Electric Low Speed Vehicles (LSV’s) are becoming tremendously popular these days for a number of reasons. They are quiet, fun and relatively comfortable to drive, but more importantly, Custom Electric Golf Carts in Benoni they do not use fossil fuel. New LSV’s like the GEM and others can be very expensive though and not a practical purchase for those who would only use them occasionally or on weekends. Welcome the “lease turn in”, out of warrantee, golf course Fleet Vehicles (golf carts) to the rescue. Three year old Club Car, EZ-Go and others show up by the thousands at auctions across the US every year.
Some Yamaha Golf Carts Prices end up in neighborhood classified ads or used car lots after a quick cosmetic makeover. Many of them make their way to “chop shops” where they are stripped of their original golf paraphernalia, jacked up, fitted with showy wheels, carbon fiber dashboards, plush upholstery and satellite radios. They have paint themes ranging from your favorite adult beverage to your alma mater’s team and such. A $1400 golf cart is magically transformed into a $6,000 “pride ride” for some lucky consumer.
The one thing under the fabulous makeover these vehicles usually have in common is the old batteries and components. The other thing is; New Yamaha Golf Cart they typically are set up to operate at really slow speeds (12 mph or so). You guys that have rented golf carts at your local course know why they do that. To operate on public roads and be categorized as a LSV, many municipalities require the vehicle to go 20 mph, and must be equipped with lights, seat belts and a horn. The lights and belts are pretty easy to deal with but getting your cart to go 20 mph is another story. Even if you are not trying to make it street legal, most users want the extra speed capability just to add more usefulness and enjoyment. 12 mph is just too painfully slow for most users. If you think that 12 mph is fast enough, give it a few weeks.
Whichever method you use to increase the speed of you golf cart, be sure to use good judgment and utilize proper safety equipment. Carting can be fun and functional for everyone and has many applications. Be safe enjoying your fast golf cart. Watch for more articles about golf cart upgrades and maintenance.
Custom Electric Golf Carts in Benoni ?
The Harley Davidson golf cart is a great, old buggy and those who have one consider themselves lucky. This particular vehicle has not been in production for several decades now, and this often means those buying one will not have the owner's manual that goes with the vehicle. One of the most common mistakes made by new owners is improperly mixing the fuel and oil. Without the owner's manual handy, this mistake is easy to understand. This article goes into how to properly mix the oil and fuel in a vintage Harley Davidson golf cart.
Before we go into the proper method for mixing the oil and fuel in a vintage Harley Davidson golf cart, let's be clear about one thing. Improper mixing can lead to severe damage in the engine. Once this damage occurs it has to be repaired if you want to operate the vehicle. These repairs can be time consuming and expensive. While you can certainly find Harley Davidson golf cart repair parts online, it is not always easy finding them. When you do find them, the price may be high simply due to the scarcity of these old parts. The best way to avoid having to make these repairs is to protect the engine by using the right fuel and oil mix.
If your Harley Davidson golf car has a recently rebuild engine, you want to use 3 ounces of good quality 2-cycle oil for each gallon of gas in the first tank of gas. Once this first tank is used up, decrease the oil to 1.5 ounces per gallon of gas. Keep in mind that this first tank (the one using 3 ounces of oil) may foul the plug. Be prepared to change out the plug before going to the second tank of gas. It is a lot less expensive to buy a new plug than it is to rebuild the engine.
Once you apply this mix to your Harley Davidson golf cart, you will be able to enjoy your vehicle without fear of burning the motor up. Take care of your vintage vehicle and don't forget to pass it on to someone who will care for it as you do.
Golf Carts: Not Just For Golfers Anymore
For gas powered carts, the cables need only be of sufficient size to operate the starter motor, which is only for a few seconds at a time. So that answer is no, the originally installed cables are plenty sufficient in size. For those of us who have the more plentiful, battery powered carts, the answer is somewhat more complicated. The short answer for us is, yes and no, depending upon what we expect from the cart or if modifications to the motor or controller have been made.
If the cart is absolutely bone stock (all original with no upgrades) and is used primarily as originally intended around the local course, the standard 6 AWG (aka 6 gauge or #6) cables are perfectly fine. Wire (cable) size is measured by a standard called American Wire Gauge or AWG and relates to the diameter or cross sectional area of the copper conductor itself. The smaller the AWG number, the larger the diameter, and hence, larger current carrying capacity. For example, a 2 AWG cable is larger than a 4 AWG which is larger than a 6 AWG. Most cart manufacturers use 6 AWG cables. The finest cables we have found so far are made by MaxiLink.com, which are super flexible and made for extreme duty electric vehicle use.
Ok, now for you guys that want better performance, we'll get a little more technical. The maximum current that will ever go through your cables is when the cart is at rest and you mash the gas pedal to the floor. At that point in time, the controller puts out the max power it is capable of, and the motor experiences what is called "locked rotor" current draw, which can be hundreds of amperes. When the motor is in a stalled state, it requires tremendous energy to get it spinning to the rated RPM. If the motor were to stay in the stalled state (if there was some mechanical restraint that would not allow it to turn) the high current would continue to be absorbed by the motor until it actually burned up the windings. Typically though, the motor begins to spin immediately, and the current drops down to 20 or so amperes within a few milliseconds (on a stock cart). There are four things that limit that maximum current; the resistance of the internal windings of the motor, the current capacity of the battery pack, the controller capacity and the resistance of the battery cables. The Battery Pack and Motor windings are pretty much fixed values. Keep these in mind because we will come back to them.
Aftermarket "high torque" or "high speed" motors installed to increase the carts performance are commonplace these days. Unfortunately, that additional performance requires additional power. The motor is only there to convert electrical energy into kinetic energy (not very efficiently either). High power motors have a lower internal resistance than stock, which in turn draws more current. If you remember from science class, power (in watts) is voltage (E) multiplied by the current (I). Since the voltage cannot go any higher than the battery's 48volts (or 36volts), the current increases in order to satisfy the power demand of the motor. Unfortunately, this is where the resistance of the battery cables come into play. As the current increases in a conductor, power is lost in the form of heat at a rate of I2R, where R is the cable resistance. In an ideal cable and to transfer max power, the cable resistance (R) should be zero ohms. Unfortunately all cables have some resistance. The cable resistance causes the voltage to drop (E=IR) and results in lost power to the motor. The solution; increase the size of the battery cables (the larger the cable the less the resistance). Of course, the cable diameter can only be increased within reasonable mechanical size limitations, but that is what is required to reap the full benefits of a high power aftermarket motor. Our example used the locked rotor current to explain the worst case effects. They are less drastic at partial throttle, where the current draw is significantly less. If you want to do the drag racing, burnouts, wheelies and such with your cart though, you will need the bigger cables to supply the required massive inrush of current to the motor. Although the resistance of the cables seems tiny (#6 = 0.00047ohms/ft vs. #2 = 0.00015 ohms/ft), the voltage drop is significant when large currents are present, which will reduce performance. So for the high power motor users out there, use large diameter cables and keep them as short as possible. Size will matter to you. Look for other articles by Randy Wade and check out www.digitaloverdrivesystems.com regularly for news, tips and performance products including the new Maxilink Extreme Duty EV cables.