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Construction

Revision as of 00:04, 21 January 2015 by Jwilson (talk | contribs)

Tools

Specialty Tools

These are tools that are specific to pinball.

Metalworking Tools

Tools-metal.jpg

  • A few different colored sharpies for marking cuts and bends
  • 4 1/2" angle grinder for cutting and grinding
  • Flap disc grinding pads of multiple grits
  • Metal cutting blades for a grinder
  • Safety glasses and gloves
  • A bunch of different size C-clamps - at least one large and two big enough to clamp large items
  • A Square
  • Measuring tape
  • Different sized ballpein hammers
  • Drill bits for steel
  • Center punch
  • Blow Torch - MAP Gas works best, Propane as a second choice


A Metal Brake is useful for bending sheet steel to make brackets.

Metal-brake.jpg

The above example is available from Harbor Freight.

If space is at a premium, there are smaller tabletop versions as well.

Home-brake.jpg

If cost is an issue, you can make your own from common hardware store parts.

Woodworking Tools

Beyond the standard hand tools needed to create a machine from scratch, here are some additional tools:

Router.png

A Hand Router for creating insert and device holes in the playfield.

Jigsaw.png

A Table Jigsaw for cutting playfield plastics, or plexi for your initial whitewood inserts.

Sander.png

A Hand Sander to level the playfield. You should also have sand paper in various grits ranging from 180 up to 320, plus finer grits for final polishing.

Forstner-bit.png]

Forstner bits for drilling clean holes. Easier than using the router.

Cabinet Tools

Table-router.png

For cabinet building, a table router with Locking Mitre bits.

Mitre-bit.png

It is a bit that creates a locking edge between cabinet corners.

Advanced Tools

Although not strictly needed for hobbyists, the following are nice-to-have if you have some deep pockets, and they make whitewood production much faster and far more consistent. Rather than purchasing these, the best option is to find a local Maker Space that has the equipment available for rent or through a monthly membership.

CNC

Cnc-router.png

A large-format CNC machine can take drawings from AutoCAD or Inkscape to cut a playfield exactly to the design, which will be much more accurate than one done by hand with a router.

Some reasonably-priced options include:


For smaller parts, there are much cheaper alternatives:

  • Shapeoko uses a standard hand router, like a Dremel, as the cutting tool, and is priced under $1K.

Laser Cutters

Laser-cutter.png

Using a laser cutter on plastics means fast prototyping of playfield plastics, and most cutters will also do engraving for interesting effects. Really high powered units will cut wood as well.

Some examples include Epilog and Universal.

A lower cost option is the Full Spectrum Laser.

Materials

A rundown of the various materials needed to produce a whitewood.

Plywood

Commercial pinball machines use a specially sourced type of plywood that is not available from big box stores and generally not even specialty wood suppliers.

The thickness of a raw playfield is 17/32", which is then sanded on top with inserts installed to a finished size of 1/2". Each side is a full face of hard Maple with five plys in-between, not a thin veneer to allow for this sanding. The following photo illustrates the full seven plys:

Plywood.png

The type of plywood available at a big box store will have a thin ply on both sides, generally of softer Baltic Birch, and will not have the surface area to allow a full 1/32" sanding to level the surface and inserts together.

For hobbyists, the best option is Cabinet Grade plywood, preferably from a lumber yard, with a minimum of seven plys but a preference for nine - the more plys, the more stable and flat. This type of plywood will have a thicker top and bottom ply suitable for sanding. It will generally be the softer birch but for one-off games, it should prove acceptable.

Cabinet-grade.png

Another affordable option for whitewoods is Medium Density Fibreboard. Typically sold as MDF, it is also available in large quantities. The drawback for MDF is that it has poor flexibility and does not allow for easy removal and re-installation of screwed in parts.

Sheetmetal

For ramps, ball guides and various other uses.

Sheet Steel at McMaster-Carr.

Sheet Steel including stainless at Grainger.

Inserts

For a whitewood, the easiest option is to use thin plexiglass for inserts as it is readily available and fairly easy to cut to size with a table jigsaw. This allows for skipping the final sanding stage if using 1/2" plywood instead of 17/32".

Real pinball inserts are available in various sizes and colors from a number of suppliers including Pinball Resource and Marco Specialities.

Some examples of the inserts available:

Inserts.png

1″ round green star #PI-1FGS

3/4″ round Orange #PI-34RO

5/8″ round White opaque #PI-58RW

1-1/2″ triangle Green #PI-112TGT

Rollover star button housing red 3A-7537 #C-901

Standard depth of inserts are 1/4" and they are designed to be sanded flat after installation - there will be a number cast into the top of the part and the top edge will be slightly raised around the radius by approximately 1/32". Thus, when creating insert holes, you must drill slightly less than 1/4" deep to allow for the sanding.

Playfield Parts

The best source of parts like switch targets, pop bumpers, posts and other miscellaneous bits is from parts machines - picking up a used machine with a worn playfield and just cleaning up those parts will be ten times cheaper than buying all new parts.

However, given the increasing value of even older solid-state machines, finding games to part out is becoming increasingly difficult, so the only option may be purchasing new.

Once a preliminary design is complete, the next step is to create an initial prototype, known in the industry as a Whitewood.

Whitewood

The origin of the term whitewood is related to the material of the playfield, which is traditionally White Maple. The first iteration of a game will not have any artwork or lighting as the purpose is to test the layout, flipper shots and the overall feel of the design to confirm it plays as expected.

The second iteration of the whitewood - generally a different playfield rather than the existing one re-cut - will include inserts, lighting and any ramps or playfield devices needed for the complete game. This version of the prototype is used to create the first iteration of the ruleset and special effects.

Here is an unpopulated whitewood for Cirqus Voltaire, which is a later iteration that does have inserts for lighting, but not yet having artwork.

Cv-whitewood.png

Here is a populated whitewood for AC/DC, which does not have the later sub-playfield so is much earlier in the design process.

Acdc-whitewood.png

Typically a playfield is made of 9-ply birch plywood, 17/32" thick with the additional 1/32" allowing for the inserts to be sanded flush. A number of European manufacturers used plastic playfields, and some domestic companies experimented with them in the 1970's, but the vast majority use plywood.

Standard Playfield Sizes

see Playfield Sizes

Foam Core

When creating an initial whitewood to test shots, install the lower third (flippers, slingshots) and side rails, but use Foam Core for your ramps and any upper playfield stuff. It is easy to cut and form with hot glue, quickly and cleanly. It is also strong enough to endure test playing without breaking.

Foam-core.jpg

Use 1/4" to 1/8" for ramp bottoms, and hot glue thinner posterboard on the sides. You can also use posterboard for the transitions between the playfield and the ramps. Trace the shape of the ramp on the foam core, cut it out, then glue on thinner sides.

Foam core can also be used for stand ups, pop bumpers and other devices to test other shots. Either stack it or stand it up and glue it together. Use hot glue for everything - easy to use, dries quickly, holds strong, and you can rip it apart to change things as needed.

Foam-core-4.jpg

When complete, the game should be basically playable in terms of playfield and ramp shots, and if the game plays okay with foam core, it will play even better in plastic and metal.

Foam-core-2.jpg

Cutting

(Sourced from a tutorial by Josh Kugler) [1]

Before proceeding with any cutting, a completed playfield drawing is needed, to be used as a template. For details on that portion of the process, visit the Design section of the wiki. One tip that will help later is to add centering lines to all the drilled insert circles to aid in proper placement.

Once complete, take the file to a FedexOffice or similar Printing House and have it printed full size. Use 3M Spray adhesive to glue the print to your playfield surface. This print acts as your drilling and cutting template.

Pf-cutting-1.png

Use two Forstner bits for each insert. The first is the wider opening that is the same size as the insert, drilled to the appropriate depth of the insert which is typically 1/4". The second bit is 1/16" smaller can then be used to drill the through hole. This leaves a 1/32" lip for the insert to sit on.

Since the Forstner bit has a centering point there is a natural centering hole for the second bit, making it easier to get it lined up right. The cleanest technique is to drill just short of going through, and then complete the hole from the other side using a standard cordless drill.

Pf-cutting-2.png

Don’t do the three steps in order per hole, but the first step for a bunch of holes, then the second and third.

For creating a non-circular insert, use a router with a template and Bushing guide - a router bit with a small roller bearing on it runs along your guide, while the cutting head runs in the playfield to cut the hole to the size of the template. Creating the template is the hard part, but once you have that, it is relatively easy to route multiple holes for the inserts. This is a three step process similar to the circular inserts.

As with the circular inserts, first create the wider opening. This is done by clamping the template to the playfield and then routing the wider opening using the bearing bit.

Drill a couple of holes in the center of the insert so there is less to route. This is also helpful when doing the second step, of cutting out the inner opening, that is slightly smaller then the insert opening, since the router bit can start in one of the holes and not have to be plunged into the wood.

Pf-cutting-4.png

A 3/16" bit and a 5/16" bushing/guide offers the best results, which gives a lip of 1/16", a little bigger then for the circular inserts. This second routing can be done without a template, since the insert opening itself can act as the template.

Pf-cutting-3.png

Cabinet

Made from 3/4" plywood, mitre-jointed at the corners. Some of the considerations when designing or building a pinball cabinet include:

  • Switch locations
  • Side rails
  • Lockdown bar mechanism
  • Plunger height
  • Coindoor size
  • Leg mounting brackets
  • Speaker bezel


There are typically two cabinet styles, Standard body and Wide body.

Cabinet Parts

If building a Williams style standard cabinet, VirtuaPin offers a Ultimate Cab-Builder's Kit that has all the cabinet-specific parts in one handy kit.

Cabinet-parts.jpg

When cutting your cabinet for the coin door, keep in mind it is installed with four bolts centered on the bottom, sides and top, and that the top hole goes through the lockdown bracket. So both need to line up.

Coin-door-lockdown.jpg

Electronics

Once the physical playfield is constructed, wiring it all together and adding a way to control the devices will be required. There are three basic options - use existing pinball boards, build custom control boards or purchase off-the-shelf units.

Existing Boards

A popular option is using boards from existing machines and replacing the main controller. For example, the Gottlieb System 3 driver board uses modern MOSFET drivers, supports 32 coils and a 8x10 lamp matrix, and is available for $100 from Pinball Resource.

Schematic for the Gottlieb System 3 Driver board

Another well documented system is the original Bally system.

Custom Boards

  • Pinheck is a system designed by Ben Heck for use in America's Most Haunted and is not currently available in kit form, but you can download the design and have it printed yourself for use in your own games.
  • System Shock is a work-in-progress and currently only the driver board is available for download.

Off-the-Shelf Boards

  • P-ROC (Pinball - Remote Operations Controller) is a well-supported generic platform that is in use by many custom games. It has a dedicated forum.
  • FAST Pinball is the new kid on the block that will be bringing out a controller in 2015.
  • milliSoft Offers an all-in-one board.

Controller PCs

Most off-the-shelf systems require an external PC with USB to provide the signals to control the solenoids and lamps. Currently these small ARM-based boards are the best candidates as they are more powerful than the Raspberry Pi or Arduino boards:

  • O-DROID : Quad-core CPU, dual-core GPU, 1GB DDR3 RAM, Gigabit Ethernet , 4x USB2.0 ports.
  • Beaglebone Black: AM335x 1GHz ARM® Cortex-A8, 512MB DDR3 RAM, 4GB 8-bit eMMC on-board flash storage
  • CubieTruck: ARM® Cortex™-A7 Dual-Core, 2GB DDR3, HDMI & VGA 1080P display output, 10M/100M/1G Ethernet, Wifi + BT, SATA 2.0 , NAND+MicroSD or TSD+ MicroSD or 2*MicroSD

Power Supplies

Power-supply.jpg Power-supply-2.jpg

There are a couple of options when it comes to power.

  • Commercial Pinball Transformer / Power Supply: Most dedicated pinball transformers will provide various power level taps like 6.3V for the GI and CPU, 24V for basic coils and 50V for flippers and other high-current coils. You'll need the comparable power supply board to convert the AC voltages to DC, or create the power supply yourself.
  • AnTek: The model PS-4N70R5R12 provides high current 70V as well as 1A 5V/12V feeds to run the CPU and lights.
  • TDK-Lamda: Available from Digikey. Model LS150-36 is a 36V switching supply, suitable for most standard coils but may not be enough for flippers or VUKs.
  • Meanwell: The SE-600-48 is a 48V 12A supply which can be dialed up to 50v. There are also lower amperage 48V models such as the Meanwell NES-350-48 which provides 7A. Meanwell is a highly respected brand that make very good power supplies.
  • eBay: Search for CNC Power Supplies. These will often be 48V high current switching supplies designed for stepper motors and should provide enough power for most coils. However, quality cannot be guaranteed.


Switching power supplies are fine for CPU and some lighting, but computer models won't provide enough current for solenoids.

As a side note: If using a standard PC as the CPU for the machine, there is a useful board for controlling PC power supplies from the external high-current supply.

Wiring

Most pinball machines have wire harnesses of some type. As high-current devices, solenoids typically need a minimum of 18AWG wire. Wiring for lighting and switches can be much thinner since it's pulling less current, particularly if using LEDs, so 20-22AWG wiring is acceptable for low-current uses.

Wire Management

Because prototyping (or one-off) projects don't have pre-determined wire lengths and quantities, how wire is routed will change many times before the game is complete. It is highly recommended to use tie mount bases (with adhesive) versus clips that are permanently screwed into the playfield. That way they can be moved around as needed.

Wire-manage-1.gif

It is also recommended to use re-usable tie-wraps, which allow repeated opening and closing as needed.

Wire-manage-2.jpg

Here is an example of a prototype playfield using these types of wire holders:

Wire-manage-3.jpg

Color Coding

To aid in troubleshooting and wire layout, pinball companies use color-coded wire, where it has one color as the main jacket and a second color as a smaller stripe, allowing for many color combinations. For instance, Williams used yellow and white wire for lamps.

Getting a full stock color-coded wire can be very expensive, but the folks at Mission Pinball came up with a cheaper alternative method of properly color-coding wire using cheap PVC piping.

Wire-marker-1.jpg

Start with purchasing single-color wire in 50' - 100' spools. Get 18 and 20AWG spools for each type of wiring. The more base colors to start, the better.

Next, get some oil-based markers, which can be found at local hobby stores. One notable brand is Sharpie, and they should be labeled specifically as oil-based paint markers - water-based will scratch or wipe off easily. They will be more expensive but are the only type that work correctly.

Although Mission used a wood block to hold the markers, using a PVC T joint and drilling a hole through it in the center allows the placement of the paint marker in the T portion of the joint and pressing down on the wire as it passes through works very well.

Wire-marker-2.png

Matrix Color Coding

Where color-coding is particularly important is in Switch and Lamp Matrix layouts. Plan ahead and design your color scheme before starting the construction of the game in a spreadsheet.

Below is an example of a color layout for a custom game. This document can be referenced during construction to make sure the right wire is going to the right switch, lamp or coil, avoiding troublesome issues later during the testing phase.

Matrix-spreadsheet.png

Displays

Numeric / Alphanumeric

Numeric or Alphanumeric score displays are sometimes chosen even today because of the ease of programming - they display simple scores or lines of text only, so no complicated graphics need to be designed or coded. That means more time to concentrate on gameplay versus interfacing with the player.

Gas Plasma

The first commercial solid-state displays in common usage were Gas Plasma displays. They use high voltage to cause a noble gas like neon to glow. Shaping the conductive layers into digits allows the display of multiple numbers or letters.

Gas-plasma.jpg

These types of displays are not only dangerous, due to the high voltages required, they are prone to burn-out or out-gassing, and have been obsolete for many years. Unless re-theming an older game and wanting to re-use existing parts, or trying to maintain a retro look, it is suggested to use LED replacements.

LED Displays

Led-display.jpg

The pinball after-market has produced a number of excellent plug-and-play LED display replacements.

  • X-PIN has 6- and 7-segment displays as well as alphanumerics.
  • Pinscore has retrofit kits for older machines.
  • PinLED in Europe has a variety of options available.


Additionally, there are many generic LED displays to choose from:

  • Adafruit offers a number of LED segment displays with instructions on programming them with various microcontrollers.

Dot Matrix

Dmd-closeup.png

Modern games make use of either a gas plasma or LED Dox Matrix Display or DMD. They work on the same principle as the segment display except they use round pixels in a grid pattern - or matrix - to display game information.

Dmd-display.png

The complexity with these displays is that the programmer must construct numbers or letters in a graphic format and then push that data to the display. Rather than program "display 300,000", they must use bitmap fonts and determine screen placement.

However, many programming frameworks currently available offer this functionality built in and are an excellent place to start learning about game graphics.

Other options for matrix displays include:

Small-dmd.png

LCD Display

The trend for modern games is using LCD screens in place of DMDs or other older display technologies. Full color with high resolution, the results can be very attractive. However, at this level a game designer essentially becomes a videogame designer. A pinball maker has to wear many hats but it is the rare individual who can do both construction and handle graphics duties.

There is some discussion of the technical side of graphical displays on the pinballcontrollers Forum.

Lighting

Socket Styles

Most lighting is socketed either by a bayonet or wedge socket.

Wedge-base.jpg

Bayonet-base.jpg

Bayonet is preferred since the bulb is more likely not to wiggle itself out from vibration during play and transport. While pinball started out with incandescent bulbs, most are moving towards LED for many reasons:

  • Less power draw
  • More color options
  • Lasts longer which means replacing less often
  • Less damaging. The constant heat/cool from incandescent bulbs are known to warp plastics and cause flaking on backglasses.

Bulb Types

The most common sizes are the #44/#47 Bayonet Base, the #555 Wedge Base, the #89 Bayonet and the #906 Wedge.

Led-bulbs.jpg

One drawback of LED's are that they don't have a ramp-up of brightness like incandescent bulbs, and sometimes they can be bright enough to hurt the eyes. The ramp-up effect can be emulated in software if the lamp controller has enough brightness levels, and diffusion-style bulbs help the brightness issue. They are best used as General Illumination.

Coin-taker-bulb.jpg

Modern Stern games going forward use a Surface Mount LED board that are driven directly which eliminates the need for sockets altogether. The drawback to these are that the boards are directly soldered, so if there are issues, they can't be easily replaced. However, the long life of LEDs makes it unlikely for them to burn out at the rate incandescent lamps do.

For a custom game, a combination of Cointaker Premium Frosted or Ablaze 4-LED for GI and the FAST Pinball RGB LED Insert boards for inserts are a good choice.

Lit Flipper Buttons

Thanks to newer LED bulbs there is more flexibility to installation than ever before.

For lighting translucent flipper buttons, use a #44 bulb holder and some 44/47 Flex Super Bright lamps from Cointaker.

Lit-flip.jpg

Screw the Socket under the flipper button and out of the way of the Flipper Button Leaf Switch. Position the head of the LED so it is shining slightly up. Don't let the LED head touch the Leaf Switch, or it may wear out the LED or break the LED's leads.

Lit-flip-2.jpg

Custom Parts

Many hobbyists plan on producing games with game-specific features that aren't included in other machines, such as ramps or ball control devices, and thus will have to design and construct mechanisms from scratch. This generally involves metalworking, welding and other more advanced skills, but are not beyond the garage hobbyist.

3D Printing

(From Wolfmarsh's Pinside tutorial)

The big revolution in garage building is 3D printing.

The most popular among home machines is Fused Deposition Modeling (FDM for short). FDM is where a thermoplastic filament is slightly melted, extruded through a small nozzle, and deposited in layers to build up the object. Most home printers use this method.

Here is an image that gives the general idea. One is the Extruder, two is the deposited Layers, and three is the Build platform.

3d-1.png

A second method that is popular with the higher end machines, is Selective Laser Sintering (SLS). With SLS, a layer of powder is deposited on the build surface, then a laser melts specific areas together. The build surface lowers a fraction of a millimeter, and more powder is deposited. Repeat until the object is built. Here are a couple short videos that shows how SLS works:

https://www.youtube.com/watch?feature=player_embedded&v=sFpSxX0SzgY

https://www.youtube.com/watch?feature=player_embedded&v=-6ItiCbYFvI

Buying a Printer vs Using a Service

Most home printers will print using plastic filament and FDM. Services like Shapeways can afford higher end printers that offer higher resolution with SLS.

For most of what a garage builder will do, FDM and home printing will cover it. If a full color print or some very fine details are needed, like screw threads, the part can be ordered from Shapeways.

If planning to purchase a home printer, it is recommended to read the Make Guide to 3D printers. One option is the Printrbot Simple Metal Kit with a Heated Bed upgrade.

3d-2.jpg

Generally with the lower cost kits, the only real sacrifice is speed and maximum build size.

Printing an Object

The easiest way to get into 3D printing without having to create models is to download pre-made models. A great source for this is Thingiverse. Pinball parts are starting to appear on Thingiverse, so there is a small library already available.

For example, here is a shooter lane designed by Pinside contributor swinks:

3d-3.jpg

Download an .STL file of the model to print. It contains the geometry for the object in a language the printing software can understand. Once you have the .STL file, you feed it to a Slicing program like Slic3r. A slicing program takes a 3D model and cuts it into the layers needed to feed to the 3D printer.

Here is a quick example of how it works. The model is on the left, and the sliced version on the right.

3d-4.jpg

Once the object has been sliced, the program will generate a G-code file, which is the common language that CNC machines use.

A G-code file looks like this:

G1 X52.008 Y54.121 E2.04455
G1 X51.948 Y52.484 E2.13013
G1 X51.969 Y52.373 E2.13608
G1 X52.042 Y50.606 E2.22844
G1 X52.067 Y50.514 E2.23342
G1 X52.258 Y48.934 E2.31658
G1 X52.708 Y48.561 E2.34712
G1 X52.998 Y48.608 E2.36247
G1 X54.421 Y48.632 E2.43686
G1 X54.532 Y48.659 E2.44282

This example is a bunch of G1 commands that tell the machine to move to a specific X position, a specific Y position, and to Extrude a specific amount of filament. The G-code file gets loaded into the Printer control software, and slowly fed to the printer as it prints the object.

The Printrbot example above can be driven using a Raspberry PI, running a special image called OctoPi. It provides a web interface to the printer.

If everything worked as expected, at the end of the print process there is a real, complete object based on the models:

3d-5.jpg

If things don't go well, it may end up as a bunch of trash plastic. It happens.

3d-6.jpg

The key is to experiment and find shapes that work well, and to design shapes with the properties of the materials being used - if building brackets to hold coils, the resulting bracket should be thick enough to maintain its shape when the coil fires. The following is an example from America's Most Haunted.

3d-7.jpg

Vacuum-Forming

(Sourced from a tutorial by Josh Kugler) [2]

Doing simple vacuum-forming in your garage is straight-forward. The basic idea is to use a standard oven to heat up a sheet of plastic until it softens, then place it over a pre-made form, using a vacuum to pull the plastic down around the form.

Materials needed to create the vacuum-former include:

  • Wood Strips
  • Pegboard (2' x 4')
  • Plywood
  • Shop Vac or similar


Sizes are not critical - the available space in the oven will determine the maximum final size of any pieces formed - so the unit should be built slightly larger than that.

Vac-form-1.png

Create a box using the wood strips and plywood, and caulk it to make it airtight.

Vac-form-2.png

Drill a hole the same size as the intake hose on your vacuum in the side or bottom of the box, and attach the pegboard to the top of the box. When you place your form on top of the box, then the heated plastic, the vacuum will draw the heated plastic down.

Using an old picture frame, or a cheap one from IKEA, trim your plastic sheet to the same size and heat the plastic in the frame in the oven at 375 degrees, until it just starts to droop. Placing the frame and plastic on oven-safe jars will prevent it from touching the racks or surface of the oven if it should droop too far.

In this photo, the extra airholes are blocked by poster board to maintain the airtight seal.

Vac-form-3.png

When creating forms, it is important to remember that it must be possible to cleanly remove the form once the process is complete, so things to avoid include:

  • Large vertical surfaces
  • Vertical holes

The best form is a pyramid shape, with the smallest details on top and increasing diameters to the base. Consider using a releasing agent to make removing the form easier - a non-stick spray or lubricant for example.

Creating the form itself can be done using foamcore, wood and bondo, aluminum or steel, depending on your available tools and ability. The smoother your initial form, the clearer your final pieces will be.

Welding

If you plan on making metal ramps or wireforms, welding will be required.

In order of quality, here are your welding options:

  • TIG: Tungsten Inert Gas arc welding is often employed to make welds on nickel alloys (like stainless steel), magnesium, aluminum, titanium and copper alloys. TIG welds can be made with or without metal fillers, unlike MIG welding, which exclusively employs filler metals to create welds.
    • Pros: Pinpoints heat better than MIG welding, allowing for smaller, more precise welding, is a very clean process, creating no spatter whatsoever while a weld is being made.
    • Cons: TIG welders are more expensive than MIG welders, and it is a more difficult process to master.
  • MIG: Metal Inert Gas arc welding is most often used with steel. MIG welders do not have to start and stop too often while welding, which allows for long, uninterrupted welds. Gas shields the weld, helping to prevent oxidation and spatter.
    • Pros: Relatively clean, creating only a little spatter while welds are made, easier for beginners.
    • Cons: Possibility of excessive melt-through and incomplete joint penetration or fusion, can be difficult to create a starting arc, welds are known to leave deposits that are heavily oxidized.
  • Flux Core Wire Feed: Arc welding without the shielding gas. Uses flux, similar to soldering, to flow metal.
    • Pros: Cheapest form of MIG welding as it doesn't require compressed gas.
    • Cons: More likely to produce dirty welds due to lack of shielding.
  • Brazing: Can be done with hand tools, but it requires a lot of heat for a long period of time in one spot, which weakens the surrounding steel. This makes it more susceptible to warping and bending due to stress. It can work, but it is not nearly as strong as MIG.

Wireforms

(From Matthew Bonnema's Tutorial on Wireform Fabrication)

One standard convention on modern pinball machines are wireform ramps. They can be made out of 1/8" steel wire which can be purchased at most big box stores. If you don't have access or the skill to use welding equipment, wireform ramps can be fabricated from brass rods and soldered together using a small torch, flux, and solder. Spooky's America's Most Haunted was prototyped this way not only because Ben Heck was already used to soldering, but because brass is a little easier to form than low carbon steel.

Spacers

Spacers help to keep the proper distance between two rails in a wireform while it is being constructed. They can also be used for welding braces. A fair number of these will be needed - two or three per curve - plus a few oversized ones to allow for the grounding clamp from the welder if you're using one.

To make them, just measure the ball and figure out where you want the ball to ride in the rail, then drill two holes the same size as the stock you are planning on using.

Wireform-7.jpg

Slide the spacers on and match the other wires bends carefully. Make sure to only bend the new wire and not the guide wire.

Wireform-8.jpg Wireform-9.jpg

Use 16 and 20 gauge sheet metal for the spacers - 20 for tight bends and 16 for straightaways. It is easier to slide the 20 gauge down the curves.

If skinning wireforms, put supports on the under side to make them stronger. You can construct ramps by welding sheet metal over the tops of the rails at the ball entry points.

Wireform-10.jpg

Loops

Loops are useful as entrance and exit points, and cut down can be used as bracing.

Take a piece of 1" PVC pipe and drill a hole centered on the pipe all the way through, roughly the same size of the stock that you intend to use.

Wireform-1.jpg Wireform-2.jpg

Insert the stock all the way through and wrap it around really tightly. It will spring back a little, but if you are using a standard size pinball, it shouldn't be a problem as long as you keep the tension consistent all the way through the wrap.

Wireform-3.jpg

With an Angle Grinder with Metal Cutting disc, cut as close to the initial bend to get as many loops as you can with out getting any of the curve in the cut.

Take caution! This is a dangerous tool!

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A simple way to get really nice and easy loops. Bolt cutters, shears, a hacksaw, or wire cutters capable of cutting the wire you are using can also be used as an alternative to the angle grinder, although the loop ends will not be as clean. Free the loop of wire by pulling down on it slightly and clipping off the bent leg that goes through the pipe. Clip or saw each ring off, using the edge of the last ring cut as a guide.

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Create supports by cutting the rings in half to make the supports. A large Side Cutter makes cutting the 1/8" steel stock easy and fast - just make sure to hold on to both pieces because they can fly apart. Eyeball guessing for the center on the rings is fine, but for consistency, measure for center.

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Drawings

After making spacers and loops, the best starting point is using drawings made in one of the drawing tools mentioned in the Design section. Match the form to the full-size 2D drawing during construction.

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Welding

Cut a straight piece of stock, place it on the end of the rail and weld it up with a good tack. This will stop the wireform from twisting out of shape while putting the supports on. Use Welding Magnets (Usually about $3 each from most hardware stores) to hold the wire in position.

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Clamp the ground for the welder to one of the jigs - you get a good, dependable circuit and it won't mess you up when you move it.

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Time to weld!

Only weld with a Welding Helmet that is tight and won't fall off. If using a auto-darkening helmet, test its function before starting to weld. It should darken from the spark of a lighter.

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First test the feed of the welder by pushing the button and watching how smooth the wire comes out. Having a jumpy feed can ruin a weld pretty fast. Then trim the wire to a comfortable length.

If the wire is too long, it will make spatter all over, while if too short, it could miss the joint and/or clog up the tip of the welder.

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A good weld has clear signs of even heating and penetration through both parent metals (the grayish circle that surrounds the weld).

The bad weld example was done by having the wire overfed or having the wand to far from the surface. This creates a large amount of spatter, which on pinball rails is difficult to clean up due to the sizing.

It also has a distinct noise when done incorrectly - it sounds like bacon popping. A good weld has a consistent buzz sound.

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After measuring where you want each support to go on the wireform, flip the rail over and set a half ring that was cut earlier across the two rails, using a magnet to hold it in place.

Make sure the ring is lined up with both sides of the rail. It should flow with curves and should be evenly placed.

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A good welding technique to use is called Pushing the puddle. It is basically starting on the thicker material and pushing the molten puddle back into the thinner cross material.

Top Rail

With all the supports are welded, it's time for the top rails.

Take the PVC pipe used to make the rings from earlier and mount it to your workbench. Put the stock where the bend should be under the pipe and pull up, keeping a lot of force at the base.

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Take the bent stock and lay it across the rail. Mark where it should get the first welds.

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Go down the entire length of the wireform, bending the top rail wire by hand as close as possible to the form without welding. Welding and bending one after the other would cause the areas that have been welded to be much softer from the heat of the weld. This is called Annealing, and your top rail bends will not match the cold bended main rail.

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Finishing

Every now and then, bring your wireform back to the machine and test fit to make sure it is not getting warped from the heat of the welder.

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During the fitting, mark areas for adding supports to hold the wireform.

After all the welding is complete, quickly run the whole wireform on a Fine Finishing Wire Wheel to clean it up and ready it for powdercoating or plating.

To see these parts powder coated and installed, see the DeadPin machine in the Custom_Games section.

Devices