KR20010010302A - Rotary switch - Google Patents

Abstract

PURPOSE: A rotary switch is provided to protect a circuit by shortening a power source when the interior resistance of the resistance device is raised by the voltage change. CONSTITUTION: A plurality of resistance devices have a PTC characteristics. A plurality of terminals are electrically connected to a power source line. A conductive heat radiating device radiates a heat according to the interior resistance. A plurality of resistance insertion holes for inserting the resistance devices and the terminals and a terminal slit are formed in an insulating case. A resistance receiving recess which has a same cross-section with the resistance insertion hole is formed in a conductive case. A rotary plate has an operating contact point for electrically connecting the radiating device and the terminals and a rotor integrally engaged with the central portion and extended by a predetermined length.

Description

Rotary switch

The present invention relates to a switch for mechanically connecting, short-circuit or switching a part of an electric circuit, in particular a resistance device electrically connected to a load in order to control the rotational speed of an electrical appliance, for example a rotary machine or a power tool inside the switch It is integrated in.

In general, a rotary machine or a power tool uses the rotational force of the electric motor. The electric motor needs to adjust its rotation speed as necessary. In order to control the rotational speed of the electric motor, the voltage applied to the electric motor is controlled. There is a need. Therefore, in order to control the rotational speed of the electric motor, a plurality of resistance elements having different resistance values are connected in series between the electric motor and the power supply, and the number of rotations of the electric motor is mechanically selected by mechanically selecting the gradual breaks between the resistance elements. You need a switch to adjust.

Switches are applied in various patterns. For example, rotary switches, slide switches, pushbutton switches, and the like, these switches can be selected according to the type of electrical appliances or the environment of use. Rotary switches and slide switches are suitable for controlling the number.

For example, the air volume control switch used in the vehicle air conditioning system is mainly applied a rotary switch or a slide switch, which is easy to operate depending on the vehicle type.

This air conditioner is forcibly blown the heat exchanged air to the blower while passing through the heat exchanger to flow into the cabin, wherein the air flowing into the car interior is introduced into the car interior by adjusting the rotational speed of the blower motor built into the blower fan. The inflow of air is determined.

Figure 6 shows a circuit diagram showing the electrical connection configuration of the air volume control switch applied to a conventional vehicle air conditioner. Referring to the drawings, the electric circuit connects a plurality of resistors 31 having different resistance values in series to one end of a blower motor 30 connected to a power source such as a battery, and branches between the resistors 31. The air volume control switch 32 is electrically connected to the connected contact point, and the air volume control switch 32 is fastened to the control panel of the vehicle, and is used separately from the resistors 31, and is illustrated in the switch. By rotating the knob not to select the resistors (31) to control the number of revolutions of the blower motor (30), as a result it is possible to control the amount of air flowing into the vehicle interior.

In such an electric circuit, when the power is supplied to the blower motor 30, deterioration may occur due to the internal resistance of the resistor 31. Furthermore, when the blower motor 30 is constrained, for example, a power failure due to a failure of the motor. In spite of the energization, if the rotor does not rotate, the internal resistance of the resistor 31 may increase rapidly and generate heat, and as a result, there is a risk of fire. If the fuse is shorted, there is an economic problem of replacing the resistor assembly.

SUMMARY OF THE INVENTION An object of the present invention is to provide a switch using a resistance element using a PTC element that is sensitive to temperature, and integrating this resistance element into the switch to simplify the structure.

Another object of the present invention is to provide a switch capable of protecting a circuit by preventing deterioration of a resistance element due to a restraint of a motor.

The switch of the present invention for achieving the above object can be applied to both rotary type and slide type switches, and is made possible by integrating a resistance element having a PTC characteristic and a cooling means for cooling the resistance element.

The present invention provides a plurality of resistance elements having a PTC characteristic; A plurality of terminals electrically connected to the power lines; A conductive heat dissipation element that radiates deterioration due to internal resistance in the same shape as the resistance element; An insulating case having a cylindrical shape through which a plurality of resistance insertion holes and terminal slits for inserting the resistance element and the terminal into concentric circles are formed in the thickness direction; A conductive case having the same radius of curvature as that of the case and coupled to a bottom surface thereof, the conductive case having a resistance receiving groove having the same resistance cross-section as the resistance insertion hole; And a rotating plate integrally coupled to a movable contact point for electrically connecting the heat dissipation element and the plurality of terminals fastened to the insulating case and having a rotor extended to a predetermined length.

In addition, the connector surrounding the plurality of terminals protruding through the terminal slit may be integrally formed, and a cooling fin for radiating deterioration of the resistance element may be integrally formed on the bottom surface of the conductive case.

According to this configuration, the resistor and the heat dissipation element for cooling the heat generated by the resistance element are integrally formed in the switch, and the deterioration of the resistance element can be prevented while the power is shorted when the motor is restrained.

1 is a longitudinal sectional view showing a coupling structure of a switch according to the present invention;

FIG. 2 is a plan view as seen from the line A-A of FIG. 1;

3 is a bottom view of FIG. 1,

4 is a cross-sectional view showing another embodiment according to the present invention;

5 is a circuit diagram of a switch according to the present invention;

6 is a circuit diagram of a conventional switch.

Explanation of symbols on the main parts of the drawings

1: rotary switch 2: insulated case

3: main body 4: resistance insertion hole

5: terminal insertion hole 6: resistance element

7: Heat dissipation element 8-10: Terminal 1-3

11 connector 12 conductive case

13: receiving groove 14: heat dissipation fin

16: rotating plate 17a-17c: movable contact

18: load 20: knob

1 is a longitudinal sectional view showing an embodiment of a switch according to the present invention, Figure 2 is a plan view as seen from the line A-A of Figure 1, Figure 3 shows a bottom view of Figure 1;

Referring to the drawings, the switch denoted by reference numeral 1 as a whole shows a rotary type switch, and the switch 1 includes a plurality of resistance elements 6 and heat dissipation elements 7 having PTC characteristics. Doing.

The Ba of the resistance element (6) is to be to be capable of performing the valence control by the addition of a small amount of rare earth thereto by a sintered body of BaTiO ₃ as a gas to the PTC thermistor having a defined thermometer semiconductor Chemistry, BaTiO ₃ Sr or Pb When replaced by, the resistivity is rapidly increased and the temperature (Curie temperature) is changed. The temperature characteristic of PTC is also greatly changed by the type and amount of additives, furthermore, the purity of the material and the sintering conditions. Therefore, when manufactured using these conditions, it is possible to obtain a resistance element required in the embodiment.

The temperature at which the PTC resistance value changes abruptly appears near the Curie point of the BaTiO ₃ crystal and is closely related to the phase transition (transition of the tetragonal and cubic fields) of the crystal. It is used as a current control device to prevent deterioration due to rapid temperature rise during the confinement of.

The heat sink 7 is a heat sink that absorbs heat of a resistance element that is sensitive to high heat, and is made of brass or aluminum, and prevents deterioration by absorbing and radiating heat generated from the resistance element. .

In the embodiment, to provide a switch in which the resistance element 6 and the heat dissipation element 7 are integrated in the insulating case 2, the insulating case 2 is formed into a cylindrical shape by injection molding a plastic material. The resistance element 6 and the heat dissipation element 7 are manufactured in an integrated case.

The insulating case 2 has a cylindrical main body 3, through which a plurality of resistance insertion holes 4 and a pair of first and second terminal slits 5 penetrate in the thickness direction of the main body 3. . This resistance insertion hole 4 is arranged concentrically on the edge of the main body 3, and has a fan shape divided about 90 degrees from the central axis, and the four insertion holes 4a-4d are provided in this divided sector. It is formed in the thickness direction of (3). Three through holes 4a-4c of the insertion holes are insertion holes into which the resistance element 6 and the heat dissipation element 7 are inserted, and the other insertion holes 4d form insertion holes for inserting the terminals. In this case, the resistance element 6 and the heat dissipation element 7 are sequentially inserted into the resistance insertion holes 4a-4c, and they are brought into contact with each other. In addition, the lower part of the resistance element 6 is seated by a conductive case 12 which will be described later, and the conductive case 12 is coupled to face the insulating case 2.

The first terminal slit 5a is located on the opposite side of the resistance insertion hole 4 and penetrates in the slit shape on the same circumference as the resistance insertion hole 4. The second terminal slit 5b is formed to be spaced apart by a predetermined distance in the radially inner side of the first terminal slit 5a, and the first and second terminal slits 5a and 5b are formed at an angle of the resistance insertion hole 4. It has a fan shape with a larger angle. This angular range is to be always electrically connected to the terminal connected to the power line and the resistance element 6 connected to the load side to match the rotational trajectory of the movable contacts (17a-17c) to be described later.

Furthermore, the insulating case 2 is inserted into the first and second terminals 8 and 9 and the resistance insertion hole 4d inserted into the lower part of the main body 3, that is, the first and second terminal slits 5a and 5b. A connector 11 extending downward to surround them with respect to the protruding portion of the third terminal 10, the connector 11 being electrically connected to an unshown connector connected to a power line; By connecting them, the electrical wiring is not required.

Numeral 12 denotes a conductive case which is coupled to the lower portion of the resistance insertion hole 4 formed in the insulating case 2 to energize the load, and is manufactured by injection molding. The conductive case 12 has a plurality of receiving grooves 13 corresponding to the resistance insertion holes 4 on the upper surface thereof. Therefore, when the insulating case 2 and the conductive case 12 face each other and are coupled, a groove having a predetermined depth is formed by the resistance insertion hole 4 and the receiving groove 13, where the resistance element 6 and the heat radiating element are formed. (7) is sequentially inserted, and when the insertion thereof is completed, the heat dissipation elements 7 and the first and third terminals 8-10 are slightly protruded from the upper surface of the insulating case 2.

In this state, the insulating case 2 and the conductive case 12 are coupled by fastening the screw 15 through the resistance element 6 and the heat radiating element 7 through the conductive case 12.

The conductive case 12 is made of a material having excellent conductivity and heat dissipation, and preferably made of light aluminum or an aluminum-based material. Since the conductive case 12 using the material is in contact with the resistance element 6, when the resistance element 6 generates heat, the heat is conducted to the conductive case 12 and at the same time, the heat is dissipated to prevent degradation. .

Furthermore, the conductive case 12 includes heat radiation fins 14 integrally formed on the bottom thereof, which is effective for dissipating heat conducted from the resistance element 6. In this case, the bottom surface of the heat radiation fins 14 may be positioned on the same plane as the connector 11 so as to prevent interference with adjacent components.

The heat dissipation fins 14 can increase the heat transfer area of the conductive case 12, and can be formed by extrusion or post-processing to cut the surface, or can be molded by a die casting method.

Meanwhile, the resistive elements 6 and the 1-3 terminals are disposed on the front surface of the assembly in which the resistors 6 and the 1-3 terminals 8-10 are fastened to the insulating case 2 and the conductive case 12. The rotating plate 16 which electrically selects and connects (8-10), and adjusts the rotation speed of the blower motor 21 is constructed.

The rotary plate 16 is electrically connected to each other with three movable contacts 17a-17c at the bottom thereof, and one of the movable contacts 17a of the movable contacts is the resistance element when the rotary plate 16 rotates. (6) are selectively connected, and the remaining two movable contacts 17a and 17b are always connected to the first and second terminals 8 and 9, respectively. The first terminal 8 is a power supply line to which power is directly applied, and the second terminal 9 is a ground line grounded to insulate the rotor plate 16 from the movable contact.

When the rotating plate 16 provided with the movable contacts 17a-17c rotates, each of the movable contacts 17a-17c rotates with the rotating plate 16 while the corresponding resistance element 6 and the first and second terminals 8 are rotated. (9) is electrically connected, and thus the amount of current applied to the blower motor 21 is variable to adjust the number of revolutions. As a result, the amount of rotation of the blower fan (not shown) stored in the blower motor 21 is adjusted. Since the amount of air discharged into the room is controlled.

Reference numeral 18 in the drawing denotes a rod integrally formed with the rotating plate 16, which has a length extending to an unshown control panel provided in the vehicle interior and fastening the knob 19 to the end thereof. Accordingly, as the rotary plate 16 rotates as the knob 19 rotates, the rotary plate 16 is selectively connected to the resistance elements 6, thereby changing the voltage applied to the blower motor 21 to change the rotation speed thereof. do. Reference numeral 20 in the figure is a case coupled to the insulating case (2).

4 is a front view showing another embodiment of the present invention, illustrating a slide type switch. Referring to the drawings, the slide switch 22 arranges the same resistance element 6, heat dissipation element 7 and terminals 8-10 as the components of the embodiment in parallel to the main body 23, and is shown on the upper surface thereof. The same operation and effect as in the embodiment can be obtained by engaging the slide knob 24 having an unmovable contact point and moving the knob 24 in a linear direction.

5 is a circuit diagram showing an electrical connection relationship according to the mechanical coupling relationship of the switch according to the embodiment. Referring to the drawings, a plurality of resistance elements 6 having different resistance values are connected in parallel to the blower motor 21 connected to the battery BAT, and the resistance elements 6 are connected. Each of the heat radiating elements 7 is correspondingly electrically connected. In addition, the movable contacts 17a-17c provided on the rotating plate 16 are selectively connected to the heat dissipation elements 7 while being electrically connected to the first and second terminals 8 and 9, respectively. 21 is rotated, and the blower motor 21 is rotated since the movable contacts 17a-17c are electrically shorted when they are out of the sectors of the heat radiating element 7 and the first and second terminals 8 and 9. You will not.

As described above, the present invention is limited to rotary type and slide type switches, but can be applied to other types of switches, and of course, it can be applied to all rotary devices.

As described above, the present invention integrates a PTC resistance element and a heat dissipation element integrally into a switch main body. The heat dissipation element is cooled by the heat dissipation element to prevent overheating of the resistance element generated when the motor is restrained, and at the same time, it is capable of sudden voltage change. As a result, when the internal resistance of the resistor increases rapidly, the power supply may be shorted to protect the circuit.

Claims (3)

A plurality of resistors having PTC characteristics; A plurality of terminals electrically connected to the power lines; A conductive heat dissipation element dissipating heat due to internal resistance in the same shape as that of the resistance element; An insulating case having a cylindrical shape through which a plurality of resistance insertion holes and terminal slits for inserting the resistance element and the terminal into concentric circles are formed in the thickness direction; A conductive case having the same radius of curvature as that of the case and coupled to a bottom surface thereof, the conductive case having a resistance receiving groove having the same resistance cross-section as the resistance insertion hole; And And a rotary plate integrally coupled to a movable contact for electrically connecting the heat dissipation element and the plurality of terminals fastened to the insulating case, and having a rotor extended to a predetermined length. Wherein the resistance element, the heat dissipation element, and the conductive case are electrically connected to each other by a combination of the insulating case and the conductive case. The rotary switch of claim 1, wherein a connector surrounding the plurality of terminals protruding through the terminal slit and coupled with a connector connected to a power source is integrally formed. The rotary switch of claim 1, wherein cooling fins for dissipating deterioration of the resistance element are integrally formed on a bottom surface of the conductive case.