The present invention relates to a bypass switch used in power electronics equipment or the like.
In recent years, renewable energy has been increasingly introduced in an electric power field, and as a measure for system stabilization, introduction or enhancement of power electronics equipment such as a STATCOM (static synchronous compensator) is performed. In the power electronics equipment, a voltage converter is needed, and in the voltage converter, a semiconductor such as an IGBT is used as a switch for current. In the converter, a bypass switch is needed for protecting a diode or preventing breakdown of the system upon failure of the IGBT. The bypass switch is to protect the diode or prevent breakdown of the system by short-circuiting and closing the bypass switch itself upon failure of the IGBT. Therefore, the bypass switch needs to operate before the diode fails. However, since the time until the diode fails is very short, it is important, as a required function of the bypass switch, that the time until closing since reception of a signal is as short as possible.
The bypass switch used in the power electronics equipment is required to allow high voltage or large current to be applied by means of short-circuit closing. Therefore, a vacuum valve may be employed for a switch main unit.
An example of conventional operation mechanism units for the vacuum valve includes: an open/close rod connected to a movable contact of the vacuum valve; an open/close block which is provided to the open/close rod, movable in the axial direction, and engaged via a predetermined play; and a disk-like open/close spring which is displaced in accordance with movement of the open/close block and has a greater turnover load to the open/close block than a vacuum-self-closing force of the vacuum valve, wherein the open/close block is moved in the axial direction by an operation lever, whereby the open/close spring acts in a contact-opening or contact-closing direction to perform contact opening or contact closing (for example, see Patent Document 1).
Patent Document 1: Japanese Examined Patent Publication No. 59-8932 (pages 1 and 2, FIGS. 1 to 4.
In the case of using, as the bypass switch, such a vacuum valve having an operation mechanism as in Patent Document 1, in the closing operation, the open/close block connected to the movable contact is directly driven by a drive mechanism, and there is a problem that it takes some time since the operation lever is pressed to the open/close block to start operation until the disk-like open/close spring turns over in the contact-closing direction and the contact is closed.
Instead of the disk-like open/close spring, a method in which an operation rod and an operation mechanism unit are linked via a link mechanism to perform a closing operation is also widely known. However, even in this case, it still takes a time of, for example, about several tens ms since start of the closing operation until completion thereof.
The present invention has been made to solve the above problems, and an object thereof is to obtain a bypass switch with the closing time shortened.
A bypass switch according to the present invention is a bypass switch using a vacuum valve having a fixed contact and a movable contact, the bypass switch including: an insulating rod having one end side connected to the movable contact; a closing spring having a closing function and a contact-pressing function, and fitted to another end side of the insulating rod; and an operation unit having a latch function to keep a contact-opened state, and connected to the other end side of the insulating rod, wherein the insulating rod, the closing spring, and the operation unit are arranged in series along an axial direction of the vacuum valve.
In the bypass switch of the present invention, the insulating rod connected to the movable contact, the closing spring having the closing function and the contact-pressing function, and the operation unit having the latch function to keep the contact-opened state are provided on the drive side of the vacuum valve composing the switch main unit, and these components are arranged in series along the axial direction of the vacuum valve. Therefore, a force of the closing spring can be smoothly transmitted to the movable contact, and the closing time taken to cancel the engagement of the latch and complete the closing can be shortened.
In addition, since the structure of the operation unit is simplified and the number of components in the movable part is reduced, the weight of the operation unit can be reduced. Further, since the assembly is facilitated, the assembly time can be shortened.
Embodiment 1
Hereinafter, the description will be given based on the drawings.
For a switch main unit of the bypass switch, a vacuum valve is used. First, the entire configuration will be described with reference to
A vacuum valve 1 has a fixed contact 2a and a movable contact 2b provided in a vacuum chamber so as to be able to contact with each other and be separated from each other. The fixed contact 2a is connected to a fixed-side conductor 4a via a fixed-side electrode rod 3a, the movable contact 2b is connected to a movable-side electrode rod 3b, and the other end of the movable-side electrode rod 3b is led out of the vacuum chamber, to be connected to an insulating rod 5. The movable-side electrode rod 3b is connected to a movable-side conductor 4b via a flexible conductor 6.
A coupling metal member 7 is connected to an end of the insulating rod 5 opposite to the side connected to the movable-side electrode rod 3b, and the coupling metal member 7 is coupled with a lever 8 via a coupling pin 9.
The fixed-side conductor 4a is fixed to a horizontal frame 10 on the upper side, the horizontal frame 10 is supported by a vertical frame 11, and a lower end side of the vertical frame 11 is fixed to a base 12. An intermediate horizontal frame 13 is provided at an intermediate part of the vertical frame 11, and a part below the intermediate horizontal frame 13 is an operation unit.
Directly under the insulating rod 5, a coil-like closing spring 14 is fitted to the insulating rod 5, and energizes the movable contact 2b in the contact-closing direction, between the insulating rod 5 and the intermediate horizontal frame 13.
The closing spring 14 drives the movable contact 2b in the closing direction, and energizes the movable contact 2b to the fixed contact 2a side in the contact-closed state.
On the base 12, a support member 15 for supporting the operation unit is fixed by a bolt. As shown in
On the back side as seen from the front side of the support member 15, one end side of the lever 8 is rotatably supported by a lever fixation pin 16. On the front side of the lever 8, a latch 17 is provided which can be engaged at an engagement part C (see
The coupling metal member 7 provided at the end of the insulating rod 5 is connected by the coupling pin 9 at an intermediate part between the lever fixation pin 16 serving as a pivot of the lever 8 and the engagement part on the front end side.
On the latch 17, a latch drive piece 18 is fixed being directed orthogonally to the axial direction of the latch 17. As shown in
A solenoid 20 of a direct-acting type is provided at a position opposed to the latch drive piece 18. The solenoid 20 is fixed on the vertical frame 11 side or the support member 15 side, although not shown. By a coil of the solenoid 20 being excited, the latch drive piece 18 is pressed and the latch 17 is turned in the clockwise direction in
As shown in
Next, operation of each part will be described. First, the closing operation of the vacuum valve 1 will be described.
In the contact-opened state as shown in
Here, when the solenoid 20 is excited in response to a contact-closing command, the latch drive piece 18 is pressed and the latch 17 is turned in the clockwise direction. By this operation, the engagement between the latch 17 and the lever 8 is cancelled, the closing spring 14 is released, and then the movable contact 2b together with the insulating rod 5 and the movable-side electrode rod 3b instantaneously moves to the fixed contact 2a side, to come into contact with the fixed contact 2a, whereby the movement is stopped, leading to the contact-closed state as shown in
Next, the contact-opening operation will be described.
Thus, the closing spring 14 provided directly under the insulating rod 5 is released by operation of the operation unit provided under the closing spring 14. Therefore, it becomes possible to perform high-speed operation after the closing operation is started, whereby the closing time can be shortened. In addition, the structure is simplified and the weight is reduced, as compared to the case of using a link or the case of using the disk-like spring as in Patent Document 1.
Since a semicircular latch is employed as the latch, the engagement with the engagement part can be cancelled by slight turning of the latch, thus contributing to increase in the speed of the closing operation.
As described above, the bypass switch of embodiment 1 is a bypass switch using a vacuum valve having a fixed contact and a movable contact, and including: an insulating rod having one end side connected to the movable contact; a closing spring having a closing function and contact-pressing function and fitted to the other end side of the insulating rod; and an operation unit having a latch function to keep a contact-opened state and connected to the other end side of the insulating rod, wherein the insulating rod, the closing spring, and the operation unit are arranged in series along the axial direction of the vacuum valve. Therefore, a force of the closing spring can be smoothly transmitted to the movable contact, and the closing time taken to cancel the engagement of the latch and complete the closing can be shortened.
In addition, since the structure of the operation unit is simplified and the number of components in the movable part is reduced, the weight of the operation unit can be reduced. Further, since the assembly is facilitated, the assembly time can be shortened.
The operation unit includes: a lever having one end side rotatably supported by a support member, the other end side at which an engagement part is formed, and an intermediate part coupled with the other end side of the insulating rod; a latch that can be engaged with an engagement part of the lever; and a solenoid for driving the latch, wherein the contact-opened state is kept by the latch being engaged with the engagement part of the lever, and the closing spring is released to perform contact closing by the engagement being cancelled by excitation of the solenoid. Therefore, it becomes possible to keep the contact-opened state and perform quick contact-closing operation, with a simple configuration.
Embodiment 2
As shown in
The shape of the latch 17 and the shape of the latch drive piece 18 fixed thereto are the same as in embodiment 1. The latch 17 is located at such a position that, depending on the turn position thereof, allows the latch 17 to be engaged with the engagement part of the coupling metal member 7, and is rotatably attached to the support member 15. The solenoid 20 for pressing the latch drive piece 18 is fixed on the support member 15 side.
By such a configuration, since the latch 17 is directly engaged with the coupling metal member 7, as compared to embodiment 1, the lever 8 is removed and downsizing and weight reduction of the movable part can be achieved, and further, the closing time can be shortened.
In
As described above, in the bypass switch of embodiment 2, the operation unit includes: a latch that can be engaged with an engagement part of the coupling metal member coupled with the other end side of the insulating rod; and a solenoid for driving the latch, wherein the contact-opened state is kept by the latch being engaged with the engagement part of the coupling metal member, and the closing spring is released to perform contact closing by the engagement being cancelled by excitation of the solenoid. Therefore, the structure of the operation unit is simplified, and downsizing and weight reduction of the movable part can be achieved.
It is noted that, within the scope of the present invention, the above embodiments may be freely combined with each other, or each of the above embodiments may be modified or abbreviated as appropriate.
1 vacuum valve
2
a fixed contact
2
b movable contact
3
a fixed-side electrode rod
3
b movable-side electrode rod
4
a fixed-side conductor
4
b movable-side conductor
5 insulating rod
6 flexible conductor
7 coupling metal member
8 lever
9 coupling pin
9
a protrusion
10 horizontal frame
11 vertical frame
12 base
13 intermediate horizontal frame
14 closing spring
15 support member
16 lever fixation pin
16
a protrusion
17 latch
18 latch drive piece
19 return spring
20 solenoid
21 operation handle
Number | Date | Country | Kind |
---|---|---|---|
2013-268297 | Dec 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2014/060940 | 4/17/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/098142 | 7/2/2015 | WO | A |
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Entry |
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International Search Report (PCT/ISA/210) issued on Jul. 8, 2014, by the Japanese Patent Office as the International Searching Authority for International Application No. PCT/JP2014/060940. |
Decision to Grant a Patent issued in the corresponding Japanese Application No. 2015-503599 on Jul. 3, 2015, pp. 1-3 (with English language translation, 3 pages). |
Notification of Reasons for Refusal issued in the corresponding Japanese Application No. 2015-503599 on Apr. 14, 2015, pp. 1-3 (with English language translation, 3 pages). |
Extended European Search Report dated Aug. 4, 2016, issued by the European Patent Office in corresponding European Application No. 14873245.6. (10 pages). |
Number | Date | Country | |
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20160211088 A1 | Jul 2016 | US |