GB2081942A - Controlling direct current in inductive loads - Google Patents

Abstract

Electric power is applied directly to the inductive load (L, RL) through a switch (SW1) which closes the circuit to apply charging current to the inductive load for fixed periods of time. A discharge path (RS, D1) is provided for the inductive load when the switch opens the charging circuit. The discharge current is monitored by controller (20), and when the voltage it produces across resistor RS (VS) decays to a selected value (VR), the switch is again closed for the fixed charge time. By this means the current controller achieves high efficiency. The load may be a D.C. motor, solenoid or a similar device. The reference voltage (VR) may be set by a motor speed regulator feedback load. <IMAGE>

Description

SPECIFICATION Direct current control in inductive loads This invention relates to methods and apparatus for controlling the current in an inductive device from a source of direct current electric power with high energy efficiency, even though the supply voltage from the source may be subject to considerable variations.

The presently existing techniques for controlling the DC current in an inductive device may be placed in three major classes as follows: a) Varying the Effective Voltage at the Load This technique makes use of the relationship that the current, through a fixed resistance, is directly proportinal to the voltage applied. The voltage applied to the load is monitored and the power source is directly or indirectly adjusted to maintain the required voltage. Direct control of the power source (e.g. adjusting the current in the field winding of a generator) is most often impractical or impossible. Indirect control is accomplished by placing some form of electronic voltage regulator between the power source and the load. A series type regulator allows for rapid and precise control of the applied voltage but often dissipates 60%-90% of the supplied power.A switching type regulator normally dissipates less than 20% of the supplied power but suffers from slow response to step changes in output voltage requirements. The power inductors and the filter capacitors are often exotic and bulky for high current applications, although this is offset by the reduced needs of heat sinks.

A-limitation of using voltage control to set the current in the load is if the load resistance changes (within one unit from unit to unit), the current will change in inverse proportion since the feedback circuits that are usually employed have no means of detecting this change of resistance.

b, Passively Limiting the Current Through the Load This technique makes use of the relationship that current is inversely proportional to resistance with a constant applied voltage. Although the least energy efficient of the three techniques, this approach is most commonly used due to its simplicity. A resistor is installed between the load and the power source. The value of the resistor is chosen such that the combined series resistance of the control resistor and the load limits the current to the desired value. If different values of currents are needed in one application, different resistor values are installed in the circuit via mechanical or electronic switches. This approach suffers several serious setbacks.

Load resistance changes will change the load current, although not to the same extent as with voltage control. The resistor will dissipate as much or more power than a series regulator does (it is in fact a very simple series regulator). The most important limitation occurs when the supply voltage varies.

Since the resistance value of the load and contro: resistor combination remains constant, the supplied load current will vary proportionally with the supply voltage. This lack of regulation can be intolerable in most situations. This approach is also lacking in energy and volume efficiencies. The resistor value is designed to produce the desired current at the minimum supplied voltage. As the voltage increases, the supplied current increases proportionately. The power dissipation. however, increases according to the square of the current change (e.g., a doubling of the input outage doubles the current, but the power dissipation increases by four times). The resistor, then, must be of a power rating to withstand the stresses at the maximum voltage.

c) Actively Llmiting the Current Through the Load In this technique, an active device (e.g., a transistor) is used to limit the current supplied to the load. A current sensing element (e.g., a resistor) is placed in series with the load and the voltage across this element is monitored. The control device is then set via electronics to adjust its effective resistance to limit the current to the desired amount. This system has merits in that the supplied current remains constant whether the load resistance changes or the input voltage varies. The power dissipation is similar to that of a series pass regulator. If the current range required is large, the sensing element may present a problem.A value that develops sufficient feedback voltage at low currents may be too large to allow the high end of the current range to be used at minimum supply voltage (too much resistance in tha ').

Efficient direct current control in an inductive load is achieved in embodiments of the present invention by applying tho electric power directly to the inductive load element through a switching means which closes the circuit to apply a charging current to the inductive load for fixed on periods of time. A discharge path is provided for the inductive load when the switching means opens the charging circuit. In the preferred embodiment the discharge path comprises a freewheel diode and a resistor connected across the inductive load. The current in the discharge ,zath is monitored, and when the discharge current has decayed to a selected value, the switching means is again closed for the fixed on charge time.

Since the electric power is applied directly to the load element with very little loss in the control circuitry, substantially all of the electric power is dissipated in the inductive load itself.

The electromagnetic energy which is stored in the inductive load may be employed to actuate a mechanical device, such as a solenoid or motor.

The present invention is a current regulator for controlling the flow of current from a source of direct current power comprising an inductor for supplying electromagnetic energy to a mechanical load, switching means for supplying power from the source of direct current power to the inductor, means for actuating said switching means to apply electric current from the source to the inductor for predetermined periods of time during charging cycles, means for discharging electric current from the inductor during periods of time constituting discharging cycles intermediate the charging cycles, and means for actuating said switching means to apply electric current from the source to the inductor to initiate a charge cycle and to terminate each discharge cycle when the electric current which is discharged from the inductor during discharge cycles decays to a predetermined value.

The present invention is also a method of controlling the flow of current from a source of direct current electric power to an inductive device for supplying energy to a mechanical device comprising applying electric current from the source to the inductive device periodically for fixed periods of time during charging cycles in which the current changes from an initial value to a larger value determined by the period of time during which the charging cycle takes place, discharging electric current from the inductive device in discharge cycles during periods of time intermediate the charging cycles, and terminating each discharge cycle and initiating the charge cycle when the electric current decays during the discharge cycle to a predetermined value.

An embodiment of the present invention will now be described, by way of example, with reference to the accompanying drawings, in which: Figure 1 illustrates the principles upon which the present invention is based; Figure 2 is a diagram which illustrates the broad concept of the invention; Figure 3 shows the idealised waveforms for the apparatus of Fig. 2; Figure 4 shows the circuit of a type Fairchild 78S40 integrated circuit; Figure 5 shows how the circuit of Fig. 4 may be employed to provide the switching action; Figure 6 shows how the circuit of Fig. 4 may be employed to provide the switching action for applying higher power to an inductive load; Figure 7 shows how the circuit of Fig. 6 may be employed to provide the switching action for solenoid; and Figure 8 illustrates how the invention may be employed to control a DC motor.

Fig. 1(A) shows an inductor L placed in a series circuit with a switch SW, and power source VIN. The freewheel diode D1 or other unidirectional conductor for electric current is used to provide an alternate current path for the inductor when SW, is opened. Assuming no initial currents, the following holds true when SW, is closed: VL = L dl (1) dt

Due to the series circuit, when SW, is closed VL = VIN and is constant. Therefore, Equation (2) becomes: V, t t --f (3) L Complications set in when one realises that real-life inductors exhibit a finite resistance RL as illustrated in Fig. 1(B). As current starts to flow, this resistance drops part of the voltage VRL leaving a lower value for the inductance. Eventually VRL will equal VIN and the current will remain at a constant value. Solving Equation (2) for this condition yields the standard charge curve:

If the time period that iL is examined is short in relation to the time constant L/RL Equation (4) can be approximated:

where lo is the current at the start of the period t2 - t1 and t is a relative time from t1 to t2. The current now appears to be a series of linear ramps with slopes dependent upon the current present in the inductor.

When SW, is opened, the inductance opposes any change in current and will develop a sourcing potential (back EMF or inductive kick) to maintain the current. Since the coil voltage changes polarity, D1 conducts. Assuming a perfect diode, the inductor voltage and current become:

where lo is the current through the indicator at the time the switch is opened.

As with the charging current, if the change in discharge current examined is small in relation to to the current value, the discharge current curve portion can be-approximated:

where Ii is the current at the start of the period t2 - t1.

Fig. 1(C) shows how the invention can be practised using a switch SW2 in the place of the diode D,. When SW1 is closed to provide the charging current SW2 is open, and when SW, is open SW2 is closed to provide the discharge path.

The charging cycles to to t1 will be of less duration than the discharge cycles t, to t2. In order to obtain more constant regulation, the charging cycle should be very short, e.g., 200 microseconds.

The present invention operates on the above-outlined principles as illustrated in broad concept in Figs. 2 and 3.

The switch SW, is turned on and off by a switch control circuit 20. A resistor R5 is employed in the discharge current leg to provide a control voltage Vs to the control circuit which compares Vs to a preset reference voltage VR and actuates SW, when Vs is equal to VR.

The switch SW, is turned on for fixed periods of time to to t1. It is turned off for variable periods of time t1 to t2 which are determined by the time required for the IR drops across A5 to equal Vfi.

In operation, a known current 1o is established and flows in the inductor L when SW1 is closed at time to. The switch is opened after a brief fixed time t1. At this time the inductor current has reached a value 11. The current in the inductor-diode loop is monitored, and when the current has decayed back to the value of lo at time t2, the switch is closed aga for the fixed charge time. This cycle is then repeated.

In order to avoid unwanted resistance during the charge time, decay current sensing is done in the diode leg of the circuit. If the time period ti - to is kept k ., the effective current in the inductor is 10.

Fig. 3 shows idealised current waveforms for tl;e inductor and the switch of Fig. 2. If the charge time ti - to is short enough to keep the current change Ii - lo small compared to 10, the inductor current is essentially a fixed DC value. The average supply current effectively becomes:

or the inductor current times the duty cycle (ratio of on time to cycle time). The duty cycle can be approximated (ignoring sense resistor loss):

The system in Fig. 2 achieves the desired results in controlling DC currents in inductive loads.

The current in the coil is maintained by means of charge and discharge cycles, the circuit losses are minimised because the control element operates in a switching mode, and current sensing does not interfere with the main current source path. The current from the source VIN is applied directly to the load inductor L during the charge cycle to provide power efficiently, and the current produced by the inductor during the discharge cycle is also employed for efficiency. The energy that is stored in the inductance provides an efficiency that is not produced by the prior art devices. R5 has small resistance so that little power is lost in developing Vs. No capacitive element is used in developing Vs because immediate response is needed, and all of the stored energy should be in the inductance.

The switch control circuit 20 may be a standard commercially available integrated circuit for switch regulation, such as the Fairchild 78S40, the Texas Instruments TI 497, or the 1 524 or 3524 that are available from multiple sources. Such circuits may be connected to drive a transistor switch, sense the voltage drop across the current sense resistor R5 and control the off time until the preset reference level VA is reached.

Fig. 4 shows the circuit of the Fairchild 78840. It comprises a fixed on period switching regulator, a voltage reference source, and an uncommitted operational amplifier. The on time is controlled by the capacitance Ct.

Fig. 5 shows the regulator of Fig. 4 in a circuit for controlling the current in an inductive load.

This circuit can be used only if the input voltage and load currents are within the opertional limits of the regulator. In Fig. 5 the operational amplifier is used to correct the polarity of the current sense signal (from negative-going to positive-going) and adjust the effective value presented to the regulator comparator (at the setpoint current the voltage output of the amplifier will equal VA). C1 is chosen to give an on time consistent with the load time constant (L/R) and the response times of the switch, amplifier, and comparator. For a varied current output, VA would be varied.

Fig. 6 shows a similar current regulator for use with higher voltage and load current requirements. A separate switch circuit (Q,, Q2, Q3) was used because the input voltage and load currents of this system exceeded the operational limits of the 78S40. Rx was added to allow for electronic system turn-off. When the ON/OFF line is open, + V forces the output of the sense amplifier Al to always exceed VA, thus keeping the regulator from turning on. When the ON/OFF line is shortened to ground, the circuit operates in the normal mode. Cut was chosen at .Oluf to allow a 200 it sec on time, which is considerably smaller than the typical time constant of the chosen load (100 msec min.) but still slow enough to allow adequate operation of Al and the switch system.

Several DC solenoids were used as loads. The circuit controlled the currents at the desired value regardless of the type of solenoid used or the nominal voltage rating of the solenoid used.

Ct was varied in order to determine the change of efficiency resulting. Better circuit efficiency was noticed as the on time was decreased until the operational speeds of the amplifier and switch were reached.

The principle requirements of a solenoid driver are a high-current drive to move the plunger and, once the plunger has completed its travel, reduce the current to a much lower value that is sufficient to hold the plunger in place. Current practice is to apply the entire source supply across the solenoid for the time needed to move the solenoid. When this time is passed (either a fixed time period or plunger motion sensed by some device), a load reduction device (typically a resistor) is switched into the circuit (e.g., Patent No. 3,766,432).

Fig. 7 shows a solenoid driver using the current driver of Fig. 6. When the "OPEN" signal is applied to Q4, Q6 is turned on (allowing the regulator to operate). Also the one-shot multivibrator OS, is fired for a fixed period of time turning Q5 off during this time period. This applies the entire + V to VA of the regulator (via RA) and the RF/RI feedback ratio in the driver sets the value of the high pull-in current. The one-shot multivibrator is reset by an external plunger motion sensing system 30 having a switch which is closed when the solenoid is energised and moves its armature 31 upwardly. When the one-shot time is reset Q5 turns on.

This action reduces VA by the resistance ratio of R8/(RA + Ras). With a lower reference voltage to meet, the regulator reduces the output current by the same ratio so that Vs is substantially equal to VR, thus deriving the required holding current. When the "OPEN" signal is removed, Q6 is turned off preventing the regulator from supplying any current to the solenoid.

The circuit of Fig. 7 is particularly suitable for use in well logging during the drilling operation for the well, where the power for operating the solenoid is obtained from a turbine generator that is actuated by the flow of mud used in the drilling operation. In such applications the voltage VIN may vary from 48 to 96 volts so that good regulation is essential in order to obtain substantially constant current for actuating the solenoid. It is essential that overheating caused by the electric circuitry be avoided, and the efficiency of the apparatus of this invention satisfies that requirement.

Fig. 8 illustrates the application of the current controller to operate a DC motor.

A RPM sensor 40 provides a voltage that is proportional to the speed of rotation of the DC motor 42. The sensor 40 may be a tachometer or an encoding disk. A RPM set 44 serves to provide a voltage representative of the desired speed of rotation, and that may be adjustable if desired.

The outputs of RPM sensor 40 and RPM set 44 are applied to a comparing amplifier 46 and the resultant control signal VA is applied to constant current driver of the general type discussed above with reference to Figs. 6 or 7 which supplies a regulated current to the motor 42.

In this circuit, not only are the efficiencies of the current regulator attained, but only the power needed to maintain the requested speed is applied to the motor, thereby providing a very efficient means of controlling a DC motor that is not achieved by the prior art.

The DC motor control arrangement is especially suitable for use in electric vehicles that are battery powered because the efficiency of the circuit serves to conserve the power of the batteries. With such an arrangement, the vehicles can travel farther between charges than vehicles using other existing circuit arrangements.

The preferred embodiments employ a freewheeling diode or other unidirectional conductor means to provide the discharge path for the inductive load. However, a switching means electronically controlled by the control circuits may be employed to provide the discharge path, as illustrated in Fig. 1(C).

Claims (14)

1. A current regulator for controlling the flow of current from a source of direct current power comprising an inductor for supplying electromagnetic energy to a mechanical load, switching means for supplying power from the source of direct current power to the inductor, means for actuating said switching means to apply electric current from the source to the inductor for predetermined periods of time during charging cycles, means for discharging electric current from the inductor during periods of time constituting discharging cycles intermediate the charging cycles, and means for actuating said switching means to apply electric current from the source to the inductor to initiate a charge cycle and to terminate each discharge cycle when the electric current which is discharged from the inductor during discharge cycles decays to a predetermined value.

2. A current regulator as claimed in claim 1, wherein the means for discharging electric current from the inductor is a unidirectional conductive device.

3. A current regulator as claimed in claim 1, wherein the means for discharging electric current from the inductor is a freewheeling diode.

4. A current regulator as claimed in claim 1, wherein the charging cycle time is short enough to keep the current charge during each charging cycle small compared to the initial value of the charging current, thereby causing the inductor current to be substantially a fixed direct current value.

5. A current regulator as claimed in claim 1, wherein the inductor is the winding of a solenoid.

6. A current regulator as claimed in claim 1, wherein the inductor constitutes the windings of a direct current electric motor.

7. A current regulator for controlling the flow of current from a source of direct current power comprising: a) an inductive device for supplying electromagnetic energy to a mechanical device, b) means for applying electric current from the source to the inductive device periodically for fixed periods of time during charging cycles in which the current changes from an initial value to a larger value determined by the period of time during which the charging cycle takes place, c) means including a freewheeling diode for discharging electric current from the inductive device in discharge cycles during periods of time intermediate the charging cycles, and d) control means for initiating charging cycles and discharging cycles alternately, with each charging cycle being initiated when the current which is discharged from the inductive device decays to a value that is substantially equal to the initial value of the electric current at the beginning of a charge cycle.

8. A current regulator for controlling the flow of a current from a source of direct current electric power to an inductive load in which most of the electric power is to be dissipated by transfer of the electromagnetic energy in the load to a mechanical device comprising: a) switching means for applying electric current from the source to the inductive load periodically for predetermined periods of time during charging cycles in which the current changes from an initial value to a larger value determined by the period of time during which the charging cycle takes place, b) means for discharging electric current from the inductive load through a sensing resistor of small value which consumes a negligible amount of power compared to that consumed in the inductive load during periods of time in discharge cycles intermediate the charging cycles, and c) means responsive to the current that is discharged form the inductive load through the sensing resistor for actuating said switching means to apply electric current from the source to the inductive load to initiate a charging cycle and terminate a discharging cycle when the electric current which is discharged from the inductive load decays to a value that is substantially equal to said initial value of the electric current at the beginning of a charge cycle.

9. A current regulator for controlling the flow of current from a source of direct current power to an inductive load comprising: a) control means for applying electric current from the source to the inductive load, b) said control means providing charging cycles for applying energy to the inductive load and discharging cycles during which electric current is discharged from the inductive load and no energy is provided to the inductive load from sources other than the discharge current, and c) means responsive to said discharge current for actuating said control means to apply electric current from the source to the inductive load to initiate a charging cycle and terminate a discharging cycle when the electric current which is discharged from the inductive load decays to a predetermined value.

10. A current regulator for controlling the flow of current from a source of direct current power to an inductor comprising: a) an inductor for supplying electromagnetic energy to a mechanical load, b) switching means for supplying power from the source of direct current power to the inductor during charging cycles, c) means for discharging electric current from the inductor during discharging cycles when power is not supplied through the switching means to the inductor, d) means for providing a reference signal representative of the desired amount of current to be applied to the inductor, e) means for providing a control signal that varies in accordance with the decay of the current which is discharged from the inductor during discharge cycles, and f) control means responsive to said reference and control signals for actuating the switching means for fixed periods of time to initiate charging cycles when said control signal decays to a predetermined value with respect to the reference signal.

11. A current regulator for controlling the flow of current from a source of direct current power to an electric motor having inductive windings for receiving direct current power comprising: a) switching means for supplying power from the source of direct current power to the inductive windings of the electric motor, b) means for actuating said switching means to apply electric current from the source to said inductive windings for predetermined periods of time during charging cycles, c) means for discharging electric current from said inductive windings during periods of time constituting discharging cycles intermediate the charging cycles, d) means for sensing the decay of the electric current from said inductive windings during discharging cycles to provide a first control signal, e) means for sensing the speed of rotation of the electric motor to provide a second control signal, and f) control means responsive to said first and second control signals for initiating charge cycles and terminating discharge cycles when said control signals have a predetermined relationship.

1 2. A method of controlling the flow of current from a source of direct current electric power to an inductive device for supplying energy to a mechanical device comprising applying electric current from the source to the inductive device periodically for fixed periods of time during charging cycles in which the current changes from an initial value t6 a larger value determined by the period of time during which the charging cycle takes place, discharging electric current from the inductive device in discharge cycles during periods of time intermediate the charging cycles, and terminating each discharge cycle and initiating the charge cycle when the electric current decays during the discharge cycle to a predetermined value.

1 3. A method supplying energy from an inductive device to a mechanical device comprising causing the inductive device to apply energy to the mechanical device during charging cycles when the inductive device is energised from a source of direct current power, causing the inductive device to apply energy to the mechanical device during discharging cycles when the inductive device is discharged by applying current through a discharge path, and initiating charging cycles and discharging cycles alternately, with each charging cycle having a fixed period of time which is initiated when the current which is discharged from the inductive device decays to a predetermined value.

14. A current regulator for controlling the flow of current from a source of direct current power, substantially as hereinbefore described with reference to, and as shown in, the accompanying drawings.

1 5. A method of controlling the flow of current from a source of direct current power, substantially as hereinbefore described with reference to the accompanying drawings.