Classic Car Windshield Wiper Vacuum Motor Replacement

Up until the 1960s, most automobile windshield wipers were powered by vacuum motors.  I have a 51 Willys pickup with a vac motor.  The last time I registered the truck, the only way I could get the wipers to pass the inspection was to mist the windshield with a water spray bottle before turning them on.  It is time to reregister the truck and the wiper motor has failed. 

This Instructable describes the process I used to convert the wipers from the original vacuum motor to a 12 volt motor.  If you choose to make this conversion,  I suggest you read through all of the steps before starting.  These instructions are a little disjointed.

This is my vacuum motor.  There are several sizes of these motors.  To make the replacement, you will need to duplicate the motor drive hub and mounting holes pattern of your own motor.

To determine the radius of the motor drive, I made a cardboard template, attached it to the drive side of the motor, and marked the outer arc swing limits of the upper hub wing.  The initial photo showed only the index markings, but is was a poor photo.  I made this photo after I had taken the template off, penciled in the radius line extensions, and remounted the template to the motor.

Using a protractor,  the radius of the vac motor drive arc is shown to be about 140 degrees. 

Most older vehicles are 6 volt.  If you decide to go to an electric motor, 12 volts will work best.  We are in the process of converting my original 4 cylinder F-head engine from carbureted to fuel injected, so I have already upgraded from 6 volt to 12 volt.

Initially, I wanted to use a front windshield wiper motor in order to have the variable speeds.  The problem is that most of these systems use a motor that drives in a full circle, with linkage to provide the oscillating motion to the two wiper arm pivot points.  I designed a modification for one of these systems to have a shortened single pivot point, but did not like how big and cumbersome it looked.

The vac motor wipers have a single output pivot shaft and a cable system under the dash to transfer the power to the two wiper mount pivot shafts.  Rear windshield wiper motors are the logical replacements for the vac motors because they have only one output shaft and do not turn in a full circle, but oscillate back and forth in a fixed arc.. 

From information gained in the two previous steps, I knew that I needed a motor with an output swing arc of as close to, but not more than 140 degrees.  I experimented with three rear wiper motors, two from the local "Pick and Pull" and one given to me by my son Joe.  I checked the swing arc on these motors in the same way as with the vac motor.  I used the same type of template, taping an "L" shaped wire to the output shaft to determine the arc limits.

Of the motors I tried, the best match was from a 90 Jeep Cherokee (not a Grand).  It had an arc swing of about 135 degrees.  I knew it would not give the complete full swing of the wipers, but it would also not force the wiper cable system outside of its design limits.  The best thing was that it did not cost me anything because it came from a Jeep my son had parted out.

Unfortunately, I had already modified the motor shaft and mounted a hub before I took this photo.  As shown here, the motor is attached to a stamped sheet metal mount, with a black plastic motor controller attached.  You can see what the shaft end looked like originally by checking on Google for "rear wiper motor" and then searching for this model.

On this design there are 4 wires coming from the assembly: white, black, brown, and gray. Connecting the white and gray wires to a positive 12 volt line, at the same time the black line is grounded, powers the motor to run continuously.  If the gray wire is disconnected and the brown and white wires are connected to the positive line, while the black line is grounded, the motor runs only long enough to return the wiper to the resting position and then stops automatically.

In my first attempt to rewire the harness, I used a switch with two "on" positions.  I attached the white wire and a fused positive line to the center switch tab, then attached the gray wire to the tab on one side of the switch and the brown line to the other side.  Switching to the gray line turns on the motor.  Switching from the gray line to the brown line returns the motor drive to the resting position and turns off the motor.  I was  disappointed when I realized that the resting position for this motor places the wipers in the upper rather than in the lower position. 

To verily that this motor would work as a replacement, I needed to put a drive hub onto it and try it out.  My first step was to cut off the wiper arm mount from the shaft end. This let me see that the shaft is 4 mm in diameter.  Next, I shortened the housing to expose more of the shaft.  This motor has a plastic bearing between the shaft and the housing.  I removed the bearing and replaced it into the housing after making the cuts.  As I experimented, I cut both the shaft and housing twice each before determining the lengths.  This photo shows the final shaft/housing/bearing configuation.  This worked well for me, using a 1/2" thick hub and washer between the bearing and the hub.  Before reinstalling the bearing, I packed the shaft housing with grease.  Also shown is a flat that has been filed on the end of the shaft for the hub set screw.  Do not file this flat until the placement of the hub is determined in step 16.

I wanted to match the output drive configuration of the vac motor as closely as possible.  The dimensions of the drive wings are 1 1/8" total length, 3/16" thick and 5/16: high.  This in not too pretty, but it is functional.  I cut the hub out of a scrap piece of 1/2" aluminum using a hole saw.  The saw teeth kept filling up with metal and had to be cleaned out every few revolutions.  A belt sander was used to take off the rough edges.  The bore is 4mm.  I used aluminum cut from an old fuel pump body to make the hub wing.  With a lathe and mill, this would be a much nicer looking part.

This photo is somewhat after the fact, but before making mounting modifications or even final shaft length determination, I tested the motor.  To do this, I mounted the hub and held the motor in place to see that it had adequate power to operate the wipers.  This takes two people, one to hold the motor in place and the other to connect and disconnect the power.  I was very impressed with the amount of torque produced by the motor. To make this test I set the set screw, but did not file the flat on the shaft.  The hub position is determined in step 10.

Again, I used cardboard to make a template.  The adapter needs to match the new motor configuration with that of the vac motor mount to place the drive to place the drive hub the correct position..  One of the nice things about using cardboard is that you can placed the template over the adapter plate material and mark the center points with a sharp point, such as an ice pick.

To test the adapter layout, I first made an adapter out of plywood as shown the next step.

I made the "breadboard" model of the adapter plate out of 3/8" plywood.  Before mounting the wiper motor onto it, I added a spacer board to position it level with the existing mount.  Next, I determined where I wanted to add a firewall support bolt and drilled the hole into the adapter and attached spacer first, then screwed it onto the existing moount.

The photo show the process of using the predrilled hole in the adapter as a guide to drill the firewall mount bolt hole.  Note that the position of the receiving drive hub wing has been marked on the inside of the adapter center hole.  This is used for setting the position of the drive hub on the shaft in step 16.  At this hub position, the wiper blades are in the resting position.

I attached the motor to this wooden adapter for a trial run of the prototype before making the final adapter.

The original mount is rubber mounted.  The new spacer, with rubber pad, matches its thickness. 

Steel or aluminum plate would probably be the best material for the adapter plate.  I chose to use 3/8" nylon because I already had some and it is easy to cut.  The two motor bolt holes and the two original mount holes are 1/4".  The firewall mounting bolt hole is 5/16". After taking this photo, I sanded, primed, and painted it to match the firewall color.

I wanted to move the controller to inside the cab, under the dash, rather then leave it on the firewall next to the motor.  To accomplish this, unplug the wire connector and cut the connector from the stamped plate mount.  I drilled a hole in the remaining smaller plate to use for mounting it on the inside of the firewall.

There are three wires connecting the motor to the controller: green, lavender, and black.  Clip these wires in the center to leave enough length on each end to attach connectors.  Additionally, the white wire from the motor needs to be extended to the dash switch.  I chose to wrap and secure these wires using the original harness to motor clamp.  Not clearly shown is that the black ground line, in addition to being extended, it is grounded to the motor under the harness clamp.  Where possible, solder the connectors to the wires rather than just crimping them.  I used push-in connectors for the lines going to the controller and a loop end for the white line going to the switch.

I extended the gray wire to the switch.  It is not shown clearly, but the brown wire end is taped off due to the limitation noted in step 5.  The black wire has an additional extension to ground the system to the body on a firewall screw.

Install the hub to the shaft prior to attaching the adapter to the motor.  Based on the hub position identified in step 10, file a flat onto the shaft as shown in step 6.  Install the hub to the shaft as shown in step 8 and tighten the set screw. 

The shaft/hub length determines the position of the adapter plate.  I spaced the adapter so that the total thickness of the spacers and adapter was 1 1/2" out from the motor mount holes.  This was accomplished with extension nuts and washers.

The two motor mount holes are threaded from the back side only.  I tapped these threads through to the front side.  This may not have been necessary, but I did not want the security of the mounting to be dependent on the aluminum threads only.  With this design, the connections are made within the steel extension nuts. 

The motor controller wires are connected to the matching harness wires.  The white and gray lines are connected to one side of the switch.  By connecting a fused positive power line to the other side of the switch and connecting a ground to the black wire, it is possible to test the system by turning the switch on and off.

This process has several steps.
1.  Index the receiving wiper drive hub into the same position as the motor drive hub.

2.  Mount the motor into position with the drive hub inserted and the firewall bolt in place.

3.  Secure the motor adapter to the original mount using screws with the same threads as the original screws.  The screw that is located on the right is behind the motor and will need to be a hex head screw due to the tight quarters.  Do not over tighten these screws.  Once they are secure, tighten on the nut to the firewall bolt.

4.  Use a grommeted hole in the fire wall to pass the wire harness through to under the dash.

5.  Connect the motor controller lines and attach the controller to the inside of the firewall.  Ground the black line to the body.

6,  Connect the white wire and gray wire to one side of the on/off switch.

7.  Run an ignition switch controlled, fused line to the other side of the on/off switch.

Verify that the switch will fit in the location selected and not short on adjacent metal.  I taped the bottom of the switch to protect the wire from accidental shorts.  I liked this location.  Find what works best for you.

I was hoping it would snow to show the wiper pattern.  In the absence of snow I smeared the windshield with whipping cream.  It is a little messy, but it shows that the new motor works well.

After operating the wipers and seeing how easy it is to stop them in the right position, I am not disappointed in not having the automatic "return to resting position".

If you want to use a wiper motor that will have the correct resting position, look for one that pivots in the center, has a swing arc of 140 degrees or slightly less and its normal resting position is on the driver's side of the rear window rather than on the passenger side. 

Most importantly, share your comments, so we can all learn.