KR20220146869A - Electronic motor protection relay - Google Patents

Abstract

The present invention proposes an electronic motor protection relay which is able to calculate motor power and power volume. According to an embodiment of the present invention, the electronic motor protection relay comprises: a first switching unit arranged on a three-phase power end of a motor and switching the electric connection between the three-phase power end of the motor and a three-phase power input end of a power system; a second switching unit formed parallel to the first switching unit, arranged between the three-phase power end of the motor and the three-phase power input end, and connecting or blocking at least two-phase power end among the three-phase power end and at least two-phase power input end among the three-phase power input end by making the power and input ends cross each other; and a relay control unit selectively controlling the electric switching connection between the first switching unit and the second switching unit, and controlling the normal-directional or reverse-directional start of the motor to measure the power or power volume of the motor. The present invention is able to calculate and measure the power and power volume applied to the motor in real time regardless of the normal-directional or reverse-directional starting method of the motor.

Description

ELECTRONIC MOTOR PROTECTION RELAY

The present invention relates to a motor protection relay, and more particularly, to an electronic motor protection relay capable of calculating and measuring power and an amount of power applied to a motor in real time regardless of a forward or reverse starting method of the motor.

In general, an electric motor protection relay is a device that protects the motor in the event of an abnormality or accident by detecting abnormalities and accidents such as overcurrent, phase loss, unbalance, reverse phase, and ground fault occurring during motor starting and operation. to be.

The electronic motor protection relay blocks the power applied to the motor by opening the contact point of the breaker or relay when an abnormality or accident occurs in the motor of the power system or the load to which the motor is connected, thereby protecting the motor and its load from damage due to failure. .

The motor used in the power system can perform forward or reverse start according to the type of load. In other words, a motor applied to a load operating in only one preset direction may be started only in a forward direction corresponding to one direction. On the other hand, a motor applied to a load that is switched in the forward or reverse direction should be switched and started in the forward or reverse direction.

1 is a view showing the directionality and flow time difference of voltage and current applied to a three-phase power stage of a motor.

Referring first to Figure 1 (a), the electronic motor protection relay is a three-phase power stage (a, b, c) of the motor preset voltage (Va, Vb, Vc) and current (Ia, Ib, Ic), respectively It can be applied to start the motor in the forward direction. On the other hand, the electronic motor protection relay crosses the voltages (Va,Vc) and currents (Ia,Ic) at the power stages (a,c) of one and three phases (a,c) of the three-phase power stages (a,b,c) of the motor. The motor can be started in the reverse direction by supplying the

However, the conventional electronic motor protection relay measures the voltages (Va, Vb, Vc) and currents (Ia, Ib, Ic) of the three-phase power stage (a, b, c) and applies them to the motor when the motor is started in the forward direction. Although it was possible to measure the amount of wattage used, there was a problem that the wattage of the motor could not be measured when starting in the reverse direction.

Specifically, when the motor is started in the forward direction, when the directions of the three-phase voltages Va, Vb, and Vc are sequentially matched to the preset reference direction V, the voltage of the three-phase power stage (a, b, c) Since the directions of (Va, Vb, Vc) and current (Ia, Ib, Ic) are respectively located in the directions of the 1st and 4th quadrants (upper right, lower right), measure both the voltage level and the amount of current at a certain location. can do.

However, when the motor is started in the reverse direction, since the voltages Va, Vc and the currents Ia, Ic are cross-connected to the power terminals a and c of the 1-phase and 3-phase, the 1-phase and 3-phase voltages (Va, Vc) are cross-connected. ) When each direction corresponds to the preset reference direction (V), the currents of phase 1 and phase 3 (Ia, Ic) are located in the 2nd and 3rd quadrants (upper left and lower left), respectively, so their respective current amounts and power could not be measured.

Therefore, the conventional motor relay measures the voltage (Va, Vb, Vc) and current (Ia, Ib, Ic) of the three-phase power stage (a, b, c) only when the motor is started in the forward direction, and the reverse direction of the motor At the same time, the power amount of the three-phase power stage (a, b, c) was treated as “0” or the amount of power measured in error was shown outside as it is.

The present invention is to solve the above problems, and it is an object of the present invention to provide an electronic motor protection relay that can measure and calculate the amount of power and electric power applied to the motor in real time regardless of the forward or reverse starting method of the motor. .

In addition, the present invention provides an electronic motor protection relay that can prevent accidents due to motor malfunction in the power system according to the detection result of the amount of motor power measured in real time regardless of the forward or reverse starting method of the motor. have.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the appended claims.

Electronic motor protection relay according to an embodiment of the present invention for achieving the above object is disposed in the three-phase power stage of the motor to switch the electrical connection between the three-phase power stage of the motor and the three-phase power input stage of the power system 1 switching unit and the first switching unit are disposed between the three-phase power stage and the three-phase power input stage of the motor in a parallel structure to cross the power input stage of at least two of the three-phase power stage and the power input stage of at least two of the three-phase power input stage A second switching unit for connecting or disconnecting, and a relay control unit for selectively controlling the electrical switching connection of the first and second switching units to control forward or reverse starting of the motor and to measure the electric power or amount of power of the motor.

The electronic motor protection relay of the present invention detects and digitally converts power supplied to each of the three-phase power stages of the motor, and a power conversion unit for supplying wattage information of each of the three-phase power stages to the relay control unit, and the three-phase power of the motor It further includes at least one current converter that detects the current supplied to the stage and converts it digitally, and supplies the current amount information of each of the three-phase power stages to the relay control unit.

The first switching unit switches an electrical connection between the three-phase power stage of the motor and the three-phase power input stage in response to a first switching control signal from the relay control unit, and the second switching unit responds to the second switching control signal from the relay control unit Accordingly, the power stage of at least two phases of the three-phase power stage and the power input stage of at least two phases of the three-phase power input stage are connected or cut off by crossing each other.

The second switching unit electrically connects the first-phase power stage of the motor to the third-phase power input end of the power system according to the second switching control signal from the relay control unit, and the third-phase power stage of the motor is the first of the power system It is electrically connected to the phase power input terminal, and the second phase power terminal of the motor is electrically connected to the second phase power input terminal of the power system so that the motor is started in the reverse direction.

When the motor is started in the reverse direction, the relay control unit multiplies the voltage values or current values of the first and third phase power stages that are cross-connected with each other among the three-phase power stages to perform a multiplication operation, so that the power amount of the first and third phase power stages , and the amount of power of the second phase power stage is measured by calculating the voltage value and the amount of current of the second phase power stage.

The second switching unit electrically connects the first phase power stage of the motor to the second phase power input terminal of the power system according to the second switching control signal from the relay control unit, and the second phase power stage of the motor is the first of the power system It is electrically connected to the phase power input terminal, and the third phase power terminal of the motor is electrically connected to the third phase power input terminal of the power system so that the motor is started in the reverse direction.

When the motor is started in the reverse direction, the relay control unit measures the amount of power of the first and second phase power stages by exchanging the voltage values or current values of the first and second phase power stages and performing a multiplication operation, and the third phase power stage The amount of power is measured by multiplying the voltage value of the third phase and the amount of current.

The second switching unit electrically connects the first phase power stage of the motor to the first phase power input terminal of the power system according to the second switching control signal from the relay control unit, and the third phase power stage of the motor is the second stage of the power system It is electrically connected to the phase power input terminal, and the second phase power terminal of the motor is electrically connected to the third phase power input terminal of the power system so that the motor is started in the reverse direction.

When the motor is started in the reverse direction, the relay control unit measures the amount of power of the second and third phase power stages by exchanging the voltage values or current values of the second and third phase power stages with each other and performing a multiplication operation, and the first phase power stage The amount of power is measured by multiplying the voltage value of the first phase and the amount of current.

The first switching unit is a first switch for switching an electrical connection between the first phase power terminal of the motor and the first phase power input terminal of the power system in response to the first switching control signal, and a second switch of the motor in response to the first switching control signal a second switch for switching the electrical connection between the phase power stage and the second phase power input end of the power system, and an electrical connection between the third phase power stage of the motor and the third phase power input end of the power system in response to the first switching control signal and a third switch for switching the

The second switching unit responds to the second switching control signal, a fourth switch for switching the electrical connection between the first phase power terminal of the motor and the third phase power input terminal of the power system, in response to the second switching control signal of the motor A fifth switch for switching the electrical connection between the phase power stage and the second-phase power input end of the power system, and in response to the second switching control signal, the electrical connection between the third-phase power stage of the motor and the first-phase power input end of the power system and a sixth switch for switching.

The second switching unit responds to the second switching control signal, a fourth switch for switching the electrical connection between the first phase power stage of the motor and the second phase power input end of the power system, in response to the second switching control signal of the motor a fifth switch for switching an electrical connection between the phase power stage and the first phase power input end of the power system, and an electrical connection between the third phase power stage of the motor and the third phase power input end of the power system in response to the second switching control signal a sixth switch for switching the

The second switching unit responds to the second switching control signal, a fourth switch for switching the electrical connection between the first phase power terminal of the motor and the first phase power input terminal of the power system, a third switch of the motor in response to the second switching control signal a fifth switch for switching the electrical connection between the phase power stage and the second phase power input end of the power system, and an electrical connection between the second phase power stage of the motor and the third phase power input end of the power system in response to the second switching control signal a sixth switch for switching the

The electronic motor protection relay according to an embodiment of the present invention having various technical features as described above can measure and calculate the power and the amount of power applied to the motor regardless of the forward or reverse starting method of the motor used to drive the load. have.

In addition, it is possible to prevent an accident due to a malfunction of the motor in the power system by making it possible to immediately check whether a malfunction due to overload or the like is performed according to the detection result of the amount of motor wattage measured in real time regardless of the forward or reverse starting method of the motor.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a view showing the directionality and flow time difference of voltage and current applied to a three-phase power stage of a motor.
2 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the first embodiment of the present invention.
FIG. 3 is a view for explaining the directionality and flow time difference of the three-phase power stage voltage and current according to the forward start of the motor shown in FIG. 2 .
FIG. 4 is a flowchart for explaining a method of calculating the amount of motor power according to the forward start of the motor shown in FIGS. 2 and 3 .
FIG. 5 is a view for explaining the directionality and flow time difference of the three-phase power stage voltage and current according to the reverse start of the motor shown in FIG. 2 .
FIG. 6 is a flowchart illustrating a method of calculating an amount of motor power according to a reverse start of the motor shown in FIGS. 2 and 5 .
7 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the second embodiment of the present invention.
8 is a diagram for explaining a method of calculating the amount of motor power according to the reverse start of the motor shown in FIG. 7 .
9 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the third embodiment of the present invention.
10 is a diagram for explaining a method of calculating the amount of motor power according to the reverse start of the motor shown in FIG. 9 .

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

In the present application, the first, second, etc. are used to describe various components, but these components are not limited by these terms. These terms are only used to distinguish one component from other components, and unless otherwise stated, the first component may be the second component, of course.

In the present application, terms such as “consisting of” or “comprising” should not be construed as necessarily including all of the various components or various steps described in the specification, and some components or some steps thereof. It should be construed that they may not be included, or may further include additional components or steps. Also, as used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise.

Hereinafter, an electronic motor protection relay according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the first embodiment of the present invention.

The electronic motor protection relay shown in FIG. 2 includes a first switching unit (SM), a second switching unit (SR), a relay control unit 200, at least one current converting unit (101, 102, 103), and at least one power converting unit ( 104).

The first switching unit SM is disposed between the three-phase power terminals (a, b, c) of the motor (M) and the three-phase power input terminals (A, B, C) of the power system.

The first switching unit (SM) in response to the first switching control signal from the relay control unit (200) three-phase power terminals (a, b, c) of the motor (M) and three-phase power input terminals (A, A, Switch the electrical connection between B and C).

For example, when the first switching control signal of high logic is input from the relay control unit 200 , the first switching unit SM includes the three-phase power stages a, b, c of the motor M and the three-phase power system. Electrically connect the power input terminals (A, B, C) respectively. On the other hand, if the first switching control signal of the low logic is input or the first switching control signal is not input, the electrical connection between the three-phase power terminals (a, b, c) and the three-phase power input terminals (A, B, C) is closed. block it

The first switching unit SM includes a first switch a_A for switching the electrical connection between the first phase power terminal a of the motor M and the first phase power input terminal A of the power system, the motor M ) and a second switch (b_B) for switching the electrical connection between the second phase power terminal (b) of the power system and the second phase power input terminal (B) of the power system. In addition, the first switching unit (SM) includes a third switch (c_C) for switching the electrical connection between the third phase power terminal (c) of the motor (M) and the third phase power input terminal (C) of the power system do.

The first to third switches a_A, b_B, c_C of the first switching unit SM respond to the first switching control signal from the relay control unit 200 to each of the three-phase power stages a, b, c and the electrical connection between the three-phase power input terminals (A, B, C) are switched.

The second switching unit SR has a parallel structure with the first switching unit SM between the three-phase power terminals a, b, and c of the motor M and the three-phase power input terminals A, B, and C of the power system. is placed as

The second switching unit SR is configured to respond to a second switching control signal from the relay control unit 200 , at least two of the three-phase power stages a, b, c, and at least two power stages a, c and a three-phase power input stage. The power input terminals (A, C) of at least two phases of (A, B, C) cross each other to connect or block them.

For example, when the second switching control signal of high logic is input from the relay control unit 200 , the second switching unit SR connects the first phase power stage a of the motor M to the third phase power input stage of the power system. (C) and electrically connected thereto, so that the third phase power stage (c) of the motor (M) may be electrically connected to the first phase power input terminal (A) of the power system. In addition, the second phase power terminal (b) of the motor (M) is electrically connected to the second phase power input terminal (B) of the power system.

On the other hand, when the second switching control signal of low logic is input or the second switching control signal is not input to the second switching unit SR, the three-phase power terminals a, b, c and the three-phase power input terminals A, B ,C) cut off the electrical connection between them.

To this end, the second switching unit (SR) is a fourth switch (a_C) for switching the electrical connection between the first phase power terminal (a) of the motor (M) and the third phase power input terminal (C) of the power system, and a fifth switch (b_B) for switching the electrical connection between the second-phase power stage (b) of the motor (M) and the second-phase power input stage (B) of the power system. In addition, the second switching unit SR includes a sixth switch c_A for switching the electrical connection between the third phase power terminal c of the motor M and the first phase power input terminal A of the power system do.

With this structure, the fourth to sixth switches a_C, b_B, c_A of the second switching unit SR respond to the second switching control signal from the relay control unit 200, and each of the three-phase power stage a , b, c) of at least two phases (a, c) and at least two of the three-phase power input terminals (A, B, C) cross each other to connect or block the power input terminals (A, B).

At least one power converter 104 is a three-phase power stage of the motor M using at least one PT (Rower Transformer) electrically connected to the three-phase power stage (a, b, c) of the motor (M) The power supplied to (a, b, c) is detected in real time. Then, the power amount information of each of the three-phase power stages (a, b, c) is digitally converted and supplied to the relay control unit 200 .

Each of the current converters 101, 102, 103 is a three-phase power stage (a, b, c) using each CT (Current Transformer) electrically connected to the three-phase power stage (a, b, c) of the motor (M) to detect the current supplied to each. Then, the amount of current of each of the three-phase power stages (a, b, c) is digitally converted and supplied to the relay control unit 200 .

The relay control unit 200 selectively supplies the first or second switching control signal to the first or second switching units SM and SR, respectively, thereby electrically switching the first and second switching units SM and SR. Selectively control the connection. In other words, the relay control unit 200 starts the motor M in the forward direction by supplying the first switching control signal to the first switching unit SM, and provides the first switching control signal to the second switching unit SR. By doing so, the motor M can be started in the reverse direction. At this time, the relay control unit 200 controls the forward or reverse start of the motor M by selectively supplying the first or second switching control signal to the first or second switching units SM and SR, and in real time Measure the power or amount of power of the motor (M).

The relay control unit 200 controls the three-phase power stage (a, b, c), that is, the voltage value and the current amount value of each of the first to third phase power stages (a, b, c) when the motor M is started in the forward direction. is received from the current and power converters 101 to 104, and calculates respective voltage values and current values for each of the first to third phase power stages a, b, and c Measure the amount of power in stages (a, b, c).

On the other hand, the relay control unit 200 receives the voltage value and current value of each of the three-phase power stages (a, b, c) when the motor M is started in the reverse direction, and among the three-phase power stages (a, b, c) By calculating the voltage values or current values of the first and third phase power stages a and c that are cross-connected to each other, the amount of power of the first and third phase power stages a and c is measured. And, the amount of power Pb of the second phase power stage Pb is measured by calculating the voltage value and the amount of current of the second phase power stage b.

FIG. 3 is a view for explaining the directionality and flow time difference of the three-phase power stage voltage and current according to the forward start of the motor shown in FIG. 2 . And, FIG. 4 is a flowchart for explaining a method of calculating the amount of motor power according to the forward start of the motor shown in FIGS. 2 and 3 .

Referring to FIGS. 3 and 4 together with FIG. 2 , the relay control unit 200 may start the motor M in the forward direction by supplying the first switching control signal to the first switching unit SM (ST1). When the motor M is started in the forward direction, a malfunction between the motor M and the load can be prevented by enabling (turning-on) the reverse-phase protection function of the motor M (ST2).

As shown in FIG. 3 , when the motor M is started in the forward direction, the voltages Va, Vb, Vc and currents Ia, Ib, and Ic of the first to third phase power stages a, b, c, respectively, respectively. direction is in the same quadrant. And, when the respective directions of the three-phase voltages (Va, Vb, Vc) are sequentially corresponded to the preset reference direction (V), the voltages (Va, Vb, Vc) of the three-phase power stage (a, b, c) And since the directions of the currents Ia, Ib, and Ic are respectively located in the quadrant (lower right), it is possible to measure both the voltage value and the current amount at a constant position (ST3).

Accordingly, as shown in the table of FIG. 3 , the relay control unit 200 multiplies each voltage value and current value for each of the first to third phase power stages (a, b, c) (Va*Ia, Vb*Ib). , Vc*Ic) to measure the amount of power (Pa, Pb, Pc) and the total amount of power (Ptot) for each of the first to third phase power stages (a, b, c) (ST4).

If the voltage (Va, Vb, Vc) direction of each of the first to third phase power stages (a, b, c) and the direction of the current (Ia, Ib, Ic) are not located in the same quadrant, the Since an error occurs in measuring the amount of power (Pa, Pb, Pc) for each of the first to third phase power stages (a, b, c), an error signal may be output (ST5).

FIG. 5 is a view for explaining the directionality and flow time difference of the three-phase power stage voltage and current according to the reverse start of the motor shown in FIG. 2 . And, FIG. 6 is a flowchart for explaining a method of calculating the amount of motor power according to the reverse starting of the motor shown in FIGS. 2 and 5 .

5 and 6 together with FIG. 2 , the relay control unit 200 may start the motor M in the reverse direction by supplying the second switching control signal to the second switching unit SR (ST1). Similarly, when the motor M is started in the reverse direction, the reverse phase protection function of the motor M is enabled (turned on) to prevent a malfunction between the motor M and the load (ST2).

As shown in FIG. 5 , when the motor M is started in the reverse direction, the voltages Va and Vc and the currents Ia and Ic of the first and third phase power stages a and c by the second switching unit SR. ) cross each other, so that the directions of the voltage (Vb) and the current (Ib) of the second phase power stage (b) are maintained while the directions of the current (Ia) of the first phase and the current (Ic) of the third phase are switched. do.

Accordingly, when the voltage (Va, Vc) directions of the first and third phase power stages (a, c) correspond to the preset reference direction (V), the first and third phase power stages (a, The currents Ia and Ic of c) are respectively located in the second and third quadrants (upper left and lower left) (ST3).

Accordingly, as shown in the table of Figure 5, the relay control unit 200 receives the voltage value and current value of each of the three-phase power stages (a, b, c) when the motor M is started in the reverse direction, and the three-phase power stage ( a, b, c) by exchanging the voltage values or current values of the first and third phase power stages (a, c) cross-connected to each other and calculating (Va*Ic, Vc*Ia), Measure the amount of power (Pa, Pc) of the three-phase power stage (a, c). Then, the amount of power Pb of the second phase power stage Pb is measured by calculating (Vb*Ib) the voltage value and the amount of current of the second phase power stage b (ST4).

7 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the second embodiment of the present invention.

Referring to FIG. 7 , compared to the electronic motor protection relay connection structure of the first embodiment, the electronic motor protection relay according to the second embodiment differs only in the switch connection structure of the second switching unit SR, and the first switching unit SM ), the relay control unit 200 , the current conversion units 101 , 102 , 103 , and the power conversion unit 104 have the same structure.

Accordingly, as in the first embodiment, the first switching unit SM responds to the first switching control signal from the relay control unit 200 to the three-phase power stages a, b, c and power of the motor M. Switches the electrical connection between the three-phase power input terminals (A, B, C) of the grid.

On the other hand, the second switching unit SR responds to the second switching control signal from the relay control unit 200, at least two of the three-phase power stage (a, b, c) of the power stage (a, b) and the three-phase The power input terminals A and B of at least two phases of the power input terminals A and B are crossed with each other to connect or cut off.

For example, when the second switching control signal of high logic is input from the relay control unit 200 , the second switching unit SR connects the first phase power terminal a of the motor M to the second phase power input terminal of the power system. It is electrically connected to (B), and the second phase power stage (b) of the motor (M) may be electrically connected to the first phase power input terminal (A) of the power system so as to cross it. In addition, the third-phase power terminal (c) of the motor (M) is electrically connected to the third-phase power input terminal (C) of the power system.

On the other hand, when the second switching control signal of low logic is input or the second switching control signal is not input to the second switching unit SR, the three-phase power terminals a, b, c and the three-phase power input terminals A, B ,C) cut off the electrical connection between them.

To this end, the second switching unit (SR) is a fourth switch (a_B) for switching the electrical connection between the first phase power terminal (a) of the motor (M) and the second phase power input terminal (B) of the power system, and a fifth switch b_A for switching the electrical connection between the second phase power terminal b of the motor M and the first phase power input terminal A of the power system. In addition, the second switching unit SR includes a sixth switch c_C for switching the electrical connection between the third-phase power terminal c of the motor M and the third-phase power input terminal C of the power system. do.

With this structure, the fourth to sixth switches a_B, b_A, c_C of the second switching unit SR respond to the second switching control signal from the relay control unit 200, and each of the three-phase power stage a , b, c) of at least two phases (a, c) and at least two of the three-phase power input terminals (A, B, C) cross each other to connect or block the power input terminals (A, B).

8 is a diagram for explaining a method of calculating the amount of motor power according to the reverse start of the motor shown in FIG. 7 .

As in the first embodiment, when the motor M is started in the forward direction, the relay control unit 200 multiplies the respective voltage values and current values for each of the first to third phase power stages a, b, c. Va*Ia, Vb*Ib, Vc*Ic), it is possible to measure the amount of power (Pa, Pb, Pc) and the total amount of power (Ptot) for each of the first to third phase power stages (a, b, c).

On the other hand, referring to FIG. 8 , when the motor M is started in the reverse direction, the relay control unit 200 receives the voltage and current values of each of the three-phase power stages a, b, and c, and the three-phase power stage a ,b,c) by exchanging the voltage values or current values of the first and second phase power stages a and b cross-connected to each other and calculating (Va*Ib, Vb*Ia), the first phase and the second Measure the amount of power (Pa, Pb) of the phase power stage (a, b). And, the amount of power Pc of the third-phase power stage Pc is measured by calculating (Vc*Ic) the voltage value and the amount of current of the third phase.

9 is a configuration diagram specifically showing the connection structure of the motor and the electronic motor protection relay according to the third embodiment of the present invention.

9 , compared to the electronic motor protection relay connection structure of the first embodiment, the electronic motor protection relay according to the third embodiment also differs only in the switch connection structure of the second switching unit SR, and the first switching unit SM ), the relay control unit 200 , the current conversion units 101 , 102 , 103 , and the power conversion unit 104 have the same structure.

Accordingly, as in the first embodiment, the first switching unit SM responds to the first switching control signal from the relay control unit 200 to the three-phase power stages a, b, c and power of the motor M. Switches the electrical connection between the three-phase power input terminals (A, B, C) of the grid.

On the other hand, the second switching unit SR responds to the second switching control signal from the relay control unit 200, at least two of the three-phase power stage (a, b, c) of the power stage (b, c) and the three-phase The power input terminals B, C of at least two phases of the power input terminals A, B, and C are connected or cut off by crossing each other.

For example, when the second switching control signal of high logic is input from the relay control unit 200 to the second switching unit SR, the first phase power stage a of the motor M is connected to the first phase power input stage of the power system. Electrically connect with (B).

And, the second switching unit (SR) electrically connects the third phase power stage (c) with the second phase power input stage (B) of the power system, and the second phase power stage (M) of the motor (M) to cross it b) may be electrically connected to the third-phase power input terminal (C) of the power system.

On the other hand, when the second switching control signal of low logic is input or the second switching control signal is not input to the second switching unit SR, the three-phase power terminals a, b, c and the three-phase power input terminals A, B ,C) cut off the electrical connection between them.

To this end, the second switching unit (SR) is a fourth switch (a_A) for switching the electrical connection between the first phase power terminal (a) of the motor (M) and the first phase power input terminal (A) of the power system, and a fifth switch c_B for switching the electrical connection between the third-phase power stage c of the motor M and the second-phase power input stage C of the power system. In addition, the second switching unit (SR) includes a sixth switch (b_C) for switching the electrical connection between the second phase power terminal (b) of the motor (M) and the third phase power input terminal (C) of the power system do.

With this structure, the fourth to sixth switches a_a, c_B, and b_C of the second switching unit SR respond to the second switching control signal from the relay control unit 200, and each of the three-phase power stage a , b, c) of at least two phases (b, c) and three-phase power input terminals (A, B, C) of at least two phases of power input terminals (B, C) cross each other to connect or block.

10 is a diagram for explaining a method of calculating the amount of motor power according to the reverse start of the motor shown in FIG. 9 .

As in the first embodiment, when the motor M is started in the forward direction, the relay control unit 200 multiplies the respective voltage values and current values for each of the first to third phase power stages a, b, c. Va*Ia, Vb*Ib, Vc*Ic), it is possible to measure the amount of power (Pa, Pb, Pc) and the total amount of power (Ptot) for each of the first to third phase power stages (a, b, c).

On the other hand, referring to FIG. 10 , when the motor M is started in the reverse direction, the relay control unit 200 receives the voltage value and current value of each of the three-phase power stages a, b, and c, and the first phase power stage ( The amount of power (Pa) of a) is measured by calculating (Va*Ia) the voltage value and the amount of current of the first phase power stage (a).

On the other hand, the second and third phase power stages (b,c) cross-connected to each other are calculated by swapping the voltage values or current values of the second and third phase power stages (b,c) with each other (VB*Ic, VC). *Ib), it is possible to measure the amount of power (Pb, Pc) of the second phase and the third phase power stage (b, c).

In the above-described manner, the electronic motor protection relay according to an embodiment of the present invention is applied to the motor (M) regardless of the forward starting or reverse starting method of the motor (M) used in the power system and the amount of power (Pa + Pb+Pc) can be measured and calculated.

In addition, regardless of the forward or reverse starting method of the motor (M), it is possible to immediately check whether a malfunction due to overload, etc. has occurred according to the detection result of the amount of motor power (Pa+Pb+Pc) measured in real time. It is possible to prevent accidents caused by (M) and load malfunction.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those of ordinary skill in the art to which various modifications and equivalent other embodiments are possible. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

SM: first switching unit
SR: second switching unit
101, 102, 103: at least one current conversion unit
104: at least one power conversion unit
200: relay control unit

Claims (13)

a first switching unit disposed at the three-phase power stage of the motor to switch the electrical connection between the three-phase power stage of the motor and the three-phase power input stage of the power system;
It is disposed between the three-phase power stage of the motor and the three-phase power input end in a parallel structure with the first switching unit, and is a power input end of at least two phases among the three-phase power stage of the motor and the power input stage of at least two phases among the three-phase power input stage. a second switching unit for connecting or blocking by crossing them; and
Electronic motor protection relay comprising a relay control unit for selectively controlling the electrical switching connection of the first and second switching units to control the forward or reverse start of the motor, and to measure the electric power or amount of power of the motor.
The method of claim 1,
a power conversion unit that detects and digitally converts power supplied to each of the three-phase power stages of the motor, and supplies the amount of power information of each of the three-phase power stages to the relay control unit; and
Electronic motor protection relay further comprising at least one current converter for detecting and digitally converting the current supplied to the three-phase power stage of the motor, and supplying the current amount information of each of the three-phase power stage to the relay control unit.
The method of claim 1,
The first switching unit
In response to a first switching control signal from the relay controller to switch the electrical connection between the three-phase power stage of the motor and the three-phase power input stage,
The second switching unit
In response to a second switching control signal from the relay control unit, an electronic motor protection relay for connecting or blocking the power stage of at least two phases of the three-phase power stage and the power input stage of at least two of the three-phase power input stage by crossing each other.
4. The method of claim 3,
The second switching unit
The first phase power stage of the motor is electrically connected to a third phase power input terminal of the power system according to a second switching control signal from the relay control unit, and the third phase power stage of the motor is the first of the power system. An electronic motor protection relay electrically connected to a one-phase power input terminal, and a second-phase power terminal of the motor electrically connected to a second-phase power input terminal of the power system to reversely start the motor.
5. The method of claim 4,
The relay control unit
When the motor is started in the reverse direction, the first phase and the third phase power are multiplied by exchanging voltage values or current values of the first and third phase power stages cross-connected among the three-phase power stages. Measure the power of the stage,
The amount of power of the second phase power stage is an electronic motor protection relay for calculating and measuring the voltage value and the amount of current of the second phase power stage.
4. The method of claim 3,
The second switching unit
The first phase power stage of the motor is electrically connected to the second phase power input terminal of the power system according to a second switching control signal from the relay control unit, and the second phase power stage of the motor is the second phase of the power system. An electronic motor protection relay that is electrically connected to a one-phase power input terminal, and a third-phase power terminal of the motor is electrically connected to a third-phase power input terminal of the power system so that the motor is reversely started.
7. The method of claim 6,
The relay control unit
When the motor is started in the reverse direction, the amount of power of the first and second phase power stages is measured by multiplying the voltage values or current values of the first and second phase power stages with each other and performing a multiplication operation, and the third phase An electronic motor protection relay for measuring the amount of power in the power stage by multiplying the voltage value of the third phase and the amount of current.
4. The method of claim 3,
The second switching unit
According to a second switching control signal from the relay control unit, the first phase power stage of the motor is electrically connected to the first phase power input stage of the power system, and the third phase power stage of the motor is connected to the second stage of the power system. An electronic motor protection relay that is electrically connected to a phase power input terminal, and the second phase power terminal of the motor is electrically connected to a third phase power input terminal of the power system so that the motor is started in the reverse direction.
9. The method of claim 8,
The relay control unit
When the motor is started in the reverse direction, the electric power of the second and third phase power stages is measured by multiplying the voltage values or current values of the second and third phase power stages with each other, and the first phase An electronic motor protection relay for measuring the amount of power in the power stage by multiplying the voltage value of the first phase and the amount of current.
4. The method of claim 3,
The first switching unit
a first switch for switching an electrical connection between a first phase power end of the motor and a first phase power input end of the power system in response to the first switching control signal;
a second switch for switching an electrical connection between a second-phase power end of the motor and a second-phase power input end of the power system in response to the first switching control signal; and
Electronic motor protection relay including a third switch for switching the electrical connection between the third phase power terminal of the motor and the third phase power input terminal of the power system in response to the first switching control signal.
11. The method of claim 10,
The second switching unit
a fourth switch for switching an electrical connection between the first phase power end of the motor and a third phase power input end of the power system in response to the second switching control signal;
a fifth switch for switching an electrical connection between the second-phase power stage of the motor and a second-phase power input stage of the power system in response to the second switching control signal;
and a sixth switch for switching an electrical connection between the third-phase power stage of the motor and the first-phase power input stage of the power system in response to the second switching control signal.
11. The method of claim 10,
The second switching unit
a fourth switch for switching an electrical connection between the first phase power terminal of the motor and a second phase power input terminal of the power system in response to the second switching control signal;
a fifth switch for switching an electrical connection between the second phase power end of the motor and the first phase power input end of the power system in response to the second switching control signal; and
and a sixth switch for switching an electrical connection between the third-phase power stage of the motor and the third-phase power input end of the power system in response to the second switching control signal.
11. The method of claim 10,
The second switching unit
a fourth switch for switching an electrical connection between the first phase power terminal of the motor and the first phase power input terminal of the power system in response to the second switching control signal;
a fifth switch for switching an electrical connection between the third-phase power end of the motor and the second-phase power input end of the power system in response to the second switching control signal; and
Electronic motor protection relay comprising a sixth switch for switching the electrical connection between the second phase power terminal of the motor and the third phase power input terminal of the power system in response to the second switching control signal.

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