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CAMTECH/99/S/DAIDO/1.0 1
S/ Line Tokenless B/Instrument December’ 1999
SINGLE LINE, HANDLE TYPE TOKEN LESS BLOCK INSTRUMENT
(FM CODED)
1. INTRODUCTION
This Hand book covers the general requirements of, Single line, Handle type Token lessBlock Instrument for use in RE & Non-RE sections.
A pair of Block Instruments is connected electrically through overhead or cable tocontrol the movement of trains on single line Block Section in either direction.
The Instrument is designed to work on Frequency Modulation (Carrier frequency 1800Hz or 2700 Hz and modulating frequency 65 Hz and 85 Hz).
1.1 Advantages over Token Block Instrument :
1. Less operating time. 2. No Token exchange.3. Less physical strain.4. Problems like token missing, token balancing, census of token, recoupment of lost
token or damaged token etc. are not encountered.5. Avoidable detention is minimized.6. Increase section capacity7. Maintaining normal polarity/Reverse Polarity of Block instrument is not required.
CAMTECH/99/S/DAIDO/1.0 2
S/ Line Tokenless B/Instrument December’ 1999
2. SYSTEM COMPOSITION
The Block instrument is compact & robust in construction and fit to stand for roughhandling. It is easy to maintain. Removal/ replacement of any part or sub-assemblydoes not disturb the adjoining parts/ sub-assemblies. The following components are provided within the Block Instrument:
TCF
LINEPB2 PB1
Train OnLineIndicator
COUNTER
TimeRelease
Bell
NS1 S2
TGT
BlockHandle
GalvoBlockphone
21
SM SH
CAMTECH/99/S/DAIDO/1.0 3
S/ Line Tokenless B/Instrument December’ 1999
2.1 Block Handle :
A mechanically operated rotary type handle, called Block Handle is located in the fronton the lower part of the Block instrument. Different contact positions of the handle areshown in figure given below:
FORCE DROP LOCKING ARRANGEMENT(DEVELOPED VIEW)
YIXI
YX N
BA
VARIOUS POSITION OF BLOCK HANDLE
FORCED DROPPROJECTION
FORCED DROPPROJECTION
LOCKPAWL
L A B X X 1 N Y Y1 D R
L R
D
CAMTECH/99/S/DAIDO/1.0 4
S/ Line Tokenless B/Instrument December’ 1999
2.1.1 The handle is free to be turned between X and Y, R and D and also between L and B.Movement of the handle to Train Coming From, Train Going To and back to Normalposition from Train Coming From and Train Going To is controlled by an electric lockand this lock is required to be energized at Y position for turning handle to TrainComing From and at D or B position for turning from Train Coming From or TrainGoing To to Normal. For turning to Train Going To, the lock is initially energised at Xposition but gets forced dropped before X and is actuated at X position for furthermovement to Train Going To. The locking effective at X is termed as check lockingand is provided to ensure the conscious cooperation of the operator at the other end.This locking is however not effective while turning the handle from Train Going Tonormal even though the lock is forced dropped. It is because of the beveled edge of theconcerned notch on which the lock just slides over and does not cause an obstruction tothe movement of the handle.
The block handle assembly consists of 24 sets of spring contacts (circuit controller),actuated during the course of handle of operation.
2.1.2 Need for Forced Drop Arrangement
When the lock gets energised then the handle is free to move from Normal to TrainComing From/Train Going To position depending upon the code that is received. Dueto residual magnetism there is a possibility of lock armature to stick up, then theoperator can normalise the block handle from Train Coming From/Train Going To. Toavoid such type of irregular movement there is a need to lock the handle in respectiveposition. The projection on the locking bracket ensure the forced drop of the lock coilso that the operator can not normalise the block handle, once it is turned to TrainComing From/Train Going To, with out cooperation of other operator.
2.2 Galvo
Indicates incoming and outgoing DC current. The resistance of the coil is 18.2 ohms,working current is 110 mA and working voltage is 2 volt.
2.3 Time release Indication
It is an electromagnetic indicator to indicate the maturity of Time Element Relay duringcancellation of a line clear. The coil resistance is 200 ohms.
Normally it shows white indication with words LOCKED and when operated it showsgreen indication with words FREE.
2.4 TOL Indicator
It is an electromagnetic indicator(magnetic latch type). It operates on entry of train in toblock section at either of station.
When the Block section is clear, it displays white indication and when the train entersinto the Block Section on a line clear it changes to Red indication with writing “TrainOn Line” and it holds magnetically. The indicator again changes to white when blockhandle is turned from any position to line closed.
2.5 Switch S1 with counter
CAMTECH/99/S/DAIDO/1.0 5
S/ Line Tokenless B/Instrument December’ 1999
Switch Sl is a two position switch. when operated to reverse it initiates thecancellation of line clear. The counter is used to register cancellation operation.
2.6 Switch S2 with counter
Switch S2 is a two position switch. when operated to reverse it is used for normalisingthe instrument during a push-back operation of a train to the starting station.
Push Back operation is performed immediately after reversing S2. The counter is usedto register Push Back operation.
2.7. Push Button PB1
It transmits DC current for exchanging bell codes.
When PB1 is pressed alone it transmit
1. DC (-ve) on Line 1 for Bell.2. DC (+ve) on L1 for TOL acknowledgment.3. The same button, when pressed along with PB2, is used for sending of operational
code.
2.8 Push Button PB2
It is used in conjection with PB1 to transmit operational codes to permit the operationof block handle at other station. The code sent is frequency modulated code along witha DC (+ve) code.
PB2 is pressed always along with PB1 to pickup PBPR, which in turn sends ;
i) Frequency modulated code by switching on the Transmitter.ii) DC (+ve) on L1.
2.9 Single Stroke Bell
It is mounted on the top of the instrument and is used for exchanging bell code signalsi.e. It provides to receive bell code. The bell coil is wound to a resistance of 310 ohmsand requires about 70 mA for operation.
It sounds when BLR or NR picks up and used for exchanging Bell Code.
2.10 Buzzer
Two electronic buzzers (BZ1 & BZ2) are provided in side the Block instrument.
BZ1 - It is a dual tone buzzer & sounds at both stations when the train enters into theblock section and stops after acknowledgment by the pressing PB1 at the trainreceiving station.
BZ2 - It Sounds at the Receiving station on train arrival on proper reception signals andsequence. It stops by normalizing the Home Signal SM’s slide/lever.
CAMTECH/99/S/DAIDO/1.0 6
S/ Line Tokenless B/Instrument December’ 1999
2.11 SM’s Key
To avoid unauthorised operation in the absence of SM.
When this key is taken out the block instrument becomes inoperative for all functionsexcept for:
i) Reception of Bell Code.ii) Reception or transmission of TOL Code.
2.12 Shunting Key
This key is used as a shunting authority to shunt in any direction beyond Last stopsignal up to first stop signal of the station. It is normally kept inserted in the Blockinstrument. It can be taken out only when the block handle is in Line Closed or TrainGoing To position, and when taken out, the Block handle is locked mechanically in lastposition. The insertion and extraction of key can be done only when SM’s key isinserted and turned ON.
2.13 Transmitter
It transmits a frequency modulated output (1800 or 2700 with 65 or 85 Hz) when theDC feed is connected to it by different selections. The modulated frequency is selectedby the transmitter by an external loop completed through the relevant selectionaccording to the condition of the block instrument.
2.14 Receiver This receives the frequency modulated signals transmitted from the other end and gives DC
output for energising either CR1 or CR2 depending on the modulating frequency of thecode received. The receiver is switched on when the DC feed is connected through therelevant selections.
2.15 The block instruments are designed to work either on 1800 Hz or 2700 Hz carrier
frequencies. The modulating frequencies are 85 Hz and 65 Hz and these are commonfor all the instruments.
The codes used in the Block Instrument are 2.15.1 1800 Hz or 2700 Hz modulated by 85 Hz with DC positive : To permit operation of
block handle from line closed to Train Coming From, Train Coming From to lineclosed and Train Going To to line closed.
2.15.2 1800 Hz or 2700 Hz modulated by 65 Hz with DC positive : To permit operation of
block handle from line closed to Train Going To.
2.15.3 1800 Hz or 2700 Hz modulated by 65 Hz : To set the other end’s Block instrument to“Train On Line”.
CAMTECH/99/S/DAIDO/1.0 7
S/ Line Tokenless B/Instrument December’ 1999
2.15.4 DC negative : For exchanging bell code signals.
NOTE :
• DC positive refers to line battery positive connected to line 1 and negative to line 2.
• DC negative refers to line battery negative connected to line 1 and positive to line 2.
3. RELAYS NOMENCLATURES
3.1 BLR
It is a biased Relay and picks up when (+ve) on L2 and (-ve) on L1 is received from theline and the single stroke Bell sounds through the pickup contacts of BLR.
3.2 NR
It is also a biased Relay and pickup when (+ve) on L1 and (-ve) on L2 is received fromthe line, Single stroke Bell sounds and lock magnet energised through its pickupcontact.
3.3 PBPR
Picks up when PB1 & PB2 are pressed simultaneously or only PB1 with TOLR pickupcondition during TOL code transmission. It connects DC (+ve) on L1 and (-ve) on L2and transmitter to the local Battery.
3.4 CR1 : Coding Relay
3.5 CR2 : Coding Relay
3.6 TRSR : Train sending Relay
3.7 1R
It proves the normal condition of reception signal’s and Last stop signal’s levers andSM’s slide.
3.8 1TPR
This is a repeater of FVT Track Relay (ASTR).
CAMTECH/99/S/DAIDO/1.0 8
S/ Line Tokenless B/Instrument December’ 1999
3.9 TOLR : Train on line relay
3.10 2R
Picks up after the complete arrival of the train with proper sequence.
3.11 3R : Cancellation Relay
When S1 is turned for normal cancellation, after a specified time (120 sec.) delay itpicks up and the ‘FREE’ indicator energised through its pick up.
3.12 TEPR
Once S1 is turned for normal cancellation the electronic timer relay gives output of 24v after a specified time delay (120 sec.) which in turns picks up the TEPR.
3.13 Timer Relay
It is an electronic Type Relay used for pickup of TEPR relay after 120 sec. time delayin case of normal cancellation.
3.14 TELR
Telephone Relay of resistance 70 ohms, picks up when switch of hand micro telephoneis pressed and in turns it connects the telephone on line and also disconnect the TX &RX from the frequency line.
3.15 External Relays :
3.15.1 ASR : Advance Starter Relay
3.15.2 HSR : Home Signal Control relay. 3.15.3 TAR : Train Arrival Relay
3.15.4 SNR : Signal Normal Relay
4. POWER SUPPLY
Three sets of batteries are required :
4.1. Line Battery
Line battery is normally of dry cells. The voltage is varying from 24 V depending onthe length of the block section in order to get a working current of 100 mA on line. Thisbattery is connected on line whenever the DC is required to be sent either foeexchanging the bell signals or as a part of the operational code.
CAMTECH/99/S/DAIDO/1.0 9
S/ Line Tokenless B/Instrument December’ 1999
4.2. Local Battery
Local battery is of 24 Volt and is used for giving the supply to the transmitter andreceiver and also operating relays, indicators, local magnets etc. of the instruments.Since the current drain on the battery is high, secondary cells are generally used.
4.3 Location/External Battery
It is used for external circuits to repeat the external conditions to the instrumentsaccording to the requirements of the circuits. Picking up of PBPR, connects +ve to L1& -ve to L2 and also switches on the DC feed for the transmitter. Since the blockhandle is in normal position, the loop circuit is connected for the modulated output isconnected to the line.
5. SPECIAL FEATURES
5.1 Special features of Daido Tokenless Block Instrument are given below:
5.1.1 To ensure that the relays “NR” and “BLR” are not picked up simultaneously backcontact of NR relay is proved in BLR circuit. Similarly in the PBPR circuit backcontact of CR1 and CR2 relays have been provided to ensure that PBPR relay will notbe energized. While receiving modulated frequencies.
5.1.2 Front contact of PBPR Relay has been proved in the DC feed circuit of transmitter,whereas back contact has been proved to the receiver circuit to guard against receivingits own F.M. output modulated frequency transmitted similarly, back contact of CR2and CR2 relays have been proved in the DC feed circuit for transmitted to ensure thatno code except the code of bell signals can be generated unless the code relays are de-energised.
5.1.3 Since TOL code has to be transmitted automatically as soon as a train occupies FVT,Front contact of PBPR Relay is not proved in DC feed circuit to the transmitter but thesame is taken in TOLR Front contact NR Relay back contact with the block handle at Lposition.
5.1.4 Similarly for the receiver to be in readiness. To receive the TOL code, the DC feedcircuit is taken via 2R Relay back contact with the block handle “R” position.
5.1.5 Pressed contact of the PB2 button in the DC feed circuit of the transmitter, proves thepositive action taken to energise PBPR Relay for transmitting modulated frequencyalong with DC.
5.1.6 Block handle contacts (BX) and (DY) are included in the DC feed circuit to thereceiver so that the DC feed to the receiver is switched on only. When the Block handleoperation is initiated. Thus minimising battery consumption.
5.1.7 SM’s key contact has not been provided in the DC feed circuit of Transmitter fortransmitting and receiving of automatic TOL code to ensure that the TOL indicator willdisplay, immediately the block sections occupied irrespective of the position of theSM’s key.
CAMTECH/99/S/DAIDO/1.0 10
S/ Line Tokenless B/Instrument December’ 1999
5.1.8 To ensure that the relay CR1 and CR2 are not be energised one at a time, back contactof CR1 relay is proved to energise CR2 relay and similarly back contact of CR2 relay isproved to energise CR1 relay.
5.1.9 Cross protection to the lock Magnet is given through the CR1 and CR2 back contacts.
5.1.10 “Transmitter” and “Receiver” are connected to line through the back contact of TELRrelay is ensure that during conversation on telephone, no code is transmitted or receivedby the transmitter and receiver respectively at either end. Similarly the telephone set isconnected to the lines through the front contact of TELR Relay and TELR Relay feed istaken through the back contact of CR1 and CR2 relays to ensure that duringTransmission and reception of Code the telephone is disconnected the back contact ofTOLR is included in the TELR PICK UP circuit to ensure that the telephone circuit isdisconnected the moment TOLR picks up to transmit TOL Code.
5.1.11 TOLR relay is made slow to release since its energising circuit is through the frontcontact of TRSR released stick circuit as through the back contact of TRSR relay.
5.2 POSITION OF RELAYS IN RELAY RACK
T E P R C R 1 C R 2P B P R B L R N RT O L R T R S R I T P RI R 2 R 3 R
5.3 DIFFERENT COLOUR CODE FOR INTERNAL WIRING
COLOUR DESCRIPTION
RED - Local Source (+)BLUE - Local Source (-)BLACK - Block Line CircuitBROWN - Relays circuit for Reverser ControlYELLOW - Transmitter and Receiver circuitGREEN - Relays and Lock magnet circuitWHITE - Other circuit
6. CIRCUIT DESCRIPTIONS
6.1 NORMAL POSITION :
Normally, the Block handle is in center upright position, i.e. ‘Line Closed’ position.The SM Key is IN, shunting (SH) key is IN, cancellation switch (S1) and push backswitch (S2) are in normal position. The TOL and time release indicator are white andthe Galvo indicator indicates zero current position. In this case, all the relays exceptfor ITPR and 1R are dropping away, with no current flowing in the block line and theconcerned signals and levers are in normal position (Fig. 1).
CAMTECH/99/S/DAIDO/1.0 11
S/ Line Tokenless B/Instrument December’ 1999
10TPPR 5 15 1+ 2- 55 45 10TPPR
6.2 When a train is leaving A Station to B Station.
6.2.1 Turning the SM key to ON position at Station A completes a circuit. Push ButtonPB1 is pressed to give CALL ATTENTION Bell code signal to B station. A DC (-ve) current flows to B station in Line 1, to pick up the BLR at B station as per fig. 2and fig. 3.
1RN1 24V
B1 24V
N N N
FIGURE 1
1 2N1 24V
B1 24 V
1TPR
2 1
BTPR 10NBPR 3 4 10 10LCC 1+ 2- 56 46
6 16
1 2
35 25
36 26
2 12 67 68 CHI SM PPB1 NR PBPR
N2 3 13 1 R2 2 PB1 PB2L1 (-)
L2 (+)
OUTGOINGCIRCUIT AT
20 OHM/2W 2
4 UF/160V
FIGURE 2
B2
2 3•
6A 5A 6D 2/5D
3
BLR
4 UF/160V
1 2 35 25
36 26PBPR PB2 PB1 2- 1+ D2 26 PB1 NRPBPR
L2
L1
INCOMMINGCIRCUIT AT B
BH-1264/7B 8B 3 2 6A 5A 6D 2/5D
FIGURE 3
3
CAMTECH/99/S/DAIDO/1.0 12
S/ Line Tokenless B/Instrument December’ 1999
Now with the BLR picking up, a current flows to ring the BELL as per fig. 4.
6.2.2 Upon receipt of a call attention at B station, SM inserts & turns SM key to IN. SMpresses to acknowledge call attention signal from Stn. A. The circuit is same asdescribed in Fig. 4 above.
6.2.3 Verbal communication for grant of Line Clear takes place between SM of Stn. A andStn. B over block telephone.
6.2.4 Push Button PB1 and PB2 are pressed simultaneously at Stn. A to send the IS LINECLEAR code. PBPR relay picks up as per fig. 5.
6.2.5 With the PBPR picking up at A the NR picks up at B station through the line circuit asper fig. 6 & 8.
PBPR
21
B24V 61 62 SM CR1 PB1 PB2 CR2 1R NR N24V
7D 8D 2B 1B 8B 4/7B
OUTGOINGCIRCUIT AT‘A’ 36 26
B2 2 12 67 68 CH1 PBPR 35 25
N2 3 13 1 R2 2 PPBPR
20 OHM/2W 1D 2/5DL2
L1
FIGURE 6
FIGURE 5
61 62 48 58
2A 1A 1 2
N24V
B24V
LOCAL CIRCUIT AT B
BELL
FIGURE 4
BLR
21
31
LOCALCIRCUITAT ‘A’
CAMTECH/99/S/DAIDO/1.0 13
S/ Line Tokenless B/Instrument December’ 1999
6.2.6 An FM code is generated due to picking up of PBPR at ‘A’, which connects power toTX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer ( in this case the input circuit to RX of same station is isolatedby PBPR back contacts.
B 24 V 61 62 48 SM 1R PBPR PB2 TOLRCR1
4A 3A 4/7 D 3D 6A 2/5A 5D 6D 5D6D
TO ISOLATIONTRANSFORMERLINE SIDE
3 4
5
6 1 27
158
N
131
21TX
34
37
FIGURE 7
N24
R3 / 470 ohm 2 watt
-2 +1 D1 18 8 PBPR 3525
PBPR 36 26
8B 4/7 BNR
XYLBRD
BY-126
6D 2/5 D
FIGURE 8
L1
L2
CAMTECH/99/S/DAIDO/1.0 14
S/ Line Tokenless B/Instrument December’ 1999
6.2.7 CR1 picks up at Stn. B on receipt of modulated current as per fig. 9.
6.2.8 On getting the Bell & Galvo deflection at Stn. B, SM turns the block handle as far asY point, Lock magnet picks up to releases the Block Handle, which can be turned toright position (Train Coming From position), as per fig. 11.
B24 V 61 62 48 SM 1R PBPR TOLR 4142
4A 3A 4/7 D 8D 5D 6D
TO ISOLATETRANSFORMER(LINE SIDE)
3 4
7
1 25
15831
21TX
PBPR CR2
TELR
BXDY
7A 8A
5B 6B
CR1
CR2 1+
FIGURE 9
61 62 48 58 NR
4A 3A 1 2
N24VB 24V
LOCAL CIRCUITAT ‘B’
31
21BELL
FIGURE 10
N24
CAMTECH/99/S/DAIDO/1.0 15
S/ Line Tokenless B/Instrument December’ 1999
•
6.2.9 While the block handle is being turned from one to another position, the circuitcontroller contact (XY-RD-LB) of the handle in line circuit, in series with the relayNR is opened between the Y&D points.
6.2.10 On opening of circuit controller contact in Line circuit, a resistance R3 to be added inseries to line circuit with a resultant reduction in the volume of line current ( whichremains substantially greater than the drop away current of NR). This cause a click onGalvo needle at both stations, making it possible for SM of button pressing station toknow that the block handle has been turned. Then PB1 and PB2 at station A may bereleased (The same procedure is followed in operating the handle as subsequently tobe described).
6.2.11 After confirming that the Galvo needle has returned to zero position (indicating that Astation has stopped sending a code of signal), PB1 and PB2 are now simultaneouslypressed down at B station to send a code of signal to A station (Fig. II). PBPR relaypicks up as per fig. 5. With the PBPR picking up at A the NR picks up at B stationthrough the line circuit as per fig. 6 & 8.
6.2.12 An FM code is generated due to picking up of PBPR at ‘A’, which connects power toTX as per circuit in Fig. 7. The modulating frequency F2(65 Hz) is selected overterminal TX-5 & TX-7 & modulated current flows to terminals 34, 37 to the line sideisolation transformer
XYLBRD 6D 2/5 D
R3 (470 Ohm)
PBPR
2/5A 6A
31
N 24V
R1
BXDY
48
58
61 62S1 N1 S2 N1 TEPR TRSRT
21
CR1
B 24V SM
5D 6D 4/7B 8B 1A 8/5AR2
M4/7B 3B
NR 2 1
FIGURE 11
CAMTECH/99/S/DAIDO/1.0 16
S/ Line Tokenless B/Instrument December’ 1999
Local and outgoing circuit at ‘A’ (Fig. 12,13 & 14) local and incoming circuit at ‘B’(Fig. 15 to 16).
LOCAL AND OUTGOING CIRCUITS AT B
B24V 61 62 SM K CR1 PB1 PB2 CR2 1R NR
PBPR
21
7D 8D 2B1B
8B 4/7B
FIGURE 12
N24 V
CAMTECH/99/S/DAIDO/1.0 17
S/ Line Tokenless B/Instrument December’ 1999
B2 2 12 67 68 CH1 PBPR 35 25
3B 4/7B
20 OHM/2W 1D 2/5D
36 26N2 3 13 R2 PPBPR
L2 -
L1 +
FIGURE 13
4A 3A 4/7 D 3D 6A 2/5A 5D 6D 5D6D
TO LINE SIDE TRANS
3 4
5
6 1 27
158
R
1 31
21TX
34
37 5 6 2R
B24 V 61 62 48 SM k 1R PBPR PB2 TOLR CR1CR2
TELR
2/5D 6D
4 1
FIGURE 14
N24
CAMTECH/99/S/DAIDO/1.0 18
S/ Line Tokenless B/Instrument December’ 1999
R3
18 8 1 35 25L1
PBPR 36 26 L2
8B 4/7 BNR
XYLBRD
BY-126
6D 2/5 D
470 OHM/2W
‘X’
FIGURE 16
31
61 62 48 58 NR
4A 3A
N24VB 24V21
BELL
FIGURE 17
37
B 24 V 61 62 48 SM k 1R PBPR TOLR 41 42
4A 3A 4/7 D 8D 5D 6D
TO LINE SIDE I.TRANS
3 4
78
5 26
58
PBPR CR
TELR
BXDY
7A 8A
5B 6B
CR2
CR2 1+ 2-4 1
34
7B 8B
LOCAL AND INCOMING CIRCUITS AT `A’
N24
FIGURE 15
RX
21
31
31
61 62 48 58 NR
4A 3A
N24VB 24V21
BELL
FIGURE 17
CAMTECH/99/S/DAIDO/1.0 19
S/ Line Tokenless B/Instrument December’ 1999
6.2.13 On getting the Bell & Galvo deflection at Stn. B, SM turns the block handle from Npoint to as far as the X point. At X point TRSR picks up & releases the lock on blockhandle by picking up lock magnet as per fig. 17 & 18. TRSR remains UP till X/ andlater on sticks through its own front contact in LX/ position of Block handle. Thelock magnet is once again required to be in picked up condition to release the blockhandle at check lock position at X/as per fig. 18 &19.
6.2.14 When Block handle is in Train Going To position, i.e., Line clear is granted, Last stopsignal can be taken OFF by reversing the necessary controls like SM control onsignal, Lever/ switch/ push button operation etc. Reversing of any of above controlcauses 1R to drop. An external relay ASR (Advance starter control relay) picks up asper fig. 20. With ASR picking up, it possible to take OFF the Last Stop signal.
6.2.15 Now the train can be sent into block section. On entry of train into block section, FVTtrack relay drops causing 1TPR to drop, thus releasing the stick circuit of TRSR todrop. Dropping of the TRSR causes the ASR to drop and replace the Last Stop signalto ON automatically.
6.2.16 With the 1TPR drop, the circuit of TRSR breaks , which drops with a time lag, butbefore its dropping, TOLR picks up as per fig. 21 through Path 1.
B24
31
21
TRSR ITPR 37 38
R1 C1 1000 UF/60V
61 62 48 58 3R CR2 NR ITPR 3940
N24
2/5 D 1D 2/5A2A
TRSR
1+
7B 8B
FIGURE 18
LX/
XX/
B3 24V 65 66 1R 2R TRSR S1 17 18 53 43 HSR
8B 4/7 B N312V
7D 6D ASR
R3FIGURE 20
N3
48
58
S1 S2 TRSR 2R 3R CR1 9 10 1 2NR
B 24V SM 1R
N 5D 6D 4/7B 5B 6B 7A 8A 1A 2/5A
21
31
3B 4BXX
M
CR2
6A 2/5A
N24
2A 1A
FIGURE 19
CAMTECH/99/S/DAIDO/1.0 20
S/ Line Tokenless B/Instrument December’ 1999
When TRSR drops after the time lag, TOLR sticks through Path 2. the indicatorTOLK and buzzer BZ1 are actuated through a branch of a contact LB, indicating atrain departure (TOL). An additional Path 3 is provided to prevent the premature dropping of TOLR duringtransition, when other station is transmitting TGT code & at the same time TOLRpicks up. It ensures that TOLR will not drop before transmission of TOL code.A Normal contact of S2 switch is provided in the stick circuit to stop the transmissionof TOL code, during a failure of its transmission or acknowledgment to silence thedeparture buzzer.
6.2.17 At this time the advance starter lever is restored to normal position.
B24 61 62
31
21 TRSR ITPR 13 14
CR2 NR 23 24
N24
XX’YY’
LB
2/5 D 6D 7D 8D
TOLR
1+
7B 8B
D3 BY-126LB
BZ1
2B 1B 2/5B 1B
N3R3
TOLR S2
3R48
58
TRSR NR
4B 3B
5
FIGURE 21
Path1
Path2
Path3
TOLK
CAMTECH/99/S/DAIDO/1.0 21
S/ Line Tokenless B/Instrument December’ 1999
6.2.18 An FM code is generated due to picking up of TOLR at ‘A’, which connects power toTX as per circuit in Fig. 22. The modulating frequency F2(65 Hz) is selected overterminal TX-5 & TX-7 & modulated current flows to terminals 34, 37 to the line sideisolation transformer ( in this case the input circuit to RX of same station is isolatedby TOLR back contacts.
6.2.19 CR2 picks up at Stn. B on receipt of modulated code F2. The power to RX isconnected through B24-fuse (61-62)- Terminals (48-58)-2R(B)-R. TOLR picks up asper fig. 24. With the TOLK and BZ1 operating through the same circuit as in Astation to give an indication of train departure. Local and incoming circuit at ‘B’ (Fig.23).
2/5D 6D 1A 2/ 5A 5D 6D 5D 6D
LINE SIDE I. TRANS
3 4
5 (c)6 1
27
L43
L
31
21
TX
34
37
6D 5D 3A 4/7
B24 V 61 62 48 SM
TELR 313R TOLR 4 3
44 NR TOLR CR1 CR2
4 1
N24
FIGURE 22
58
CAMTECH/99/S/DAIDO/1.0 22
S/ Line Tokenless B/Instrument December’ 1999
37
B 24 V 61 62 48
TO LINE - SIDE I.TANS
3 47
8
5 26
58
31
21
RX
PBPR CR2
TELR
7A 8A
5B 6B
CR2
CR1
RN24 V
2R 45 46
7A 8A
7B 8B
4 1
34
FIGURE 23
6.2.20 SM of Stn. B, on getting TOL buzzer, presses push button PB1 to acknowledge theTOL code. PBPR at picks up as per fig. 5.
6.2.21 With the PBPR picking up, the NR picks up at Stn. B station through the line circuit asper fig. 6 & 8. Picking up of NR causes TOLR to drop & stop the buzzer. As theTOLK is a magnetic stick type, it maintains its TOL indication. (Refer Path 2 in fig.21)
6.2.22 Dropping of TOLR at Stn. A, stops TOL code transmission by disconnecting powerto TX. As the TOLK is a magnetic stick type, it maintains its TOL indication.
6.2.23 CR2 drops at Stn. B & stops the buzzer .
B24 61 62
61 62 42 SM CR1 PB1 PB2TOLR 19 20
PBPR1 2
1
RD
2A
PBPR
21
7D 8D
B24 61 62
31
21 CR2 NR 11 12
N24
XX’YY’
RD
2/5 D 6D 7D 8D 4B
TOLR
01 UF/100 V
7B 8B
D3 BY-126
BZ1N3R3
TOLR S2
3R
48
58
TRSR NR
2B 1B 2/5B 6B
TOLR
1+ 2-
47 48
1 2
7A 8A 470 OHM/2W
R5
220 OHM/2W
FIGURE 24
CAMTECH/99/S/DAIDO/1.0 23
S/ Line Tokenless B/Instrument December’ 1999
N3 12
7D 6D
HSR
ASR
B3 12V 65 66 1R 2R TRSR S1 N4 35 36 54 44XYRD
LA
2
7D 8D 4/7D 8DR4
FIGURE 26
6.2.24 A bell code for train departure is issued from A station and a answering signal isissued from B station. After departure of train bell code is exchanged.
6.2.25 At Stn. B, Reception signals are taken OFF. As soon as any of the control pertaining
to reception signal is disturbed from its Normal position, 1R drops. Where SM’scontrol is not provided on reception signals, 1R back contact, in HSR and ASRcircuit, is looped in instrument. The HSR picks up (Fig. 26). The home operates in thesame way as advance starter.
6.2.26 On arrival of train at Stn. B, AT & BT tracks operate & sense the direction of travelof train. 2R picks up (Fig. 27) & sticks over LX/-RY. With the relay 2R picking upthe HSR drops away and the home signal is automatically restored to normal position.At the same time a Buzzer BZ2 sounds to announce the train arrival. The buzzer canbe stopped by restoring the SM slide or Home signal controls to their Normal positionas per fig. 27.
CAMTECH/99/S/DAIDO/1.0 24
S/ Line Tokenless B/Instrument December’ 1999
6.2.27 Stn. B verifies the e complete arrival of train & sends Train Out Of Section signal toStn. A. who in turn replies to Stn. B by similar signal. Stn. B presses PB1 and PB2simultaneously to transmit Line closed code (F1). PBPR picks up at ‘B’ station. ( seeFig. 5).
6.2.28 An FM code is generated due to picking up of PBPR at Stn. B, which connects powerto TX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
XX’ Y’
B24 61 62 48 52 7 17 TAR 15 16 21N24
2R
TAR
R
R
4
R
OUTER2
2
BZ2
31
HOME SM 3 4SLIDE
2B 1B
R
FIGURE 27
CAMTECH/99/S/DAIDO/1.0 25
S/ Line Tokenless B/Instrument December’ 1999
6.2.29 With the PBPR picking up at Stn. B the NR picks up at Stn. A through the line circuitas per fig. 6 & 8. CR1 picks up at Stn. A on receipt of modulated current as per fig.9.
2/5D 6D 1A 2/ 5A 5D 6D 5D 6D
TO I. TRANS
3 4
5 (c)
6 2
1
43 31
3A 4A TX
34
37
B 24 42 SM
TELR
2/5D 6D
44 NR TOLR CR1CR2
4 1
N24
R
21
1R
2R
FIGURE 28
TO TRANS
3 4
7 1
28
31
41
RX
7B AB
24 V 61 62 48 SM 1R PBPR
TELR
4
TOLR
BXDY
4A 3A 4 2D 5D 6D 41
CR1
CR2
4258 1
5B 6B
CR2
FIGURE 29
CAMTECH/99/S/DAIDO/1.0 26
S/ Line Tokenless B/Instrument December’ 1999
With the NR and CR1 picking up Lock magnet is energised at B point of block handle as perfig. 30, making it possible to restore the handle to Line Closed position. TOLKrelease coil is energised to restore it Normal as per fig. 31.
6.2.30 SM at Stn. A presses PB1 and PB2 simultaneously to transmit Line closed code (F1).PBPR picks up at Stn. A as per fig. 5.
6.2.31 An FM code is generated due to picking up of PBPR at Stn. A, which connects powerto TX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
6.2.32 With the PBPR picking up at Stn. A, NR picks up at Stn. B through the line circuit asper fig. 6 & 8. CR1 picks up at Stn. B on receipt of modulated current as per fig. 9.
With the NR and CR1 picking up Lock magnet is energised at B point of blockhandle as per fig. 30, making it possible to restore the handle to Line Closed position.TOLK release coil is energised to restore it Normal as per fig. 31.
The same procedure is followed when a train leaves B station from A station.
48
58
S1 N1 S2 N2 TEPR TRSR CR1 7 8 2 NR 21B 24V
N 5D 6D 4/7B 5B 6B 7A 8A 1A 2/5A
21
31
5B 4/7BBDY M
CR1
6A
N24
2A 1A61 62
SM 1R
XX’YY’
TOLK220 OHM/2W
R51 247 48
FIGURE 31
FIGURE 30
CAMTECH/99/S/DAIDO/1.0 27
S/ Line Tokenless B/Instrument December’ 1999
6.3 CANCELLATION OF “LINE CLEAR” BEFORE A TRAIN ENTERS THEBLOCK SECTION :
6.3.1 When a line clear has been taken by Stn. A, i.e., Block Handle in Train Going To, & itbecomes necessary to cancel the Line Clear, the cancellation switch S1 is put to reverseposition at Stn. The following sequence is observed:
• External relay ASR drops• S1 counter increments to next higher number.• All controls are to be replaced to Normal so as to pick up 1R• Timer relay times up as per fig. 32• On expiry of 120 seconds TEPR picks up• TEK appears Green with wording “FREE”• 3R picks up.
An advice for cancellation of Line clear is sent By SM at Stn. A to SM of Stn. B
6.3.2 SM at Stn. A presses PB1 and PB2 simultaneously to transmit Line closed code (F1).PBPR picks up at Stn. A as per fig. 5.
6.3.3 An FM code is generated due to picking up of PBPR at Stn. A, which connects power toTX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
6.3.4 With the PBPR picking up at Stn. A, NR picks up at Stn. B through the line circuit asper fig. 6 & 8. CR1 picks up at Stn. B on receipt of modulated current as per fig. 9.
With the NR and CR1 picking up Lock magnet is energised at D point of block handleas per fig. 30, making it possible to restore the handle to Line Closed position.
6.3.5 Similarly Stn. B takes action to bring the instrument of Stn. A to Line Closed. SM atStn. B presses PB1 and PB2 simultaneously to transmit Line closed code (F1). PBPRpicks up at Stn. B as per fig. 5.
An FM code is generated due to picking up of PBPR at Stn. B, which connects powerto TX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
CAMTECH/99/S/DAIDO/1.0 28
S/ Line Tokenless B/Instrument December’ 1999
4A 4B3R
58
B 24V
TRSR 3R
30
2A 1A61 62
1 2
S1
N24
3R LX
29
48 38
2B 1B
TEPR
1 S1 2
R1
COUNTER2A 1A 7D 8D
COM
TEK
TEPR
TIMER
INPUT OUTPUT
N2SM 1R S1
3R
2A 1A
TER1
FIGURE 32
6.3.6 With the PBPR picking up at Stn. B, NR picks up at Stn. A through the line circuit asper fig. 6 & 8. CR1 picks up at Stn. A on receipt of modulated current as per fig. 9.
With the NR and CR1 picking up Lock magnet is energised at B point of block handleas per fig. 30, making it possible to restore the handle to Line Closed position. WhenStn A turns block handle to Line Closed, TEK changes to White.
6.4 PUSH BACK OPERATION :
When a train sent from Stn. A to Stn. B has entered the Block section, but due tounavoidable circumstances, it has to be pushed back to departure Stn. A, it is calledPUSH BACK OPERATION .
6.4.1 The block handle at Stn. A and Stn. B are in left position (Train Going To) and rightposition (Train Coming From) respectively. TOL indicator indicates that train in toblock section.
4/7A 8A 2/5A 1A TO I. TRANS
FIGURE 33
58
B 24V
61 62
IR PBPR PB2 TOLR CR1
4A 3A 4/7D 3D 1 6A 2/ 5A 5D6D
3 4
5 (c)
6 2
43 SM
31
TX
34
37
TELR
4 1
N24
L
21
TOLR 3R
CAMTECH/99/S/DAIDO/1.0 29
S/ Line Tokenless B/Instrument December’ 1999
6.4.2 SM at Stn. A push back switch S2 to reverse position, actuates the counter S2 as per fig.34. Reception signals are taken OFF. As soon as any of the control pertaining to receptionsignal is disturbed from its Normal position, 1R drops. HSR picks up as per fig. 26.
6.4.3 On arrival of train at Stn. B, AT & BT tracks operate & sense the direction of travel oftrain. 2R picks up (Fig. 27) & sticks over LX/-RY. With the relay 2R picking up theHSR drops away and the home signal is automatically restored to normal position. Atthe same time a Buzzer BZ2 sounds to announce the train arrival. The buzzer can bestopped by restoring the SM slide or Home signal controls to their Normal position asper fig. 27.
6.4.4 Stn. A verifies the complete arrival of train. An advice for push back operation is sentBy SM at Stn. A to SM of Stn. B
6.4.5 SM at Stn. A presses PB1 and PB2 simultaneously to transmit Line closed code (F1).PBPR picks up at Stn. A as per fig. 5.
6.4.6 An FM code is generated due to picking up of PBPR at Stn. A, which connects powerto TX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
6.4.7 With the PBPR picking up at Stn. A, NR picks up at Stn. B through the line circuit asper fig. 6 & 8. CR1 picks up at Stn. B on receipt of modulated current as per fig. 9.
With the NR and CR1 picking up Lock magnet is energised at D point of block handleas per fig. 30, making it possible to restore the handle to Line Closed position. TOLindicator changes to White during turning of handle from Train Coming From to LineClosed.
6.4.8 Similarly Stn. B takes action to bring the instrument of Stn. A to Line Closed. SM atStn. B presses PB1 and PB2 simultaneously to transmit Line closed code (F1). PBPRpicks up at Stn. B as per fig. 5.
An FM code is generated due to picking up of PBPR at Stn. B, which connects powerto TX as per circuit in Fig. 7. The modulating frequency F1(85 Hz) is selected overterminal TX-5 & TX-6 & modulated current flows to terminals 34, 37 to the line sideisolation transformer.
6.4.9 With the PBPR picking up at Stn. B, NR picks up at Stn. A through the line circuit asper fig. 6 & 8. CR1 picks up at Stn. A on receipt of modulated current as per fig. 9.
With the NR and CR1 picking up Lock magnet is energised at B point of block handleas per fig. 30, making it possible to restore the handle to Line Closed position. TOLindicator changes to White during turning of handle from Train Coming From to LineClosed.
B24 61 62
158
48 SM S2N2
1 S2 2 29 3021
C2R2
CAMTECH/99/S/DAIDO/1.0 30
S/ Line Tokenless B/Instrument December’ 1999
(D) WHEN A TRAIN SHUNTING (AT ‘A’ STATION)
The Block handles are in Line Closed position at both stations ‘A’ & ‘B’, or Stn. A inTrain Going To & Stn. B in Train Coming From.
A station calls ‘B’ station to obtain authorization over the telephone.
SM at Stn. A inserts SM key & turns IN. SHUNT key is taken out & handed over tothe driver of a shunting train. The Block handle is locked at the time. The SM key istaken out.
On completion of shunting operation, Shunt key is taken back from driver of train. SMinserts SM key & turns to IN, thereafter inserts SHUNT key and turns IN. The advice issent to Stn. B over the telephone to that effect.
4/7A 8A 2/5A 6A 1ATO I. TRANS
FIGURE 35
58
B 24V
61 62
IR PBPR PB2
4A 3A 4/7D 3D
3 4
5 (c)
6 2
48 SM
31
34
37
TELR
4 1
N24
L
21
TOLR 3R
TX1 1
6A 2/3A 5D 6D 5D6D
TOLR CR1 CR2
CAMTECH/99/S/DAIDO/1.0 31
S/ Line Tokenless B/Instrument December’ 1999
(E) TELEPHONE CIRCUIT :
While modulated current F1 to F2 is being transmitted or received, telephone circuit isisolated from power line.
While telephone is used, transmitter and receiver are isolated from line. To explain indetail telephone relay TELR is inserted in series connection with relay. CR1 (B)CR2(B) and TOLR (B) in the circuit fig. 36. Also TELR(F) is connected in series in thetelephone circuit, Thus telephone circuit is isolated from signal circuit. Wheremodulated current is transmitted and received by TELR which is inserted betweensignal circuit and Transmitter/Receiver, Transmitter/Receiver is isolated form signalline which telephone is used.
7. TRANSMITTER AND RECEIVER
7.1 Operating Parameters
Transmitter
Item Rating ToleranceTransmitting frequency 1800 Hz or 2700 Hz + 2%Transmitting output 1 mW, 3 mW, 5 mW,
adjustable+10%,-5%
Output impedance 600 Ohms, 1120 Ohmsadjustable
+ 2%
Modulation system Frequency modulationModulation frequency 65 Hz or 85 Hz + 1.5 HzPower consumption 1.2 watts or less at 24 V DCInput power supply 24 V DC + 20%Shift frequency 160 Hz + 15%
Receiver
Item Rating ToleranceReceiving frequency 1800 Hz or 2700 Hz +2%Level range 0 to 28 dB In step of 2
dB or lessMax. noise allowance -44 dBm + 2%Input impedance 600 ohms, 1120
ohms adjustableRelay output voltage 24V DC or above 21V min.Power consumption 8 watt or less at 24 V DCInput power supply 24V DC + 20%Sense level for receiving less than - 29 dBmNo Sense level forreceiving
More than - 38 dBm
Shift frequency 160 Hz. + 15 %
7.2 Connection Terminals & Test Blocks
7.2.1 Transmitter
CAMTECH/99/S/DAIDO/1.0 32
S/ Line Tokenless B/Instrument December’ 1999
Connection Terminals
It have 8 fixed terminals. Serial Nos. and connections are as below:
Terminal Nos. Connections1 & 2 Out put3 Positive DC input4 Negative DC input5 Common6 85 Hz.7 65 Hz.8 Spare
Test Blocks
Test blocks are provided at the back side of the transmitter with a cover and seatingarrangements.
1. 24V DC supply2. Regulated voltage3. Modulated frequency 65 Hz & 85 Hz4. Carrier frequency 1800 Hz. or 2700 Hz.5. TX output
7.2.2 Receiver
Connection Terminals
It have 8 fixed terminals. Serial Nos. and connections are as below:
Terminals Connections1 & 2 Input3 Positive DC input4 Negative DC input5 & 6 Output for CR2 relay7 & 8 Output for CR1 relay
CAMTECH/99/S/DAIDO/1.0 33
S/ Line Tokenless B/Instrument December’ 1999
Test Blocks
Test blocks are provided at the back side of the receiver with a cover and seatingarrangements.
1. 24V DC supply2. Regulated DC supply3. Input4. Demodulated Signal5. Input to CR16. Input to CR2
7.3 Trouble Shooting Method for Transmitter & ReceiverSr. SYMPTOM ACTION TO BE TAKEN1. No output from
receiver.Check if the supply is OK bypressing push to make switch intransmitter and receiver. If power ONindicators are glowing with red LEDit means power supply is OK. If thered LED does not glow, check thefuse. If the fuses are missing/blown,replace it.
2 Power OK,LEDs OK butrelay does notpick up.
Press the PTM switch which is on thefront panel and see if the levelindicator green LED glows or not. Ifglows that means relay driving signalis OK & the problem is withrespective relay, so replace it and getthe desired result.
If the level indicator Amber LEDglows:
The relay driving signal is missing,check the following:
Input to the RX between 5&6 (+10Vto +13V PP) between 7&8 (+1.5V to+ 2.5V PP), between 9&10 or 11&12(+21.6V to +26V PP).If the above voltage signals are notregular/proper, open the cabinet andfollow the signal flow and check thevoltages.
CAMTECH/99/S/DAIDO/1.0 34
S/ Line Tokenless B/Instrument December’ 1999
8. EARTHING
A separate earth should be provided for each block instrument.
The resistance of earth shall not exceed 10 Ohm.
The earth shall be located on lower level soft ground far from underground cable, waterand gas pipes.
9. SAFETY CHECK
• Ensure that double lock is provided and seal is intact. • Try to operate the instrument without cooperation i.e. without receipt of functional
code, it shall not be possible to turn the block handle from Line Closed to Train GoingTo or Train Coming From position.
• On receipt of TGT code, turn block handle from Line Closed towards Train Going to
& stop midway. Disconnect Line & try to turn the handle further. It shall lock in checklock position. Ensure armature of electric lock on block handle is force dropped incheck lock notch and the block handle can not be turned to Train Going to position.
• With a train in Block Section, try to bring the block handle to Line closed with &
without cooperation from other station, it shall not be possible to turn the block handleto line closed position. The Block handle should remain locked in last operatedposition.
For Last Stop Signal :
• Try to take OFF the Last Stop Signal without taking line clear (“L” position of blockhandle), the signal should not clear.
• Shunt the FVT track, the Last Stop Signal shall go back to danger automatically.
• It is not possible to take OFF the Last Stop Signal again unless a fresh line clear is
obtained.
SUGGESTION :
a) Removal of Filter unit & X, Y relays in RE area. b) Disconnect the two condensers of the Block Filter unit c) The rare gas lightning arrestor should be replaced with MOVR.
10. MAINTENANCE
CAMTECH/99/S/DAIDO/1.0 35
S/ Line Tokenless B/Instrument December’ 1999
10.1 Periodicity of Overhauling
A thorough periodical overhauling in Workshop is necessary and the period shall notexceed 7 years.
10.2 Maintenance
The following points are to be kept in mind while doing maintenance for reliableworking of block instrument.
• The local battery voltage at the instrument terminals on load should not be below 24
volts. Secondary cells of sufficient capacity may be used as the maximum workingcurrent per instrument is about 2 Amps ( when thermal time element relay is used) &0.6 Amp (when Electronic time element relay is used)
• The upper limit of local battery on load should not exceed 29 V as it may affect the
Zener diode working. • The line battery shall be capable of circulate 110 mA in Line circuit measured at code
receiving station. • The line current shall be measured both at the transmitting end and the receiving end.
There shall not be an appreciable variation.• Separate battery or DC-DC converter shall be provided for line circuit of each block
instrument. Whenever the line battery/ DC-DC converter is changed, the line currentshould be checked.
• ??Whenever old type condenser units are changed ( with 4 BA fixing screw ), ensure
that the other interconnected instrument condenser unit is also changed to the same typesince the values are different.
• Care shall be taken to ensure that the relay jack boards and relays are clean and dustfree.
• During the periodical Maintenance/ Inspection, the charger shall be switched “OFF ”
and the working of the relays shall be observed for few operations. The terminalvoltage should be monitored during the code transmission in order to ensure thecondition of the battery.
• Whenever the instrument fails, interchanging of relays and units shall not be restoredto, without ascertaining the actual cause and this change may be effected only if it iswarranted.
• While plugging in relays/ units, excessive force should not be exerted as it may affectthe jack board clips.
11. TROUBLE SHOOTING
Fault Cause/ Rectification
CAMTECH/99/S/DAIDO/1.0 36
S/ Line Tokenless B/Instrument December’ 1999
Sr.no.
Condition
1. Bell beatsfailed fromStn. ’A’ toStn. B
1. Line battery low or disconnection atstation ‘A’.
2. PB1 push button contact developsdisconnection at Stn A.
3. Line is open/short circuit or offeringhigh resistance.
4. PB1 button contact developsdisconnection at Stn. B.
5. Local battery disconnection or weak atStn. B. It shall be 24 V.
6. BLR relay not picking up at Stn. ‘B’when PB1 pressed at Stn. A due tosome fault.
7. Diode, in series with BLR/ NRpunctured.
8. Relay contacts NR, BLR, PBPRoffering high resistance at Stn. A &Stn. B.
9. When PB1 is pressed at Stn. A, BLRshall pick up at Stn. B. Suppose BLRis not picking up, check up theincoming line voltage at Stn. B acrossL1 & L2(Terminal No. 25 & 26working voltage 24 Volt. If voltage isavailable and relay is not picking up,check for working current ( 110 mA.).
CAMTECH/99/S/DAIDO/1.0 37
S/ Line Tokenless B/Instrument December’ 1999
Sr.no.
FaultCondition
Cause/ Rectification
2. Failure ofLockMagnet.
Ensure the following:1. SM’s key ‘ON’ contact is making.2. Relay 1R front contact is making
(checking up the slides/ levers/ blocksignals ‘ON’).
3. TER cold contact in TER.4. Switch S1 & switch S2 in ‘N’.5. Back contact of relay 2R & relay 3R is
making.6. Relay TRSR front contact is making in
case of turning the block handle from‘N’ to ‘L’ including check lock.
7. Relay TRSR back contact is making incase of turning the block handle from‘N’ to ‘R’, ‘T’ to ‘N’, ‘L’ to ‘N’.
8. Block handle contact XX/, in case ofturning block handle from ‘N’ to ‘L’.
9. Block handle contact BDY, in case ofturning block handle from ‘N’ to ‘R’,‘R’ to ‘N’, ‘L’ to ‘N’ respectively..
10. Front contact of relay NR is making.11. Front contact of relay CR2 is making
for turning the Block handle from ‘N’to ‘L’.
12. Front contact of relay CR1 is makingfor turning the Block handle from ‘N’to ‘R’, ‘R’ to ‘N’, ‘L’ to ‘N’.
13. Local battery voltage 24 Volts.14. Ensure cross protection contact viz.
CR1 & CR2 breaking during therespective operations.
CAMTECH/99/S/DAIDO/1.0 38
S/ Line Tokenless B/Instrument December’ 1999
Sr.no.
FaultCondition
Cause/ Rectification
3. Failure ofrelay 1R
1. Ensure voltage of location battery24 Volt.
2. All block signals at ‘ON’ concernedlevers/slides normal.
4. Failure ofrelay 2R
Ensurea. TAR pickup while train arrives. If
TAR is not pickup, check TAR circuit.b. TAR front contact making properly.c. Stick circuit is taken through block
handle contact LB/RD, check the blockhandle contacts.
4. Failure ofrelay 3R.
Check TER circuit, SM’s key contact,Switch S1, ‘R’ contact, TER hot contact,TEPR circuit, TER cold contact, Blockhandle LX contact.
5. Failure ofPBPR relay.
Check the PB1 & PB2 contact of pushbutton, 1R front contacts. When Blockhandle is in (RD) check up Block handlecontact, TOLR front contact, check SM’skey contacts.
6. Failure ofrelay TRSRat trainsendingend ‘A’
1. Check for CR2 front contacts NR frontcontacts, 1 TPR front contacts.
2. Block handle contracts XX/, LX.3. Local voltage 24V(Including fuses
etc.)4. 3R back contacts.5. If stick feed is not available, check
TRSR front contacts, make beforebreak contacts of XX//LX/.
6. Check the condenser across TRSR.
CAMTECH/99/S/DAIDO/1.0 39
S/ Line Tokenless B/Instrument December’ 1999
Sr.no.
FaultCondition
Cause/ Rectification
7. Failure ofTOLR at‘A’
A. Pickup circuit for TOLR. i) Ensure TRSR show to release feature
(condenser)-(slow to release)ii) Ensure TRSR front contact making.iii) Ensure ITPR back contact making.iv) Ensure Block handle contacts LB
making.v) Ensure 3R back contacts making.
B. Ensure stick feed to TOLR.
i) Ensure S2 normal contacts making.ii) Ensure TOLR front contacts making.iii) NR back contacts making.iv) TRSR back contacts making.v) 3R back contacts making.
8. Failure ofTOLR atStn. ‘B’.
i) Ensure CR2 front contacts making.ii) Ensure NR back contact making.iii) Ensure block handle RD contact
making.iv) Ensure local voltage 24 Volt.
9. Failure ofCR1/ CR2
Ensure at code receiving end.If CR1 & CR2 are picking up. Check atthe receiver test terminals for (a) 24V DCinput to receiver (b) FM input. If DC inputis absent check the block handle contactXY/LB/RD. If FM input is presentcheckup the level. If the level is OK,adjust the attenuator. If the level is low atthe TX, check the level low/high/medium.
Sr.no.
FaultCondition
Cause/ Rectification
If the level is OK, check the frequency forCR1 carrier frequency 1800/2700 Hz./Modulated frequency 85 Hz, for CR2carrier frequency 1800/2700 Hz./Modulated frequency 65 Hz. If the leveland frequency OK check the FM inputpath in to RX. At the TX end check DCinput, TX freq. Loop circuit for FM, whichincludes block handle contacts N, R & L.
10. Failure ofLast StopSignalcircuit.
Check for ASR:- TRSR front contacts, S1normal contact, LA contact of blockhandle, 1R back contacts.
CAMTECH/99/S/DAIDO/1.0 40
S/ Line Tokenless B/Instrument December’ 1999
11 Failure ofHomeSignal
Check for HSR circuit:- S1 normalcontacts & RY/ LB contact or ( S2 reversecontacts & L of block handle for pushback operation).
12 PrematureTOL
Stick feed to TRSR cut off due to ITPRmomentarily dropped due to unknownreason before train enters into section.Check the TPR circuit, if OK, check trackcircuit & block handle’s LX/ contact .
13 Normalcancellationnotpossible.
TRSR dropped due to momentarydropping of 1 TPR or 3R circuit. LX/
contact not making. Check S1 switch Rcontacts in TER circuit and 3R circuit aremaking properly. Check 1R front contactand SM’s key contact.