1 STEAM HEATING. 2 ) What is Steam Heating a) Steam heat is similar to hot water heat except the latent heat of the steam vapor contains a larger amount

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STEAM HEATING

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STEAM HEATING

) What is Steam Heating a) Steam heat is similar to hot water heat except the latent heat of the steam vapor contains a larger amount of heat 1) 970 btu of latent heat in each pound of water will turn to steam at 212 degrees F. b) Steam is circulated through the system as a vapor to the steam terminal unit, where it is condensed to a liquid & returned to the boiler continue

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STEAM HEATINGSTEAM HEATING

• 1) What is Steam Heating• c) In a typical 1 pipe system, the

boiler is below the terminal heat exchange unit & the steam supply line in pitched upward toward the boiler

• 1) The condensate returns down the steam line to the boiler by gravity

• d) In a 2 pipe system the steam vapor line is larger than the liquid condensate return line

• 1) What is Steam Heating• c) In a typical 1 pipe system, the

boiler is below the terminal heat exchange unit & the steam supply line in pitched upward toward the boiler

• 1) The condensate returns down the steam line to the boiler by gravity

• d) In a 2 pipe system the steam vapor line is larger than the liquid condensate return line

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• 2) Boilers & Controls• a) Gas & oil fired steam boilers are like

hot water boilers• 1) Electric steam boilers are typically

larger than electric water boilers because of the need for a steam dome

• b) The low pressure steam boiler has a working pressure of 15 psig or less

• 1) A quick opening safety relief valve to relieve the pressure is set for 15 psig

• continue

• 2) Boilers & Controls• a) Gas & oil fired steam boilers are like

hot water boilers• 1) Electric steam boilers are typically

larger than electric water boilers because of the need for a steam dome

• b) The low pressure steam boiler has a working pressure of 15 psig or less

• 1) A quick opening safety relief valve to relieve the pressure is set for 15 psig

• continue

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• 2) Boilers & Controls• c) The steam boiler does not have the

liquid head that the hot water boiler has in a tall building

• 1) When the steam condenses the pressure lowers, The higher pressure steam moves to the lower pressure therefore steam does not require a head pressure like water

• d) Each boiler must be equipped with a pressure gauge & pressure control for shutting off the boiler when the proper pressure is reached

• continue

• 2) Boilers & Controls• c) The steam boiler does not have the

liquid head that the hot water boiler has in a tall building

• 1) When the steam condenses the pressure lowers, The higher pressure steam moves to the lower pressure therefore steam does not require a head pressure like water

• d) Each boiler must be equipped with a pressure gauge & pressure control for shutting off the boiler when the proper pressure is reached

• continue

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• 2) Boilers & Controls• e) The pressure control & pressure gauge are

installed with a trap connector between them and the boiler

• 1) The trap prevents raw steam from reaching the indicator mechanism

• a) A bourdon tube is a tube expands with pressure, used in gauges & controls

• 2) The connector is called a pigtail or a U-Tube• a) The pig tail must be installed so that expansion

& contraction will not effect the pressure controls• 3) A gauge valve should be positioned in the line

to allow service to the gauge• continue

• 2) Boilers & Controls• e) The pressure control & pressure gauge are

installed with a trap connector between them and the boiler

• 1) The trap prevents raw steam from reaching the indicator mechanism

• a) A bourdon tube is a tube expands with pressure, used in gauges & controls

• 2) The connector is called a pigtail or a U-Tube• a) The pig tail must be installed so that expansion

& contraction will not effect the pressure controls• 3) A gauge valve should be positioned in the line

to allow service to the gauge• continue

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• 2) Boilers & Controls• f) Each steam system has a boiler

vent that allows air to escape the boiler on start up & that breaks the vacuum when the boiler cools the room temperature

• a) When the boiler cools, the steam inside condenses, The condensation reduces the volume, The boiler pressure would reduce to a vacuum without a vent

• continue

• 2) Boilers & Controls• f) Each steam system has a boiler

vent that allows air to escape the boiler on start up & that breaks the vacuum when the boiler cools the room temperature

• a) When the boiler cools, the steam inside condenses, The condensation reduces the volume, The boiler pressure would reduce to a vacuum without a vent

• continue

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• 2) Boilers & Controls• g) A gauge glass should be provided

with each steam boiler so that the technician can see the boiler water level at a glance

• a) This glass has valves so that it can be isolated for servicing & in case of breakage

• b) The gauge glass can be protected by steel rods on the sides of the glass

• continue

• 2) Boilers & Controls• g) A gauge glass should be provided

with each steam boiler so that the technician can see the boiler water level at a glance

• a) This glass has valves so that it can be isolated for servicing & in case of breakage

• b) The gauge glass can be protected by steel rods on the sides of the glass

• continue

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• 2) Boilers & Controls• h) A low water fuel cutoff control is located at the

water level to prevent the boiler from overheating• a) Water level is critical in a steam boiler because

the heat exchanger surface is just below the operating water level

• b) The low water cutoff is a limit switch which turns off the burner

• c) The low water cutoff may contain a water makeup switch that operates a solenoid to add water when the float drops

• d) The low water cutoff is at the water level of the boiler where light floating debris collects, this control should be blown down daily to remove any foreign particles

• 2) Boilers & Controls• h) A low water fuel cutoff control is located at the

water level to prevent the boiler from overheating• a) Water level is critical in a steam boiler because

the heat exchanger surface is just below the operating water level

• b) The low water cutoff is a limit switch which turns off the burner

• c) The low water cutoff may contain a water makeup switch that operates a solenoid to add water when the float drops

• d) The low water cutoff is at the water level of the boiler where light floating debris collects, this control should be blown down daily to remove any foreign particles

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• 3) Heating Units & Traps• a) Steam terminal units receive steam

vapor & condense it while adding heat to the conditioned space

• 1) A terminal unit can exchange heat to a hot water circuit, a steam radiator, or a forced air coil

• a) A hot water circuit can be heated with steam by the use of heat exchangers

• b) The heat exchanger will have pipes which carry steam through a tank of water

• continue

• 3) Heating Units & Traps• a) Steam terminal units receive steam

vapor & condense it while adding heat to the conditioned space

• 1) A terminal unit can exchange heat to a hot water circuit, a steam radiator, or a forced air coil

• a) A hot water circuit can be heated with steam by the use of heat exchangers

• b) The heat exchanger will have pipes which carry steam through a tank of water

• continue

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• 3) Heating Units & Traps• b) Terminal units are rated in square

feet of steam • 1) One square foot of steam equals

240 btu of heat per hour• continue

• 3) Heating Units & Traps• b) Terminal units are rated in square

feet of steam • 1) One square foot of steam equals

240 btu of heat per hour• continue

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• 3) Heating Units & Traps• c) There are several types of steam system

condensate return methods• 1) All methods return condensate to the boiler• 2) Many systems have a steam trap at the heat

exchanger outlet that creates a liquid seal between the vapor & the liquid parts of the system

• a) If raw steam is allowed to enter the liquid portion of the system, there will be no pressure difference to encourage steam to flow

• condensate

• 3) Heating Units & Traps• c) There are several types of steam system

condensate return methods• 1) All methods return condensate to the boiler• 2) Many systems have a steam trap at the heat

exchanger outlet that creates a liquid seal between the vapor & the liquid parts of the system

• a) If raw steam is allowed to enter the liquid portion of the system, there will be no pressure difference to encourage steam to flow

• condensate

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• 3) Heating Units & Traps• d) Three types of common steam

traps • 1) Mechanical • 2) Thermostatic• 3) Kinetic• continue

• 3) Heating Units & Traps• d) Three types of common steam

traps • 1) Mechanical • 2) Thermostatic• 3) Kinetic• continue

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• 3) Heating Units & Traps• e) The mechanical trap is either a

float or an inverted bucket• 1) The mechanical trap can have

an additional thermostatic feature that vents trapped air to the atmosphere

• continue

• 3) Heating Units & Traps• e) The mechanical trap is either a

float or an inverted bucket• 1) The mechanical trap can have

an additional thermostatic feature that vents trapped air to the atmosphere

• continue

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• 3) Heating Units & Traps• f) The thermostatic trap is farther

downstream from the terminal unit to allow the condensate to cool and thus attain a lower temperature difference than the saturated steam

• 1) When the thermostatic element senses condensate, it opens and allows the sub-cooled liquid to move into the condensate main until the element senses hot steam, then the trap closes

• continue

• 3) Heating Units & Traps• f) The thermostatic trap is farther

downstream from the terminal unit to allow the condensate to cool and thus attain a lower temperature difference than the saturated steam

• 1) When the thermostatic element senses condensate, it opens and allows the sub-cooled liquid to move into the condensate main until the element senses hot steam, then the trap closes

• continue

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• 3) Heating Units & Traps• g) The kinetic trap has a moveable

disc that allows air & condensate to pass, but not steam. It operates according to the difference between the energy of the moving steam & the energy of the moving air & liquid

• 3) Heating Units & Traps• g) The kinetic trap has a moveable

disc that allows air & condensate to pass, but not steam. It operates according to the difference between the energy of the moving steam & the energy of the moving air & liquid

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• 3) Heating Units & Traps• h) Each trap must be able to move

more condensate during a cold start up than during normal operation because a large volume of condensate develops in the cold pipes & coils when steam is first turned into the system

• i) Each trap has a very small bore through which the condensate passes

• 1) This bore must be protected with a strainer to prevent pipe scale & other foreign objects from blocking it

• 3) Heating Units & Traps• h) Each trap must be able to move

more condensate during a cold start up than during normal operation because a large volume of condensate develops in the cold pipes & coils when steam is first turned into the system

• i) Each trap has a very small bore through which the condensate passes

• 1) This bore must be protected with a strainer to prevent pipe scale & other foreign objects from blocking it

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• 4) Residential Type• a) Low Pressure Gravity• 1) All of the condensate returns to

the boiler by its own weight

• 4) Residential Type• a) Low Pressure Gravity• 1) All of the condensate returns to

the boiler by its own weight

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• 5) Low Pressure Steam Boiler• a) Operates below 15 psi, usually

between 0.5 psi to 5 psi• b) Low pressure boilers are used in

residential heating applications because

• 1) Safer than high pressure systems

• 2) Economical • 3) Less Service

• 5) Low Pressure Steam Boiler• a) Operates below 15 psi, usually

between 0.5 psi to 5 psi• b) Low pressure boilers are used in

residential heating applications because

• 1) Safer than high pressure systems

• 2) Economical • 3) Less Service

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• 6) Steam Main• a) From the Boiler• 1) Minimum size 1.5 inches• 2) Maximum run 25 feet• b) Horizontal Runs• 1) ½ inch to 1 inch pitch towards

the boiler return 10 feet run • c) Cast iron fittings are used

• 6) Steam Main• a) From the Boiler• 1) Minimum size 1.5 inches• 2) Maximum run 25 feet• b) Horizontal Runs• 1) ½ inch to 1 inch pitch towards

the boiler return 10 feet run • c) Cast iron fittings are used

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• 7) Branches • a) From the top of the main at a 45

degree angle • 1) Never from side to side

because this could create water hammer

• b) Cast iron fittings are used• c) Full size pipe the main and then

the branch is reduced• d) The pitch is 1 inch per 5 feet of

pipe

• 7) Branches • a) From the top of the main at a 45

degree angle • 1) Never from side to side

because this could create water hammer

• b) Cast iron fittings are used• c) Full size pipe the main and then

the branch is reduced• d) The pitch is 1 inch per 5 feet of

pipe

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• 8) Risers• a) Risers are run vertically• 1) From the branch or the main to

the radiator• b) The size of the risers should be no

less than 1 inch• 1) If the riser is to small it will cause• a) Water in the radiator• b) Increased friction • c) Less circulation

• 8) Risers• a) Risers are run vertically• 1) From the branch or the main to

the radiator• b) The size of the risers should be no

less than 1 inch• 1) If the riser is to small it will cause• a) Water in the radiator• b) Increased friction • c) Less circulation

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• 9) Return• a) Carries condensate to the boiler• b) If the return is horizontal the pitch

must be towards the boiler• c) Wet return • 1) Water in the pipe is higher than

the boiler water level• d) Dry return• 1) Water in the pipe is the same

height as the boiler water level

• 9) Return• a) Carries condensate to the boiler• b) If the return is horizontal the pitch

must be towards the boiler• c) Wet return • 1) Water in the pipe is higher than

the boiler water level• d) Dry return• 1) Water in the pipe is the same

height as the boiler water level

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• 10) Hartford Loop• a) Runs from the T on the boiler

main to boiler return• b) Return line• 1) Ties in at the nipple 2 inches

below the normal water line• c) Keeps water level safe• d) Gives longer life to the boiler

• 10) Hartford Loop• a) Runs from the T on the boiler

main to boiler return• b) Return line• 1) Ties in at the nipple 2 inches

below the normal water line• c) Keeps water level safe• d) Gives longer life to the boiler

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• 11) Steam Piping• a) One Pipe• 1) Main & return piping are in the

same line• a) Riser comes off the main• b) Condensate returns through the

main• 2) Size • a) Main piping is larger• b) Only one valve is used on the

radiator• 3) Radiators• a) The flow end of the radiator is

slightly lower

• 11) Steam Piping• a) One Pipe• 1) Main & return piping are in the

same line• a) Riser comes off the main• b) Condensate returns through the

main• 2) Size • a) Main piping is larger• b) Only one valve is used on the

radiator• 3) Radiators• a) The flow end of the radiator is

slightly lower

Documents

1 STEAM HEATING. 2 ) What is Steam Heating a) Steam heat is similar to hot water heat except the latent heat of the steam vapor contains a larger amount