JPH09147709A - Switch device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch device capable of surely opening a circuit at the time of an overcurrent at a low cost without being enlarged in size. SOLUTION: A spring 15 is provided at the portion adjacent to a moving contact point 10 on the back side of the curved surface of the moving piece 7 of a switch device 1, the periphery of the spring 15 is surrounded by a heat fusing member 16 such as a thermoplastic resin, and the spring 15 is kept at the compression-fixed state to the moving piece 7. The heat melting member 16 is fused when it is heated by an overcurrent, the compression-held spring 15 is extended, and the moving piece 7 is pushed up to open a circuit.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switch device, and more particularly to a switch device configured to open a circuit when heat is generated due to overcurrent.

[0002]

2. Description of the Related Art Heretofore, the following measures have been known as measures against smoke, ignition, breakdown of peripheral equipment, etc. due to overcurrent in a switch device. (1) Incorporate a fuse or an overcurrent protection element in the circuit, and open the circuit when an overcurrent flows. (2) When an overcurrent flows, the movable piece supporting portion resin (plunger) is melted and the movable piece is lifted to open the circuit. FIG. 7 shows a schematic configuration of the switch device in the case of (2).
In the switch device 50, in the initial state, the movable piece 51 having the shape shown in FIG. 7 and the contact a are open (switch off state). From this state, when the knob 52 is rotated about the rotary shaft 53, the plunger 54 pushes the movable piece 51, the movable piece 51 contacts the contact point a, and the circuit is closed as shown in the drawing. In this configuration, when an overcurrent flows, the plunger 54 melts and cannot press the movable piece 51, the movable piece 51 moves by its own weight, and the circuit returns to the initial state to open the circuit. (3) In a switch device having a configuration in which the movable piece in the switch-off position in the initial state is switched on by pushing it down with an actuator, when an overcurrent flows, the actuator melts and pushes down the movable piece. Then, the movable piece itself is returned to the initial state by the spring force of the movable piece itself to be switched off (see Japanese Patent Laid-Open No. 7-65681).

[0003]

However, the above-mentioned conventional measures against overcurrent have the following problems. In the case of the above (1), since the fuse member is required, the cost of the switch device becomes high, and the space for incorporating the fuse member in the circuit is required, so that the switch device becomes large. In the case of (2) above,
Since the plunger and the movable piece are in line contact with each other, heat conduction from the movable piece to the plunger is poor and melting of the plunger becomes unstable, so that the switch cannot be reliably turned off. Further, when the plunger is melted, the circuit is opened by the movement of the movable piece by its own weight, so that the circuit opening force is weak and the reliability is low. Furthermore, its mounting direction is limited. Even in the case of (3) above, due to poor heat conduction due to line contact between the actuator and the movable piece,
In some cases, the problem of instability of the melting of the plunger cannot be solved, and the switch cannot be reliably turned off. The present invention has been made in order to solve the above-mentioned problems, and it is possible to surely open the circuit and switch it off when an overcurrent occurs without increasing the cost and size of the switch device. An object of the present invention is to provide a switch device that can be used.

[0004]

In order to achieve the above object, a switch device according to a first aspect of the present invention is a switch device in which an actuator pushes a movable piece which is in a switch-off position in an initial state. A switch device that is turned on, in which the movable member is provided with a spring member that is compressed and held by a heat melting member that is melted by the heat generated when an overcurrent flows through the movable member, and the compressed spring member is The movable piece is moved by the force of expansion caused by the melting of the melting member, the movable piece is returned to the initial state, and the switch is turned off.

In the above structure, the heat-melting member is melted by the heat generated by the overcurrent, the compressed and held spring member expands, and this spring force forcibly pushes up the movable piece to open the circuit. The reliability that the switch can be reliably turned off at the time of heat generation due to current is significantly improved. Further, since the contact area between the movable piece and the heat melting member is wide, the melting of the heat melting member is stable. Also,
Since the melting temperature can be changed by changing the material of the heat melting member, various current values can be dealt with. Further, since the above-described configuration can be collectively provided on the movable piece, the space of the switch device can be saved, and an external device such as a fuse is not required.

A switch device according to a second aspect of the present invention is the switch device according to the first aspect, wherein the movable piece is made of a material having rigidity, and a part of the movable piece is the spring member. Used as.

In the above structure, since a part of the movable piece made of a rigid material is used as the spring member, the spring member is not required, so that the cost can be reduced and the structure of the switch device can be simplified. be able to.

The switch device according to a third aspect of the present invention is the switch device according to the first aspect, wherein the movable piece slides on the fixed-side contact to turn on / off the switch. It is the one that is switched off.

In the above structure, the heat-melting member is melted by the heat generated by the overcurrent, so that the spring member compressed and held by the heat-melting member extends, and the spring force forcibly moves the movable piece to switch the switch. Since it is turned off, the reliability is significantly improved. Furthermore, since the contact area between the movable piece and the heat melting member is large, the melting is stable. Also,
Since the melting temperature changes by changing the material of the heat melting member, it is possible to deal with various current values. Since the above configuration can be collectively provided on the movable piece, the space of the switch device can be saved, and an external device such as a fuse is not required.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION A switch device according to an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic cross-sectional view showing the initial state (switch-off state) of the switch device, and FIG. 2 is a diagram showing the main configuration of the switch device in the switch-on state. The switch device 1 includes an operation knob 2 that is rotationally operated, a case 3 that incorporates a switch section that is operated by the operation knob 2, a fixed contact a,
b, c (respectively connected to power supply, load, GND)
And a base 6 provided with. The operation knob 2 includes a plunger (pressing member) 8 that abuts on the movable piece 7,
A spring 9 for urging the plunger 8 is provided. The plunger 8, the spring 9, and the operation knob 2 function as an actuator. The switch portion has a movable piece 7 made of a rigid material and provided with movable contacts 10 and 11. The movable piece 7 is set so as to always contact the fixed contact c. A spring 15 is provided on the back side of the curved surface 7 a of the movable piece 7 and adjacent to the movable contact 10. The spring 15 is surrounded on all sides by a heat melting member 16 such as a thermoplastic resin, and is kept in a state of being compressed and fixed to the movable piece 7.

Further, the fixed contact b is connected to GND, and in the movable piece 7, the movable contact 11 and the fixed contact b are connected in the initial state (when the switch is in a neutral state) so that the movable piece 7 is switched off. It is set. And the movable piece 7
Is set to connect the movable contact 10 and the fixed contact a by a switch operation. That is, when the operation knob 2 is rotated clockwise in the drawing by a switch operation, the plunger 8 presses the curved surface 7a of the movable piece 7 to rotate the movable piece 7 around its axis. As a result, the movable contact 10 and the fixed contact a are connected, and the movable contact 1
1 and the fixed contact b are disconnected, and the switch device 1 is switched on. Although not shown in the drawing, the switch is operated by rotating the operation knob 2 in the counterclockwise direction.
There is provided another set of movable pieces that are turned on and a fixed contact that faces the movable contacts of the movable pieces. With these two sets of switch mechanisms, the direction of electricity to the load can be switched between forward and reverse. It is like this.

Next, the operation of the spring 15 and the heat melting member 16 when an overcurrent flows through the movable piece 7 will be described. FIG. 3 is a diagram showing a main configuration of the switch device in a state where the heat melting member 16 is melted and the movable piece 7 is pushed up by the spring 15. When the movable contact 10 and the fixed contact a are connected and are in the switch-on state, if an overcurrent continues to flow in the movable piece 7 due to an abnormal situation of the load,
Although the movable piece 7 has a temperature high enough to cause ignition or the like, the heat melting member 16 is made of a material that melts when the movable piece 7 reaches such a high temperature. Therefore, when an overcurrent flows and the movable piece 7 rises to a certain temperature, the heat-melting member 16 begins to melt, and along with this, the force for compressing and fixing the spring 15 to the movable piece 7 becomes weaker. Then, when the melting of the heat melting member 16 progresses and the heat melting member 16 cannot compress and fix the spring 15 to the movable piece 7, the spring 16 is opened and extends.

As described above, the spring 15 is extended and opened.
Reaches the base 6 and pushes up the movable piece 7. This spring 1
By pushing up the movable piece 7 of 5, the movable contact 10 and the fixed contact a, which have been connected until then, are brought into a non-connection state, and the circuit of the switch device 1 is opened. Therefore, when an overcurrent flows and the movable piece 7 reaches a high temperature, the spring 15 is released from the heat melting member 16 and extends, and the movable piece 7 is pushed up, whereby the switch device 1 is forcibly switched.
It is turned off and no current flows in the circuit.

Next, an embodiment applied to the slide contact type switch device of the present invention will be described. FIG. 4 is a diagram showing a configuration of a main part of the switch device in a switch-on state, and FIG. 5 shows a configuration of a main part of the switch device in a state in which a heat melting member is melted and a movable piece is pushed up by a spring. It is a figure. The switch device 20 has fixed contacts a, b, and c.
And a movable piece 22 which slides on the base 21 and is connected to the fixed contacts a, b, c. At the end of the movable piece 22 on the fixed contact a side,
A spring 23 is provided. The spring 23 is surrounded by heat-melting members 24 on all sides, and is held in a state of being compressed and fixed to the movable piece 22. The spring 2 is provided above the movable piece 22.
An operation knob 26 is provided via 5.

In the initial state of the switch device 20,
The movable piece 22 is at a position where the fixed contact c and the fixed contact b are connected (not shown). Since the fixed contact b is connected to GND, it is switched off in this state. The movable piece 22 slides on the base 6 when the operation knob 26 is operated, and connects the fixed contact c and the fixed contact a. At this time, the switch device 1 is switched on, and the fixed contact c and the fixed contact b are disconnected.

Next, the operation of the spring 23 and the heat melting member 24 when an overcurrent flows through the movable piece 22 will be described. When the fixed contact c and the fixed contact a are connected to each other and are in a switch-on state, if an overcurrent continues to flow in the movable piece 22 due to an abnormal situation of a load or the like, the movable piece 22 is heated to such a high temperature. Becomes Here, the heat melting member 24 is made of a material that melts when the movable piece 22 reaches such a high temperature as in the switch device 1. Therefore, when an overcurrent flows and the temperature of the movable piece 22 rises to a certain temperature, the heat melting member 24 melts and the force for compressing and fixing the spring 23 to the movable piece 7 becomes weak, and the heat melting member 24 springs. When 23 cannot be compressed and fixed to the movable piece 22, the spring 23 is released and extends. The released and extended spring 23 reaches the base 21 and pushes up the movable piece 22. By pushing up the spring 23, the fixed contact c and the fixed contact a that have been connected are brought into a non-connection state, and the circuit of the switch device 20 is opened. Therefore, the switch device 20 is forcibly switched off and no current flows in the circuit.

The spring 15 in the switch device 1, the heat-melting member 16, and the spring 2 in the switch device 20.
3, a specific configuration example of the heat melting member 24 will be described. 6 (a), (b), (c), and (d) are diagrams showing a specific configuration example of the main parts of the spring and the heat melting member. FIG. 6A shows the spring 15 shown in the description of the switch devices 1 and 20.
23 (hereinafter, referred to as spring 15) and heat melting member 16,
24 (hereinafter referred to as the heat melting member 16 and the like).
The movable piece 7 or 22 (hereinafter referred to as the movable piece 7 etc.) is provided with a spring 15 or the like, which is a spring spring.
This is a configuration in which all four sides such as 5 are covered with the heat melting member 16 and the like. In contrast to this structure, FIG. 6B shows a structure in which the heat-melting member 16 and the like are arranged only in the upper and lower portions, which are the locations required to compress and hold the spring 15 and the like. FIG.
(C) is a configuration in which a leaf spring is used as the spring 15 and the like without using a spring spring. In the case of using the leaf spring, the heat melting member 16 and the like can be compressed and fixed only by providing it on a part of the leaf spring. FIG. 6D shows a configuration in which a part of the movable piece 7 or the like is used as the spring 15 or the like. As described above, since the movable piece 7 and the like are made of a rigid material, the same action as when the spring 15 and the like is formed of a leaf spring can be obtained. Also in the case of this configuration, the heat melting member 1
The spring 15 and the like can be compressed and fixed by simply providing 6 and the like on a part of the spring 15 and the like.

As described above, the switch device 1 of this embodiment is
According to No. 20, when the movable piece 7 or the like is heated to a high temperature due to overcurrent, the contact area between the movable piece 7 or the like and the heat-melting member 16 or the like is large, so that the heat-melting member 16 or the like is melted. Stabilize. Therefore, when the movable piece 7 or the like has a high temperature, the compression-fixed spring 15 or the like is reliably opened. Since the movable piece 7 and the like are pushed up by the spring force of the released spring 15 and the like to open the circuit forcibly, the open failure can be surely caused when the heat is generated due to the overcurrent. Greatly improved. Further, since the melting temperature can be changed by changing the material of the heat melting member 16 or the like, it is possible to deal with various current values. Further, since the above-described configuration can be collectively provided in the movable piece 7 or the like, space saving of the switch devices 1 and 20 can be achieved, and an external device such as a fuse is not required, resulting in cost reduction. Can be achieved.

The present invention is not limited to the configuration of the above embodiment, and various modifications are possible. For example, in the above-described embodiment, the switch device 1 of the type in which the contacts face each other are opened and closed, and the switch device 20 of the slide contact type are described, but the present invention is not limited to these two types of switch devices. Other types of switch devices may be used.

[0020]

As described above, according to the switch device of the first or third aspect of the present invention, the heat-melting member melts at the time of heat generation due to overcurrent, and the spring member that has been compression-held up to that time. The elastic member is stretched, and the movable piece is pushed up by this spring force to open the circuit and switch it off. Therefore, the reliability of opening the circuit is increased. Also,
Since the contact area between the movable piece and the heat melting member is wide, the melting of the heat melting member is stable. Therefore, at the time of heat generation due to overcurrent, the spring is released from the state in which it is reliably compressed and fixed. Furthermore, since the melting temperature can be changed by changing the material of the heat melting member, it is possible to deal with various current values. Since this structure can be collectively provided on the movable piece, the space of the switch device can be saved and an external device such as a fuse is not required, so that the cost of the device can be reduced.

Further, according to the switch device of the second aspect of the present invention, since a part of the movable piece made of a material having rigidity is used as the spring member, the spring member is not required, and the cost is reduced. It is possible to simplify the structure of the device.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional view showing an initial state of a switch device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a main configuration of a switch device in a switch-on state.

FIG. 3 is a diagram showing a main configuration of a switch device in a state where a circuit is opened when heat is generated due to an overcurrent.

FIG. 4 is a diagram showing a configuration of a main part of a switch device in a switch-on state according to another embodiment of the present invention.

FIG. 5 is a diagram showing a main configuration of a switch device in a state where a circuit is opened when heat is generated due to an overcurrent.

6 (a), (b), (c), and (d) are diagrams showing a specific configuration example of main parts of a spring and a heat melting member.

FIG. 7 is a diagram showing a schematic configuration of a conventional switch device in which a circuit is opened when heat is generated due to an overcurrent.

[Explanation of symbols]

 1,20 Switch device 2 Operation knob 7,20 Movable piece 8 Plunger 9,25 Spring 10,11 Movable contact 15,23 Spring 16,24 Thermal melting member 26 Operation knob

Claims (3)

[Claims] 1. A switch device in which an actuator pushes a movable piece in a switch-off position in an initial state so that the movable piece is switched on and is melted by heat generated by an overcurrent flowing through the movable piece. A spring member compressed and held by the heat melting member is provided on the movable piece, and the compressed spring member moves the movable piece by a force extending by melting of the heat melting member to return the movable piece to an initial state. A switch device characterized by being switched off. 2. The switch device according to claim 1, wherein the movable piece is made of a material having rigidity, and a part of the movable piece is used as the spring member. 3. The switch device according to claim 1, wherein the movable piece slides with respect to the fixed side contact to switch the switch on and off.