Building and Powering AAR A Trucks: Difference between revisions
| Line 107: | Line 107: | ||
File:Chain attached With link.jpg|The chain is attached with a Connecting Link in this case. | File:Chain attached With link.jpg|The chain is attached with a Connecting Link in this case. | ||
File:Completed Motor Sprocket Bearing Set.jpg|A completed drive chain, waiting for wheels to be pressed on. Note that the Zerk fittings on the bearings are both on the same side. | File:Completed Motor Sprocket Bearing Set.jpg|A completed drive chain, waiting for wheels to be pressed on. Note that the Zerk fittings on the bearings are both on the same side. | ||
File:AAR A Motor Washer Spaces DNevil.jpg|Washers may be inserted between the motor and block bearing to remove slack in the chain. | |||
File:Zerk protector on bearing block AAR A.jpg|The Zerk fittings on the bearing block were protected by a plastic cap. The Zerk is unscrewed in order to remove the cap. Be sure to tighten the Zerk fitting back in place. | File:Zerk protector on bearing block AAR A.jpg|The Zerk fittings on the bearing block were protected by a plastic cap. The Zerk is unscrewed in order to remove the cap. Be sure to tighten the Zerk fitting back in place. | ||
File:Bearing Block set screw AAR A.jpg|These bearing blocks were selected because they include set screws that prevent the blocks from sliding laterally on the axle. This photo shows one of the set screws. Make sure the chain is aligned between the motor sprocket and the axle sprocket, then tighten the Allen set screws on both bearings. Note that there are two set screws per bearing. Also note that the set screws are on the opposite side from the sprockets. | File:Bearing Block set screw AAR A.jpg|These bearing blocks were selected because they include set screws that prevent the blocks from sliding laterally on the axle. This photo shows one of the set screws. Make sure the chain is aligned between the motor sprocket and the axle sprocket, then tighten the Allen set screws on both bearings. Note that there are two set screws per bearing. Also note that the set screws are on the opposite side from the sprockets. | ||
Revision as of 13:53, 20 March 2015
Building and Powering AAR A Trucks
5 March 2015
A little over 12 years ago I purchased a set of castings from MDM Locomotive Works to build a pair of AAR A trucks. I am really impressed with this kit, as it includes everything except the motors. It includes all screws and hardware, flame cut parts for brakes, wheels, axle material, even a set of Clippard air brake cylinders. It's really a shame that no one has taken over Jim Murray's fine business.
I have worked on this kit off and on since I purchased it. I had never quite been sure how I was going to power the trucks. I wanted electric driven axles, as I know how to design and wire the electric circuits. Recently (well, about a year ago), I decided to put more effort into constructing the trucks, partially in hopes that an epiphany would come regarding what motors to use and how to mount them.
This plan has worked. I am nearing completing of the trucks, including the electric motor drives. The motor design is simple but effective, and may be used on other truck styles or even single axle trucks, such as on Plymouth switches. This article will illustrate the method and materials I used.
AAR A Trucks
First, a little background on the AAR A Diesel Truck.
Martin P. Blomberg filed a patent application for the truck design on 6 July 1937, and the patent was issued on 15 November 1938. Blomberg worked for General Motors Electro Motive Division at the time.
The AAR A trucks were designed for switcher service where the more complex high-speed passenger locomotive trucks were not needed. The truck uses drop equalizers but does not have swing hangers as used on the Blomberg B and others. A combination of coil springs, and leaf springs, positioned fore-and-aft inside the drop equalizers, give a good balance of damping. The wheelbase is 8 feet 0 inches.
Electric Motor
I finally settled on an electric motor for the trucks. I chose the MY-1016 scooter motor, which is commonly available on eBay and other scooter supply sites on the Internet. The motor has a convenient four-bolt motor mount and includes an 11-tooth sprocket for #25 chain. It is rated at 24 volts D.C. with maximum power consumption of 250 watts (about 1/3 horsepower). The best part is that the motor is very affordable. They can be had for less than $40 each.
A single MY-1016 motor drives my mini-F9 diesel, which has plenty of power for hauling. I believe that four of these motors, one per axle, will provide more than enough pulling power for my target diesel.
Specifications:
- Voltage: 24Vdc
- Rated Speed: 2650-2900 Rpm
- Rated Current: 16.0-16.4A
- Output: 300 Watt
- Sprocket: Removable Bolt Sprocket
- Case Length: 4-1/8" (105 mm)
- Case Diameter: 3-15/16" (100 mm)
- Drive Shaft Length: 1" (25 mm)
- Drive Shaft Diameter: 5/16" (8 mm)
- Bolt Hole Distance (Adjacent): 4-1/8" (105 mm)
- Bolt Hole Distance (Cross Bracket): 2-3/16" (56 mm)
Bill of Materials
This section provides a list of materials used for mounting the motor to the axles, and for the chain drive system.
Each wheel set (pair of wheels and an axle), use the following components. The quantities required are shown in parenthesis.
- (1) Electric Motor - MY-1016
- (2) Pillow Block - UCP204-12
- (1) Martin SPK Roller B - 25B48
- #25 Roller Chain
- (1) #25 Connecting Link
- (1) #25 Offset Link
- (1) Taper Pins - #2 by 2-3/4 inch
- (4) Motor mount bushings
- (4) M6-1.00 x 40 Hex Cap Screws (Lowes)
- (4) M6-1.00 Nylon Insert Lock Nuts (Lowes)
- (1) 5" x 5" Tee-brace (Home Depot), modified as shown below
- (1) Everbuilt #304 1/2 inch pipe U-bolt (Home Depot)
- (1) 5/8 inch outside diameter rubber hose (such as for car coolant system), 1 inch long
Specialty Tools
- (1) Roller Chain Breaker
The only custom parts in the list above are the "Motor mount bushing" and the "Tee brace". I turned the bushings out of 3/4 inch round bar CRS. They help stabilize the pillow blocks and provide a solid foundation for the heads of the bolts securing the motor to the block.
The "Tee brace" parts are modified stock Tee braces used in building construction. They prevent the motor from spinning on the axle.
I ordered the large sprockets directly from Martin Sprocket. They came with a 1/2 inch bore and no key or set screw. The MDM truck kit came with 1/2 inch axle stock, but I prefer 3/4 inch and substituted using 3/4 inch round CRS. The sprockets were drilled and bored from 1/2 inch to 3/4 inch, then placed on the axles in the correct location and taper drilled all the way through. The sprocket was locked into place by driving the taper pin and cutting off the excess.
I later found the equivalent sprocket from McMaster-Carr. The next wheel-sets I build will use the McMaster-Carr sprocket, as it is already bored for a 3/4 inch axle and includes a 1/8 inch keyway and set screw. It is the same price as the Martin sprocket (I'm guessing the McMaster-Carr sprocket is also made by Martin).
T Plate 5x5 inches, unmodified
5x5 inch T Plate modifications
Here is a Tee Brace after drilling the extra holes, trimming the arms and painting.
Everbuilt #304 1/2 inch pipe U-bolt
Motor mount bushing
A handful of newly turned motor mount bushings. A total of 16 bushings were required.
Assembly
Drilling a tapered hole through the sprocket and axle. Be sure to use lots of lubricant to keep the bit cool. Make sure the hub of the sprocket is facing towards the short end of the axle.
Reaming a tapered hole after drilling. Rapid Tap works well to keep the reamer cool. Pull the reamer out frequently to extract chips, then apply more cutting fluid.
A completed axle with the #25 chain drive sprocket attached with a tapered pin. The pin has been lightly driven in with a chisel and hammer, and the extra length cut off neatly.
The bearing blocks are slid onto the axles. Make sure both Zerk fittings point the same way. Assemble the motor onto the block bearing using the motor mount bushings and a bolt, both inserted from the underside of the block towards the motor.
Assembling the #25 chain on the sprocket and motor. This step is performed after attaching the motor to the bearing blocks using four motor mount bushings and four M6-1.00 x 40 hex cap bolts.
Place the chain on the two sprockets in order to measure the correct length. You will need to use either a Connecting Link or Offset Link, depending on which section of the chain must be removed. Use a black Sharpie marker to indicate which link pins to remove.
Use a Chain Breaker to remove the unwanted link. Refer to the video Splitting a Chain with a Chain Breaker
The chain is attached with a Connecting Link in this case.
A completed drive chain, waiting for wheels to be pressed on. Note that the Zerk fittings on the bearings are both on the same side.
Washers may be inserted between the motor and block bearing to remove slack in the chain.
The Zerk fittings on the bearing block were protected by a plastic cap. The Zerk is unscrewed in order to remove the cap. Be sure to tighten the Zerk fitting back in place.
These bearing blocks were selected because they include set screws that prevent the blocks from sliding laterally on the axle. This photo shows one of the set screws. Make sure the chain is aligned between the motor sprocket and the axle sprocket, then tighten the Allen set screws on both bearings. Note that there are two set screws per bearing. Also note that the set screws are on the opposite side from the sprockets.
A completed wheelset after pressing on the wheels. The wheelset is ready to be mounted into the truck frame.
Test fitting the T-brace along with the U-bolt before cutting the extra length off the T-brace. The motor T-brace is attached to the motor block bearings using two nylon lock bolts. Likewise the U-bolt nuts are replaced with nylon lock bolts. This allows the tension on the rubber hose to be adjusted. The U-bolt/rubber tube configuration allows the motor to rotate on the axis as the wheelset moves up and down over the road.
