KR101062205B1 - motor - Google Patents

Abstract

 The present invention relates to a motor, comprising: a stator winding unit to which power is supplied; An overload circuit breaker for cutting off the overload power applied to the stator winding unit; A fixing bracket fixed to a surface of the stator winding part, the overload circuit breaker coupling part detachably coupled to the overload circuit breaker, and a fixed bracket formed on an outer surface thereof and having a linear yarn guide groove; It is characterized in that it comprises a yarn (yarn) accommodated in the yarn guide groove wound around the stator winding. Thereby, by easily coupling the overload circuit breaker to the winding portion can reduce the production cost of the motor, it is possible to improve the quality.

Motor, stator winding part, overload breaker, fixed bracket

Description

Motor

The present invention relates to a motor, and more particularly, to a motor having an improved structure for coupling an overload circuit breaker to a winding part of a stator.

 The motor is a driving device applied to a variety of devices, including rotary compressors for cooling devices such as air conditioners and refrigerators.

 In general, a motor includes a stator configured to receive a power supply to form a magnetic field. The stator includes a winding coil provided on an iron core, and an overload circuit breaker is used to prevent overcurrent from flowing to the rolling coil during operation of the motor. Is attached to.

 However, such a conventional motor directly connects the connection end of the energizing coil to the connection part of the overload circuit breaker and bundles the overload circuit breaker and the energizing coil together with a yarn called a yarn in the state where the overload circuit breaker is placed on the coil. There is a problem that the production cost can be increased because the time and manpower required for the process is increased.

 In addition, there is a problem that the quality can be deteriorated because the support state of the overload circuit breaker coupled to the coil for electricity is unstable.

 It is an object of the present invention to provide a motor that can easily couple an overload circuit breaker to a winding.

 Another object of the present invention is to provide a motor capable of firmly coupling an overload circuit breaker to a winding part.

 The object is, according to the present invention, a motor, comprising: a stator winding portion to which power is supplied; An overload circuit breaker for cutting off the overload power applied to the stator winding unit; A fixing bracket fixed to a surface of the stator winding part, the overload circuit breaker coupling part detachably coupled to the overload circuit breaker, and a fixed bracket formed on an outer surface thereof and having a linear yarn guide groove; It is achieved by a motor, characterized in that it comprises a yarn (yarn) received and guided to the yarn guide groove wound around the stator winding.

 Here, the overload breaker includes a connection pin protruding toward the fixing bracket,

The fixing bracket includes a seating part on which the overload circuit breaker is seated, a pin insertion part into which the connection pin is inserted, and a connection terminal provided at the pin insertion part to electrically connect the connection pin to an end of the stator winding part. It is desirable to.

 In addition, the fixing bracket is preferably made of an insulating material.

  According to the present invention, by easily coupling the overload circuit breaker to the winding portion it is possible to reduce the production cost of the motor.

 In addition, it is possible to improve the quality of the motor by firmly coupling the overload circuit breaker to the winding.

 Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

 The rotary compressor 100 to which the motor 130 according to the present invention is applied, as shown in FIG. 1, has a casing 110 that forms the exterior of the rotary compressor 100 and a refrigerant provided inside the casing 110. Compression unit 120 for compressing, and a motor 130 for transmitting a rotational force generated by receiving power to the compression unit 120.

 The casing 110 includes a refrigerant discharge part 111 for guiding the discharge of the compressed high pressure refrigerant and a refrigerant suction part 112 connected to the compression unit 120 to guide the inflow of the refrigerant.

 As shown in FIG. 1, the compression unit 120 includes a cylinder 121 having a compression chamber 121a through which refrigerant is compressed, an upper flange 122 coupled to an upper portion of the cylinder 121, and a cylinder. A lower flange 123 coupled to the lower portion of the 121 and the roller 124 is installed eccentrically in the compression chamber 121a and receives a rotational force from the motor 130 to compress the refrigerant.

 1 and 2, the motor 130 according to the present invention, the stator 140 having a stator winding portion 141 is supplied with power, and a rotation rotatably installed in the stator 140 Electron 150, a rod-shaped and one end is coupled to the rotor 150 and the other end is installed to penetrate through the compression unit 120, the rotating shaft 160 and rotated together with the rotor 150, the stator It includes an overload circuit breaker 170 for cutting off the overload power applied to the winding unit 141, and a fixing bracket 180 fixed to the surface of the stator winding unit 141.

 As shown in FIG. 1, the stator 140 includes a stator winding part 141 in which an iron core and a coil for energization which are easily passed through magnetic flux are formed to receive magnetic power to form a magnetic field.

 As shown in FIGS. 2 and 3, the stator winding part 141 is bundled in a thread or a string called a yarn 142 such that the coils for energization are fixed in a predetermined shape (concentric circles). It is provided, and includes a connection end 141a electrically indirectly connected to the overload circuit breaker 170 through the fixing bracket 180.

 As shown in FIG. 3, the overload breaker 170 protrudes toward the fixed bracket 180 and is coupled to the fixed bracket 180 to connect the connecting end 141a of the stator winding part 141 through the fixed bracket 180. ) And a connection pin 171 electrically indirectly connected thereto.

 In one embodiment of the present invention, the overload circuit breaker 170 preferably includes a large overload protector (OLP) that is bimetallic to prevent overcurrent from flowing through the stator winding unit 141.

 The fixing bracket 180 is formed in the center of the overload circuit breaker coupling portion 181 and the overload circuit breaker coupling portion 181 to which the overload circuit breaker 170 is detachably coupled, as shown in FIG. 4. The inside of the overload breaker coupling part 181 is mounted from the seating part 182 to which the 170 is mounted, the linear yarn guide groove 183 formed on the outer surface of the overload breaker coupling part 181, and the seating part 182. It includes a connection terminal 184 extending to the outer surface of the overload breaker coupling portion 181 through.

 Accordingly, by easily coupling the overload circuit breaker 170 to the fixing bracket 180 coupled to the stator winding unit 141 in a one-touch manner, it is possible to reduce the production cost of the motor 130.

 In one embodiment of the present invention, the fixing bracket 180 is preferably made of an insulating material.

 In the overload breaker coupling portion 181, as shown in FIG. 4, a seating portion 182 and a yarn guide groove 183 are formed, and a connection pin 171 is inserted into the seating portion 182 to be engaged with the pin. Insertion portion 182a is formed.

 In one embodiment of the present invention, the seating portion 182 is preferably formed corresponding to the shape of the overload circuit breaker 170.

 Yarn guide groove 183, as shown in Figure 4 as an embodiment of the present invention, on both sides of the seating portion 182 on the plate surface of the overload breaker coupling portion 181 spaced apart from the seating portion 182 It is preferable that it is formed.

 Meanwhile, as illustrated in FIGS. 3 and 4, the yarn guide 142 is accommodated in the yarn guide groove 183, and the fixing bracket 180 and the stator winding 141 are accommodated in the yarn guide groove 183. It is wound and fastened by guided yarn 142.

 Accordingly, by firmly coupling the fixing bracket 180 to the stator winding portion 141 as a yarn 142, the supporting state of the overload circuit breaker 170 coupled to the fixing bracket 180 can be stably maintained.

 The connection terminal 184 is provided in the pin insertion portion 182a to electrically connect the connection pin 171 of the overload circuit breaker 170 with the connection end portion 141a of the stator winding portion 141. That is, in the state in which the connecting pin 171 is coupled to the pin insertion portion 182a, the connecting end 141a and the connecting pin 171 are energized with each other.

 Accordingly, the fixing bracket 180 is firmly coupled to the stator winding part 141 as a yarn 142, and the overload circuit breaker 170 is detachably coupled to the fixing bracket 180 to stator the overload circuit breaker 170. While firmly coupled to the winding unit 141, it is possible to reduce the manpower and time required for the coupling process.

 By such a configuration, the process of coupling the overload breaker 170 of the motor 130 according to the present invention will be described with reference to FIGS. 1 to 4.

 First, the fixing bracket 180 is disposed on the stator winding part 141 provided on the upper part of the stator 140, and the fixing bracket 180 and the stator winding part are formed by the yarn 142 accommodated and guided in the yarn guide groove 183. Combine 141.

 Next, the connecting end 141a of the stator winding part 141 is inserted into the connecting terminal 184 of the fixing bracket 180, and the connecting pin 171 of the overload circuit breaker 170 is seated on the fixing bracket 180. The connection pin 171 is fitted into the pin insertion portion 182a formed in the portion 182 to engage the connection terminal 184. Accordingly, the connecting pin 171 and the connecting end 141a may be energized with each other through the connecting terminal 184.

 Thus, according to the present invention, by easily coupling the overload circuit breaker 170 to the stator winding portion 141 it is possible to reduce the production cost of the motor 130.

 In addition, by firmly coupling the overload circuit breaker 170 to the stator windings 141, it is possible to improve the quality of the motor 130.

1 is a block diagram showing a rotary compressor applied to the motor according to the present invention,

2 is a perspective view illustrating a fixing bracket and an overload circuit breaker coupled to the stator winding part of FIG. 1;

3 is an enlarged exploded perspective view illustrating a coupling method of region “A” of FIG. 2;

4 is a perspective view illustrating the fixing bracket of FIG. 3.

Explanation of symbols on the main parts of the drawings

100: rotary compressor 110: casing

120: compression unit 130: motor

140: stator 141: stator winding

141a: connecting end 142: yarn

150: rotor 160: axis of rotation

170: overload breaker 171: connection pin

180: fixed bracket 181: overload circuit breaker coupling

182: seating portion 182a: pin insertion portion

183: yarn guide groove 184: connecting terminal

Claims (3)

In the motor, A stator winding unit to which power is supplied; An overload circuit breaker for cutting off the overload power applied to the stator winding unit; A fixing bracket fixed to a surface of the stator winding part, the overload circuit breaker coupling part detachably coupled to the overload circuit breaker, and a fixed bracket formed on an outer surface thereof and having a linear yarn guide groove; And a yarn (yarn) accommodated in the yarn guide groove and wound around the stator winding. The method of claim 1, The overload circuit breaker includes a connection pin protruding toward the fixing bracket, The fixing bracket includes a seating part on which the overload circuit breaker is seated, a pin insertion part into which the connection pin is inserted, and a connection terminal provided at the pin insertion part to electrically connect the connection pin to an end of the stator winding part. Characterized in that the motor. The method of claim 2, The fixing bracket is a motor, characterized in that made of an insulating material.

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