CN214378188U

CN214378188U - Electromagnetic repulsion force quick mechanism and quick mechanical switch

Info

Publication number: CN214378188U
Application number: CN202022963858.1U
Authority: CN
Inventors: 姚文彬; 门博; 孙英杰; 孙珂珂; 董佩冉; 熊萍萍; 张良杰; 井琼琼; 张利欣; 胡延涛
Original assignee: State Grid Corp of China SGCC; Pinggao Group Co Ltd; Henan Pinggao Electric Co Ltd
Current assignee: State Grid Corp of China SGCC; Pinggao Group Co Ltd; Henan Pinggao Electric Co Ltd
Priority date: 2020-12-11
Filing date: 2020-12-11
Publication date: 2021-10-08
Anticipated expiration: 2030-12-11

Abstract

The utility model provides an electromagnetic repulsion quick mechanism and quick mechanical switch, electromagnetic repulsion quick mechanism includes: a transmission rod; the induction disc is fixed on the transmission rod; a brake separating repulsion coil; closing repulsion coil; at least two electromagnetic coils; the electromagnetic coil control circuits are connected with each electromagnetic coil in a one-to-one correspondence manner so as to control the electrification and the outage of the electromagnetic coils; in the switching-on and switching-off process, at least one of the electromagnetic coils is an accelerating coil, the accelerating coil is powered on in the first half section and powered off in the second half section through which the induction disc passes, at least one of the electromagnetic coils is a decelerating coil, and the decelerating coil is powered off in the first half section and powered on in the second half section through which the induction disc passes. The utility model discloses the utilization is accelerated the coil and is accelerated the response dish earlier stage at divide-shut brake, shortens whole divide-shut brake time, utilizes the reduction coil to decelerate the response dish in the divide-shut brake later stage simultaneously, avoids too big and produce the impact to explosion chamber or operating mechanism body, prolongs the life of operating mechanism and explosion chamber.

Description

Electromagnetic repulsion force quick mechanism and quick mechanical switch

Technical Field

The utility model relates to a high tension switchgear technical field, concretely relates to electromagnetic repulsion quick mechanism and quick mechanical switch.

Background

The existing rapid mechanical switch mainly comprises a repulsion mechanism and a moving end assembly, wherein the repulsion mechanism comprises a charger, an energy storage capacitor, a thyristor, a repulsion coil and a repulsion disc, and the moving end assembly comprises a moving contact, a moving contact seat and a transmission rod for driving the moving contact to move along the opening and closing direction. After the switch is powered on, the charger charges the energy storage capacitor and the buffer capacitor which are used for switching on and off, when the switch is switched on, the system receives a switch-on instruction, the thyristor which controls discharging is triggered, at the moment, the thyristor is conducted, current is discharged to the switch-on coil through the thyristor, at the moment, the repulsion plate generates a force moving in the opposite direction due to the eddy current effect, so that the repulsion plate is pushed to drive the transmission shaft to move, the switch-on motion is realized, and at the end stage of a stroke, due to the fact that the speed is too high, the buffer coil needs to be involved to conduct deceleration at the moment. When the system is in brake-off, the system receives a brake-off command to trigger a brake-off thyristor, the current of the brake-off coil generates vortex on the repulsion plate, and then generates repulsion force for pushing the repulsion plate to perform brake-off motion, and at the end of a stroke, the buffer coil is required to be involved to decelerate the repulsion plate, so that the impact on the bottom is reduced.

The existing quick switch is limited by small-stroke on-off, still has the principle defect that the existing quick switch cannot exceed large-stroke on-off, and limits the development of the quick switch to the direction of large opening distance. On the premise of ensuring rapid opening and closing, various rapid switches are continuously developed towards a large stroke and an effective buffering direction, so that the intervention of peripheral hydraulic mechanical buffering is reduced, the mechanical structure tends to be simpler, and the reliability is improved, which becomes the design idea of the rapid mechanical switch.

For example, the application publication No. CN111415830A discloses an electromagnetic repulsion operating mechanism and a switch using the same, wherein the electromagnetic repulsion operating mechanism includes a transmission pull rod for being in transmission connection with a switch moving contact, a repulsion disc (i.e., an induction disc) is fixedly disposed on the transmission pull rod, an opening coil and a closing coil are disposed at two axial sides of the repulsion disc, and at least one accelerating coil is disposed between the opening coil and the closing coil and surrounds the outer side of the repulsion disc to form a moving channel for the axial movement of the repulsion disc therein, and the accelerating coil is charged with current to provide axial electromagnetic force to the repulsion disc, thereby increasing the moving speed of the repulsion disc and further increasing the opening and closing speed of the fast mechanical switch.

The plurality of accelerating coils arranged in the electromagnetic repulsion operating mechanism provide a moving channel for the movement of the repulsion disc on one hand, and accelerate the opening and closing movement of the repulsion disc on the other hand, but in practical application, if the closing speed of the repulsion disc is too high, a great impact can be caused to the arc extinguish chamber, and if the opening speed is too high, a great impact can be caused to the operating mechanism body, so that the service lives of the operating mechanism and the arc extinguish chamber can be shortened. In addition, a plurality of accelerating coils are used for enclosing a moving channel, the moving precision requirement on the repulsive force disc is high, the repulsive force disc can not be in contact with the accelerating coils, and otherwise the accelerating coils can be damaged to cause serious faults.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an electromagnetic repulsion force quick mechanism which can reduce the brake opening and closing impact and prolong the service life of an operating mechanism and an arc extinguish chamber; an object of the utility model is to provide a can reduce divide-shut brake and strike, extension operating mechanism and explosion chamber life's quick mechanical switch.

In order to achieve the above object, the utility model provides an electromagnetic repulsion quick mechanism adopts following technical scheme:

electromagnetic repulsion quick-action mechanism includes:

the transmission rod is used for being in transmission connection with the moving contact in the arc extinguishing chamber;

the induction disc is fixed on the transmission rod;

the opening repulsion coil is arranged at one axial side of the induction disc;

the closing repulsion coil is arranged on the other axial side of the induction disc;

at least two electromagnetic coils which are arranged between the opening repulsion coil and the closing repulsion coil and are used for the induction disc and the transmission rod to pass through;

each electromagnetic coil is arranged along the axial of transfer line in proper order, and electromagnetic repulsion quick mechanism still includes:

the electromagnetic coil control circuits are provided with at least two electromagnetic coils which are connected with each electromagnetic coil in a one-to-one correspondence manner so as to control the electrification and the outage of the electromagnetic coils;

in the switching-on and switching-off process, at least one of the electromagnetic coils is an accelerating coil, the accelerating coil is electrified in the front half section through which the induction disc passes, and the rear half section is powered off, so that the induction disc moves under the accelerating force in the front half section through which the induction disc passes, and moves by means of inertia in the rear half section;

in the switching-on and switching-off process, at least one of the electromagnetic coils is a speed reduction coil, the speed reduction coil is powered off in the first half section through which the induction disc passes, and the speed reduction coil is powered on in the second half section, so that the induction disc moves through the first half section of the speed reduction coil by means of inertia, and the induction disc moves through the second half section of the speed reduction coil by means of speed reduction force.

The beneficial effects of the above technical scheme are that: by utilizing the principle of the electromagnetic coil cannon, when the induction disc passes through the electromagnetic coil, if the electromagnetic coil is electrified all the time, the front half section can generate accelerating force to the induction disc, the rear half section can generate resistance to the induction disc, therefore, the utility model is provided with an electromagnetic coil control circuit, can control the time of electrifying and powering off the electromagnetic coil, so that the electromagnetic coil is electrified in the first half section and powered off in the second half section of the induction disc to become an accelerating coil, the electromagnetic coil is powered off in the first half section and powered on in the second half section through the induction disc to form a speed reducing coil, therefore, in the process of opening and closing, the induction disc is accelerated by the accelerating coil, the integral opening and closing time is shortened, meanwhile, the induction disc is decelerated by the deceleration coil at the later stage of switching on and off, so that the phenomenon that the arc extinguish chamber or the operating mechanism body is impacted due to overlarge speed is avoided, and the service lives of the operating mechanism and the arc extinguish chamber are prolonged.

Furthermore, in order to facilitate the movement of the induction disc and the arrangement of the electromagnetic coils, the electromagnetic repulsion rapid mechanism further comprises a cylinder body fixedly connected with the arc extinguish chamber, the transmission rod and the induction disc are arranged in the cylinder body, the induction disc is movably matched with the inner wall of the cylinder body in a guiding manner, and each electromagnetic coil is sleeved outside the cylinder body.

Furthermore, in order to facilitate the arrangement of the opening repulsive coil and the closing repulsive coil, the opening repulsive coil and the closing repulsive coil are respectively positioned at two ends in the cylinder body.

Furthermore, in order to facilitate arrangement and simplify the structure, the induction disc is fixed at one end of the transmission rod, and the other end of the transmission rod penetrates through the opening repulsion coil.

Furthermore, in order to improve the deceleration control effect, the electromagnetic repulsion quick mechanism also comprises an opening coil control circuit which is connected with the opening repulsion coil to control the opening and the disconnection of the opening repulsion coil, and the electromagnetic repulsion quick mechanism also comprises a closing coil control circuit which is connected with the closing repulsion coil to control the opening and the disconnection of the closing repulsion coil; in the closing process, a closing repulsion coil and an accelerating coil are electrified in the early stage of the motion of the induction disc to accelerate the induction disc, and a decelerating coil and a separating repulsion coil are electrified in the later stage of the motion of the induction disc to decelerate the induction disc; in the process of opening the brake, the opening repulsion coil and the accelerating coil are electrified in the early stage of the motion of the induction disc so as to accelerate the induction disc, and the decelerating coil and the closing repulsion coil are electrified in the later stage of the motion of the induction disc so as to decelerate the induction disc.

Furthermore, in order to facilitate the control of the energization and the de-energization of the coil, the opening coil control circuit and the closing coil control circuit respectively comprise an energy storage capacitor and a thyristor.

Furthermore, in order to conveniently control the energization and the de-energization of the coil, the electromagnetic coil control circuit comprises an energy storage capacitor and a thyristor.

Furthermore, in order to improve the acceleration effect and optimize the power-on time, at least two acceleration coils are arranged, each acceleration coil comprises an initial acceleration coil for the induction disc to pass through firstly and a subsequent acceleration coil for the induction disc to pass through later, and the subsequent acceleration coils are powered on when the induction disc is about to leave the initial acceleration coils.

In order to achieve the above object, the utility model provides a quick mechanical switch adopts following technical scheme:

quick mechanical switch, including explosion chamber and the moving contact of setting in the explosion chamber, quick mechanical switch still includes electromagnetic repulsion quick-operation mechanism, and electromagnetic repulsion quick-operation mechanism includes:

the transmission rod is in transmission connection with the moving contact;

the induction disc is fixed on the transmission rod;

the opening repulsion coil is arranged at one axial side of the induction disc;

Drawings

Fig. 1 is a perspective view of a medium-speed mechanical switch according to the present invention;

FIG. 2 is a structural diagram of the medium-speed mechanical switch of the present invention in the open state;

fig. 3 is a structural diagram of the fast mechanical switch in the acceleration process of closing (the first electromagnetic coil starts to be powered off) in the present invention;

fig. 4 is a structural diagram of the fast mechanical switch in the acceleration process of closing (the second electromagnetic coil starts to be energized) in the present invention;

fig. 5 is a structural diagram of the middle-speed mechanical switch of the present invention during the acceleration process of closing (the second electromagnetic coil starts to be powered off);

fig. 6 is a structural diagram of the middle-speed mechanical switch of the present invention in the process of closing and decelerating (the third electromagnetic coil starts to be energized);

fig. 7 is a structural diagram of the middle-speed mechanical switch of the present invention during the closing deceleration process (the fourth electromagnetic coil and the opening repulsion coil start to be energized);

fig. 8 is a structural diagram of the middle-speed mechanical switch of the present invention in a closing state;

FIG. 9 is a structural diagram of the middle speed mechanical switch of the present invention during the brake-off acceleration process (the fourth electromagnetic coil starts to be powered off);

FIG. 10 is a structural diagram of the middle speed mechanical switch of the present invention during the opening acceleration process (the third electromagnetic coil is turned on);

FIG. 11 is a structural diagram of the middle speed mechanical switch of the present invention during the brake-off acceleration process (the third electromagnetic coil starts to be powered off);

fig. 12 is a structural diagram of the middle speed mechanical switch of the present invention during the opening deceleration process (the second electromagnetic coil starts to be energized);

fig. 13 is a structural diagram of the middle-speed mechanical switch of the present invention during the opening and deceleration processes (the first electromagnetic coil and the closing repulsion coil start to be energized);

in the figure: 1-a first electromagnetic coil; 2-a second electromagnetic coil; 3-a third electromagnetic coil; 4-a fourth electromagnetic coil; 5-opening repulsion coil; 6-a first solenoid control circuit; 7-a second solenoid control circuit; 8-a third solenoid control circuit; 9-a fourth solenoid control circuit; 10-a switching-off coil control circuit; 11-a switching-on coil control circuit; 12-closing repulsion coil; 13-a transmission rod; 14-a cylinder body; 15-a sensing plate; 16-arc extinguishing chamber.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention, i.e., the described embodiments are only some, but not all embodiments of the invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiment of the present invention, all other embodiments obtained by the person skilled in the art without creative work belong to the protection scope of the present invention.

It is noted that relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The features and properties of the present invention are described in further detail below with reference to examples.

The utility model discloses an embodiment of well quick mechanical switch is shown in fig. 1 and 2, including explosion chamber 16 and the moving contact (not shown in the figure) of setting in explosion chamber 16, quick mechanical switch still includes electromagnetism repulsion quick-operation mechanism, and electromagnetism repulsion quick-operation mechanism includes barrel 14, transfer line 13, response dish 15, separating brake repulsion coil 5, combined floodgate repulsion coil 12, first solenoid 1, second solenoid 2, third solenoid 3, fourth solenoid 4.

The induction disc 15 is fixed at one end of the transmission rod 13, and the other end of the transmission rod 13 penetrates through the opening repulsion coil 5 to be in transmission connection with the moving contact in the arc extinguish chamber 16. One end of the cylinder 14 is fixedly connected with the arc extinguish chamber 16, the transmission rod 13 and the induction disc 15 are both arranged in the cylinder 14, and the induction disc 15 is matched with the inner wall of the cylinder 14 in a guiding and moving manner. The opening repulsion coil 5 and the closing repulsion coil 12 are respectively located at two ends of the cylinder 14 (namely, respectively arranged at two axial sides of the induction disc 15), the first electromagnetic coil 1, the second electromagnetic coil 2, the third electromagnetic coil 3 and the fourth electromagnetic coil 4 are arranged between the opening repulsion coil 5 and the closing repulsion coil 12, and the four electromagnetic coils are all sleeved and fixed outside the cylinder 14, so that the induction disc 15 and the transmission rod 13 penetrate through inner holes of the four electromagnetic coils.

The solenoids are arranged at intervals in the axial direction of the transmission rod 13, that is, in the axial direction of the cylinder 14. The electromagnetic repulsion quick mechanism also comprises four electromagnetic coil control circuits, each electromagnetic coil control circuit is connected with each electromagnetic coil in a one-to-one correspondence manner so as to control the electrification and the power failure of the electromagnetic coils, and the four electromagnetic coil control circuits are respectively as follows: the electromagnetic control device comprises a first electromagnetic coil control circuit 6 connected with a first electromagnetic coil 1, a second electromagnetic coil control circuit 7 connected with a second electromagnetic coil 2, a third electromagnetic coil control circuit 8 connected with a third electromagnetic coil 3, and a fourth electromagnetic coil control circuit 9 connected with a fourth electromagnetic coil 4, wherein each electromagnetic coil control circuit comprises an energy storage capacitor and a thyristor.

The electromagnetic repulsion quick mechanism further comprises an opening coil control circuit 10 which is connected with the opening repulsion coil 5 to control the opening repulsion coil 5 to be electrified and cut off, the electromagnetic repulsion quick mechanism further comprises a closing coil control circuit 11 which is connected with the closing repulsion coil 12 to control the closing repulsion coil 12 to be electrified and cut off, and the opening coil control circuit 10 and the closing coil control circuit 11 both comprise energy storage capacitors and thyristors.

In addition, the electromagnetic repulsion fast mechanism further comprises a controller (not shown in the figure) respectively connected with the capacitor in each electromagnetic coil and the capacitors in the opening coil control circuit 10 and the closing coil control circuit 11 in a control manner, and the electromagnetic repulsion fast mechanism further comprises a position sensor for detecting the motion position of the induction disc 15, and the position sensor is also connected with the controller to feed back the detection signal to the controller.

As shown in fig. 2, when the fast mechanical switch is in an open state, in a closing acceleration stress mode, the controller controls the capacitances of the closing repulsion coil 12, the first electromagnetic coil 1 and the second electromagnetic coil 2 to sequentially discharge, and in a closing deceleration stress mode, the controller controls the capacitances of the third electromagnetic coil 3, the fourth electromagnetic coil 4 and the opening repulsion coil 5 to sequentially discharge.

The specific control logic is as follows: after receiving a closing command, the controller controls the closing repulsion coil 12 and the capacitance of the first electromagnetic coil 1 to trigger discharge, and the repulsion force generated by the closing repulsion coil 12 and the electromagnetic attraction force generated by the first electromagnetic coil 1 on the induction disc 15 at the moment drive the induction disc 15 to move forward in an accelerated manner. As shown in fig. 3, when the sensing plate 15 moves to 1/2 of the width of the first electromagnetic coil 1, in order to ensure that the sensing plate 15 is not decelerated by the electromagnetic attraction force of the first electromagnetic coil 1 in the opposite direction, the capacitance of the first electromagnetic coil 1 needs to be discharged at the position 1/2 where the head end of the sensing plate 15 moves to the first electromagnetic coil 1, and then the sensing plate 15 moves forward by inertia.

As shown in fig. 4, when the head end of the sensing plate moves to the tail end of the first electromagnetic coil 1 in the moving direction, that is, when the sensing plate 15 will leave the first electromagnetic coil 1, the thyristor of the energy storage capacitor of the second electromagnetic coil 2 is turned on to discharge, the sensing plate 15 is attracted again at this time to accelerate to move in the closing direction, similarly to the first electromagnetic coil 1, when the head end of the sensing plate moves to 1/2 of the second electromagnetic coil 2, as shown in fig. 5, the energy storage capacitor of the second electromagnetic coil 2 has been discharged, and thereafter the sensing plate 15 moves forward by inertia.

After the second electromagnetic coil 2 is moved out, the deceleration state is performed, as shown in fig. 6, the capacitance of the third electromagnetic coil 3 is discharged by the controller when the head end of the inductive disk moves to the 1/2 position of the third electromagnetic coil 3, at this time, the force generated by the third electromagnetic coil 3 on the inductive disk 15 will hinder the forward movement of the inductive disk 15, and the whole mechanism starts to decelerate. Similarly, when the third electromagnetic coil 3 moves to the 1/2 position of the fourth electromagnetic coil 4, as shown in fig. 7, the energy storage capacitors of the coil and the opening repulsion coil 5 are both discharged, and the deceleration force is continuously provided for the mechanism. The capacitance and the charging voltage which provide buffering in the motion process can be changed, the speed of the capacitor moving to the terminal point is guaranteed to be small, and the impact on a subsequent arc extinguish chamber is reduced.

As shown in fig. 8, when the fast mechanical switch is in a closing completion state, in a closing acceleration stress mode, the controller controls the capacitances of the closing repulsion coil 5, the fourth electromagnetic coil 4, and the third electromagnetic coil 3 to sequentially discharge in a sequence, and in a closing deceleration stress mode, the controller controls the capacitances of the second electromagnetic coil 2, the first electromagnetic coil 1, and the closing repulsion coil 12 to sequentially discharge in a sequence.

The specific control logic is as follows: after receiving the opening command, the thyristor of the energy storage capacitor of the opening repulsion coil 5 is turned on and discharges through the opening repulsion coil 5, and at the same time, the thyristor of the energy storage capacitor of the fourth electromagnetic coil 4 is turned on and discharges through the fourth electromagnetic coil 4, the opening repulsion coil 5 generates an eddy current on the induction disc 15 to form a thrust force to the induction disc 15, and at the same time, the fourth electromagnetic coil 4 generates an electromagnetic attraction force to the induction disc 15 to jointly drive the induction disc 15 to move in an accelerated manner (i.e., move in an accelerated manner backwards) along the opening direction, as shown in fig. 9, when the induction disc 15 moves to the position 1/2 of the fourth electromagnetic coil 4, the energy storage capacitor of the fourth electromagnetic coil 4 finishes discharging, and at this time, the induction disc 15 continues to move backwards through inertia.

As shown in fig. 10, when the head end of the inductive disk 15 goes out of the fourth electromagnetic coil 4, that is, when the inductive disk 15 is about to leave the fourth electromagnetic coil 4, the thyristor of the energy storage capacitor of the third electromagnetic coil 3 is turned on, and the capacitor starts to discharge to continuously generate an electromagnetic attraction force to drive the inductive disk 15 to accelerate the opening movement.

As shown in fig. 11, when the sensing plate 15 moves to the 1/2 position of the third electromagnetic coil 3, the energy storage capacitor of the third electromagnetic coil 3 is discharged. After the third electromagnetic coil 3 is completely moved out, as shown in fig. 12, when the inductive disc 15 moves to the 1/2 position of the second electromagnetic coil 2 by inertia, the energy storage capacitor of the second electromagnetic coil 2 starts to discharge at this time, the generated electromagnetic attraction becomes resistance to the backward movement of the inductive disc 15, and at this time, the mechanism driven by the inductive disc 15 will decelerate.

As shown in fig. 13, when the sensing disc 15 moves to 1/2 of the first electromagnetic coil 1, the capacitor of the first electromagnetic coil 1 discharges, and continues to generate a force for hindering the movement to the sensing disc 15, and at the same time, the thyristor of the energy storage capacitor of the closing repulsion coil 12 also triggers and conducts a repulsion force generated as a deceleration of the mechanism, and the two forces act together to continue to decelerate the mechanism driven by the sensing disc 15.

To sum up, the utility model discloses utilized the principle of solenoid big gun, when the response dish passes through solenoid, if solenoid is circular telegram all the time, then the first half section can produce acceleration force to the response dish, the latter half section can produce the resistance to the response dish, consequently the utility model discloses set up four solenoid and set up corresponding solenoid control circuit respectively, control the circular telegram of each solenoid and outage opportunity, make solenoid pass through at the response dish first half section circular telegram, the latter half section outage become accelerating coil, the response dish is received acceleration force and is removed, relies on inertia to remove at the latter half section through accelerating coil first half section; the electromagnetic coil is powered off in the first half section and powered on in the second half section of the induction disc to form a speed reducing coil, and the induction disc moves through the speed reducing coil in the first half section by means of inertia and moves under the speed reducing force in the second half section.

For example, in the closing process, the first electromagnetic coil 1 and the second electromagnetic coil 2 are used as accelerating coils in the electromagnetic coils, the coils are electrified through the discharging of a capacitor, the coils are powered off through the discharging of the capacitor, the induction disc is accelerated through controlling the time of the electrification and the power-off, and under the combined action of the closing repulsion coil 12 and the electromagnetic coils, the initial speed is improved for a switch with large motion quality, and even the time of the whole closing stroke is shortened. And, the first electromagnetic coil 1 forms a first acceleration coil through which the induction disc passes first, and the second electromagnetic coil 2 forms a second acceleration coil through which the induction disc passes later, the second acceleration coil being energized when the induction disc is about to leave the first acceleration coil.

In the closing process, the third electromagnetic coil 3 and the fourth electromagnetic coil 4 are used as the speed reduction coils in the electromagnetic coils, the coils are powered on through the discharging of the capacitor, the coils are powered off through the discharging of the capacitor, the speed of the induction disc is reduced through controlling the power-on and power-off time, and in addition, the repulsion effect of the brake-off repulsion coil 5 is used for realizing the effective speed reduction at the terminal point, so that the impact on the arc extinguish chamber caused by overlarge speed is avoided, and the service life of the arc extinguish chamber is prolonged.

The brake separating process is the same as the above, the third electromagnetic coil 3 and the fourth electromagnetic coil 4 are used as accelerating coils in the electromagnetic coils in the brake separating process, the first electromagnetic coil 1 and the second electromagnetic coil 2 are used as decelerating coils in the electromagnetic coils, and the deceleration in the brake separating process is to avoid the impact on the operating mechanism body caused by overlarge speed and prolong the service life of the operating mechanism. In a word, the repulsion force generated by the repulsion coil is combined with the ampere force of the electromagnetic coil to provide the force for accelerating for the mechanism at the initial stage in the whole movement process, the electromagnetic coil is adopted for accelerating at the middle stage, and the buffer scheme combining the electromagnetic coil and the repulsion coil is adopted at the final stage, so that the characteristics of short opening and closing time, high acceleration and high speed reduction in the whole large-opening-distance stroke are ensured.

And because the acceleration and deceleration coils can be used in a multi-stage superposition mode according to actual conditions, the multi-stage superposition type high-speed switching device can adapt to switches with different opening distances and can quickly switch on and switch off, the switching-on and switching-off time of a large-range switch can be greatly reduced, the impact time of fault current on a power grid is reduced, and a foundation is laid for the stable operation of the whole power grid.

In other embodiments of the rapid mechanical switch, the solenoids may also be located next to each other.

In other embodiments of the fast mechanical switch, when there are multiple accelerating coils, the post-accelerating coil may also be re-energized when the inductive disk is about to enter the post-accelerating coil.

In other embodiments of the fast mechanical switch, only one accelerating coil may be provided, and only one decelerating coil may be provided, that is, two electromagnetic coils are provided, in the opening and closing process, one is responsible for accelerating and the other is responsible for decelerating.

In other embodiments of the fast mechanical switch, the solenoid control circuit may also include a power supply and a switch, and the controller controls the switch to be turned on and off, and of course, the opening coil control circuit and the closing coil control circuit may also respectively include a power supply and a switch, and the controller controls the switch to be turned on and off.

In other embodiments of the fast mechanical switch, during the closing deceleration process, the deceleration can be performed only by the deceleration coil in the electromagnetic coil, and the opening repulsion coil does not participate in the action.

In other embodiments of the fast mechanical switch, the end of the transmission rod may also pass through the sensing disk.

In other embodiments of the fast mechanical switch, the opening repulsion coil and the closing repulsion coil can be located outside the cylinder or inside the cylinder.

In other embodiments of the fast mechanical switch, the electromagnetic repulsion fast mechanism may not include a cylinder, and since the transmission rod is in transmission connection with the moving contact in the arc extinguishing chamber, the transmission rod and the induction disc can be ensured to move stably to some extent.

The utility model discloses the embodiment of well electromagnetic repulsion quick-operation mechanism does: the specific structure of the electromagnetic repulsion fast mechanism is the same as that of the electromagnetic repulsion fast mechanism in the above fast mechanical switch embodiment, and will not be repeated here.

The above description is only for the preferred embodiment of the present invention, and the present invention is not limited thereto, the protection scope of the present invention is defined by the claims, and all structural changes equivalent to the contents of the description and drawings of the present invention should be included in the protection scope of the present invention.

Claims

1. Electromagnetic repulsion quick-action mechanism includes:

the induction disc is fixed on the transmission rod;

the opening repulsion coil is arranged at one axial side of the induction disc;

it is characterized in that each electromagnetic coil is arranged along the axial direction of the transmission rod in sequence, and the electromagnetic repulsion quick mechanism further comprises:

2. The electromagnetic repulsion rapid mechanism according to claim 1, characterized in that the electromagnetic repulsion rapid mechanism further comprises a cylinder body fixedly connected with the arc extinguish chamber, the transmission rod and the induction disc are both arranged in the cylinder body, the induction disc is movably matched with the inner wall of the cylinder body in a guiding manner, and each electromagnetic coil is sleeved outside the cylinder body.

3. The electromagnetic repulsion fast mechanism of claim 2, characterized in that the opening repulsion coil and the closing repulsion coil are respectively located at two ends of the cylinder.

4. An electromagnetic repulsion rapid mechanism according to any one of claims 1 to 3, characterized in that the induction disc is fixed at one end of the transmission rod, and the other end of the transmission rod passes through the opening repulsion coil.

5. The electromagnetic repulsion rapid mechanism according to any one of claims 1 to 3, characterized in that the electromagnetic repulsion rapid mechanism further comprises a switching-off coil control circuit connected with the switching-off repulsion coil to control the switching-on and switching-off of the switching-off repulsion coil, and further comprises a switching-on coil control circuit connected with the switching-on repulsion coil to control the switching-on and switching-off of the switching-on repulsion coil; in the closing process, a closing repulsion coil and an accelerating coil are electrified in the early stage of the motion of the induction disc to accelerate the induction disc, and a decelerating coil and a separating repulsion coil are electrified in the later stage of the motion of the induction disc to decelerate the induction disc; in the process of opening the brake, the opening repulsion coil and the accelerating coil are electrified in the early stage of the motion of the induction disc so as to accelerate the induction disc, and the decelerating coil and the closing repulsion coil are electrified in the later stage of the motion of the induction disc so as to decelerate the induction disc.

6. The electromagnetic repulsion fast mechanism of claim 5, wherein said opening coil control circuit and closing coil control circuit respectively comprise an energy storage capacitor and a thyristor.

7. An electromagnetic repulsion rapid mechanism according to any one of claims 1 to 3, characterized in that the electromagnetic coil control circuit comprises an energy storage capacitor and a thyristor.

8. An electromagnetic repulsion rapid mechanism according to any of claims 1 to 3, characterized in that there are at least two accelerating coils, the accelerating coils include a first accelerating coil for the induction disk to pass through first and a second accelerating coil for the induction disk to pass through second, and the second accelerating coil is energized when the induction disk is about to leave the first accelerating coil.

9. The rapid mechanical switch comprises an arc extinguish chamber and a movable contact arranged in the arc extinguish chamber, and is characterized by further comprising the electromagnetic repulsion rapid mechanism as claimed in any one of claims 1 to 8.