The present invention relates to a switch.
There exists a seesaw switch for controlling on and off of, for example, a power source. A surface of a portion of a seesaw switch to be pressed has a wave shape. ON-OFF control can be performed by pressing one or the other end of the pressed part having a wave-shaped surface.
Such a seesaw switch is easy to operate and is therefore often used as a power switch.
[Patent Document 1] Japanese Laid-Open Patent Publication No. 2001-307597
Although a 100 V alternating-current power source is currently used as a commercial power source in Japan, there is a demand for a high-voltage direct-current power source to achieve energy saving and high efficiency. However, when currently-available switches designed for the 100 V alternating-current power source are used for a high-voltage direct-current power source, those switches may be broken or damaged. Specifically, if such a switch is used for a high-voltage direct-current power source, an arc tends to be generated when the switch is turned on and off, particularly when turned off, and the switch itself may be damaged by the heat of the generated arc. When a switch is damaged by heat, the damaged switch becomes either open-circuited or short-circuited. Particularly, when a switch is short-circuited, an electric current continues to flow and cannot be cut off. This may also influence parts other than the switch and worsen the problem.
For the above reasons, there is a demand for a seesaw switch that can be operated in a manner similar to a currently-available power switch and supports a direct current or a high voltage.
In an aspect of the embodiments of the present invention, there is provided a switch that includes a fixed contact part including a fixed contact, a movable contact part including a movable contact, a control button that includes an engaging part and supports the movable contact part, an operation part including a first end and a second end, and a lock including a first protrusion and a second protrusion.
The switch is configured such that when the first end is pressed, the control button is pressed, the movable contact touches the fixed contact, and the switch becomes an ON state; and when the second end is pressed, the movable contact moves away from the fixed contact, and the switch becomes an OFF state. While the movable contact and the fixed contact are in contact with each other, the first protrusion of the lock touches the engaging part of the control button to maintain the ON state. When the second end is pressed, the operation part touches the second protrusion of the lock and moves the lock in such a direction that the first protrusion moves away from the engaging part, and the switch becomes the OFF state.
The present invention makes it possible to provide a seesaw switch that supports a direct current or a high voltage.
Embodiments of the present invention are described below. The same reference number is assigned to the same component throughout the accompanying drawings, and repeated descriptions of the same component are omitted.
Configurations of a switch for a high-voltage direct-current power source are described below. When a switch is turned on and off while a high voltage, for example, a high voltage direct current, is being applied between contacts of the switch, an arc is generated between the contacts and an arc current flows even if the contacts are not in contact with each other. When an arc is generated, the contacts are heated by the generated arc and the switch may be broken or damaged. For this reason, there is a demand for a switch having a configuration for preventing generation of an arc or a switch that, even when an arc is generated, can extinguish the arc in a shortest possible period of time.
A switch according to a first embodiment is described with reference to
When a first end 10a or a second end 10b of the wave-shaped operation part 10 is pressed, the switch is turned on or off. More specifically, when the first end 10a of the operation part 10 is pressed by, for example, a finger while the switch is in an OFF state, the switch changes to an ON state, the power cable 31 is electrically connected to the power cable 32, and power is supplied from the power cable 31 to the power cable 32. In this case, the second end 10b of the operation part 10 rises. On the other hand, when the second end 10b of the operation part 10 is pressed by, for example, a finger while the switch is in the ON state, the switch changes to the OFF state, the electrical connection between the power cable 31 and the power cable 32 is broken, and the supply of power from the power cable 31 to the power cable 32 is stopped. In this case, the first end 10a of the operation part 10 rises.
Because the switch is configured such that the second end 10b of the operation part 10 rises when the first end 10a is pressed and the first end 10a rises when the risen second end 10b is pressed, the switch is called a seesaw switch.
<Internal Structure>
Next, an internal structure of the switch of the present embodiment is described with reference to
The switch of the present embodiment includes two switching mechanisms each of which includes one movable contact part 12 and one fixed contact part 13. More specifically, a first movable contact part 12 and a first fixed contact part 13 constitute a first switching mechanism, and a second movable contact part 12 and a second fixed contact part 13 constitute a second switching mechanism. A movable contact 12a is provided at an end of each movable contact part 12, and a fixed contact 13a is provided at an end of each fixed contact part 13. In the switch of the present embodiment, the movable contact part 12 and the fixed contact part 13, except for the movable contact 12a and the fixed contact 13a, are comprised of a conductive metal material such as a copper (Cu) plate, and the movable contact part 12 has elasticity. The movable contact 12a and the fixed contact 13a are comprised of, for example, silver (Ag) or a material including a metal such as silver. Also in the present embodiment, components including the movable contact parts 12 and the fixed contact parts 13 are disposed at predetermined positions on a substrate 40.
The switch of the present embodiment becomes the ON state when the movable contact 12a of the movable contact part 12 contacts with the fixed contact 13a of the fixed contact part 13, and becomes the OFF state when the movable contact 12a moves away from the fixed contact 13a.
As described above, the power cables 31 and 32 are connected to the switch of the present embodiment. The power cable 31 includes a positive (+) electric wire 31a, a negative (−) electric wire 31b, and a ground potential (GND) electric wire 31c. The power cable 32 includes a positive (+) electric wire 32a, a negative (−) electric wire 32b, and a ground potential (GND) electric wire 32c.
The positive (+) electric wire 31a of the power cable 31 is connected to a first one of the two movable contact parts 12, and the negative (−) electric wire 31b is connected to a second one of the two movable contact parts 12. The positive (+) electric wire 32a of the power cable 32 is connected to a first one of the two fixed contact parts 13, and the negative (−) electric wire 32b is connected to a second one of the two fixed contact parts 13. The ground potential (GND) electric wire 31c of the power cable 31 and the ground potential (GND) electric wire 32c of the power cable 32 are connected to each other in the switch.
<On-Off Operations>
Next, ON-OFF operations of the switch of the present embodiment are described.
First, the ON state is described. The switch of the present embodiment includes a control button 11 below the operation part 10. When the first end 10a of the operation part 10 is pressed, the operation part 10 rotates around an operation part rotating shaft 10c and presses the control button 11, and the control button 11 rotates around a control button rotating shaft 11a. A movable contact support 11b of the control button 11 supports a portion of the movable contact part 12. When the control button 11 rotates around the control button rotating shaft 11a, the movable contact part 12 supported by the movable contact support 11b moves toward the fixed contact part 13, the movable contact 12a of the movable contact part 12 contacts with the fixed contact 13a of the fixed contact part 13 as illustrated by
The ON state of the switch of the present embodiment is described in more detail with reference to
The switch of the present embodiment becomes the ON state when the first end 10a of the operation part 10 is pressed while the switch is in the OFF state, and the ON state is maintained by a force of an operation part spring 14. In
Next, a state of the switch between the ON state and the OFF state is described with reference to
In the present embodiment, when the second end 10b of the operation part 10 is pressed while the switch is in the ON state illustrated by
Next, the OFF state is described with reference to
The switch of the present embodiment becomes the OFF state when the second end 10b of the operation part 10 is pressed further from the position illustrated in
When the second end 10b of the operation part 10 is pressed further from the position in the transient state illustrated by
Because the switch of the present embodiment can be changed from the ON state to the OFF state in a very short period of time by the restoring force of the return spring 17, no arc is generated between the movable contact 12a and the fixed contact 13a, or an arc is generated only for a very short period of time. Accordingly, the switch is not damaged due to, for example, the melting of the movable contact part 12.
<Arc Extinguishing Function>
The switch of the present embodiment includes a function for instantly extinguishing an arc generated between the movable contact 12a and the fixed contact 13a. As illustrated by
Next, a second embodiment is described. In a switch of the present embodiment, as illustrated by
In the first embodiment, the transient state illustrated by
In the switch of the present embodiment, the raised part 120 is provided on the case 20 on each side of the operation part 10 to prevent an operation with a finger from being stopped around the time when the movable contact 12a moves away from the fixed contact 13a. This configuration makes it possible to more reliably turn on or off the operation part 10 in a short period of time and prevent the switch from being damaged.
Also in the switch of the present embodiment, operation protrusions 110a and 110b are provided near the first end 10a and the second end 10b of the operation part 10. The operation protrusions 110a and 110b prevent a finger operating the operation part 10 from slipping on the surface of the operation part 10, and make it possible to more effectively prevent an operation with a finger from being stopped around the time when the movable contact 12a moves away from the fixed contact 13a. Other configurations of the second embodiment not described above are substantially the same as those of the first embodiment.
Next, a switch according to a third embodiment is described with reference to
When a first end 210a or a second end 210b of the operation part 210 is pressed, the switch is turned on or off. When the first end 210a of the operation part 210 is pressed while the switch is in the OFF state, the switch changes to the ON state, the power cable 231 is electrically connected to the power cable 232, and power is supplied. In this case, the second end 210b of the operation part 210 rises. On the other hand, when the second end 210b of the operation part 210 is pressed while the switch is in the ON state, the switch changes to the OFF state, the electrical connection between the power cable 231 and the power cable 232 is broken, and the supply of power is stopped. In this case, the first end 210a of the operation part 210 rises.
In the switch of the present embodiment, similarly to the switch of
Also in the switch of the present embodiment, operation protrusions 310a and 310b are provided near the first end 210a and the second end 210b of the operation part 210. The operation protrusions 310a and 310b make it possible to prevent a finger from slipping on the surface of the operation part 210 and prevent occurrence of chattering.
<Internal Structure>
Next, an internal structure of the switch of the present embodiment is described with reference to
The case 220 includes an upper plate 221 and a lower case 222. The switch includes, in the case 220, an inner plate 261, an operation part inner cover 262 having an opening at a position where the operation part 210 is placed, an inner box 263, a control button 211 that transmits an operation on the operation part 210 to movable contact parts 212, an operation part spring 218 that maintains the operation part 210 in the ON state or the OFF state, return springs 217a and 217b that raise the control button 211 in the OFF state, an operation part spring support 264 that supports a lower part of the operation part spring 218, a lock 215 and a lock spring 216 for maintaining the ON state, and a permanent magnet 250.
The switch of the present embodiment includes two switching mechanisms each of which includes one movable contact part 212 and two fixed contact parts 213 and 214. More specifically, a first movable contact part 212, a first fixed contact part 213, and a first fixed contact part 214 constitute a first switching mechanism, and a second movable contact part 212, a second fixed contact part 213, and a second fixed contact part 214 constitute a second switching mechanism.
Each movable contact part 212 includes two movable contacts 212a and 212b. Each fixed contact part 213 includes one fixed contact 213a, and each fixed contact part 214 includes one fixed contact 214a. In the switch illustrated by
The switch of the present embodiment becomes the ON state when the movable contact 212a of the movable contact part 212 contacts the fixed contact 213a of the fixed contact part 213 and the movable contact 212b contacts the fixed contact 214a of the fixed contact part 214, and becomes the OFF state when the contacts are separated from each other. In the present embodiment, the movable contact part 212 needs not have elasticity and therefore can be formed to have a large thickness. That is, the movable contact part 212 can be formed to have a low resistance and a high heat capacity. Therefore, even when a high voltage power is supplied and an arc is generated, the movable contact part 212 is not deformed or melted by heat of the arc.
As described above, the power cables 231 and 232 are connected to the switch of the present embodiment. The power cable 231 includes a positive (+) electric wire 231a, a negative (−) electric wire 231b, and a ground potential (GND) electric wire 231c. The power cable 232 includes a positive (+) electric wire 232a, a negative (−) electric wire 232b, and a ground potential (GND) electric wire 232c.
The positive (+) electric wire 231a of the power cable 231 is connected to a first one of the two fixed contact parts 213, and the negative (−) electric wire 231b is connected to a second one of the two fixed contact parts 213. The positive (+) electric wire 232a of the power cable 232 is connected to a first one of the two fixed contact parts 214, and the negative (−) electric wire 232b is connected to a second one of the two fixed contact parts 214. The ground potential (GND) electric wire 231c of the power cable 231 and the ground potential (GND) electric wire 232c of the power cable 232 are connected to each other via a connecting part 234 comprised of, for example, a metal material.
Also in the switch of the present embodiment, to support a high voltage direct current, a wire whose conductor has a cross-sectional area of 3.5 mm2 is used for each of the positive (+) electric wire 231a and the negative (−) electric wire 231b of the power cable 231 and the positive (+) electric wire 232a and the negative (−) electric wire 232b of the power cable 232. For this reason, to make the movable contact part 212 have a conductance greater than or equal to the conductance of the positive (+) electric wire 231a, etc. of the power cable 231, the cross-sectional area of the movable contact part 212 in a direction perpendicular to a current flow direction is preferably greater than or equal to the cross-sectional area of the conductor of the positive (+) electric wire 231a, etc. of the power cable 231, i.e., 3.5 mm2. When the width of a cross section of the movable contact part 212 perpendicular to the current flow direction is 7 mm, the thickness of the movable contact part 212 is preferably greater than or equal to 0.5 mm. In the switch of the present embodiment, the cross section of the movable contact part 212 which is perpendicular to the current flow direction has a width of 7 mm and a thickness of 1 mm.
<On-Off Operations>
Next, ON-OFF operations of the switch of the present embodiment are described.
First, the ON state is described.
In the switch of the present embodiment, the control button 211 is provided below the operation part 210 and is movable in the vertical direction in the figures. When the first end 210a of the operation part 210 is pressed, the operation part 210 rotates around an operation part rotating shaft and presses the control button 211. As a result, the control button 211 moves downward. In other words, when the first end 210a of the operation part 210 is pressed while the switch is in the OFF state as illustrated by
The control button 211 supports the movable contact part 212. When the first end 210a of the operation part 210 is pressed while the switch is in the state illustrated by
In the ON state, the positive (+) electric wire 231a of the power cable 231 and the positive (+) electric wire 232a of the power cable 232 are electrically connected to each other, the negative (−) electric wire 231b of the power cable 231 and the negative (−) electric wire 232b of the power cable 232 are electrically connected to each other, and power is supplied from the power cable 231 to the power cable 232.
The ON state of the switch of the present embodiment is described in more detail with reference to
The switch of the present embodiment becomes the ON state illustrated by
When the first end 210a is pressed, a lock contact part 215a of the lock 215 and a side contact part 210e of the operation part 210 illustrated in
Next, a state of the switch between the ON state and the OFF state is described with reference to
In the present embodiment, when the second end 210b of the operation part 210 is pressed while the switch is in the ON state illustrated by
Next, the OFF state is described with reference to
The switch of the present embodiment becomes the OFF state when the second end 210b of the operation part 210 is pressed further from the position illustrated in
When the second end 210b of the operation part 210 is pressed further from the position in the transient state illustrated by
Because the switch of the present embodiment can be changed from the ON state to the OFF state in a very short period of time by the restoring forces of the return springs 217a and 217b, no arc is generated between the movable contact 212a and the fixed contact 213a and between the movable contact 212b and the fixed contact 214a, or an arc is generated only for a very short period of time. Accordingly, the switch is not damaged due to, for example, the melting of the movable contact part 212.
<Arc Extinguishing Function>
The switch of the present embodiment includes a function for instantly extinguishing arcs generated between the movable contact 212a and the fixed contact 213a and between the movable contact 212b and the fixed contact 214a.
The switch of the present embodiment includes the permanent magnet 250 below the movable contact part 212 and between the fixed contact part 213 and the fixed contact part 214. Arcs generated between the movable contact 212a and the fixed contact 213a and between the movable contact 212b and the fixed contact 214a are instantly extinguished by a magnetic field generated by the permanent magnet 250. In the switch of the present embodiment, the permanent magnet 250 is disposed below the movable contact part 212 and between the fixed contact part 213 and the fixed contact part 214 so that a magnetic field is efficiently applied between the movable contact 212a and the fixed contact 213a and between the movable contact 212b and the fixed contact 214a.
Preferred embodiments of the present invention are described above. However, the present invention is not limited to the specifically disclosed embodiments, and variations and modifications may be made without departing from the scope of the present invention.
The present application is based on and claims the benefit of priority of Japanese Patent Application No. 2012-222552 filed on Oct. 4, 2012, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | Kind |
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2012-222552 | Oct 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/076734 | 10/1/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/054654 | 4/10/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4167720 | Krasser | Sep 1979 | A |
5543595 | Mader | Aug 1996 | A |
6225881 | Felden | May 2001 | B1 |
6559398 | Takeda et al. | May 2003 | B2 |
Number | Date | Country |
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S53-139185 | Dec 1978 | JP |
S56-081453 | Jul 1981 | JP |
H01-060430 | Apr 1989 | JP |
2001-307597 | Nov 2001 | JP |
Entry |
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International Search Report mailed on Dec. 10, 2013. |
Number | Date | Country | |
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20150287558 A1 | Oct 2015 | US |