CN113208321B - Simple and convenient mounting structure of energy storage rebound device - Google Patents

Abstract

The invention relates to a simple installation structure of an energy storage rebound device, which comprises the energy storage rebound device and an installation seat; the energy storage rebound device comprises a rebound bracket, an elastic element and a pushing element; the mounting seat is provided with a fixing part for fixing and assembling; a heart-shaped chute is arranged on the rebound bracket, and a plurality of limit assembly matching parts are formed between the rebound bracket and the mounting seat; the rebound bracket and the mounting seat are mounted in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; the elastic element elastically acts on the rebound bracket and the pushing element respectively; the pushing element is provided with a movable part, and the pushing element elastically stretches and slides on the rebound bracket through an elastic element and drives the movable part to slide and/or position along the track of the heart-shaped chute in a sequence direction when sliding. The rebound bracket can be mounted on the mounting seat in an up-down and/or left-right and/or front-back limit manner by utilizing the cooperation of the plurality of limit mounting cooperation parts, so that the mounting operation of a user is facilitated.

Description

Simple and convenient mounting structure of energy storage rebound device

Technical Field

The invention relates to a simple installation structure of an energy storage rebound device.

Background

The Chinese patent document No. CN211269467U discloses a pressing rebound simple assembly structure on the 18 th month of 2020, which comprises a pressing rebound device, wherein the pressing rebound device comprises a shell, an elastic piece and a sliding piece, a connecting hole is formed in the shell, a heart-shaped sliding groove is formed in the connecting hole, one end of the elastic piece is elastically acted on the shell, the other end of the elastic piece is elastically acted on the sliding piece, a sliding part is arranged on the sliding piece, the sliding part elastically stretches and slides and/or is positioned on the shell along the track of the heart-shaped sliding groove along a sequential direction through the matching of the sliding part and the elastic piece, a first hole inner positioning part and a second hole inner positioning part are arranged in the connecting hole, and a sliding-in positioning part and a sliding-out positioning part are arranged on the sliding part and the sliding-out positioning part respectively and are positioned on the first hole inner positioning part and the second hole inner positioning part. The structure can effectively simplify the whole structure of the pressing rebound device, reduce the whole volume, thereby reducing the production and assembly cost of the pressing rebound device and simultaneously reducing the storage space inside the furniture occupied by the pressing rebound device during assembly; meanwhile, the structure has two mounting modes, namely, a notch part is arranged on the furniture component, the shell is fixedly arranged in the notch part, and the outer wall of the shell is provided with a fixing part which is fixedly arranged on the furniture component. For the first, the furniture part is required to be provided with a notch, so that the appearance of the furniture part is influenced, the production process is increased, and the service life of the furniture part provided with the notch is relatively low; for the second type, the fixing part is integrally arranged on the outer wall of the shell, the production process is complex, and the shell is also assisted by other tools during installation, so that the installation operation of a user is not facilitated. Therefore, further improvements are needed.

Disclosure of Invention

The invention aims to provide a simple installation structure of an energy storage rebound device, which overcomes the defects in the prior art.

The simple and convenient mounting structure of energy storage rebound device according to this purpose design, including energy storage rebound device, this energy storage rebound device includes bounce bracket, elastic element and pushing element, its characterized in that: the device also comprises a mounting seat, wherein the mounting seat is provided with a fixing part for fixing and assembling; the rebound bracket is provided with a heart-shaped chute and a plurality of limit assembly matching parts are formed between the rebound bracket and the mounting seat; the rebound bracket and the mounting seat are mounted in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; the elastic element elastically acts on the rebound bracket and the pushing element respectively; the pushing element is elastically stretched and slid on the rebound bracket through the elastic element, and drives the movable element to slide and/or position along the track of the heart-shaped chute in a sequence direction when sliding.

The rebound bracket is provided with a concave part; the mounting seat is mounted in the concave part in an up-down mode, a left-right mode and/or a front-back mode through a plurality of limit mounting matching parts; wherein, the rebound support covers on the mount pad through the concave part, and the mount pad outside is basic parallel and level with the rebound support outside.

The plurality of limit assembly matching parts at least comprise bracket limit steps arranged on the concave parts and mounting seat limit steps arranged on the mounting seats.

The mounting seat is placed in the concave part and is clamped on the support limiting step through the mounting seat limiting step in a sliding mode, so that left and right limiting mounting between the rebound support and the mounting seat is realized.

The limiting assembly matching parts comprise bracket elastic clamping positions arranged on the concave parts and mounting seat elastic clamping positions arranged on the mounting seats.

The mounting seat is placed in the concave part and is elastically clamped on the elastic clamping position of the bracket through the sliding type elastic clamping position of the mounting seat, so that front and back limiting mounting between the rebound bracket and the mounting seat is realized.

The plurality of limit assembly matching parts further comprise protruding positions arranged on the mounting seat and/or the concave part.

The mounting seat is placed in the concave part, and the mounting seat and the concave part are mutually abutted through the convex position, so that the upper limit and the lower limit mounting between the rebound bracket and the mounting seat are realized.

The rebound bracket comprises a cover plate and an assembly seat; the heart-shaped chute is arranged on the cover plate; the cover plate is fixedly covered on one side of the assembly seat; a concave part is arranged on the other side of the assembly seat; the mounting seat is mounted in the concave part in an up-down mode, a left-right mode and/or a front-back mode through a plurality of limit mounting matching parts; the mounting seat is covered on the mounting seat through the concave part, and the outer side surfaces of the mounting seat and the mounting seat are basically flush.

The pushing element and/or the movable piece are/is provided with a positioning part, and an elastic piece is positioned by the positioning part, and two ends of the elastic piece are respectively and elastically acted on the pushing element and the movable piece.

One end of the movable piece is rotatably or swingably arranged on the pushing element, the middle part of the movable piece is elastically connected with the pushing element through an elastic piece, and the other end of the movable piece is provided with a sliding part.

The pushing element drives the movable part to move along when the pushing element elastically stretches and slides, the movable part drives the sliding part to always generate elastic friction force with the assembly seat through the elastic part when the movable part moves, and the sliding part always slides and/or is positioned along the track of the heart-shaped sliding groove in a sequence direction through the elastic friction force.

The elastic friction force generated by the movable piece is larger than the rotation or swing force generated by the movable piece.

The heart-shaped sliding groove is provided with a first limit sliding area, a first conversion position, an inclined guiding area, a heart-shaped stay area, a second conversion position and a second limit sliding area.

The sliding part slides along the track of the first conversion position when the first limit sliding area slides to a certain position, slides onto the inclined guide area by the cooperation of the elastic friction force and the elastic element, and finally slides into and stays in the heart-shaped stay area by the inclined guide action of the inclined guide area.

The pushing element is positioned and closed on the assembly seat when the sliding part stays in the heart-shaped stay area.

When the sliding part stays in the heart-shaped stay area and the pushing element slides relative to the assembly seat in a pressing way, the sliding part slides out of the heart-shaped stay area through the driving of the pushing element and slides along the track of the second conversion position, and slides to the second limiting sliding area through the cooperation of elastic friction force and the elastic element.

The pushing element elastically stretches out and opens on the assembly seat through the elastic element when the sliding part slides to the second limit sliding area.

The cover plate is also provided with a guide part corresponding to the heart-shaped chute, and the guide part is positioned at the front end of the heart-shaped chute; the sliding part is guided by the guide part to limit the sliding part to slide into a first limit sliding area of the heart-shaped chute.

The assembly seat is provided with an assembly cavity, and the assembly cavity is provided with a sleeve joint piece; the elastic element is a pressure spring and is sleeved on the sleeve joint piece, one end of the elastic element is elastically acted on the assembly cavity or the sleeve joint piece, and the other end of the elastic element is elastically acted on the pushing element and always generates elastic acting force towards the pushing element; the pushing element is sleeved on the sleeve joint piece and elastically stretches out and draws back on the assembly cavity through the elastic element; the elastic force generated by the elastic element is larger than the elastic force generated by the elastic piece.

The rebound bracket is also provided with a control circuit board, a power supply element and a reset driving assembly which are respectively and electrically connected with the control circuit board; the reset driving assembly is in driving connection with the pushing element; the control circuit board obtains working power through the power supply element and drives the reset driving assembly to reciprocate on the rebound bracket.

When the rebound bracket is elastically stretched out and opened, the reset driving assembly drives the pushing element to automatically reset and slide in under the control of the control circuit board, and the pushing element is positioned and closed on the rebound bracket; the reset driving assembly is reset to an initial position by the control of the control circuit board when the pushing element is closed.

According to the invention, through the improvement of the structure, the mounting seat and the rebound bracket are separately arranged, and then a plurality of limit assembly matching parts are arranged between the mounting seat and the rebound bracket. When the energy storage rebound device is installed, the installation seat is firstly installed and fixed through the fixing part, the rebound bracket is installed on the installation seat in a sliding mode through a plurality of limit installation matching parts up and down, and/or left and right, and/or front and back in a limiting mode, so that the installation of the energy storage rebound device can be realized, the defect that in the prior art, a notch part is arranged on a furniture part, or an auxiliary tool is used for assisting in installing the energy storage rebound device is avoided, a user only needs to align the rebound bracket with the fixed installation seat during installation, and the whole installation process can be completed through simple sliding, so that the installation operation of the user is facilitated.

Comprehensively, the novel pressing type opening and closing device has the characteristics of simple and reasonable structure, low manufacturing cost, simplicity and convenience in disassembly and assembly operation, compact and stable assembly among the components, high pressing opening and closing stability, safety and reliability in use and the like, and has strong practicability.

Drawings

FIG. 1 is a schematic view of an assembly structure of a furniture component, a furniture cabinet, an energy storage rebound device, and a mounting base according to an embodiment of the present invention.

Fig. 2 is a schematic view of an exploded structure of a furniture component, an energy storage rebound device, and a mounting base according to an embodiment of the present invention.

Fig. 3 is a schematic diagram illustrating an assembly structure of an energy storage rebound device and a mounting base according to an embodiment of the present invention.

Fig. 4 and 5 are schematic diagrams illustrating an assembling process of the energy storage rebound device and the mounting base according to an embodiment of the invention

Fig. 6 is a schematic diagram illustrating an assembled structure of an energy storage rebound device according to an embodiment of the present invention.

Fig. 7 is a schematic diagram of another assembly structure of an energy storage rebound device according to an embodiment of the invention (the cover plate is omitted).

Fig. 8 and 9 are schematic exploded views of an energy storage rebound device according to an embodiment of the invention.

Fig. 10 is a schematic diagram illustrating an assembled cross-sectional structure of an energy storage rebound device according to an embodiment of the present invention.

Fig. 11 is a schematic diagram of a heart-shaped chute according to an embodiment of the invention.

Fig. 12-14 are schematic diagrams of a press-open process according to an embodiment of the present invention.

Fig. 15-18 are schematic diagrams illustrating an automatic reset shutdown process according to an embodiment of the present invention.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Referring to fig. 1-18, the simple mounting structure of the present energy storage rebound device comprises a furniture component X, a furniture door Y, an energy storage rebound device and a mounting base 30. The energy storage rebound device comprises a rebound bracket, an elastic element 1 and a pushing element 2.

The mounting seat 30 is provided with a fixing part 31 for fixing and assembling, and is vertically installed inside the furniture component X through the fixing part 31.

The rebound bracket is provided with a heart-shaped chute 3, and a plurality of limit assembly matching parts are formed between the rebound bracket and the mounting seat 30; the rebound bracket and the mounting seat 30 are mounted in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; the elastic element 1 elastically acts on the rebound bracket and the pushing element 2 respectively; the pushing element 2 is provided with a movable piece 4, the pushing element 2 elastically slides on the rebound bracket in a telescopic way through the elastic element 1, and the movable piece 4 is driven to slide and/or position along the track of the heart-shaped chute 3 in a sequence direction during sliding.

The mounting block 30 and the rebound bracket are separately provided, and then a plurality of limit fitting portions are provided therebetween. When the energy storage rebound device is installed, the installation seat is firstly fixed on the inner side of the furniture component X through the fixing part, the rebound bracket is installed on the installation seat 30 in a sliding mode through a plurality of limit installation matching parts up and down, and/or left and right and/or front and back in a limiting mode, so that the installation and fixation of the energy storage rebound device on the inner side of the furniture component X can be realized, the defect that in the prior art, a notch part is required to be arranged on the furniture component X, or in addition, the installation of the energy storage rebound device can be completed only by using a tool for assistance is avoided, a user only needs to align the rebound bracket with the fixed installation seat 30 during the installation, and then the whole installation process can be completed through simple sliding, so that the installation operation of the user is facilitated.

Specifically, the rebound bracket is provided with a concave portion 32; the mounting seat 30 is mounted in the concave part 32 in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; wherein, the rebound bracket covers the mounting seat 30 through the concave part 32, and the outer side of the mounting seat 30 is basically level with the outer side of the rebound bracket.

Further, the plurality of limit fitting portions at least includes a bracket limit step 33 provided on the recess 32, and a mount limit step 34 provided on the mount 30.

The mounting seat 30 is placed in the concave portion 32 and is slidably clamped on the bracket limiting step 33 through the mounting seat limiting step 34, so that left and right limiting mounting between the rebound bracket and the mounting seat 30 is realized.

Wherein, the mounting seat limiting step 34 is provided with at least four, at least four mounting seat limiting steps 34 are respectively arranged at the front end, the rear end, the upper side and the lower side of the mounting seat 30. The bracket limiting steps 33 are provided in the same number as the mount limiting steps 34 and are provided at the corresponding positions of the recess 32. The cooperation of the plurality of mounting seat limiting steps 34 and the bracket limiting steps 33 can ensure the left and right limiting mounting between the rebound bracket and the mounting seat 30.

The plurality of limit assembly matching parts comprise a bracket elastic clamping position 35 arranged on the concave part 32 and a mounting seat elastic clamping position 36 arranged on the mounting seat 30.

The mounting seat 30 is placed in the concave portion 32, and is elastically clamped on the elastic clamping position 35 of the bracket in a sliding manner through the elastic clamping position 36 of the mounting seat, so that front and rear limiting mounting between the rebound bracket and the mounting seat 30 is realized.

The two elastic clamping positions 36 of the mounting seat are respectively arranged on the upper side and the lower side of the mounting seat 30, and the same number of elastic clamping positions 35 of the bracket are arranged corresponding to the elastic clamping positions 36 of the mounting seat and are arranged at the corresponding positions of the concave part 32. The cooperation between the plurality of mounting seat elastic clamping positions 36 and the bracket elastic clamping positions 35 can ensure the front and rear limit mounting between the rebound bracket and the mounting seat 30.

The number of limit fit fits further include raised locations 37 provided on the mount 30 and/or the recess 32.

The mounting seat 30 is placed in the concave part 32, and the two are mutually abutted through the convex position 37, so that the upper limit and the lower limit mounting between the rebound bracket and the mounting seat 30 are realized.

The two protruding positions 37 in this embodiment are disposed on the upper and lower sides of the mounting seat 30, and the two protruding positions 37 can respectively abut against the upper and lower positions of the recess 32, so as to ensure the upper and lower limiting installation between the rebound bracket and the mounting seat 30.

Namely, when the rebound bracket and the mounting seat 30 are mounted, the left and right limiting can be realized by utilizing the matching of the mounting seat limiting step 34 and the bracket limiting step 33, the front and rear limiting can be realized by utilizing the matching of the mounting seat elastic clamping position 36 and the bracket elastic clamping position 35, the up and down limiting can be realized by utilizing the abutting of the raised position 37, and further, the rebound bracket can be fixed on the inner side of the furniture component X in a left-right, front-back and up-down limiting manner, and the mounting stability of the rebound bracket is ensured.

The rebound bracket comprises a cover plate 14 and an assembly seat 15; the heart-shaped chute 3 is arranged on the cover plate 14; the cover plate 14 is fixedly covered on one side of the assembly seat 15; the other side of the assembly seat 15 is provided with a concave part 32; the mounting seat 30 is mounted in the concave part 32 in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; wherein, the assembly seat 15 is covered on the mounting seat 30 through the concave part 32, and the outer side surfaces of the assembly seat and the mounting seat are basically flush.

Because mount pad 30 can all be covered and shelter from, consequently not only can improve the installation wholeness of both, can also avoid because of mount pad 30 exposes, user or foreign matter touch easily in the use, lead to user's injury, or the problem that rebound support dropped, make the installation of rebound support more stable.

The pushing element 2 and/or the movable piece 4 are/is provided with a positioning part 6, and an elastic piece 5 is positioned by the positioning part 6, and two ends of the elastic piece 5 respectively and elastically act on the pushing element 2 and the movable piece 4.

One end of the movable piece 4 is rotatably or swingably arranged on the pushing element 2, the middle part of the movable piece is elastically connected with the pushing element 2 through an elastic piece 5, and the other end of the movable piece is provided with a sliding part 7.

The pushing element 2 drives the movable piece 4 to move along when in elastic telescopic sliding, the movable piece 4 drives the sliding part 7 to generate elastic friction force with the assembly seat 15 all the time through the elastic piece 5 when moving, and the sliding part 7 slides and/or is positioned along the track of the heart-shaped chute 3 all the time along a sequence direction through the elastic friction force.

The elastic piece 5 is respectively and elastically acted on the pushing element 2 and the movable piece 4, so that the movable piece 4 is always and elastically acted on the rebound bracket through the elastic piece 5, and therefore, when the pushing element 2 elastically stretches and slides, elastic friction force can be generated between the movable piece 4 and the rebound bracket, assembly gaps among the rebound bracket, the pushing element 2 and the movable piece 4 are reduced, assembly among the rebound bracket, the pushing element 2 and the movable piece 4 is more compact and stable, and limiting movement of the movable piece 4 can be realized. Namely, when the pushing element 2 performs pushing telescopic sliding on the rebound support, the movable piece 4 can rotate or swing along the pushing element 2 and always slide and/or position along the track of the heart-shaped chute 3 in a sequence direction through elastic friction force, so that the problem that the movable piece 4 is difficult to slide along the track of the heart-shaped chute 3 in a sequence direction due to self rotation or swinging force, elastic acting force of an elastic element, or pushing acting force and the like, and even the problem that the heart-shaped chute 3 is blocked and cannot move is solved, and further, the pushing element 2 can be rebound to open and slide to be closed on the rebound support under any condition no matter whether the pushing element 2 is assembled in a longitudinal mode, an oblique mode, a transverse mode or a flip-chip mode, so that the service stability of a product is improved.

The elastic friction force generated by the movable piece 4 is larger than the rotation or swing force generated by the movable piece.

As can be seen from the above description, the elastic friction force is the force of the movable member 4 acting on the rebound support through the elastic member 5 when the pushing member 2 elastically slides in an expanding manner, and the rotation or swing force is the rotation or swing force generated by the end of the movable member 4 in a natural state when the rebound support is vertically mounted. Since the elastic friction force is greater than the rotation or swinging force, the movable element 4 will not generate any displacement phenomenon due to the action of the elastic friction force when stationary, so as to ensure that the movable element is always slid and/or positioned along the track of the heart-shaped chute 3 in a sequential direction when the pushing element 2 elastically slides in a telescopic manner.

The heart-shaped chute 3 is provided with a first limit sliding area 8, a first conversion position 9, an inclined guiding area 10, a heart-shaped stay area 11, a second conversion position 12 and a second limit sliding area 13.

As shown in fig. 12 to 14, when the pushing element 2 slides into the mounting seat 15, the movable element 4 is driven to slide in the direction of the heart-shaped chute 3, the sliding part 7 is limited to slide into the first limit sliding area 8 by elastic friction force when the movable element 4 slides into a certain position, the sliding part 7 slides along the track of the first conversion bit 9 when the first limit sliding area 8 slides into a certain position, and is limited to slide onto the inclined guiding area 10 by the elastic friction force and the cooperation of the elastic element 1, and finally slides into and stays in the heart-shaped stay area 11 by the inclined guiding action of the inclined guiding area 10.

The sliding element 2 is positioned closed on the mounting seat 15 when the sliding part 7 is resting in the heart-shaped resting area 11.

As shown in fig. 15 to 18, when the sliding portion 7 stays in the heart-shaped stay region 11 and the pushing element 2 is pushed to slide relative to the assembly seat 15, the sliding portion 7 slides out of the heart-shaped stay region 11 by the driving of the pushing element 2 and slides along the track of the second conversion bit 12, and slides onto the second limit sliding region 13 by the elastic friction force and the cooperation of the elastic element 1.

The push element 2 is elastically extended out by the elastic element 1 and is opened on the mounting seat 15 when the sliding part 7 slides on the second limit sliding area 13.

The cover plate 14 is also provided with a guide part 16 corresponding to the heart-shaped chute 3, and the guide part 16 is positioned at the front end of the heart-shaped chute 3; the sliding part 7 is guided by a guiding part 16 to limit the sliding on the first limit sliding area 8 of the heart-shaped chute 3. That is, the sliding portion 7 can slide into the first limit sliding region 8 by the guiding action of the guiding portion 16 every time it slides in the direction of the heart-shaped chute 3.

An assembly cavity 17 is formed in the assembly seat 15, and a sleeve joint piece 18 is arranged on the assembly cavity 17; the elastic element 1 is a pressure spring and is sleeved on the sleeve joint piece 18, one end of the elastic element is elastically acted on the assembly cavity 17 or the sleeve joint piece 18, and the other end of the elastic element is elastically acted on the pushing element 2 and always generates elastic acting force towards the pushing element 2; the pushing element 2 is sleeved on the sleeve joint piece 18 and elastically stretches and contracts on the assembly cavity 17 through the elastic element 1; wherein the elastic force generated by the elastic element 1 is larger than the elastic force generated by the elastic piece 5. When the pushing element 2 is positioned and closed on the rebound support, the elastic element 1 is compressed and stored energy, and when the pushing element 2 is pressed, the energy can be released and the elastic element is elastically opened relative to the rebound support.

In order to realize the automatic reset of the pushing element 2, the rebound bracket is also provided with a control circuit board 19, a power supply element 20 and a reset driving assembly 21 which are respectively and electrically connected with the control circuit board 19; the reset driving assembly 21 is in driving connection with the pushing element 2; the control circuit board 19 obtains working power through the power supply element 20 and drives the reset driving assembly 21 to reciprocate on the rebound bracket.

As shown in fig. 15-17, when the rebound bracket is elastically extended and opened, the reset driving assembly 21 drives the push element 2 to automatically reset and slide in and be positioned and closed on the rebound bracket under the control of the control circuit board 19.

As shown in fig. 17 and 18, the reset driving assembly 21 is reset to the initial position by the control of the control circuit board 19 when the pushing element 2 is closed, and waits for the next operation.

The foregoing is a preferred embodiment of the invention showing and describing the general principles, features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the foregoing embodiments, which have been described in the foregoing embodiments and description merely illustrates the principles of the invention, and that various changes and modifications may be effected therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a simple and convenient mounting structure of energy storage bounce device, includes energy storage bounce device, and this energy storage bounce device includes bounce bracket, elastic element (1) and pushing element (2), its characterized in that: the device also comprises a mounting seat (30), wherein a fixing part (31) for fixing and assembling is arranged on the mounting seat (30); a heart-shaped chute (3) is arranged on the rebound bracket, and a plurality of limit assembly matching parts are formed between the rebound bracket and the mounting seat (30); the rebound bracket and the mounting seat (30) are mounted in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; the elastic element (1) respectively elastically acts on the rebound bracket and the pushing element (2); the pushing element (2) is provided with a movable piece (4), the pushing element (2) elastically stretches and slides on the rebound bracket through the elastic element (1), and the movable piece (4) is driven to slide and/or position along the track of the heart-shaped chute (3) in a sequence direction when sliding;

the rebound bracket comprises a cover plate (14) and an assembly seat (15); the heart-shaped chute (3) is arranged on the cover plate (14); the cover plate (14) is fixedly covered on one side of the assembly seat (15); a concave part (32) is arranged on the other side of the assembly seat (15); the mounting seat (30) is mounted in the concave part (32) in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; wherein, the assembly seat (15) is covered on the installation seat (30) through the concave part (32) completely, and the outer side surfaces of the assembly seat and the installation seat are basically level;

The heart-shaped sliding chute (3) is provided with a first limit sliding area (8), a first conversion bit (9), an inclined guiding area (10), a heart-shaped stay area (11), a second conversion bit (12) and a second limit sliding area (13);

When the pushing element (2) slides into the assembly seat (15), the movable piece (4) is driven to slide towards the direction of the heart-shaped sliding groove (3), the sliding part (7) is limited to slide into the first limit sliding area (8) through elastic friction force when the movable piece (4) slides to a certain position, the sliding part (7) slides along the track of the first conversion position (9) when the first limit sliding area (8) slides to a certain position, and is limited to slide onto the inclined guide area (10) through the elastic friction force and the cooperation of the elastic element (1), and finally slides into and stays in the heart-shaped stay area (11) through the inclined guide action of the inclined guide area (10);

the pushing element (2) is positioned and closed on the assembly seat (15) when the sliding part (7) stays in the heart-shaped stay area (11);

When the sliding part (7) stays in the heart-shaped stay area (11) and the pushing element (2) slides relative to the assembly seat (15) in a pressing way, the sliding part (7) slides out of the heart-shaped stay area (11) through the driving of the pushing element (2) and slides along the track of the second conversion bit (12), and slides to the second limit sliding area (13) through the cooperation of elastic friction force and the elastic element (1);

When the sliding part (7) slides onto the second limit sliding area (13), the pushing element (2) elastically stretches out and opens on the assembly seat (15) through the elastic element (1);

The rebound bracket is provided with a concave part (32); the mounting seat (30) is mounted in the concave part (32) in an up-down and/or left-right and/or front-back limit manner through a plurality of limit mounting matching parts; wherein, the rebound support is covered on the mounting seat (30) through the concave part (32), and the outer side of the mounting seat (30) is basically level with the outer side of the rebound support.

2. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: the plurality of limit assembly matching parts at least comprise bracket limit steps (33) arranged on the concave parts (32) and mounting seat limit steps (34) arranged on the mounting seats (30); the mounting seat (30) is placed in the concave part (32) and is clamped on the bracket limiting step (33) in a sliding mode through the mounting seat limiting step (34) so as to realize left and right limiting mounting between the rebound bracket and the mounting seat (30).

3. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: the plurality of limit assembly matching parts comprise bracket elastic clamping positions (35) arranged on the concave parts (32) and mounting seat elastic clamping positions (36) arranged on the mounting seats (30); the mounting seat (30) is placed in the concave part (32) and is elastically clamped on the support elastic clamping position (35) in a sliding mode through the mounting seat elastic clamping position (36) so as to realize front-back limiting mounting between the rebound support and the mounting seat (30).

4. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: the plurality of limit assembly matching parts also comprise raised positions (37) arranged on the mounting seat (30) and/or the concave part (32); the mounting seat (30) is placed in the concave part (32) and the mounting seat and the concave part are mutually abutted through the convex position (37) so as to realize the up-down limiting mounting between the rebound bracket and the mounting seat (30).

5. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: a positioning part (6) is arranged on the pushing element (2) and/or the movable piece (4), an elastic piece (5) is positioned by the positioning part (6), and two ends of the elastic piece (5) respectively elastically act on the pushing element (2) and the movable piece (4);

One end of the movable piece (4) is rotatably or swingably arranged on the pushing element (2), the middle part of the movable piece is elastically connected with the pushing element (2) through an elastic piece (5), and the other end of the movable piece is provided with a sliding part (7);

The pushing element (2) drives the movable piece (4) to move along when in elastic telescopic sliding, the movable piece (4) drives the sliding part (7) to generate elastic friction force with the assembly seat (15) all the time through the elastic piece (5) when in moving, and the sliding part (7) slides and/or is positioned along the track of the heart-shaped chute (3) all the time according to a sequence direction through the elastic friction force;

the elastic friction force generated by the movable piece (4) is larger than the rotation or swing force generated by the movable piece.

6. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: the cover plate (14) is also provided with a guide part (16) corresponding to the heart-shaped chute (3), and the guide part (16) is positioned at the front end of the heart-shaped chute (3); the sliding part (7) is guided and limited on a first limit sliding area (8) of the heart-shaped chute (3) through a guide part (16);

an assembly cavity (17) is formed in the assembly seat (15), and a sleeve joint piece (18) is arranged on the assembly cavity (17); the elastic element (1) is a pressure spring and is sleeved on the sleeve joint piece (18), one end of the elastic element is elastically acted on the assembly cavity (17) or the sleeve joint piece (18), and the other end of the elastic element is elastically acted on the pushing element (2) and always generates elastic acting force towards the pushing element (2); the pushing element (2) is sleeved on the sleeve joint piece (18) and elastically stretches out and draws back on the assembly cavity (17) through the elastic element (1); wherein the elastic force generated by the elastic element (1) is larger than the elastic force generated by the elastic piece (5).

7. The easy-to-install structure of the energy storage rebound device of claim 1, wherein: the rebound bracket is also provided with a control circuit board (19), a power supply element (20) and a reset driving assembly (21) which are respectively and electrically connected with the control circuit board (19); the reset driving assembly (21) is in driving connection with the pushing element (2); the control circuit board (19) acquires working power through the power supply element (20) and drives the reset driving assembly (21) to reciprocate on the rebound bracket;

When the rebound bracket is elastically stretched out and opened, the pushing element (2) is driven by the reset driving assembly (21) to automatically reset and slide in through the control of the control circuit board (19), and is positioned and closed on the rebound bracket; the reset driving assembly (21) is reset to an initial position by the control of the control circuit board (19) when the pushing element (2) is closed.