CN113257595A - Switching mechanism applied to dual-power automatic transfer switch - Google Patents

Abstract

The invention provides a switching mechanism applied to a dual-power automatic transfer switch, which comprises a face mask and a sliding cover, wherein the sliding cover is assembled on the outer surface of the face mask in a sliding way and can be switched among a double-branch padlock position, an automatic position and a manual position in a reciprocating way; the face mask is provided with a micro switch mechanism for connecting or disconnecting a switch control loop, when the sliding cover is positioned at an automatic position, the micro switch mechanism is not influenced by external force, the micro switch is in a normally closed state, and when the sliding cover is switched from the automatic position to a manual position or from the automatic position to a double-branch padlock position, the sliding cover drives the reset trigger assembly to trigger the micro switch to be disconnected; meanwhile, the face mask is also movably connected with two cover plates which are respectively linked with the two operating mechanisms, and the closing of the switch can drive the cover plates to block the path from the automatic position to the position of the double-division padlock; the separating brake of the switch can drive the cover plate to give way to the pressure rod. The switching mechanism has the characteristics of simple structure and ingenious design; meanwhile, the operation is simple and quick.

Description

Switching mechanism applied to dual-power automatic transfer switch

Technical Field

The invention relates to the field of low-voltage electrical switches, in particular to a switching mechanism applied to a dual-power automatic transfer switch.

Background

The dual-power automatic transfer switch is used for simply connecting two power supplies, one power supply is usually used for standby, and when the common power fails suddenly or is powered off, the dual-power automatic transfer switch is automatically switched into the standby power supply to enable equipment to still normally operate. The most common is elevator, fire control and monitoring. Most factories or units with one type of load and two types of load exist.

The dual-power automatic transfer switch generally has three operation modes, namely automatic operation, manual operation and double-branch padlock operation which are controlled by a controller; in the prior art, the switching mechanism of the three operation modes is complex, and the operation is also complex. Further improvements are needed.

Disclosure of Invention

Therefore, the invention provides a switching mechanism applied to a dual-power automatic transfer switch, which can effectively improve the problems.

In order to achieve the purpose, the technical scheme provided by the invention is as follows:

a switching mechanism applied to a dual-power automatic transfer switch comprises a face mask and a sliding cover, wherein the sliding cover is assembled on the outer surface of the face mask in a sliding mode and can be switched among a double-division padlock position, an automatic position and a manual position in a reciprocating mode; the sliding cover is also provided with a guide rod and a pressure rod which are arranged in the mask in a penetrating way; the mask is provided with a micro switch mechanism for connecting or disconnecting a switch control loop, the micro switch mechanism comprises a micro switch and a reset trigger assembly for triggering the switching state of the micro switch, and the reset trigger assembly is provided with an abutting joint part positioned on a pressure lever path and an abutting tail part positioned on a guide rod path; when the sliding cover is positioned at the automatic position, the micro switch mechanism is not influenced by external force, and the micro switch is in a normally closed state; when the sliding cover is switched from the automatic position to the double-branch padlock position, the reset trigger assembly is driven to trigger the micro switch to be disconnected through the matching of the guide rod and the abutting tail part; the mask is also movably connected with two cover plates which are respectively linked with the two operating mechanisms, and the closing of the switch can drive the cover plates to block the path from the automatic position to the position of the double-branch padlock; the separating brake of the switch can drive the cover plate to give way to the pressure rod.

Further, the microswitch is a normally closed microswitch; and the reset trigger component is separated from the microswitch under the action of no external force so that the microswitch is in a normally closed state, and when the sliding cover is switched from the automatic position to the manual position or from the automatic position to the double-branch padlock position, the reset trigger component contacts the microswitch to trigger the microswitch to be disconnected.

Furthermore, the reset triggering assembly comprises a turntable and a reset torsion spring, the turntable is rotatably arranged on the inner surface of the outer cover, the abutting head part and the abutting tail part are formed by integrally extending the turntable, and the abutting head part also corresponds to the microswitch; when the sliding cover is switched from the automatic position to the manual position, the pressing rod abuts against the abutting joint part and drives the turntable to rotate until the abutting joint part abuts against the microswitch so as to trigger the microswitch to be switched off; when the sliding cover is switched to the double-branch padlock position from the automatic position, the abutting tail part is driven to move through the guide rod, and then the rotary table is driven to rotate until the abutting head part abuts against and presses the micro switch, so that the micro switch is triggered to be disconnected.

Further, a handle operation hole penetrating through the inner surface and the outer surface is formed in the face shield; the handle operation hole is covered by a sliding cover, and the handle operation hole can be exposed only when the sliding cover is switched from an automatic position to a manual position.

Furthermore, the number of the handle operation holes is two, and the handle operation holes correspond to the common side and the standby side respectively; the two cover plates are respectively arranged on the two handle operation holes in a sliding way to shield the handle operation holes.

Further, a handle placing groove for placing a handle is formed in the outer surface of the mask in a recessed mode, and the handle placing groove can be exposed when the sliding cover is switched from the automatic position to the manual position.

Furthermore, a guide limit groove penetrating through the inner surface and the outer surface is formed in the face mask; the guide rod is inserted into the guide limiting groove to form guide fit, the tail end of the guide rod extends into the mask, and a thick gasket with the diameter larger than the groove width of the guide limiting groove is fixed on the guide rod.

Furthermore, a positioning structure is arranged between the face mask and the sliding cover, and when the sliding cover slides to the position of the double-split padlock, the automatic position or the manual position, the positioning and the fixing are realized through the positioning structure.

Furthermore, the face guard and the sliding cover are both provided with locking holes, and when the sliding cover slides to the position of the double-split padlock, the two locking holes correspond to each other.

Furthermore, a marking structure for marking the position is arranged on the face mask, an indicating arrow is arranged on the sliding cover, and when the sliding cover slides to the position of the double-division padlock, the automatic position or the manual position, the indicating arrow corresponds to the marking structure for marking the arrival position.

Through the technical scheme provided by the invention, the method has the following beneficial effects:

when the sliding cover is in an automatic position, the microswitch is in a normally closed state, and a control loop of the switch is switched on to realize automatic control switching; when the sliding cover slides from the automatic position to the manual position, the reset trigger assembly is driven by the matching of the pressing rod and the abutting joint part to trigger the micro switch to be switched off, a control loop of the switch is switched off, the controller cannot realize automatic operation, and manual control can be carried out at the moment; when the sliding cover needs to be switched to the double-branch padlock position from the automatic position, the cover plate can give way to the pressure lever only under the condition that the two operating mechanisms are in the opening state, at the moment, the sliding cover can be switched to the double-branch padlock position, in the switching process, the reset trigger assembly is driven to be reset through the matching of the guide rod and the abutting tail part to trigger the micro switch to be disconnected, at the moment, a control loop of the switch is disconnected, and the controller cannot realize automatic operation; therefore, the maintenance safety under the position of the double-branch padlock can be well guaranteed.

The switching mechanism has the characteristics of simple structure and ingenious design; meanwhile, the operation is simple and quick; only the sliding cover is required to be shifted to slide and switch among three positions.

Drawings

FIG. 1 is an exploded view of a switching mechanism for use in an embodiment of a dual power automatic transfer switch;

FIG. 2 is a schematic view showing the surface structure of the mask in the embodiment;

FIG. 3 is a front view of the surface structure of the mask in the embodiment;

FIG. 4 is a schematic view showing the internal structure of the mask in the embodiment;

FIG. 5 is a schematic perspective view of an embodiment of a sliding cover;

FIG. 6 is a schematic perspective view of the slider at another angle in the embodiment;

FIG. 7 is a schematic diagram of an embodiment of a dual power automatic transfer switch configured to switch to an automatic position;

FIG. 8 is a front view of FIG. 7;

FIG. 9 is a schematic diagram of an internal fitting structure of the dual power automatic transfer switch in the embodiment in a dual-split state when the dual power automatic transfer switch is switched to an automatic position;

FIG. 10 is a front view of FIG. 9;

FIG. 11 is a schematic diagram of an internal mating structure of the dual power automatic transfer switch in the embodiment when the dual power automatic transfer switch is switched to an automatic position and one of the power sources is switched on;

FIG. 12 is a front view of FIG. 11;

FIG. 13 is a schematic external view of the dual power automatic transfer switch of the embodiment shown in the manual position;

FIG. 14 is a front view of FIG. 13;

FIG. 15 is a schematic diagram of an internal mating structure of the dual power automatic transfer switch in the embodiment when switched to the manual position;

FIG. 16 is a front view of FIG. 15;

FIG. 17 is a schematic diagram of the dual power automatic transfer switch of the embodiment shown in an external view when the dual power automatic transfer switch is switched to a dual padlock position;

FIG. 18 is a front view of FIG. 13;

FIG. 19 is a schematic diagram of an internal mating structure of the dual power automatic transfer switch of the embodiment when the dual power automatic transfer switch is switched to the dual split padlock position;

fig. 20 is a front view of fig. 19.

Detailed Description

To further illustrate the various embodiments, the invention provides the accompanying drawings. The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the embodiments. Those skilled in the art will appreciate still other possible embodiments and advantages of the present invention with reference to these figures. Elements in the figures are not drawn to scale and like reference numerals are generally used to indicate like elements.

The invention will now be further described with reference to the accompanying drawings and detailed description.

Referring to fig. 1 to 20, the switching mechanism applied to the dual power automatic transfer switch provided in this embodiment includes a face mask 1 and a sliding cover 2, and in order to achieve insulation and convenient preparation, the material of the face mask 1 is preferably plastic, and the face mask may be integrally formed by injection molding or the like.

The sliding cover 2 is slidably assembled on the outer surface of the face mask 1 and can be switched back and forth between a double-split padlock position (shown in figures 17 and 18), an automatic position (shown in figures 7 and 8) and a manual position (shown in figures 13 and 14); the sliding cover 2 is also provided with a guide rod 21 and a pressure rod 22 which are arranged in the face mask 1 in a penetrating way.

The mask 1 is equipped with a micro switch mechanism for connecting or disconnecting the switch control loop, the micro switch mechanism comprises a micro switch 3 and a reset trigger component for triggering the switching state of the micro switch 3, namely the micro switch 3 is connected in series on the switch control loop, the on/off of the switch control loop is realized through the on/off of the micro switch 3, and the electric control and manual control switching of the switch body is further realized.

Specifically, the reset trigger assembly is provided with an abutting head part 41 positioned on a path of the pressure rod 22 and an abutting tail part 42 positioned on a path of the guide rod 21; when the sliding cover 2 is located at the automatic position, the micro switch mechanism is not affected by external force, and the micro switch 3 is in a normally closed state, when the sliding cover 2 is switched from the automatic position to the manual position, the reset trigger component is driven to trigger the micro switch 3 to be disconnected through the cooperation of the pressure lever 22 and the abutting head 41; the switch control loop is cut off, the switch can not realize electric control, and manual control can be carried out at the moment.

The mask 1 is also movably connected with two cover plates 6 which are respectively linked with the two operating mechanisms, and the closing of the switch can drive the cover plates 6 to block the path from the automatic position to the position of the double-division padlock; the opening of the switch can drive the cover plate 6 to give way to the pressure rod 22.

When the sliding cover 2 needs to be switched from the automatic position to the double-split padlock position, both the two operating mechanisms need to be switched to the opening state, and thus, both the two cover plates 6 give way to the pressing rod (as shown in fig. 9 and 10). If only one of the operating mechanisms is open and the other is closed as shown in fig. 11 and 12, the cover 6 linked to the closed switch is also in the blocking position so that the pressing lever 22 cannot move from the automatic position to the double-split padlock position.

After the two cover plates 6 are abducted, the reset trigger component is driven to trigger the micro switch 3 to be disconnected by the matching of the guide rod 21 and the abutting tail part 42, so that a control loop is cut off; the position is locked subsequently, so that the opening and manual control states of the switch are kept, and the maintenance safety in the position of the double-branch padlock can be well guaranteed.

The switching mechanism has the characteristics of simple structure and ingenious design; meanwhile, the operation is simple and quick; only the sliding cover is required to be shifted to slide and switch among three positions.

Further, as a preferable implementation structure of the micro switch mechanism, in this embodiment, the micro switch 3 is a normally closed micro switch; and the reset trigger component is separated from the microswitch 3 under no external force action (namely, automatic position) so that the microswitch 3 is in a normally closed state, and when the sliding cover 2 is switched from the automatic position to the manual position or from the automatic position to the double-branch padlock position, the reset trigger component contacts the microswitch 3 to trigger the microswitch 3 to be disconnected.

More specifically, the subassembly that triggers resets includes carousel 4 and the reset torsion spring 5 of connecting carousel 4, carousel 4 is rotatable to be set up in the internal surface of dustcoat 1, butt joint head 41 and butt afterbody 42 form by 4 integrative extensions of carousel, and butt head 41 still corresponds micro-gap switch 3. When the slide cover 2 is switched from the automatic position to the manual position, the pressing rod 22 abuts against the abutting head 41 and drives the turntable to rotate until the abutting head 41 abuts against the microswitch 3 to trigger the microswitch 3 to be switched off (for example, the position of the pressing rod 22 in fig. 10 moves rightwards to reach the position in fig. 16); similarly, when the manual position is switched back to the automatic position, the contact head 41 loses contact with the plunger 22, and the dial 4 is returned by the elastic force of the return torsion spring 5 (as shown in fig. 16, the position of the plunger 22 moves leftward to reach the position of fig. 10). When the sliding cover 2 is switched from the automatic position to the double-split padlock position, the guide rod 21 abuts against the abutting tail part 42 and drives the rotary table 4 to rotate until the abutting head part 41 abuts against the micro switch 3 to trigger the micro switch 3 to be disconnected (for example, the position of the pressing rod 22 in fig. 10 moves leftwards to reach the position in fig. 20); similarly, when the position of the double-split padlock is switched back to the automatic position, the abutting tail part 42 loses the abutting of the pressure rod 21, and the rotary disc 4 is reset under the elastic action of the reset torsion spring 5. So set up, simple structure, the action is smooth and easy.

More specifically, the inner surface of the face shield 1 is further provided with a boss 19 protruding for limiting the rotation range of the rotary disc 4, so that the reset starting position of the rotary disc 4 and the working position when contacting the micro switch 3 can be well limited, and abnormal actions caused by excessive movement can be prevented.

Of course, in other embodiments, the structure of the reset triggering component is not limited to this, for example, the reset torsion spring 5 may be replaced by another elastic component capable of resetting the rotating disc; or, the micro switch 3 may also be a normally open micro switch, so that in order to ensure that the micro switch 3 in the micro switch mechanism keeps a normally closed state when the sliding cover 2 is located at the automatic position, the state of triggering needs to be kept through the resetting triggering component. Under the action of no external force at the automatic position, the reset trigger component of the microswitch mechanism always contacts the microswitch 3 to trigger the normally open microswitch to keep the normally closed state; when the sliding cover 2 is switched from the automatic position to the manual position or from the automatic position to the double-split padlock position, the reset trigger assembly is driven to be separated from the microswitch 3 to trigger the microswitch 3 to be disconnected.

The face mask 1 is provided with a guide limiting groove 11 penetrating through the inner surface and the outer surface; the guide rod 21 is inserted into the guide limiting groove 11 to form guide fit, so that the sliding cover 2 can slide in a guide manner, the structure is simple, and other guide fit structures are not required to be additionally arranged; the end of the guide rod 21 is fixed with a thick spacer 211 with a diameter larger than the groove width of the guide limit groove 11. Thus, the sliding cover 2 can be effectively prevented from being separated from the face mask 1. Meanwhile, the matching of the guide rod 21 and the abutting tail part 42 is realized through the thick gasket 211, that is, the guide rod 21 contacts the abutting tail part 42 through the thick gasket 211 thereon and drives the abutting tail part 42 to move. Of course, in other embodiments, the engagement between the guide rod 21 and the abutment tail portion 42 is not limited to be realized by the thick pad 211 thereon, and in the case of no thick pad 211, the guide rod 21 may directly abut on the abutment tail portion 42 to directly drive the abutment tail portion 42 to move.

More specifically, the guide matching structures of the guide rods 21 and the guide limiting grooves 11 are provided with two groups, namely two guide limiting grooves 11 and two guide rods 21; the structure is more stable. The abutment tail 42 cooperates with one of the guide rods 21.

Of course, in other embodiments, the guiding and matching structure of the face mask 1 and the sliding cover 2 is not limited to this, and other structures may be added to implement the guiding and matching structure.

Similarly, the face mask 1 is further provided with a yielding long slot hole 12 which runs through the inner surface and the outer surface and is parallel to the guide limiting groove 11, so that the pressure rod 22 can penetrate through the yielding long slot hole to play a role in yielding.

The mask 1 is provided with a handle operation hole 13 penetrating through the inner surface and the outer surface; specifically, the number of the handle operation holes 13 is two, so as to correspond to the common side and the standby side respectively; meanwhile, the handle operating hole 13 is a long slotted hole and is used for the movement stroke of the abdicating operating mechanism during switching on and switching off; as shown in fig. 13, the operating mechanism has a protruding portion 7 extending into the handle operating hole 13, and in the manual position, the switch can be manually controlled to switch on and off by connecting the protruding portion 7 with the handle 8 and shifting the protruding portion 7.

The length direction of the handle operation hole 13 is set to be perpendicular to the length direction of the abdicating long slot hole 12 and is positioned at two sides of the abdicating long slot hole 12. The handle operation hole 13 is covered by the sliding cover 2, and only when the sliding cover 2 is switched from the automatic position to the manual position, the handle operation hole 13 can be exposed, and at this time, the handle 8 extends into the handle operation hole 13 to be connected with the protruding part 7 of the operation mechanism, so that manual operation is performed.

More specifically, two apron 6 are slidable respectively and are set up on two handle operation holes 13, and the slip direction of apron 6 is the same with the length direction of handle operation hole 13, specifically, has seted up through-hole 61 on the apron 6, and control switch on-off's operating device's bellying 7 wears to locate in the through-hole 61 of apron 6 to realize apron 6 and operating device's linkage and be connected. When the switch is switched on, the cover plate 6 is driven to slide by the operating mechanism, so that the cover plate 6 slides to block the abdicating long slot hole 12 to block a path from the automatic position to the position of the double-division padlock by the pressure lever 22; when the switch is opened, the cover plate 6 is driven to slide, so that the cover plate 6 slides to be separated from the abdicating long slot hole 12, and abdicating is realized. Meanwhile, the cover plate 6 is arranged on the handle operation hole 13, the vacant position of the handle operation hole 13 can be shielded, sundries and the like are prevented from entering from the vacant position of the handle operation hole 13, and the protection effect is good while the movement of the limiting pressure rod 22 is met.

Of course, in other embodiments, the cover plate 6 may be provided separately from the handle operation hole 13, instead of being provided on the handle operation hole 13 to shield the handle operation hole 13.

More specifically, the outer surface of the face mask 1 is also concavely provided with a handle placing groove 14 for placing the handle 8, the handle 8 for operation can be placed in the handle placing groove 14, and the handle 8 is convenient to store. When the sliding cover 2 is switched from the automatic position to the manual position, the handle placing groove 14 can be exposed; at this time, the handle 8 in the handle placing groove 14 can be taken out and then inserted into the handle operating hole 13 to perform opening and closing of the manual control switch; the operation is more convenient.

In order to enable the sliding cover 2 to reach the position more accurately, a positioning structure is further arranged between the face mask 1 and the sliding cover 2, and when the sliding cover 2 slides to the position of the double-division padlock, the automatic position or the manual position, positioning and fixing are achieved through the positioning structure. Specifically, in this embodiment, two sets of positioning structures are provided, which are respectively defined as a first positioning structure and a second positioning structure.

The first positioning structure comprises an elastic convex part 15 arranged on the face mask 1 and three limiting holes (a first limiting hole 241, a second limiting hole 242 and a third limiting hole 243) arranged on the sliding cover 2, when the sliding cover 2 slides to a double-division padlock position, an automatic position and a manual position respectively, the elastic convex part 15 is clamped in the three limiting holes respectively, and therefore accurate positioning and fixing of sliding of the sliding cover 2 are achieved; when the slide cover 2 needs to be separated from the position, a certain external force is applied to the slide cover 2, so that the elastic convex part 15 is separated from the matched limiting hole.

Specifically, the first positioning structure is provided with two groups, so that the structure is more stable and uniform.

The second positioning structure comprises a limiting groove component arranged on the face mask 1 and a limiting bulge arranged on the sliding cover 2; specifically, the limiting groove assembly comprises two convex strips 16 which are oppositely arranged, a limiting hole which is used for being matched with the limiting protrusion and a limiting channel 163 which is connected with the limiting hole are formed between the two convex strips 16, and the width of the limiting channel 163 is smaller than the diameter of the limiting protrusion; more specifically, the number of the limiting protrusions is two (the first limiting protrusion 251 and the second limiting protrusion 252 are respectively); the number of the limiting holes is also two (the first limiting hole 161 and the second limiting hole 162, respectively); when the sliding cover 2 slides to the double-split padlock position, the automatic position and the manual position respectively, one of the limiting bulges passes through the limiting channel 163 and is clamped in one of the limiting holes to realize the accurate positioning and fixing of the sliding cover in sliding; when the sliding cover 2 needs to be separated from the position, a certain external force is applied to the sliding cover 2, so that the matched limiting bulge and the limiting hole are separated.

More specifically, the second positioning structures are also provided with two groups, so that the structure is more stable and uniform.

Of course, in other embodiments, the positioning structure may be disposed in one of the above two groups; alternatively, other positioning structures may be used.

The mask 1 is provided with a marking structure for marking positions, in this embodiment, the marking structure is three marking arrows (a first marking arrow 171, a second marking arrow 172 and a third marking arrow 173, respectively) arranged on the mask, and the first marking arrow 171, the second marking arrow 172 and the third marking arrow 173 are respectively marked with characters "manual", "automatic" and "double-branch padlock" to respectively indicate a manual position, an automatic position and a double-branch padlock position. Meanwhile, an indication arrow 26 is arranged on the sliding cover 2, and when the sliding cover 2 slides to a double-split padlock position, an automatic position or a manual position, the indication arrow 26 corresponds to a marking structure for marking a reaching position; thus, the operator can more intuitively confirm the current position. Of course, in other embodiments, the labeling is not limited thereto.

All be formed with the locking hole (respectively for setting up the first locking hole 18 at face guard 1 and setting up the second locking hole 23 on sliding closure 2) on face guard 1 and the sliding closure 2, when sliding closure 2 slides to two branch padlocks positions, two locking holes (be first locking hole 18 and second locking hole 23) are corresponding, at this moment, can pass two locking holes through the tool to lock and lock, guarantee that sliding closure 2 can not cause the switch to close because of the maloperation. By adopting the locking structure, the structure is simple and easy to realize. Of course, in other embodiments, the locking structure between the mask 1 and the slide cover 2 is not limited thereto.

While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides a switching mechanism for dual supply automatic transfer switch which characterized in that: the sliding cover can be assembled on the outer surface of the face mask in a sliding mode and can be switched among a double-split padlock position, an automatic position and a manual position in a reciprocating mode; the sliding cover is also provided with a guide rod and a pressure rod which are arranged in the mask in a penetrating way;

the mask is provided with a micro switch mechanism for connecting or disconnecting a switch control loop, the micro switch mechanism comprises a micro switch and a reset trigger assembly for triggering the switching state of the micro switch, and the reset trigger assembly is provided with an abutting joint part positioned on a pressure lever path and an abutting tail part positioned on a guide rod path; when the sliding cover is positioned at the automatic position, the micro switch mechanism is not influenced by external force, and the micro switch is in a normally closed state; when the sliding cover is switched from the automatic position to the double-branch padlock position, the reset trigger assembly is driven to trigger the micro switch to be disconnected through the matching of the guide rod and the abutting tail part;

the mask is also movably connected with two cover plates which are respectively linked with the two operating mechanisms, and the closing of the switch can drive the cover plates to block the path from the automatic position to the position of the double-branch padlock; the separating brake of the switch can drive the cover plate to give way to the pressure rod.

2. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: the microswitch is a normally closed microswitch; and the reset trigger component is separated from the microswitch under the action of no external force so that the microswitch is in a normally closed state, and when the sliding cover is switched from the automatic position to the manual position or from the automatic position to the double-branch padlock position, the reset trigger component contacts the microswitch to trigger the microswitch to be disconnected.

3. The switching mechanism applied to the dual-power automatic transfer switch of claim 2, wherein: the reset trigger assembly comprises a turntable and a reset torsion spring connected with the turntable, the turntable is rotatably arranged on the inner surface of the outer cover, the abutting joint head and the abutting tail are formed by integrally extending the turntable, and the abutting joint head also corresponds to the microswitch; when the sliding cover is switched from the automatic position to the manual position, the pressing rod abuts against the abutting joint part and drives the turntable to rotate until the abutting joint part abuts against the microswitch so as to trigger the microswitch to be switched off; when the sliding cover is switched to the double-branch padlock position from the automatic position, the abutting tail part is driven to move through the guide rod, and then the rotary table is driven to rotate until the abutting head part abuts against and presses the micro switch, so that the micro switch is triggered to be disconnected.

4. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: the mask is provided with a handle operation hole penetrating through the inner surface and the outer surface; the handle operation hole is covered by a sliding cover, and the handle operation hole can be exposed only when the sliding cover is switched from an automatic position to a manual position.

5. The switching mechanism applied to the dual-power automatic transfer switch of claim 4, wherein: the number of the handle operation holes is two, and the handle operation holes correspond to the common side and the standby side respectively; the two cover plates are respectively arranged on the two handle operation holes in a sliding way to shield the handle operation holes.

6. The switching mechanism applied to the dual-power automatic transfer switch of claim 4, wherein: the outer surface of the face mask is also concavely provided with a handle placing groove for placing a handle, and when the sliding cover is switched from the automatic position to the manual position, the handle placing groove can be exposed.

7. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: the face mask is provided with a guide limiting groove penetrating through the inner surface and the outer surface; the guide rod is inserted into the guide limiting groove to form guide fit, the tail end of the guide rod extends into the mask, and a thick gasket with the diameter larger than the groove width of the guide limiting groove is fixed on the guide rod.

8. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: and a positioning structure is further arranged between the face mask and the sliding cover, and when the sliding cover slides to the position of the double-split padlock, the automatic position or the manual position, the positioning and the fixing are realized through the positioning structure.

9. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: the face guard and the sliding cover are both provided with locking holes, and when the sliding cover slides to the position of the double-split padlock, the two locking holes correspond to each other.

10. The switching mechanism applied to the dual-power automatic transfer switch of claim 1, wherein: the face guard is provided with a marking structure for marking the position, the sliding cover is provided with an indicating arrow, and when the sliding cover slides to the position of the double-split padlock, the automatic position or the manual position, the indicating arrow corresponds to the marking structure for marking the arrival position.

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