KR200352461Y1 - Device for saving electricity added automatic power factor control function - Google Patents

Abstract

The present invention; The present invention relates to an electric power saving device that increases the efficiency of electricity supplied to a load, thereby extending the life of an electric line and reducing electric charges.

The present invention as such; A reactor 10 for converting the primary voltage V1 into the secondary voltage V2 and supplying it to the load 5; An automatic switching switch 20 for turning on / off the primary voltage V1; A current sensor 30 for sensing a current value of the load applied voltage V2; A power saving mode opening and closing switch 40; An overcurrent detection control device 50 for turning off the automatic opening / closing switch when an overcurrent is detected; A plurality of magnetic switches 60 for turning on and off the output voltage of each tap of the reactor 10; A power meter 70 for adjusting the output voltage V2 of the reactor 10 according to the active power of the load; A plurality of power factor correction capacitors 80 for adjusting the power factor of the load 5; A plurality of capacitor open / close switches 90 for turning on / off a power factor correcting capacitor 80; And an automatic power factor regulator 100 that controls the plurality of capacitor open / close switches 90 to perform power factor correction of the load 5 when the power factor of the load 5 varies.

According to the present invention; By compensating the output voltage of the reactor and the power factor of the load automatically, it is possible to maximize the power saving effect and stabilize the equipment by maintaining the load efficiency.

Description

DEVICE FOR SAVING ELECTRICITY ADDED AUTOMATIC POWER FACTOR CONTROL FUNCTION}

The present invention relates to an electric power saving device with an automatic power factor adjustment function. More specifically, in implementing the electric power saving device, an additional power meter, a plurality of reactor tap select switches, an automatic power factor regulator and a plurality of power factor correction capacitors are installed. When the current flows in the load and the power factor changes according to the load situation, or when the power factor changes according to the increase or decrease of the current flowing in the load, the tap of the reactor is automatically selected to increase or decrease the output voltage of the reactor accordingly. At the same time, the present invention relates to an electric power saving device with an automatic power factor adjustment function that automatically compensates for a power factor of a load, thereby achieving stabilization of a facility and maximizing a power saving effect by maintaining a power usage efficiency of a load.

As is well known, energy consumption in Korea and other countries around the world is continuously increasing in proportion to the expansion of economic scale and the improvement of living standards. Accordingly, in order to meet the necessity of increasing electricity consumption and reducing production costs, the interest in power saving of each industry is increasing day by day. In this case, power saving means reducing power consumption by suppressing unnecessary power consumption and removing waste elements in using electric energy.

However, since the power consumption of the electrical load is proportional to the input voltage, if the input voltage is lowered more than necessary to reduce the power consumption, the power consumption is reduced, but it has a detrimental effect on the performance and life of the electric device. Therefore, when the input voltage is higher than a certain standard, the surplus power is cut off by supplying the output voltage lower when the input voltage is higher than a predetermined standard, and conversely, when the input voltage is low, the surplus power is bypassed to reduce the output voltage. There is a need for a technology that prevents this, and a product developed according to such a need is an electric saver.

As shown in FIG. 1, the conventional electric power saving device has a power supply unit 1, a reactor 2, a power factor correction capacitor C1, an automatic switching switch SW1, a current sensing sensor 3, and an overcurrent. It consisted of the detection control apparatus 4 and the power save mode switch SW2.

Hereinafter, an operation process of the above-described conventional electric power saving device will be described.

First, when the reactor 2 receives an applied voltage (V1: 220V or 380V, 60HZ in the case of three-phase power) from the power applying unit 1, the reactor 2 converts it into a load applied voltage V2 to the load 5. Supply. At this time, the magnitude of the voltage V2 supplied to the load 5 is defined as shown in Equation 1 below, and the load 5 is supplied with an I2 current as the load applied voltage V2 is supplied. do.

Where V1 represents the primary applied voltage, V2 represents the load voltage, N1 represents the primary winding number of the reactor, N2 represents the secondary winding number, I1 represents the primary current of the reactor, and I2 represents Indicates load current.

At this time, when the overcurrent detecting control device 4 detects whether the load 5 is short-circuited by the current detecting sensor 3, the automatic opening / closing switch SW1 is turned off (OFF) to the load 5. Shut off current.

On the other hand, if the phase difference between the voltage and the current flowing in the load (5) in this situation becomes much, the power factor is lowered, the efficiency of electricity is lowered, in order to compensate for this, the fixed capacity of the power factor correction capacitor (C1) as a temporary measure It is attached.

Here, for example, the electric savings expected through the above-described conventional electric saving device will be described. The difference between the primary voltage V1 and the secondary voltage V2 of the reactor 2 is shown in Equation 2 below. Obtained, and the primary power consumption W1 is as shown in Equation 3 below.

V1-V2 = differential voltage

Here, V1 represents the primary side applied voltage, and V2 represents the load voltage.

W1 = V1 × I1 × cosΦ

Here, V1 represents the primary side applied voltage, I1 represents the primary side applied current, and cos Φ represents the phase angles of V1 and I1.

However, in order to meet the formula ratio of Equation 1 as the secondary voltage V2 decreases, the primary current I1 must be reduced, so that the primary power consumption W1 in Equation 3 is reduced. This effect is reduced. That is, assuming that the load current consumes 10A when the primary voltage V1 is applied to the load 5 as it is without the reactor 2, the power consumption W1 consumes "220V x 10A = 2200W". However, when the output of the secondary voltage V2 is reduced by about 10% using the reactor 2 determined as the fixed ratio of the primary and secondary winding numbers N1 and N2, the primary voltage V1 is 220V. At this time, the secondary voltage (V2) becomes "V2 = 220V × 90% = 198V", and if the load current is used as 10A, the power consumption (W1) becomes "198V × 10A = 1980W" and the total electricity consumption is 10. % Decrease.

In the ideal case, "primary power (W1) = power consumption of the reactor + power consumed by the load (I2 x V2 x cosΦ), and the loss of the reactor 2 is constantly 0% regardless of the type of load. Assuming that the load voltage (V2) is reduced by about 10%, the primary power (V1) will always consume 10% reduced power regardless of the load conditions.

However, in the case of the conventional electric saving device as described above, even if the electricity saving effect of about 10% is maintained in the ideal case, when the current flows in the load, but the power factor fluctuates depending on the load condition, the current I2 of the load When increasing, or when the current I2 of the load decreases, it causes a fatal disadvantage that the electricity saving effect decreases or the burden of equipment damage increases. The problems occurring in these three cases will be described in more detail as follows. .

First, if a current flows in the load but the power factor varies depending on the load condition, the conventional power saving device changes the power factor of the load since the power factor adjustment of the load depends only on a fixed capacity capacitor C1 without a coil component. Not only does it react sensitively, but there are limitations, and even though the power factor of the load becomes worse, it can not cope with this, resulting in a loss of load, which leads to an increased power, and in the worst case, the facility may be damaged. There was a problem.

Second, when the current I2 of the load increases, the ratio of the primary and secondary winding numbers N1 and N2 of the reactor is constant, so the ratio of the primary and secondary voltages V1 and V2 is also constant. Therefore, when the secondary current I2 increases, the primary current I1 must increase simultaneously. This means that the secondary voltage (V2) has already been reduced to about 10%, so if the current increases by 5%, the primary current (I1) must also increase by 5% at the same time. However, the load may be an inductive load, or a capacitive load, which is not a simple load that always responds immediately, such as a resistor, and thus may be a capacitive load, so that the phase difference (cosΦ) may change in the formula of "I2 × V2 × have. In this case, it is not just a matter of increasing the secondary current (I2) but also considering the phase difference (cosΦ) .In this case, if the secondary current (I2) increases by 10% but the phase difference (cosΦ) decreases by 10% "Load power = V2 x I2 x 1.1 x cosphi x 0.9 = V2 x I2 x 0.99", resulting in only 0.01% reduction in load power. However, since the load power factor is reduced by 10%, the secondary load side results in a 10% reduction in electric power, which causes a serious problem, but the primary load side remains unchanged. In conclusion, when the current I2 of the load increases, the power factor fluctuates as the phase difference between the voltage and the current flowing through the load occurs, so that a 10% savings cannot be guaranteed. there was.

Third, when the current I2 of the load decreases, if the secondary current I2 decreases in the load power formula, the load power decreases naturally and the primary current I1 also decreases. However, even in this case, the power factor fluctuates as the phase difference (cosΦ) between the voltage and the current flowing through the load is generated, thereby preventing a 10% saving effect.

Therefore, the present invention has been made to solve the conventional problems as described above, the object of the present invention is to compensate by adjusting the power factor automatically according to the load condition when the current flows in the load but the power factor is changed according to the load condition In order to prevent load loss and wasted power, the present invention provides an electric power saving device with an automatic power factor adjustment function to reduce the burden of facility damage.

Another purpose is to implement a power saver by installing a separate power meter, a reactor's tap selector switch, and an automatic power factor regulator, selecting the load voltage to increase the reactor's tap voltage when the load's current increases. According to the present invention, the power factor is automatically compensated to maintain a constant supply efficiency, thereby providing an electric power saving device with an automatic power factor adjustment function for maximizing the stability and power saving effect of the facility.

Another purpose is to install a separate power meter, reactor tap selector switch, and automatic power factor regulator in order to implement an electric saver. According to the present invention, the power factor is automatically compensated to maintain a constant supply efficiency, thereby providing an electric power saving device with an automatic power factor adjustment function for maximizing the stability and power saving effect of the facility.

In order to achieve the above object, an electric power saving device having an automatic power factor adjustment function of the present invention has a plurality of tab terminals attached thereto, and receives a primary voltage V1 from a power supply unit, and loads the voltage into a load applied voltage V2. A reactor for converting and supplying the load to the load;

An auto-opening switch mounted between the power supply unit and the reactor to allow the primary voltage V1 to pass or cut off;

A current sensor mounted between the reactor and the load to sense a current value of a load applied voltage V2;

A power saving mode opening and closing switch mounted between the reactor and the current sensing sensor;

An overcurrent detection control device which cuts off the primary power by turning off the automatic switching switch when the overcurrent is detected by the current detection sensor;

A plurality of magnetic switches, one side of which is connected to each tab of the reactor and the other side of which is connected to the power saving mode opening and closing switch to perform a switching operation;

After obtaining the active power of the load by measuring the voltage (V2) and the current (I2) of the load, and controlling the on / off of the plurality of magnetic switches in accordance with the power of the load to adjust the output voltage (V2) of the reactor Regulating power meter;

A plurality of power factor correction capacitors each mounted in parallel to adjust the power factor according to the voltage V2 and current I2 of the load;

A plurality of capacitor opening / closing switches connected to the plurality of power factor correction capacitors in a one-to-one correspondence to turn on / off a connection of the power factor correction capacitors; And

When the power factor fluctuates according to the voltage V2 and the current I2 of the load, an automatic power factor regulator for controlling the power factor correction operation of the load through the plurality of power factor correction capacitors is performed by controlling the plurality of capacitor open / close switches. Characterized in that consisting of.

1 is a functional block diagram showing the configuration of a conventional electric power saving device,

Figure 2 is a functional block diagram showing the configuration of an electric power saving device with an automatic power factor adjustment function according to an embodiment of the present invention,

FIG. 3 is a graph illustrating a relationship between voltage, current, and power factor in describing an electric power saving device to which an automatic power factor adjustment function according to FIG. 2 is added.

<Explanation of symbols for the main parts of the drawings>

10: Reactor 20: Automatic switch

30: current sensor 40: power saving mode switch

50: overcurrent detection control device 60: magnetic switch

70: power meter 80: power factor correction capacitor

90: condenser opening and closing switch 100: automatic power factor regulator

Hereinafter, with reference to the accompanying drawings, an electric power saving device with an automatic power factor adjustment function according to an embodiment of the present invention will be described in detail. In the following description, a specific apparatus is illustrated, which is only an embodiment provided to aid the overall understanding of the present invention, and it will be apparent to those skilled in the art that such specific matters may be changed or changed within the scope of the present invention.

2 is a functional block diagram showing an electric power saving device with an automatic power factor adjustment function according to an embodiment of the present invention, the electric power saving device with an automatic power factor adjustment function according to an embodiment of the present invention is a reactor 10 ), Automatic switch 20, current sensor 30, power saving mode switch 40, overcurrent detection control device 50, a plurality of magnetic switches 60, power meter 70, a plurality of power factor correction capacitor 80, a plurality of capacitor open / close switches 90 and an automatic power factor regulator 100.

In this case, the reactor 100 has a plurality of tab terminals attached thereto as shown in FIG. 2, and receives the primary voltage V1 from the power supply unit 1 to convert the load voltage V2 into a load. (5) serves as a supply.

In addition, the automatic opening and closing switch 20 is mounted between the power applying unit 1 and the reactor 10, the ON / OFF (ON / OFF) under the control of the overcurrent detection control device 50 is the 1 It is a switch that passes or cuts off the difference voltage V1.

On the other hand, the current sensor 30 is mounted between the reactor 10 and the load 5, and detects the current value of the load applied voltage (V2) and outputs to the overcurrent detection control device 50 Do it.

In addition, the power saving mode opening and closing switch 40 is a switch mounted between the reactor 10 and the current sensor (30).

On the other hand, the overcurrent detection control device 50 serves to cut off the primary power by turning off the automatic switch 20 when the overcurrent is detected by the current sensor 30.

In addition, the plurality of magnetic switches 60 are each connected to each tab of the reactor 10 and the other side is connected to the power saving mode switch 40, respectively, under the control of the power meter 70 It is turned on / off to adjust the output voltage V2 of the reactor 10.

The power meter 70 measures the voltage V2 and the current I2 of the load 5 to obtain the effective power of the load 5, and then, according to the power of the load 5, It controls the on / off of the magnetic switch 60 to adjust the output voltage (V2) of the reactor 10. In this case, the power meter 70 adjusts the output voltage V2 of the reactor 10 according to the power of the load 5 when the power of the load 5 decreases. By selecting one of the tab terminals of the control of the on / off of the plurality of magnetic switches 60 so that the output of the voltage is selected in a step gradually lowered, if the power of the load (5) increases the reactor 10 By selecting one of the tab terminals of the to control the on / off of the plurality of magnetic switches 60 so that the output of the voltage is selected in a higher step.

On the other hand, the plurality of power factor correction capacitors 80 are mounted in parallel to adjust the power factor according to the voltage V2 and the current I2 of the load 5, respectively, each having a coil component.

In addition, the plurality of capacitor open / close switches 90 are connected to the plurality of power factor correction capacitors 80 so as to correspond one-to-one to each other, thereby turning on the connection of the power factor correction capacitor 80 under the control of the automatic power factor regulator 100. On / off switch.

On the other hand, the automatic power factor regulator 100 controls the plurality of capacitor open / close switches 90 when the power factor fluctuates depending on the voltage V2 and the current I2 of the load 5. The power factor correction operation of the load 5 through the correction capacitor 80, the automatic power factor regulator 100 is the on / off state of the power saving mode switch 40 and the power meter 70 Regardless of the operating state of the power factor correction according to the variation of the load 5 is implemented to always be made.

Next, an operation process of the electric power saving device to which the automatic power factor adjustment function is added according to an embodiment of the present invention having the above configuration will be described with reference to FIGS. 2 and 3.

First, the reactor 100 receives the primary voltage V1 from the power applying unit 1 and converts it into a load applying voltage V2, and then the automatic switch 20 and the power saving mode switch 40 Is supplied to the load (5). At this time, the power saving mode opening and closing switch 40 is ON (B terminal connection) so that the output voltage V2 of the reactor 10 is supplied to the load 5 as shown in FIG. . In addition, the current sensor 30 detects the current value of the load applied voltage (V2) and outputs it to the overcurrent detection control device (50).

In such a situation, when the current supplied to the load 5 is detected as the overcurrent by the current sensor 30, the overcurrent detection control device 50 turns off the automatic opening and closing switch 20 (OFF) Shut down primary power.

On the other hand, when the current supplied to the load 5 is not in an overcurrent state, the wattmeter 70 measures the voltage V2 and the current I2 of the load 5 to make the load 5 effective. Find the power. Then, the power meter 70 turns on only one corresponding switch of the plurality of magnetic switches 60 so that the output of the voltage of the reactor 10 is gradually selected when the power of the load 5 decreases. (ON), which means that only one of the corresponding taps of the tap terminals of the plurality of reactors 10 is selected to control the output of the voltage to be gradually selected. On the other hand, when the power of the load 5 is increased, the power meter 70 turns on only one corresponding switch of the plurality of magnetic switches 60 so that the output of the voltage of the reactor 10 is gradually selected. (ON), which means that only one of the corresponding taps of the tab terminals of the plurality of reactors 10 is selected to control the output of the voltage to be gradually selected.

The automatic power factor regulator 100 controls the plurality of capacitor open / close switches 90 when the power factor fluctuates depending on the voltage V2 and the current I2 of the load 5. The power factor correction operation of the load 5 through the correction capacitor 80 is performed. At this time, a detailed operation process of the automatic power factor regulator 100 will be described with reference to FIG. 3.

First, in a typical electric circuit, the phase difference between voltage and current is caused by the characteristics of the load 5, which is called cosine angle or phase angle. That is, since the phase angle when the difference in phase is 0 degrees as shown in Fig. 3 is "cos0 = 1", voltage and current are supplied to the load 5 without any additional loss. Thus, this situation can be said to be an optimal situation.

However, in a typical electric circuit, the phase of the voltage sometimes precedes the phase of the current, which is called a phase (induction) as shown in FIG. On the other hand, the voltage phase is later than the phase of the current also occurs, this case is called ground (capacitive).

Therefore, the automatic power factor regulator 100 connects the corresponding power factor correcting capacitor 80 by turning on the corresponding ones of the plurality of capacitor open / close switches 90 when the load characteristic is a true phase. While the phase angle φ of 5) is set to "0", when the ground angle is set, the phase angle φ of the load 5 is set to "0" using the coil component built in the power factor correction capacitor 80. Is made of ". The power factor correction operation is performed by turning on or off one or more power factor correction capacitors, thereby enabling more accurate power factor correction.

Hereinafter, the result of comparing the performance of the present invention and the performance of the conventional method will be described in detail. Here, assuming that "W2 = V2 x I2 x cosφ" and the trans power is constant at "W1 = trans power + W2", a relation proportional to "W1 = W2" is established.

First, a case in which the power factor correction is not performed as in the conventional method described above is as follows.

1) when V2 is reduced by 10% and cosφ is "1.0", "W1 = 0.90";

2) If V2 is reduced by 10% and cosφ is "0.9", "W1 = 0.81": the power tries to fill the shortfall of "0.09", causing overload problem;

3) If V2 is reduced by 10% and cosφ is "0.5", "W1 = 0.45": the power will try to fill the shortage of "0.45", causing overload problem, and the system is unstable, which may cause fire or system damage This happens.

On the other hand, when the load current fluctuates in the above-described present invention, the case in which the power meter 70 does not operate but only the automatic power factor regulator 100 operates will be described below.

1) when V2 is reduced by 10% and cosφ is "1.0", "W1 = 0.90";

2) If V2 is reduced by 10% and cosφ is "0.9", then automatic power factor correction results in "W1 = 0.89";

3) When V2 is reduced by 10% and cosφ is "0.5", automatic power factor correction results in "W1 = 0.89";

Therefore, according to the automatic power factor compensation according to the present invention, it is possible to expect a constant electric energy saving effect corresponding to the difference between V1 and V2 by maintaining W1 constant.

In addition, the case in which the power meter 70 and the automatic power factor regulator 100 operate in the above-described present invention will be described. In this case, it is assumed that the tap voltage of the reactor 10 is provided with 210V, 205V, 200V, and 195V. Of course, the tap voltage can be changed to suit the purpose.

1) When "W2 = 210V x 5A" is normal, 5% reduction compared to the primary 220V x 5A at all times;

2) when the measured current of the power meter 70 is reduced to "4.0", the voltage is adjusted to 205V to obtain a 7% reduction effect to 820W;

3) when the measured current of the power meter 70 is reduced to "3.0", if the voltage is adjusted to 200V to obtain a 10% reduction effect to 600W;

4) when the measured current of the power meter 70 is reduced to "2.5", if the voltage is adjusted to 195V to obtain a 12% reduction effect to 487W;

This assumes a case of outputting four voltages arbitrarily, and the system stability is greatly improved as well as a certain saving effect in such an operation.

Although the present invention has been described in more detail with reference to some embodiments, the present invention is not necessarily limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention.

As described above, according to the electric power saving device having an automatic power factor adjustment function according to the present invention, when the current flows in the load but the power factor varies according to the load condition, the power factor is automatically adjusted according to the load condition to compensate for the loss. In addition, it prevents load loss and wasted power, thereby reducing the burden of equipment damage.

In addition, according to the electric power saving device with the automatic power factor adjustment function according to the present invention, when implementing the electric power saver by installing a separate power meter, a tap select switch of the reactor, and an automatic power factor regulator, when the load current increases After selecting the tap voltage of the reactor in the increasing direction, the power factor is automatically compensated according to the load condition to maintain a constant supply efficiency, thereby maximizing the stability and power saving effect of the facility.

In addition, according to the electric power saving device with the automatic power factor adjustment function according to the present invention, in implementing the electric power saver, a separate power meter, a tap select switch of the reactor, and an automatic power factor regulator are installed to reduce the load current. When you select the direction to reduce the tap voltage of the reactor, the power factor is automatically compensated according to the load condition to maintain a constant load supply efficiency, thereby maximizing the stability and power saving effect of the equipment. .

Claims (4)

A reactor having a plurality of tab terminals attached thereto, receiving a primary voltage V1 from a power supply unit, converting the load voltage into a load applied voltage V2, and supplying the load to a load; An auto-opening switch mounted between the power supply unit and the reactor to allow the primary voltage V1 to pass or cut off; A current sensor mounted between the reactor and the load to sense a current value of a load applied voltage V2; A power saving mode opening and closing switch mounted between the reactor and the current sensing sensor; An overcurrent detection control device which cuts off the primary power by turning off the automatic switching switch when the overcurrent is detected by the current detection sensor; A plurality of magnetic switches, one side of which is connected to each tab of the reactor and the other side of which is connected to the power saving mode opening and closing switch to perform a switching operation; After obtaining the active power of the load by measuring the voltage (V2) and the current (I2) of the load, and controlling the on / off of the plurality of magnetic switches in accordance with the power of the load to adjust the output voltage (V2) of the reactor Regulating power meter; A plurality of power factor correction capacitors each mounted in parallel to adjust the power factor according to the voltage V2 and current I2 of the load; A plurality of capacitor opening / closing switches connected to the plurality of power factor correction capacitors in a one-to-one correspondence to turn on / off a connection of the power factor correction capacitors; And When the power factor fluctuates according to the voltage V2 and the current I2 of the load, an automatic power factor regulator for controlling the power factor correction operation of the load through the plurality of power factor correction capacitors is performed by controlling the plurality of capacitor open / close switches. Electric power saving device with an automatic power factor adjustment function, characterized in that consisting of. The method of claim 1, The power meter controls on / off of the plurality of magnetic switches to select one of the tap terminals of the plurality of reactors when the power of the load decreases so that the output of the voltage is gradually selected. When the power is increased, the electric power saving function with the automatic power factor adjustment function is selected by controlling one of the tap terminals of the reactor to control the on / off of the plurality of magnetic switches so that the output of the voltage is gradually selected. Device. The method of claim 1, And said plurality of power factor correction capacitors each use a capacitor having a built-in coil component. The method of claim 1, The automatic power factor adjuster is an electric power factor adjustment function that is implemented so that the power factor correction is always performed according to the load change irrespective of the on / off state of the power saving mode switching switch and the operating state of the power meter. Saving device.