KR100722882B1 - Rust Prevention Structure of blower motor - Google Patents

Abstract

The present disclosure relates to a corrosion protection structure of a blower motor, and more particularly, to prevent the inflow of pollutants such as water into a circuit portion disposed between a heat sink and a base, thereby preventing short circuit of the circuit and corrosion of parts due to the infiltration of pollutants. The present invention relates to a corrosion protection structure of a blower motor which improves the reliability of the product by preventing the damage.

The corrosion protection structure of the blower motor of the present invention is a corrosion protection structure of the blower motor, the circuit unit 110 for controlling the drive rate of the blower motor through the FET 111 fixed on the printed circuit board 114; A heat sink 120 formed on top of a heat sink fin 121 for absorbing heat generated from the circuit unit 110 to radiate heat to the outside; and a base 130 fixed to the bottom of the heat sink 120; And a rubber seal 140 disposed on an assembly surface of the base 130 and the heat sink 140 so that the base 130 and the heat sink 120 are tightly assembled.

Blower motors, field effect transistors (FETs), rubber seals

Description

Rust prevention structure of blower motor

1 is a control circuit diagram of a typical blower motor,

Figure 2a is an exploded perspective view showing a corrosion preventing structure of a conventional blower motor,

Figure 2b is a cross-sectional view showing a corrosion preventing structure of a conventional blower motor,

Figure 3 is a perspective view showing a corrosion protection structure of the blower motor of the present invention,

Figure 4 is an exploded perspective view showing a corrosion protection structure of the blower motor of the present invention,

5A and 5B are cross-sectional views illustrating a corrosion preventing structure of the blower motor of the present invention.

※ Explanation of code for main part of drawing

110: circuit portion, 111: FET, 112: temperature fuse, 113: fixed plate, 114: printed circuit board,

115: terminal, 120: heat sink, 121: heat sink fin, 122: receiving groove, 123: fixing piece,

124: fastener, 125: through, 130: base, 131: seating groove, 132: protrusion, 133: through,

134: insertion groove, 140: rubber seal

The corrosion prevention structure of the blower motor of the present invention prevents contaminants such as water from flowing into the circuit unit disposed between the heat sink and the base, thereby preventing short circuit of the circuit due to infiltration of contaminants and improving corrosion of the product. The corrosion protection structure of the blower motor.

In general, a vehicle is equipped with a cooling and heating system to provide a comfortable indoor space for a driver or a passenger by performing various air conditioning functions such as ventilation and air conditioning of the vehicle's air by a driver's operation.

As shown in FIG. 1, a circuit for controlling the operation of a blower motor for supplying air to a heating / cooling system for supplying warm or cold air to an inside of a vehicle is illustrated in FIG. 1. A microprocessor (1) for controlling the operation of a cooling and heating system by temperature, solar radiation, etc., a current controller (2) for adjusting and outputting a current according to a drive signal output from the microprocessor (1), and a current controller (2). The transistor 4 is configured to adjust the operating power supplied to the blower motor 3 by receiving a current output from the base terminal.

As described above, in the apparatus for controlling the operation of the blower motor 3, the microprocessor 1 first detects an unshown key input to change the operation mode (1, 2, 3, 4) of the heating and cooling system. Detect. In response thereto, a driving signal is generated and output to the current controller 2. According to the input drive signal, the current controller 2 varies the current and supplies the current to the base terminal of the transistor 4.

Then, the negative terminal (-) side of the blower motor 3 is connected to the collector terminal of the transistor 4 to the battery voltage Vign applied when the positive terminal (+) side of the blower motor 3 is started. When the transistor 4 is driven by a current flowing through the base terminal of the transistor 4, the power supply Vign applied to the positive terminal (+) side of the blower motor 3 is connected to the blower motor 3 and the transistor 4. The blower motor 3 rotates by passing through to ground.

The inside or outside air introduced by the rotation of the blower motor 3 is cooled or heated by an evaporator or a heater constituting the air-conditioning system, and is discharged into the vehicle. Accordingly, the driver or the passenger may be provided with cool air or warmth. .

Figure 2a is an exploded perspective view showing a corrosion protection structure of a conventional blower motor, Figure 2b is a combined cross-sectional view showing a corrosion protection structure of a conventional blower motor, the corrosion of the conventional blower motor as shown in the figure The prevention structure includes a circuit portion for controlling the drive rate of the blower motor, a heat sink for absorbing heat generated from the circuit portion to radiate heat to the outside, and a base fixed to the lower portion of the heat sink.

By the way, such a conventional corrosion protection structure does not have a problem in the lower part of the base in the case of a small amount because there is no leakage prevention device when water flows into the circuit portion disposed between the heat sink and the base during use, it is not a big problem functionally Corrosion of parts shortens the life of the product, and when a large amount of water is introduced, a short circuit occurs between terminals, causing a problem of malfunction.

The present invention has been made in order to solve the above problems blower motor to prevent the inflow of contaminants such as water to the circuit portion disposed between the heat sink and the base to prevent the short circuit of the circuit due to the infiltration of contaminants The purpose is to provide a corrosion protection structure for

Corrosion protection structure of the blower motor of the present invention for achieving the above object is a corrosion protection structure of the blower motor, the circuit portion for controlling the drive rate of the blower motor through the FET fixed on the printed circuit board; and in the circuit portion A heat sink formed at an upper portion of a heat sink to absorb heat generated and radiate heat to the outside; and a base fixed to a lower portion of the heat sink; And a rubber sealing structure including a rubber seal disposed on an assembly surface of the base and the heat sink so that the base and the heat sink are tightly assembled.

The heat sink of the corrosion protection structure of the blower motor of the present invention preferably has a receiving groove having both sides opened at a lower portion thereof, and the base protrudes from both sides of the upper surface of the protrusion to block the receiving grooves of the heat sink.

Preferably, the base of the corrosion protection structure of the blower motor of the present invention forms an insertion groove into which a rubber seal is inserted into an assembly surface with the heat sink.

Preferably, the rubber seal of the corrosion protection structure of the blower motor of the present invention is integrally formed by double injection onto the base so that an upper portion of the rubber seal is exposed at the assembly surface of the base and the heat sink.

Hereinafter, a preferred embodiment of the corrosion protection structure of the blower motor of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a perspective view showing a corrosion protection structure of the blower motor of the present invention, Figure 4 is an exploded perspective view showing the corrosion protection structure of the blower motor of the present invention.

The corrosion preventing structure of the blower motor of the present invention as shown in the drawings is largely composed of a circuit portion, a heat sink, a base and a rubber seal.

The circuit unit 110 is a field effect transistor (FET) for controlling the drive ratio of the blower motor by receiving an external signal, and a temperature fuse (short-circuit when the heat sink 120 is overheated) to prevent the blower motor from being overloaded. 112, a fixed plate 113 for fixing the FET 111 and the temperature fuse 112 to the bottom surface of the heat sink 120, and a circuit is formed on the plate to the FET 111 and the temperature fuse 112. A printed circuit board 114 to be connected and a terminal 115 fixed to the printed circuit board 114 to supply a control signal and power.

The heat sink 120 has a plurality of heat dissipation fins 121 are formed on the upper side, receiving grooves 122 having both sides open at the bottom thereof, and fixing pieces 123 are protruded from both sides of the lower end. In addition, the bottom surface of the receiving groove 122 is formed with a fastening hole 124 for fixing the circuit unit 110 by the fastening member (B), the fixing piece 123 is a through hole for coupling with the base 130 ( 125) is formed.

The base 130 has a mounting groove 131 formed on an upper surface thereof, and protruding pieces 132 protruding upwards to block both sides of the receiving groove 122 of the heat sink 120 to both sides of the mounting groove 131. Is formed, the through hole 133 for fastening with the heat sink 120 is formed.

In addition, the insertion groove 134 is formed in the assembly surface in contact with the heat sink 120, and the rubber sealing 140 for maintaining the watertightness of the assembly surface is inserted into the insertion groove 134. The rubber seal 140 may be integrally formed by double injection on the assembly surface of the base 130.

Hereinafter, the function of the corrosion preventing structure of the blower motor of the present invention having the above configuration will be described.

5A and 5B of the accompanying drawings are cross-sectional views illustrating a corrosion preventing structure of the blower motor of the present invention.

As shown in the figure, the FET 111 and the temperature fuse 112 of the circuit unit 110 are disposed on the inner surface of the receiving groove 122 formed under the heat sink 120, and the FET 111 and The temperature fuse 112 is fixed to the position by the fixing plate 113, the fastening member (B) passing through the fixing plate 113 is a fastening hole 124 formed in the bottom surface of the receiving groove 122 of the heat sink 120 It is fixed tightly as it is tightened.

The FET 111 and the temperature fuse 112 fixed to the bottom surface of the accommodating groove 122 of the heat sink 120 by the fixing plate 113 of the printed circuit board 114 disposed below the fixing plate 113. The terminal 115, which is electrically connected to the circuit and which receives the control signal and the power, is fixed to the lower portion of the printed circuit board 114.

As described above, the heat sink 120 to which the circuit unit 110 is fixed is mounted on the upper surface of the base 130, and a fastening member B such as a screw penetrates the through hole 133 of the base 130. It is fastened to the fastening hole 124 of the fixing piece 123 formed at both ends of the heat sink 120 is assembled firmly.

On the other hand, both openings of the receiving groove 122 formed in the longitudinal direction in the lower portion of the heat sink 120 is closed by the protrusion pieces 132 formed to protrude upward on both sides of the mounting groove 131 of the base 130 is accommodated The circuit unit 110 located inside the groove 122 prevents contamination by external pollutants.

In particular, the rubber sealing 140 disposed on the upper surface of the base 130 has an insertion groove 134 formed along a line connecting the edge of the receiving groove 122 of the base 110 and the side and top of the protruding piece 132. It is inserted into, or formed integrally by double injection along the line connecting the edge of the receiving groove 122 on the base 130 and the side of the protruding piece 132 and the top of the protruding piece 132 is exposed to the upper part .

Accordingly, when the base 130 and the heat sink 120 are assembled, the bottom edge portion of the heat sink 120 comes into contact with the rubber seal 140 inserted into the edge of the assembly surface of the base 130 and thus the rubber seal 140. ), The assembly part is sealed to maintain the watertightness, thereby preventing corrosion of the circuit part 110 by penetration of moisture or water, thereby prolonging the life of the product and preventing short between terminals. To improve.

As described above, the corrosion protection structure of the blower motor of the present invention prevents water from flowing into the circuit unit disposed between the heat sink and the base, thereby preventing the short circuit of the circuit and the corrosion of the parts, thereby improving reliability of the product.

Claims (4)

In corrosion protection structure of blower motor, A circuit unit 110 for controlling a driving rate of the blower motor through the FET 111 fixed on the printed circuit board 114; A heat sink 120 formed on top of a heat dissipation fin 121 for absorbing heat generated from the circuit unit 110 to radiate heat to the outside; A base 130 fixed to the lower portion of the heat sink 120; And, Corrosion preventing structure of the blower motor including a rubber seal 140 is disposed on the assembly surface of the base 130 and the heat sink 140 so that the base 130 and the heat sink 120 is tightly assembled. The method of claim 1, The heat sink 120 has a receiving groove 122 having both sides opened at the bottom thereof, and the base 130 protrudes 132 blocking both sides of the receiving groove 122 of the heat sink 120 at both sides of the upper surface. Corrosion preventing structure of the blower motor, characterized in that the protrusion). The method according to claim 1 or 2, The base 130 is corrosion protection structure of the blower motor, characterized in that to form an insertion groove 134 into which the rubber seal 140 is inserted into the assembly surface with the heat sink 120. The method according to claim 1 or 2, The rubber sealing 140 is a corrosion prevention structure of the blower motor, characterized in that the double injection on the base 130 is formed integrally so that the upper portion is exposed from the assembly surface of the base 130 and the heat sink 120.

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