Difference between revisions of "General"
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Pinball Machine Fuse Table Some games may have different fuses and quantities
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:Some players will adjust the pitch outside of "Factory" settings, to suit their taste or playing style. After playing a game for a while on the "Standard" settings, you may wish to experiment with different pitches. | :Some players will adjust the pitch outside of "Factory" settings, to suit their taste or playing style. After playing a game for a while on the "Standard" settings, you may wish to experiment with different pitches. | ||
| + | |||
| + | '''Tweaking a pop bumper''' | ||
| + | :Pop bumpers should be adjusted so the slightest touch of a ball at any point causes them to activate, but not be so sensitive that vibration causes them to activate. Clean the spoon switch actuator very well, if it's plastic you can use novus to polish it. If it's metal some 2000 grit sandpaper will polish it nicely. On solid state or EM machines with high voltage points you should file the switches clean and flat. On machines with gold flashed contacts inspect them well and clean with brasso, alcohol, or a business card wiped between the points. | ||
| + | |||
| + | :Adjust the position of the spoon switch underneath the skirt's actuator so that the pin sits naturally in the center of the spoon switch. The spoon switch bracket has oblong mounting holes for exactly this purpose. Once it's positioned in the center, tighten the switch bracket mounting screws. Now, using a contact adjuster tool, adjust either the spoon blade itself (for metal ones) or the blade that provides the tension to the plastic spoon so that there's barely tension on the actuation pin. (The softer this adjustment, the more sensitive the pop bumper will be.) You want enough force so that the spoon re-centers the pin, but not so much that anything other than a hard ball hit activates the bumper. With the playfield raised you can activate the pop skirt by hand to see how much to adjust the spoon. It takes several tries to get this right but it's well worth taking the time to do this. | ||
| + | |||
| + | :Adjust the second blade to between 1/16"-1/8" gap between the contacts of the first blade. This will vary depending on if the machine uses high voltage activation of pop bumpers or not. You want the gap close enough so the pop is sensitive, but not so close that other mechanisms in the machine activate the pop. A good way to test this is to adjust the switch, then with the playfield lowered, make a fist and pound on the playfield in the area of the pops. | ||
| + | |||
| + | :Some machines that use direct activation of pops might benefit from wiring in a gottlieb pop bumper driver board. This applies mostly to gottlieb system 1 solid state machines, but could also be used on some early williams games as well as specialized purposes on other games. Basically, high voltage activated switches can pit and arc; generally, they require a slightly larger gap to ensure the contacts do not weld together from the arcing. Using a pop bumper driver board on this type of bumper with the actuation contacts changed to gold flashed type allow a closer switch gap, and the board provides a solid activation regardless of how hard the skirt was hit. | ||
| + | |||
| + | :A specialized purpose for a pop bumper driver board would be on a Stern 9 Ball, for the lone pop at the top. Bally/Stern machines do not have the ability to fire more than one momentary solenoid simultaneously; this comes into heavy play on 9 ball as the drop banks reset and drop their targets. It is possible for the top pop to not fire while this resetting is going on, especially if the game is set to require both 3 bank drops to reset to advance the bonus multiplier. The scenario is this: You drop both banks and the ball hits the pop.... with a thud. You receive score for the hit, but the pop doesn't fire because the 2 3 bank drop targets are still resetting. Changing the pop to activate with a pop bumper driver board removes the hardware limitation from the equation, as the pop is able to activate on it's own; the mpu still scores the pop as a secondary switch gets added similar to Gottlieb system 1 games or early williams games. | ||
| + | |||
| + | '''Tuning a spinner''' | ||
Revision as of 07:59, 16 May 2011
1 The Switch Matrix
Discuss general switch matrix operation here
Under MPU control
For each Strobe Line strobe the line listen for "returns" Next Strobe Line Repeat forever
2 The Lamp Matrix
Discuss general lamp matrix operation here
Under MPU control
For a particular lamp column Enable returns on the appropriate rows Strobe the column Next lamp column
3 How are coils driven?
Discuss "finding ground" via a controlled transistor to turn on a coil.
Every coil will have power "waiting at the ready" at the coils lugs. All that is required is for the ground lug of coil to find a path to ground. This is accomplished by "turning on" a transistor.
4 Flippers
- How does a flipper work?
- Flippers have two coil windings, one is a high powered, low resistance winding, used for the power stroke (initial "flip"). The other is used to keep the flipper held up, when you are holding the flipper to trap a ball. There needs to be a mechanism to switch from the high powered side to the low powered side. The high powered side of the coil is almost a dead short, and anything other than a momentary activation would cause the fuse to blow.
- High Voltage flipper operation
- The original flipper operation was completely high voltage, requiring tungsten point contacts at the flipper switches and at the normally closed end of stroke switches. These switches need to be filed periodically and gapped correctly for proper operation. A maladjusted end of stroke switch can burn out a coil or a fuse as well as damage the plastic bobbin the coil is wrapped around, making for sluggish operation. Tarnished and burnt contacts at any point in the system can cause a weak flipper power stroke, making for diminished game play. Additionally, there are contacts on a machine's flipper relay that may need to be cleaned to provide the maximum power to the flippers. Connectors and header pins can also play a factor in a flipper's power; heavily tarnished connections will degrade performance.
- When you press a flipper button, you are actually grounding the flipper circuit, not providing the power. The power is already present at the coil's input lug. The power flows from the power supply to the flipper coil in the most direct path possible. The input lug has the solenoid power present, one wire going to one blade of the end of stroke switch, and one end of the hold winding. One end of the high powered coil's winding is attached to the other blade of the end of stroke switch.
- The flipper button has one contact attached to the terminus of both flipper coil windings; the other contact is attached to ground via the flipper relay. When the flipper relay is pulled in a ground path exists for the flipper, when it is deactivated (in game over/tilt modes) there is no ground path for the flippers. When you push the flipper button, the power travels through the end of stroke switch, the high powered coil, through the flipper cabinet switch and the relay to ground, pulling the flipper in with great force.
- A small arm on the pivot point of the flipper presses against the end of stroke switch outer blade, moving it away from the inner blade. This cuts the high power to the stroke side of the coil. Because the hold coil still is getting power via the input lug, the flipper will stay in an up position as long as you hold the button in. The hold coil has much greater resistance and so does not blow the fuse or create a short circuit.
- Solid State Flipper operation
- Solid state flippers do not refer to flippers in any solid state machine; rather, they refer to a design in later machines (post 1989) to eliminate the traditional high powered tungsten contacted type of flipper, which was subject to degradation over time. Less maintenance is required for solid state flippers.
- There are a few different designs to eliminate the high power switches used with flippers. One circuit monitors the time the flipper is held in; anything over 50-100 milliseconds continuous activation switches the power to the low side of the coil from the upper side electronically. Some designs of this nature also have a low powered normally open end of stroke switch, so that the flipper feels more like a traditional flipper. The time function of the solid state circuit only comes into play if the end of stroke switch is never detected, switching the power to the hold coil. Williams Fliptronics(tm) flippers operate in this fashion.
- Another design monitors the end of stroke switch/time and pulses the power supply to the flipper to reduce the voltage during the hold cycle. This allows a cheaper coil to be used as there is only one winding on the coil. Examples of this type of PVM flipper are late model Stern games. Sometimes the pulsing of the voltage causes the flipper to buzz slightly.
5 Lamp Chart
| Lamp | Voltage (V) | Current(A) | Candle Power | Life (hours) | Base | Typical Use |
|---|---|---|---|---|---|---|
| 44 | 6.3 | 0.25 | 0.9 | 3,000 | Miniature Bayonet (BA9) | Common GI bulb |
| 47 | 6.3 | 0.15 | 0.5 | 3,000 | Miniature Bayonet (BA9) | A low-power version of the #44; reduced heat and candle power |
| 55 | 7.0 | .41 | 2.00 | 500 | Miniature Bayonet (BA9) | Used on some EM games, high current, heat and candle power compared to #44 and #47 |
| 67 | 13.5 | .59 | 4.0 | 5,000 | S.C. Bayonet (BA15s) | F-14 Tomcat Flash Lamps |
| 73 | 14.0 | .80 | .30 | 15,000 | Wedge (T 1-3/4) | A low-power alternative for the 86 used in Twilight Zone's clock mechanism |
| 86 | 6.3 | .20 | .40 | 15,000 | Wedge (T 1-3/4) | Small lamp used in Creature from the Black Lagoon ramps and Twilight Zone's clock mechanism |
| 89 | 13.0 | .58 | 6.00 | 750 | S.C. Bayonet (BA15s) | Flash Lamps on many Sys11/DE/WPC |
| 194 | 14.0 | .27 | 2.00 | 1,500 | Wedge | Whitewater Topper Lamps |
| 199 | 12.8 | 2.25 | 32.00 | 1500 | S.C. Bayonet (BA15s) | HS2 Getaway Topper Lamp, CFTBL Hologram Lamp |
| 251 | 28.0 | .23 | 3.00 | 2,000 | S.C. Bayonet (BA15s) | Pin-Bot and Cyclone Flash Lamps |
| 313 | 28 | 0.17 | 3.5 | 500 | Miniature Bayonet (BA9) | Used for lower playfield illumination on Black Hole and Haunted House |
| 447 | 6.3 | 0.15 | 0.5 | 3,000 | Wedge | A low-power version of the 555; reduced heat and candle power |
| 455 | 6.5 | 0.5 | N/A | 500 | Miniature Bayonet (BA9) | Blinker |
| 545 | 6.5 | 0.31 | N/A | 500 | Wedge | Blinker - used in Twilight Zone, Dirty Harry, No Good Gofers |
| 555 | 6.3 | 0.25 | 0.9 | 3,000 | Wedge | Common GI bulb |
| 906 | 13.0 | .69 | 6.00 | 1000 | T-5 Wedge | Flash Lamp |
| 1683 | 28.0 | 1.02 | 32.00 | 500 | S.C. Bayonet (BA15s) | High Speed Topper Lamp |
Notes:
- A "blinker" is a lamp with an internal thermal switch (a bi-metallic strip) that interrupts power to the lamp causing it to blink on and off; the cycle is usually a few seconds. These are often used behind the title on EM games. A "flash lamp" is a lamp that is purposely over-driven for a brief instant (milliseconds) to produce an extremely bright flash of light. These are used to draw attention to game features such as bonuses.
- 47 lamp is often used as a replacement for 44 lamps where heat is a concern for backglass or plastics.
- 447 lamp serves the same purpose replacement for 555 lamps.
- Candlepower is measured in Mean Spherical Candlepower (MSCP)
- T-3 1/4 refers shape and size, for example T-3 1/4 is "tubular", 3.25 8ths of an inch in diameter
Detailed specifications on lamps is available at http://www.donsbulbs.com . Just enter the lamp number in the "Bulb Search" field.
6 Lamp Sockets
7 Fuse Table
| Qty | Bally EM | Qty | Gottlieb EM | Qty | Williams EM | |||
| 2 | 5A | BR, DC coils | 2 | 2A SB | Drop target bank | 6 | 10A | Main, BR, coils |
| 2 | 8A | Main line fuse | 2 | 5A SB | Main line fuse | 6 | 15A | Lamps, coils |
| 4 | 10A | Coils | 4 | 10A | Lamps | |||
| 4 | 15A | Lamps | 4 | 15A | Coils | |||
| Qty | Atari | Qty | Bally/Stern (1977-1984) | Qty | Gottlieb Solid-State | |||
| 2 | 1A SB | Power supply | 3 | 1A SB | Coils-under PF | 2 | 1/4A SB | Displays |
| 1 | 2A SB | Service outlet | 1 | 3A SB | Main line power | 1 | 1A SB | Coils |
| 1 | 5A SB | Main power | 1 | 3/16A | High Voltage on SDB | 2 | 2A SB | Drop target bank |
| 2 | 7A SB | Power supply | 1 | 3/4A | Display power supply | 4 | 5A SB | Main, coils, lamps |
| 2 | 10A SB | Power supply | 1 | 4A | 12v/5v power supply | 2 | 8A | Lamps |
| 4 | 15A SB | PS, lamps, displays | 3 | 5A | Coils | 1 | 10A | Lamps |
| 2 | 15A | General Illumination | ||||||
| 1 | 20A | Switched Lamps | ||||||
| Qty | Williams L3-L7 (1977-1984) | Qty | Williams System 9-11 (1985-1990) | Qty | Williams WPC (1990-1994) | |||
| 1 | 1/4A SB | Display high voltage | 1 | 1/4A SB | Power supply (displays) | 1 | 3/8A SB | Display driver board |
| 3 | 2-1/2A SB | Coils | 5 | 2A SB | Aux board | 4 | 3A SB | Coils, flippers |
| 2 | 4A SB | Sound board | 2 | 2-1/2A SB | Coils | 3 | 5A SB | Power supply, lamps |
| 2 | 7A SB | 5v power (L7 games) | 2 | 4A SB | Coils, flippers | 1 | 7A SB | Power supply |
| 2 | 8A | Main, switched lamps | 6 | 5A SB | Flpr, aux, cab, lamps | 1 | 3/4A | 12v power supply |
| 2 | 20A | General illumination | 2 | 7A SB | Power supply | 2 | 8A | Main, switched lamps |
| 2 | 1/10A | Cabinet, displays | ||||||
| 1 | 3/4A | 12v power supply | ||||||
| 2 | 8A | Main, switched lamps | ||||||
| Qty | Data East | Qty | Sega & New Stern | Qty | Williams WPC-95 (1995-1999) | |||
| 3 | 3A SB | Coils, flippers | 1 | 3/4A SB | Display | 2 | T0.315A SB | Display |
| 2 | 4A SB | Coils | 4 | 3A SB | Coils, flippers | 1 | T0.63A SB | 12v PS F101 |
| 4 | 5A SB | Lamps, power supply | 1 | 4A SB | Power supply | 5 | T4.0A SB | Cls,5/12v,lmps,flsh,flpr,ln |
| 2 | 7A SB | Power supply | 4 | 5A SB | Coils, lamps | 1 | T5.0A SB | Switched lamps, line |
| 1 | 8A SB | Line, power supply | 1 | 7A SB | Coils | 1 | T6.3A SB | Coils main F108 |
| 1 | 8A SB | Power line, lamps | 2 | T2.5A | Audio F501, F502 | |||
8 Tuning a Game for Best Performance
Leveling the Game
- One of the most important things you can do to tune a game is make sure the playfield is level side to side. Some games contain a bubble level on the apron to check side to side leveling. Do to differing floor conditions, any time a game is moved, the level should be checked. Use an inclinometer or small torpedo level to check the side to side level. Check the level on the playfield itself, NOT on the playfield glass. The playfield may not sit level in the cabinet, or may be warped. Check the the level at several points on the upper and lower playfield. Adjust using the leg levelers. After your done, make sure you tighten the locknuts on the levelers.
Adjusting the Game Pitch
- The pitch of the game drastically affects game play. A steeper game plays faster. Too steep can tax the flippers ability to make ramp shots. Too shallow, slows the game down. Too shallow also can allow the ball to be redirected more by playfield irregularities, such as warped inserts. Again, do to differing floor conditions, any time a game is moved, the pitch should be checked. The proper pitch of a given game may be indicated in the manual. In the case of games which include a bubble level for pitch, the manufacturers recommendations may be marked on the level. In the case where a recommended pitch is not indicated, the generally accepted "Rule of Thumb" is 3 1/2 degrees for EM games and 6 1/2 to 7 degrees for Solid State Games. Use an inclinometer, again on the playfield itself NOT the playfield glass, to measure pitch. Adjust using the leg levelers. After your done leveling, make sure you tighten the locknuts on the levelers.
- Some players will adjust the pitch outside of "Factory" settings, to suit their taste or playing style. After playing a game for a while on the "Standard" settings, you may wish to experiment with different pitches.
Tweaking a pop bumper
- Pop bumpers should be adjusted so the slightest touch of a ball at any point causes them to activate, but not be so sensitive that vibration causes them to activate. Clean the spoon switch actuator very well, if it's plastic you can use novus to polish it. If it's metal some 2000 grit sandpaper will polish it nicely. On solid state or EM machines with high voltage points you should file the switches clean and flat. On machines with gold flashed contacts inspect them well and clean with brasso, alcohol, or a business card wiped between the points.
- Adjust the position of the spoon switch underneath the skirt's actuator so that the pin sits naturally in the center of the spoon switch. The spoon switch bracket has oblong mounting holes for exactly this purpose. Once it's positioned in the center, tighten the switch bracket mounting screws. Now, using a contact adjuster tool, adjust either the spoon blade itself (for metal ones) or the blade that provides the tension to the plastic spoon so that there's barely tension on the actuation pin. (The softer this adjustment, the more sensitive the pop bumper will be.) You want enough force so that the spoon re-centers the pin, but not so much that anything other than a hard ball hit activates the bumper. With the playfield raised you can activate the pop skirt by hand to see how much to adjust the spoon. It takes several tries to get this right but it's well worth taking the time to do this.
- Adjust the second blade to between 1/16"-1/8" gap between the contacts of the first blade. This will vary depending on if the machine uses high voltage activation of pop bumpers or not. You want the gap close enough so the pop is sensitive, but not so close that other mechanisms in the machine activate the pop. A good way to test this is to adjust the switch, then with the playfield lowered, make a fist and pound on the playfield in the area of the pops.
- Some machines that use direct activation of pops might benefit from wiring in a gottlieb pop bumper driver board. This applies mostly to gottlieb system 1 solid state machines, but could also be used on some early williams games as well as specialized purposes on other games. Basically, high voltage activated switches can pit and arc; generally, they require a slightly larger gap to ensure the contacts do not weld together from the arcing. Using a pop bumper driver board on this type of bumper with the actuation contacts changed to gold flashed type allow a closer switch gap, and the board provides a solid activation regardless of how hard the skirt was hit.
- A specialized purpose for a pop bumper driver board would be on a Stern 9 Ball, for the lone pop at the top. Bally/Stern machines do not have the ability to fire more than one momentary solenoid simultaneously; this comes into heavy play on 9 ball as the drop banks reset and drop their targets. It is possible for the top pop to not fire while this resetting is going on, especially if the game is set to require both 3 bank drops to reset to advance the bonus multiplier. The scenario is this: You drop both banks and the ball hits the pop.... with a thud. You receive score for the hit, but the pop doesn't fire because the 2 3 bank drop targets are still resetting. Changing the pop to activate with a pop bumper driver board removes the hardware limitation from the equation, as the pop is able to activate on it's own; the mpu still scores the pop as a secondary switch gets added similar to Gottlieb system 1 games or early williams games.
Tuning a spinner