PM935 full system WJ200 VFD build

mksj

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I was asked several weeks ago by a forum member to do a full turn-key VFD build for a 935 that he was planning on ordering. Normally I would decline to do these systems because of the time and complexity, but I have know this individual for a few years and had previously done a control system for his 1340GT lathe. The specifications where that the VFD enclosure would be mounted behind the mill and not directly attached to it. On my mill builds I use a larger metal enclosure which is 12x20x8, the volume being large enough that is does not require venting.

Additional features were momentary buttons for stop and run, forward/reverse rotary switch, auto-reverse triggered by the a proximity sensor, back gear proximity sensor to always maintain the same spindle direction, coolant switch that runs when the spindle is active, 1 and 2 stage braking (reverts to 1 stage for E-Stop), speed control, tachometer (with spindle pick-up), LED ram mounted spindle light ring and momentary snap action buttons for instantaneous spindle operation that can be used for tapping. We opted not to use a toggle switch/joystick as used on the lathe because the danger of accidentally knocking it. The low voltage relay control system is run by a 24VDC fused supply, and a separate fused 12VDC for the tach/LED light ring. There is also provisions for powering additional 12/24VDC systems such as solenoid coolant, other lights, and a separated 120/240VAC on e separate breaker for drives and DRO. The external control wiring uses custom made plug and socket shielded cables for the control pods. There are a few additional features and interlocks within the system, the build time was approximately 4 weeks after all the supplies were in house. All VFD system components are mounted to the back plate so it is removable with the sockets mounted from the rear (in the cabinet).

The speed control is a military grade 3 turn precision pot, the programming allows a speed range of 15-120Hz using the motor 4 pole (1750 RPM) base speed. The motor on the PM935 and the PM949 are the same, it is a 2 speed constant Hp 4 pole low speed and 2 pole high speed (3500 RPM). So there is no limitation in using the motor in its 4 pole setting and the performance of the mill will be better by over speeding the motor on the to 120Hz to give the same high speed range.

Turning the 100mm LED light ring holder, the tach sensor is 8mm diameter. Tolerance to dimensional drawings are -0.000 +0.001. I will post the drawing once I know that everything fits and works. With these smaller sensors, the distance between the sensor and the magnet needs to be ~0.050" for it to detect correctly. You also need to verify the polarity of the magnet and that the tach works correctly before it is installed. For some reason on the sensor the magnet orientation needed to be flipped after the install, not an easy task once it is pressed into the ring with Loctite. A small 8-32 SS set screw is used to lock the rings once mounted, the LED ring cover is a press fit to allow replacement, but can also be mounted with some silicone sealant.
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Preparing the cables, the upper control pod using a 16 pin socket, the lower is a 12 pin. Each pin soldered with a lead/tin/silver solder to assure good flow (unleaded solder is more prone to cold joints), fusing shrink tube is place over each pin and then an outer shrink tube binds all the wires.
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Initial layout of components on the back plate and drilling/tapping the holes, followed by component mounting. I use a star ground on all these types of builds via a threaded post through the back plate, then a star nut to lock. I also remove the paint around the bolt.
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Wiring begins, all socket wiring is direct connections with the exception of interconnects between sockets that are connected at the gray terminal blocks. My total workspace for the wiring is a small 3x4' table so it can get messy.
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Building/wiring the control pods.
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Wiring the upper pod, both the LED ring and tach connections are plug and socket.
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Powering up the system for VFD programming and testing the VFD with the motor connected.
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The LED light rings are quite bright and they attach to the ram so move up and down with it so one does not get shadowing. The red and black buttons are the momentary spindle buttons with the black being down (right hand) and red reverse up (left hand). The right toggle is the 1 stage (1.2 seconds) and 2 stage (3 seconds) braking. E-Stop breaks both power to the control relays and P24 for the VFD inputs. The back gear sensor and auto reverse sensor are the small square sensors. The auto reverse can be used for right hand or left hand threading, essentially it reverse whatever the spindle direction is when triggered. It is reset when the stop button is pressed.
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Hopefully the system will ship out next week, a lot of planning and time goes into these builds. Hopefully it will be a long time before I commit to another system like this.
Cheers,
Mark
 
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WOW, very nice work Mark, those multi pin quick connects look like a lot of extra work but they sure make the install slick.

Now that I've finished my PM935 VFD install, I can really appreciate the thought and work that has gone into this build.

I'm working on my PM 1340GT Lathe VFD install and enjoying the process, but man it hurts my brain trying to figure out the wiring, routing and layout.

Cheers

David.
 
Awesome work Mark!! Makes me wish my mill was 3 Phase with a VFD. You'll have to post some pictures after installation.

Do you have a link to the LED ring? That would be so much better than the light that comes with the mill.
 
The LED ring lights are automotive Xenon White 100mm-117SMD LED COB Angel Eyes Halo Ring For Headlights (link below). They come with 3 small plastic tabs on the lens which I cut off and sand a little half moon for the wires to exit on this build. If no tach sender than the ring can be thinner and you can route the wires differently. In this build I stripped out the wires from some 22AWG 8 conductor cable so I just had the outer insulation, then pulled two power wires that I directly soldered to the LED ring and also pulled the sender cable through the same sheath. This way the tach cable stayed intact. I use some fusing shrink tubing where it enters the ring along with some gorilla glue. You must use the provided power regulator supplied with the LED ring, this can be mounted remotely and then wire the output to the LED ring.
https://www.ebay.com/itm/2x-Xenon-W...el-Eyes-Halo-Ring-For-Headlights/251644516817
https://www.ebay.com/itm/Proximity-...M8-NPN-PNP-NO-NC-Magnetic-Switch/253104253128
https://www.ebay.com/itm/US-Stock-2...th-Neodymium-Magnets-8-x-3mm-N50/232387414827
https://www.ebay.com/itm/4-Digital-...er-Tester-Hall-Sensor-Switch-NPN/151262634420

Drawing for the PM935 LED/Tach ring are attached. I advise that one checks the dimensions of your ram and spindle as there are some variations. I usually turn the ID/OD for 0.001" clearance in this application. I shipped the system to the owner of the PM935, and hopefully he will post his Pm935 evolution as he gets everything installed and running.

As far as mill lights, the LED ring light on the ram works amazing well to prevent shadows, I use it along with a 24" LED light bar mounted to the back of the mill. Color wise (K) I prefer what is known as bright daylight (around 4000K) which is a bit whiter without being too yellow or blue.
https://www.ebay.com/itm/Brand-New-...rd-And-mount-Brackets-HIGH-POWER/292243489843

Mill LED lights.jpg
 

Attachments

  • 935 Mill VFD LED Tach date 12JUN2018 ver 2.pdf
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Very cool Light-Ring/Tach Sensor Mount from mksj. Although I'm a long way from receiving my PM-935TS-3PH, I decided to use Mark's design drawings to model the mount and 3D print it to see how it would turn out. I am quite pleased with the results and see no reason why this would not work well. Here's a link to the print-files
 
Mark:
That looks very nice. What are you sensing with the back gear sensor? I assume that you are using a proximity switch for this. Where is it mounted?

Thanks
Roger L
 
We are using a Hall effect sensor, that reads a pulse from a tiny magnet placed in the ring around the spindle. Since we are reading the spindle RPM directly, there's no need to sense the back-gear.
 
In the writeup Mark stated that he is using a switch to sense the machine was in back gear so he knows to turn the spindle the opposite direction when the forward push button is pushed. To do this he would need to sense either the location of the back gear gear or the position of one of the levers when the machine is setup for back gear. I was wondering what he is sensing.

Roger L
 
Roger, you are correct I use a small square proximity sensor for the back gear and also the auto reverse. They are much more compact and do not have to worry about physical contact for engagement. This is an example on my mill which is a single speed pulley with a back gear, it already had a Hi/Low mechanical switch for the tach speed range.
Back Gear Sensor.jpg
 
Ahhh! .....ok, my bad. Did not fully understand.
 
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