JP2019505085A - Improved wiring structure for contact system of rotary double break switch - Google Patents

Abstract

The improved wiring structure of the rotary double break switch contact system comprises a movable contact (1), a fixed contact (2) and a short-circuit bus bar (3). An electrical connection between the movable contact (1) and the stationary contact (2) can be achieved during rotation. The stationary contact (2) is connected to the short-circuit bus bar (3) by using a terminal screw (4). The terminal screw (4) allows the wire to enter along the circumferential direction. The present invention improves the wiring method so that the wiring direction of the contact system of the rotary double break disconnect switch can be flexibly changed so as to meet the requirements in the field installation of the disconnect switch. [Selection] Figure 1

Description

BACKGROUND The present invention relates to the field of disconnector technology, and more particularly to an improved wiring structure for a rotary double break switch contact system.
Related Art Disconnectors are the most commonly used appliances in high voltage switch appliances. The main features of the disconnector are that the disconnector has no arc-extinguishing capacity and that the circuit is closed and opened only when there is no load current. Disconnectors are used for all classes of voltages and are used to change circuit connections or to isolate lines or devices from a power source. The disconnector has no breaking capacity and can only perform an action after the line is closed by using other devices. The disconnector typically has an interlocking device that is used to prevent malfunction when the switch withstands the load. In some cases, a pin is required to prevent the switch from being turned off under the magnetic effects of a large anomaly. In a circuit system, a circuit breaker is activated when the circuit is abnormal or when improved maintenance needs to be performed on the circuit. In this case, the disconnector serves the function of interrupting low currents or providing obvious breakage to ensure worker safety during repair or improved maintenance. In general, there are two types of disconnectors. Non-sealing disconnectors and gas-insulated metal sealed disconnectors. Unsealed disconnectors are directly exposed to air, and when the disconnector is switched off, obvious damage can be found, but unsealed disconnectors are large and relatively heavy. Gas insulated metal hermetic disconnectors are widely used because of their small size and high reliability. Gas-insulated metal hermetic disconnectors typically have three disconnector single phases. Each disconnector single phase has a cylindrical body. A movable contact, a fixed contact, and a transmission mechanism that drives the movable contact to move are disposed within the cylindrical body. Electrical drive is used in most transmission mechanisms. However, since the gas-insulated metal hermetic disconnect switch is sealed, the operator cannot directly observe and cannot clearly determine whether or not the gas-insulated metal hermetic disconnect switch is in a break state.

  Currently, common rotary double break disconnectors are available on the market. The wiring of the rotary double break disconnect switch contact system can only be implemented in such a way that the wire enters in one direction. For this reason, the applicable range of the rotary double break disconnector is narrowed. In some special situations where it is necessary to change the mounting position of the disconnector, the disconnector cannot be applied because the wiring direction cannot be adjusted.

SUMMARY An object of the present invention is to provide an improved wiring structure of a contact system for a rotary double break disconnector that solves the technical disadvantage that the wiring direction of an existing rotary double break disconnector is one. . The wiring method is improved so that the wiring direction of the contact system of the rotary double break disconnect switch can be changed flexibly so as to meet the requirements in field installation of disconnect switch.

Technical Solution To achieve the above technical object, the improved wiring structure of the contact system of the rotary double break switch designed in the present invention comprises a movable contact, a fixed contact and a short-circuit bus bar. An electrical connection between the movable contact and the stationary contact can be achieved during rotation. By using the terminal screw, the stationary contact is connected to the shorting bus bar so that the terminal screw allows the wire to enter along the circumferential direction.

Further, the mounting direction of the terminal screw is perpendicular to the main axis of the movable contact.
Further, the short-circuit bus bar has a shape in which both ends of the plate are bent in opposite directions. Terminal screw mounting via holes are formed at the two ends of the short-circuit bus bar. The short-circuit bus bar is locked to the end of the stationary contact by using a terminal screw. The tip of the stationary contact extends into the slot of the movable contact. As the movable contact rotates, the contact end can contact the tip of the stationary contact to form an electrical connection.

Furthermore, a screw hole is formed at the end of the stationary contact. The distal end of the stationary contact is connected to the end by a connecting portion.
Furthermore, the tip and end of the stationary contact have a planar structure perpendicular to each other.

In addition, during rotation, the movable contact can contact the tip of the stationary contact to achieve a double break.
Further, the movable contact is attached to the coupling.

Furthermore, the movable contact, the fixed contact, and the short-circuit bus bar are attached to the base.
Furthermore, the bottom surface of the wiring port where the terminal screw is connected to the fixed contact is inclined downward so that the wiring angle of the connection wire inserted between the terminal screw and the fixed contact is increased.

Useful Effects The present invention provides an improved wiring structure for a rotary double break switch contact system. The terminal screw changes the wiring method to allow the wire to enter along the circumferential direction, i.e. the fixed contact is connected to the short-circuit busbar by using the terminal screw. In this way, the wiring direction of the contact system of the rotary double break disconnect switch can be flexibly changed so as to meet the requirements in the field installation of the disconnect switch.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention.
FIG. 2 is a schematic exploded view of an embodiment of the present invention.
FIG. 3 is a schematic structural diagram for mounting the short-circuit bus bar according to the embodiment of the present invention.
FIG. 4 is a schematic structural diagram of a short-circuit bus bar according to an embodiment of the present invention.
FIG. 5 is a schematic structural diagram of the movable contact according to the embodiment of the present invention.
FIG. 6 is a schematic structural diagram of a stationary contact according to an embodiment of the present invention.

DETAILED DESCRIPTION The present invention is further described below with reference to the accompanying drawings and embodiments.

Embodiment As shown in FIGS. 1 and 2, the improved wiring structure of the contact system of the rotary double break switch provided in the present invention includes a movable contact 1, a fixed contact 2, and a short-circuit bus bar 3. An electrical connection between the movable contact 1 and the fixed contact 2 can be achieved during rotation. The stationary contact 2 is connected to the short-circuit bus bar 3 by using terminal screws 4. The terminal screw 4 allows the wire to enter along the circumferential direction. In this embodiment, the wire enters from the outside (right side).

Further, referring to FIG. 1, the mounting axis direction of the terminal screw 4 is perpendicular to the main axis of the movable contact 1. The movable contact 1, the fixed contact 2, and the short-circuit bus bar 3 are attached to the base 6.
As shown in FIGS. 3 and 4, the short-circuit bus bar 3 has a shape in which both ends of the plate are bent in opposite directions. The two ends of the short-circuit bus bar 3 each have a planar structure and are parallel to each other. The two ends are connected by using a rod or plate structure between them. A terminal screw mounting via hole 301 is formed at each end. One end is locked to the end 203 of the stationary contact 2 by using the terminal screw 4 and can be used for external wiring (see FIGS. 2 and 6). The other end 305 extends to the connection slot 8 of the base 6 and can be appropriately coupled (electrically connected) with other rotary double break switches used in combination as required. The distal end 202 of the stationary contact 2 is extended to the slot 101 of the movable contact 1. The surface of the slot 101 is perpendicular to the main axis of the movable contact 1. In this way, when the movable contact 1 rotates, the contact end 102 can contact the tip 202 of the stationary contact 2 so as to form an electrical connection. In the present embodiment, the mounting via hole 301 is a gap (U-shaped portion) that is not closed, which facilitates connection. It is also true that a closed hole can be used.

  Still referring to FIG. 1, the wiring angle of the connecting wire inserted between the terminal screw 4 and the stationary contact 2 can be different so that different wiring angles of 0 ° to 45 ° can be achieved. In order to facilitate, the bottom surface 91 of the wiring port 9 to which the terminal screw 4 is connected to the stationary contact 2 is inclined downward (toward the bottom surface of the base). The high bottom surface of the existing switch is substantially parallel to the surface of the base 6, and only one-way wiring can be performed.

  As shown in FIG. 6, a screw hole 201 is formed at the end of the stationary contact 2. The distal end 202 of the stationary contact 2 is connected to the end 203 by the connecting portion 204. In this embodiment, the planar tip 202 of the stationary contact 2 is brought into the face of the end 203 through the connecting portion 204 as a transition portion so that the terminal screw 4 can enter the wire along the circumferential direction. It is perpendicular to it.

  Still referring to FIG. 5, during rotation, the movable contact 1 can contact the tips 202 of the two stationary contacts 2 to achieve a double break. (Please explain what “double break” means. If “double break” is a common noun in the field, no explanation is needed.)

The movable contact 1 is attached to the coupling 5.
With the improved wiring structure of the rotary double break switch contact system provided in the present invention, the wiring method is improved so that the terminal screw 4 allows the wire to enter along the circumferential direction. That is, the fixed contact 2 is connected to the short-circuit bus bar 3 by using the terminal screw 4. In this way, the wiring direction of the rotary double break disconnect switch contact system can be flexibly changed to meet the field installation requirements of the disconnect switch of the present invention at various locations.

  The structures, scales, and sizes shown in the accompanying drawings of the embodiments are only used in combination with the contents disclosed in the specification for easy understanding and reading by those skilled in the art, and limit the constraints to which the present application can be applied. Not intended. Therefore, it is not technically essential. Any variation in structure, any change in scale relationship, or any adjustment in size that does not affect the effect and purpose achieved by the present invention is within the scope of the technical content disclosed in the present invention. is there. Furthermore, the terms “upper”, “lower”, “left”, “right”, “center”, “clockwise”, “counterclockwise” and the like used in the specification are for easy understanding of the explanation. It is not intended to limit the scope of the invention. It should be noted that changes or adjustments in relative relationships that do not fundamentally change the technical content are within the scope of the present invention.

Claims (9)

An improved wiring structure for a contact system of a rotary double break switch comprising a movable contact (1), a fixed contact (2) and a short circuit bus bar (3),
An electrical connection between the movable contact (1) and the stationary contact (2) can be achieved during rotation;
The fixed contact (2) is connected to the short-circuit bus bar (3) by using a terminal screw (4),
The terminal screw (4) is an improved wiring structure of the contact system of the rotary double break switch that allows the wire to enter along the circumferential direction.   The improved wiring structure of the contact system of the rotary double break switch according to claim 1, wherein the mounting axis direction of the terminal screw (4) is perpendicular to the main axis of the movable contact (1). Improved wiring structure for contact system of rotary double break switch. An improved wiring structure for the contact system of the rotary double break switch according to claim 1,
The short-circuit bus bar (3) has a shape in which both ends of the plate are bent in opposite directions,
Terminal screw mounting via holes (301) are formed at two ends of the short-circuit bus bar (3),
The short-circuit bus bar (3) is locked to the end of the stationary contact (2) by using the terminal screw (4),
The tip (202) of the stationary contact (2) extends to the slot (101) of the movable contact (1),
When the movable contact (1) rotates, the contact end (102) can contact the tip (202) of the stationary contact (2) to form an electrical connection. Improved wiring structure for switch contact system. An improved wiring structure for the contact system of the rotary double break switch according to claim 1,
A screw hole (201) is formed at the end (203) of the stationary contact (2),
An improved wiring structure of a rotary double break switch contact system in which the tip (202) of the stationary contact (2) is connected to the end (203) by a connection (204).   The improved wiring structure of the contact system of the rotary double break switch according to claim 1, wherein the front end (202) and the end (203) of the stationary contact (2) are perpendicular to each other. An improved wiring structure for the contact system of the rotary double break switch.   2. The improved wiring structure of the contact system of the rotary double break switch according to claim 1, wherein, when rotating, the movable contact (1) is fixed in two in order to realize a double break. An improved wiring structure for a contact system of a rotary double break switch capable of contacting the tip (202) of the contact (2).   The contact structure of the rotary double break switch according to claim 1, wherein the movable contact (1) is a contact of the rotary double break switch mounted on the coupling (5). Improved wiring structure of the system.   The improved double break switch contact system wiring structure according to claim 1, wherein the movable contact (1), the fixed contact (2) and the short-circuit bus bar (3) Improved wiring structure of the contact system of the rotary double break switch mounted on (6).   It is an improved wiring structure of the contact system of the rotary double break switch of Claim 1, Comprising: The wiring angle of the connection wire inserted between the said terminal screw (4) and the said stationary contact (2) The bottom surface (91) of the wiring port (9) where the terminal screw (4) is connected to the stationary contact (2) is inclined downward so that the terminal screw (4) is inclined downward. Improved wiring structure for contact system.

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