KR0127090B1 - Mutual Induction Reactor Power Saver - Google Patents

Abstract

The present invention is for practical use of a power saving device using the voltage drop effect and the power factor improvement effect of the mutual induction reactor, which the inventor has filed in Patent No. 94-21274, and determines the voltage variation of the input power source or the load variation state of the load side to the load side. The present invention relates to a mutual induction reactor power saving device comprising the above-mentioned control device using a primary side voltage coil and a secondary side current coil of a mutual induction reactor. .

Description

Mutual Induction Reactor Power Saver

1 is a schematic diagram of a conventional mutual induction reactor

2 is a diagram illustrating the configuration of the present invention.

3 is an explanatory diagram of a control method of the present invention.

a is an explanatory diagram of primary voltage detection comparison

b is a comparison diagram of the secondary current coil voltage detection comparison

4 is a view showing an embodiment of a power saving device of the present invention

5 is a functional explanatory diagram according to an embodiment of FIG. 4 of the present invention.

a is a functional diagram of the primary voltage detection comparison amplifier

b is the function diagram of the secondary current coil voltage comparison amplifier

* Explanation of symbols for main parts of the drawings

1: Input power 2: Primary voltage coil

3: secondary current coil 4: mutual induction reactor

5: load 6: primary side voltage detection control means

7: secondary current coil voltage detection control means 12 primary voltage detecting terminal

15, 16: stop 17: hysteresis voltage signal generator

18, 19: Comparative Amch 20: Timer

23: primary side reference voltage 24: secondary side reference voltage

25,26: Relay V ₁ : Primary side voltage

V _Z : Current coil voltage V ₂ : Output voltage

I ₁ : Primary side current I ₂ : Secondary side current

L _P : Control point VI _IL : Primary voltage control reference voltage

V _ZL : Current coil voltage control reference voltage

The present invention relates to a power saving device. In particular, a mutual induction reactor capable of simultaneously obtaining a voltage drop and a power factor improvement effect is used. A reactor type power saving device.

As a reactor using a self-inducing interaction, which the inventors have applied for (94-21274), the mutual induction reactor is supplied with a proper voltage drop to the load side to obtain a power saving effect, and also to improve the power factor to obtain a power saving effect. The power supplied to the device has the function of shaping waveforms (including noise) and smoothing sudden inrush and surge voltages.

However, since these inductive reactors alone cannot properly cope with input / output voltage relationships according to load conditions or input voltage conditions, there are practical problems in using them for a wide range of load conditions and power supply conditions.

That is, in case of heavy load fluctuation such as motor operation, in normal operation, since the load ratio is usually 60 ~ 70% of the motor rating, if a certain voltage drops, and the power factor is improved, considerable power saving effect can be obtained while maintaining the motor operation normally. When starting up or suddenly increasing the load rate, it is necessary to raise the voltage or supply 100% of the power supply voltage for sufficient power supply. In addition, when the input power drops below a certain voltage, the voltage drop occurs so that the load-side voltage through the mutual induction reactor may interfere with normal operation. Therefore, it is necessary to increase the voltage or supply 100% of the power supply voltage.

SUMMARY OF THE INVENTION An object of the present invention is to provide a related control technique for realizing the power saving characteristics of a mutual induction reactor by creating a control device using the operating characteristics of the mutual induction reactor in solving the above problems.

It will be described in detail according to the accompanying drawings of the present invention.

The mutually induced reactor 4 shown in FIG. 1 has a primary side voltage coil 2 and a secondary side current coil 3 in parallel with respect to the input power source 1 as described in the specification of patent application 94-21274. This is electromagnetically coupled, and the secondary side current coil 3 is connected in series with the load 5 circuit.

In addition, the winding n ₁ of the primary side voltage coil 2 is determined by the voltage V ₁ of the input power source 1, and the winding n ₂ of the secondary side current coil 3 has any appropriate voltage drop amount ( V _Z ).

At this time, the output voltage (V ₂ ) is determined by V ₁ -V _Z and the power amount of V _Z × I ₂ is fed back to the primary power source 1 by mutual induction, thereby saving power.

However, such mutually induced reactor 4 is allowed a voltage range of 187 to 253V when the normal operating voltage range of the load 5 is 200 ± 15%, but for example the voltage of the secondary current coil 3 (V _Z ). Is 15V and the voltage of the input power source 1 is 190V, the voltage supplied to the load 5 is only 175V. In this case, the load cannot work normally rather than the power saving effect. In this case, at least a means of directly connecting the input power source 1 to the load side is required.

On the other hand, when the load 5 requires a large current due to a sudden load change or an overload, the current flowing in the secondary side current coil 3 also increases greatly, and at this time, the secondary side current coil voltage V _Z increases greatly, so the load side output voltage (V ₂ ) decreases so much that it cannot meet the demand power of the load 5 side.

Even in this case, since the reverse function is provided for the power saving function of the mutual induction reactor 4, there will be a practical problem.

The concept of the control configuration of the present invention detects the primary side voltage through the intermediate tap 12 of the primary side voltage coil 2 with the input power source 1 connected in parallel to the primary side voltage coil 2 as illustrated in Article 2. A primary side voltage detection control means (6) capable of comparative control is constructed to monitor the variation of the input division (1) and to monitor the amount of current (I ₂ ) flowing through the secondary side current coil (3). Secondary side current coil voltage detection control means (7) capable of detecting and comparing V _Z ) so that the input power (1) is directly supplied to the load (5) in accordance with the output signal of each means (6) (7) Or the contact terminals 27 and 28 of the switch switching means connected in series with the secondary side current coil 3 of the mutual induction reactor 4 can be suitably coped with according to the situation of the input power source 1 and the load condition. Function.

First, when the voltage of the input power source 1 becomes lower than the reference voltage (11, V _IL ) than the rated voltage 10 of FIG. 3 (a), a control method for automatically causing the load circuit to be directly connected to the input power source is fourth. The power saving device of the present invention will be described according to an embodiment.

Draw an intermediate tap 12 for detecting a constant voltage to the primary side voltage coil 2 of the mutual induction reactor 4, and between the lead line and the starting line of the primary side voltage coil 2 winding n ₁ . A known hysteresis circuit is configured to have a hysteresis operating point with respect to a reference voltage (23: V _IL ) as a comparison voltage, but the rectified, smoothed and rectified DC voltage is compared at a known bridge stop 15. It is applied as negative input of comparative amplifier 18.

The reference voltage 23 V _IL is applied to the positive input.

Such control characteristics by the circuit configurations 15, 17 and 18 are realized as shown in FIG.

That is, the power supply voltage of which the primary side voltage V ₁ of the input power supply 1 is lower than the reference voltage 23 V _IL applied to the positive (+) input of the comparator 18 is rectified, so that the negative voltage of the comparator 18 is rectified. When applied to the negative input, the output of the comparator 18 outputs an H state.

When this output is applied to one input of the OR gate, the OR gate output outputs this H state. At this time, the power relay 26 is turned ON, and the output passing through the NOT gate 22 is turned to L state, and the power relay 25 is OFF. Therefore, the load input line 29 is connected to the contact terminal 27 of the relay 26 that can be directly connected to the input power source (1).

On the contrary, when a normal voltage of more than the reference voltage V _IL is applied, the output of the comparison amplifier 18 becomes L at a voltage slightly higher than the low voltage detection control voltage in the hysteresis input characteristic, and the power relay 25 (T _RY ) is turned ON. The load input line 29 is connected to the contact terminal 28 of the relay 25 to enable normal power saving operation.

On the other hand, the load current detection control method according to the voltage V _Z variation of the secondary side current coil 3 when the current on the load side increases.

Since the secondary side current coil 3 of the mutually induced reactor 4 shown in FIG. 1 is connected in series with the load 5 side, the secondary side current coil ( The current (I ₂ ) of 3) increases and the current coil voltage (V _Z ) increases in proportion to the current according to E (V _Z ) = IR law.

The relationship between the current I ₂ and the current coil voltage V _Z is shown in FIG. 3B.

The present invention directly detects the current coil voltage (V _Z ) at the secondary side current coil (3) without using a separate current detecting device, and loads the input power supply (1) when the reference voltage (V _ZL ) is above a predetermined limit. (5) The control device is constructed so that the circuit is connected directly.

The load current detection control method of the present invention constituted by such an idea makes full-wave rectification of the voltages at both ends 13 and 14 of the secondary side current coil 3 of FIG. It is connected to the negative (-) input of the comparison amplifier 19, the reference voltage (24, V _IL ) is connected to the positive (+) input, and the output of the comparison amplifier 19 is connected to the input of the timer (20).

The timer 20 outputs a predetermined time when an input is triggered and uses a timer that can be retriggered.

Therefore, when the secondary side current coil voltage V _Z is full-wave rectified by the stop value 16, it is output as shown in FIG. 5 (b), and when the load current increases, for example, when the motor is started, the reference voltage V _ZL ) than is comparison amplifier (19 is the high current coil voltage (V _Z), the comparison amplifier 19) to the output is H state.

In the normal operation, when the current coil voltage V _Z is lowered and lower than the reference voltage V _ZL , the output of the comparison amplifier 19 is in the L state.

The timer 20 triggered by the output signal of the comparison amplifier 19 outputs the predetermined H state for a predetermined time, and maintains the continuous H state when a continuous signal is input within a predetermined time as shown in FIG.

This output of the timer 20 is connected to the other input of the OR gate 21, and the configuration thereafter is as described in the input power detection control circuit.

Therefore, when the output of the timer 20 is H, that is, when a large amount of current flows, such as starting a motor, the relay 26 (T _RY ) is turned on and the load input line 29 is connected to the contact terminal 27 of the relay 26. ) Is directly connected to the input power source (1).

Therefore, when enough power can be supplied to the load side and the load current falls below a proper current, the relay 25 (T _RY ) is turned on and the load input line 29 is connected to the contact terminal 28 of the relay 25 to save power. You can drive.

On the other hand, the relays 25 and 26 may use power semiconductor switching elements.

The present invention configured as described above can provide a power saving device that does not interfere with normal operation or normal operation of the load side by enabling the power saving characteristics of the mutual induction reactor to be practical and smoothly supplying power according to the input power variation and the load variation. .

Claims (4)

In the load circuit configuration of the mutual induction reactor 4, the middle tap 12 of the primary side voltage coil 2 is taken out and the primary side voltage between the winding starting points (.) Of the primary side voltage coil 2 is detected. A secondary side current coil voltage detection control means 7 having primary voltage detection control means 6 for comparative control and detecting and controlling the current coil voltage V _Z of the secondary side current coil 3, The output of the control device is processed by the OR gate 21, and the OR gate 21 outputs the load 5 input terminal 29 directly connected to the input power source 1 as the contact terminal 27 or the secondary side current coil ( 3) and an inductive reactor power saving device comprising a switch switching means capable of being connected in series with a contact terminal (28). The primary voltage detection control means (6) draws out an arbitrary voltage intermediate tap (12) of the primary side voltage coil (2) and converts the voltage with the winding starting point (.) To a known full-wave rectifier ( 15), the rectified output is connected to the negative (-) input of the comparison amplifier 18 having the hysteresis input 17 characteristic, and the reference voltage V _{IL is} connected to the positive (+) input. Mutual induction reactor power saving device. The secondary side current coil voltage detection control means (7) for detecting and comparing and controlling the current coil voltage (V _Z ) of the secondary side current coil (3) is characterized in that both ends (13) of the secondary side current coil (3). (14) to a known low-wave rectifier 16 and its rectifying output to the negative input of the comparison amplifier 19, to the positive input of the reference voltage (V _ZL ) Mutual induction reactor type power saving device, characterized in that by connecting the output of the amplifier (19) to the timer (20). 4. The mutual inductive reactor power saving device according to claim 3, wherein the timer (20) uses a timer that can be retriggered.