KR100671898B1 - Join structure of switched reluctance motor with driving circuit - Google Patents

Abstract

The present invention relates to a fastening structure of a switch reluctance motor integrated with a drive circuit, and more particularly, a rotation in which a rotating protrusion is rotated by a stator having a field coil wound around a fixed protrusion, and rotated by an electromagnetic force generated by the fixed protrusion of the stator. A motor case installed inside the self and having a rotating shaft protruding from the rotor; An upper case fixed to a rotating shaft of the motor case and installed with a rotating fan, and having an inlet for sucking air on one side thereof; A heat dissipation tube installed in communication with the suction port of the upper case is bent toward the inside, and a cover portion fixed to one side of the upper case; A fixing part detachably fixing the heat dissipation pipe of the cover part to an inlet of the upper case; And a driving circuit part embedded in a cover part fixed to the upper case by the fixing part and having a power device for controlling power supplied to the account coil.

According to the present invention as described above, the coupling force of the cover portion in which the drive circuit unit is built in the upper case of the switched reluctance motor is improved, and the coupling force and airtightness of the heat dissipation tube and the suction port are further improved to improve operation reliability.

Switched reluctance motor, drive circuit part, cover part, motor case, fixed part

Description

Join structure of switched reluctance motor with driving circuit unit

1 is a circuit diagram of a conventional switched reluctance motor.

2 is an exploded perspective view illustrating a fastening structure of a switch reluctance motor integrated with a driving circuit unit according to an embodiment of the present invention.

3 is a side cross-sectional view showing a fastening structure of a switched reluctance motor integrated with a driving circuit unit according to an embodiment of the present invention.

Figure 4 is a side cross-sectional view showing a fastening structure of the switch circuit integral integrated reluctance motor according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

20: switched reluctance motor 30: main body case

40: upper case 41: blowing fan

42: inlet 44: outlet

45: side 46: upper surface

47: first side 48: second side

50: motor case 52: fixed protrusion

54: stator 56: rotating protrusion

58: rotor 60: axis of rotation

62: bearing 70: drive circuit

72: printed circuit board 74: power device

76: fastening member 80: cover

81: cover side 82: mounting portion

84: heat radiating pipe 86: inner side

88: outer side 89: step projection

90: upper thread mountain 92: lower thread mountain

94: cover screw thread 96: body screw thread

98: fixed part

The present invention relates to a fastening structure of a switch reluctance motor integrated with a drive circuit unit, and more particularly, a cover part and a switch reluctance motor in which the drive circuit unit is integrated are easily coupled to each other by a screwing method. The present invention relates to a device in which airtightness is also improved due to an improved fastening force of the switched reluctance motor and the cover part.

In general, a switched reluctance motor generates rotational torque by interrupting power supplied to a coil wound around a multi-phase stator by using a switching element. Forward rotation torque can be generated, and when the specific excitation state is not changed, the rotor can be stopped at a certain position, and the reverse rotational power is increased by controlling the phase of the input pulse signal applied to the switching element based on the maximum inductance shape. Various drive control that can be generated is being used as a power source for home appliances such as washing machines and vacuum cleaners.

Switched reluctance motor (SRM) as described above is made of a structure that does not have a winding or permanent magnet in the rotor, the drive circuit is simple, manufacturing cost is low, the inertia of the rotor and a wide range of It is an electric motor that has many advantages in its structure and operation because of its high efficiency of operation at speed.

1 is a circuit diagram of a general switched reluctance motor.

The switched reluctance motor (SRM) according to the related art includes a stator 2 wound around a driving circuit unit 10, a field coil 2a receiving current from the driving circuit unit 10, and the stator. It is made of a rotor 4 or the like inserted into the inside of (2) and rotated in one direction by the reluctance torque generated between the stator 2 when a current flows in the field coil 2a.

The stator (2) is a yoke (2b) formed in a cylindrical shape of the upper and lower openings, a protrusion (2c) protruding at a predetermined interval in the circumferential direction toward the rotor from the inner wall of the yoke (2b), and It consists of the field coil 2a wound by the protrusion 2c.

The rotor 4 is formed by stacking cores 4b having protrusions 4a protruding at predetermined intervals in a circumferential direction, and a rotation shaft for transmitting a driving force of a motor to the outside in the center of the rotor 4 ( 6) is built up and rotates with the rotor 4.

The driving circuit unit 10 receives a signal from an optical sensor or a hall sensor that detects the position or speed of the rotor 4 to vary the intensity of the current flowing through the field coil. To this end, a printed circuit board Insulated gate bipolar transistors (IGBTs) and diodes, which are used for multiple chips and switching transistors, are installed.

In this switched reluctance motor, when a current flows through the field coil 2a by the driving circuit unit 10, reluctance torque is generated between the stator 2 and the rotor 4, so that the rotor 4 is magnetic. The resistance of the circuit is rotated in the direction of minimum.

In the switched reluctance motor, an auxiliary coil (not shown) is wound on the stator pole 2c of the stator, or the rotor pole 4a of the rotor generates an effective torque with respect to the stator pole 2c of the stator when starting. The rotary shaft 6 is rotated in one direction because it is located in the area.

However, since the switched reluctance motor and the driving circuit unit 10 having the above operating characteristics are manufactured separately, many parts are required and productivity is reduced due to an increase in an assembly process and the like.

In the case of integrally manufacturing the driving circuit unit 10 and the switched reluctance motor as described above, there is a problem in that the airtight action is not properly performed with a detachable structure which is not easy.

In addition, some devices including an insulated gate bipolar transistor (IGBT) and a diode among the power devices used in the driving circuit unit 10 generate heat of relatively high temperature so that a separate heat dissipation device for cooling the driving circuit unit 10 is generated. Is required, resulting in a problem that the production cost is increased.

An object of the present invention for solving the above-mentioned conventional problems, the production cost is increased due to the need for a separate device for the cooling of the drive circuit portion, and the assembly process by the switched reluctance motor and the drive circuit portion is installed separately It is to provide a fastening structure of the drive circuit unit integrated switch reluctance motor to solve this increasing problem and the problem that the drive circuit unit and the switch reluctance motor is not easily detached.

The present invention for achieving the above object, the stator coil winding the field coil to the fixed pole, and the rotor having a rotating protrusion formed to rotate by the electromagnetic force generated in the fixed pole of the stator is installed on the inside, and rotates with the rotor A motor case in which a rotating shaft is formed; An upper case which is fixed to a rotating shaft of the motor case and is provided with a rotating blower fan at an inner side thereof, and an inlet for sucking air on one side thereof; A heat dissipation tube installed in communication with the suction port of the upper case is bent toward the inside, and a cover portion fixed to one side of the upper case; A fixing part detachably fixing the heat dissipation pipe of the cover part to an inlet of the upper case; And a driving circuit part embedded in a cover part fixed to the upper case by the fixing part and having a power device for controlling power supplied to the account coil.

Preferably, the fixing portion, a screw thread is formed on the side contact with the heat dissipation tube and the suction port is fastened to each other.

Then, a screw thread is formed on the side contacting the cover portion and the upper case is fastened to each other.

According to the present invention as described above, the coupling force of the cover portion in which the drive circuit unit is built in the upper case of the switched reluctance motor is improved, and the coupling force and airtightness of the heat dissipation tube and the suction port are further improved to improve operation reliability.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is an exploded perspective view showing a fastening structure of a drive circuit unit integrated switched reluctance motor according to an embodiment of the present invention, Figure 3 is a fastening structure of a drive circuit unit integrated switch reluctance motor according to an embodiment of the present invention. Figure 4 is a side cross-sectional view, Figure 4 is a side cross-sectional view showing a fastening structure of the switch circuit integral type switch reluctance motor according to another embodiment of the present invention.

The external shape of the switched reluctance motor according to the embodiment of the present invention is formed of a main body case 30, the main body case 30 is the upper case 40 and the stator 54 and the blowing fan 41 is installed inside; The rotor 58 is divided into a motor case 50 installed inside.

One side of the upper case 40 is a suction port 42 is through, it is a passage through which the outside air is sucked by the rotation of the blowing fan 41.

The side surface 45 is formed along the circumferential circumference of the suction port 42, and the upper side of the side surface 45 is bent outward to form the upper surface 46.

Since the outlet 44 is formed between the upper case 40 and the motor case 50, the air sucked through the inlet 42 is an outward passage.

In addition, a first side surface 47 and a second side surface 48 are formed on the side surface of the upper case 40 with respect to the bent portion.

Inside the motor case 50 to which the upper case 40 is coupled to the upper side, the stator 54 is wound around the stator pole 52 and the stator pole 52 of the stator 54. The rotor 58 is provided with the rotary salient pole 56 so as to be rotated by the electromagnetic force.

The rotor 58 is installed through the rotation shaft 60 to protrude outward from the motor case 50.

Bearings 62 are respectively provided on the upper and lower sides of the rotation shaft 60 to provide a smooth rotation operation.

The cover part 80 fixed to the upper side of the upper case 40 (refer to FIG. 2) is a cylindrical shape having only one side open, and the lower inner side of the cover side surface 81 is fixed to contact the first side surface 47.

Since the first side surface 47 and the second side surface 48 are made of a material having elasticity, when the cover side surface 81 is fixed to the outer side of the first side surface 47, it is coupled by an interference fit method. By the elastic restoring force of the first side surface 47, the fastening force of the cover part 80 and the upper case 40 is imparted.

According to another embodiment of the present invention, as shown in Figure 4, the cover screw portion 94 and the body screw thread 96 is formed on the side contact with the cover portion 80 and the upper case 40, The cover part 80 and the upper case 40 are coupled by a screwing method.

On the other hand, located in the center of the cover portion 80, the tubular heat dissipation tube 84 installed in communication with the suction port 42 of the upper case 40, from the center of the cover portion 80 to the inside. Bending is formed.

The heat dissipation tube 84 is formed toward the inner portion of the through hole, and is divided into the outer surface 88 in contact with the air, the inner surface 86 installed on the other side of the outer surface 88 is installed, the cooling effect In order to maximize the inner surface 86 is formed in a polygonal shape.

The lower end of the heat dissipation tube 84 has a stepped protrusion 89 having a predetermined height in a stepped shape, and an upper screw thread 90 is formed on the side surface of the stepped protrusion 89.

In addition, the lower screw thread 92 for coupling the upper screw thread 90 is formed at the side surface 45 of the suction port 42, and the upper screw thread 90 and the lower screw thread 92 are provided in the embodiment of the present invention. The fixing part 98 is configured.

The fixing part 98 is not limited to the configuration of the upper screw thread 90 and the lower screw thread 92 as described above, and the heat dissipation tube 84 of the cover portion 80 is connected to the suction port of the upper case 40. In the technical idea of fixing, various fastening structures are applicable.

In addition, the upper and lower screw thread (90,92) is formed on the side of the heat pipe 84 and the suction port 42 in contact with each other, the various modifications of the position where the upper and lower screw thread (90,92) is formed is also present invention Is another embodiment of.

The mounting portion 82 for fastening the bolt is formed to protrude downward from the inner side of the upper side of the cover portion 80, the printed circuit board 72 is fixed to the mounting portion 82 is fastened by the fastening member 76. do.

The printed circuit board 72 is equipped with power devices 74 for constituting the driving circuit unit 70. The power device 74 is a transistor (TR), a field effect transistor (FET), an insulating gate. An Insulated Gate Bipolar Transistor (IGBT) or the like is used, and in particular, a device that generates a lot of heat including an insulated gate bipolar transistor is fixedly installed on the inner surface 86 of the heat dissipation tube 84 formed in a polygon.

As described above, the printed circuit board 72 of the driving circuit unit 70 installed inside the cover part 80 may be used by stacking only a single layer as shown in FIG. 3, but as the number of electronic devices used increases. Therefore, when the printed circuit board is additionally required, the product appearance is further miniaturized by being stacked and used inside the cover part 80 in a multilayer structure having two or three layers or more.

In addition, a wiring hole 83 is formed at a side surface of the cover part 80 to become a passage through which an electric wiring connecting the driving circuit part 70 and the stator 54 passes.

An operation and a coupling state of the fastening structure of the switch circuit integrated integrated reluctance motor according to the embodiment of the present invention having the above configuration will be described.

In the switched reluctance motor 20, when current flows through the field coil wound around the fixed salient pole 52 of the stator 54 by the operation of the driving circuit unit 70, between the stator 54 and the rotor 58. Reluctance torque is generated so that the rotor 58 is rotated in the direction in which the resistance of the magnetic circuit is minimized.

The rotation shaft 60 also rotates by the rotation of the rotor 58, and the blowing fan 41 connected to the rotation shaft 60 also rotates.

The outside air is introduced into the intake port 42 of the upper case 40 through the heat dissipation tube 84 of the cover part 80 by the rotation of the blowing fan 41, and the air passing through the blowing fan 41. Is discharged through the outlet 44.

The outer surface 88 of the heat dissipation tube 84 is cooled by the sucked air, and thus, the power device 74 fixed to the inner surface 86 of the heat dissipation tube 84 is also cooled. Will be done.

Since the inner surface 86 of the heat radiating tube 84 has a polygonal shape, the area in contact with the power device 74 is increased, thereby further improving the cooling effect.

The printed circuit board 72 connected to the power device 74 is installed inside the cover part 80, and the printed circuit board 72 is stacked in multiple layers as necessary to maximize space utilization. .

As shown in FIGS. 2 and 3, when the thread is formed only on the side surfaces of the heat dissipation tube 84 and the suction port 42, the cover is disposed after the upper thread 90 is positioned above the lower thread 92. By turning the unit 80, the heat radiating tube 84 is fastened to the side surface 45 of the suction port 42.

Since the heat dissipation tube 84 is fastened to the inlet 42 in the same manner as described above, air moved along the outer surface 88 of the heat dissipation tube 84 is disposed between the heat dissipation tube 84 and the upper case 40. It does not leak into the space of the through, so that the inlet flows into the blowing fan 41 side through the inlet 42 to further improve the operation efficiency of the device.

In addition, when the thread is formed on the side surface of the cover 80 and the upper case 40 located above the main body case 30 as shown in FIG. 4, the cover screw 94 and the main screw 96 are engaged with each other. By the operation, the upper screw thread 90 of the heat dissipation tube 84 and the lower screw thread 92 of the suction port 42 are fastened, so that the fastening force of the cover portion 80 and the upper case 40 is further improved. In addition, the heat dissipation pipe 84 and the suction port 42 also provide a good connection without leakage of air.

Since the cooling of the heat dissipation tube 84 is improved, the cooling of the power device 74 mounted on the heat dissipation tube 84 is also efficient, and the operation performance of the device is prevented from being degraded by high heat, thereby improving operation reliability. Will be provided.

According to the present invention as described above, the removable cover of the cover 80 and the upper case 40 in which the drive circuit unit 70 is built is made easy, improved sealing between the heat dissipation tube 84 and the suction port 42 To provide a structure.

The embodiments of the present invention as described above are not intended to limit the scope of the present invention, but are presented by way of example, and various embodiments may be applied within the spirit of the present invention.

As described above, according to the fastening structure of the switched reluctance motor integrated drive circuit unit according to the present invention, since the switched reluctance motor and the drive circuit unit is integrally installed, the assembly process and the number of parts are reduced to provide the effect of improving productivity. do.

In addition, in the coupling of the heat dissipation tube and the suction port or the coupling of the cover part and the upper case side, it is easy to attach and detach by using the screw fastening method, and the leakage of air is prevented between the heat dissipation pipe and the intake port, thereby cooling the heat dissipation pipe. As a result, cooling of the driving circuit unit is efficiently performed, thereby providing an effect of improving the operation reliability of the device.

Claims (3)

A motor case having a stator coiled with field coils around the stator poles, a rotor having a rotational salient pole formed therein so as to be rotated by an electromagnetic force generated by the stator poles of the stator, and a rotating shaft protruding with the rotor; An upper case fixed to a rotating shaft of the motor case and installed with a rotating fan, and having an inlet for sucking air on one side thereof; A heat dissipation tube installed in communication with the suction port of the upper case is bent toward the inside, and a cover portion fixed to one side of the upper case; A fixing part detachably fixing the heat dissipation pipe of the cover part to an inlet of the upper case; Fastening of the integrated reluctance motor of the integrated driving circuit unit, characterized in that the drive circuit unit is built in the cover portion fixed to the upper case by the fixing unit, and includes a power circuit for controlling the power supplied to the account coil. rescue. The fastening structure of the integrated switch circuit of the integrated circuit of the driving circuit unit according to claim 1, wherein the fixing unit is threaded on a side of the heat dissipating tube and the suction port to be in contact with each other. The fastening structure of a switch reluctance motor incorporating a drive circuit unit according to claim 1, wherein a screw thread is formed on a side of the cover part and the upper case in contact with each other.

Images