KR102076070B1 - A mechanical relay having a plurality of contacts for energy storage system - Google Patents

Abstract

Disclosed is a relay having multiple contact points. The relay having multiple contact points comprises: a first contact point (100); and a second contact point (300) connected in parallel to the first contact point (100). The second contact point (300) is made of a flexible carbon material. Therefore, arc discharge generated at the contact point can be reduced, the first contact point can be protected by turning on / off the second contact point in accordance with a state of the first contact point, and a control time of the second contact point can be adjusted and optimized. Moreover, the first contact point can be protected by forming a current path by the arc discharge.

Description

Mechanical relay having a plurality of contacts of energy storage system (ESS) {A MECHANICAL RELAY HAVING A PLURALITY OF CONTACTS FOR ENERGY STORAGE SYSTEM}

The present invention relates to a relay for an ESS, and more particularly, to a relay having a first contact point and a second contact point.

ESS (Energy Storage System) is a storage device that stores power generated by a power plant and transmits it when power is temporarily lacked. There are batteries that collect electricity and related devices that manage them efficiently. For example, the battery type ESS uses lithium ions and sodium sulfate.

The reason why the mechanical relay having a plurality of contacts in the ESS is more useful is that in the case of the ESS, since a large current of 50 to 100 amps flows, the mechanical relay deteriorates faster during switching. The arc can be effectively suppressed, and the deterioration of the contact caused by the relay's inherent contact bouncing phenomenon can be prevented, thereby preventing the failure of the ESS and improving the service life.

The mechanical relay of the present invention may have a first contact point and a second contact point. In this case, the second contact may use a carbon material or materials using the same. By using these materials, it is possible to further increase the conductivity and to provide high durability even at the high temperature that may occur at the contact point.

In addition, in a mechanical relay composed of a plurality of contacts, when one contact is turned on / off, another contact is turned on / off at a time difference, and it may be difficult to adjust the time difference required for the on / off.

Registration No. 10-1698653, Method and apparatus for reducing relay arc Registration No. 10-1714885, Operation Monitoring Circuit for Contact Arc Reduction Devices

An object of the present invention for solving the above problems is to include a second contact connected in parallel to the first contact, the second contact is to provide a flexible relay.

In addition, the coating material of the second contact is made of carbon nanotrees to provide high electrical conductivity and high heat resistance.

In addition, the present invention provides a function for controlling the on / off of the second contact according to the state of the first contact.

In addition, to provide a relay for setting the control time of the second contact within a certain range, and adjusts the predetermined range corresponding to the next control time until there is no change in the state value detected by the sensor in the control time out of a certain range. have.

In addition, when the arc discharge is sensed to provide a relay to control the second contact to form a current path by the arc discharge.

The present invention for achieving the above object, the first contact point (100); And a second contact 300 connected in parallel to the first contact 100, and the second contact 300 is made of a flexible carbon material.

In addition, the carbon material is carbon fiber.

In addition, carbon fiber is any one or more of acryl (polyacrylonitrile, PAN) fiber, pitch fiber, and liquid crystal pitch fiber.

In addition, the relay includes a sensor 200 for detecting a state of the first contact point 100; And a second contact 300 that is turned on / off according to the state of the first contact 100 sensed by the sensor 200.

In addition, when the first contact point 100 is turned on, the second contact point 300 is turned on after a predetermined time, and when the first contact point 100 is turned off, the second contact point 300 is turned off after a certain time.

In addition, the sensor 200 includes a current sensor 210 for sensing a current of the first contact point 100; And a temperature sensor 220 for sensing a temperature of the first contact 100, and when the amount of current sensed by the current sensor 210 exceeds a predetermined level, the first contact 100 is turned off and the second contact is turned off. When 300 is turned on and the temperature value detected by the temperature sensor 220 exceeds a predetermined value, the first contact point 100 is turned off, and the second contact point 300 is turned on.

In addition, the sensor 200 detects the state of the first contact point 100 and outputs the detected state value. If the state value falls within a predetermined range, the first contact point 100 continues to be used, and the state value corresponds to the predetermined range. When the first contact point 100 is off, the second contact point 300 is controlled.

In addition, when the first contact point 100 is turned off, the control time of the second contact point 300 is set within a predetermined range, and is generated from the first contact point 100 or the second contact point 300 at a control time outside the predetermined range. The predetermined range corresponding to the next control time is adjusted until there is no change in the state value detected by the sensor 200.

The state value is at least one of a temperature value and a current value.

In addition, when the first contact point 100 is turned off, the sensor 200 detects an arc discharge, and the second contact point 300 is controlled when the arc discharge is detected by the sensor 200. Form a current path by discharge.

When using a relay having a plurality of contacts according to the present invention as described above can be reduced arc discharge generated from the contact.

In addition, the first contact may be protected by turning on / off the second contact according to the state of the first contact.

In addition, there is an advantage that can be optimized by adjusting the control time of the second contact.

In addition, the first contact may be protected by forming a current path by arc discharge.

1 is an exemplary view showing the configuration of a relay.
2 is a diagram illustrating a configuration of a relay having a sensor 200.
3 is an exemplary view showing a type of sensor 200 used in a relay.
4 is an exemplary view illustrating a relay that copes with arc discharge.
5 is an exemplary view showing a fixed contact portion 10 and a moving contact portion 30 compared to the first contact point 100 and the second contact point 300.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary view showing the configuration of a relay.

The relay is a first contact point (100); And a second contact 300 connected in parallel to the first contact 100, and the second contact 300 is made of a flexible carbon material. The relay has a hard first contact 100 and a flexible second contact 300. According to the on / off operation of the first contact point 100, the second contact point 300 turns on / off with a time difference. For example, after the hard first contact point 100 is turned off, the flexible second contact point 300 turns off. The time difference between the first contact point 100 and the second contact point 300 may reduce arc generation due to inrush current generated when the contact point is turned off.

The carbon material used for the second contact point 300 may be carbon fiber. The carbon fiber is at least one of acrylic (polyacrylonitrile, PAN) fiber, pitch fiber and liquid crystal pitch fiber. Carbon nanotubes may be used as the material constituting the carbon fiber. Carbon nanotubes have a hexagonal shape consisting of six carbons connected to each other to form a tubular shape. The diameter of the tube is only a few tens of nanometers.

In an embodiment, the material that can be used for the second contact point 300 may be a flexible material in addition to carbon fiber. According to the degree of elasticity of the flexible material used for the second contact point 300, the time difference between turning on / off the second contact point 300 after the first contact point 100 is turned on / off varies. The elasticity of the second contact 300 is set according to the design time difference required.

In another embodiment, the carbon nanotree may be used as the material used for the second contact point 300. Carbon nanotrees are carbon nanotubes grown in tree form. Carbon nano tree is a step of supplying a carbon raw material in a vacuum state on the substrate in the process chamber; Decomposing the supplied carbon raw material using microwave or RF plasma; It can be made by a manufacturing method comprising a three step of growing a carbon nano tree using a material decomposed in two steps, in the first step the substrate is a glass substrate, or includes Au, Ag, TiN, ITO and TaN The substrate is accompanied by a conductive layer including one conductive material selected from the group, and the carbon raw material may be graphene.

The carbon nanotree manufacturing method is as follows.

The first step is implemented as a process of supplying carbon to the substrate in the process chamber, and carbon nanotrees can be implemented using PECVD (Plasma Enhanced Chemical Vapor Deposition). In this case, the substrate may preferably be a silicon wafer, but may be a glass or silicon substrate, or a substrate carrying a conductive layer including any one conductive material selected from the group consisting of Au, Ag, TiN, ITO, and TaN. It can also be used.

In the carbon nanotree formation process, the one-step process is preferably implemented by forming a vacuum in the process chamber, and in this case, the working pressure may be implemented in the range of 0.1 to 50 Torr.

In addition, when supplying a carbon raw material, preferably graphene, the density of the carbon nanotree increases according to the amount of carbon flowing in the process chamber. Preferably, the amount of carbon supplied through the supplied carbon raw material is 1 Make sure to supply in the range of ~ 100sccm. Thereafter, a two-step process of decomposing the carbon raw material supplied to the process chamber using microwave or RF plasma and a three-step process of growing the carbon nanotree using the material decomposed in the second step are performed.

The two-step process of decomposing the carbon raw material using microwave or RF plasma in the process chamber can proceed the power of the microwave at an output of 200-1000W.

Synthesis of the carbon nanotree according to the present invention is a three-step process of depositing carbon nanotrees using MPECVD. Float the plasma to 500W to decompose. Carbon nanotree synthesis in the process chamber can be implemented by varying the size of the nanotree from 30 seconds to 10 minutes by microwave plasma.

2 is a diagram illustrating a configuration of a relay having a sensor 200.

The relay includes a sensor 200 for detecting a state of the first contact point 100; And a second contact 300 controlled on / off according to the state of the first contact 100 sensed by the sensor 200.

When the first contact point 100 is turned on, the second contact point 300 is turned on after a predetermined time, and when the first contact point 100 is turned off, the second contact point 300 is turned off after a certain time. A certain time is a time difference.

The relay is a first contact point (100); A sensor 200 that detects a state of the first contact point 100; And a second contact 300 controlled on / off according to the state of the first contact 100 sensed by the sensor 200.

The sensor 200 detects a state of the first contact point 100. The second contact 300 is turned on / off according to the state of the first contact 100 sensed by the sensor 200. The first contact 100 may deteriorate according to the amount of current flowing and the operating temperature. The sensor 200 detects a state of the first contact point 100. The deterioration occurs according to the amount of current and the operating temperature of the state of the first contact point 100 detected by the sensor 200, and the second contact point 300 is on / off controlled. In response to the deterioration of the first contact point 100, the second contact point 300 is controlled to protect the first contact point 100.

3 is an exemplary view showing a sensor type used in a relay.

The sensor 200 may include a current sensor 210 that senses a current of the first contact point 100; And a temperature sensor 220 for sensing a temperature of the first contact 100, and when the amount of current sensed by the current sensor 210 exceeds a predetermined level, the first contact 100 is turned off and the second contact is turned off. When 300 is turned on and the temperature value detected by the temperature sensor 220 exceeds a predetermined value, the first contact point 100 is turned off, and the second contact point 300 is turned on.

The sensor 200 may include a current sensor 210 that senses a current of the first contact point 100; And a temperature sensor 220 for sensing a temperature of the first contact 100, and when the amount of current sensed by the current sensor 210 exceeds a predetermined level, the first contact 100 is turned off and the second contact is turned off. When 300 is turned on and the temperature value detected by the temperature sensor 220 exceeds a predetermined value, the first contact point 100 is turned off, and the second contact point 300 is turned on.

The current sensor 210 and the temperature sensor 220 are used for the sensor 200, the current sensor 210 senses the current of the first contact point 100, and the temperature sensor 220 of the first contact point 100 is used. Sense the temperature. When the amount of current sensed by the current sensor 210 or the temperature value detected by the temperature sensor 220 exceeds a predetermined level or a predetermined value, the first contact 100 may be turned off and the second contact 300 may be turned on. . As the sensor 200, a current sensor 210 and a temperature sensor 220 capable of detecting a state of the first contact point 100 may be used. The second contact 300 is controlled according to the state of the first contact 100 sensed by the current sensor 210 or the temperature sensor 220.

The sensor 200 detects the state of the first contact point 100 and outputs the detected state value. When the state value is within a certain range, the first contact point 100 continues to be used. The first contact point 100 is turned off, and the second contact point 300 is controlled. The state value is at least one of a temperature value and a current value.

When the first contact point 100 is turned off, the control time of the second contact point 300 is set within a predetermined range, and is generated from the first contact point 100 or the second contact point 300 at a control time outside the predetermined range, and the sensor ( The predetermined range corresponding to the next control time is adjusted until there is no change in the state value detected by the step 200). The control time of the second contact 300 can be adjusted optimally.

The sensor 200 detects the state of the first contact point 100 and outputs the detected state value. When the state value is within a certain range, the first contact point 100 continues to be used. The first contact point 100 is turned off, and the second contact point 300 is controlled.

When the first contact point 100 is turned off, the control time of the second contact point 300 is set within a predetermined range, and is generated from the first contact point 100 or the second contact point 300 at a control time outside the predetermined range, and the sensor ( The predetermined range corresponding to the next control time is adjusted until there is no change in the state value detected by 200). The state value is at least one of a temperature value and a current value.

4 is an exemplary view illustrating a relay that copes with arc discharge.

When the first contact point 100 is turned off, the sensor 200 uses a sensor 200 that detects an arc discharge. When the arc discharge is detected by the sensor 200, the second contact point 300 is controlled to control the arc discharge. To form a current path.

The sensor 200 can be used to cope with arc discharge. When the arc discharge is detected by the sensor 200, the second contact 300 may be controlled. By controlling the second contact 300, it is possible to form a current path by arc discharge, thereby preventing the inrush current from occurring in the first contact 100. When the relay is turned on or off at which the arc discharge may occur at the first contact point 100, the second contact point 300 may be turned on to form a current path by the arc discharge. The arc discharge may be reduced by turning on the second contact 300.

5 is an exemplary view illustrating a fixed contact portion 10 and a moving contact portion 30 compared to the first contact point 100 and the second contact point 300.

In the mechanical relay, the fixed contact portion 10 is fixed, and the moving contact portion 30 moves to the fixed contact portion 10 while moving. The first contact point 100 and the second contact point 300 are formed in the fixed contact portion 10 and the moving contact portion 30. The first contact point 100 corresponds to the conventional fixed contact point 10 and the moving contact point 30, and the second contact point 300 corresponds to the present invention. The second contact point 300 may include an extension part 310 extending from the fixed contact part 10; And a contact portion 320 formed in an annular shape at the end of the extension portion 310. The contact part 320 is formed to be in contact with the moving contact part 30.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: first contact point 200: sensor
210: current sensor 220: temperature sensor
300: second contact

Claims (5)

First contact point 100; And
A second contact 300 connected in parallel to the first contact 100,
The second contact 300 is made of a flexible carbon material,
Carbon nano tree is possible as a material used for the second contact point 300,
The carbon nano tree is a carbon nanotube grown in the form of a tree, the first step of supplying a carbon raw material in a vacuum state on the substrate in the process chamber;
Decomposing the supplied carbon raw material using microwave or RF plasma; And
It can be made by a manufacturing method comprising a three step of growing carbon nanotrees using the material decomposed in the second step, in the first step the substrate is a glass substrate, or Au, Ag, TiN, ITO and TaN It is a substrate with a conductive layer comprising a conductive material selected from the group containing, the carbon raw material is graphene,
A sensor 200 for detecting a state of the first contact 100 and a second contact 300 controlled on / off according to a state of the first contact 100 detected by the sensor 200. Include,
When the first contact point 100 is turned on, the second contact point 300 is turned on after a predetermined time, and when the first contact point 100 is turned off, the second contact point 300 is turned off after a certain time point.
When the first contact point 100 is turned off, the sensor 200 detects an arc discharge, and when the arc discharge is detected by the sensor 200, the second contact point 300 is controlled to control the arc discharge. By forming a current path by, by forming a current path by the arc discharge can prevent the inrush current occurs in the first contact point 100,
The first contact point 100 is
It includes a fixed contact portion 10 and the moving contact portion 20,
The second contact 300 is
An extension part 310 extending from the fixed contact part 10; And a contact portion 320 formed in an annular shape at the end of the extension portion 310. The method of claim 1,
The carbon material is a relay having a plurality of contacts of carbon fiber. The method of claim 2,
And the carbon fiber has a plurality of contacts which are at least one of acrylic (polyacrylonitrile, PAN) fiber, pitch fiber, and liquid crystal pitch fiber. delete delete

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