KR100252007B1 - Condenser type induction motor - Google Patents

Abstract

PURPOSE: A condenser type induction motor is provided to maintain sufficient balanced state and be capable of being reversely rotated using a reversible rotation control unit. CONSTITUTION: First and second windings(L1,L2) have same thickness and winding number. Respective windings(L1,L2) have first and second tabs(TAB1,TAB2) having first/second winding numbers(TN1,TN2). The current path of a condenser(C) is controlled first to third relays(R1-R3) between two terminals. The relay(R1) is switched to 'a' 'b' terminal to be connected to the first winding(L1), the relay(R2) is switched to an 'a' terminal to be connected to the second tab(TAB2), and the relay(R3) is switched to the 'b' terminal to be connected to the second tab(TAB2) when a rotor is clockwise rotated. At this time, the first winding acts as a main winding and the second winding acts as a sub winding.

Description

Capacitor Induction Motor

1 is a schematic view showing the configuration of a condenser induction motor.

2 is a circuit diagram showing an embodiment of a conventional capacitor induction motor.

3 is a circuit diagram showing another embodiment of a conventional capacitor induction motor.

4 is a circuit diagram showing an embodiment of a capacitor induction motor according to the present invention.

5 is a circuit diagram showing another embodiment of the capacitor induction motor according to the present invention.

The present invention relates to a condenser induction motor, and more particularly, to an improved condenser induction motor that adopts a winding having a tab to perform an improved forward and reverse operation.

The condenser induction motor is used by connecting a capacitor having the same capacity in series with the auxiliary winding both during start-up and operation. There is an advantage that the capacity of the condenser is minimal compared to the distributed starting induction motor, the condenser induction motor, and the like.

1 is a conceptual diagram showing a condenser induction motor. The main winding and auxiliary winding shown in FIG. 1 are installed on the stator iron core, and the alternating magnetic field generated by the combination of the magnetic field of the main winding and the auxiliary winding and the alternating magnetic field generated by the cage rotor are generated to generate the rotating magnetic field. As a result, the cage rotor rotates.

In order to reversely rotate the condenser induction motor, the phases of the currents flowing through the main windings and the auxiliary windings are switched to each other or the direction of the currents flowing through the auxiliary windings is reversed.

2 is a circuit diagram showing an embodiment of a conventional capacitor induction motor. In the apparatus shown in FIG. 2, the first and second windings L1 and L2, the capacitor C and the relays R1 and R2 are provided between the first terminal and the second terminal to which an AC voltage is applied. have. Here, L1 and L2 are used interchangeably with the main winding or auxiliary winding, and have the same impedance characteristics.

In the operation of the apparatus shown in FIG. 2, when R1 is in a conducting state and R2 is in a non-conducting state, L1 operates as the main winding and L2 acts as the auxiliary winding so that the rotor rotates clockwise. Then, R1 is in a non-conduction state, R2 is in a conductive state, L1 is a secondary winding, and L2 is a primary winding, so that the rotor rotates counterclockwise. L1 and L2 should be designed so that the coil thickness and the number of turns are the same so that the torque is equal in the forward and reverse rotation.

As is known, the alternating magnetic field may be represented by a combination of two rotating magnetic fields rotating in opposite directions, that is, a rotating magnetic field of a normal portion and a rotating magnetic field of a reverse phase. For equilibrium operation of induction motors, the magnetic field of the reverse phase should be sufficiently small. However, in the apparatus shown in FIG. 2, the reactance values of L1 and L2 are equal so that the reverse phase rotor magnetic field is not sufficiently small. Therefore, there is a problem that sufficient balance driving performance is not secured in the apparatus shown in FIG.

3 is a circuit diagram showing another embodiment of the conventional condenser induction motor, in which the reverse phase magnetic field in the alternating magnetic field generated in the main winding LM by the proper winding design is applied to the auxiliary winding LS and the condenser C. FIG. This is an example of an induction motor that is to be offset by. In the apparatus shown in FIG. 3, the auxiliary winding LS and the condenser whose current direction is controlled by the first to fourth relays R1 to R4 between the first terminal and the second terminal to which an AC voltage is applied. The serial connector of (C) and the main winding LM are connected in parallel.

In the operation of the apparatus shown in FIG. 3, when the rotor rotates clockwise, R1 and R3 are in a conductive state, and R2 and R4 are in a non-conducting state, and the current from left to right when viewed in the drawing is LS. To flow. When the rotor rotates in the counterclockwise direction, R1 and R3 become non-conductive, and R2 and R4 become conductive, and the current flowing from the right to the left flows in the LS when viewed in the drawing. That is, the rotor rotates forward and backward by changing the direction of the current flowing in the LS.

Although the device shown in FIG. 3 has the advantage of improved balance operation over the device shown in FIG. 2, the power source for driving the first relay group including R1 and R3 and the second relay group including R2 and R4. This has to be separated, there are a number of relays, there was a problem such as complicated circuit for controlling it.

An object of the present invention is to provide a condenser induction motor that maintains a sufficient equilibrium operation state and is capable of forward and reverse rotation by a simple device as created to solve the above problems.

The condenser induction motor according to the present invention for achieving the above object generates a rotating magnetic field, and has a first and second windings having the same number of turns, and first and second terminals connected in parallel with the first and second windings. 1. A capacitor induction motor, comprising: first and second taps for converting the number of turns of the first and second turns into a first number or a second number of turns; And in response to the forward rotation command, the first winding is connected between the first terminal and the second terminal through the capacitive reactance element and the second winding is connected through the second tap, or the second winding is capacitive. And a forward and reverse control means for connecting the first winding through the first tap while being connected through the reactance element. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

4 is a circuit diagram showing a capacitor induction motor according to an embodiment of the present invention. In the apparatus shown in FIG. 4, the first and second windings L1 and L2 have equal thicknesses and turns, and each winding is divided so as to have a first winding TN1 and a second winding TN2. The first and second tabs TAB1 and TAB2 are provided. Here, the number of turns of each winding of TN1 + TN2 is the same.

L1 and L2 capacitors C, in which a current path is controlled by the first to third relays R1 to R3 between the first terminal and the second terminal to which an AC voltage is applied, are provided.

In the operation of the apparatus shown in FIG. 4, when the rotor rotates clockwise, R1 is switched to b side and connected to L1, R2 is switched to a side and connected to TAB2, and B3 is switched to b side to C It is connected to the terminal side connected to TAB2. Accordingly, L1 acts as an auxiliary winding, and L2 acts as a main winding, which is the same as the operation in the clockwise rotation of the apparatus shown in FIG. At this time, the number of windings of L1 and L2 is different from TN1 and (TN1 + TN2), and the equilibrium operating conditions can be satisfied by appropriately selecting the ratio of TN1 and TN2 in accordance with the relationship between LM and LS shown in FIG.

When the rotor rotates counterclockwise, R1 is switched to the a side and connected to TAB1, R2 is switched to the b side and connected to L2, and R3 is switched to the a side and connected to the terminal side connected to TAB1 of C. Accordingly, L1 acts as the main winding and L2 acts as the auxiliary winding, which is equivalent to the operation in the counterclockwise direction of the apparatus shown in FIG. At this time, the number of turns of L1 and L2 is different from (TN1 + TN2) and TN1, and as in the clockwise rotation, the ratio of TN1 and TN2 is appropriately selected according to the relationship between LM and LS shown in FIG. Operation condition can be satisfied.

5 is a circuit diagram showing a capacitor induction motor according to another embodiment of the present invention. In the apparatus shown in FIG. 5, the first and second windings L1 and L2 divide each winding into a first winding TN1 and a second winding TN2 in the same manner as the apparatus shown in FIG. Has first and second taps TAB1 and TAB2.

L1, L2, first and second capacitors C1 and C2 are installed in which the current path is controlled by the second to fourth relays R1 to R4 between the first terminal and the second terminal to which an AC voltage is applied. It is done.

In the operation of the apparatus shown in FIG. 5, when the rotor rotates clockwise, R1 and R3 remain in a non-conducting state, and R2 and R4 remain in a conducting state. Accordingly, L1 acts as an auxiliary winding, and L2 acts as a main winding, which is the same as the operation in the clockwise rotation of the apparatus shown in FIG. At this time, the number of windings of L1 and L2 is different from TN1 and (TN1 + TN2), and the equilibrium operating conditions can be satisfied by appropriately selecting the ratio of TN1 and TN2 in accordance with the relationship between LM and LS shown in FIG.

When the rotor rotates counterclockwise, R1 and R3 remain in the conduction state, and R2 and R4 remain in the conduction state. Accordingly, L1 operates as the main winding, and L2 operates as the auxiliary winding, which is the same as the operation in the counterclockwise rotation of the apparatus shown in FIG.

As in the clockwise rotation of the rotor, the number of turns of L1 and L2 is different from TN1 and (TN1 + TN2), and the ratio of TN1 and TN2, is appropriately selected in accordance with the relationship between LM and LS shown in FIG. By this, the equilibrium operation condition can be satisfied.

As described above, the condenser induction motor according to the present invention sets the tap so that the number of turns when used as the main winding and the number of turns when used as the auxiliary winding can be set so that the first and second windings and the tap during the forward and reverse rotations. This has the advantage of simplifying the configuration of the switch and control circuit which differ in the current path between the capacitor and the capacitor.

Claims (5)

In a condenser induction motor having a first and second windings having a rotating magnetic field and having the same number of turns and the first and second windings connected in parallel, the first and second windings First and second tabs for converting the number of turns into the first or second volume; A first winding is connected between the first terminal and the second terminal through a capacitive reactance element in response to a forward rotation command, and the second winding is connected through the second tap; And a forward and reverse control means for causing a winding to be connected through a capacitive reactance element and to allow the first winding to be connected through the first tab. The apparatus of claim 1, wherein the forward rotation control means comprises: a condenser; And a terminal not connected to the first terminal of the first winding in response to a forward rotation command, to be connected to an input terminal of one side of the capacitor, and wherein the first tap is connected to one side of the capacitor in response to a reverse rotation command. A first switch adapted to be connected to the first switch; The second tap is connected to the other input terminal of the capacitor in response to the forward rotation command, and the terminal not connected to the first terminal of the second winding in response to the reverse rotation command is connected to the other input terminal of the capacitor. A second switch to be connected; And a third switch for allowing the other input terminal of the condenser to be connected to the second terminal in response to the forward rotation command, and the one input terminal of the condenser to be connected to the second terminal in response to the reverse rotation command. Capacitor induction motor characterized in that. 3. The condenser induction motor of claim 2, wherein the first to third switches perform an interlocking operation with respect to a forward and reverse rotation command. 2. The forward and reverse rotation control means according to claim 1, further comprising: first and second capacitors connected to a terminal side not connected to said first terminal of said first and second windings; A first switch coupled to the first tab and the second terminal to maintain an open state with respect to the forward rotation command and to maintain a conduction state so that the first tab and the second terminal are connected with respect to the reverse rotation command; Coupled to the terminal side and the second terminal not connected to the first winding of the first capacitor, and in a conduction state such that the first winding is connected to the second terminal through the first capacitor in response to a forward rotation command. A second switch for maintaining and maintaining an open state with respect to the reverse rotation command; It is coupled to the terminal side and the second terminal which are not connected to the second winding of the second capacitor, maintains an open state with respect to the forward rotation command, and the second winding with the second capacitor with respect to the reverse rotation command. A third switch for maintaining a conducting state so as to be connected to the second terminal through the third terminal; A fourth switch coupled to the second tab and the second terminal to maintain a conducting state such that the second tab is connected to the second terminal with respect to the forward rotation command, and to maintain an open state with respect to the reverse rotation command; Capacitor induction motor, characterized in that it comprises a. The condenser induction motor of claim 4, wherein the first to fourth switches are interlocked with a forward and reverse rotation command.