CN220439429U - Isolating switch closing energy storage mechanism and isolating switch - Google Patents

Isolating switch closing energy storage mechanism and isolating switch Download PDF

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Publication number
CN220439429U
CN220439429U CN202321701904.8U CN202321701904U CN220439429U CN 220439429 U CN220439429 U CN 220439429U CN 202321701904 U CN202321701904 U CN 202321701904U CN 220439429 U CN220439429 U CN 220439429U
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China
Prior art keywords
contact
energy storage
isolating switch
energy
elastic piece
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Active
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CN202321701904.8U
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Chinese (zh)
Inventor
康宽
郑发锦
胡国丰
陈杨杰
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Zhejiang Chint Electrics Co Ltd
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Zhejiang Chint Electrics Co Ltd
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Priority to CN202321701904.8U priority Critical patent/CN220439429U/en
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Abstract

The utility model belongs to the technical field of piezoelectric devices, and discloses a closing energy storage mechanism of an isolating switch and the isolating switch. The isolating switch closing energy storage mechanism comprises a contact support, a contact bridge, an elastic piece and an energy storage structure, wherein the contact support is assembled in a shell in a sliding manner, the contact bridge is movably assembled in the contact support, the elastic piece is connected with the contact bridge and the contact support, the elastic piece is used for driving a moving contact on the contact bridge to move towards a fixed contact, the energy storage structure is used for enabling the elastic piece to store energy first and then release energy when the contact support drives the moving contact on the contact bridge to move towards the fixed contact, the elastic piece releases energy to drive the moving contact to rapidly contact with the fixed contact, contact arc can be reduced, contact resistance and temperature between the moving contact and the fixed contact can be effectively reduced, so that the degree of contact ablation and abrasion is reduced, and the electrical life performance of the isolating switch is improved.

Description

Isolating switch closing energy storage mechanism and isolating switch
Technical Field
The utility model relates to the technical field of piezoelectric devices, in particular to a closing energy storage mechanism of an isolating switch and the isolating switch.
Background
An isolating switch is a common electrical device used to isolate a circuit. The working principle and the structure are relatively simple, but the influence on the design, establishment and safe operation of a substation and a power plant is large due to large use amount, so the requirement on the working reliability is extremely high.
The important index of isolator is switch-on breaking capacity, because the closing speed is slow can lead to moving contact and stationary contact to receive great pressure in the closing process, contact resistance is great, and the temperature is very high under the effect of electric current to lead to the contact to ablate, shortened isolator's life.
Therefore, a closing energy storage mechanism of an isolating switch and the isolating switch are needed to solve the problems in the prior art.
Disclosure of Invention
The utility model aims to provide a closing energy storage mechanism of an isolating switch, which can reduce the generation of contact electric arcs, and can effectively reduce the contact resistance and the temperature between a moving contact and a fixed contact, thereby reducing the degree of contact ablation and abrasion and prolonging the service life of the isolating switch.
To achieve the purpose, the utility model adopts the following technical scheme:
the isolator combined floodgate energy storage mechanism includes:
the contact support is assembled in the shell in a sliding way;
the contact bridge is provided with a movable contact, and the contact bridge is movably assembled on the contact support;
the elastic piece is connected with the contact bridge and the contact support and is used for driving a moving contact on the contact bridge to move towards a fixed contact;
the energy storage structure is configured to enable the elastic piece to store energy and then release energy when the contact support drives the moving contact on the contact bridge to move towards the fixed contact, and the elastic piece releases energy to drive the moving contact to contact with the fixed contact.
Optionally, the energy storage structure includes:
the energy storage boss is arranged on the inner wall of the shell along the contact support moving direction;
the energy storage shaft is arranged on one side, away from the elastic piece, of the contact bridge, an energy storage hole is formed in the contact support, an energy release inclined plane is arranged on the wall of the energy storage hole, the energy storage shaft is positioned in the energy storage hole, and two ends of the energy storage shaft are slidably arranged in the shell;
the energy storage boss is configured to limit the energy storage shaft to slide along the closing direction supported by the contact when the contact supports to move towards the closing direction so as to prevent the contact bridge from continuing to move, so that the elastic piece stores energy, the energy storage shaft can be driven by the energy release inclined plane to leave the energy storage boss so that the elastic piece releases energy, and the contact bridge is driven by the energy storage shaft to drive the moving contact to move to the closing position.
Optionally, the guiding groove is arranged on the inner wall of the shell along the opening and closing direction supported by the contact.
Optionally, the energy storage groove sets up in the guide way is inside, during the divide-shut brake the contact support is located the guide way is inside and butt is in on the energy storage groove.
Optionally, the energy storage structure further includes a reset inclined plane, the reset inclined plane is disposed on a hole wall of the energy storage hole, and when the contact supports to move towards the opening direction, the reset inclined plane resets the energy storage shaft.
Optionally, an arc transition surface is arranged at the joint of the energy release inclined plane and the reset inclined plane.
Optionally, the arc transition surface is located energy storage boss one side, and the closing process in-process energy storage axle slides to the arc transition surface on the position of corresponding energy storage boss.
Optionally, an assembly hole is formed in the contact support, the moving contact is movably assembled in the assembly hole, one end of the elastic piece is abutted to the moving contact, and the other end of the elastic piece is abutted to the top wall of the assembly hole.
Another object of the utility model is to provide an disconnector that reduces the closing time and the generation of contact arcs, improving the electrical life and reliability of the disconnector.
To achieve the purpose, the utility model adopts the following technical scheme:
the isolating switch comprises a shell, a handle, fixed contacts and the isolating switch closing energy storage mechanism, wherein the handle is pivoted to the shell, the contact support can be linked with the handle, and the two fixed contacts are respectively arranged in the shell corresponding to the moving contacts at two ends of the contact bridge.
Optionally, the isolating switch further comprises an indicating mechanism, and the indicating mechanism is used for displaying that the isolating switch is at a switching-off position or a switching-on position.
Optionally, the indicating mechanism includes the pin joint is in the pilot unit in the shell, be provided with first sign and second sign on the pilot unit, be equipped with the instruction window on the shell, the contact support is close to one side of pilot unit is provided with drive division, drive division can drive the pilot unit rotates so that first sign or second sign remove to the instruction window department.
Optionally, the indicator includes pivot portion, power portion, connecting rod portion and indicator portion, pivot portion rotates with the shell and is connected, power portion with the connecting rod portion is the contained angle set up in on the pivot portion, indicator portion with connecting rod portion connects, first sign and second sign set up in on the indicator portion.
Optionally, the isolating switch further comprises a torsion elastic member, one end of the torsion elastic member is connected with the housing, the other end of the torsion elastic member is connected with the handle, and the torsion elastic member is configured to keep the handle in a closing position or a separating position.
The beneficial effects are that:
the utility model provides an isolating switch closing energy storage mechanism, which comprises a contact support, a contact bridge, an elastic piece and an energy storage structure, wherein the contact support is assembled in a shell in a sliding manner, the contact bridge is movably assembled on the contact support, the elastic piece is connected with the contact bridge and the contact support, the elastic piece is used for driving a moving contact on the contact bridge to move towards a fixed contact, the energy storage structure is used for enabling the elastic piece to store energy first and then release energy when the contact support drives the moving contact on the contact bridge to move towards the fixed contact, the elastic piece releases energy to drive the moving contact to rapidly contact with the fixed contact, contact electric arc can be reduced, and contact resistance and temperature between the moving contact and the fixed contact can be effectively reduced, so that the degree of contact ablation and abrasion is reduced, and the electric life performance of an isolating switch is improved.
According to the isolating switch provided by the utility model, the isolating switch-on energy storage mechanism is adopted, and the handle can be linked with the contact support, so that the operation can be rapidly and reliably completed during switch-on, the switch-on time and the generation of contact arc are reduced, and the electric life and reliability of the isolating switch are improved.
Drawings
FIG. 1 is a schematic diagram of a structure of an isolating switch closing energy storage mechanism in a state of opening;
fig. 2 is a schematic diagram of a closing process of the closing energy storage mechanism of the isolating switch provided by the utility model;
fig. 3 is a schematic diagram II of a closing process of the closing energy storage mechanism of the isolating switch;
fig. 4 is a schematic structural diagram of the isolating switch in a closing state of the closing energy storage mechanism;
FIG. 5 is an exploded view of the isolating switch closing energy storage mechanism provided by the utility model;
FIG. 6 is a schematic diagram of an energy storage structure according to the present utility model;
fig. 7 is a schematic structural view of an indicator provided by the present utility model.
In the figure:
100. a contact support; 110. an energy storage hole; 111. an energy release inclined plane; 112. resetting the inclined plane; 113. a circular arc transition surface; 120. a fitting hole; 130. a driving section; 200. a contact bridge; 210. a moving contact; 300. an elastic member; 400. a housing; 410. an energy storage tank; 411. an energy storage boss; 420. an indication window; 430. the contact supports the limit groove; 440. a guide block; 450. a guide groove; 500. an energy storage shaft; 600. a handle; 700. a stationary contact; 800. an indicator; 810. a pivoting portion; 820. a power section; 830. a link portion; 840. an indication part.
Detailed Description
The utility model is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present utility model are shown in the drawings.
In the description of the present utility model, unless explicitly stated and limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.
In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.
In the description of the present embodiment, the terms "upper", "lower", "left", "right", and the like are orientation or positional relationships based on those shown in the drawings, merely for convenience of description and simplicity of operation, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the utility model. Furthermore, the terms "first," "second," and the like, are used merely for distinguishing between descriptions and not for distinguishing between them.
The embodiment provides a closing energy storage mechanism of an isolating switch, which is used in the isolating switch, as shown in fig. 1-5, and the closing energy storage mechanism of the isolating switch comprises a contact support 100, a contact bridge 200, an elastic piece 300 and an energy storage structure, wherein the contact support 100 is slidably assembled in a shell 400, the contact bridge 200 is movably assembled in the contact support 100, two ends of the contact bridge 200 are provided with moving contacts 210, the elastic piece 300 is connected with the contact bridge 200 and the contact support 100, and the elastic piece 300 is used for driving the moving contacts 210 on the contact bridge 200 to move towards the direction of a fixed contact. The elastic member 300 is located on the upper side of the contact bridge 200, and the energy storage structure is located on the lower side of the contact bridge 200. The energy storage structure is used for enabling the elastic piece 300 to store energy and then release energy when the contact support 100 drives the moving contact 210 on the contact bridge 200 to move towards the direction of the fixed contact 700, and the elastic piece 300 can drive the contact bridge 200 to drive the moving contact 210 to rapidly contact with the fixed contact 700 after releasing energy, so that the generation of contact arc can be reduced, the contact resistance and the temperature between the moving contact 210 and the fixed contact 700 can be effectively reduced, the contact ablation and abrasion degree are reduced, and the electrical life performance of the isolating switch is improved.
Alternatively, as shown in fig. 1-5, the energy storage structure includes an energy storage boss 411 and an energy storage shaft 500, the energy storage boss 411 is disposed on an inner wall of the housing 100 along a moving direction of the contact support 100, the energy storage shaft 500 is disposed on a side of the contact bridge 200 away from the elastic member 300, an energy storage hole 110 is formed in a position of the contact support 100 corresponding to the energy storage shaft 500, an energy release inclined plane 111 is disposed on a hole wall of the energy storage hole 110, the energy storage shaft 500 is disposed in the energy storage hole 110, two ends of the energy storage shaft are respectively slidably disposed in the housing 100, when the contact support 100 moves in a closing direction, the contact bridge 200 and the elastic member 300 can be driven to move downward together, the energy storage shaft 500 slides to the energy storage boss 411 along the closing direction of the contact support 100, the energy storage shaft 500 and the energy storage boss 411 abut against to prevent the contact bridge 200 from moving continuously, at this time, the contact support 100 continues to move downward, the elastic member 300 is compressed, and the elastic member 300 is compressed to store energy. When the contact support 100 continues to move downwards, the energy release inclined plane 111 can push the energy storage shaft 500 to move horizontally along the energy storage boss 411, when the energy storage shaft 500 leaves the energy storage boss 411, the elastic piece 300 releases energy, and after the elastic piece 300 releases energy, the contact bridge 200 can be driven to drive the moving contact 210 to quickly contact with the fixed contact 700, so that the generation of contact electric arcs is reduced, the contact resistance and the temperature between the moving contact 210 and the fixed contact 700 are reduced, the degree of contact ablation and abrasion is reduced, and the electrical life performance of the isolating switch is improved.
Optionally, a guiding slot 450 extending along the opening and closing direction of the contact support 100 is further provided on the inner wall of the housing 400, and the guiding slot 450 can guide the moving direction of the contact support 100, so as to ensure that the contact support 100 moves along the correct direction, and improve the reliability of opening and closing.
Optionally, the inside of guide slot 450 is provided with energy storage slot 410, energy storage boss 411 sets up in energy storage slot 410, contact support 100 is located the inside and butt in energy storage slot 410 of guide slot 450 during the divide-shut brake, the setting of energy storage slot 410 guarantees on the basis that contact support 100 removed along guide slot 450, has planned the exact direction of movement for energy storage axle 500, make energy storage axle 500 can cooperate with energy storage boss 411, energy storage hole 110 and elastic component 300, store energy and release the energy to the movable contact bridge, make movable contact 210 and static contact 700 quick contact, can reduce the production of contact electric arc.
Optionally, a contact support limit groove 430 extending along the opening and closing direction of the contact support 100 is further provided on the inner wall of the housing 400, and the contact support limit groove 430 can limit the contact support 100, specifically, when the switch is opened, the contact support 100 is located in the guide groove 450, during the switching-on process, the contact support 100 moves into the contact support limit groove 430 along the guide groove 450, and the setting of the limit groove can prevent the contact support 100 from deviating from the guide groove 450, so that the switching-on reliability is improved.
Optionally, the energy storage structure further includes a reset inclined plane 112, where the reset inclined plane 112 is disposed on the bottom wall of the energy storage hole 110, and when the contact support 100 moves in the opening direction, the energy storage shaft 500 falls back to the initial position along the reset inclined plane 112 under the action of gravity and the pressure of the elastic member 300, so as to implement reset. The energy storage shaft 500 is simple in structure, the possibility of blocking during resetting of the energy storage shaft 500 is reduced, and the reliability and stability of the energy storage structure are improved. In addition, by adding the reset inclined plane 112, the energy storage shaft 500 can be ensured to return to the initial position after each brake separation, and is ready for next energy storage, so that the efficiency and the service life of the energy storage structure are improved, and the safe operation of the power system is ensured.
Optionally, the arc transition surface 113 is disposed at the connection position between the energy release inclined surface 111 and the reset inclined surface 112, so that the transition between the energy release inclined surface 111 and the reset inclined surface 112 is smoother, the abrasion and the blocking of the energy storage shaft 500 are reduced, and the smoothness of closing and opening of the isolating switch is improved.
Alternatively, the arcuate transition surface 113 may serve as an initial position for the storage shaft 500 to fall back. The arc transition surface is arranged on one side of the energy storage boss, and the energy storage shaft slides to the arc transition surface along the reset inclined plane under the gravity action of the energy storage shaft in the closing process, so that preparation is made for energy storage in the next closing process. The energy storage shaft can store energy correctly in the next closing process, and the reset structure is simple, safe and reliable. Meanwhile, due to the existence of the arc transition surface, the resetting process of the energy storage shaft is more stable, the impact and vibration are reduced, and the circuit breaker can be ensured to run reliably.
Optionally, as shown in fig. 6, an assembly hole 120 is formed on the contact support 100, the opening direction of the assembly hole 120 is perpendicular to the opening direction of the energy storage hole 110, the contact bridge 200 is movably assembled in the assembly hole 120, the elastic member 300 is installed on the upper side of the contact bridge 200, the energy storage shaft is movably arranged on the lower side of the contact bridge 200, one end of the elastic member 300 is abutted to the contact bridge 200, the other end of the elastic member is abutted to the top wall of the assembly hole 120, the elastic member 300 can cooperate with the energy storage shaft 500 and the contact support 100 to store and release energy, the movable contact 210 on the contact bridge 200 of the isolating switch can be contacted with the fixed contact 700 quickly in the closing process, the arc generation is reduced, the elastic member 300 can provide contact pressure for the contact bridge 200 to ensure that the movable contact 210 on the contact bridge 200 is well contacted with the fixed contact 700, and the circuit operation is more stable.
Optionally, the elastic member 300 in this embodiment is a leaf spring, and the leaf spring can implement energy storage and energy release of the isolating switch through elastic deformation, so that the moving contact 210 on the contact bridge 200 of the isolating switch can be ensured to be quickly contacted with the fixed contact 700 in the switching-on process, arc generation is reduced, and the electrical life performance of the isolating switch is improved. Meanwhile, the leaf spring is used as an elastic element, has good fatigue resistance, can keep good elastic deformation capacity for a long time, and improves the reliability and stability of the isolating switch.
The embodiment further provides an isolating switch, as shown in fig. 1-7, including a housing 400, a handle 600, a fixed contact 700, and the isolating switch-on energy storage mechanism, where the handle 600 is pivoted to the housing 400, the contact support 100 can be linked with the handle 600, the two fixed contacts 700 are respectively corresponding to the moving contacts 210 at two ends of the contact bridge 200 and are disposed in the housing 400, and the handle 600 is used for driving the isolating switch to switch off or switch on, so that the contact state between the moving contact 210 and the fixed contact 700 is switched. The handle 600 can be interlocked with the contact support 100 so that the operation can be rapidly and reliably completed at the time of closing, the closing time and the generation of contact arc are reduced, and the electrical life and reliability of the isolating switch are improved. The isolating switch is compact in structure, simple and convenient to operate, has good energy storage and release performances, can effectively reduce the generation of electric arcs and the contact resistance of the moving and static contacts 700, and prolongs the service life of the isolating switch.
Optionally, the isolating switch further comprises an indicating mechanism, and the indicating mechanism is used for displaying that the isolating switch is at the opening position or the closing position. Through the design of the indicating mechanism, an operator can intuitively know the opening and closing state of the isolating switch, and misoperation and safety accidents are avoided.
Optionally, the indication mechanism includes an indication member 800 pivotally connected in the housing 400, a first mark and a second mark are provided on the indication member 800, an indication window 420 is provided on the housing 400, a driving portion 130 is provided on a side of the contact support 100 near the indication member 800, and along with the up-down movement of the contact support 100, the driving portion 130 can drive the indication member 800 to rotate so that the first mark or the second mark moves into the indication window. Therefore, when the user needs to use the isolating switch, the user only needs to observe the mark on the indicator 800 through the indicator window 420 to judge the state of the isolating switch, which is convenient and quick.
Alternatively, as shown in fig. 7, the indicator 800 includes a pivoting portion 810, a power portion 820, a connecting rod portion 830, and an indicator portion 840, where the pivoting portion 810 is rotationally connected to the housing 400, the power portion 820 and the connecting rod portion 830 are disposed on the pivoting portion 810 at an included angle, the indicator portion 840 and one end of the connecting rod portion 830, which is not connected to the pivoting portion 810, are connected, the first identifier and the second identifier are sequentially disposed on the indicator portion 840, and the driving portion 130 is connected to the power portion 820 to drive the indicator 800 to rotate. Through the design, the isolating switch can directly display the switch position through the indication window 420 in the opening or closing process, so that the convenience and safety of operation are improved.
For example, the first indicator may be red and the second indicator may be green when the disconnector is in the closed state, and the indicator may be red when the disconnector is in the open state. The design is convenient for operators to use, and the safety performance of the isolating switch is improved.
Optionally, the isolating switch further includes a torsion elastic member having one end connected to the housing 400 and the other end connected to the handle 600, the torsion elastic member being configured to maintain the handle 600 in the on position or the off position. The function of the torsion spring is to provide a damping force when the handle 600 is twisted to the on or off position to maintain the handle 600 in this position. This can prevent the handle 600 from being accidentally mishandled during use, resulting in a change in the state of the switch, thereby increasing the reliability and safety of the disconnector.
Optionally, in this embodiment, the torsion elastic member is a torsion spring, and the torsion spring has a simple structure and low cost, and can further save cost, and improve the reliability of opening and closing the isolating switch.
The closing process of the isolating switch provided by the embodiment is as follows:
first, as shown in fig. 1 to 5, the handle 600 is manually rotated, and as the handle 600 is rotated, the contact support 100 moves downward, driving the energy storage shaft 500 downward and moving in the energy storage slot 410 of the housing 400, and when the energy storage shaft 500 moves to the energy storage boss 411 of the energy storage slot 410, the energy storage shaft 500 is caught in the slot of the housing 400 to stop moving and prevent the contact bridge 200 from moving, but the handle 600 continues to rotate, causing the leaf spring to start compressing and storing energy.
Then, as the contact support 100 continues to move downward, the energy release inclined surface 111 on the left side wall of the energy storage hole 110 can drive the energy storage shaft 500 to move horizontally, and when the energy storage shaft 500 slides down from the energy storage step after moving to the critical point shown in fig. 3, the leaf spring is unlocked.
Finally, after the leaf spring is unlocked, as shown in fig. 4-5, the leaf spring rapidly rebounds to drive the moving contact 210 on the contact bridge 200 to contact with the fixed contact 700 at a higher speed, so that the generation of contact arc can be reduced, and the electrical life performance of the isolating switch can be improved.
The disconnecting switch provided in this embodiment has the following disconnecting process:
the handle 600 rotates in the opening direction, the belt contact bridge 200 moves upward, and the energy storage thin shaft returns to the initial position under the gravity and the pressure of the leaf spring due to the inclined arrangement of the reset inclined plane 112, so that the reset is realized.
It is to be understood that the above examples of the present utility model are provided for clarity of illustration only and are not limiting of the embodiments of the present utility model. Various obvious changes, rearrangements and substitutions can be made by those skilled in the art without departing from the scope of the utility model. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (10)

1. Isolator combined floodgate energy storage mechanism, its characterized in that includes:
a contact support (100) slidably mounted within the housing (400);
the contact bridge (200) is provided with a movable contact (210), and the contact bridge (200) is movably assembled on the contact support (100);
an elastic piece (300) which is connected with the contact bridge (200) and the contact support (100), wherein the elastic piece (300) is used for driving a moving contact (210) on the contact bridge (200) to move towards a fixed contact (700);
the energy storage structure is configured to enable the elastic piece (300) to store energy first and then release energy when the contact support (100) drives the moving contact (210) on the contact bridge (200) to move towards the fixed contact, and the elastic piece (300) releases energy to drive the moving contact (210) to be in contact with the fixed contact (700).
2. The isolating switch-on energy storage mechanism of claim 1, wherein the energy storage mechanism comprises:
the energy storage boss (411) is arranged on the inner wall of the shell (400) along the moving direction of the contact support (100);
the energy storage shaft (500) is arranged on one side, deviating from the elastic piece (300), of the contact bridge (200), an energy storage hole (110) is formed in the contact support (100), an energy release inclined plane (111) is formed in the wall of the energy storage hole (110), the energy storage shaft (500) is positioned in the energy storage hole (110), and two ends of the energy storage shaft (500) are slidably arranged in the shell (400);
the energy storage boss (411) is configured to limit the energy storage shaft (500) to slide along the closing direction of the contact support (100) when the contact support (100) moves towards the closing direction so as to prevent the contact bridge (200) from continuing to move, so that the elastic piece (300) stores energy, the energy storage shaft (500) can be driven to leave the energy storage boss (411) by the energy release inclined plane (111) so that the elastic piece (300) releases energy, and the contact bridge (200) is driven to drive the moving contact (210) to move to the closing position.
3. The isolating switch-on energy storage mechanism of claim 1, further comprising a guide slot (450), the guide slot (450) being disposed on an inner wall of the housing (400) along the contact support (100) opening and closing direction.
4. The disconnecting switch closing energy storage mechanism according to claim 3, wherein an energy storage groove (410) is arranged inside the guide groove (450), and the contact support (100) is positioned inside the guide groove (450) and is abutted against the energy storage groove (410) when the disconnecting switch is opened.
5. The isolating switch closing energy storage mechanism of claim 2, further comprising a reset ramp (112), the reset ramp (112) being disposed on a wall of the energy storage hole (110), the reset ramp (112) resetting the energy storage shaft (500) when the contact support (100) moves in a breaking direction.
6. The isolating switch closing energy storage mechanism as claimed in claim 5, wherein an arc transition surface (113) is arranged at the connection of the energy release inclined surface (111) and the reset inclined surface (112).
7. The isolating switch closing energy storage mechanism as claimed in claim 6, wherein the arc transition surface (113) is located at a side close to the energy storage boss (411), and the energy storage shaft (500) slides to a position on the arc transition surface (113) corresponding to the energy storage boss (411) during closing.
8. The isolating switch closing energy storage mechanism as claimed in claim 1, wherein the contact support (100) is provided with an assembly hole (120), the moving contact (210) is movably assembled in the assembly hole (120), one end of the elastic member (300) is abutted to the moving contact (210), and the other end is abutted to the top wall of the assembly hole (120).
9. The isolating switch is characterized by comprising a shell (400), a handle (600), fixed contacts (700) and the isolating switch closing energy storage mechanism as claimed in any one of claims 1-8, wherein the handle (600) is pivoted to the shell (400), the contact support (100) can be linked with the handle (600), and the two fixed contacts (700) are respectively arranged in the shell (400) corresponding to the moving contacts (210) at two ends of the contact bridge (200).
10. The disconnector of claim 9, further comprising an indication mechanism for displaying whether the disconnector is in a closed or open position.
CN202321701904.8U 2023-06-30 2023-06-30 Isolating switch closing energy storage mechanism and isolating switch Active CN220439429U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202321701904.8U CN220439429U (en) 2023-06-30 2023-06-30 Isolating switch closing energy storage mechanism and isolating switch

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202321701904.8U CN220439429U (en) 2023-06-30 2023-06-30 Isolating switch closing energy storage mechanism and isolating switch

Publications (1)

Publication Number Publication Date
CN220439429U true CN220439429U (en) 2024-02-02

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Application Number Title Priority Date Filing Date
CN202321701904.8U Active CN220439429U (en) 2023-06-30 2023-06-30 Isolating switch closing energy storage mechanism and isolating switch

Country Status (1)

Country Link
CN (1) CN220439429U (en)

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