Contents. General Description... 1

Contents General Description... Data Processor Box... 3 Power Supply PCB... 4 Data Processing Module... 5 CCD Scanner Module DIP Switch Setup... 8 Camera Assembly... Scanner Tester Connector... Ball Detect... 2 Ball Detect Adjustments... 3 Brunswick A-2 Pinsetter Modifications... 4 Switch Cluster... 4 44 /44 Switch ( Take Data )... 4 0 Switch... 4 Adjustments... 5 0 Switch... 5 44 /44 Switch... 6 New Pins Solenoid and Cycle Link... 7 Cycle Link Operation... 9 Adjustments... 2 AMF Pinspotter Modification... 22 Switch Overview... 22 Sweep Switch... 22 Sweep Up Switch... 22 Table Switch... 22 AMF 82-30 Model Pinspotter Switch Adjustments... 23 Sweep Up Switch (0 )... 23 Table Switch... 24 Sweep Switch... 25 Chassis Cam Switch... 26 CCD Scanner 8i

AMF 82-70 Model Pinspotter Switch Adjustments... 26 Sweep Up Switch (0 )... 28 Table Switch... 28 Sweep Switch... 29 AMF Interface PCBs... 30 AMF Third Ball, Tenth Frame/No Tap Relay... 34 AMF 82-30 Pinspotter... 34 AMF 82-70 and 82-70 SS Pinspotters... 34 Brunswick A-2 Pinsetter Scoring Sequence of Events... 36 First Ball... 36 Second Ball... 37 First Ball Foul... 38 Third Ball, Tenth Frame... 39 No Tap Cycling... 40 Brunswick GS-0/GS-92 Pinsetter Scoring Sequence of Events... 4 First Ball... 4 Second Ball... 42 First Ball Foul... 43 AMF Pinspotter Scoring Sequence of Events... 44 First Ball... 44 All Models... 44 Second Ball... 45 All Models... 45 First Ball Foul... 46 All Models... 46 Third Ball, Tenth Frame... 47 AMF 82-30, 82-70, and 82-70 SS Pinspotter with Version.35 or Higher CCD Software... 47 AMF 82-70 and 82-70 SS Pinspotters with Version.3 and.32 CCD Software... 48 No Tap... 49 AMF 82-30, 82-70, and 82-70 SS Pinspotters with Version.35 or Higher CCD Software... 49 82 ii CCD Scanner

Double Diamond Cycles... 50 Scanner Tester... 5 Overview... 5 Displays... 5 Normal Display... 52 Align L. Side Display... 53 Align R. Side Display... 54 Cal Pins Display... 55 Camera Adjustments... 56 Scanner Tester Messages... 58 Cable Diagrams... 59 CCD Scanner 83 iii

80 iv CCD Scanner Intentionally Blank

General Description The CCD (charged-coupled device) Scanner is an electrical/optical device used to count standing pins. The scanner uses a camera, a ball detect, a data processor box, and special pinsetter modifications to properly count pins. Refer to the figure titled CCD Scanner Camera and Data Processor Box. (2) BALL DETECT (3) DATA PROCESSOR BOX CCD Scanner Camera and Data Processor Box () CCD SCANNER CAMERA (2) BALL DETECT (3) DATA PROCESSOR BOX The camera is mounted in the center of a lane pair over the ball return so the camera lens is 56" from the center of the last row of pins. Refer to the figure titled CCD Scanner Location. The camera uses a wide angled lens to take a picture of the pit area of both pinsetters. The picture is then analyzed by the Data Processing Module. During the analysis, a portion of the picture is examined for bright spots. Each bright spot found in this portion is further analyzed to determine the height or size of the spot. Once the size of the spot is determined, the scanner refers to its stored calibration to decide which pin caused it. (The closer a pin is to the camera, the larger its bright spot. Each pin will therefore have a uniquely sized bright spot. ) This information is then sent through the Pinsetter Interface Box to the Lane Group Processor (LGP) where it is processed. To provide the timing required, a ball detect is located by the scanner to ensure that the scanner scores only after a ball has been thrown. In addition, add-on pinsetter switches are used to ensure that the picture is taken at the proper time during the pinsetter cycle. Alignment of the scanner camera is accomplished by using a scanner tester connected to the Data Processor Box. CCD Scanner

CCD Scanner Location () CAMERA LENS The CCD Scanner consists of the following components:. Camera - The camera is responsible for taking a picture of the pit area of both pinsetters with a wide angle lens and sending the information to the Data Processor Box for evaluation. 2. Data Processor Box - The Data Processor Box contains two printed circuit boards (PCBs): the Data Processing Module and the Power Supply. The Data Processing Module receives information from the camera and sends it to the Lane Group Processor (LGP). The scoring process begins when the module receives a signal from the ball detect. As the pinsetter cycles, switches on the machine are activated which tell the Data Processing Module to count the number of standing pins as seen through the camera lens. It is at this time the module sends the pin count to the LGP. 3. Ball Detect - The ball detect is an infrared device that senses when a ball has been thrown. The signal from the ball detect tells the Data Processor to begin the scoring cycle. 4. Pinsetter Modifications - Switches added to the pinsetter to make sure the camera takes the picture at the proper time during the pinsetter cycle. Also additional components may be added to allow special pinsetter cycles for fouls, No Tap, and 3rd ball 0th frame situations. 5. Scanner Tester - A video display unit attached to the Data Processor Box via an external connector. The tester is used to check or align the camera. 2 CCD Scanner

Data Processor Box The Data Processor Box is the brain of the scanner. It contains two printed circuit boards to accomplish all the functions of the scanner: a Power Supply PCB and a Data Processing Module. Refer to the figure titled CCD Scanner PCBs. CCD Scanner PCBs () CCD DATA PROCESSOR BOX (2) POWER SUPPLY PRINTED CIRCUIT BOARD (3) DATA PROCESSING MODULE CCD Scanner 3

Power Supply PCB The Power Supply PCB is responsible for supplying the Data Processing Module with all the power necessary to operate the CCD Scanner. It contains a transformer to reduce incoming 28 VAC (volts alternating current) from the Pinsetter Interface Box, as well as voltage regulators to regulate power to the Data Processing Module. The incoming power is protected by a 4A (amp) fuse labeled F. Refer to the figure titled CCD Scanner Power Supply PCB. CCD Scanner Power Supply PCB () F INPUT POWER FUSE (2) J 28 VOLTS ALTERNATING CURRENT INPUT (3) J2 DIRECT CURRENT OUTPUT (4) TX TRANSFORMER (5) VOLTAGE REGULATORS The Power Supply PCB consists of the following components: () Input Power Fuse (F) - A 4 amp main power fuse. (2) 28 VAC Input (J) - Connector for input voltage from the Secondary Console's 28 VAC transformer. The 28 VAC is wired through the Pinsetter Interface Box. (3) DC Output (J2) - Output power to the Data Processing Module. (4) Transformer (TX) - Step-down transformer used to reduce incoming 28 VAC to necessary voltage levels for use at the Data Processing Module. (5) Voltage Regulators (VR, VR2, and VR3) - These voltage regulators supply steady +5V, -5V, and +5V for the Data Processing Module. 4 CCD Scanner

Data Processing Module The Data Processing Module is the brain of the CCD Scanner. It receives information from the scanner camera and sends it to the scorer console. Refer to the figure titled CCD Scanner Data Processing Module. CCD Scanner Data Processing Module () BALL DETECT INPUT (J5) (2) CAMERA POWER (J90) (3) CLOCK (J0) (4) DATA LOGGER (J502) (5) FOUL INPUT (J6) (6) GAMESETTER INPUT (J65) (7) LED BAR DISPLAY (U705) (8) LEFT PINSETTER INPUT/OUTPUT (J8) (9) POWER SUPPLY (DC INPUT) (J9) (0) RIGHT PINSETTER INPUT/OUTPUT (J9) () TO SCORER PINSETTER INTERFACE (J67) (2) SETUP SWITCH (SW70) (3) TEST SET (SCANNER TESTER) (J50) (4) VIDEO IN (J20) (5) SWITCH SETUP FOR TEN PIN BOWLING WITH BRUNSWICK A-2 PINSETTERS AND FRAMEWORX (REFERENCE TEXT FOR ADDITIAL SETUPS) CCD Scanner 5

The scoring process begins when the module receives a signal from the ball detect. As the pinsetter cycles, switches on the machine are activated which tell the Data Processing Module to count the number of standing pins as seen through the camera lens. It is at this time the module sends the pin count to the LGP via the Pinsetter Interface Box. In the event the module receives a foul signal from the Tel-E-Foul unit, the module will send an "F" in place of the pin count. There are no adjustments on the Data Processing Module. All adjustments are done on the camera itself or through the Scanner Tester. The only setup necessary on the Data Processing Module is the setting of switches on SW70. The Data Processing Module consists of the following components: () Ball Detect Input (J5) - Signals from both the left and right lane ball detects enter the PCB through these connections. (2) Camera Power (J90) - Connector for DC power to the scanner camera. (3) Clock (J0) - Connection for the clock signal sent between the Data Processing Module and the scanner camera. (4) Data Logger (J502) - Not used. (5) Foul Input (J6) - Signals from the Tel-E-Foul unit enter the PCB through these connections. (6) Gamesetter Input (J65) - Connection for the Brunswick GS Pinsetters. (Not used with the Frameworx Scoring Systems.) This connector is removed on most PCBs. (7) LED Bar Display (U705) - A ten segment light-emitting diode (LED) bar display used for diagnostics and troubleshooting. In normal operation, all LEDs should be off. If any LED is on, calibrate the scanner through the Scanner Tester and power down the scanner. Typically if LEDs, 2, or 3 remain on, recalibrating the scanner will correct the problem. When LEDs 4-0 (or any combination that includes any of these LEDs) remain on, the problem typically is caused by a bad data processor box, bad camera, or faulty cabling between the two. (8) Left Pinsetter Input/Output (J8) - Connection for signals coming from the left (odd) pinsetter. Signals for the take data and 0 switches, second ball, and New Pins Solenoid control enter the PCB here. (9) Power Supply (DC Input) (J9) - Input power from the Power Supply PCB. 6 CCD Scanner

(0) Right Pinsetter Input/Output (J9) - Connection for signals coming from the right (even) pinsetter. Signals for the "take data" and zero degree switches, second ball, and New Pins Solenoid control enter the PCB here. () To Scorer (Pinsetter I/O) (J67) - Connection for all communications to and from the LGP (via the Pinsetter Interface Box). (2) Setup Switch (SW70) - Used to determine the type of console, type of pinsetter, and type of scoring system the scanner is connected to. The switch settings are determined by the software version installed. Reference the tables titled Software Version.30 and Prior, Software Version.3 and.32, and Software Version.34 and.35 for proper settings. NOTE: Before changing any switch setup the power must be removed from the data processor box. Refer to J 28 VAC Input on the Power Supply PCB. (3) Test Set (Scanner Tester) (J50) - Connection for an external connector to the Scanner Tester. (4) Video (J20) - Connection for the video image coming from the camera. CCD Scanner 7

CCD Scanner Module DIP Switch Setup Switch # Function Setting # Host Type # (Factory Use Only) Automatic Scorer #2 Trigger Type #2 All Installations (Factory Use Only) #3,#4,#5 Pinsetter Type #3 #4 #5 A-2, A GS-0/GS-92 AMF A-2, Double Detect A (90 Overtravel) BowlerVision with A-2 Undefined Undefined #6,#7,#8 Pin Type #6 #7 #8 0 Pin 5 Pin Duck Pin 0 Pin Stringer Concealed Surface Surface Undefined Undefined Software Version.3.0 and Prior 8 CCD Scanner

Switch # Function Setting # Factory Diagnostics # (Factory Use Only) Ready to Operate #2 Host Type #2 Automatic Scorer BowlerVision #3,#4 Pinsetter Type #3 #4 A-2, A A with 90 Overtravel AMF A-2, Double Detect #5 Reset Calibration #5 Ready to Operate Reset Calibration #6,#7,#8 Pin Type/ Camera Height #6 #7 #8 0 Pin Subway 0 Pin Concealed Surface 0 Pin Surface Return 5 Pin Surface Return Duck Pin Surface Return Undefined Undefined Undefined Software Version.3. and.3.2 CCD Scanner 9

Switch # Functio n Setting # Factory Diagnostics # (Factory Use Only) Ready to Operate # 2 Host Typ e # 2 AS-80, AS-90, AS-K, & Frameworx BowlerVision #3,#4, #5 Pinsetter Type # 3 #4 #5 A, A-2 o A with 90 Overtrave l AMF AMF 82-30 None of the Above None of the Above None of the Above Reset Calibration # 6,#7,#8 Pin Type/Camera Height #6 #7 #8 0 Pin Subway 0 Pin Concealed Surface 0 Pin Surface Return 5 Pin Duck Pin Undefined Undefined Undefined Software Version.34 and.35 NOTE: Anytime the switch setup is changed, the scanner must be calibrated through the Scanner Tester. In addition, the scanner must be powered down prior to changing the switch position. 0 CCD Scanner

Camera Assembly The CCD Camera takes a picture using a wide-angled lens. This information is sent to the Data Processing Module through the video cable. A clock, located on the Processor PCB, ensures that the camera sends the information at the proper speed. The Processor PCB supplies the camera with power to operate. The figure titled Back View of CCD Camera shows the connections to the camera. Back View of CCD Camera () CLOCK (2) CAMERA POWER (3) VIDEO OUT Scanner Tester Connector The CCD Scanner provides an external connector for the Scanner Tester. Two LEDs on the connector bracket indicate whether the scanner has power and whether the scanner start-up tests that are performed at power-up passed without problems. Refer to the figure titled CCD Scanner Tester Connector. If the diagnostic LED remains off check the LED bar display located on the Data Processor PCB to determine which LEDs are on. CCD Scanner Tester Connector () POWER LIGHT-EMITTING DIODE (2) DIAGNOSTICS LIGHT-EMITTING DIODE (3) CCD SCANNER EXTERNAL (SHOULD BE ) (SHOULD BE ) CNECTOR FOR SCANNER TESTER CCD Scanner

Ball Detect The CCD Scanner uses a ball detect that is an infrared sensing device. The ball detect is made up of two infrared transmitters and receivers, one for each lane. Within each lane unit there are two lenses, one to focus the transmitted infrared beam toward the retroreflector on the opposite side of the lane, and one to focus the return light from the reflector onto the infrared receiver. A red indicator LED turns on when the infrared beam is blocked. Refer to the figure titled CCD Scanner Ball Detect and Lens. () INDICATOR LED (3) VERTICAL ADJUSTING SCREW (2) TRANSMITTER (4) RECEIVER (5) HORIZTAL ADJUSTING SCREWS CCD Scanner Ball Detect and Lens () INDICATOR LIGHT-EMITTING DIODE (2) TRANSMITTER (3) VERTICAL ADJUSTING SCREW (4) RECEIVER (5) HORIZTAL ADJUSTING SCREWS (6) BALL DETECT (7) BALL RETURN 2 CCD Scanner

Ball Detect Adjustments The Ball Detect Assembly uses an infrared light which cannot be seen without an optical aid. Therefore, it has a red indicator light on the face of the unit that will light when insufficient infrared light is reflected back to it. Refer to the figure titled CCD Scanner Ball Detect and Lens. To center the infrared beam on the reflector, use the following steps:. With power on to the CCD Scanner, cover the reflector so the red indicator light on the ball detect unit comes on. 2. Using another reflector, start above the covered reflector and slowly move the second reflector down toward the first while holding it square to the ball detect unit. Continue to move it downward until the red light goes out. Note the position of the second reflector. Refer to the figure titled Adjusting Reflector. () COVER REFLECTOR SO INDICATOR LED BALL DETECT COMES (2) MOVE REFLECTOR DOWNWARD UNTIL INDICATOR LED BALL DETECT GOES OUT Adjusting Reflector () COVER REFLECTOR SO INDICATOR (2) MOVE REFLECTOR DOWNWARD UNTIL LIGHT-EMITTING DIODE BALL DETECT INDICATOR LIGHT-EMITTING DIODE COMES BALL DETECT GOES OUT 3. Repeat the same procedure but start below the covered reflector (in the ball gutter) and move up until the light goes off. Note that position. 4. Repeat the same procedure starting from the left of the covered reflector and then from the right until you have located the relative position of the infrared beam. 5. If the beam is not centered on the covered reflector, it can be adjusted with the three adjustment screws on the face of the unit. Reference the figure titled CCD Scanner Ball Detect and Lens. The top screw moves the beam up and down. A clockwise turn moves the beam down, while a counterclockwise turn will move it up. The side screws will move the beam left to right. 6. After each adjustment, recheck the beam's location with the second reflector and procedure detailed above. CCD Scanner 3

Brunswick A-2 Pinsetter Modifications Switch Cluster The Switch Cluster is a metal plate containing switches and cams that are mounted on the detector and is engaged to the detector : gear. The nylon gear that drives the cam shaft turns the cams which are timed to close the switches at proper times during the pinsetter cycle. Refer to the figure titled Brunswick A-2 Pinsetter Switch Cluster. Brunswick A-2 Pinsetter Switch Cluster () ADJUSTABLE CAM (2) 0º SWITCH (ZERO) (3) B-2000 SWITCH (NO LGER USED) (4) 44º/44º SWITCH ("TAKE DATA") 44 o /44 o Switch ( Take Data ). This switch closes twice every pinsetter cycle. The first switch closing will cause a take data signal when the deck is approximately " (44 ) above the pins if the pinsetter is on first ball. 2. The second switch closing will cause a take data signal at 44 when the rake is approximately 0" from the no. pin if the pinsetter is on second ball. 3. The switch is also used during special pinsetter cycles to energize the New Pins Solenoid during the first ball foul or No Tap cycles so any standing pin(s) will be swept away. 0 o Switch. The 0 switch closes once each pinsetter cycle. It is used to reset memory on the Data Processor PCB and allows the Data Processor to accept the ball detect signal. 2. Energize the New Pins Solenoid at the end of the first ball and third ball fouls, tenth frame cycles so that the bowler will have a second ball shot. 4 CCD Scanner

Adjustments The Switch Cluster contains three switches. Two of these switches, the 0 o and the 44 o /44 o, monitor the pinsetter to provide timing information for proper scoring. Correct adjustment of these switches is necessary and must be checked after clutch adjustment, detector repair, or any other change to the timing of the pinsetter. The third switch is used only for timing of the ball director on the Systems 2000 Ball Rack and is no longer used. 0 o Switch The lobe of the inside cam on the Switch Cluster must actuate the 0 o switch when the pinsetter is at 0 o. Refer to the figure titled 0 Switch Adjustment. 0 o Switch Adjustment () OLD CFIGURATI (2) NEW CFIGURATI (3).025" OVERTRAVEL AT TOP OF LOBE (4) 0º SWITCH (5) ACTUATE HALFWAY UP LOBE (6) MARK LOBE Adjusting the cam is done by removing the Switch Cluster Assembly from the detector's : gear and repositioning the cam to actuate the 0 o switch. (The pinsetter must be at 0 o.) To adjust the switch perform the following steps:. Remove the switch cluster from the detector. 2. Position the cam and switch so the switch is activated half way up the front edge of the lobe. Reference the figure titled 0 Switch Adjustment. An overtravel dimension of.025" is necessary at the top of the lobe to prevent damage to the switch. (On cams with a long lobe duration, the switch should be actuated at the scribe mark located near the middle of the lobe.) 3. Replace the cluster on the detector making sure that the cam does not change position. 4. Verify the operation of the switch by monitoring the 0 o indicator on the CCD Scanner Tester. The indicator should read close only when the pinsetter is at 0 o. CCD Scanner 5

44 /44 Switch To adjust the 44 /44 switch perform the following steps. Refer to the figure titled 44 /44 Switch Adjustment.. Cycle the pinsetter to a full rack first ball. 2. Lower the pinsetter deck until it is approximately 6" ± / 2 above the pin deck (" above the pins). 3. Loosen the lockscrew holding to outer cam to the shaft. 4. Loosen the 44 /44 switch mounting screws. 5. Rotate the outer cam clockwise until the roller of the switch lever is positioned halfway up the front edge of the outer cam. 6. Adjust the switch so that it activates. 7. Tighten the cam lockscrew and the switch mounting screws. 8. Cycle the pinsetter so that the switch is at the top of the lobe. 9. Verify that there is approximately.025" gap between the switch and the switch lever to prevent switch damage. () LOCKSCREW (2) SECD LOBE (3) ACTUATE HALFWAY UP FIRST LOBE (4).025" OVERTRAVEL AT TOP OF LOBE (5) 44 /44 SWITCH 44 o /44 o Switch Adjustment () LOCKSCREW (2) SECD LOBE (3) ACTUATE HALFWAY UP FIRST LOBE (4).025" OVERTRAVEL AT TOP OF LOBE (5) 44º/44º SWITCH 6 CCD Scanner

New Pins Solenoid and Cycle Link The New Pins Solenoid is used to switch the pinsetter to second ball in the event of a first ball foul, third ball, tenth frame or a No Tap strike to eliminate the bowler's need to push the reset button. Refer to the figure titled New Pins Solenoid. New Pins Solenoid () OLD CFIGURATI (2) NEW CFIGURATI (3) BRACKET (4) SOLENOID LINK (5) TO PINSETTER (6) RELAY ASSEMBLY (7) SIGNAL LIGHT-EMITTING DIODE (8) RELAY PRINTED CIRCUIT BOARD (9) 20 VOLTS ALTERNATING CURRENT SOLENOID CCD Scanner 7

In order to make the New Pins Solenoid actuate on a foul, the following signals must occur:. First ball. 2. Foul signal. 3. Ball detect. If the signals are present, the New Pins Solenoid will be energized two times during the pinsetter cycle. At 44 the New Pins Solenoid will energize causing the pinsetter to switch to second ball and sweep all standing pins. It energizes again at 0 causing the pinsetter to switch to second ball to give the bowler a full rack, second ball shot. For third ball, tenth frame, the New Pins Solenoid will fire one time at 0 o after a tenth frame spare or a double. This will automatically put the pinsetter in a second ball mode for the final ball of the game. For No Tap situations the New Pins Solenoid energizes at 44 causing the pinsetter to switch to second ball, sweep all pins from the pin deck, and reset to a full rack first ball for the next bowler. 8 CCD Scanner

Cycle Link Operation The New Pins Solenoid signal is received from the Data Processor Module for a foul third ball, tenth frame and No Tap cycles. When the New Pins Solenoid is energized, it pulls the standing pins selector clockwise, unblocking the standing pins cam follower. The standing pins cam follower goes into the low of the cam causing the C shaft to turn clockwise. The first and second ball switch lever is attached to the C shaft, and as it turns clockwise, it switches the ball light to second ball. Refer to the figure titled New Pins Solenoid Activated - Cycle Link Raised. (4) STANDING PIN CTROLLER (5) STANDING PIN SELECTOR (6) NEW PINS SOLENOID (7) A SHAFT () CYCLE LINK CRANK (2) CYCLE LINK ASSEMBLY (8) DETECTOR : SHAFT (9) C SHAFT (3) STANDING PIN CAM FOLLOWER (0) 0-90 OVERTRAVEL SELECTOR New Pins Solenoid Activated - Cycle Link Raised () CYCLE LINK CRANK (2) CYCLE LINK ASSEMBLY (3) STANDING PIN CAM FOLLOWER (4) STANDING PIN CTROLLER (5) STANDING PIN SELECTOR (6) NEW PINS SOLENOID (7) A SHAFT (8) DETECTOR : SHAFT (9) C SHAFT (0) 0º-90º OVERTRAVEL SELECTOR CCD Scanner 9

The 90 o overtravel hook selector is also attached to the "C" shaft, and as it turns clockwise, it forces the cycle link up. The upward motion of the cycle link turns the cycle crank clockwise around the "E" shaft. A pin in the cycle crank turns the strike selector in a counterclockwise direction unblocking the strike cam follower. The strike cam follower goes into the low of the timing cam rotating the "D" shaft counterclockwise. The moving deck/scissors selector rotates counterclockwise pulling the adjustable scissors link forward, rotating the moving deck/scissors latch counterclockwise to block the cam follower, and freeing the moving deck cam follower. This prevents the deck from picking up any pins standing on the pin deck during the detection stroke. The rake sweeps all the pins and the deck will then set ten new pins on the lane surface. The New Pins Solenoid will fire once more at 360 o to place the pinsetter in second ball. Refer to the figure titled New Pins Solenoid Activated - Strike Selected. (3) CYCLE CRANK ASSEMBLY (4) STRIKE CTROLLER (5) B SHAFT (6) STRIKE CAM FOLLOWER (7) MOVING DECK AND SCISSORS SELECTOR () STRIKE SELECTOR (8) D SHAFT (2) 0-90 OVERTRAVEL SELECTOR (9) C SHAFT New Pins Solenoid Activated - Strike Selected () STRIKE SELECTOR (2) 0º-90º OVERTRAVEL SELECTOR (3) CYCLE CRANK ASSEMBLY (4) STRIKE CTROLLER (5) B SHAFT (6) STRIKE CAM FOLLOWER (7) MOVING DECK AND SCISSORS SELECTOR (8) D SHAFT (9) C SHAFT 20 CCD Scanner

Adjustments The New Pins Solenoid (NPS) is adjusted by moving the NPS box toward or away from the pinsetter detector. This is made possible by two elongated holes drilled into the mounting bracket to which the box is attached. Refer to the figure titled New Pins Solenoid Mounting Bracket. (3) BRACKET (4) ADJUSTMENT SCREWS () CYCLE LINK (2) SOLENOID PLUNGER New Pins Solenoid Mounting Bracket () CYCLE LINK (2) SOLENOID PLUNGER (3) BRACKET (4) ADJUSTMENT SCREWS. Cycle the pinsetter to first ball. 2. Loosen the screws that mount the NPS box to the bracket. 3. Hold in the plunger solenoid and move the NPS box away from the pinsetter until the pinsetter switches to second ball. 4. Tighten the NPS box mounting screws. 5. Cycle the pinsetter back to first ball. 6. Verify the cycle link is free of any binds and has plenty of "play." 7. Verify the New Pins Solenoid operation by creating a first ball foul, third ball, tenth frame or No Tap situation. CCD Scanner 2

AMF Pinspotter Modification Switch Overview To time the CCD Scanner to the AMF Pinspotter so that the score is taken at the proper time during the pinsetter cycle, various switches are mounted on the pinspotter. The switches required for scoring are dependent on the model of pinspotter being used. In original 82-30 and all 82-70 installations, three switches are needed to provide the correct timing information. For recent 82-30 installations a single switch mounted on the timing cam is all that is required. For 82-70 and original 82-30 installations the following switches are used to perform specific functions. Sweep Switch The sweep switch is used to tell the scanner to score take data during a second ball cycle. This switch is similar to the 44 switch used in Brunswick A and A-2 Pinsetters. Sweep Up Switch The sweep up switch is used to tell the scanner when the pinspotter has finished it s cycle. This signal causes the scanner to reset and prepare for the next ball. It also allows the scanner to accept a ball detect signal. (When the switch is open the scanner ignores all ball detect signals). The switch also is used by the scanner to determine when the reset button should be actuated in No Tap and third ball, tenth frame situations. Table Switch The table switch is used to tell the scanner when to score during a first ball cycle. This switch is similar to the 44 switch used in Brunswick A and A-2 installations. For recent 82-30 installations a single switch attached to the timing cam is used. This switch performs all timing functions needed by the scanner and eliminates the need for separate table, sweep, and sweep up switches. 22 CCD Scanner

AMF 82-30 Model Pinspotter Switch Adjustments Sweep Up Switch (0 ) Adjust sweep up switch and switch actuator so the switch is actuated when the sweep is in the up position. Check 0 signal at Scanner Tester. Refer to the figure titled AMF 82-30 Pinspotter Sweep Up Switch. (3) EXISTING ALLEN CAP SCREW (4) SWEEP UP SWITCH (ZERO DEGREE) () CABLE CLIP (2) 5/8 HEX NUT (5) SWITCH ACTUATOR (6) EXISTING HEX NUT AMF 82-30 Pinspotter Sweep Up Switch () CABLE CLIP (2) 5/8 HEX NUT (3) EXISTING ALLEN CAP SCREW (4) SWEEP UP SWITCH (ZERO DEGREE) (5) SWITCH ACTUATOR (6) EXISTING HEX NUT CCD Scanner 23

Table Switch Using the hand crank, lower the table until the lowest projection on the table is 6" from the deck. Rotate the cam and collar assembly so the high of the cam will actuate the switch. Adjust the switch so the switch will be actuated only on the high of the cam. Check the 44 o signal on the Scanner Tester. Refer to the figure titled AMF 82-30 Pinspotter Table Switch. ().025 OVERTRAVEL (2) CAM AND COLLAR ASSEMBLY AMF 82-30 Pinspotter Table Switch ().025 OVERTRAVEL (2) CAM AND COLLAR ASSEMBLY 24 CCD Scanner

Sweep Switch Using the hand crank, position the sweep 0" in front of the no. pin spot. Position the cam and collar assembly to where it will actuate the switch at this point. Adjust switch so it will only make during the high of the cam. Check for proper indication on 44 o on the Scanner Tester. Refer to the figure titled AMF 82-30 Pinspotter Sweep Switch. (3).025 OVERTRAVEL (4) CAM AND COLLAR ASSEMBLY () EVEN LANE (2) ODD LANE AMF 82-30 Pinspotter Sweep Switch () EVEN LANE (2) ODD LANE (3).025 OVERTRAVEL (4) CAM AND COLLAR ASSEMBLY CCD Scanner 25

Chassis Cam Switch With the pinspotter at 0, adjust the position of the bracket using the slots so the new switch is just activated by the cam. Check for 44 /44 signal onthe Scanner Tester. Refer to the figure titled AMF 82-30 Pinspotter Chassis Cam Switch. () ADJUST BRACKET POSITI HERE (2) SWITCH IS ACTIVATED BY CAM AMF 82-30 Pinspotter Chassis Cam Switch () ADJUST BRACKET POSITI HERE (2) SWITCH IS ACTIVATED BY CAM The sweep position switch assembly on the AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters contains three switches. Two switches, the sweep switch and the B-2000 switch, are ganged together and must be checked when adjustments are made. The third switch, the sweep up switch, is to be adjusted after the sweep switch adjustment has been checked. AMF 82-70 Model Pinspotter Switch Adjustments The sweep position switch assembly on the AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters contains three switches. Two switches, the sweep switch and the B-2000 switch are ganged together and must be checked when adjustments are made. The third switch, the sweep up switch, is to be adjusted after the sweep switch adjustment has been checked. An additional switch called the table switch is located on the table shaft. Refer to the figure titled AMF 82-70, 82-70 MP, 82-70 SS Pinspotter Scoring Switches. 26 CCD Scanner

() SWEEP MOTOR (2) TABLE MOTOR (3) AMF 82-70 PINSPOTTER (4) TABLE SWITCH (5) B-2000 SWITCH (NOT USED) (6) SWEEP SWITCH (7) SWEEP UP SWITCH AMF 82-70, 82-70 SS, 82-70 MP Pinspotter Scoring Switches () SWEEP MOTOR (2) TABLE MOTOR (3) AMF 82-70 PINSPOTTER (4) TABLE SWITCH (5) B-2000 SWITCH (NOT USED) (6) SWEEP SWITCH (7) SWEEP UP SWITCH CCD Scanner 27

Sweep Up Switch (0 o ) With the pinspotter at 0 o, adjust the sweep up switch and the cam so the switch is actuated on the high of the cam. NOTE: The cam for this switch rotates on the collar independently of the sweep cam. Refer to the figure titled AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters Sweep Switch. Check the 0 o signal on the Scanner Tester for proper operation of this switch. () CAM ROTATES COLLAR INDEPENDENTLY OF SWEEP CAM AMF 82-70, 82-70 SS, and 82070 MP Pinspotters Sweep Switch () CAM ROTATES COLLAR INDEPENDENTLY OF SWEEP CAM Table Switch Position the table so the bottom of the table is 6" +/6" from the pin deck. Adjust the table cam and collar and the switch so the switch is actuated on the high of the cam. Check the 44 o indication on the Scanner Tester for proper operation of this switch. Refer to the figure titled AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters Table Switch. 28 CCD Scanner

().025 OVERTRAVEL (2) ADJUST CAM AND COLLAR SO SWITCH IS ACTUATED HIGH OF CAM AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters Table Switch ().025 OVERTRAVEL (2) ADJUST CAM AND COLLAR SO SWITCH IS ACTUATED HIGH OF CAM Sweep Switch Lower the sweep with the hand crank and position it 0" from the no. pin spot. Adjust the cam and collar assembly so the switch is actuated on the high of the cam. Check the 44 o signal at the Scanner Tester for proper operation of this switch. Refer to the figure titled AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters Sweep Switch. () ADJUST CAM AND COLLAR ASSEMBLY SO SWITCH IS ACTUATED BY HIGH OF CAM AMF 82-70, 82-70 SS, and 82-70 MP Pinspotters Sweep Switch () ADJUST CAM AND COLLAR ASSEMBLY SO SWITCH IS ACTUATED BY HIGH OF CAM CCD Scanner 29

AMF Interface PCBs There are two versions of the AMF Interface PCB. One version contains jumper wires that allow for interfacing with the proper pinspotter. The other version contains a switch assembly to allow for proper interfacing. Refer to the figures titled AMF 82-30 Pinspotter Interface PCB, AMF 82-70 Pinspotter Interface PCB, AMF 82-70 SS Pinspotter Interface PCB, and A/ P Relay PCB, (AMF Third, Ball Tenth Frame PCB.) The purpose of the AMF Interface PCB is to adapt the AMF electrical signals so that they can be used by the scanner. Although many signals are routed through the PCB, only the foul signal is actually altered. 30 CCD Scanner

() GROUND AMF LANE (2) POWER DC LANE (3) POWER AC LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER AC LANE 2 (7) POWER DC LANE 2 (8) GROUND AMF LANE 2 2 9 3 4 5 6 7 8 2 3 4 5 6 0 7 8 2 3 4 5 6 7 8 9 D2-IN4003 SW SW SW SW.5K IN94 IN94 IN94 20 WATT 20 WATT MCT-2 MCT-2 5 5 3 3uf 3 3uf 4 2 2 4.5K IN94 SW SW D5-IN4003 SW SW P25 9 8 7 2 ORN 0 VAC 0 VAC 6 5 P23 YEL 4 3 POWER +2 VAC 2ND SWEEP UP SWEEP AC P 4 5 VAC P 5 P 2 5 VAC FOUL P 3 O N 2 3 4 5 6 7 8 (9) SWITCH POSITIS FOR 8230 AMF 82-30 Pinspotter Interface PCB (20) JUMPER WIRE (20) JUMPER WIRE (2) TO EVEN LANE PINSPOTTER 9 (22) TO SCANNER 8 (23) FACTORY INSTALLED JUMPER WIRES (20) (20) JUMPER WIRE (25) JUMPER WIRE POSITI OF DIP SWITCH IF PRESENT 9 (24) TO ODD LANE PINSPOTTER 9 8 7 6 5 4 3 2 P25 ORN 0 VAC 0 VAC YEL WHT P23 POWER TABLE 2ND N.O. COMM N.C. (26) CHASSIS CAM SWITCH AC P 4 5 VAC P 5 P 2 5 VAC FOUL P 3 +2 VAC () GROUND AMF LANE (2) POWER DIRECT CURRENT LANE (3) POWER ALTERNATING CURRENT LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER ALTERNATING CURRENT LANE 2 (7) POWER DIRECT CURRENT LANE 2 (8) GROUND AMF LANE 2 (9) SWITCH POSITIS FOR 82-30 (20) JUMPER WIRE (2) TO EVEN LANE PINSPOTTER (22) TO SCANNER (23) FACTORY INSTALLED JUMPER WIRES (24) TO ODD LANE PINSPOTTER (25) POSITI OF DIP SWITCH IF PRESENT (26) CHASSIS CAM SWITCH CCD Scanner 3

() GROUND AMF LANE (2) POWER DC LANE (3) POWER AC LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER AC LANE 2 (7) POWER DC LANE 2 (8) GROUND AMF LANE 2 2 9 3 4 5 6 7 8 2 3 4 5 6 0 7 8 D2-IN4003 SW IN94 20 WATT IN94 20 WATT SW D5-IN4003 9 TO BRN POWER PIN 9 0 VAC 5 VAC 5 VAC TS-4 TS-8 2 3 4 5 6 7 8 9 SW SW SW.5K IN94 MCT-2 MCT-2 5 5 3 3uf 3 3uf 4 2 2 4 IN94.5K SW SW SW 8 7 6 5 4 3 2 P27 ORN P24 P22 YEL WHT 2 VAC FOUL 2 VAC 2ND SWEEP UP SWEEP (20) JUMPER WIRES (2) TO SCANNER 8 (22) FACTORY INSTALLED JUMPER WIRES (20) JUMPER WIRES O N TABLE (9) TO EVEN LANE PINSPOTTER 9 9 2 3 4 5 6 7 8 (23) POSITI OF DIP SWITCH IF PRESENT (24) TO ODD LANE PINSPOTTER (25) SWITCH POSITIS FOR 8270 AMF 82-70 Pinspotter Interface PCB () GROUND AMF LANE (2) POWER DIRECT CURRENT LANE (3) POWER ALTERNATING CURRENT LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER ALTERNATING CURRENT LANE 2 (7) POWER DIRECT CURRENT LANE 2 (8) GROUND AMF LANE 2 (9) TO EVEN LANE PINSPOTTER (20) JUMPER WIRES (2) TO SCANNER (22) FACTORY INSTALLED JUMPER WIRES (23) POSITI OF DIP SWITCH IF PRESENT (24) TO ODD LANE PINSPOTTER (25) SWITCH POSITIS FOR 82-70 32 CCD Scanner

() GROUND AMF LANE (2) POWER DC LANE (3) POWER AC LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER AC LANE 2 (7) POWER DC LANE 2 (8) GROUND AMF LANE 2 2 9 3 4 5 6 7 8 2 3 4 5 6 0 7 8 9 IN94 20 WATT IN94 20 WATT D2-IN4003 SW SW D5-IN4003 SW SW SW SW.5K.5K 5 5 2 8 SW SW IN94 3 3uf 3 3uf IN94 3 4 2 7 2 4 4 6 5 5 6 4 7 3 8 2 9 MCT-2 MCT-2 +2 VOC POWER P29 ORN +2 VOC P27 FOUL P25 YEL +2 VOC WHT 2ND SWEEP UP SWEEP (9) JUMPER WIRE (9) JUMPER WIRE (20) TO EVEN LANE PINSPOTTER (2) TO SCANNER AMF 82-70 SS Pinspotter Interface PCB 9 8 (22) FACTORY INSTALLED JUMPER WIRES (23) POSITI OF DIP SWITCH IF PRESENT 9 (9) JUMPER WIRE (9) JUMPER WIRE (24) TO ODD LANE PINSPOTTER O 2 3 4 5 6 7 8 N (25) SWITCH POSITIS FOR 8270-SS TABLE () GROUND AMF LANE (2) POWER DIRECT CURRENT LANE (3) POWER ALTERNATING CURRENT LANE (4) POWER LANE (5) FOUL LANE (6) GROUND SCORER LANE (7) SECD LANE (8) SWEEP UP LANE (9) TABLE/SWEEP LANE (0) TABLE/SWEEP LANE 2 () SWEEP UP LANE 2 (2) SECD LANE 2 (3) GROUND SCORER LANE 2 (4) FOUL LANE 2 (5) POWER LANE 2 (6) POWER ALTERNATING CURRENT LANE 2 (7) POWER DIRECT CURRENT LANE 2 (8) GROUND AMF LANE 2 (9) JUMPER WIRE (20) TO EVEN LANE PINSPOTTER (2) TO SCANNER (22) FACTORY INSTALLED JUMPER WIRES (23) POSITI OF DIP SWITCH IF PRESENT (24) TO ODD LANE PINSPOTTER (25) SWITCH POSITI FOR 82-70 SS CCD Scanner 33

AMF Third Ball, Tenth Frame/No Tap Relay The AMF Third Ball, Tenth Frame/No Tap Kit which consists of an A/P Relay PCB, can be installed with new or existing AS-K, AS-90, AS-90C, or Frameworx Automatic Scorers with CCD Scanners (Version.34 or higher) and AMF 82-30, 82-70, 82-70 SS, or 82-70 MP Pinspotters. Refer to the figure titled AMF Reset Kit Relay PCB. AMF Reset Kit Relay PCB () TO CCD PROCESSOR (2) TO PINSETTER (3) SIGNAL LIGHT-EMITTING DIODE The kit eliminated the need for the bowler to press the Reset button after he throws his bonus ball in the tenth frame and during No Tap scoring if no N T X occurs. The kit is controlled by the CCD Data Processor PCB. AMF 82-30 Pinspotter When installed on the AMF 82-30 Pinspotter, the kit is activated when a bowler bowls his bonus ball and does not get a strike or he bowls a N X T during No Tap Scoring. The kit causes the pinspotter to cycle a second time so that any standing pins are swept off the pin deck and the machines sets a full rack, first ball for the next bowler. AMF 82-70 and 82-70 SS Pinspotters On an AMF 82-70 Pinspotter with CCD Software Version.32 or.33, the kit actuates after the bowler throws his second ball in the tenth frame. At the end of a pinspotter cycle in which the bowler receives a spare or a double, the kit will cause the pinspotter to switch to second ball. As a result, the bowler will shoot at a full rack, second ball for his bonus ball. With CCD Software Version.35, the kit is rewired to the Reset button so the pinsetter cycles automatically for the next bowler. (Refer to AMF 82-30 Pinspotter for description.) 34 CCD Scanner

The functions of the A/P Relay PCB components are: () CCD Processor (J) - Connection to the CCD Data Processor PCB. The signal to energize the relay on the A/P Relay PCB enters the PCB here at a level of 5VDC. (2) Pinsetter (T, T2) - Connections to the following pinspotter switches in the rear mechanic's switch box: AMF 82-30 PBC Cycle Switch * AMF 82-70 PB2B Second Ball Switch * AMF 82-70SS PB2-st First Ball Stepper Switch ** AMF 82-70 Mechanic's Cycle Switch ** AMF 82-70SS Mechanic's Cycle Switch * Connection for third ball, tenth frame with version.3 or.32 CCD software. ** Connection for third ball, tenth frame and No Tap cycling with version.35 or later CCD software. (3) Signal LED - Lights to indicate the 5VDC signal from the CCD Processor is being received. CCD Scanner 35

Brunswick A-2 Pinsetter Scoring Sequence of Events First Ball NOTE: The scorer console must be turned on, with a bowler's name entered and the sequencing arrows on the bowler's name.. The bowler delivers the first ball. The ball breaks the ball detect light path and sends a signal to the Scanner Data Processor PCB. 2. The scanner takes a picture for the lane. Refer to the figure titled First Ball Scoring Sequence-Brunswick A-2. 3. The pinsetter triggers. 4. At 44 o, the switch signal enables the Scanner Data Processor PCB to accept the pinfall information. 5. With a successful take data, the scanner sends the score to the LGP. 6. The score is displayed. 7. 44 switch signal occurs but no action is taken. 8. 0 switch closes causing the scoring cycle to reset and enable another ball detect. First Ball Scoring Sequence - Brunswick A-2 () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (PICTURE TAKEN) (4) 44 PULSE (5) TAKE DATA (PICTURE TAKEN) (6) SCORE (7) 44 PULSE (NO ACTI) (8) RESETS SCORING CYCLE (9) 0 PULSE/360 (0) FIRST BALL 36 CCD Scanner

Second Ball. The bowler delivers the second ball. The ball breaks the ball detect's path of light. Refer to the figure titled Second Ball Scoring Sequence - Brunswick A-2. 2. The scanner starts the scoring process. 3. The pinsetter triggers. 4. At 44 o, the switch signal enables the Scanner Data Processor PCB to accept the pinfall data. 5. With the successful take data, the scanner sends the score to the LGP. 6. A score is displayed for the bowler. 7. The 0 o switch sends a signal to reset the scoring cycle and enable another ball detect. Second Ball Scoring Sequence - Brunswick A-2 () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) 44 PULSE (NO ACTI) (5) 44 PULSE (6) TAKE DATA (7) SCORE (8) RESETS SCORING CYCLE (9) 0 PULSE/360 (0) SECD BALL CCD Scanner 37

First Ball Foul On a first ball foul, the New Pins Solenoid switches the detector to second ball. On a first ball foul, when the New Pins Solenoid switches the detector to the second ball, the cycle link and crank generates a strike in the detector. It then blocks the scissors and prevents the pinsetter from picking up the standing pins.. Bowler delivers his first ball and fouls. 2. The ball breaks the ball detect's light path and triggers the pinsetter. Refer to the figure titled First Ball Foul - Brunswick A-2. 3. The New Pins Solenoid switches the pinsetter to the second ball at 44 o, selecting a strike cycle. 4. The scorer displays an "F" and scores a "0." 5. 44 switch closes, but no action is taken. 6. The pinsetter sweeps the pins and sets a new rack of pins. 7. The New Pins Solenoid switches the pinsetter to second ball when the 0 switch closes. 8. The 0 signal resets the scoring cycle to accept another ball detect. 7. The 0 signal resets the scoring cycle to accept another ball detect. First Ball Foul - Brunswick A-2 () FOUL (2) BALL DETECT (3) PINSETTER TRIGGERS (4) NEW PINS SOLENOID SELECTS (5) SCORER DISPLAYS FOUL AND SCORES 0 (6) SCISSORS BLOCKED STRIKE (7) SWITCHES TO FIRST BALL AND (8) SETS A NEW RACK OF PINS (9) NEW PINS SOLENOID SWITCHES SWEEPS STANDING PINS PINSETTER BACK TO SECD BALL (0) RESETS SCORING CYCLE () 0 PULSE/360 (2) 44 PULSE (3) 44 PULSE (NO ACTI) (4) FIRST BALL FOUL 38 CCD Scanner

Third Ball, Tenth Frame When a bowler scores either a spare or double in the tenth frame, the LGP sends a signal to the Scanner Data Processor PCB to place the pinsetter in second ball. This eliminates the need for the bowler to press reset after bowling the third ball (if standing pins are left.). The scoring sequence for a spare or first ball (double) occurs normally. 2. 44º Pulse (scores double). 3. 44º Pulse (scores spare). 4. 0 switch closes causing the new pins solenoid to switch the pinsetter to 2nd ball. In addition to scoring functions, the 0 signal at 360 causes the New Pins Solenoid to place the pinsetter in second ball. 5. 0 resets the scoring cycle to accept another ball detect. Third Ball, Tenth Frame - Brunswick A-2 () BALL DETECT (2) PINSETTER TRIGGER (3) SCORES DOUBLE OR SPARE NORMALLY (4) NEW PINS SOLENOID SWITCHES PINSETTER (5) O PULSE - 360 (6) 44 PULSE (SCORES DOUBLE) TO SECD BALL (7) 44 PULSE (SCORES SPARE) (8) THIRD BALL TENTH FRAME (9) SCORING CYCLE RESETS CCD Scanner 39

No Tap Cycling When a bowler bowls a No Tap strike, the scorer console sends a signal to the CCD Data Processor PCB. In turn, the Processor energizes the New Pins Solenoid at 44 so the standing pins are swept away.. Bowler delivers his first ball and the ball breaks the ball detect's light path. 2. The ball causes the pinsetter to trigger. Refer to the figure titled No Tap - Brunswick A-2. 3. The 44 switch closes causing the new pin solenoid to switch the pinsetter to the second ball. 4. The scorer displays an " N T X." 5. 44 switch closes, but no action is taken. 6. The pinsetter sweeps the pins and sets a new rack of pins. 7. The 0 signal resets the scoring cycle to accept another ball detect. No Tap - Brunswick A-2 () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) NEW PINS SOLENOID SELECTS STRIKE (5) SCORER DISPLAYS NT AND X SCO (6) SCISSORS BLOCKED (7) SWITCHES TO FIRST BALL AND SWEEPS (8) SETS A NEW RACK OF PINS (9) RESETS SCORING CYCLE STANDING PINS (0) 0 PULSE/360 () 44 PULSE (2) NO TAP (3) 44 PULSE (NO ACTI) 40 CCD Scanner

Brunswick GS-0/GS-92 Pinsetter Scoring Sequence of Events First Ball The following describes the events necessary for the first ball scoring sequence. NOTE: The scorer console must be turned on, the bowler's name entered, and the Bowl key pressed with the sequencing arrows on the bowler's name.. The bowler delivers the first ball. The ball breaks the ball detect's light path and sends a signal to the Scanner Data Processor PCB. 2. The scanner starts sweeping both lanes. Refer to the figure titled First Ball Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter. 3. The pinsetter is triggered by the ball. 4. When the table is 6" (406 mm) above the pin deck, the table switch signal enables the Scanner Data Processor PCB to accept the pinfall information. 5. The scanner stops when the table switch is actuated with a successful take data. 6. Score is displayed on CRTs. 7. The sweep up switch resets the scoring cycle to accept another ball detect. First Ball Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter. () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) TAKE DATA (5) SCORE (6) RESETS SCORING CYCLE (7) TABLE PULSE (8) SECD TABLE PULSE (NO ACTI) (9) SWEEP PULSE (NO ACTI) (0) 0 PULSE (SWEEP UP)/360 () FIRST BALL CCD Scanner 4

Second Ball. The bowler delivers their second ball. The ball breaks the ball detect's light path and sends a signal to the Scanner Data Processor PCB. 2. The scanner starts sweeping both lanes. Refer to the figure titled Second Ball Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter. 3. The pinsetter is triggered by the ball. 4. When the sweep switch is enabled, the Scanner Data Processor PCB accepts the pinfall information. 5. The scanner stops with a successful take data. 6. Score is displayed on CRTs. 7. The sweep up switch resets the scoring cycle to accept another ball detect. Second Ball Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) TAKE DATA (5) SCORE (6) RESETS SCORING CYCLE (7) TABLE PULSE (NO ACTI) (8) 0 PULSE (SWEEP UP)/360 (9) SECD BALL (0) SWEEP PULSE 42 CCD Scanner

First Ball Foul On first ball foul, the data is transmitted to the Scanner's Data Processor. At take data (44 o ), the scorer displays an F and scores a 0. The normal foul cycle of the pinspotter sets a new full set of pins for the second ball cycle.. The bowler delivers the first ball and fouls. 2. The ball breaks the ball detect's light path. Refer to the figure titled First Ball Foul Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter. 3. Scorer displays an F and scores a 0 at take data. 4. Pinspotter cycles, sweeps pins, and returns to 0 o. NOTE: A new rack of pins will be set only on GS-0/GS-92 Pinsetters equipped with a foul cycle function. The scorer console does not control the pinsetter. First Ball Foul Scoring Sequence - Brunswick GS-0/GS-92 Pinsetter () FOUL (2) BALL DETECT (3) PINSETTER TRIGGER (4) DISPLAYS FOUL (TAKE DATA) (5) SWEEP UP SWITCH CLOSES (6) SWEEP PULSE (NO ACTI) (7) 0 PULSE (SWEEP UP) 360 (8) FIRST BALL FOUL CCD Scanner 43

AMF Pinspotter Scoring Sequence of Events First Ball All Models The following describes the events necessary for the first ball scoring sequence. NOTE: The scorer console must be turned on, the bowler's name entered, and the Bowl key pressed with the sequencing arrows on the bowler's name.. The bowler delivers the first ball. The ball breaks the ball detect's light path and sends a signal to the Scanner Data Processor PCB. 2. The scanner starts the scoring process. Refer to the figure titled First Ball Scoring Sequence - AMF (All Models). 3. The pinsetter is triggered by the ball. 4. When the table is 6" (406 mm) above the pin deck, the cam switch or table switch signal enables the Scanner Data Processor PCB to accept the pinfall information. 5. With a successful take data, the scanner sends the score to the LGP. 6. Score is displayed on CRTs. 7. The sweep switch and table switch close, but no action is taken. 8. The sweep up switch resets the scoring cycle to accept another ball detect. First Ball Scoring Sequence - AMF (All Models) () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) TAKE DATA (5) SCORE (6) RESET SCORING CYCLE (7) TABLE PULSE (8) SECD TABLE PULSE (NO ACTI) (9) SWEEP PULSE (NO ACTI) (0) 0 PULSE (SWEEP UP)/360 () FIRST BALL 44 CCD Scanner

Second Ball All Models. The bowler delivers their second ball. The ball breaks the ball detect's light path and sends a signal to the Data Processor PCB. 2. The scanner starts the scoring process. Refer to the figure titled Second Ball Scoring Sequence - AMF (All Models). 3. The pinsetter is triggered by the ball. 4. When the cam switch or sweep switch is enabled, the Data Processor PCB accepts the pinfall information. 5. With a successful take data, the scanner sends a score to the LGP. 6. Score is displayed on CRTs. 7. The table switch closes, but no action is taken. 8. The sweep up switch resets the scoring cycle to accept another ball detect. Second Ball Scoring Sequence - AMF (All Models) () BALL DETECT (2) SCANNER STARTS SCORING PROCESS (3) PINSETTER TRIGGERS (4) TAKE DATA (5) SCORE (6) RESETS SCORING CYCLE (7) TABLE PULSE (NO ACTI) (8) 0 PULSE (SWEEP UP) 360 (9) SECD BALL CCD Scanner 45