1. Field of the Invention
This invention relates to manual control of the speed of electrically powered vehicles. More particularly, this invention relates to an improvement in the user interface and control of vehicles having direct current motors with commutators, whose speed is controlled by pulse width modulated direct current, the improvement permitting the user temporary to elevate the power curve of the motor.
2. Description of the Related Art
To vary the speed of a direct current motor with commutators, modern systems typically employ pulse width modulation. In control by pulse width modulation, a circuit between a direct current source and a direct current drain is pulsed by opening and closing at a specific frequency, controlling the variable of interest by varying the duration or width of the pulse. In the case of controllers for direct current motors with commutators, the width of the pulse at a given frequency is directly related to motor speed. The voltage across the motor is always either in a full “on” condition or a full “off” condition, with the ratio of “on” duration to “off” duration determining average motor current and, hence, motor speed. For a given supply of current, power to the motor approaches that at dead short as the duration of the pulse or “on” condition grows broader, while power to the motor is reduced by shortening the duration of the pulse and is cut off altogether when the pulse duration is reduced to zero. In comparison with other means of varying direct current motor speed, such as resistive circuitry, pulse width modulation is a highly efficient means of control because it uses effectively all of the available current from the current source for driving the motor.
Embodiments of pulse width controllers for direct current motors typically use solid state devices for providing motor drive current at variable pulse width. In such controllers, typically a network comprising a plurality of solid state devices deployed in parallel is used to accommodate the relatively large amounts of current involved in driving the motor. Modern controllers commonly employ power MOSFET (metal oxide semiconductor field effect transistor) or IGBT (insulated gate bipolar transistor) network for such purpose.
A controller employing such a network is described in U.S. Pat. No. 4,626,750 issued to Post. Post employs a power MOSFET network as a high-speed switch to deliver power to a motor using a periodic on/off cycle generated in response to an operator input. Post's user interface comprises a throttle control allowing user input to a variable resistance to generate a signal representative of desired vehicle speed. Post's controller then compares that signal to a reference signal in order to determine the on/off cycle of conduction for the power MOSFET network. For example, at full speed, the power MOSFETS will conduct 100% of the time while at half speed, the power MOSFETS will conduct at approximately a 50% duty cycle.
Throttle operation for user regulation of motor speed in a D.C. motor powered electric vehicle is usually fashioned to be familiar to drivers accustomed to operating internal combustion engine powered vehicles: the power applied to the motor is proportional to displacement of the throttle control from its lowest power setting. So, for example, with a floorboard based throttle as in an automobile, power applied to the motor is proportional to the depression of the throttle in response to pressure from the operator's foot, while, with a handlebar grip based throttle as in a motor scooter or motorcycle, more power is applied to the motor as the operator rotates the grip. In any case, displacement of the throttle control from the lower power setting to higher power setting causes the motor to operate at a higher power level along its power curve.
Optimal tuning of a vehicle powered by an electric motor will balance the need for power against the need to conserve available charge, in order simultaneously to maximize performance, driving range and time before recharging is needed. Accordingly, the power curve for an electrically powered vehicle will generally be fixed to optimize these values. As known to those of skill in the art, the power curve for pulse width modulated inductive direct current motors is generally regulated by limiting the provision of current to the motor over time. Current limiting circuitry regulates the amount of current consumed by the vehicle over time to constrain vehicle performance within established standard performance parameters, which may be tuned to restrict vehicle performance within an optimized power curve.
At times, however, a need arises to elevate the vehicle's power curve temporarily above the constraints of the standard performance parameters, for example when passing other vehicles. At such times, the availability of extra power would greatly enhance the utility of the vehicle, while, if the duration of power elevation is short and only as needed, available charge will not be unduly diminished.
What is needed is control for a vehicle powered by an electric motor that, in response to a signal from the user, overrides current limiting circuitry, thereby allowing enhanced vehicle performance along an elevated power curve. What is needed further is a user interface whereby it is natural for the user normally to operate the vehicle within its standard power curve, elevating the vehicle's power curve only temporarily and as needed, so that available charge is conserved.
The present invention is a controller coupled with a user interface that together enable a user temporarily to elevate the power curve of motor operation in electric vehicles that utilize pulse width modulation controllers to regulate mechanical power supplied by commutator type direct current motors. The user interface comprises a switch which, in its normal state, allows the controller to operate the motor along a standard power curve that may be optimized to conserve electrical charge. When the user sets the switch out of its normal state, the controller elevates the current limit applied to vehicle operation, thereby enabling the motor to operate along an elevated power curve, permitting enhanced vehicle performance. In preferred embodiments, the user interface is fashioned so that standard operation is the preferred, default mode of operation of the vehicle and enhanced operation will be selected only temporarily and as needed.
Other objects, advantages, features and characteristics of the present invention, as well as methods, operation and function of related elements of structure, and the combination of parts and economies of deployment, will become apparent upon consideration of the following description and claims with reference to the accompanying drawings, all of which form a part of this specification, wherein:
As described above, pulse width modulation control of electric motor speed is accomplished by varying the width of pulses of voltage that are supplied to the electric motor over time. When the pulse duration is short, a smaller amount of current is supplied to the motor over time, while increasing the duration of pulses supplies more current to the motor, thereby increasing the power supplied by the motor.
As understood by persons of skill in the art, actual pulse width modulation controllers do not provide perfect square wave pulses. However, it also will be recognized that the depiction of such pulses as perfect square waves herein is sufficient to illustrate principles of operation so that persons of skill in the art may make and use the present invention.
Turning to
As discussed earlier, limiting current in general serves to keep the performance of the vehicle within a power curve that conserves available charge, enabling tuning the performance of the vehicle to an optimized power curve. However, it is desirable to limit the current supplied to induction motors over time in a number of other circumstances. As understood by persons of skill in the art, when the armature of a direct current motor is at rest it has very little resistance, and so if normal working voltage is applied, a large quantity of current can flow which may damage the commutator or armature windings. Current limiting functionality can prevent such excessive surges in current which could harm the motor and control circuitry. Heat generated by handling large quantities of current by the controller power transistors or by the motor can, if unchecked, result in damage to the controller or to the motor itself. Current limiting circuitry can be engaged when abnormally high temperatures are detected in the controller or motor, thereby preventing component damage. When available charge has become very low, operation of the motor at higher levels of current will result loss of all available charge in short order. Current limiting circuitry can be engaged when it is determined that available charge is low, in order to maximize remaining operating time or cruising range. For these and other reasons, pulse width modulated direct motor controllers generally have some form of current limiting circuitry that is called into play when conditions merit limiting current supplied to the motor over time.
Turning now to
While clipping pulses at the trailing edge is a commonplace practice for limiting current in pulse modulated controllers, persons of skill in the art understand that current limitation may be effected in manners not depicted herein, such as by clipping leading pulse edges or by simply eliminating certain sets of pulses in the pulse width modulation waveform altogether. The principles of the present invention apply to all such means and are not limited to any particular embodiment of current limiting functionality in pulse width modulated controllers.
As will be understood by those of skill in the art, means of providing an enhanced current limit to the motor, other than that depicted in
Turning now to
As generally implemented in MOSFET based pulse width modulating direct current motor controllers, the current delivered at peak voltage is limited by circuitry which thereby determines the applicable power curve. As understood by those of skill in the art, and as exemplified in embodiments depicted in Post supra, current usage in such systems is regulated by comparing voltage drop between power MOSFET drain and source electrodes, indicative of MOSFET current flow when the power MOSFETs are conducting, with a reference voltage corresponding to a desired current limit.
Comparator circuitry then limits the duty cycle of the power MOSFETs so that MOSFET current flow, as indicated by drain-source voltage, does not exceed the current limit indicated by the reference voltage.
Turning to
In the depicted embodiment, hyper-drive switch 502 is a normally open SPST type switch, in communication with the base of transistor 504. In normal operation with switch 502 open, the base of transistor 504 is supplied with voltage and therefore transistor 504 normally conducts current through standard mode variable resistor 506, thereby supplying normal voltage to comparator 508. Comparator 508 in general supplies reference voltage 510 to circuitry limiting current supplied to the MOSFET power transistors, as described above. In normal mode, the reference voltage signal 510 supplied by comparator 508 is based on voltage supplied by transistor 504 through standard mode variable resistor 506. Variable resistor 506 is tuned so that the reference voltage 510 supplied by comparator 508 normally corresponds to the current limit required for standard mode operation, which in preferred embodiments in turn corresponds to providing an optimized power curve for system performance.
When hyper-drive switch 502 is closed, base voltage to transistor 504 is grounded, thereby switching off voltage supplied by transistor 504 through standard mode variable resistor 506 to comparator 508. In such case, voltage supplied to comparator 508 instead derives from enhanced mode variable resistor 512. Variable resistor 512 is tuned so that the reference voltage 510, supplied by comparator 508 when hyper-drive switch 502 is closed, corresponds to the elevated current limit employed in the enhanced mode of system operation, corresponding in turn to a power curve wherein system performance is elevated. In the depicted embodiment, because switch 502 is normally open, the enhanced mode of operation will occur only when the user depresses the switch. The default, normal operation of the system will be in standard mode.
As will be appreciated by those of skill in the art, embodiments of the present invention differing from that depicted in
As will be further appreciated by those of skill in the art, the present invention as described does not exclude the limitation of current supplied to the power MOSFETs for reasons other than user selection of operation mode. For example, as discussed above, it is desirable to limit current when the motor is started because of the low resistance of the armature and the risk of motor damage from current surge. By way of further example, for purposes of safety and system protection, it may be desirable to limit MOSFET current based on measurements of the operating temperature of system components, such as controller circuitry or the motor itself. Yet further, it may be desirable to limit MOSFET current based upon a determination of low voltage in the system power supply in order to conserve available charge, effectively changing the power curve to favor such conservation. As will be appreciated by those of skill in the art, embodiments of the present invention do not prevent these and other additional controls limiting MOSFET current. As will be further appreciated, embodiments may be constructed wherein some such other controls (such as those directed toward safety and system protection) override the user's selection of enhanced mode operation. Rather than excluding such controls, the present invention is complementary to such additional controls, enabling embodiments accommodating the user's need for temporarily enhanced performance when appropriate.
Although the detailed descriptions above contain many specifics, these should not be construed as limiting the scope of the invention but as merely providing illustrations of some of the presently preferred embodiments of this invention. Various other embodiments and ramifications are possible within its scope, a number of which are discussed in general terms above. It is intended that the scope of the present invention encompass all means known to those of skill in the electronics arts to provide a temporarily enhanced power curve for vehicles employing pulse code modulated commutator motor controllers as generally described in the foregoing.
While the invention has been described with a certain degree of particularity, it should be recognized that elements thereof may be altered by persons skilled in the art without departing from the spirit and scope of the invention. Accordingly, the present invention is not intended to be limited to the specific forms set forth herein, but on the contrary, it is intended to cover such alternatives, modifications and equivalents as can be reasonably included within the scope of the invention. The invention is limited only by the following claims and their equivalents.