CN110873272A - Fixing support - Google Patents

Abstract

A fixing support. The fixing support is used for being fixed on a setting surface and connected with an object and comprises a base and a connecting unit; the base is used for being fixed on the setting surface; the connecting unit is connected with the base and comprises a unit inclined plane and at least one unit abutting part; the object comprises at least one object abutting part, when the object is in a separated state, the object abutting part is separated from the unit abutting part, when the object is in a connected state, the object abutting part abuts against the unit abutting part, and when the object moves from the separated state to the connected state, the object abuts against the unit inclined plane and slides relative to the unit inclined plane. The invention can easily fix the object on the setting surface, and the user can easily complete the connection between the object and the fixed bracket only by pushing the object upwards or slightly rotating the object, and the safety of the connection between the object and the fixed bracket is improved.

Description

Fixing support

Technical Field

The present disclosure relates to fixing supports, and particularly to a fixing support for fixing an object to a setting surface.

Background

Known wireless routers are fixed above the ceiling by means of a fixed bracket. The wireless router is combined with the fixed bracket in a screw locking mode and the like. Since the wireless router has a considerable weight and requires multiple screws to be locked at multiple angles. The process of locking the wireless router to the fixed bracket often cannot be completed by a single user, which is time-consuming and has safety concerns.

Therefore, it is desirable to provide a fixing bracket to solve the above problems.

Disclosure of Invention

The present invention provides a fixing bracket for fixing to a setting surface and connecting to an object, the fixing bracket including a base and a connecting unit; the base is used for being fixed on the setting surface; the connecting unit is connected with the base and comprises a unit inclined plane and at least one unit abutting part; the object comprises at least one object abutting part, when the object is in a separated state, the object abutting part is separated from the unit abutting part, when the object is in a connected state, the object abutting part abuts against the unit abutting part, and when the object moves from the separated state to the connected state, the object abuts against the unit inclined plane and slides relative to the unit inclined plane.

In one embodiment, the object rotates around an axis between a first object orientation and a second object orientation relative to the connecting unit, when the object is in the first object orientation, the object abutting portion is separated from the unit abutting portion, when the object is in the second object orientation, the object abutting portion abuts against the unit abutting portion to limit the movement of the object relative to the fixed bracket in the axial direction of the axis, and when the object rotates from the first object orientation to the second object orientation, the object abuts against the unit inclined surface and slides relative to the unit inclined surface.

In one embodiment, the connection unit includes a first tray and a second tray, the first tray is connected to the base, the first tray is opposite to the second tray, the unit slope is formed on the first tray and faces the second tray, the unit abutting portion is formed on the second tray and faces the first tray, the second tray has at least one tray notch, and when the object is in the first object orientation, the object abutting portion corresponds to the tray notch.

In one embodiment, the object abutting portion includes a cantilever, and the object abutting portion abuts against and slides relative to the unit inclined surface during rotation of the object from the first object orientation to the second object orientation.

In an embodiment, the connection unit further includes a retaining wall and a limiting block, the retaining wall connects the first tray and the second tray, the limiting block is disposed on the second tray and protrudes toward the first tray, when the object is located at the second object position, the object abutting portion abuts against the unit abutting portion, and the object abutting portion is limited between the retaining wall and the limiting block.

In one embodiment, the connection unit includes a bracket housing, a rotating member and a compression spring, the bracket housing is connected to the base, the rotating member is rotatably disposed in the bracket housing, one end of the compression spring abuts against the base, the other end of the compression spring abuts against the rotating member, and the unit inclined plane and the unit abutting portion are disposed on the rotating member.

In one embodiment, the rotating member rotates between a first rotating member state and a second rotating member state, the object abutting portion is separated from the unit abutting portion when the rotating member is in the first rotating member state, and the object abutting portion abuts the unit abutting portion when the rotating member is in the second rotating member state.

In one embodiment, the object includes a plurality of object ramp structures, the rotating member includes a plurality of rotating member ramp structures, the unit ramp is formed on the rotating member ramp structures, and the object ramp structures contact the rotating member ramp structures and push the rotating member during movement of the object from a first object position to a second object position to adapt the rotating member to switch between the first rotating member state and the second rotating member state.

In one embodiment, the rotating member further includes a plurality of engaging protrusions arranged around an axis, the holder housing includes a plurality of first limiting walls and a plurality of second limiting walls, the first limiting walls and the second limiting walls are arranged alternately around the axis, the engaging protrusions pass over the first limiting walls when the rotating member is switched from the first rotating member state to the second rotating member state, and the engaging protrusions pass over the second limiting walls when the rotating member is switched from the second rotating member state to the first rotating member state.

In one embodiment, the first limiting walls are lower than the second limiting walls, when the object moves from the first object position to the second object position, the rotating member is moved from a first rotating member height to a second rotating member height, when the rotating member is at the second rotating member height, the engaging protrusions are higher than the first limiting walls, and the engaging protrusions are lower than the second limiting walls.

In one embodiment, the rotating member is further pushed from the second rotating member height to a third rotating member height by rotating the object when the object is at the second object position, and the engaging protrusions are higher than the second limiting walls when the rotating member is at the third rotating member height.

In one embodiment, each of the first restriction walls includes a first restriction wall guide surface, each of the second restriction walls includes a second restriction wall guide surface, and each of the fitting projections includes a fitting projection guide surface abutting the first restriction wall guide surface when the fitting projection passes over the first restriction wall and abutting the second restriction wall guide surface when the fitting projection passes over the second restriction wall.

In one embodiment, the object includes at least one object-limiting groove, the holder housing includes at least one housing-limiting protrusion located in the object-limiting groove, the housing-limiting protrusion moves along the object-limiting groove when the object is located at the second object position, the object is further rotated in a first object rotation direction such that the rotating member is moved from the second rotating member height to the third rotating member height, and when the object is to be rotated in a second object rotation direction, one side of the object-limiting groove abuts against the housing-limiting protrusion to prevent the object from rotating in the second object rotation direction, wherein the second object rotation direction is opposite to the first object rotation direction.

In one embodiment, the base includes a base limiting portion, and the rotating member includes a rotating member limiting portion, and the rotating member limiting portion abuts against the base limiting portion when the base and the connecting unit are assembled.

In one embodiment, the connecting unit includes a bracket housing, a torsion spring, and a stop piece, the bracket housing is connected to the base, the stop piece is pivotally connected to the bracket housing, the stop piece includes a first stop surface and a second stop surface, the first stop surface is opposite to the second stop surface, the unit inclined surface is formed on the first stop surface, the unit abutting portion is formed on the second stop surface, one end of the torsion spring abuts against the bracket housing, and the other end of the torsion spring abuts against the stop piece.

In one embodiment, the object comprises an object plate, the object plate comprises a first plate surface and a second plate surface, the first plate surface is opposite to the second plate surface, an object inclined surface is formed on the first plate surface, and the object inclined surface abuts against the unit inclined surface and pushes the stop piece to rotate in the process that the object moves from a first object position to a second object position.

In one embodiment, the stop piece rotates between a first stop piece orientation and a second stop piece orientation, the stop piece is pushed to the second stop piece orientation by the object from the first stop piece orientation in the process that the object moves from the first object position to the second object position, the stop piece returns to the first stop piece orientation from the second stop piece orientation under the elastic force provided by the torsion spring, and when the object is located at the second object position, the unit abutting part of the stop piece abuts against the surface of the second plate body.

In an embodiment, the connecting unit further includes a rotating member, the stopping piece further has a stopping piece sliding slot formed thereon, and the rotating member includes a guide post inserted into the stopping piece sliding slot and adapted to slide in the stopping piece sliding slot.

In an embodiment, the toggle member includes a ring, the guide post is disposed on the ring, the toggle member rotates between a first toggle member orientation and a second toggle member orientation, when the toggle member is in the first toggle member orientation, the stop piece is in the first stop piece orientation, and when the toggle member is rotated from the first toggle member orientation to the second toggle member orientation, the guide post slides in the stop piece sliding slot and pushes the stop piece to rotate to the second stop piece orientation.

By applying the fixing bracket of the embodiment of the invention, an object (such as a wireless router or other electronic devices) can be easily fixed on a setting surface (such as a ceiling). The user only needs to push the object upwards or slightly rotate the object to easily complete the connection between the object (such as a wireless router) and the fixed support, and the safety of the connection between the object and the fixed support is improved.

Drawings

Fig. 1 shows an exploded view of a first embodiment of a fixing bracket according to the invention.

Fig. 2A shows a detailed structure of the rotating member according to the first embodiment of the present invention.

FIG. 2B shows the detailed structure of the object according to the first embodiment of the present invention.

FIG. 2C shows a partial state of the article in a separated state according to the first embodiment of the present invention.

FIG. 2D shows a partial connection state of the article according to the first embodiment of the present invention.

FIG. 2E shows the object abutting against the unit inclined surface and sliding relative to the unit inclined surface according to the first embodiment of the present invention.

Fig. 3A, 3B and 3C illustrate a process of connecting an object to a fixing bracket according to a first embodiment of the present invention.

Fig. 4A shows the detailed structure of the rotating member and the bracket housing according to the first embodiment of the invention.

Fig. 4B shows the situation that the engaging protrusion of the first embodiment of the present invention is engaged between the first limiting wall and the second limiting wall.

Fig. 5A and 5B show the process of the engaging protrusion crossing the second limiting wall according to the first embodiment of the invention.

Fig. 6A, 6B and 6C show the release process of the object from the fixing bracket according to the first embodiment of the present invention.

FIG. 7 shows an object-limiting groove and a housing-limiting protrusion according to a first embodiment of the present invention.

Fig. 8A and 8B show the base position-limiting portion 11 and the rotation-member position-limiting portion according to the first embodiment of the present invention.

Fig. 9A shows an exploded view of a mounting bracket according to a second embodiment of the invention.

Fig. 9B shows an assembly view of a fixing bracket according to a second embodiment of the present invention.

FIG. 10A shows the second embodiment of the present invention with the object in the first object orientation.

FIG. 10B shows the second embodiment of the present invention with the article in the second article orientation.

Fig. 11A shows an exploded view of a mounting bracket according to a third embodiment of the invention.

Fig. 11B shows a combination view of a fixing bracket according to a third embodiment of the present invention.

Fig. 12 shows a detailed structure of a baffle plate of a third embodiment of the invention.

Fig. 13A, 13B and 13C show a process of connecting an object to a fixing bracket according to a third embodiment of the present invention.

Fig. 14A and 14B show a process of detaching an object from a fixing bracket according to a third embodiment of the present invention.

Description of the main component symbols:

b1 fixed support 44 stopper

AP1 article B3 fixed bolster

1 base AP3 article

11 base limiting part 5 base

2 connecting unit 6 connecting unit

21 cradle housing 601 unit ramp

211 first limit wall 602 unit abutting part

212 second limiting wall 61 bracket housing

213 first limit wall guide surface 62 torsion spring

214 second limiting wall guide surface 63 stop piece

215 housing stop projection 631 first catch surface

22 rotor 632 second stop surface

Chute with 633 baffle plates for 221 unit

222 unit contact part 64 toggle

223 rotating part inclined surface structure 641 guide pillar

224 engaging projection 81 article abutment

225 fitting projection guide surface 82 object ramp structure

226 rotating member limiting portion 83 object limiting groove

23 compression spring 85 article abutment

B2 fixed bracket 91 article plate

First plate surface of AP2 object 911

3 second plate surface of base 912

4 attachment unit 913 object ramp

401 unit inclined plane C axle center

402 unit contact part Z axis

41 first tray α 1 first object rotation direction

42 second disk α 2 second object rotational direction

43 barricade

Detailed Description

Referring to fig. 1, there is shown an exploded view of a mounting bracket B1 according to a first embodiment of the present invention. The fixing bracket B1 is used to be fixed on a setting surface (e.g., a ceiling, not shown) and connected with an object AP1 (e.g., a wireless router or other electronic device). The fixing bracket B1 includes a base 1 and a connection unit 2. The base 1 is fixed to the installation surface. The connection unit 2 is connected to the base 1.

Referring to fig. 1, in an embodiment, the connection unit 2 includes a bracket housing 21, a rotation member 22 and a compression spring 23, the bracket housing 21 is connected to the base 1, the rotation member 22 is rotatably disposed in the bracket housing 21, one end of the compression spring 23 abuts against the base 1, and the other end of the compression spring 23 abuts against the rotation member 22. The compression spring 23 serves to provide an elastic restoring force.

Fig. 2A shows a detailed structure of the rotating member 22 according to the first embodiment of the present invention. Referring to fig. 2A, the connection unit 2 includes a unit inclined surface 221 and at least one unit abutting portion 222. The unit inclined surface 221 and the unit abutting portion 222 are provided on the rotating member 22. FIG. 2B shows the detailed structure of the article AP1 according to the first embodiment of the present invention. Referring to fig. 2B, the article AP1 includes at least one article abutment 81. Referring to fig. 2C and 2D, when the article AP1 is in a separated state (fig. 2C), the article abutting portion 81 is separated from the cell abutting portion 222. When the object is in a connected state (fig. 2D), the object abutting portion 81 abuts against the cell abutting portion 222. Referring to fig. 2E, during the process that the object AP1 moves from the detached state to the connected state, the object AP1 abuts against the cell inclined surface 221 and slides relative to the cell inclined surface 221.

Referring to fig. 2C and 2D, in this embodiment, the rotation member 22 is rotated to switch between the separated state and the connected state. The rotary member 22 rotates between a first rotary member state (fig. 2C, disconnected state) and a second rotary member state (fig. 2D, connected state). When the rotating member 22 is in the first rotating member state, the object abutting portion 81 is separated from the unit abutting portion 222. When the rotating member 22 is in the second rotating member state, the object abutting portion 81 abuts against the unit abutting portion 222.

With reference to fig. 2B and 2E, in one embodiment, the object includes a plurality of object bevel structures 82, the rotator includes a plurality of rotator bevel structures 223, and the unit bevel 221 is formed on the rotator bevel structures 223. Referring to fig. 2E and 3A-3C, during the movement of the object AP1 from a first object position (fig. 3A, detached state) to a second object position (fig. 3B), the object ramp structure 82 contacts the rotator ramp structure 223 and pushes the rotator 22 such that the rotator 22 is adapted to rotate from the first rotator state to the second rotator state (by the distance of one rotator ramp structure 223). Thus, the object AP1 is engaged with the rotating member 22. After the object AP1 completes the engagement with the rotating member 22, the user releases the object AP1 and the object AP1 falls back to the first object position (FIG. 3C, connected state).

Through the above design, the object AP1 can be easily hung on the installation surface through the fixing bracket B1.

Referring to fig. 4A, in one embodiment, the rotating member 22 further includes a plurality of engaging protrusions 224 arranged around an axis C, and the engaging protrusions 224 are located on an outer wall of the rotating member 22. The bracket housing 21 includes a plurality of first limiting walls 211 and a plurality of second limiting walls 212, and the first limiting walls 211 and the second limiting walls 212 are staggered around the inner wall of the rotating member 22. The engaging projections 224 pass over the first limiting walls 211 when the rotating member 22 is switched from the first rotating member state to the second rotating member state, and the engaging projections 224 pass over the second limiting walls 212 when the rotating member 22 is switched from the second rotating member state to the first rotating member state. Referring to fig. 4B, the situation that the fitting protrusion 224 is fitted between the first limiting wall 211 and the second limiting wall 212 is shown. The design of the engaging protrusion 224 between the first limiting wall 211 and the second limiting wall 212 can prevent the rotating member 22 from rotating relative to the bracket shell 21 due to shaking.

With reference to fig. 3A to 3C, fig. 4A and 4B, in an embodiment, the height of the first limiting walls 211 is smaller than that of the second limiting walls 212. When the object AP1 moves from the first object position (fig. 3A) to the second object position (fig. 3B), the rotating member 22 is moved from a first rotating member height to a second rotating member height, and when the rotating member 22 is at the second rotating member height, the engaging protrusions 224 are higher than the first limiting walls 211. Thereby, the rotating member 22 can easily rotate and pass over the first limiting walls 211, and the engagement connection between the object AP1 and the rotating member 22 is completed.

The release process of the article AP1 to disengage from the fixed bracket B1 is described below. Referring to fig. 6A-6C, the release process of the article AP1 from the fixed bracket B1 is shown. When it is desired to detach the object AP1 from the fixed bracket B1, in the state where object AP1 is connected to the fixed bracket B1, the object AP is translated upward from the first object position (FIG. 6A, connected state) to the second object position (FIG. 6B). Next, referring to fig. 5A and 5B in combination, by rotating the object AP1 (fig. 6B), the object inclined surface structure 82 further pushes the rotating member inclined surface structure 223, so that the rotating member 22 is further pushed from the second rotating member height (fig. 5A) to a third rotating member height (fig. 5B), and when the rotating member 22 is at the third rotating member height (fig. 5B), the engaging protrusions 224 are higher than the second limiting walls 212. Thus, the engaging protrusions 224 can pass over the second limiting walls 212, so that the rotating member 22 is switched from the second rotating member state to the first rotating member state, and the object AP1 is adapted to be detached from the fixed bracket B1 (fig. 6C). Through the design, the object AP1 can be prevented from being separated from the fixed bracket B1 due to the pure up-and-down translation, and the safety is improved.

Referring to fig. 4A, in one embodiment, each of the first retaining walls 211 includes a first retaining wall guide surface 213, each of the second retaining walls 212 includes a second retaining wall guide surface 214, each of the engagement projections 224 includes an engagement projection guide surface 225, the engagement projection guide surface 225 abuts the first retaining wall guide surface 213 when the engagement projection 224 passes over the first retaining wall 211, and the engagement projection guide surface 225 abuts the second retaining wall guide surface 214 when the engagement projection 224 passes over the second retaining wall 212. The first stopper wall guide surface 213 and the second stopper wall guide surface 214 can guide the fitting projection 224 to smoothly fall between the first stopper wall 211 and the second stopper wall 212.

Referring to fig. 7, the object includes at least one object retaining groove 83, the bracket housing 21 includes at least one housing retaining protrusion 215 located in the object retaining groove 83. referring to fig. 6B and 7, in the above embodiment, when the object AP1 is located at the second object position, the housing retaining protrusion 215 moves along the object retaining groove 83, the rotator 22 is further pushed from the second rotator height to the third rotator height by rotating the object AP1 in a first object rotation direction α 1, when the object AP1 intends to rotate in a second object rotation direction α 2, one side of the object retaining groove 83 abuts against the housing retaining protrusion 215 to prevent the object AP1 from rotating in the second object rotation direction α 2, the second object rotation direction α 2 being opposite to the first object rotation direction α 1.

Referring to fig. 8A and 8B, in an embodiment, the base 1 includes a base limiting portion 11, and the rotation member 22 includes a rotation member limiting portion 226, when the base 1 is assembled with the connection unit 2, the rotation member limiting portion 226 abuts against the base limiting portion 11, so as to prevent the rotation member 22 from rotating relative to the bracket shell 21 during assembly.

Fig. 9A shows an exploded view of a second embodiment of a mounting bracket B2 of the present invention. Fig. 9B shows an assembly view of a fixing bracket B2 of the second embodiment of the present invention. Referring to fig. 9A and 9B, in this embodiment, the fixing bracket B2 includes a base 3 and a connecting unit 4. The base 3 is fixed to the installation surface. With reference to fig. 10A and 10B, the object AP2 rotates about an axis Z relative to the connecting unit 4 between a first object orientation (fig. 10A) and a second object orientation (fig. 10B). Referring to fig. 10A, when the item AP2 is in the first item orientation, item abutment 85 is separated from cell abutment 402. Referring to fig. 10B, when the object AP2 is in the second object orientation, the object abutment 85 abuts the unit abutment 402 to restrict movement of the object AP2 relative to the fixed bracket B2 in the axial direction of the axis Z. During rotation of the article from the first article orientation to the second article orientation, the article AP2 abuts the cell ramp 401 and slides along the cell ramp 401.

Referring to fig. 9A, in an embodiment, the connection unit 4 includes a first tray 41 and a second tray 42, the first tray 41 is connected to the base 3, the first tray 41 is opposite to the second tray 42, the unit inclined plane 401 is formed on the first tray 41 and faces the second tray 42, the unit abutting portion 402 is formed on the second tray 42 and faces the first tray 41, the second tray 42 has at least one tray notch 421, and the object abutting portion 85 corresponds to the tray notch 421 when the object AP2 is in the first object orientation (refer to fig. 10A).

Referring to fig. 10A and 10B, in one embodiment, the article abutment 85 comprises a cantilever, and the article abutment 85 abuts the unit slope 401 and slides along the unit slope 401 during the rotation of the article AP2 from the first article orientation to the second article orientation.

Referring to fig. 10A and 10B, in an embodiment, the connection unit 4 further includes a retaining wall 43 and a stopper 44, the retaining wall 43 connects the first tray 41 and the second tray 42, and the stopper 44 is disposed on the second tray 42 and faces the first tray 41. When the object AP2 is in the second object orientation, the object abutting portion 85 abuts against the unit abutting portion 402, and the object abutting portion 85 is confined between the retaining wall 43 and the stopper 44.

Referring to fig. 11A and 11B, a fixing bracket B3 for being fixed to a mounting surface (not shown) and connected to an object AP3 according to a third embodiment of the present invention is shown. The fixing bracket B3 includes a base 5 and a connecting unit 6. The base 5 is fixed to the installation surface. The connecting unit 6 is connected to the base 5, the connecting unit 6 includes a bracket shell 61, a torsion spring 62 and a stopping sheet 63, the bracket shell 61 is connected to the base 5, the stopping sheet 63 is pivotally connected to the bracket shell 61, and the stopping sheet 63 includes a first stopping surface 631 and a second stopping surface 632. Referring to fig. 12, the first stop surface 631 is opposite to the second stop surface 632. The unit inclined surface 601 is formed on the first stopping surface 631, the unit abutting portion 602 is formed on the second stopping surface 632, one end of the torsion spring 62 abuts against the bracket shell 61, and the other end of the torsion spring 62 abuts against the stopping piece 63.

Referring to fig. 11A, 12, 13A, 13B and 13C, in one embodiment, the object AP3 includes an object plate 91, the object plate 91 includes a first plate surface 911 and a second plate surface 912, the first plate surface 911 is opposite to the second plate surface 912, and an object bevel 913 is formed on the first plate surface 911. During the movement of the article AP3 from a first article position (fig. 13A) to a second article position (fig. 13C), the article inclined surface 913 abuts the unit inclined surface 601 and pushes the stopper 63 to rotate (fig. 13B). Whereby the object AP3 can smoothly reach the second object position (FIG. 13C).

Referring to fig. 13A, 13B and 3C, in one embodiment, the stopper piece 63 rotates between a first stopper piece orientation and a second stopper piece orientation, and during the movement of the article AP3 from the first article position (fig. 13A, detached state) to the second article position (fig. 13C, attached state), the stopper piece is pushed by the article from the first stopper piece orientation (fig. 13A) to the second stopper piece orientation (fig. 13B) and returns from the second stopper piece orientation (fig. 13B) to the first stopper piece orientation (fig. 13C) by an elastic force provided by the torsion spring 62. When the article AP3 is in the second article position (fig. 13C, connected state), the unit abutting portion 602 of the stopper piece 63 abuts against the second plate body surface 912.

Referring to fig. 11A, fig. 14A and fig. 14B, in an embodiment, the connection unit 6 further includes a rotation member 64, the stop sheet 63 further has a barrier slide groove 633 formed thereon, and the rotation member 64 includes a guide post 641, the guide post 641 is inserted into the barrier slide groove 633 and is adapted to slide in the barrier slide groove 633. Toggle member 64 is used by a user to detach the item AP3 from the fixed bracket B3.

Referring to fig. 11A, 14A and 14B, in one embodiment, the toggle member 64 includes a ring, the guide post 641 is disposed on the ring, the toggle member 64 rotates between a first toggle member orientation (fig. 14A) and a second toggle member orientation (14 th B), and the stop tab 63 is in the first stop tab orientation when the toggle member 64 is in the first toggle member orientation (fig. 14A). When the toggle piece 64 is rotated from the first toggle piece orientation (fig. 14A) to the second toggle piece orientation (fig. 14B), the guide post slides in the stop slot 633 and pushes the stop piece 63 to rotate to the second stop piece orientation, whereby the fixed bracket B3 releases the object AP 3.

By applying the fixing bracket of the embodiment of the invention, an object (such as a wireless router or other electronic devices) can be easily fixed on a setting surface (such as a ceiling). The user only needs to push the object upwards or slightly rotate the object to easily complete the connection between the object (such as a wireless router) and the fixed support, and the safety of the connection between the object and the fixed support is improved.

Although the present invention has been described with respect to the preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (19)

1. A fixing support is used for being fixed on an arrangement surface and being connected with an object, and comprises:

a base, which is used for fixing on the setting surface; and

the connecting unit is connected with the base and comprises a unit inclined plane and at least one unit abutting part;

the object comprises at least one object abutting part, when the object is in a separated state, the object abutting part is separated from the unit abutting part, when the object is in a connected state, the object abutting part abuts against the unit abutting part, and when the object moves from the separated state to the connected state, the object abuts against the unit inclined plane and slides relative to the unit inclined plane.

2. The fixing bracket as claimed in claim 1, wherein the object rotates about an axis relative to the connecting unit between a first object orientation and a second object orientation, the object abutting portion is separated from the unit abutting portion when the object is in the first object orientation, the object abutting portion abuts the unit abutting portion when the object is in the second object orientation to restrict movement of the object relative to the fixing bracket in the axial direction of the axis, and the object abuts the unit inclined surface and slides relative to the unit inclined surface in a process of rotating the object from the first object orientation to the second object orientation.

3. The fixing bracket as claimed in claim 2, wherein the connection unit includes a first tray and a second tray, the first tray being connected to the base, the first tray opposing the second tray, the unit slope being formed on the first tray and facing the second tray, the unit abutment being formed on the second tray and facing the first tray, the second tray having at least one tray notch, the object abutment corresponding to the tray notch when the object is in the first object orientation.

4. The securing bracket as claimed in claim 3, wherein the object abutment portion includes a cantilever arm, the object abutment portion abutting and sliding relative to the unit inclined surface during rotation of the object from the first object orientation to the second object orientation.

5. The fixing bracket as claimed in claim 4, wherein the connecting unit further comprises a retaining wall connecting the first tray and the second tray, and a stopper disposed on the second tray and protruding toward the first tray, wherein when the object is in the second object orientation, the object abutting portion abuts against the unit abutting portion, and the object abutting portion is confined between the retaining wall and the stopper.

6. The fixing bracket of claim 1, wherein the connecting unit includes a bracket housing, a rotating member and a compression spring, the bracket housing is connected to the base, the rotating member is rotatably disposed in the bracket housing, one end of the compression spring abuts against the base, the other end of the compression spring abuts against the rotating member, and the unit inclined surface and the unit abutting portion are disposed on the rotating member.

7. The stationary bracket according to claim 6, wherein the rotary member rotates between a first rotary member state in which the object abutment portion is separated from the unit abutment portion and a second rotary member state in which the rotary member is in the second rotary member state in which the object abutment portion abuts the unit abutment portion.

8. The stationary bracket of claim 7, wherein the object includes a plurality of object ramp structures and the rotating member includes a plurality of rotating member ramp structures, the unit ramp being formed on the rotating member ramp structures, the object ramp structures contacting the rotating member ramp structures and urging the rotating member during movement of the object from a first object position to a second object position to adapt the rotating member between the first rotating member state and the second rotating member state.

9. The stationary bracket according to claim 8, wherein the rotary member further comprises a plurality of engaging projections arranged around an axis, the bracket housing comprises a plurality of first limit walls and a plurality of second limit walls, the first limit walls and the second limit walls being staggered around the axis, the engaging projections passing over the first limit walls when the rotary member is switched from the first rotary member state to the second rotary member state, and the engaging projections passing over the second limit walls when the rotary member is switched from the second rotary member state to the first rotary member state.

10. The fixing bracket as claimed in claim 9, wherein the first limiting walls are smaller in height than the second limiting walls, the rotating member is moved from a first rotating member height to a second rotating member height when the object is moved from the first object position to the second object position, the engaging protrusions are higher than the first limiting walls and the engaging protrusions are lower than the second limiting walls when the rotating member is at the second rotating member height.

11. The fixed bracket of claim 10, wherein the rotatable member is further advanced from the second rotatable member height to a third rotatable member height by rotating the object when the object is in the second object position, the engagement projections being higher than the second limiting walls when the rotatable member is at the third rotatable member height.

12. The fixing bracket as claimed in claim 11, wherein each of the first restriction walls includes a first restriction wall guide surface, each of the second restriction walls includes a second restriction wall guide surface, and each of the engagement projections includes an engagement projection guide surface abutting the first restriction wall guide surface when the engagement projection passes over the first restriction wall, and abutting the second restriction wall guide surface when the engagement projection passes over the second restriction wall.

13. The fixing bracket of claim 11, wherein the object includes at least one object-limiting groove, the bracket housing includes at least one housing-limiting protrusion located in the object-limiting groove, the housing-limiting protrusion moves along the object-limiting groove when the object is located at the second object position, the object is further rotated in a first object rotation direction such that the rotating member is moved from the second rotating member height to the third rotating member height, and when the object is to be rotated in a second object rotation direction, one side of the object-limiting groove abuts against the housing-limiting protrusion to prevent the object from rotating in the second object rotation direction, wherein the second object rotation direction is opposite to the first object rotation direction.

14. The fixing bracket as claimed in claim 11, wherein the base includes a base limiting portion, and the rotation member includes a rotation member limiting portion, and the rotation member limiting portion abuts against the base limiting portion when the base is assembled with the connecting unit.

15. The fixing bracket of claim 1, wherein the connecting unit includes a bracket housing, a torsion spring, and a stopper, the bracket housing is connected to the base, the stopper is pivotally connected to the bracket housing, the stopper includes a first stopper surface and a second stopper surface, the first stopper surface is opposite to the second stopper surface, the unit slope is formed on the first stopper surface, the unit abutting portion is formed on the second stopper surface, one end of the torsion spring abuts against the bracket housing, and the other end of the torsion spring abuts against the stopper.

16. The securing bracket as claimed in claim 15, wherein the object includes an object plate, the object plate includes a first plate surface and a second plate surface, the first plate surface is opposite to the second plate surface, an object inclined surface is formed on the first plate surface, and the object inclined surface abuts against the unit inclined surface and pushes the stopper piece to rotate during the movement of the object from a first object position to a second object position.

17. The fixing bracket as claimed in claim 16, wherein the stopping sheet rotates between a first stopping sheet orientation and a second stopping sheet orientation, the stopping sheet is pushed from the first stopping sheet orientation to the second stopping sheet orientation by the object in the process of moving the object from the first object position to the second object position, and returns from the second stopping sheet orientation to the first stopping sheet orientation by an elastic force provided by the torsion spring, and the unit abutting portion of the stopping sheet abuts against the surface of the second plate when the object is in the second object position.

18. The fixing bracket as claimed in claim 17, wherein the connecting unit further comprises a toggle member, the stop plate further has a stop plate sliding groove formed thereon, and the toggle member comprises a guide post inserted into the stop plate sliding groove and adapted to slide therein.

19. The fixed bracket of claim 17, wherein the toggle member comprises a ring, the guide post is disposed on the ring, the toggle member rotates between a first toggle member orientation and a second toggle member orientation, the stop tab is in the first stop tab orientation when the toggle member is in the first toggle member orientation, and the guide post slides within the stop slot and pushes the stop tab to rotate to the second stop tab orientation when the toggle member is rotated from the first toggle member orientation to the second toggle member orientation.

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