hydraulicpressure to force coating througha small elliptical shaped orifice toatomize.

2. What do I need to know tochoose an airless fluid tip?

The following will determinepattern size and atomization,:

Fluid tip orifice shapeFluid tip orifice areaFluid viscosityFluid pressure

Fluid tips for airless guns aresized based on an equivalentcircular opening. As an example, a.015” opening can take on manydifferent shapes, thus differentpattern sizes and atomizationlevels. For example, Table 1shows 7 different .015 fluid tipsavailable for one model of anairless spray gun.

The shape of the opening is thevariable that determines thepattern size.

An additional note: The largerpattern sizes are the result of a tipopening that is more slender thanthe shorter pattern tip. This willgive a larger pattern size at theexpense of more frequent tipplugging and shorter tip life.

114-01506 .015 4” – 6”114-01508 .015 6” – 8”114-01510 .015 8” – 10”114-01512 .015 10” – 12”114-01514 .015 12” – 14”114-01516 .015 14” – 16”114-01518 015 16” – 18”

Table 1 – Sample .015 tips

3. How does an airless gunoperate?

An airless spray gun uses highhydraulic fluid pressuregenerated by a pump. The fluidis forced through a smallelliptical shaped orif ice (fluid tipor fluid nozzle) to generate thepattern.

Figure 1 – Airless Spray Gun

4. What is an air assistairless gun?

When air airless gun (see Figure4) is set up with pressures under2000 psi, the possibility ofincomplete atomizationincreases. The net result is apattern that has “tails” at the topand bottom. If sprayed with sucha pattern, one would see a stripeat the top and bottom of eachpass (see figure 2).

Figure 2 – IncompleteAtomization

Figure 3 – Air Assist

An air cap similar to aconventional or HVLP spray gunis added to a high pressurespray gun, thus the name AirAssist Airless. Set the pressureon the assist air is set highenough to eliminate the tails.(see figure 3)

Figure 4 – Air Assist Gun

13. Two Ball Piston Pumps

38

Two Ball Piston Pumps

Introduction

Figure 1 – Two Ball Piston Pump

A pump is required to generate thepressures required for airless and airassist airless spray guns,.

The most common pump used tosupply high pressure spray guns is anair driven two ball piston pump.

1. How are piston pump pressuresdetermined?

Pump ratios are determined by thesize of the piston in the air motorcompared to the size of the piston inthe fluid section.

The maximum pump pressureavailable from a pump is the ratio ofthe pump multiplied by the maximumair inlet pressure as stated in thepump literature.

As an example, consider a pistonpump with an 8” air motor and a 2”fluid section.

8” = 50.24 square inch area2” = 3.14 square inch area

50.24/3.14 = 16:1 ratio

If the pump had a maximum air inletpressure of 100 psi, the maximumfluid pressure the pump couldgenerate is 1600 psi.

2. What ratio do I need for my spraygun?

It is generally recommended that themaximum usable pressure isapproximately 60-70% of themaximum pump pressure. A spraygun that requires 1000 psi of fluidpressure would need approximatelyan 18:1 pump (60% times 1800 psiwould give 1080 psi of workingpressure.

Other factors that influence ratioselection include:�Gun distance from pump (pressure

drop)�Circulation requirements (if used)�Viscosity of material�Size of fluid tip in gun�Pipe layout

3. What is meant by priming thepump?

Before setting working fluid pressures,start an empty pump by slowlyopening the air pressure valve (orregulator) to the air motor. When thepump no longer cycles (full ofcoating), adjust the regulator to set thefluid pressure to the working pressure.

If the air motor receives full workingpressure with an empty fluid section,the fluid section contains air and willinitially run at high speed with nolubrication. This will increase the riskof friction/heat damaging the packingsand/or fluid section.

4. How does a Two Ball FluidSection work?

The fluid section is connected to theair motor. As the air motor moves up(1 stroke) it brings the displacementrod up. As the air motor moves down,it pushes the displacement rod down.

Figure 2 – 2 Ball Fluid Section

During the upstroke, the lower ball (B)raises allowing coating to enter thelower portion of the fluid section.Coating in the upper portion of thefluid section is pushed out of theoutlet. The upper ball (A) remainsclosed. (see to Figure 2)

During the downstroke, the lower ballremains closed. The upper ball isforced open allowing coating from thelower portion of the pump to enter theupper portion pushing coating out ofthe outlet.

If the pump is designed properly, 50percent of the pumps output will bedelivered on each stroke. (oneupstroke, one downstroke). Note thatwith most 2 ball pumps all of thecoating siphoned into the pump for thecomplete cycle enters the fluid sectionon the upstroke.

5. What is the purpose of the WetCup?

Lubrication for the upper packings isprovided by a lubricant added to the“Wet Cup” at the upper portion of thefluid section. This cup is not designedto contain solvent. Solvent willevaporate, leaving the upper packingswithout lubricant. Throat SealLubricant (TSL) should be used in thewet cup.

6. What is meant by cavitation?

A pump has little difficulty pushingmaterial through the outlet into thepiping or tubing system.

If the pump cannot bring material intothe pump as fast as it pushes it out, acavity or void is created in the inputarea. This could result if the materialis highly viscous or the siphon tube isundersized or not airtight

14. High Pressure System Setup – Dead End

39

Introduction

Proper setup of high pressureequipment is necessary not only forefficient operation of the equipment,but safe operation as well.

Airless and Air Assist Airless may besupplied by a dead-end system or acirculating system.

Following are instructions for a dead-end system.

1. How do I set up a simple (dead-end) high pressure system?

Refer to Figure 1 for a typical “deadend” high pressure system.

1. 2 Ball Piston PumpAvailable in range of approximately11:1 to 60:12. Filter/Regulator for Pump air motorThe air motor of a piston pump needsto be supplied with clean, dry air3. Surge tank (pulsation chamber)Eliminates pulsation that happenswhen the piston changes direction4. Dual Fluid FiltersPrevents the line from being shutdown when it is time to clean the filter5. Fluid pressure gaugeMonitors the fluid pressure in the mainline

6. Drop Line regulatorAllows for regulation to the requiredpressure of the spray gun.

2. What parameters in a “dead end”system should be of concern?

1. Use only components that canhandle the pressures in thesystem. This includes allcomponents in figure 1 as well ashoses, guns, fittings, etc.

2. Fluid lines must be sizedadequately to prevent largepressure losses

3. When using coating materials that“settle out” or high viscositymaterials that need to be heated,a circulating system may be abetter option.

3. How fast or slow should mypump be cycling?

Most pumps give a flow rate percycle as well as a flow rate for 60cycles. A flow rate of 15 cycles perminute will keep maintenance to aminimum. As you increase cyclespeed, maintenance cost will increaseas well.

If you undersize a pump, high cyclerates and high maintenance costs willbe the result.

4. What safety issues should beaddressed in a high pressuresystem?

1. All components in the systemsmust be rated to handle themaximum pressure the pumpcould generate.

2. Avoid the possibility of anyportion of the body being near thefluid tip whenever there is achance of fluid leaving the tip. Ifyou inject your skin with coating,seek medical help immediately.

3. If the gun is equipped with atrigger safety, engage it when thegun is not in use.

4. If the gun is equipped with a tipguard (duck bill), do not removeit.

Figure 1 – Dead End High Pressure System

15. Four Ball Pumps

40

Introduction

Figure 1 – Four Ball PistonPump

A four ball pump generally isused in a “pump house” or “paintkitchen” for delivering lowerpressures a long distance orhigh flow rates.

Pressures tend to be much lowerthan 2 ball pumps and are oftenregulated down at the point ofuse for air atomized spray guns.

1. What ratios are availablein a four ball pump.

Due to the larger fluid section, avery large air motor would berequired to achieve the typicalpressures achieved with two ballpumps. Using the same airmotors used in two ball pumps,four ball pumps typically top atabout a 7:1 ratio.

2. How does the fluid sectionof a four ball pump work?

A four ball piston pump fluidsection contains four ball checksthat alternate open and closedduring up and down strokes(refer to figure 2).

During the down stroke:Ball checks (D) and (A) open.Ball (A) allows fluid to exit whileball (D) allows fluid to enter thepump.Ball checks (B) and (C) remainclosed.

During the up stroke:Ball checks (B) and (C) open.Ball (B) allows fluid to exit whileball (C) allows fluid to enter thepump. Ball checks (D) and (A)remain closed.

Figure 2- FourBall Fluid Section

16. Circulating Systems

41

Introduction

A circulating system delivers fluidfrom the pump to the spray gunand back to the pump. (see figure1).

You should consider a circulatingsystem:

1. When multiple stations needthe same coating.

2. When you want to put a paintheater in the system (toreduce viscosity withoutadding solvents).

3. When you have problems withthe solids of a coating “settlingout”.

1. What flow rates are used in aCirculating system?

Typical flow rates for solventbased materials are one foot persecond (60 feet/min).

Typical water based materials useone half foot per second (30feet/min).

Consult your Product Data Sheetor your coating supplier forrecommendations for yourcoating.

2. How does a circulatingsystem work?

While some circulating systemscan get very complex, refer tofigure 1 for a very basic circulatingsystem

The coating leaves the fluidsection of the pump and travelsthrough hoses, pipes, etc. to thespray gun.

A valve or tee at the spray dropline returns a portion of thematerial back to the pump on areturn line.

The materials may return to thepump inlet or into the materialcontainer.

3. What is a back pressureregulator?

Referring to figure 1, imagine theback pressure regulator (3)removed from the system and thepiping is straight through back tothe pump.There would be no reason for thematerial to flow to the spray gunas the path of least resistance forthe material is back to the pump.

By putting a back pressureregulator in the system we createa dam that allows some fluid toreturn to source but set up apartial blockade (back pressure) toallow material to flow to the spraygun.

The general sequence foradjusting a back pressureregulator is:

1. Set the regulator to insurethat the spray guns haveadequate operatingpressure.

2. Adjust for proper flow rate3. Adjust for proper pump

speed

Figure 1 – Circulating System

5

5. Fluid Pressure Regulator w/gauge and standpipe/riser tube

16. Circulating Systems

42

4. What other components areused in a circulating system?

Downstream Fluid Regulators:For controlling pressure at eachspray gun

Surge Tanks/Chambers:For suppressing the “wink” orpulse in the system, induced bythe pump changing directionduring the cycle

Heaters:For decreasing viscosity withoutadding solvent and maintaining aconstant viscosity

Filters:For removing contaminants andpreventing plugging gun fluid tipsand spray defects. Note: Filtersare located in the pressure side ofthe system.

Strainers:For removing “trash” prior toentering the pump. Note: Strainersare located on the non-pressureportion of the system, normally onthe end of the pump pick-up tube.

Drum Lifts/Elevators:Allows the pump and drum lid tobe raised to facilitate replacementof the drum.

Agitator:Keeps material in suspension inthe drum/container.

17. High Pressure Troubleshooting

43

Introduction

Problems arising in a highpressure pumping system canrange from something as simpleas a plugged fluid tip to arunaway pump.

Service literature thataccompanies your equipment ishighly recommended reading.

1. What problems can I havewith my high pressuresystem?

Plugged airless tips:Caution: At a minimum, lock thetrigger before working on a highpressure airless fluid tip. Ifpossible, remove the pressure tothe gun.Be cautious when cleaning thetip orifice. Use onlyrecommended tools to clean aplugged tip.

Runaway Pump

When the material supply “runsout”, the pump will cycle atmaximum speed.

A “runaway” detecting valve canbe installed in the air linebetween the air motor and theregulator to prevent pumpdamage. Check your pumpaccessory catalog for runawayvalve options.

Defective Spray Patterns

Airless:Replace or clean the tip

Air Assist Airless:Rotate the air cap 180 degrees.If the pattern changes, clean orreplace the air cap. If the patterndid not change, clean or replacethe fluid tip.

Fluid Section Problems

No Material at outlet(Pump continually cycles)

Check material supply

Material on one stroke only.(fast down stroke) 2 Ball

Lower ball not properly seating

Material on one stroke only.(fast upstroke)

Worn or damaged seals

Material leakage from solventcupWorn or improperly adjustedupper packings.

Air bubbles in product dischargeSiphon kit improperly installed.

(not air tight)

Material on one stroke only.(fast up or down stroke) 4 Ball

One of lower balls not properlyseating.

Air Motor Problems

Air leakage out of mainexhaustWorn Insert

Replace InsertWorn valve plate & pin assyReplace plate & assy.

Damaged piston assy.Replace piston assy.

Sales and ServiceThrough a Nationwide Network of Industrial Distributors

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Toledo, OH 43612

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Glendale Heights,IL 60139

630.237.5000630.237.5011 Fax

www.binks.comwww.devilbiss.comwww.ransburg.com

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Technical Support1-888 - 992 -4657

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Documents

ABC’s of Spray Finishing - ABsupply.netsSprayFinishing.pdf · While this book examines the spray finishing operation and its equipment from many viewpoints, ... painting equipment