Blogs
|
E-Scooter Controller Directions GIO 500w E-Scooter Controller Directions The Controllers on the GIO E-Scooters contain circuitry which limits the amount of current that can be sent to the motor. This circuitry serves to protect both the controller and the motor. In doing so, it also limits the hill-climing ability of the bike to such an extent that it becomes dangerous to drive the bike up even very slight grades in heavy traffic. In most states, these bikes need not be registered, but are street legal, and in most cases cannot legally be driven on sidewalks. Increasing the available torque therefore becomes a necessity if the bike is to be used for common adult tasks like commuting to and from work, short grocery store trips, and just visiting friends in nearby suberbs.
http://visforvoltage.org/forum/3990-xb600-quotshunt-modquot-instructions. Since the GIO E-Scooter controllers are not the same, I decided it would be helpful for others if I documented the steps I took to do the modification on my bike. I have had my GIO E-Scooter for about a month now, and I decided to order an extra controller for my bike, rather than take the chance of putting my bike out of comission by some mistake I might make while doing the modification. Let me preface by stating that I am a retired Electrical Engineer who work my way up from Electronic Technician to Electronics Design Engineer, so I have had a great deal of soldering experience, and circuit board design and repair. If you are going to attempt this mod, and you haven't done any soldering, I would suggest you find a local computer shop and ask one of the good techs to teach you how to solder correctly. So lets get started. First, unplug your battery by pulling out the battery box plug which is found
underneath the bike just forward of the right pedal socket. Once the battery is disconnected, turn the key to the ON position and pull the brake pedal to discharge all the capacitors in the system. This will not fully discharge everything, but it will get the charge low enough to help eliminate sparks when you make connections to the controller. Now turn the key off and remove it.
Next we must open the controller. There are four screws on each end of the controller which hold the two end plates to the box. Remove all four, and if necessary, cut away the silicone insulation material so that the end plates can be separated from the box. Remove the blank end plate firstand set it aside. You will then be able to see inside the box.
There are six power MosFets on the controller. They are clamped to the side of the box for heat transfer, using a metal bar and three flat-head machine screws. The screw heads are very soft, so you should be careful not to strip them. Use a #2 Phillips screwdriver bit to remove the three screws. the plate which clamps the MosFets to the box can then be pulled out through the open end of the box. Once this is done, you will be able to pull the circuit board out of the box through the end where the cables enter.
I also decided not to drill holes through the board, but to just surface solder my shunt to the circuit board. The easiest way to do this is on the bottom of the board. There is a fairly large surface at each end of the shunt where the wire may be attached. But first, you must scrape the green coating off of the board so your shunt and the solder makes good contact with the copper circuitry. There is a piece of insulator material attached to a voltage regulator on the bottom of the board which is in the way. I held this back with a clamp while I did my work. See Figure 4.
0.076 inch, which corresponds to 12.5 gage wire. This wire has a resistance of 10.6 ohms per 1000 feet, so my 3 inch section would be about 0.0026 ohms. (I didn't fig As I said earlier, I made my shunt from a piece of coat hanger wire. I used a really cheap coathanger, made of thin steel wire. I measured the thickness to be ure this out until after the fact.)
I bent my wire loop so that it would fit inside the controller box without the risk of touching the metal box or any of the other circuitry on the board. Figure 5 shows the shape of my shunt. Once I had it bent to shape, I filed down the side that would come in contact with the circuit board so there would be good contact between the board and the wire. I used a clamp to hold one end of the shunt wire in place while I soldered the other end. Then I removed the clamp and soldered the remaining end to the board. You can see how it turned out in Figure 6. I used a 100 watt soldering gun to solder the shunt to the board, and I made sure there was enough heat to cause the solder to flow freely around the shunt and to cover the clean part of the circuit board where I had cleaned away the coating, and I made sure the shunt would not break away from the board from vibration. The rest of the job consisted of re-inserting the board into the case and securing it in place. I put lots of silicone grease on the MosFets to insure that they would be properly heat-sinked to the case. It wasn't easy to line up the clamping bar so I could get the screws to go back into the holes in the bar, but with a pair of needle-nosed plires, I was able to eventually line up one of the screws and get it started into the clamping bar. The other two screws were much easier to line up once the first one was started and acted as a guide for the rest.
To make it easier to re-mount the controller to the mounting plate, I drilled two small holes in the mounting plate to line up with the top mounting holes of the controller, and used sheet metal screws to secure the controller in place. There just isn't enough room to hold a washer and nut in place for a machine screw.
**** UPDATE **** 10/01/2008
After doing some testing on my bike, I found that the stock controller on GIO E-Scooter limits the motor current to 15 amps, and that the voltage drop across the shunt wire is 50 MV. That would mean that the resistance of the shunt is 0.0033 ohms. Taking these measurements into consideration, I calculated that my modification effectively bypasses the current limiter, and allows the controller to pass as much current as the battery and circuitry of the bike can furnish. Knowing this, I decided to re-do my shunt mod and place the proper parallel resistance into the circuit to allow 25 amps of current. That would mean that my total resistance would have to be 0.002 ohms. To achieve this, I need to place 0.00508 ohms in parallel with the shunt. I decided instead of the coat hanger, I would use wire of known resistance... common steel electric fence wire. This can be bought at Home Depot in various sizes. 16 gage steel wire has a resistance of 26.5 ohms/1000 feet, or .0022 ohms/inch. So we will need 2.3 inches for our shunt. I cut my piece of wire 2.7 inches long to allow 0.2 inches on each end to solder it to the circuit board.
Electrical Schematic
|
|
|
|
|
|
1100w Electric Snowblower GIO 5003
Laissez par: rickyetnath
Ecrit le: 02/08/2012 10:21 AM
good for smale mechinne  |
|
1. Can you please provide some specs on this....size etc....thank you! See more Q&As... 2. is this a 110? 90? 70? See more Q&As... 3. whats the fuel economy on one of these bikes? See more Q&As... 4. do you combine shipping?
when parts are listed in plural form does that mean you get two? for example pedals and mirrors? when ordering one do they... See more Q&As... 5. what is the seat height on mini viper See more Q&As... 6. $20.00 to ship this whats going on here...A profit that isnt nessary.
See more Q&As... |
|
Privacy | Terms of Use Phone: 1.877.274.0480 Designed by CodeIT |
www.mr-scooterboost.com
Top speed boost kits and lithium batteries with chemistry suitable for use even in outer space.
Mr. Scooterboost doesn't just sell electric scooters.
Will ship via Canada Post and you should have it in under a week.
can pay via Paypal or RBC account.
$120 shipped
I also have a top speed boost kit that will make your electric scooter 10-15kmh faster top speed.
let me know via email thanks... info@mr-scooterboost.com
thanks
-Larry
Owner Operator
http://mr-scooterboost.com/
inf