CN113152828B - High-precision ultrathin aluminum profile - Google Patents

Abstract

The application discloses ultra-thin aluminium alloy of high accuracy, its size is thinner, and can install such as glass, LED board or other structures that have the decoration function with high accuracy. The high-precision ultrathin aluminum profile comprises a bottom layer decorative plate, a top layer decorative plate, a mounting piece and a middle mounting assembly. The intermediate mounting assembly includes a mid-plane plate and a mounting mechanism. The middle-layer plate, the bottom-layer decorative plate and the top-layer decorative plate are sequentially connected, the centers of the middle-layer plate, the bottom-layer decorative plate and the top-layer decorative plate are all in a through groove shape, the through groove position of the middle-layer plate is defined as an installation area, and the installation part is located in the installation area. The middle panel includes opposing top and bottom ends, opposing first and second side edges. The mounting mechanism comprises a top end slide rail structure, a bottom end slide rail structure, a synchronous driving structure and two clamping structures, wherein the top end slide rail structure is arranged at the top end, and the bottom end slide rail structure is arranged at the bottom end; the two ends of the clamping structures are respectively matched with the top end sliding rail structure and the bottom end sliding rail structure in a sliding mode, the synchronous driving structure drives the two clamping structures to move in a centering mode between the first side edge and the second side edge, and the mounting pieces are clamped together.

Description

High-precision ultrathin aluminum profile

Technical Field

The application relates to the technical field of building profiles, in particular to a high-precision ultrathin aluminum profile.

Background

The section bar is an object with a certain geometric shape, which is made of iron or steel and materials with certain strength and toughness through the processes of rolling, extruding, casting and the like. The material has certain appearance size, certain shape of cross section and certain mechanical and physical properties. The section bar can be used independently and can be further processed into other manufactured products, and is commonly used for building structures and manufacturing and installation.

The existing section bars for mounting glass, LED boards or other structures with decoration functions are generally thick in size, the mounting precision is low, and the glass, LED boards or other structures with decoration functions are difficult to mount at the right position.

Disclosure of Invention

The application provides a high-precision ultrathin aluminum profile for solving the technical problem.

The application provides an ultra-thin aluminium alloy of high accuracy, include:

a bottom layer decorative plate;

a top layer decorative plate;

a mounting member; and

the middle mounting assembly comprises a middle layer plate and a mounting mechanism;

the middle layer plate, the bottom layer decorative plate and the top layer decorative plate are sequentially connected, the centers of the middle layer plate, the bottom layer decorative plate and the top layer decorative plate are all in a through groove shape, the through groove position of the middle layer plate is defined as an installation area, and the installation part is located in the installation area;

The middle layer plate comprises a top end, a bottom end, a first side edge and a second side edge which are opposite;

the mounting mechanism comprises a top end slide rail structure, a bottom end slide rail structure, a synchronous driving structure and two clamping structures, wherein the top end slide rail structure is arranged at the top end, and the bottom end slide rail structure is arranged at the bottom end; the two ends of the clamping structure are respectively matched with the top end slide rail structure and the bottom end slide rail structure in a sliding mode, and the synchronous driving structure drives the two clamping structures to move in a centering mode between the first side edge and the second side edge so as to clamp the mounting piece together;

the clamping structure is sequentially provided with a first sliding fit part, an ultrathin plate part and a second sliding fit part along the direction from the top end to the bottom end, the first sliding fit part is matched with the top end slide rail structure, the second sliding fit part is matched with the bottom end slide rail structure, the ultrathin plate part is used for abutting against the mounting piece, and the size of the ultrathin plate part in the direction from the top layer decorative plate to the bottom layer decorative plate is smaller than the size of the first sliding fit part and the second sliding fit part in the direction from the top layer decorative plate to the bottom layer decorative plate;

The bottom decorative board with the top decorative board all with middle installation component laminating is connected.

The in-process of above-mentioned realization, but high accuracy ultra-thin aluminium alloy is one kind and has thin size and high accuracy centering fixed mounting spare, the installed part includes and is not limited to glass, LED board or other decorative structure, it will be used for fixed mounting spare's bearing structure to set up the upper and lower both ends at high accuracy ultra-thin aluminium alloy, the event can make the position of high accuracy ultra-thin aluminium alloy between its upper and lower both ends have thinner size, in the in-service use, the upper and lower both ends of high accuracy ultra-thin aluminium alloy can be pour as an organic wholely with the building, only leave its thinner position in order to reach ultra-thin effect.

Wherein, the bearing structure of fixed mounting spare includes top slide rail structure, bottom slide rail structure, synchronous drive structure.

When assembling the ultra-thin aluminium alloy of high accuracy, can place the installed part in the installation region, constructor adjusts synchronous drive structure and makes two clamping structure do the centering motion for two clamping structure push the installed part in the central point of installation region in step, accomplish the centering adjustment of installed part, and because it adopts the centering motion to realize the installation, so its actual mounted position is unanimous with the mounted position of prediction planning, has the high accuracy. The bottom layer decorative plate and the top layer decorative plate can be assembled later, the bottom layer decorative plate and the top layer decorative plate are attached to the middle mounting assembly, the shape and the size of the bottom layer decorative plate and the shape and the size of the top layer decorative plate and the middle mounting assembly are attached to highlight the ultrathin part of the top layer decorative plate and shield the mounting mechanism, so that the high-precision ultrathin aluminum profile is neat and attractive in appearance.

Optionally, in an embodiment, the first sliding fit portion and the second sliding fit portion each include a concave structure forming a first mounting groove and a second mounting groove for accommodating a slider, respectively;

the ultrathin plate part comprises a flat plate structure, two ends of the ultrathin plate part are respectively connected to the notch positions of the first sliding fit part and the second sliding fit part, and reinforcing ribs are arranged between the ultrathin plate part and the first sliding fit part as well as between the ultrathin plate part and the second sliding fit part;

the bottom wall of the ultrathin plate part is provided with two balls which are respectively close to the first sliding fit part and the second sliding fit part and are used for abutting against the middle plate;

an installation groove is formed at the end part of the ultrathin plate part and used for clamping the installation piece.

In the implementation process, the design of the first sliding fit part, the second sliding fit part and the ultrathin plate part is beneficial to highlighting that the ultrathin plate part has an ultrathin thickness dimension compared with the first sliding fit part and the second sliding fit part, and meanwhile, due to the existence of the reinforcing ribs, the connection strength of the first sliding fit part, the second sliding fit part and the ultrathin plate part can be ensured; meanwhile, the two ends of the ultrathin plate part are respectively provided with the balls, so that the balls are abutted to the middle plate, and the clamping structure is favorable for smoothly finishing centering motion.

Optionally, in one embodiment, the top end rail structure and the bottom end rail structure are located on a front side of the middle layer board, and the synchronous driving structure is located on a back side of the middle layer board;

the top end sliding rail structure comprises a first sliding rail, two first sliding blocks and a first strip-shaped groove, and the bottom end sliding rail structure comprises a second sliding rail, two second sliding rails and a second strip-shaped groove;

the first strip-shaped groove is parallel to the first slide rail, and the second strip-shaped groove is parallel to the second slide rail;

the first sliding fit parts of the two clamping structures are respectively connected to the first sliding block, and the second sliding fit parts of the two clamping structures are respectively connected to the second sliding block;

the synchronous driving structure is connected with the two first sliding blocks through the first strip-shaped grooves and connected with the two second sliding blocks through the second strip-shaped grooves.

Optionally, in one embodiment, the synchronous driving structure includes a first synchronous belt, a second synchronous belt, a first synchronous wheel set, a second synchronous wheel set, a torsion wheel, a pull rope, and a fixing member;

the first synchronous wheel set is arranged at the top end of the middle layer plate and positioned on the back surface of the middle layer plate, the first synchronous belt is sleeved on the first synchronous wheel set, and the two first slide rails are respectively fixed on the upper layer and the lower layer of the first synchronous belt;

The second synchronous wheel set is arranged at the bottom end of the middle layer plate and positioned on the back face of the middle layer plate, the second synchronous belt is sleeved on the second synchronous wheel set, and the two second slide rails are fixed to the lower layer and the upper layer of the first synchronous belt respectively;

the torsion wheel is rotatably arranged on the first side edge, the middle section of the pull rope is fixed on the torsion wheel, and two ends of the pull rope are respectively connected with belt wheels of the first synchronous wheel set and the second synchronous wheel set which are positioned on the same side and are used for driving the belt wheels of the first synchronous wheel set and the second synchronous wheel set to rotate;

the fixing piece is used for fixing the torsion wheel on the first side edge so as to restrain the torsion wheel from rotating.

The in-process of the aforesaid realization, operating personnel is through rotating the torsion wheel, and the pulling stay cord, make first synchronous wheelset and second synchronous wheelset take place to rotate, the band pulley of first synchronous wheelset rotates (a clockwise, another is anticlockwise) along opposite direction each other with the band pulley of second synchronous wheelset, thereby order about two first sliders and two second sliders and all draw close to the center, realize clamping structure's centering motion, the centering back that targets in place, the installation mounting, realize the fixed of torsion wheel, avoid it to become flexible.

Optionally, in an embodiment, the number of the first bar-shaped grooves is two, so as to respectively correspond to the two first sliders, and the number of the second bar-shaped grooves is two, so as to respectively correspond to the two second sliders;

the torque wheel is formed with a plurality of through-holes, the mounting is the screw, first side is formed with the screw, the screw passes one of a plurality of through-holes spiro union in the screw.

Optionally, in one embodiment, the first synchronizing wheel set comprises a first drive pulley and the second synchronizing wheel set comprises a second drive pulley;

the first driving belt wheel is rotatably arranged at the top end and close to the first side edge, and the second driving belt wheel is rotatably arranged at the bottom end and close to the second side edge;

and the centers of the first driving belt wheel and the second driving belt wheel are respectively provided with a rotating shaft which is used for being fixedly connected with the end part of the pull rope.

Optionally, in an embodiment, the top end slide rail structure includes two third slide rails and two third sliding blocks, the two third slide rails are parallel to each other and disposed at the top end, and the third sliding blocks are slidably disposed on the two third slide rails;

The bottom end slide rail structure comprises a fourth slide rail and two fourth slide blocks, the fourth slide rail is arranged at the bottom end, and the fourth slide blocks are slidably arranged on the fourth slide rail;

the first sliding fit parts of the two clamping structures are respectively connected to the third slide block, and the second sliding fit parts of the two clamping structures are respectively connected to the fourth slide block;

the synchronous driving structure is arranged at the top end and connected with the two third sliding blocks.

Optionally, in one embodiment, the synchronous driving structure comprises a centering rotary disc, two connecting rods and a rotating part;

the centering rotary table is rotatably arranged at the centers of the two third slide rails, and the connecting rod is positioned between the third slide block and the centering rotary table;

one end of the connecting rod is hinged to the third sliding block, and the other end of the connecting rod is hinged to the centering rotary table;

the rotating part is used for adjusting the rotating angle of the centering rotary disc.

In the process of realizing, the rotating angle of the centering turntable is adjusted through the rotating part, so that the centering turntable drives the two third sliding blocks to do centering motion through the connecting rod, force is transferred through the clamping structure, the fourth sliding rail moves along, and centering motion of the clamping structure is realized.

Optionally, in one embodiment, the rotating portion includes a hinge lever, a hinge shaft, and a fixing bolt;

the hinge rod is hinged with the centering rotary table through a hinge shaft;

a plurality of fixing threaded holes are formed in the top end of the centering rotary disc, and the distance from the plurality of fixing threaded holes to the centering rotary disc is gradually reduced;

the hinge rod is formed with a through hole provided with a shaft sleeve, and the fixing bolt is rotatably connected with one of the fixing threaded holes through the shaft sleeve.

In the process of the realization, an operator screws the fixing bolt into one of the fixing threaded holes to adjust the relative position of the hinge rod and the centering rotary disk, and the rotation angle of the centering rotary disk can be changed due to the two hinge points (the hinge shaft and the shaft sleeve).

Optionally, in one embodiment, the synchronous drive structure is further configured with a spring;

two ends of the spring are respectively connected with the two fourth sliding blocks, so that the two fourth sliding blocks have the tendency of being close to each other.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

Fig. 1 is a front view of a high-precision ultrathin aluminum profile in the embodiment;

fig. 2 is a side view of the high-precision ultrathin aluminum profile in the embodiment.

FIG. 3 is a schematic view of a clamping structure in the present embodiment;

FIG. 4 is a schematic view of the intermediate mounting assembly of the present embodiment;

FIG. 5 is a schematic view of a first mounting mechanism in accordance with the present embodiment;

FIG. 6 is an enlarged view taken at A in FIG. 5;

FIG. 7 is a schematic view of a second mounting mechanism in accordance with the present embodiment;

fig. 8 is an enlarged view at B in fig. 7.

Icon: 10-bottom decorative plate; 11-top decorative plate; 12-a mounting member; 13-intermediate mounting assembly; 14-a mounting area;

20-a middle layer plate;

30-a mounting mechanism; 31-a top end slide rail structure; 32-a bottom end slide rail structure; 33-synchronous drive configuration; 34-a clamping structure;

40-a first slip fit; 41-ultrathin sheet portions; 42-a second slip fit; 43-a first mounting groove; 44-a second mounting groove; 45-a ball bearing;

50-a first slide rail; 51-a first slider; 52-a first bar-shaped groove; 53-a second slide rail; 54-a second slide; 55-a second strip groove; 56-first synchronization belt; 57-a second synchronous belt; 58-a first synchronous wheel set; 59-a second synchronous wheel set; 60-torque wheel; 61-a pull rope; 62-a fixing member; 63-through holes;

70-a third slide rail; 71-a third slider; 72-a fourth slide rail; 73-a fourth slider; 74-centering the rotating disc; 75-a connecting rod; 76-a rotating part; 77-a hinged lever; 78-a hinged axis; 79-fixing bolts; 80-fixing threaded holes; 81-spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the embodiments of the present application, it is to be understood that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like, refer to the orientation or positional relationship as shown in the drawings, or as conventionally placed in use of the product of the application, or as conventionally understood by those skilled in the art, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and therefore should not be considered as limiting the present application.

In the description of the embodiments of the present application, it should also be noted that, unless otherwise explicitly stated or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

The technical solution in the present application will be described below with reference to the accompanying drawings.

The present embodiment provides a high-precision ultra-thin aluminum profile which is thin in size and capable of mounting, for example, glass, LED panels, or other structures having a decoration function with high precision.

Referring to fig. 1-2, fig. 1 is a front view of the high-precision ultrathin aluminum profile in this embodiment, and fig. 2 is a side view of the high-precision ultrathin aluminum profile in this embodiment.

The high-precision ultrathin aluminum profile comprises a bottom layer decorative plate 10, a top layer decorative plate 11, a mounting piece 12 and a middle mounting component 13.

The intermediate mounting assembly 13 includes a mid-plane plate 20 and a mounting mechanism 30. The middle layer plate 20, the bottom layer decorative plate 10 and the top layer decorative plate 11 are connected in sequence, the centers of the middle layer plate 20, the bottom layer decorative plate 10 and the top layer decorative plate 11 are all in a through groove shape, the through groove position of the middle layer plate 20 is defined as an installation area 14, and the installation part 12 is located in the installation area 14.

The middle panel 20 includes opposite top and bottom ends, and opposite first and second side edges.

The mounting mechanism 30 includes a top end sliding rail structure 31, a bottom end sliding rail structure 32, a synchronous driving structure 33, and two clamping structures 34, where the top end sliding rail structure 31 is disposed at the top end, and the bottom end sliding rail structure 32 is disposed at the bottom end; the two ends of the clamping structure 34 are slidably engaged with the top end rail structure 31 and the bottom end rail structure 32, respectively, and the synchronous driving structure 33 drives the two clamping structures 34 to move in a centering manner between the first side edge and the second side edge so as to clamp the mounting member 12 together.

The clamping structure 34 sequentially forms a first sliding fit portion 40, a ultrathin plate portion 41 and a second sliding fit portion 42 along the direction from the top end to the bottom end, the first sliding fit portion 40 is matched with the top end sliding rail structure 31, the second sliding fit portion 42 is matched with the bottom end sliding rail structure 32, the ultrathin plate portion 41 is used for abutting the mounting piece 12, and the size of the ultrathin plate portion 41 in the direction from the top layer decorative plate 11 to the bottom layer decorative plate 10 is smaller than the size of the first sliding fit portion 40 and the second sliding fit portion 42 in the direction from the top layer decorative plate 11 to the bottom layer decorative plate 10.

The bottom layer decorative plate 10 and the top layer decorative plate 11 are attached and connected with the middle installation component 13.

In-process of above-mentioned realization, but high accuracy ultra-thin aluminium alloy is one kind and has thin size and high accuracy centering fixed mounting 12, installed part 12 is including not being limited to glass, LED board or other decorative structure, it will be used for fixed mounting 12's bearing structure to set up the upper and lower both ends at high accuracy ultra-thin aluminium alloy, the event can make the position of high accuracy ultra-thin aluminium alloy between its upper and lower both ends have thinner size, in the in-service use, the upper and lower both ends of high accuracy ultra-thin aluminium alloy can be pour as an organic wholely with the building, only reserve its thinner position in order to reach ultra-thin effect.

The bearing structure of the fixed mounting member 12 includes a top end slide rail structure 31, a bottom end slide rail structure 32, and a synchronous driving structure 33.

When assembling the ultra-thin aluminium alloy of high accuracy, can place installed part 12 in installation region 14, constructor adjusts synchronous drive structure 33 and makes two clamping structure 34 do the centering motion for two clamping structure 34 push installed part 12 in the central point of installation region 14 in step, accomplish the centering adjustment of installed part 12, and because it adopts the centering motion to realize the installation, so its actual mounted position is unanimous with the mounted position of planning of prediction, has the high accuracy. And then the bottom layer decorative plate 10 and the top layer decorative plate 11 can be assembled, the bottom layer decorative plate 10 and the top layer decorative plate 11 are attached to the middle mounting component 13, the shape and the size of the bottom layer decorative plate and the top layer decorative plate 11 are matched with the middle mounting component 13, so that the ultrathin part of the bottom layer decorative plate is highlighted, and meanwhile, the mounting mechanism 30 is shielded, so that the high-precision ultrathin aluminum profile is neat and attractive in appearance.

It should be noted that the mounting member 12, including but not limited to glass, LED panels or other decorative structures, may be exposed through the center of the three of the center layer panel 20, the bottom layer decorative panel 10 and the top layer decorative panel 11.

Referring to fig. 3, fig. 3 is a schematic view of the clamping structure 34 in the present embodiment.

The first sliding fit portion 40 and the second sliding fit portion 42 each include a concave structure that forms a first mounting groove 43 and a second mounting groove 44 for receiving the slider, respectively;

the ultrathin plate part 41 comprises a flat plate structure, two ends of the ultrathin plate part are respectively connected to the notch positions of the first sliding fit part 40 and the second sliding fit part 42, and reinforcing ribs are arranged between the ultrathin plate part 41 and the first sliding fit part 40 and the second sliding fit part 42;

two balls 45 are arranged on the bottom wall of the ultrathin plate portion 41, and the two balls 45 are respectively close to the first sliding fit portion 40 and the second sliding fit portion 42 and are used for abutting against the middle plate 20;

an end of the ultra-thin plate portion 41 is formed with an engagement mounting groove for engaging the attachment 12.

In the implementation process, the design of the first sliding fit portion 40, the second sliding fit portion 42 and the ultra-thin plate portion 41 is beneficial to highlighting that the ultra-thin plate portion 41 has an ultra-thin thickness size compared with the first sliding fit portion 40 and the second sliding fit portion 42, and meanwhile, due to the existence of the reinforcing ribs, the connection strength of the three portions can be ensured; meanwhile, the balls 45 are respectively arranged at two ends of the ultra-thin plate part 41, so that the balls 45 are abutted against the middle plate 20, and the clamping structure 34 can smoothly complete centering motion.

Referring to fig. 4 and 5, fig. 4 is a schematic view of the intermediate mounting assembly 13 in the present embodiment, and fig. 5 is a schematic view of the first mounting mechanism 30 in the present embodiment.

The top and bottom track structures 31 and 32 are located on the front side of the middle deck 20 and the synchronous drive structure 33 is located on the back side of the middle deck.

The top end slide rail structure 31 comprises a first slide rail 50, two first sliding blocks 51 and a first strip-shaped groove 52, and the bottom end slide rail structure 32 comprises a second slide rail 53, two second sliding blocks 54 and a second strip-shaped groove 55;

the first elongated slot 52 is parallel to the first slide rail 50 and the second elongated slot 55 is parallel to the second slide rail 53. The respective first sliding engagement portions 40 of the two clamping structures 34 are respectively connected to the first slider 51, and the respective second sliding engagement portions 42 are respectively connected to the second slider 54. The synchronous drive structure 33 is connected to the two first sliders 51 through a first strip-shaped groove 52 and to the two second sliders 54 through a second strip-shaped groove 55.

The synchronous drive structure 33 includes a first synchronous belt 56, a second synchronous belt 57, a first synchronous pulley group 58, a second synchronous pulley group 59, a torsion pulley 60, a pull rope 61, and a fixing member 62.

The first synchronous wheel set 58 is arranged at the top end of the middle plate 20 and is positioned on the back surface of the middle plate 20, the first synchronous belt 56 is sleeved on the first synchronous wheel set 58, and the two first slide rails 50 are respectively fixed on the upper layer and the lower layer of the first synchronous belt 56. The second synchronous wheel set 59 is arranged at the bottom end of the middle layer plate 20 and is positioned at the back of the middle layer plate 20, the second synchronous belt 57 is sleeved on the second synchronous wheel set 59, and the two second sliding rails 53 are respectively fixed at the lower layer and the upper layer of the first synchronous belt 56. The torsion wheel 60 is rotatably arranged on the first side, the middle section of the pull rope 61 is fixed on the torsion wheel 60, and two ends of the pull rope 61 are respectively connected with the belt wheels of the first synchronous wheel set 58 and the second synchronous wheel set 59 which are positioned on the same side, and are used for driving the belt wheels of the first synchronous wheel set 58 and the belt wheels of the second synchronous wheel set 59 to rotate. The fixing member 62 is used to fix the torque wheel 60 at the first side to prevent the torque wheel 60 from rotating.

In-process of above-mentioned realization, operating personnel is through rotating torque wheel 60, and pulling stay cord 61, make first synchronous wheelset 58 and second synchronous wheelset 59 take place to rotate, the band pulley of first synchronous wheelset 58 rotates along opposite direction each other with the band pulley of second synchronous wheelset 59 (a clockwise, another is anticlockwise), thereby order to order about two first sliders 51 and two second sliders 54 and all draw close to the center, realize clamping structure 34's centering motion, the centering is in place the back, installation mounting 62, realize torque wheel 60's fixing, avoid it to become flexible.

The number of the first bar-shaped grooves 52 is two to correspond to the two first sliders 51, and the number of the second bar-shaped grooves 55 is two to correspond to the two second sliders 54.

Referring to fig. 6, fig. 6 is an enlarged view of a portion a of fig. 5.

The torque wheel 60 is formed with a plurality of through holes 63, the fixing member 62 is a screw, and a screw hole is formed at a first side thereof, and the screw passes through one of the through holes 63 to be threadedly coupled to the screw hole.

The first synchronizing wheel set 58 comprises a first drive pulley and the second synchronizing wheel set 59 comprises a second drive pulley. First driving pulley rotationally sets up in the top and is close to first side, and second driving pulley rotationally sets up in the bottom and is close to the second side. The centers of the first driving pulley and the second driving pulley are provided with rotating shafts respectively and are used for being fixedly connected with the end part of the pull rope 61.

Referring to FIG. 7, FIG. 7 is a schematic view of a second mounting mechanism 30 according to the present embodiment.

The top end slide rail structure 31 includes two third slide rails 70 and two third sliding blocks 71, the two third slide rails 70 are parallel to each other and are disposed at the top end, and the third sliding blocks 71 are slidably disposed on the two third slide rails 70. The bottom end slide rail structure 32 comprises two fourth slide rails 72 and two fourth sliders 73, the fourth slide rails 72 are arranged at the bottom end, and the fourth sliders 73 are slidably arranged on the two fourth slide rails 72.

The respective first sliding-fit portions 40 of the two clamping structures 34 are respectively connected to the third slider 71, and the respective second sliding-fit portions 42 are respectively connected to the fourth slider 73.

The synchronous driving structure 33 is disposed at the top end and connected to the two third sliders 71.

In the present disclosure, the synchronous drive structure 33 includes a centering dial 74, two links 75, and a rotating portion 76. The centering rotary disk 74 is rotatably disposed at the center of the two third slide rails 70, and the connecting rod 75 is located between the third slide block 71 and the centering rotary disk 74.

One end of the connecting rod 75 is hinged to the third sliding block 71, and the other end of the connecting rod 75 is hinged to the centering rotary disc 74. The rotating portion 76 is used to adjust the rotation angle of the centering dial 74.

In the implementation process, the rotating angle of the centering rotary disc 74 is adjusted through the rotating part 76, so that the rotating part drives the two third sliding blocks 71 to move in a centering manner through the connecting rod 75, force is transferred through the clamping structure 34, and the fourth sliding rail 72 moves along with the fourth sliding block, so that the centering movement of the clamping structure 34 is implemented.

Referring to fig. 8, fig. 8 is an enlarged view of B in fig. 7.

The rotating portion 76 includes a hinge lever 77, a hinge shaft 78, and a fixing bolt 79.

The hinge lever 77 is hinged to the centering dial 74 through a hinge shaft 78. The top end is formed with a plurality of fixing threaded holes 80 arranged at intervals, and the distance from the plurality of fixing threaded holes 80 to the centering rotary disk 74 is gradually reduced.

The hinge rod 77 is formed with a through hole provided with a boss through which a fixing bolt 79 is rotatably coupled with one of the fixing screw holes 80.

In the above implementation, the operator screws the fixing bolt 79 into one of the fixing threaded holes 80 to adjust the relative position of the hinge rod 77 and the centering dial 74, and since there are two hinge points (the hinge shaft 78 and the bushing), the rotation angle of the centering dial 74 can be changed.

Note that, the synchronous drive structure 33 is further provided with a spring 81; both ends of the spring 81 are connected to the two fourth sliders 73, respectively, so that the two fourth sliders 73 have a tendency to approach each other. The centering movement of the fourth slider 73 and the third slider 71 can be rapidly performed by the elastic force of the spring 81.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a high accuracy ultra-thin aluminium alloy which characterized in that includes:

a bottom layer decorative plate;

a top layer decorative plate;

a mounting member; and

the middle mounting assembly comprises a middle layer plate and a mounting mechanism;

the middle layer plate, the bottom layer decorative plate and the top layer decorative plate are sequentially connected, the centers of the middle layer plate, the bottom layer decorative plate and the top layer decorative plate are all in a through groove shape, the through groove position of the middle layer plate is defined as an installation area, and the installation part is located in the installation area;

the middle layer plate comprises a top end, a bottom end, a first side edge and a second side edge which are opposite;

the mounting mechanism comprises a top end slide rail structure, a bottom end slide rail structure, a synchronous driving structure and two clamping structures, wherein the top end slide rail structure is arranged at the top end, and the bottom end slide rail structure is arranged at the bottom end; the two ends of the clamping structure are respectively matched with the top end slide rail structure and the bottom end slide rail structure in a sliding mode, and the synchronous driving structure drives the two clamping structures to move in a centering mode between the first side edge and the second side edge so as to clamp the mounting piece together;

the clamping structure is sequentially provided with a first sliding fit part, an ultrathin plate part and a second sliding fit part along the direction from the top end to the bottom end, the first sliding fit part is matched with the top end slide rail structure, the second sliding fit part is matched with the bottom end slide rail structure, the ultrathin plate part is used for abutting against the mounting piece, and the size of the ultrathin plate part in the direction from the top layer decorative plate to the bottom layer decorative plate is smaller than that of the first sliding fit part and the second sliding fit part in the direction from the top layer decorative plate to the bottom layer decorative plate;

The bottom decorative board with the top decorative board all with middle installation component laminating is connected.

2. A high-precision ultra-thin aluminum profile as claimed in claim 1,

the first sliding fit part and the second sliding fit part respectively comprise concave structures which respectively form a first mounting groove and a second mounting groove for accommodating a sliding block;

the ultrathin plate part comprises a flat plate structure, two ends of the ultrathin plate part are respectively connected to the notch positions of the first sliding fit part and the second sliding fit part, and reinforcing ribs are arranged between the ultrathin plate part and the first sliding fit part as well as between the ultrathin plate part and the second sliding fit part;

the bottom wall of the ultrathin plate part is provided with two balls which are respectively close to the first sliding fit part and the second sliding fit part and are used for abutting against the middle plate;

and the end part of the ultrathin plate part is provided with a clamping and installing groove which is used for clamping the installation piece.

3. A high-precision ultra-thin aluminum profile as claimed in claim 2,

the top end slide rail structure and the bottom end slide rail structure are positioned on the front surface of the middle layer plate, and the synchronous driving structure is positioned on the back surface of the middle layer plate;

The top end sliding rail structure comprises a first sliding rail, two first sliding blocks and a first strip-shaped groove, and the bottom end sliding rail structure comprises a second sliding rail, two second sliding blocks and a second strip-shaped groove;

the first strip-shaped groove is parallel to the first slide rail, and the second strip-shaped groove is parallel to the second slide rail;

the first sliding fit parts of the two clamping structures are respectively connected to the first sliding block, and the second sliding fit parts of the two clamping structures are respectively connected to the second sliding block;

the synchronous driving structure is connected with the two first sliding blocks through the first strip-shaped grooves and connected with the two second sliding blocks through the second strip-shaped grooves.

4. A high-precision ultra-thin aluminum profile as claimed in claim 3,

the synchronous driving structure comprises a first synchronous belt, a second synchronous belt, a first synchronous wheel set, a second synchronous wheel set, a torsion wheel, a pull rope and a fixing piece;

the first synchronous wheel set is arranged at the top end of the middle layer plate and positioned on the back surface of the middle layer plate, the first synchronous belt is sleeved on the first synchronous wheel set, and the two first slide rails are respectively fixed on the upper layer and the lower layer of the first synchronous belt;

The second synchronous wheel set is arranged at the bottom end of the middle layer plate and positioned on the back surface of the middle layer plate, the second synchronous belt is sleeved on the second synchronous wheel set, and the two second slide rails are respectively fixed on the lower layer and the upper layer of the first synchronous belt;

the torsion wheel is rotatably arranged on the first side edge, the middle section of the pull rope is fixed on the torsion wheel, and two ends of the pull rope are respectively connected with belt wheels of the first synchronous wheel set and the second synchronous wheel set which are positioned on the same side and are used for driving the belt wheels of the first synchronous wheel set and the second synchronous wheel set to rotate;

the fixing piece is used for fixing the torsion wheel on the first side edge so as to restrain the torsion wheel from rotating.

5. A high-precision ultra-thin aluminum profile as claimed in claim 4,

the number of the first strip-shaped grooves is two so as to correspond to the two first sliding blocks respectively, and the number of the second strip-shaped grooves is two so as to correspond to the two second sliding blocks respectively;

the torque wheel is formed with a plurality of through-holes, the mounting is the screw, first side is formed with the screw, the screw passes one of a plurality of through-holes spiro union in the screw.

6. A high-precision ultra-thin aluminum profile as claimed in claim 5,

the first synchronous wheel set comprises a first driving belt wheel, and the second synchronous wheel set comprises a second driving belt wheel;

the first driving belt wheel is rotatably arranged at the top end and close to the first side edge, and the second driving belt wheel is rotatably arranged at the bottom end and close to the second side edge;

and the centers of the first driving belt wheel and the second driving belt wheel are respectively provided with a rotating shaft which is used for being fixedly connected with the end part of the pull rope.

7. A high-precision ultra-thin aluminum profile as claimed in claim 2,

the top end slide rail structure comprises two third slide rails and two third slide blocks, the two third slide rails are parallel to each other and arranged at the top end, and the third slide blocks are slidably arranged on the two third slide rails;

the bottom end slide rail structure comprises a fourth slide rail and two fourth slide blocks, the fourth slide rail is arranged at the bottom end, and the fourth slide blocks are slidably arranged on the fourth slide rail;

the first sliding fit parts of the two clamping structures are respectively connected to the third sliding block, and the second sliding fit parts of the two clamping structures are respectively connected to the fourth sliding block;

The synchronous driving structure is arranged at the top end and connected with the two third sliding blocks.

8. A high-precision ultra-thin aluminum profile as claimed in claim 7,

the synchronous driving structure comprises a centering rotary table, two connecting rods and a rotating part;

the centering rotary table is rotatably arranged at the centers of the two third slide rails, and the connecting rod is positioned between the third slide block and the centering rotary table;

one end of the connecting rod is hinged to the third sliding block, and the other end of the connecting rod is hinged to the centering rotary table;

the rotating part is used for adjusting the rotating angle of the centering rotary disc.

9. A high-precision ultra-thin aluminum profile as claimed in claim 8,

the rotating part comprises a hinge rod, a hinge shaft and a fixing bolt;

the hinge rod is hinged with the centering rotary table through a hinge shaft;

a plurality of fixing threaded holes are formed in the top end of the centering rotary disc, and the distance from the plurality of fixing threaded holes to the centering rotary disc is gradually reduced;

the hinge rod is formed with a through hole provided with a shaft sleeve, and the fixing bolt is rotatably connected with one of the fixing threaded holes through the shaft sleeve.

10. A high-precision ultra-thin aluminum profile as claimed in claim 9,

the synchronous driving structure is also provided with a spring;

two ends of the spring are respectively connected with the two fourth sliding blocks, so that the two fourth sliding blocks have the tendency of being close to each other.

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