A.C. motor starting system - Patent Review 3970908

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BACKGROUND OF THE INVENTION

Capacitor-start single-phase induction motor control systems have been known heretofore. However, these prior systems have been subject to one or more disadvantages such as presence of hysteresis where ordinary electromagnetic relays are used for switching the start winding circuit making the pickup and dropout points hard to control, contact bounce creating electrical noise, bulkier requiring more mounting space, affected by temperature and other environmental factors, more subject to wear and deterioration, complex in number of parts and operation and adjustment, more costly, more connections to motor, require internal power supplies, inability to withstand sustained locked rotor conditions, and lack of sensitivity. While these prior systems have been useful for their intended purpose, this invention relates to improvements thereover.

SUMMARY OF THE INVENTION

This invention relates to A.C. motor starting systems and more particularly to capacitor-start systems for single-phase induction motors.

An object of the invention is to provide an improved capacitor-start system for an A.C. motor.

A more specific object of the invention is to provide a simple and effective control system for the start winding of a single-phase induction motor.

Another specific object of the invention is to provide an improved precision control system affording accurate control of motor start winding energization and de-energization points with respect to motor speed.

Another specific object of the invention is to provide a single-phase induction motor with an improved substantially static start winding control system that is small in size and accurate in operation.

Another specific object of the invention is to provide an improved capacitor-start control system for a single-phase induction motor that affords precise control and full-cycle condition of the start winding current.

Other objects and advantages of the invention will hereinafter appear.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 diagrammatically illustrates a capacitor-start induction-run control system for a single-phase induction motor constructed in accordance with the invention; and

FIG. 2, 3 and 4 graphically depict operating characteristics of the system of FIG. 1.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings, there is shown a circuit diagram of a capacitor-start control system for a single-phase induction motor M. This motor comprises a rotor or armature A, a main field winding MW and a start field winding STW. The system is powered from an alternating current source A.C. connectable to power supply lines L1 and L2. An on-off switch SW is connected to line L1.

The capacitor-start control system comprises a precision current detector such as a reed relay RR, a gating-type semiconductor means such as a bidirectional thyristor or Triac Q1, along with its small capacitor C1 and resistor R connected in series thereacross and a gate resistor Rg, and a phase-shift capacitor C2 of large size. As shown in the drawing, line L1 is connected through normally-open switch SW, operating coil RR1 of reed relay RR and main winding MW of the motor to line L1. This main winding is known also as the run winding of the motor.

Also in this capacitior-start system, junction X between switch SW and coil RR1 is connected through the main conduction path anodes of Triac Q1, large capacitor C2, and start winding STW of the motor to line L2. This same junction X is also connected through the reed switch or normally-open contacts RR2 of the reed relay and gate resistor Rg to the gate of Triac Q1. A dv/dt circuit comprising resistor R and small capacitor C1 in series is connected across the anodes of the Triac to slow down the rate of change of voltage thereacross thereby to prevent unwanted triggering of this Triac. Gate resistor Rg provides some current limiting to the gate to help prevent reed welding under certain conditions.

A typical single-phase, capacitor-start induction motor includes in addition to the armature or rotor assembly, sometimes referred to as a squirrel cage, and field winding, also called a run winding, an extra field winding that is used only in starting the motor. This is called a start winding. Its purpose is to provide a phase-shifted magnetic field with respect to the run winding magnetic field which, working together, provide a rotating magnetic field that induces a high starting torque on the rotor.

The curves in FIG. 2 show how effective a start winding can be. That is, the main winding and start winding together produce a much higher starting torque as shown by the solid line than can be obtained by the main winding alone as shown by the broken line. Once the rotor approaches synchronous speed, the start winding can be de-energized and the run winding left energized alone, the motor action now being that of a normal single-phase induction motor.

A typical system uses a centrifugal force switch. This switch is normally closed to energize the start winding. This switch is coupled to the rotor so that centrifugal force of rotation will cause the switch to open when the rotor RPM has attained a desired value.

There is also another means of sensing when the start winding circuit should be opened, such as sensing the current flowing in the run winding circuit. When the motor is first accelerating from zero speed, the initial run winding current is typically several times higher than what it decreases to at running speed. Thus, for specific load conditions, run winding current can be used to correlate to speed and can be sensed to open the start winding circuit at the desired speed level.

Such a current sensing system, designed properly, offers advantages over centrifugal switches with respect to mechanical complexity, space required, remote mounting, and limited switch mechanical and electrical life.

This current sensing has been used in FIG. 1. The circuit is very simple and strightforward. A Triac device is used as the switch for the start winding. It in turn is commutated by the small reed relay that is used as a precision current sensor. Although these two have been known heretofore, nevertheless when they are combined with the phase-shifting capacitor and the run and start windings, a unique combination results as will hereinafter appear.

FIG. 3 shows what happens when a large run winding current flows such as during initial start-up. As shown therein, the reed relay picks up on the leading side of each half-cycle of run winding current I.sub.run and drops out on the trailing side of each such half-cycle. A small coil operated reed switch is fast enough to do this and, thus, is a precise current sensor. The dropout point is at a lower current value than the pickup point due to the inherent magnetic characteristics of the reed. This characteristic will be used to advantage. Thus, the reed switch is closed through a wide range overlapping the center point of each run winding current half-cycle.

One would expect this to provide pulses of current to the start winding, that is, to chop up the current, but that is not the case. The reason for this is that the start winding current leads the run winding current by almost 90 degrees as shown in FIG. 3. Therefore, the reed switch closure widely overlaps the point where the start winding current passes through zero. As a result, the Triac is fired into conduction at the beginning of each start winding current half-cycle. And since the Triac inherently continues to conduct until its anode current approaches zero, the start winding is energized throughout each half-cycle and there is no chopping up of the current wave.

As illustrated in FIG. 4, it will be apparent that the reed relay, being a precision current sensor device, has a critical current amplitude at and above which it will pick up. When the run winding current decreases below this critical amplitude as the motor reaches the desired running speed, the reed switch will stop picking up. This, of course, means that the start winding will be deenergized and the point with respect to run winding current amplitude at which this happens can be accurately controlled.

However, at the run winding current amplitude slightly above this critical value as shown in FIG. 4, the reed relay will pick up on each half-cycle and will produce appreciable closure time due to the differential of pickup and dropout produced by the aforementioned magnetic characteristics. And this closure time will overlap the point where the start winding current wave passes through zero thereby to afford good control of the start winding with a very simple and economical circuit.

The reed has a long mechanical life. Thus, although it closes and opens at a fast rate during the motor starting time, once the motor is running, it no longer closes; thus there is no more wear. The accelerating time in most applications is very short, less than one second.

This reed relay remains a precise current sensor even over temperature ranges. Thus, the reed relay mmf (magnetomotive force) does not change even if the coil temperature and its resistance change since the mmf is proportional to amperes times turns of the coil and, therefore, is independent of coil resistance. Also, this reed relay has no metal core structure to change its characteristics is in an electromechanical relay device.

The reed closes symmetrically on positive and negative half-cycles. This is very important as any dissymmetry could produce a condition where D.C. components would be introduced into the motor, thus causing braking.

The performance of this system is not dependent on Triac gate characteristics such as gate sensitivity as in other systems that use a voltage threshold to determine the firing point. This is because of the low impedance of the gate-anode circuit whereby the Triac is force-fired into conduction at the start of each half-cycle. Thus, there is no requirement for Triac selection. In view of this, temperature changes affecting Triac gate characteristics do not affect the performance of this system. In other systems using Triacs, these characteristics and lack of symmetry can be a big problem.

Moreover, this system is capable of withstanding sustained locked rotor current without any damage to the sensor. This is because you can overdrive a reed without damage in that, once closed, additional mmf won't hurt it. Also, it has only a few turns and very low resistance so that the wattage dissipation in the coil is not great.

While the system hereinbefore described is effectively adapted to fulfill the objects stated, it is to be understood that the invention is not intended to be confined to the particular preferred embodiment of A.C. motor starting system disclosed, inasmuch as it is susceptible of various modifications without departing from the scope of the appended claims.

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