CN113931372B

CN113931372B - U-shaped hyperboloid aluminum square through clamp type mounting structure

Info

Publication number: CN113931372B
Application number: CN202111266752.9A
Authority: CN
Inventors: 白伟; 刘鸿卫; 孙志敏
Original assignee: Beijing Lby Building Decoration Engineering Co ltd
Current assignee: Beijing Lby Building Decoration Engineering Co ltd
Priority date: 2021-10-28
Filing date: 2021-10-28
Publication date: 2023-06-02
Anticipated expiration: 2041-10-28
Also published as: CN113931372A

Abstract

The application relates to a U type hyperboloid aluminium square tube anchor clamps formula mounting structure, including fossil fragments and aluminium square tube, the aluminium square tube includes the bottom plate and is fixed in the curved surface board of bottom plate both sides, the inside mounting groove that forms the opening up that forms of aluminium square tube, the both sides of mounting groove upper end are equipped with the limiting plate respectively, form the spread groove between two limiting plates, be equipped with mounting fixture between fossil fragments and the aluminium square tube, mounting fixture includes the supporting shoe of sliding connection in the aluminium square tube, the width of supporting shoe is less than the width of mounting groove, and be greater than the tip of spread groove, the upper end of supporting shoe is equipped with the connecting rod that stretches out in the follow spread groove and be used for linking to each other with the fossil fragments, the sliding tray has been seted up to the both sides of supporting shoe, the horizontal motion is connected with the clamping block in the sliding tray. Through the setting of mounting fixture, the supporting shoe can slide in curved mounting groove to after sliding to relevant position, press from both sides tight piece and can stretch out in the sliding tray and contradict with the mounting groove inner wall, thereby realize the fixed of supporting shoe.

Description

U-shaped hyperboloid aluminum square through clamp type mounting structure

Technical Field

The application relates to the field of building material installation, in particular to a U-shaped hyperboloid aluminum square through clamp type installation structure.

Background

The bamboo skin aluminum square tube is an indoor common ceiling decorative material, has transparent visual field, ventilation and ventilation, and has the effects of clear and tidy lines and distinct layers. The traditional aluminum square through modeling positioning is constructed by adopting an angle intersection method. The traditional aluminum square tubes are long straight, and along with the development of society, suspended ceilings are more and more diversified, the modeling of the aluminum square tubes is no longer regular, and the aluminum square tubes with hyperboloid sides are more and more.

The related art can refer to Chinese patent with publication number CN206091016U to disclose a U-shaped aluminum square tube, which comprises a keel, a U-shaped aluminum square tube and a bolt, wherein the keel is fixed on the ceiling, and the U-shaped aluminum square tube is connected with a keel hanging buckle or connected with the bolt; the U-shaped aluminum square tube solves the problems of difficult installation, unstable surface scratch and complex processing of the existing aluminum ceiling, and has the advantages of simple manual assembly, low material processing cost and beautiful decoration.

When the U-shaped aluminum square tube is installed, the aluminum square tube is connected with the hanging buckle on the keel, so that the aluminum square tube is installed, and when the U-shaped aluminum square tube is installed, the hanging buckle needs to slide to each position in the aluminum square tube from the end part of the aluminum square tube, so that the aluminum square tube is supported and connected. When the aluminum square tube is long-strip straight, the hanging buckle can slide along the length direction of the aluminum square tube so as to be installed, and the hyperboloid aluminum square tube is difficult to slide in the aluminum square tube due to the fact that the whole shape of the aluminum square tube is bent to be wavy, so that the installation of the aluminum square tube is affected.

Disclosure of Invention

In order to facilitate the installation of hyperboloid aluminium square tube, the application provides a U type hyperboloid aluminium square tube anchor clamps formula mounting structure.

The application provides a U type hyperboloid aluminium square through anchor clamps formula mounting structure adopts following technical scheme:

the utility model provides a U type hyperboloid aluminium square tube anchor clamps formula mounting structure, includes fossil fragments and aluminium square tube, aluminium square tube includes the bottom plate and is fixed in the curved surface board of bottom plate both sides, and the inside mounting groove that forms the opening up of aluminium square tube, the both sides of mounting groove upper end are equipped with the limiting plate respectively, form the spread groove between two limiting plates, the width of spread groove is less than the width of mounting groove, be equipped with mounting fixture between fossil fragments and the aluminium square tube, mounting fixture one end links to each other with fossil fragments, and the other end links to each other with the aluminium square tube, mounting fixture includes the supporting shoe of sliding connection in the aluminium square tube, the width of supporting shoe is less than the width of mounting groove, and is greater than the tip of spread groove, the upper end of supporting shoe is equipped with the connecting rod that stretches out in the follow spread groove and is used for linking to each other with fossil fragments, the sliding tray has been seted up to the both sides of supporting shoe, the smooth dynamic connection has the clamp block in the sliding tray.

Through adopting above-mentioned technical scheme, when installing aluminium square tube, slide the supporting shoe from the tip of aluminium square tube in the mounting groove, the connecting rod stretches out in the spread groove and links to each other with fossil fragments are fixed. At this time, the clamping block contracts in the sliding tray, leaves the clearance between the both sides of supporting shoe and the inner wall of mounting groove, and the supporting shoe can slide in curved mounting groove, even meet bent angle department, because the size of supporting shoe is less, has certain avoidance space in the mounting groove, can not block, and the supporting shoe can slide to relevant position. Then the clamping block slides out of the sliding groove to be abutted against the inner wall of the mounting groove, so that clamping and fixing are carried out. At this time, the upper end of the supporting block is connected with the keel through the connecting rod, the supporting block is connected with an aluminum square through the clamping block, and the aluminum square is fixedly connected with the keel through the mounting fixture to complete the mounting.

Optionally, vertical control hole has been seted up to the bottom of supporting shoe, the control hole is linked together with the sliding tray, sliding connection has the control rod that is used for controlling the clamp block motion in the control hole.

Through adopting above-mentioned technical scheme, when the supporting shoe slides in the mounting groove, upwards extrude aluminium square tube or upwards pull the supporting shoe for the bottom of supporting shoe hangs in the top of bottom plate, makes the control lever upwards or downward movement in the supporting shoe, thereby the control lever moves upwards and exerts effort to the clamping block and control clamping block and stretch out or retract the sliding groove, realizes the clamp of clamping block or relax.

Optionally, be equipped with reset spring on the clamping block, reset spring one end links to each other with the clamping block, and the other end links to each other with the supporting shoe, reset spring is in the natural state, the tip of clamping block contracts in the sliding tray.

By adopting the technical scheme, when the supporting block slides in the mounting groove, the supporting block is contracted in the sliding groove under the action of the return spring so as to facilitate the normal sliding of the supporting block. After the clamping block slides to the corresponding position, the control rod controls the clamping block, so that the clamping block extends out of the sliding groove and is abutted against the inner wall of the curved plate, the clamping is performed, and the position of the supporting block is limited.

Optionally, the one end that the control rod was pressed from both sides tight piece is established to the back taper, the diameter of control rod upper end is greater than the diameter of lower extreme, the outer wall of control rod is inconsistent with the one end that the tight piece was pressed from both sides tight piece towards the control hole, be equipped with control spring between the upper end of control rod and the control hole, when control spring is in natural state, control hole is stretched out to the lower extreme of control rod, control spring's elasticity is greater than reset spring's elasticity.

Through adopting above-mentioned technical scheme, when sliding the supporting shoe, operating personnel presses down the supporting shoe for the lower extreme of control lever is contradicted with the bottom plate, and the control lever overcomes control spring's elasticity, rises in the control hole, and the control lever is in-process that rises, because the diameter of control lever diminishes gradually, presss from both sides tight piece and contracts gradually in the sliding tray under reset spring's effect, thereby makes things convenient for sliding the supporting shoe. After the supporting block slides to the corresponding position, an operator releases the supporting block, the control rod moves downwards in the control hole under the action of the control spring and stretches out of the control hole, and the control rod extrudes the clamping block in the downward movement process, so that the end part of the clamping block stretches out of the sliding groove and is abutted against the inner wall of the curved plate.

Optionally, the rolling groove has been seted up to the lower extreme in control hole, roll in the rolling groove and be connected with the spin, the bottom in rolling groove is equipped with the roll mouth, the diameter of spin is greater than the diameter of roll mouth, the control lever keeps away from the one end of clamp block and contradicts with the spin.

Through adopting above-mentioned technical scheme, when the supporting shoe slides in the mounting groove, the bottom passes through spin and bottom plate contact, and frictional force is less, removes conveniently.

Optionally, the control rod is connected with the ball towards the one end rotation of spin.

Through adopting above-mentioned technical scheme, the spin is at the roll in-process, and the control lever is contradicted with the spin through the ball, and frictional force is less between the two, facilitates the use.

Optionally, a plurality of clamping grooves matched with the clamping blocks are formed in one side, facing each other, of the curved plate.

Through adopting above-mentioned technical scheme, after the supporting shoe removes to relevant position in the mounting groove, press from both sides tight piece and stretch out the block from the sliding tray and inlay in pressing from both sides tight inslot, press from both sides tight groove and supporting shoe mutually support, inject the position of supporting shoe, improve the stability of supporting shoe.

Optionally, vertical locking hole has been seted up to the upper end of supporting shoe, the locking hole is linked together with the sliding tray, vertical sliding connection has the locking lever in the locking hole, be equipped with locking spring on the locking lever, locking spring one end links to each other with the locking lever, and the other end links to each other with the supporting shoe, locking spring is in when nature state, and locking hole is stretched out to the upper end of locking lever, offered on the clamp block with locking lever matched with locking groove, when the tip of clamp block stretches out the sliding tray and contradicts with the curved plate, locking groove is just right with locking hole.

Through adopting above-mentioned technical scheme, after all supporting shoes all moved to relevant position, hoist aluminium square tube and link to each other with the fossil fragments, at this moment, aluminium square tube falls naturally under the action of gravity to make the up end of supporting shoe contradict with the lower surface of limiting plate, thereby push down the locking lever, the lower extreme of locking lever stretches out the locking hole and inserts the locking inslot, and the locking lever locks the clamping block, further improves the stability of clamping block, prevents that the clamping block from taking off.

In summary, the present application includes at least one of the following beneficial technical effects:

1. through the setting of mounting fixture, the supporting shoe can slide in curved mounting groove to after sliding to relevant position, press from both sides tight piece and can stretch out in the sliding tray and contradict with the mounting groove inner wall, thereby realize the fixed of supporting shoe.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a U-shaped hyperboloid aluminum square through clamp type mounting structure.

Fig. 2 is a schematic structural diagram of aluminum square tube in the embodiment.

Fig. 3 is a schematic structural view of the mounting jig in the embodiment.

Fig. 4 is a schematic view of the internal structure of the mounting jig in the embodiment.

Reference numerals illustrate: 1. a keel; 11. a support rod; 2. aluminum square tube; 21. a bottom plate; 22. a curved panel; 221. a clamping groove; 23. a mounting groove; 24. a limiting plate; 25. a connecting groove; 3. installing a clamp; 31. a support block; 311. a sliding groove; 312. a control hole; 313. a rolling groove; 314. a rolling port; 315. a locking hole; 32. a connecting rod; 4. a clamping block; 41. a return spring; 411. a reset plate I; 412. a reset plate II; 42. a locking groove; 5. a control lever; 51. a control spring; 52. a ball; 6. a rolling ball; 7. a locking lever; 71. a locking spring; 711. a first locking plate; 712. and a locking plate II.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses U type hyperboloid aluminium square tube anchor clamps formula mounting structure, refer to fig. 1, including fossil fragments 1, mounting fixture 3 and aluminium square tube 2. The aluminum square tube 2 is fixedly connected with the keel 1 through the mounting fixture 3.

Referring to fig. 1, the keel 1 is formed by a plurality of crisscross supporting rods 11, and the supporting rods 11 are fixedly connected with each other by bolts or welding.

Referring to fig. 2, the aluminum square tube 2 includes a bottom plate 21 and curved plates 22 fixed to both sides of the bottom plate 21, the curved plates 22 are wavy as a whole, and both sides of the bottom plate 21 are wavy as well, which are matched with the curved plates 22. The two curved plates 22 and the bottom plate 21 form an installation groove 23 with an upward opening, the top of the installation groove 23 is provided with a horizontal limiting plate 24, and the limiting plate 24 is provided with two curved plates 22 which are fixedly connected with the upper ends of the two curved plates 22 respectively. A gap is reserved between the two limiting plates 24 to form a connecting groove 25, and the width of the connecting groove 25 is smaller than that of the mounting groove 23.

Referring to fig. 1 and 2, a plurality of clamping grooves 221 for matching with the mounting fixture 3 are formed on the opposite sides of the curved plate 22, so as to improve the connection stability of the mounting fixture 3 and the aluminum square tube 2.

Referring to fig. 1 and 2, the mounting fixture 3 includes a support block 31 and a connection rod 32, and the connection rod 32 is fixedly connected to an intermediate position of the top of the support block 31. The supporting block 31 is slidably connected to the mounting groove 23, and the connecting rod 32 is inserted from the connecting groove 25. The upper end of connecting rod 32 links to each other with fossil fragments 1 is fixed, and supporting shoe 31 is located the mounting groove 23 and links to each other with aluminium square tube 2 to realize the installation of aluminium square tube 2 and fossil fragments 1.

Referring to fig. 2 and 3, the width of the support block 31 is greater than the width of the connection groove 25 to ensure that the support block 31 is not separated from the connection groove 25, the width of the support block 31 is less than the width of the installation groove 23, and the height of the support block 31 is less than the height of the installation groove 23 to ensure that the support block 31 can slide in the curved installation groove 23 to prevent jamming, and the height of the support block 31 is less than the height of the installation groove 23.

Referring to fig. 3 and 4, horizontal sliding grooves 311 are formed on both sides of the supporting block 31, and clamping blocks 4 are horizontally and movably connected in the sliding grooves 311, and the clamping blocks 4 may be completely retracted in the sliding grooves 311 or may partially extend out of the sliding grooves 311. When the supporting block 31 slides in the mounting groove 23, the clamping block 4 is retracted in the sliding groove 311, and when the clamping block 4 slides to the corresponding position, the clamping block 4 extends out of the sliding groove 311 to abut against the inner wall of the curved plate 22, so that the supporting block 31 is limited.

Referring to fig. 2 and 3, the end of the clamping block 4 facing the curved plate 22 is engaged with the clamping groove 221, and the clamping block 4 may be inserted into the clamping groove 221, thereby defining the clamping block 4 and the supporting block 31, and improving the stability of the supporting block 31.

Referring to fig. 4, a first reset plate 411 is fixed on the clamping block 4, a second reset plate 412 is fixed in the sliding groove 311, and a reset spring 41 between the first reset plate 411 and the second reset plate 412 is sleeved on the clamping block 4. One end of the reset spring 41 is fixedly connected with the first reset plate 411, and the other end is fixedly connected with the second reset plate 412. When the return spring 41 is in a natural state, the end of the clamp block 4 is retracted into the slide groove 311.

Referring to fig. 2 and 4, when the support block 31 is slidably adjusted in the mounting groove 23, the clamping block 4 is always retracted in the sliding groove 311 under the action of the return spring 41, so as to facilitate sliding of the support block 31 in the mounting groove 23, and prevent the clamping block 4 from suddenly extending to cause the clamping block 31 to be clamped.

Referring to fig. 4, a vertical control hole 312 is provided at a middle position of the bottom of the support block 31, and the control hole 312 is located at a middle of the two sliding grooves 311 and is simultaneously communicated with the two sliding grooves 311. A control rod 5 for controlling the movement of the clamping block 4 is slidably connected to the control hole 312. The upper end of the control rod 5 faces the clamping block 4 and is in an inverted cone shape, and the diameter of the upper end of the control rod 5 is larger than that of the lower end. The outer wall of the control rod 5 abuts against the end of the clamping block 4 facing the control rod 5.

Referring to fig. 4, when the control lever 5 moves upward in the control hole 312, the clamping block 4 is gradually retracted by the return spring 41 until the clamping block 4 is completely retracted in the sliding groove 311, thereby facilitating the sliding of the support block 31. When the support block 31 is slid to the corresponding position, the control lever 5 slides downward in the control hole 312, and the control lever 5 pushes the two clamp blocks 4 outward, thereby pushing the ends of the clamp blocks 4 out of the slide groove 311.

Referring to fig. 2 and 4, the control hole 312 is a blind hole, a control spring 51 is disposed between the upper end of the control lever 5 and the bottom of the control hole 312, and when the control spring 51 is in a natural state, the lower end of the control lever 5 extends out of the control hole 312, and the elastic force of the control spring 51 is greater than that of the return spring 41. That is, when no external force acts, the control spring 51 presses the control lever 5 downward, the control lever 5 is at the lowest position, and the clamp block 4 protrudes from the slide groove 311. After the aluminum square tube 2 is finally installed, the clamping block 4 always maintains the state, so that the stability of the connection of the supporting block 31 can be ensured.

Referring to fig. 4, a rolling groove 313 is formed at the lower end of the control hole 312, the width of the rolling groove 313 is greater than that of the control hole 312, one side of the rolling groove 313 away from the control hole 312 is located on the lower surface of the support block 31 and is provided as a rolling opening 314, and the diameter of the rolling opening 314 is smaller than that of the control hole 312. A ball 6 which can roll in the rolling groove 313 is arranged in the rolling groove 313, and the diameter of the ball 6 is larger than that of the rolling opening 314. The height of the rolling groove 313 is smaller than the diameter of the ball 6, i.e. when the top of the ball 6 abuts against the bottom of the rolling groove 313, there is still a part of the rolling opening 314 below the ball 6 exposed. When the supporting block 31 slides in the mounting groove 23, the rolling ball 6 at the bottom rolls on the bottom plate 21, the friction force between the two is small, the sliding is convenient, and the rolling ball 6 cannot completely submerge in the rolling groove 313, so that the rolling stability is ensured.

Referring to fig. 4, when the ball 6 naturally falls under the force of gravity, the lower end of the ball 6 protrudes from the rolling port 314, and a gap is left between the upper end of the ball 6 and the top of the rolling groove 313. I.e. the ball 6 can move up and down in the rolling groove 313. The lower end of the control rod 5 is rotatably connected with a ball 52, and the ball 52 is abutted against the ball 6.

Referring to fig. 2 and 4, when the support block 31 is installed, the support block 31 slides into the installation groove 23 from the end of the installation groove 23, the operator presses the support block 31 downward, the support block 31 is pressed downward, and the ball 6 moves upward with respect to the support block 31, thereby lifting up the control lever 5. The control lever 5 is raised, and the clamp block 4 is retracted into the slide groove 311 by the return spring 41. At this time, a gap is left between the two sides of the supporting block 31 and the inner wall of the mounting groove 23, so that the sliding of the supporting block 31 is facilitated. After the supporting block 31 slides to the corresponding position, the operator releases the supporting block 31, the supporting block 31 rises under the action of the control spring 51, the rolling ball 6 moves downwards relative to the supporting block 31, and the control rod 5 moves downwards, so that the clamping block 4 is pushed out from the sliding, and the clamping block 4 is clamped in the clamping groove 221 on the inner wall of the curved plate 22, so that the supporting block 31 is fixed.

Referring to fig. 4, the upper end surface of the supporting block 31 is vertically provided with two locking holes 315 located below the limiting plate 24, and the two locking holes 315 are respectively communicated with the two sliding grooves 311. A locking rod 7 is vertically and slidably connected in the locking hole 315, and the length of the locking rod 7 is greater than the depth of the locking hole 315. The clamping block 4 is provided with a locking groove 42 matched with the locking rod 7, and when the end part of the clamping block 4 extends out of the sliding groove 311 to be in contact with the curved plate 22, the locking groove 42 is opposite to the locking hole 315.

Referring to fig. 4, when the support block 31 is slid to the corresponding position, the clamping block 4 is protruded from the sliding groove 311 to clamp and fix the support block 31. At this time, the locking hole 315 is opposite to the locking groove 42, and the locking rod 7 slides down until the lower end of the locking rod 7 is inserted into the locking groove 42, so that the clamping block 4 is fixed, and the clamping block 4 cannot retract, so that the fixing effect of the supporting block 31 is ensured.

Referring to fig. 4, a first locking plate 711 is fixed on the locking rod 7, a second locking plate 712 is fixed in the locking hole 315, a locking spring 71 between the first locking plate 711 and the second locking plate 712 is sleeved on the locking rod 7, and two ends of the locking spring 71 are fixedly connected with the first locking plate 711 and the second locking plate 712 respectively. When the locking spring 71 is in a natural state, the upper end of the locking rod 7 extends out of the locking hole 315, the lower end of the locking rod 7 is not in contact with the clamping block 4, and the locking rod 7 is prevented from moving downwards by itself to influence the stability of the clamping block 4.

Referring to fig. 1 and 4, after all the supporting blocks 31 are slid to the corresponding positions, an operator lifts the aluminum square tube 2, and fixedly connects the connecting rod 32 with the keel 1 by means of bolts or welding, thereby lifting the aluminum square tube 2. After the aluminum square tube 2 is lifted, the aluminum square tube 2 naturally falls under the action of gravity, and all the supporting blocks 31 support the aluminum square tube 2 together. At this time, the upper surface of the supporting block 31 abuts against the lower surface of the limiting plate 24, so that the locking rod 7 is pressed down, the lower end of the supporting block 31 is suspended above the bottom plate 21, the control spring 51 is always in a natural state, and at this time, the stability of the clamping block 4 is strong and is not easy to loose.

The implementation principle of the U-shaped hyperboloid aluminum square through clamp type installation structure is as follows: the operating personnel puts into the mounting groove 23 with a plurality of supporting shoe 31 in proper order, presses the supporting shoe 31 and slides, loosens the supporting shoe 31 after sliding to the relevant position can, after all supporting shoes 31 slide to the relevant position, with aluminium square tube 2 hoist with fossil fragments 1 link to each other can, convenient to use.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims

1. The utility model provides a U type hyperboloid aluminium square tube anchor clamps formula mounting structure, is led to (2) its characterized in that including fossil fragments (1) and aluminium square tube: the aluminum square tube (2) comprises a bottom plate (21) and curved plates (22) fixed on two sides of the bottom plate (21), mounting grooves (23) with upward openings are formed in the aluminum square tube (2), limiting plates (24) are respectively arranged on two sides of the upper end of the mounting grooves (23), connecting grooves (25) are formed between the two limiting plates (24), the width of each connecting groove is smaller than that of each mounting groove (23), mounting fixtures (3) are arranged between each keel (1) and the aluminum square tube (2), one end of each mounting fixture (3) is connected with the corresponding keel (1), the other end of each mounting fixture is connected with the corresponding aluminum square tube (2), each mounting fixture comprises a supporting block (31) which is connected in the corresponding aluminum square tube (2) in a sliding mode, the width of each supporting block (31) is smaller than that of each mounting groove (23) and is larger than that of the end of each connecting groove (25), connecting rods (32) which are used for connecting with the corresponding keel (1) extend out of the connecting grooves (25) are arranged at the upper ends of the supporting blocks (31), sliding blocks (311) are arranged on two sides of the supporting blocks (31), sliding blocks (311) are arranged in the sliding blocks (311) and are provided with locking holes (315) in the sliding blocks (315) which are communicated with the sliding blocks, the locking device is characterized in that a locking rod (7) is vertically and slidably connected in the locking hole (315), a locking spring (71) is arranged on the locking rod (7), one end of the locking spring (71) is connected with the locking rod (7), the other end of the locking spring is connected with the supporting block (31), when the locking spring (71) is in a natural state, the upper end of the locking rod (7) extends out of the locking hole (315), a locking groove (42) matched with the locking rod (7) is formed in the clamping block (4), and when the end part of the clamping block (4) extends out of the sliding groove (311) to be in contact with the curved plate (22), the locking groove (42) is opposite to the locking hole (315); a vertical control hole (312) is formed in the bottom of the supporting block (31), the control hole (312) is communicated with the sliding groove (311), and a control rod (5) for controlling the movement of the clamping block (4) is connected in a sliding manner in the control hole (312); a reset spring (41) is arranged on the clamping block (4), one end of the reset spring (41) is connected with the clamping block (4), the other end of the reset spring is connected with the supporting block (31), and when the reset spring (41) is in a natural state, the end part of the clamping block (4) is contracted in the sliding groove (311); one end of the control rod (5) facing the clamping block (4) is in an inverted cone shape, the diameter of the upper end of the control rod (5) is larger than that of the lower end, the outer wall of the control rod (5) is in contact with one end of the clamping block (4) facing the control hole (312), a control spring (51) is arranged between the upper end of the control rod (5) and the control hole (312), when the control spring (51) is in a natural state, the lower end of the control rod (5) extends out of the control hole (312), and the elasticity of the control spring (51) is larger than that of the reset spring (41); the lower extreme of control hole (312) has seted up rolling groove (313), roll in rolling groove (313) and be connected with spin (6), the bottom of rolling groove (313) is equipped with rolls and moves mouth (314), the diameter of spin (6) is greater than the diameter of roll mouth (314), the one end that clamp block (4) was kept away from to control lever (5) is contradicted with spin (6).

2. The U-shaped hyperboloid aluminum square through clamp type mounting structure according to claim 1, wherein: the control rod (5) is rotatably connected with a ball (52) towards one end of the ball (6).

3. The U-shaped hyperboloid aluminum square through clamp type mounting structure according to claim 1, wherein: a plurality of clamping grooves (221) matched with the clamping blocks (4) are formed in one side, facing each other, of the curved plate (22).