WO2018236684A1 - Door lock - Google Patents

Abstract

The present application provides a door lock, comprising a main sliding block, the main sliding block being able to move to and fro between a locked position and a released position along a first direction (length direction), and the main sliding block being able to lock the door lock when at the locked position, and the main sliding block being able to release the door lock when at the released position; and an induction sliding block, the induction sliding block being able to move to and fro between a closed position and an open position along the first direction (length direction) when the main sliding block moves to and fro between the locked position and the released position along the first direction (length direction), wherein the closed position and the open position of the induction sliding block are used for indicating whether the door lock is in a locked state or in a released state. The door lock of the present application can make the output state of a door lock state indicating apparatus stable.

Description

SPECIFICATION

Door lock

Technical field

The present application refers to a door lock for electrical equipment (e.g. washing machines, dish-washing machines).

Background art

Door locks can be used to control locking or opening of doors of electrical equipment (e.g. washing machines, dish-washing machines).

The present application provides a novel door lock mechanism to improve the operation of electrical equipment.

Summary of the invention

To improve the operation of electrical equipment, the present application provides a door lock for use in an electric appliance.

A first aspect of the present application seeks to protect a door lock, the door lock comprising: a main sliding block, the main sliding block being able to move to and fro between a locked position and a released position along a first direction (length direction), and the main sliding block being able to lock the door lock when at the locked position, and the main sliding block being able to release the door lock when at the released position; and an induction sliding block, the induction sliding block being able to move to and fro between a closed position and an open position along the first direction (length direction) when the main sliding block moves to and fro between the locked position and the released position along the first direction (length direction), wherein the closed position and the open position of the induction sliding block are used for indicating whether the door lock is in a locked state or in a released state.

The door lock according to the first aspect of the present application further comprises an indicating apparatus, the indicating apparatus being able to output an indicating signal according to the closed position and the open position of the induction sliding block, and the indicating signal being used for indicating whether the door lock is in the locked state or in the released state.

According to the door lock in the first aspect of the present application, the induction sliding block is able to move to and fro between the closed position and the open position along the first direction (length direction); the induction sliding block is able to move from the open position to the closed position when the main sliding block moves from the released position to the locked position; and the induction sliding block is able to move from the closed position to the open position when the main sliding block moves from the locked position to the released position.

The door lock according to the first aspect of the present application further comprises an induction latch, the induction latch being able to accordingly move to and fro along a second direction (up-down direction) when the induction sliding block moves to and fro along the first direction (length direction); and the induction latch being used for starting the indicating apparatus so that the indicating apparatus outputs the indicating signal.

According to the door lock in the first aspect of the present application, the induction sliding block is arranged at one side of the main sliding block, and the main sliding block brings the induction sliding block to move from the closed position to the open position.

A ccording to the door lock in the first aspect of the present application, a push arm is provided at one side of the main sliding block, and the push arm is able to bring the induction sliding block to move from the closed position to the open position.

According to the door lock in the first aspect of the present application, the door lock further comprises a biasing apparatus, and the biasing apparatus pushes the induction sliding block to move from the open position to the closed position.

According to the door lock in the first aspect of the present application, the biasing apparatus is a spring,

According to the door lock in the first aspect of the present application, the induction sliding block comprises a stepped part, and the stepped part comprises an upper step and a lower step that are arranged by way of connection; a bearing surface and a recess are provided on the upper step, the bearing surface is arranged at a distal end of the upper step, the bearing surface is higher than the recess, a dista! end of the recess is connected to the bearing surface, and an induction sliding block restoration part is provided at an outer side face at a proximal end of the recess; an induction sliding block release pari is provided on an upper surface at a distal end of the lower step, a blocking surface is provided at a proximal end of the lower step, and the blocking surface is used for blocking the movement of the main sliding block when the main sliding block moves from the locked position to the released position; and the induction sliding block protrusion locking claw extends out of an outer side face at the distal end of the lower step.

According to the door lock in the first aspect of the present application, the induction sliding block restoration part comprises a restoration bevel, and the restoration bevel tilts inward in a direction from the distal end of the upper step to the proximal end; and the induction sliding block release part comprises a rotation bevel, and the rotation bevel tilts outward in a direction from the proximal end of the lower step to the distal end,

The door Sock according to the first aspect of the present application further comprises a door lock box, the door lock box comprising an induction sliding block sliding chute, and the induction sliding block sliding chute comprising an inside wail and an outside wall; a notch provided at a distal end of the inside wall, for accommodating the induction sliding block protrusion locking claw, wherein a blocking surface is provided at a distal end of the notch, and the blocking surface is used for blocking the movement of the induction sliding block when the main sliding block moves from the released position to the locked position along the first direction; and an induction sliding block recovery bevel provided at a proximal end of the outside wall, for cooperating with the induction sliding block restoration part to restore the induction sliding block.

The door lock according to the first aspect of the present application can make the output state of a door lock state indicating apparatus stable. A second aspect of the present application seeks to protect a door lock, the door lock comprising: a main sliding block, the main sliding block being able to move to and fro between a locked position and a released position along a first direction (length direction), and the main sliding block being able to lock the door lock when at the locked position, and the main sliding block being able to release the door lock when at the released position; an induction sliding block, the induction sliding block being able to move to and fro along the first direction (length direction) when the main sliding block moves to and fro between the locked position and the released position along the first direction (length direction); an induction latch, the induction latch being able to move to and fro on an upper surface of the induction sliding block, and the induction latch being able to accordingly move to and fro along a second direction (up-down direction) when the induction sliding block moves to and fro along the first direction (length direction); and a switching apparatus, the induction latch being able to close or disconnect the switching apparatus.

According to the door lock in the second aspect of the present application, the induction sliding block is arranged at one side of the main sliding block, and the main sliding block brings the induction sliding block to move from a closed position to an open position.

According to the door lock in the second aspect of the present application, a push arm is provided at one side of the main sliding block, and the push arm is able to bring the induction sliding block to move from the closed position to the open position.

According to the door lock in the second aspect of the present application, the door lock further comprises a biasing apparatus, and the biasing apparatus pushes the induction sliding block to move from the open position to the closed position.

According to the door lock in the second aspect of the present application, the biasing apparatus is a spring.

According to the door lock in the second aspect of the present application, the induction sliding block comprises a stepped part, and the stepped part comprises an upper step and a lower step that are arranged by way of connection; a bearing surface and a recess are provided on the upper step. the bearing surface is arranged at a distal end of the upper step, the bearing surface is higher than the recess, a distal end of the recess is connected to the bearing surface, and an induction sliding block restoration part is provided at an outer side face at a proximal end of the recess; an induction sliding block release part is provided on an upper surface at a distal end of the lower step, a blocking surface is provided at a proximal end of the lower step, and the blocking surface is used for blocking the movement of the main sliding block when the main siiding block moves from the locked position to the released position; and the induction sliding block protrusion locking claw extends out of an outer side face at the distal end of the lower step.

According to the door lock in the second aspect of the present application, the induction sliding block restoration part comprises a restoration bevel, and the restoration bevel tilts inward in a direction from the dis tal end of the upper step to the proximal end; and

the induction sliding block release part comprises a rotation bevel, and the rotation bevel tilts outward in a direction from the proximal end of the lower step to the distal end.

The door lock according to the second aspect of the present application further comprises a door lock box, the door lock box comprising an induction sliding block sliding chute, and the induction sliding block siiding chute comprising an inside wall and an outside wall; a notch provided at a distal end of the inside wall, for accommodating the induction sliding block protrusion locking claw, wherein a blocking surface is provided at a distal end of the notch, and the blocking surface is used for blocking the movement of the induction siiding block when the main siiding block moves from the released position to the locked position along the first direction; and an induction siiding block recovery bevel provided at a proximal end of the outside wall, for cooperating with the induction siiding block restoration part to restore the induction siiding block.

According to the door Sock in the second aspect of the present application, the induction latch can be steadily in a closed position or an open position, and it is an instantaneous jump process when the induction latch move from the disconnected position to the closed position or from the closed position to the disconnected position, avoiding the state of semi-linkage or bad contact when a movable contact and a stationary contact are in contact.

Brief description of the drawings

Fig. 1A is a schematic diagram of the overall structure of a door lock 100 in the present application shown from its front side, with some components of the door lock 100 shown by way of an explosive view;

Fig. IB is a schematic diagram of the overall structure of the door lock 100 in the present application shown from its back side:

Fig. 2 is a schematic diagram of the structure of the door lock 100 in Fig. 1A after a top cover I I 7 is cut off and an actuator 103 is taken away;

Fig. 3A and Fig. 3B are respectively a structural stereogram and a plan view of an induction sliding block 300 of the present invention;

Fig. 4A is a schematic diagram of the interior structure of a door lock box 1 10 in Fig. 2 with ail components in the door lock box 1 10 removed;

Fig. 4B is a partial enlarged drawing of the part 403 in Fig. 4A;

Fig. 5A is a stereoscopic schematic diagram showing the installation of a main sliding block 204 and an induction sliding block 300 in the door lock box 1 10;

Fig. 5B is a schematic plan showing the installation of the main sliding block 204 and the induction sliding block 300 in the door lock box 1 10:

Fig. 6 A and Fig. 6B are an assembly stereogram and an assembly explosive view of the main sliding block 204 and the induction sliding block 300;

Fig. 6C and Fig. 6D are an assembly stereogram and an assembly explosive view of the main sliding block 204 and the induction sliding block 300 shown from the back sides thereof;

Fig. 7A and Fig. 7B are schematic structural diagrams of the components located above the induction sliding block 300 in the induction sliding block sliding chute 402 in Fig. 4A and Fig. 4B; Fig. 8A to Fig. 8G are operational process drawings about the cooperation of relevant components in the door lock 100 of the present application; and

Fig. 9 is an embodiment of an indicating circuit 706 shown in Fig. 7 A and Fig. 7B, to show the structure details of the indicating circuit 706.

Detailed description

Various specific implementation manners of the present application will be described below with reference to the accompanying drawings that constitute a part of this specification. It should be understood that although terms for denoting directions, such as "front", "back', "up", "down", "left", "right", "head", "tail", "proximal end", "distal end", are used in the present application to describe various exemplary structure parts and components of the present application, these terms are used here only for the purpose of convenient illustration and are determined based on the exemplary orientation shown in the accompanying drawings. Since the embodiments disclosed in the present application can be set in different directions, these terms that denote directions serve only as illustration and should not be regarded as restriction. Where possible, same or similar figure labels used in the present application refer to the same components,

Fig, 1A is a schematic diagram of the overall structure of a door lock 100 in the present application observed from its front side, with some components of the door lock 100 shown by way of an explosive view. Fig. IB is a schematic diagram of the overall structure of the door lock 100 in the present application observed from its back side.

As shown in Fig. 1A, the door iock 100 includes a door lock box 1 10, a top cover 1 17 is provided at the upper part of the door lock box 1 10. and a door lockhole 1 12 is set above the head of the top cover 1 17 for accommodating a door hook 101. The door hook 101 is located above the door lockhole 1 12, and when the door hook 101 inserts, from the door lockhole 1 12 above the door lock box 1 10, into the door lock 100 and hooks a cam 201 (see Fig. 2) inside the door lock 300, and when the cam 201 is locked, the door of the electric appliance is accordingly in a position that can be locked. In Fig, 1A₅ the door lock 100 further includes an actuating component 103 and a switch box 105. A bottom surface 1 19 is provided below the head of the top cover 1 17 of the door !ock 100, an accommodating cavity i 15 is formed between the top cover 1 17 and the bottom surface 1 19, and the actuating component 103 is accommodated in the accommodating cavity 1 15. The actuating component 103 is an electromagnetic drive part, in which a coil 121 and an iron core 122 as well as a contact probe 123 at the front end are provided. After the actuating component 103 receives a starting signal, the coil 121 is powered on, and the coil 121 produces an electromagnetic pushing force to the iron core 122 to push out the contact probe 123, and after the power is off, the contact probe 123 is retracted, The switch box 105 is mounted below the tail of the top cover 1 17. The function of the actuating component 103 is to actuate relevant components in the door lock 100, while the function of the switch box 105 includes locking or releasing the main sliding block 204 and connecting or disconnecting the main circuit that controls the door lock 100.

As shown in Fig, IB, a chassis 1 14 is provided below the head of the top cover 1 17, while the switch box 105 is provided below the tail of the top cover 1 17, and the chassis 1 14 and the switch box 105 are arranged next to each other in the width direction of the door lock box 1 10 on the surface below the top cover 1 17.

Fig. 2 is a schematic diagram of the structure of the door lock 100 in Fig, 1 A after the top cover 1 17 is cut off and the actuating component 103 is taken away, for more particularly showing the components in the chassis 1 14, the switch box 105 and the main sliding block 204, and the relationship among the chassis 1 14, the switch box 105 and the main sliding block 204,

in Fig. 2, the chassis 1 14 and the switch box 105 are arranged side by side in the width direction of the door lock box 1 10 on the surface below the top cover 1 17, The main sliding block 204 is arranged between the top cover 1 17 and the switch box 105 and stretches across the chassis 1 14 and the switch box 105 in the width direction of the door lock box 1 10, and the left end (distal end) of the main sliding block 204 can cover the part above the chassis 1 14. A lockhole 219 is provided on the main sliding block 204, and when the main sliding block 204 is at the locked position and a locking dog (not shown) in the switch box 105 extends out of the lockhole 219, the main sliding block 204 is locked, and thus the electric door is also locked.

As shown in Fig. 2, a cam 201 is provided on the chassis 1 14, the cam 201 is arranged below the door hook 101 , the main body of the cam 201 is of a crescent curved structure and is provided with an open slot 202 of circular arc shape, and an upper end of the open slot 202 is a hook 205. After being inserted in the door lockhole 1 12 (see Fig. 1), the door hook 103 pushes the cam 201 to rotate, and the rotation of the cam 201 makes the hook 205 insert in the hole 102 of the door hook 101 and hook the door hook 101. A lower end 206 of the open slot 202 contacts the front end of the door hook 101, and when the door hook 101 is inserted, the front end of the door hook 101 presses against the lower end 206 of the open slot 202, so as to push the cam 201 to rotate anticlockwise.

The cam 201 is fixated on the chassis 1 14 via circular shafts 212 and 214 at two sides, such that the cam 201 is enabled to rotate around the circular shafts 212 and 214, The torsional spring includes torsional springs 210. 1 and 210.2, the torsional springs 210.1 and 210.2 respectively sleeve the circular shafts 212 and 214, and the torsional springs 210.1 and 210.2 provide a torsion for resetting the cam 201. When the door hook 301 is pulled out from the cam 201, the torsional springs 230.1 and 210.2 bring the cam 203 to rotate clockwise, A cam latch 21 1 is also provided at two sides of the tail end of the cam 201 , and the cam latch 21 1 abuts against the left end (distal end) of the main sliding block 204. Meanwhile, the torsional springs 210.1 and 210.2 provide a biasing force for opening the door, that is, when the cam 201 and the main sliding block 204 are at the released position, the torsional spring 210 ejects the door hook 101 out of the cam 203,

Fig. 2 shows the front end of the main sliding block 204, a reset spring 213 is provided at the right end (proximal end) of the main sliding block 204, the torsion of the torsional springs 210.3 and 210.2 on the cam 201 is greater than the elastic force of the reset spring 213 on the main sliding block 204, and therefore, when the earn 201 rotates clockwise, the cam 201 is able to push the main sliding block 204 to move from the locked position to the released position. Due to the mutual effect of the reset spring 213 and the torsional springs 210.1 and 210.2, when the cam 201 rotates, the main sliding block 204 moves to and fro along with it. Particularly, the reset spring 213 provides a pretightening force for the main sliding block 204 to abut against the cam latch 21 1 on the cam 205 , while the torsional springs 210.1 and 210.2 provide a pushing force for the cam 201 to rotate clockwise. Due to the mutual effect of the torsional springs 210.1 and 210.2 and the reset spring 213, when the cam 201 rotates clockwise and anticlockwise, the contact between the back end of the cam 201 and the main sliding block 204 makes the main sliding block 204 produce corresponding reciprocating movement. More particularly, when the door hook 103 is inserted in the cam 201 , the earn 201 rotates anticlockwise, and under the action of the reset spring 213, the main sliding block 204 moves from the released position thereof to the locked position thereof (moving to the left); and when the door hook 101 is pulled out of the cam 201, the cam 201 rotates clockwise, the cam latch 21 1 on the cam 201 pushes the main sliding block 204 to overcome the acting force of the reset spring 213, and the main sliding block 204 moves from the Socked position thereof to the released position thereof (moving to the right).

Fig. 3 A and Fig. 3B are respectively a structural stereogram and a plan view of an induction sliding block 300 of the present invention. As shown in Fig. 3A and Fig. 3B, the induction sliding block 300 is approximately a rectangular structure and can be divided into a distal end (left end) part 301 and a proximal end (right end) part 302. The distal end of the induction sliding block 300 is in a stepped form, with a first side (outer side) of the distal end part 301 being an upper step 303 and a second side (inner side) of the distal end part 301 being a lower step 304.

A bearing surface 342 and a recess 328 are provided on the upper step 303, the bearing surface 342 is arranged at a distal end (left end) part 352 of the upper step 303, the bearing surface 342 is higher than the recess 328, the distal end (left end) of the recess 328 is connected to the bearing surface 342, an induction sliding block restoration part 327 is provided on the outer side face at the proximal end (right end) of the recess 328, the induction sliding block restoration part 327 includes a restoration bevel 370, and the restoration bevel 370 tilts inward toward the proximal end direction of the recess 328. An induction sliding block release part 323 is provided at a distal end (left end) of the upper surface 325 of the lower step 304, the induction sliding block release part 323 includes a rotation bevel 324, and the rotation bevel 324 tilts outward toward the distal end of the recess; and the inner side face 353 of the distal end part 352 of the upper step 303 is connected to the induction sliding block release part 323, and the induction sliding block release part 323 protrudes at the inner side face 353. A blocking surface 326 is provided at the proximal end of the lower step 304, and the blocking surface 326 is used so that the main sliding block 204 can bring the induction sliding block 300 to move when the main sliding block 204 moves from the locked position to the released position. An induction sliding block protrusion locking claw 355 extends out of an outer side face at the distal end (left end) of the lower step 304. A through-hole 331 and a registration mast 337 are provided at the tail on the proximal end (right end ) part 302 of the induction sliding block 300, for mounting a biasing apparatus 336 (e.g. a spring) on the induction sliding block 300. in addition, Fig, 3 A also shows an induction latch 360. The induction latch 360 has a tail 361, a head 362 and a shoulder 363. The head 362 of the induction latch 360 is slidably supported on the bearing surface 342 of the upper step 303 and on the surface 380 of the recess 328, and the induction latch 360 cannot move along the length direction (first direction, i.e. the direction shown by arrow 350) of the induction sliding block 300, but the relative movement between the induction latch 360 and the induction sliding block 300 can enable the induction latch 360 to move up and down along the direction (second direction) shown by arrow 351 , where the second direction and the first direction are perpendicular to each other. When the induction latch 360 is located in the recess 328 (closed position), the tail 361 of the induction latch 360 can close the switching apparatus in the door lock 100 (see Fig. 7A); and when the induction latch 360 is located on the bearing surface 342 (disconnected position), the tail 361 of the induction latch 360 can disconnect the switching apparatus in the door lock 100 (see Fig. 7B).

Fig. 4A is a schematic diagram of the interior structure of a door lock box 1 30 in Fig. 2 with all components in the door lock box 1 10 removed. As shown in Fig. 4A, the door lock box 1 10 includes an induction siiding block sliding chute 402 and a main sliding block sliding chute 404, The induction sliding block sliding chute 402 has an outside wall 412 and an inside wail 414, and the main sliding biock sliding chute 404 has an outside wall 414 (a wail that is shared with the inside wail 414 of the induction sliding biock sliding chute 402) and an outside wall 416. A groove 413 is provided at the distal end part of the outside wall 412 of the induction sliding block sliding chute 402, and a groove 415 is provided at the distal end part of the inside wail 414 of the induction sliding block sliding chute 402. The induction sliding biock siiding chute 402 is used for accommodating the induction sliding block 300, while the main sliding block sliding chute 404 is used for accommodating the main sliding block 204. The door lock box 1 10 further includes a support frame 418, to facilitate the support of the induction latch 360 while the induction latch 360 slides.

Fig. 4B is a partial enlarged drawing of the part 403 in Fig. 4A, for showing the structure of the induction sliding block sliding chute 402 more clearly. As shown in Fig. 4B, a groove 413 is provided at the distal end part of the outside wall 412 of the induction siiding block sliding chute 402, and a groove 415 is provided at the distal end part of the inside wall 414 of the induction siiding block siiding chute 402. An induction sliding block recovery bevel 437 is provided below the inner side face at the distal end of the groove 413 on the outside wall 412, and the induction sliding block recovery bevel 437 tilts outward in the proximal end (right end) direction of the groove 415. A notch 422 is provided below the outer side face at the distal end part (left side) of the groove 415 on the inside wail 414, and a blocking surface 423 is provided at the distal end part (left end part) of the notch 422,

Fig. 5A is a stereoscopic schematic diagram showing the installation of a main sliding block 204 and an induction sliding block 300 in the door lock box ] 10, Fig. 5B is a schematic plan showing the installation of the main sliding block 204 and the induction sliding biock 300 in the door lock box 1 10. As shown in Fig. 5 A and Fig. 5B, the induction sliding block 300 is mounted in the induction sliding biock sliding chute 402, and the induction sliding block 300 can slide to and fro in the induction sliding block sliding chute 402; while the main sliding block 204 is mounted in the main sliding block sliding chute 404, and the main sliding block 204 can slide to and fro in the main sliding block sliding chute 404. A push arm 502 is provided at the side face of the main sliding block 204, and the push arm 502 is slidabiy placed on the upper surface 325 of the lower step 304 in the induction sliding block 300, for bringing the induction sliding block 300 to move when the main sliding block 204 moves from the locked position to the released position thereof. The head 362 of the induction latch 360 is slidabiy arranged above the induction sliding block 300, to enable the induction sliding block 300 to steadily move to and fro in the length direction (first direction, i.e. the direction shown by arrow 350) of the induction sliding block 300.

Fig. 6 A and Fig. 6B are an assembly stereogram and an assembly explosive view of the main sliding block 204 and the induction sliding block 300, in which Fig. 6A and Fig. 6B are the assembly stereogram and the assembly explosive view of the main sliding block 204 and the induction sliding block 300 shown from the front sides thereof; and Fig. 6C and Fig. 6D are the assembly stereogram and the assembly explosive view of the main sliding block 204 and the induction sliding block 300 shown from the back sides thereof for more clearly showing the cooperative relationship between the main sliding block 204 and the induction sliding block 300 and the shape details of the push arm 502. As shown in Fig. 6A to Fig. 6D, the push arm 502 has a side part 603 and a fiat bottom 605. When the main sliding block 204 moves from the locked position to the released position along the length direction (first direction, i.e. the direction shown by arrow 350) thereof, the side part 603 thereof presses against the blocking surface 326 of the induction sliding block 300, so as to bring the induction sliding block 300 to move from the closed position to the open position along the length direction (first direction) thereof. When the main sliding block 204 moves from the released position to the locked position along the length direction (first direction) thereof, the biasing force from the spring 336 moves the induction sliding block 300 from the open position to the closed position. Referring to Fig. 6A to Fig. 6D. when the push ami 502 of the main slid ing block 204 moves from the released position to the locked position and passes by the rotation bevel 324 of the induction sliding block 300, a component force produced on the rotation bevel 324 will rotate the induction sliding block 300 by an angle (e.g. 2.0-2.5 degrees), so that an included angle (see Fig. 8C and Fig. SD) is formed between the induction sliding block 300 and the length direction (first direction) of the main sliding block 204. When the push arm 502 moves from the locked position to the released position, and when the restoration bevel 370 on the induction sliding block 300 passes by the induction sliding block recovery bevel 437 on the induction sliding block sliding chute 402, the component force produced as a result of the mutual effect of the two bevels will rotate the induction sliding bevel 300 by an angle to the opposite direction (rotate reversely by 2.0- 2.3 degrees), so that the induction sliding block 300 returns to the position parallel to the length direction (first direction) of the main sliding block 204 (see Fig, 8F and Fig. 8G),

Fig, 7A and Fig. 7B show the components located above the induction sliding block 300 in the induction sliding block sliding chute 402 in Fig, 4A and Fig. 4B, for showing how the induction latch 360 closes and disconnects the switching apparatus. As shown in Fig. 7 A and Fig. 7B, the switching apparatus includes a movable spring piece 702, a movable contact 703 arranged on the movable spring piece 702 and a fixed conductor rod 704. As shown in Fig. 7A, after the induction latch 360 moves downward for a certain distance, the tail 361 of the induction latch 360 leaves the movable spring piece 702, so that the movable contact 703 contacts the fixed conductor rod 704 to connect the power circuit. As shown in Fig, 733, after the induction latch 360 moves upward for a certain distance, the tail 361 of the induction latch 360 props up the movable spring piece 702, so that the movable contact 703 leaves the fixed conductor rod 704 to disconnect the power circuit.

As shown in Fig, 7 A and Fig, 7B, the input 705 of the indicating apparatus 706 is electrically connected to the fixed conductor rod 704, and when the power circuit is connected, the indicating apparatus 706 outputs a first state signal (e.g. high level or low level), indicating that the door lock 100 is in the locked state; and when the power circuit is disconnected, the indicating apparatus 706 outputs a second state signal (e.g. low level or high level), indicating that the door lock 100 is in the released state.

Fig. 8A to Fig. 8G show operational process drawings about the cooperation of relevant components in the door lock 100 of the present application. Here, Fig. 8A to Fig. 8D show the process in which the door lock 100 is from the open state to the closed state; and Fig. 8E to Fig. 8G show the process in which the door lock 300 is from the closed state to the open state,

As shown in Fig, 8A, the door lock 100 is in the open state at this time. The main sliding block 204 is in the leftmost position (i.e. released position), and the side part 603 of the push arm 502 on the main sliding block 204 presses against the blocking surface 326, Previously, in the process where the door hook 101 is pulled out of the earn 201, the push arm 502 pushes the induction sliding block 300 to move the compression spring 336 to the left side to store the elastic potential energy, and pushes the induction sliding block 300 to the leftmost end. At this time, the induction sliding block 300 is blocked by the main sliding block 204 at the leftmost side and is unable to move. The head 362 of the induction latch 360 is on the bearing surface 342 of the induction sliding block 300, and the tail 361 of the induction latch 360 props up the movable spring piece 702, so thai the movable contact 703 leaves the fixed conductor rod 704 and disconnects the power circuit, and thus the indicating apparatus 706 outputs a second state signal (low level or high level). At this time, the main sliding block 204 is at the released position, the induction sliding block 300 is at the open position, and the door lock 100 is in the open state.

As shown in Fig, 8B, as the door hook 103 enters the cam 201, the door lock 100 starts to close. The main sliding block 204 moves from the released position thereof to the locked position at the right side. The elastic force of the spring 336 helps the induction sliding block 300 move to the right with the main sliding block 300, until the induction sliding block protrusion locking claw 355 is blocked by the blocking surface 423 in the induction sliding block sliding chute 402, and at this time the induction sliding block 300 is temporarily unable to move. At this time, the head 362 of the induction latch 360 is still on the bearing surface 342 of the induction sliding block 300, and the tail 361 of the induction latch 360 props up the movable spring piece 702, so that the movable contact 703 leaves the fixed conductor rod 704 and disconnects the power circuit, and thus the indicating apparatus 706 keeps the second state signal. At this time, the main sliding block 204 leaves the released position thereof and moves to the locked position, but the induction sliding block 300 is still at the open position.

As shown in Fig. 8C, the main sliding block 204 continues to move to the right side, and the right side of the push arm 502 contacts the rotation bevel 324 on the induction sliding block 300. The continuous movement of the push arm 502 will produce a component force that pushes the induction sliding block 300 to move downward, pushing the distal end (right end) of the induction sliding block 300 to rotate downward. At this time, the induction sliding block protrusion locking claw 355 on the induction sliding block 300 is still blocked by the blocking surface 423 in the induction sliding block sliding chute 402, and therefore the induction sliding block 300 is still unable to move. At this time, the head 362 of the induction latch 360 is still on the bearing surface 342 of the induction sliding block 300, and the tail 361 of the induction latch 360 props up the movable spring piece 702, so that the movable contact leaves the fixed conductor rod 704 and disconnects the power circuit, and thus the indicating apparatus 706 keeps the second state signal. At this time, the main sliding block 204 moves to the locked position, and the induction sliding block 300 is still at the open position.

As shown in Fig, 8D, the main sliding block 204 continues to move to the right side, and the right side of the push arm 502 passes by the middle or top of the rotation bevel 324 on the induction sliding block 300. The push ami 502 pushes the distal end (right end) of induction sliding block 300 to continue to rotate downward. When the distal end of the induction sliding block 502 rotates downward by a certain angle (e.g. 2.0-2.5 degrees), the induction sliding block protrusion locking claw 355 is pushed out of the notch 422, At this time, the induction sliding block 300 is able to move because it is no longer blocked by the blocking surface 423 in the induction sliding block sliding chute 402, and the elastic force of the spring 336 instantaneously ejects the induction sliding block 300 to the end of the distal end (right end) of the induction sliding block sliding chute 402, At the same time, the induction latch 360 instantaneously moves from the bearing surface 342 to the recess 328, and the tail 361 of the induction latch 360 moves down instantaneously, leaves the movable spring piece 702, and causes the movable contact 703 to contact the fixed conductor rod 704 to close the power circuit instantaneously, so that the second state signal output by the indicating apparatus 706 changes to the first state signal. At this time, the main sliding block 204 is at the locked position, the induction sliding block 300 is at the closed position, and the door lock 100 is in the closed state.

As shown in Fig. 8E, the door hook 1 01 starts to be pulled out of the cam 201 , the door lock 100 starts to open, the main sliding block 204 moves to the left side from the locked position thereof, and the side part 603 of the push arm 502 pushes the blocking surface 326, brings the induction sliding block 300 to move to the left side, and compresses the spring 336 to the left to store the elastic potential energy. Since the head 362 of the induction latch 360 is still in the recess 328 of the induction sliding block 300 and the tail 361 of the induction latch 360 does not contact the movable spring piece 702, the movable contact 703 contacts the fixed conductor rod 704 and closes the power circuit, so that the indicating apparatus 706 outputs and keeps the first state signal. At this time, the main sliding block 204 moves from the locked position thereof to the released position, but the induction sliding block 300 is still at the closed position.

As shown in Fig. 8F, the main sliding block 204 continues to compress the spring 336 to move to the left side, and the restoration bevel 370 on the induction sliding block 300 and the induction sliding block recover)' bevel 437 on the induction sliding block sliding chute 402 start to contact and produce a force to push the induction sliding block 300 to deflect upward, so that the induction sliding block 300 starts to rotate upward, and the induction sliding block protrusion locking claw 355 on the induction sliding block 300 gradually enters the notch 422 of the induction sliding block sliding chute 402. Since the head 362 of the induction latch 360 moves to the bearing surface 342 of the induction sliding block 300, the induction latch 360 moves upward, the tail 361 of the induction latch 360 props up the movable spring piece 702, and the movable contact 703 leaves the fixed conductor rod 704 and disconnects the power circuit, so that the first state signal output by the indicating apparatus 706 changes to the second state signal. At this time, the main sliding block 204 moves from the locked position thereof to the released position, and the induction sliding block 300 is at the open position.

As shown in Fig. 8G, the main sliding block 204 continues to move to the left side to further compress the spring 336. The restoration bevel 370 on the induction sliding block 300 passes by the middle or top of the induction sliding block recovery bevel 437 on the induction sliding block sliding chute 402, so that the induction sliding block 300 starts to rotate upward. When the induction sliding block 300 moves upward by a certain angle (2.0-2.5 degrees), the induction sliding block 300 restores to the position parallel to the main sliding block 204, and the induction sliding block protrusion locking claw 355 on the induction sliding block 300 enters the notch 422 of the induction sliding block sliding chute 402. Since the head 362 of the induction latch 360 moves to the middle (or close to the middle) above the bearing surface 342 of the induction sliding block 300, the tail 361 of the induction latch 360 props up the movable spring piece 702, and the movable contact 703 leaves the fixed conductor rod 704 and disconnects the power circuit, so that the indicating apparatus 706 outputs and keeps the second state signal. At this time, the main sliding block 204 moves from the locked position thereof to the released position, the induction sliding block 300 is at the open position, and the door lock 100 is in the open state (the state shown in Fig. 8A).

It should be noted that the locked position and the released position are in terms of the main sliding block 204; the open position and the closed position are in terms of the induction sliding block 300; and the open state and the closed state are in terms of the door lock 100.

Fig. 9 is an embodiment of an indicating circuit 706 shown in Fig. 7A and Fig. 7B, to show the structure details of the indicating circuit 706. As shown in Fig, 9, the indicating circuit 706 includes a flip-flop circuit 902, an input resistor 904 and a sampling resistor 905. A signal sampling input end 903 of the flip-flop circuit 902 is electrically connected to earth via the input resistor 904; and a signal input end 903 of the flip-flop circuit 902 is also electrically connected with the fixed conductor rod 704 shown in Fig, 7 via the sampling resistor 905. When the movable contact 703 is connected to the fixed conductor rod 704, a voltage signal is produced on the input resistor 904, so that the output end 708 of the flip-flop circuit 902 is set to a first state signal (high level or low level); and when the movable contact 703 is not connected to the fixed conductor rod 704, no voltage signal is produced on the input resistor 904, and the output end 708 of the flip-flop circuit 902 is set to a second state signal (low level or high level) In Fig. 9, the choice of the input resistor 904 and the sampling resistor 905 should make the current passing through the two resistors small, so that the partial current in the two resistors will not affect the work of the main circuit of the electric appliance,

A current door lock of an electric appliance is provided with a door lock state indicating apparatus for indicating whether the door lock is in the iocked state or in the open state; and the output of the door lock state indicating apparatus is used for controlling the operation of the electric appliance (e.g. a washing machine). The current door lock of an electric appliance is also provided with a switching apparatus for disconnecting the power supply when the door lock is in the open state and for connecting the power supply when the door lock is in the closed state. In order to achieve the above two functions, the current door lock of an electric appliance adopts a sliding block and arrange a bevel on the sliding block, the bevel have positions of different heights at two sides, and a driving latch is slidably arranged on the bevel of the sliding block. As such, the movement of the sliding block in the horizontal direction can bring the driving latch to move up and down, and the up-down movement of the driving latch brings the contact to move up and down, so that the movable contact and the stationary contact of the switching apparatus contact and separate to close or disconnect the power supply of the electric appliance, At the same time, the state change of the switching apparatus drives the door lock state indicating apparatus to output a signal for indicating the door lock state. Some problems exist in this structure: firstly, the vibration produced due to the operation of the electric appliance will cause the sliding block to produce slight vibration or small movement, the slight vibration or small movement produced by the sliding block will be accordingly directly transferred to the driving latch via the bevel to cause the driving latch to vibrate up and down, while the up-down vibration of the driving latch will lead to a semi-contact state of the movable contact and the stationary contact, and the output signal state of the door lock state indicating apparatus will also be unstable; secondly, the speed of using the bevel on the sliding block to bring the driving latch to move is related to the speed of a user opening the door, and therefore the process in which the switching apparatus moves from the open position to the closed position may be continuous and relatively slow, and in this process the semi-contact state of the movable contact and the stationary contact easily appears, causing bad contact.

In the process in which the door lock 100 is from the open state to the closed state shown in Fig. 8A to Fig, 8D, the main sliding block 204 moves from the released position to the locked position and brings the induction sliding block 300 to move from the open position and instantaneously jump to the closed position, the induction latch 360 instantaneously jumps from the disconnected position to the closed position, and the movable contact 703 is instantaneously connected to the fixed conductor rod 704. Moreover, in this process, after the main sliding block 204 moves for a certain distance, the elasticity of the spring 336 brings the induction sliding block 300 to instantaneously jump from the open position to the closed position, releasing the elastic potential energy of the spring 336. As shown in Fig. 8F. to Fig. 8G, in the process in which the door lock is from the closed state to the open state, the main sliding block 204 first moves for a certain distance and then pushes the induction sliding block 300 from the closed position to the open position. That is to say, in the above-mentioned two processes, the preliminary movement of the main sliding block 204 is an idle movement and does not cause the change in the open position or closed position of the induction sliding block 300. Therefore, in the process of the operation of the electric appliance, although the vibration or small movement produced by the operation of the electric appliance will cause small movement or shake of the main siiding block 204, as the movement of the main sliding block 204 caused is just an idle movement, it will not cause the induction sliding block 300 to move. Therefore, no matter whether the door lock 100 is in the closed state or in the open state, although the vibration or small movement produced by the operation of the electric appliance will cause small movement or shake of the main sliding block 204, the small movement or shake of the main sliding block 204 will not cause the induction sliding block 300 to move. Therefore, in the process of the operation of the electric appliance, the induction latch 360 can be steadily at the closed position or the open position, and the phenomenon where bad contact is caused due to small movement or shake of the main sliding block 204 will not appear. Moreover, the process in which the induction sliding block 300 moves from the open position to the closed position is an instantaneous process, which causes the process in which the induction latch 360 moves from the disconnected position to the closed position to be an instantaneous process, and will not cause the state of semi-linkage or bad contact when the movable contact and the stationary contact, in addition, the output state of the door lock state indicating apparatus 706 will also be stable, and the output state will not be made unstable due to the small shake of the main sliding block 204.

Although only some features of the present application are illustrated and described herein, a person skilled in the art may make various improvements and changes. Therefore, it should be understood that the appended claims are intended to cover all of the above-mentioned improvements and changes that fail into the substantial spirit scope of the present application.

Claims

1. A door lock (100), characterized by comprising:

a main sliding block (204), the main sliding block (204) being able to move to and fro between a locked position and a released position aiong a first direction (length direction), and the main sliding block (204) being able to lock the door lock (100) when at the locked position, and the main sliding block (204) being able to release the door lock (100) when at the released position; and an induction sliding block (300), the induction sliding block (300) being able to move to and fro between a closed position and an open position along the first direction (length direction) when the main sliding block (204) moves to and fro between the locked position and the released position along the first direction (length direction),

wherein the closed position and the open position of the induction sliding block (300) are used for indicating whether the door lock (100) is in a locked state or in a released state.

2. The door lock (100) as claimed in claim 1, characterized by further comprising:

an indicating apparatus (706), the indicating apparatus (706) being able to output an indicating signal according to the closed position and the open position of the induction sliding block (300). and the indicating signal being used for indicating whether the door lock (100) is in the locked state or in the released state.

3, The door lock (300) as claimed in claim 2, characterized in that:

the induction sliding block (300) is able to move to and fro between the closed position and the open position along the first direction (length direction); the induction sliding block (300) is able to move from the open position to the closed position when the main sliding block (204) moves from the released position to the locked position; and the induction sliding block (300) is able to move from the closed position to the open position when the main sliding block (204) moves from the locked position to the released position

4. The door lock (100) as claimed in claim 3, characterized by further comprising:

an induction latch (360), the induction latch (360) being able to accordingly move to and fro along a second direction (up-down direction) when the induction sliding block (300) moves to and fro along the first direction (length direction),

wherein the induction latch (360) is used for starting the indicating apparatus (706) so that the indicating apparatus (706) outputs the indicating signal.

5. A door lock (100), characterized by comprising:

a main sliding block (204), the main sliding block (204) being able to move to and fro between a locked position and a released position along a first direction (length direction), and the main sliding block (204) being able to lock the door lock (100) when at the locked position, and the main sliding block being able to release the door lock (100) when at the released position;

an induction sliding block (300), the induction sliding block (120) being able to move to and fro along the first direction (length direction) when the main sliding block (204) moves to and fro between the locked position and the released position along the first direction (length direction); an induction latch (360), the induction latch (360) being able to move to and fro on an upper surface of the induction sliding block (300), and the induction latch (360) being able to accordingly move to and fro along a second direction (up-down direction) when the induction sliding block (300) moves to and fro along the first direction (length direction); and

a switching apparatus, the induction latch (360) being able to close or disconnect the switching apparatus,

6. The door lock (100) as claimed in claim 5, characterized in that:

the induction sliding block (300) is arranged at one side of the main sliding block (204), and the main sliding block (204) brings the induction sliding block (300) to move from the closed position to the open position.

7. The door lock (100) as claimed in claim 6, characterized in that:

a push arm (502) is provided at one side of the main sliding block (204), and the push arm (502) is able to bring the induction sliding block (300) to move from the closed position to the open position.

8. The door lock (100) as claimed in claim 7, characterized in that:

the door lock (100) further comprises a biasing apparatus (336). and the biasing apparatus (336) pushes the induction sliding block (300) to move from the open position to the closed position.

9. The door lock (100) as claimed in claim 8, characterized in that:

the biasing apparatus (336) is a spring.

10. The door lock (100) as claimed in claim 6, characterized in that:

the induction sliding block (300) comprises a stepped part, and the stepped part comprises an upper step (303) and a Iower step (304) that are arranged by way of connection;

a bearing surface (342) and a recess (328) are provided on the upper step (303), the bearing surface (342) is arranged at a distal end of the upper step (303), the bearing surface (342) is higher than the recess (328), a distal end of the recess (328) is connected to the bearing surface (342). and an induction sliding block restoration part (327) is provided at an outer side face at a proximal end of the recess (328);

an induction sliding block release part (323) is provided on an upper surface at a distal end of the Iower step (304), a blocking surface (326) is provided at a proximal end of the iower step (304), and the blocking surface (326) is used for blocking the movement of the main sliding block (204) when the main sliding block (204) moves from the locked position to the released position; and an induction sliding block protrusion locking claw (355) extends out of an outer side face at the distal end of the lower step (304).

1 1. The door lock ( 100) as claimed in claim 10, characterized in that:

the induction sliding block restoration part (327) comprises a restoration bevel (370). and the restoration bevel (370) tilts inward in a direction from the distal end of the upper step (303) to the proximal end; and

the induction sliding block release part (323) comprises a rotation bevel (324), and the rotation bevel (324) tilts outward in a direction from the proximal end of the lower step (304) to the distal end.

12. The door lock (100) as claimed in claim 10, characterized by further comprising:

a door lock box (1 10), the door lock box (1 10) comprising an induction sliding block sliding chute (402), and the induction sliding block sliding chute (402) comprising an inside wall (414) and an outside wall (412): wherein

a notch (422) is provided at a distal end of the inside wall (434) and used for accommodating the induction sliding block protrusion locking claw (355), a blocking surface (423) is provided at a distal end of the notch (422), and the blocking surface (423) is used for blocking the movement of the induction sliding block (300) when the main sliding block (204) moves from the released position to the locked position along the first direction; and

an induction sliding block recovery bevel (437) is provided at a proximal end of the outside wall (412) and used for cooperating with the induction sliding block restoration part (327) to restore the induction sliding block (120).

13. The door lock (100) as claimed in claim I, characterized in that:

the induction sliding block (300) is arranged at one side of the main sliding block (204), and the main sliding block (204) brings the induction sliding block (300) to move from the closed position to the open position.