KR20110037660A - Resistor for controlling fan of automobile - Google Patents

Abstract

PURPOSE: A resistor for a cooling fan is provided to enhance safety by preventing explosion due to heat in use and to extend lifespan due to durability increase. CONSTITUTION: A resistor for a cooling fan comprises a casing member(10), a coil member(20) and a molding member(30). The casing member comprises a coil storage, of which one side is open. The coil member is inserted into the inside of the coil storage. Both ends of the coil member are protruded onto the outside of the casing member, and the coil member has resistance. The molding member is filled in the coil storage of the casing member. A protrusion for supporting the coil member is formed on the floor of the coil storage of the casing member. A hole is formed in the floor of the coil storage.

Description

Resistor for Controlling Fan of Automobile}

The present invention relates to a resistor for a cooling fan, and more particularly, to invent explosion by moisture expansion.

 In general, a car can keep the indoors contaminated by the passenger's breathing, outdoor atmosphere, or external temperature change in a fresh state, or by cooling and heating the room temperature to maintain a comfortable temperature for the passenger's body. An air conditioning system is installed.

In the air conditioner, a radiator, a heat exchanger such as a condenser, and the like, are equipped with a cooling fan that cools the fluid to be heat exchanged, and the cooling fan is operated by being rotated by a fan motor.

The cooling fan is controlled in the air volume through the speed change of the fan motor, the speed change of the fan motor is controlled by adjusting the voltage applied to the motor in each step.

The cooling fan resistor controls the voltage applied to the fan motor to control the speed change of the fan motor, and is wound around the cylindrical ceramic body member 1 and the cylindrical ceramic body member 1 as shown in FIG. 1. Is a non-combustible cement (3) which surrounds the resistance coil (2) and the outside of the resistance coil (2) in a state in which both ends of the resistance coil (2) protrude outwards, and prevents contact with outside air; It is provided on each end side of the cylindrical ceramic body member 1, and includes a terminal member (4) wound around the cylindrical ceramic body member (1) protruding to one side and both ends of the resistance coil (2) are respectively connected to each other. do.

The resistance coils 2 protrude to both sides of the non-combustible cement 3 and are welded and fixed to the terminal member 4, respectively, and the terminal members 4 are respectively connected to connectors for wiring connection with a motor. It is connected.

However, the conventional cooling fan resistor has a problem in that the non-combustible cement surrounding the resistance coil on the outside of the cylindrical ceramic body is easily peeled off by the heat generated from the shock and the resistance coil generated from the outside to expose the resistance coil to the outside.

As described above, since the resistance coil exposed to the outside is oxidized by contact with air, causing a malfunction, there is a closed end that requires maintenance.

In addition, the non-combustible cement of the conventional cooling fan resistor has a low insulation and thermal conductivity, which is a factor to increase the risk of deformation, fire, explosion, etc. of the product, thereby causing a problem that the stability of the resistor for the motor is greatly reduced. .

An object of the present invention is to provide a resistor for a cooling fan to prevent the risk of deformation, fire, explosion of the product and to increase the safety of the product.

An object of the present invention and the casing member having a coil storage chamber is open at one side;

A resistance coil member inserted into the coil storage chamber and having both ends projecting out of the casing member and having a resistance value;

A molding member filled in the coil storage chamber of the casing member,

It is solved by providing a cooling fan resistor on the bottom of the coil storage chamber of the casing member to support the resistance coil member to protrude a coil seating protrusion from the bottom surface.

The present invention has the effect of preventing the explosion phenomenon due to heat generated during use to improve safety.

The present invention has an effect that can be used safely for a long time to increase the durability to increase the life.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

Fig. 2 is an exploded perspective view showing the structure of the present invention, in which the cooling fan resistor of the present invention is disassembled to show each component in detail.

3 is a plan view showing an embodiment of the present invention, Figure 4 is a plan view showing another embodiment of the present invention, showing an example in which a plurality of discharge holes are formed in the casing member of the present invention.

5 is a cross-sectional view showing an embodiment of the present invention, Figure 6 is a cross-sectional view showing a comparative example of the present invention, Figure 5 is a coil storage chamber, the resistance coil member of the present invention is seated on the coil seating projection of the present invention FIG. 6 shows a state in which the resistance coil member is in close contact with the bottom surface of the coil storage chamber.

Fig. 7 is a use state diagram of the present invention, showing an example in which the motor control register according to the present invention is attached to a connector.

Hereinafter, as shown in FIG. 2, the casing member 10 includes a coil storage chamber 10a capable of inserting a part of the resistance nose part 20 into one side of the body, and the coil storage chamber 10a has one surface. It is formed by being dug into one surface of the body of the casing member 10 in an open groove shape.

In addition, the casing member 10 is not broken or damaged by heat generated from the resistance coil member 20 during operation using a ceramic housing made of ceramic material, and found that any material having a high heat resistance besides ceramic may be manufactured. Put it.

Both sides of the casing member 10 is preferably formed with a terminal guide groove 10b into which the connection terminal member 40 to be described later is inserted around the body.

The terminal guide groove 10b guides the coupling position of the connection terminal member 40 to be wrapped around the outer circumference of the casing member 10 so that the position of the connection terminal member 40 can be uniformly assembled.

The resistance coil member 20 is based on the use of nichrome wire, which is an alloy of nickel and chromium, and any material having a resistance that interrupts the flow of current is included in the configuration of the present invention.

The resistance coil member 20 is embedded in the coil storage chamber 10a so that both ends protrude to the outside of the casing member 10 to protrude to positions corresponding to the terminal guide grooves 10b.

In addition, the coil storage chamber 10a of the casing member 10 is filled with a molding member 30 after the resistance coil member 20 is inserted to block the resistance coil member 20 from the outside air.

The resistance coil member 20 is oxidized upon contact with external air, resulting in quality problems.

The coil storage chamber 10a is filled with the molding member 30 to completely block the resistance coil member 20 from external air.

The molding member 30 preferably uses alumina (AL ₂ O ₃ ) cement.

The alumina cement is a cement material having an alumina (AL ₂ O ₃ ) content of 70% or more. The alumina cement is known to have high insulation and thermal conductivity and high heat resistance.

The alumina cement has a high heat resistance to prevent the occurrence of short-circuit due to the current flow to the outside, as well as the high heat resistance is deformed due to the high heat generated in the resistance coil member 20 when overcurrent, overvoltage occurs It prevents fire and explosion due to overheating by quickly dissipating heat to the outside with high thermal conductivity.

The alumina cement is mixed with water and then poured into the coil storage chamber 10a of the casing member 10 to mold and then dry the coil storage chamber 10a.

In addition, the molding member 30 is preferably used by mixing a fluid in the alumina cement, the alumina cement and the fluid is mixed in a weight ratio of more than 100: 0.0 or less.

The fluid is to protect the surface by forming a thin coating film on the surface after drying the alumina cement.

In addition, the flow material is to make the alumina cement to clarify well in water to be easily poured with a small amount of water to reduce the shrinkage rate by evaporation of water after drying and to speed up the drying, that is, the curing speed.

In addition, the fluid increases fluidity to facilitate filling of the alumina cement into the coil reservoir 10a.

The fluid is based on the use of a polymer resin having a product name of PERAMIN CONPAC 149S, the PERAMIN CONPAC 149S is a kind of known fluid sold as a detailed description will be omitted.

The molding member 30, that is, alumina cement is filled and molded in the coil storage chamber 10a and dried to prevent oxidation of the resistance coil member 20 due to external air, thereby increasing durability of the product.

On the other hand, the casing member 10 has a discharge hole 11 is formed in the bottom surface of the coil storage chamber (10a) as shown in Figs.

As shown in FIG. 3, the discharge hole 11 is formed to have a long hole shape in the center of the bottom surface of the coil storage chamber 10a in the longitudinal direction of the casing member 10.

The discharge hole 11 discharges vaporized vapor by heat of the resistance coil member 20 when the cooling fan resistor of the present invention is operated in a state in which the molding member 30 contains a large amount of moisture.

The discharge hole 11 discharges steam generated in the molding member 30 when the cooling fan resistor of the present invention is used after immersion or during immersion to contain excess moisture in the molding member 30. 30) The casing member 10 is prevented from being deformed or damaged due to excessive expansion of moisture therein.

In addition, when the overheating occurs in the resistance coil member 20, the discharge hole 11 emits heat from the resistance coil member 20 to the outside, thereby overheating and quenching the resistance coil member 20. The casing member 10 is to prevent deformation and damage.

Preferably, a plurality of discharge holes 11 spaced apart from each other are formed in the bottom surface of the coil storage chamber 10a as illustrated in FIG. 4.

A plurality of discharge holes 11 are provided on the bottom surface of the coil storage chamber 10a to cover the entire bottom surface of the vaporized or vaporized resistance coil member 20 in which the moisture contained in the molding member 30 is vaporized. By evenly discharging to prevent further deformation and breakage of the casing member (10).

Meanwhile, the resistance coil member 20 is inserted into the coil storage chamber 10a before the molding member 30 is filled and molded in the coil storage chamber 10a. In this case, the coil storage chamber of the plane is generally shown in FIG. 5. (10a) is to be seated on the bottom to be in uniform contact with the bottom surface of the bottom of the coil reservoir (10a).

As described above, in the state where the resistance coil member 20 is seated on the bottom surface of the flat coil storage chamber 10a and is in uniform contact with the bottom surface, heat generated from the resistance coil member 20 is applied to the casing member 10. It is quickly delivered as it is to overheat the casing member 10, there is a problem that generates deformation and breakage due to overheating.

In addition, the casing member 10 receives the most of the heat generated from the resistance coil member 20 during operation in the state where the resistance coil member 20 is seated on the bottom surface of the coil storage chamber 10a and repeats overheating and quenching. There is a problem that the durability becomes weak.

In the present invention, as shown in FIG. 5, the coil seating protrusion 12, which supports the resistance coil member 20 and is spaced apart from the bottom surface, protrudes from the bottom of the coil storage chamber 10a of the casing member 10. .

The coil seating protrusions 12 are arranged in plural to be spaced apart in the longitudinal direction of the casing member 10 from the bottom surface of the coil storage chamber 10a so that the resistance coil member 20 is horizontally spaced apart from the bottom surface. It is desirable to maintain.

When the resistance coil member 20 is inserted into the coil storage chamber 10a before the molding member 30 is filled, the coil outer circumferential surface is seated on the coil seating protrusion 12 so as to be spaced apart from the bottom surface.

The resistance coil member 20 is seated on the coil seating protrusion 12 and is disposed in the coil storage chamber 10a in a state where the contact surface with the casing member 10 is minimized and filled into the coil storage chamber 10a. It is fixed to 30.

Therefore, the present invention for the cooling fan resistor is the heat generated from the resistance coil member 20 during operation is mostly discharged to the outside evenly through the molding member 30, the casing member in the overheat of the resistance coil member 20 due to overload Deformation and breakage of (10) are prevented.

In addition, the present invention for the cooling fan resistor is to increase the durability by preventing overheating and rapid cooling of the casing member (10).

On the other hand, in the coil storage chamber (10a) the coil support protrusions 13 are supported on both inner side surfaces of the casing member in the longitudinal direction of both ends of the resistance coil member 20.

The coil support protrusion 13 may be bent at both ends of the resistance coil member 20 to support an end of the resistance coil member 20 protruding to the outside through an open portion of the coil storage chamber 10a, thereby supporting the resistance. The coil member 20 is fixed in position so as to be disposed in the center of the coil storage chamber 10a.

The resistance coil member 20 is seated on the coil seating protrusion 12 in the coil storage chamber 10a, and both ends thereof are supported by the coil support protrusion 13 to support the molding member 30 in the coil storage chamber. When filling and molding into 10a, no flow is generated, and the coil storage chamber 10a is disposed in a fixed state.

Therefore, in the present invention, the molding operation is performed in a state in which the resistance coil member 20 is disposed at an accurate position, thereby increasing convenience in manufacturing and enabling mass production with uniform quality.

On the other hand, both sides of the casing member 10 is provided with a coupling terminal member 40 is coupled to each other, the connecting terminal member 40 is made of a conductive material and formed of a terminal plate having an arbitrary width and length Both sides of the casing member 10 are coupled along the terminal guide grooves 10b.

One end of the connection terminal member 40 is bent to protrude vertically from the outer peripheral surface of the casing member 10 is formed as a terminal connecting portion 41 which is connected to the connector terminal portion 53 to be described later.

One end of the connection terminal member 40 protrudes vertically from the outer circumferential surface of the casing member 10 and is bent to partially overlap with the terminal connection part 41, and a coil fixing part having a coil fixing groove 42 a formed at an end thereof ( 42).

Both ends of the resistance coil member 20 protrude toward the open side of the coil storage chamber 10a in which the molding member 30 is filled, and are inserted into the coil fixing groove 42a of the coil fixing part 42 to connect the terminal. It is connected to (41).

The coil fixing part 42 is welded and fixed to the terminal connection part 41 together with both ends of the resistance coil member 20 protruding through the coil fixing groove 42a.

As described above, both ends of the resistance coil member 20 are inserted into the coil fixing groove 42a of the coil fixing part 42 and connected to the terminal connecting part 41 at a predetermined position.

Therefore, it is possible to maintain a constant quality during the automation of the manufacturing process of the product, it is possible to mass production with a uniform quality.

On the other hand, the motor control register of the present invention is mounted on the connector 50 for wiring connection with the motor, respectively, as shown in FIG.

The connector casing 50a of the connector 50 is provided with a first connector portion 51 and a second connector portion 52 which can be connected to and connected with other connectors for wiring with a motor thereon.

In addition, the connector 50 has a fuse (60) to prevent fire when overcurrent and overload.

The lower part of the connector casing 50a is provided with a connector terminal part 53 to which each terminal connection part 41 of the connection terminal member 40 is connected and fixed, respectively. The casing member of the motor control register is provided on both sides. The housing support 54 which supports 10 and firmly mounts is protruded.

Since the casing member 10 is heated by the heating of the resistance coil member 20 during operation, the housing support 54 is preferably made of a metal material to prevent deformation due to heat generated from the resistor for controlling the motor. The manufactured housing support 54 is fixed to both sides of the connector casing (50a) by insert injection method during the manufacturing of the connector casing (50a).

In the motor control register of the present invention, the terminal connecting portion 41 is welded and fixed to the connector terminal portion 53 of the connector 50, and both ends of the casing member 10 are supported by the housing support 54 so that the connector ( 50), the connector 50 is electrically wired with the fan motor through the first connector part 51 and the second connector part 52, thereby controlling the speed of the fan motor with the motor control register of the present invention. will be.

Wiring and principle for controlling the speed of the fan motor with the motor control register of the present invention is well known and the detailed description is omitted.

The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

1 is a perspective view showing a conventional motor control register

Figure 2 is an exploded perspective view showing the structure of the present invention

Figure 3 is a plan view showing an embodiment of the present invention

Figure 4 is a plan view showing another embodiment of the present invention

5 is a cross-sectional view showing an embodiment of the present invention.

6 is a cross-sectional view showing a comparative example of the present invention.

7 is a state diagram used in the present invention

* Description of the major symbols in the drawings *

10 casing member 11 release hole

12: coil mounting protrusion 13: coil support protrusion

40: connecting terminal member 41: terminal connection

42: coil fixing part 50: connector

Claims (5)

A casing member having a coil storage chamber having one side opened; A resistance coil member inserted into the coil storage chamber and having both ends projecting out of the casing member and having a resistance value; A molding member filled in the coil storage chamber of the casing member, And a coil seating protrusion protruding from the bottom surface of the casing member to support the resistor coil member to be spaced apart from the bottom surface. The method according to claim 1, And a discharge hole is formed in a bottom surface of the coil reservoir. The method according to claim 1, And a plurality of discharge holes spaced apart from the bottom surface of the coil storage chamber. The method according to any one of claims 1 to 3, And a coil support protrusion protruding from both end sides of the resistance coil member on both inner side surfaces of the casing member in the longitudinal direction of the casing member. The method according to any one of claims 1 to 3, The molding member is a mixture of a flow material to the alumina cement, the alumina cement and the flow material is a resistor for a cooling fan, characterized in that the mixture in a weight ratio of more than 100: 0.03 or less.

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