CN117432221A - Energy-conserving wallboard installation auxiliary structure of green building - Google Patents

Abstract

The invention relates to the field of wallboard installation, and discloses an auxiliary structure for installing an energy-saving wallboard of a green building, which comprises a frame for bearing and transporting wallboards, wherein rollers are fixedly arranged at the four corners of the bottom of the frame respectively, a first concave frame and a second concave frame are fixedly arranged on the frame, the first concave frame and the second concave frame correspond to each other, a bearing structure for bearing a clamping structure is arranged on one side of the frame, the clamping structure is arranged on the bearing structure, and a pressing structure is arranged on the clamping structure.

Description

Energy-conserving wallboard installation auxiliary structure of green building

Technical Field

The invention relates to the technical field of wallboard installation, in particular to an auxiliary structure for installing an energy-saving wallboard of a green building.

Background

Wallboard to form of physical component equipment is because of its environmental protection, dampproofing, mould proof, inhale sound, thermal-insulated, temperature-resistant, cold-resistant, labour saving and time saving advantage begin gradually to replace traditional wall decoration material, becomes the new pet that indoor design university read brand-new to the wall, the kind of wallboard: the paper surface gypsum board is produced with building gypsum as main material, fiber, additive, light stuffing, etc. and through mixing with water into slurry, casting, setting and stoving.

The production method of the gypsum hollow strip board is similar to that of a common concrete hollow board. The size specification is as follows: the width is 450 mm-600 mm, the thickness is 60 mm-100 mm, the length is 2700 mm-3000 mm, the number of holes is 7-9, and the hole rate is 30% -40%. Fibrous materials or light fillers are often added in the production to improve the flexural strength and reduce the dead weight of the gypsum hollow lath, and the lath is commonly used for the partition walls of residential houses.

Fiber gypsum board is produced through loosening fiber material, such as glass fiber, paper rib, mineral wool, etc. in water, mixing with building gypsum and proper amount of impregnating agent to form slurry, spreading slurry on a fourdrinier, dewatering to form paper-free gypsum board. The bending strength and the elastic modulus of the gypsum board are higher than those of paper gypsum boards, and the gypsum board is mainly used as an inner partition wall and a suspended ceiling of a building.

When the existing wallboard is installed, the existing wallboard needs to be transported and carried, works such as aligning an adhesive area and the like, the existing mode generally adopts manual transportation operation, the mode is extremely tedious, time and labor are wasted, and therefore the auxiliary structure for installing the energy-saving wallboard for the green building is provided.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an auxiliary structure for installing an energy-saving wallboard of a green building, which solves the problems.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides an energy-conserving wallboard installation auxiliary structure of green building, is including the frame that is used for bearing transportation wallboard, and the gyro wheel is installed respectively to four corners in the bottom of frame, fixed mounting has spill frame one and spill frame two on the frame, and spill frame one and spill frame two correspond each other, one side of frame is provided with the bearing structure that is used for bearing the holding structure, and the holding structure sets up on bearing structure, and is provided with press structure on the holding structure.

Preferably, the bearing structure comprises a sliding assembly, a cross rod, an air cylinder and a mounting block, wherein the mounting block is connected with the sliding assembly, the cross rod is transversely and fixedly mounted on the inner side of the frame, the air cylinder is fixedly mounted on one side, deviating from the mounting block, of the cross rod, and an output shaft of the air cylinder penetrates through the cross rod and the frame to be fixedly connected with the mounting block.

Preferably, the sliding assembly comprises two side clamping blocks, a side groove is formed in the side face of the frame, the side clamping blocks are connected with the side groove in a sliding mode, and one end, extending to the outer side of the frame, of each side clamping block is fixedly connected with the side face of the installation block.

Preferably, the clamping structure comprises a telescopic component, a transverse rectangular rod, two slide bars arranged in a mirror image mode and clamping rods fixedly connected with the tail ends of the slide bars, a penetrating opening is formed in the transverse rectangular rod, a screw rod is installed in the transverse rectangular rod in a rotating mode, a motor II is fixedly installed on the side face of the transverse rectangular rod, an output shaft of the motor II extends to the inner end of the opening to be fixedly connected with the screw rod, external threads opposite in direction are respectively formed in the two ends of the screw rod, threaded holes are formed in one end of the slide bars, the screw rod is connected with the threads of the slide bars, and notches are formed in one sides, close to each other, of the clamping rods on the two sides.

Preferably, the telescopic assembly comprises a vertical rod, a telescopic rod and a driving assembly, the telescopic rod is movably inserted into the vertical rod, a tooth slot is formed in one side of the telescopic rod, corresponding to the driving assembly, and the tooth slot is meshed with the driving assembly.

Preferably, the drive assembly includes biax motor and gear one, and the equal fixed mounting in both sides of biax motor has gear one, gear one and tooth's socket meshing, the bottom fixed mounting of biax motor has the motor mounting bracket, and the cross section of motor mounting bracket is L shape, motor mounting bracket fixed mounting is in the top of spill frame two.

Preferably, the pressing structure comprises an adjusting component, a concave connecting block, a third motor, a second gear, a gear rotating rod and a pressing block, wherein the concave connecting block is connected with the adjusting component, the cross section of the concave connecting block is concave, the second gear is rotationally arranged in the concave connecting block, the third motor is fixedly arranged on the side surface of the concave connecting block, an output shaft of the third motor is fixedly connected with the second gear, the gear rotating rod is fixedly connected with the pressing block, the gear rotating rod is rotationally arranged on the inner side of the concave connecting block, and the gear rotating rod is meshed with the second gear.

Preferably, the adjusting component comprises a vertical plate and a first air cylinder, wherein the vertical plate is fixedly arranged at the bottom end of the transverse rectangular rod, the first air cylinder is fixedly arranged on the vertical plate, and the output end of the first air cylinder penetrates through the vertical plate to be fixedly connected with the back surface of the concave connecting block.

Preferably, the top both sides fixed mounting of frame have multiunit shrink subassembly, shrink subassembly setting is between spill frame one and spill frame two, shrink subassembly is including grafting fixed circle piece and the flexible circle piece together, and the inside fixed mounting of fixed circle piece has the spring, and the upper end and the flexible circle piece fixed connection of spring are in the same place.

Compared with the prior art, the invention provides an auxiliary structure for installing the energy-saving wallboard of the green building, which has the following beneficial effects:

1. this energy-conserving wallboard installation auxiliary structure of green building carries out the load through the wallboard that the frame will need install, later transports it to the region that needs to install, adopts the clamping component to press the wallboard centre gripping to appointed mounted position, presses the structure afterwards to press the wallboard for wallboard and glue are glued sticky more stable, and this device can integrate the transport of wallboard, the regulation of position and pressing, installs for adopting artificial mode, and this device is laborsaving more, convenient to use.

2. This energy-conserving wallboard installation auxiliary structure of green building, when the centre gripping is installed to the wallboard, the position of breach is aimed at to the wallboard side of rectangle, motor two starts afterwards, because the slide bar of screw thread relation can drive both sides is to deviating from each other or one side that is close to each other removes, until the inner wall of breach carries out the centre gripping to the side of wallboard, thereby accomplish the centre gripping to the wallboard, such setting not only can carry out the adaptation to the wallboard of different width and adjust the centre gripping, and for current multiple spot centre gripping mode, the breach of seting up in this scheme can adopt the mode of face binding face to carry out the centre gripping, can prevent to adopt the mode of multiple spot centre gripping to cause the damage to the side of wallboard.

3. This green building energy-saving wallboard installation auxiliary structure can increase the guidance quality when installation piece lateral shifting through having increased side fixture block.

4. This energy-conserving wallboard installation auxiliary structure of green building, when the wallboard is installed to needs, highly when adjusting, biax motor start drive gear one rotates, because the relation of meshing can drive the telescopic link and reciprocate to accomplish the regulation to the telescopic link height, thereby accomplish the operation of adjusting the wallboard height of fixing between both sides grip lever, convenient to use.

5. This green building energy-saving wallboard installation auxiliary structure, the cross section of pressing the piece is the arc, when the installation wallboard, paint glue in the mounted position of wallboard, later paint glue on the wallboard, start cylinder one thereupon, the output of cylinder one is to being close to one side of wallboard and remove, until pressing the piece and laminating of wallboard, then start motor three, motor three drives gear two and rotate, then the gear bull stick rotates for press the arc of pressing the piece and press the back of wallboard, such pressing mode can simulate the people hand and press reciprocally, make the bonding that glue can be abundant.

6. This energy-conserving wallboard installation auxiliary structure of green building, when the wallboard is placed on the frame, the top at flexible circle piece is pressed respectively to the bottom both sides of wallboard, flexible circle piece shrink this moment, after the wallboard of one side is got rid of, flexible circle piece upwards pops up, and the flexible circle piece of popping up can be spacing to the wallboard bottom of rear side, prevents that its bottom from sliding, causes the slope of accumulational wallboard, influences normal transportation, and places the wallboard on the frame, unnecessary wallboard can play the counter weight effect, prevents the whole forward slope of this device.

Drawings

FIG. 1 is a front perspective view of the present invention;

FIG. 2 is a schematic rear perspective view of the present invention;

FIG. 3 is an enlarged schematic view of a portion of FIG. 2;

FIG. 4 is a schematic top view of the present invention;

FIG. 5 is a schematic cross-sectional view A-A of FIG. 4;

fig. 6 is a partially enlarged schematic view at B in fig. 5.

In the figure: 1. a frame; 2. a side groove; 3. a roller; 4. a concave frame I; 5. a concave frame II; 6. a cross bar; 7. a cylinder; 8. fixing the round block; 9. a telescopic round block; 10. a side clamping block; 11. a mounting block; 12. a vertical rod; 13. a motor mounting rack; 14. a telescopic rod; 15. a slide bar; 16. a clamping rod; 17. a notch; 18. an opening; 19. a riser; 20. a first cylinder; 21. a biaxial motor; 22. a first gear; 23. a second motor; 24. a screw rod; 25. pressing the blocks; 26. a concave connecting block; 27. a third motor; 28. a second gear; 29. a gear rotating rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-6, an auxiliary structure for installing energy-saving wallboards of green buildings comprises a frame 1 for bearing and transporting wallboards, wherein rollers 3 are respectively installed at four corners of the bottom of the frame 1, a first concave frame 4 and a second concave frame 5 are fixedly installed on the frame 1, the first concave frame 4 and the second concave frame 5 correspond to each other, a bearing structure for bearing a clamping structure is arranged on one side of the frame 1, the clamping structure is arranged on the bearing structure, a pressing structure is arranged on the clamping structure, the wallboards to be installed are loaded through the frame 1 and then transported to an area to be installed, the wallboards are clamped to a designated installation position by adopting a clamping assembly, and then the wallboards are pressed by the pressing structure, so that the wallboards are more stable in adhesion with glue.

Embodiment two: on the basis of the first embodiment, the bearing structure needs to be loaded with the clamping structure, but in the practical application process, a space needs to exist between the wallboard and the wall surface during installation, so that the frame 1 needs to be pushed to adjust the space between the wallboard and the wall surface on the clamping structure, but if the frame 1 is directly pushed, the wallboard can be loaded on the frame 1, so that the adjustment of the space is difficult to realize, and a user can only push the frame 1 from the side surface, so that the adjustment is more troublesome.

To sum up, bearing structure includes slip subassembly, horizontal pole 6, cylinder 7 and installation piece 11, and installation piece 11 is connected with slip subassembly, and horizontal pole 6 horizontal fixed mounting is in the inboard of frame 1, and cylinder 7 fixed mounting is in the one side that horizontal pole 6 deviates from installation piece 11, and the output shaft of cylinder 7 passes horizontal pole 6 and frame 1 and installation piece 11 fixed connection together, when the interval between fine adjustment clamping structure and the wall, and the output shaft of cylinder 7 drives installation piece 11 lateral displacement to adjust.

The sliding component comprises two side clamping blocks 10, a side groove 2 is formed in the side face of the frame 1, the side clamping blocks 10 are connected with the side groove 2 in a sliding mode, one end, extending to the outer side of the frame 1, of each side clamping block 10 is fixedly connected with the side face of the installation block 11, and the guiding performance can be improved when the installation block 11 moves transversely through the addition of the side clamping blocks 10.

Embodiment III: on the basis of embodiment one and embodiment two, when the clamp structure needs to carry out the centre gripping fixed to the wallboard of different width to guarantee to be able to assist the wallboard of different models of installation, the clamp structure of current fixed wallboard generally comprises two cylinder subassembly cooperation splint, and such fixed knot constructs can only carry out the fixed wallboard of solitary centre gripping, and because at actual application's in-process, the wallboard needs to be installed at different heights, and current wallboard clamping equipment can not realize the purpose of altitude mixture control.

In sum, the clamping structure comprises a telescopic component, a transverse rectangular rod, two slide rods 15 which are arranged in a mirror image manner, and a clamping rod 16 which is fixedly connected with the tail ends of the slide rods 15, wherein the transverse rectangular rod is provided with a penetrating opening 18, a screw rod 24 is rotatably arranged in the opening 18, a motor II 23 is fixedly arranged on the side surface of the transverse rectangular rod, an output shaft of the motor II 23 extends to one end of the interior of the opening 18 and is fixedly connected with the screw rod 24, two ends of the screw rod 24 are respectively provided with external threads with opposite directions, one end of the slide rod 15 is provided with a threaded hole, the screw rod 24 is in threaded connection with the slide rod 15, one sides, close to each other, of the clamping rods 16 on two sides are provided with notches 17, when the wallboard needs to be installed and clamped, the side face of the rectangular wallboard is aligned with the position of the notch 17, then the motor II 23 is started, and the sliding rods 15 on two sides can be driven to move to the side away from each other or close to each other due to the relation of threads until the inner wall of the notch 17 clamps the side face of the wallboard, so that the wallboard is clamped, the wallboard with different widths can be adaptively adjusted and clamped, and compared with the existing multi-point clamping mode, the notch 17 can be clamped by adopting the mode of the surface binding face, and damage to the side face of the wallboard can be prevented by adopting the mode of multi-point clamping.

The telescopic component comprises a vertical rod 12, a telescopic rod 14 and a driving component, the telescopic rod 14 is movably inserted into the vertical rod 12, a tooth slot is formed in one side of the telescopic rod 14 corresponding to the driving component, and the tooth slot is meshed with the driving component.

The drive assembly includes biax motor 21 and gear one 22, the equal fixed mounting in both sides of biax motor 21 has gear one 22, gear one 22 and tooth's socket meshing, the bottom fixed mounting of biax motor 21 has motor mounting bracket 13, motor mounting bracket 13's cross section is L shape, motor mounting bracket 13 fixed mounting is at the top of spill frame two 5, when the wallboard is installed to needs, when highly adjusting, biax motor 21 starts to drive gear one 22 rotation, because meshing's relation can drive telescopic link 14 and reciprocate, thereby accomplish the regulation to telescopic link 14 height, thereby accomplish the operation of adjusting the wallboard height of fixing between both sides clamping lever 16, convenient to use.

Embodiment III: the method for installing the wallboard is as follows: through the wall glue, the wall board is suitable for a bamboo-wood fiber wall board because of light weight. When the fiber board is specifically installed, the surface is required to be wiped and polished to be smooth by using air nails on the wall surface and then using sand paper, the fiber board is cut according to the actual size, the surface is wiped cleanly according to the installation requirement, the universal glue is smeared on the back surface of the fiber board, and then the fiber board is stuck on the wall. Simultaneously, the filler is required to be uniformly stirred, gaps are filled, and finally, the surface is cleaned, or the method of fixing the filler is adopted by an aluminum alloy, and firstly, a woodworking plate is required to be used on a base of a wall surface, and the woodworking plate is also required to be fixed on the wall by air nails. The pin line is fixed by a pin code of aluminum alloy. The wallboard is inserted between aluminum alloy angle bead and tool bar again to can reach the effect of fastening, and when adopting glue installation wallboard, need utilize the manual work to press the wallboard, make the clearance of glue between wallboard and wall fully bond, such mode is comparatively loaded down with trivial details.

In summary, the pressing structure includes adjusting part, concave connecting block 26, motor three 27, gear two 28, gear bull stick 29 and pressing block 25, concave connecting block 26 is connected with adjusting part, the cross section of concave connecting block 26 is concave font, gear two 28 rotation is installed in the inside of concave connecting block 26, motor three 27 fixed mounting is in the side of concave connecting block 26, the output shaft of motor three 27 is in the same place with gear two 28 fixed connection, gear bull stick 29 is in the same place with pressing block 25 fixed connection, gear bull stick 29 rotates the inboard of installing at concave connecting block 26, and gear bull stick 29 meshes with gear two 28, pressing block 25's cross section is the arc, when installing the wallboard, smear glue in the mounted position of wallboard, later smear glue on the wallboard, start cylinder one 20, the output of cylinder one 20 moves to the side that is close to the wallboard, until pressing block 25 is laminated with the wallboard, then start motor three 27 drive gear two 28 rotation, then gear bull stick 29 rotates, make the back of wallboard face to pressing block 25 press, such pressing mode can simulate people's hand and reciprocate, make the bonding can fully adhere.

The adjusting component comprises a vertical plate 19 and a first air cylinder 20, wherein the vertical plate 19 is fixedly arranged at the bottom end of the transverse rectangular rod, the first air cylinder 20 is fixedly arranged on the vertical plate 19, and the output end of the first air cylinder 20 penetrates through the vertical plate 19 to be fixedly connected with the back surface of the concave connecting block 26.

Fourth, the top both sides fixed mounting of frame 1 have multiunit shrink subassembly, shrink subassembly sets up between spill frame one 4 and spill frame two 5, shrink subassembly is including pegging graft fixed circle 8 and flexible circle 9 together, fixed circle 8's inside fixed mounting has the spring, the upper end and the flexible circle 9 fixed connection of spring are together, when the wallboard is placed on the frame 1, the top at flexible circle 9 is pressed respectively to the bottom both sides of wallboard, flexible circle 9 shrink this moment, after the wallboard of one side is got rid of, flexible circle 9 upwards pops up, flexible circle 9 of popping up can carry out spacingly to the wallboard bottom of rear side, prevent that its bottom from sliding, cause piled up wallboard slope, influence normal transportation, and place the wallboard on frame 1, unnecessary wallboard can play the counter weight effect, prevent the whole forward slope of this device.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. An energy-conserving wallboard installation auxiliary structure of green building, its characterized in that: the frame comprises a frame (1) for bearing a transportation wallboard, wherein rollers (3) are respectively arranged at four corners of the bottom of the frame (1), a first concave frame (4) and a second concave frame (5) are fixedly arranged on the frame (1), the first concave frame (4) and the second concave frame (5) correspond to each other, one side of the frame (1) is provided with a bearing structure for bearing a clamping structure, the clamping structure is arranged on the bearing structure, and a pressing structure is arranged on the clamping structure;

the clamping structure comprises a telescopic component, a transverse rectangular rod, two slide bars (15) which are arranged in a mirror image mode, and clamping rods (16) which are fixedly connected with the tail ends of the slide bars (15), wherein a penetrating opening (18) is formed in the transverse rectangular rod, a screw rod (24) is rotatably arranged in the opening (18), a motor II (23) is fixedly arranged on the side face of the transverse rectangular rod, an output shaft of the motor II (23) extends to one end of the inside of the opening (18) and is fixedly connected with the screw rod (24), external threads with opposite directions are respectively formed in two ends of the screw rod (24), threaded holes are formed in one end of the slide bars (15), the screw rod (24) is in threaded connection with the slide bars (15), and notches (17) are formed in one sides, close to each other, of the clamping rods (16) on two sides;

the pressing structure comprises an adjusting component, a concave connecting block (26), a motor III (27), a gear II (28), a gear rotating rod (29) and a pressing block (25), wherein the concave connecting block (26) is connected with the adjusting component, the cross section of the concave connecting block (26) is concave, the gear II (28) is rotationally arranged in the concave connecting block (26), the motor III (27) is fixedly arranged on the side face of the concave connecting block (26), an output shaft of the motor III (27) is fixedly connected with the gear II (28), the gear rotating rod (29) is fixedly connected with the pressing block (25), the gear rotating rod (29) is rotationally arranged on the inner side of the concave connecting block (26), the gear rotating rod (29) is meshed with the gear II (28), and the cross section of the pressing block (25) is arc-shaped.

2. The green building energy-saving wallboard installation auxiliary structure according to claim 1, wherein: the bearing structure comprises a sliding assembly, a cross rod (6), an air cylinder (7) and a mounting block (11), wherein the mounting block (11) is connected with the sliding assembly, the cross rod (6) is transversely and fixedly mounted on the inner side of the frame (1), the air cylinder (7) is fixedly mounted on one side, deviating from the mounting block (11), of the cross rod (6), and an output shaft of the air cylinder (7) penetrates through the cross rod (6) and the frame (1) to be fixedly connected with the mounting block (11).

3. The green building energy-saving wallboard installation auxiliary structure according to claim 2, wherein: the sliding assembly comprises two side clamping blocks (10), a side groove (2) is formed in the side face of the frame (1), the side clamping blocks (10) are connected with the side groove (2) in a sliding mode, and one end, extending to the outer side of the frame (1), of each side clamping block (10) is fixedly connected with the side face of the installation block (11).

4. The green building energy-saving wallboard installation auxiliary structure according to claim 1, wherein: the telescopic component comprises a vertical rod (12), a telescopic rod (14) and a driving component, the telescopic rod (14) is movably inserted into the vertical rod (12), a tooth slot is formed in one side of the telescopic rod (14) corresponding to the driving component, and the tooth slot is meshed with the driving component.

5. The auxiliary structure for installing energy-saving wallboard of green building according to claim 4, wherein: the driving assembly comprises a double-shaft motor (21) and a first gear (22), wherein the first gear (22) is fixedly arranged on two sides of the double-shaft motor (21), the first gear (22) is meshed with a tooth slot, a motor mounting frame (13) is fixedly arranged at the bottom of the double-shaft motor (21), the cross section of the motor mounting frame (13) is L-shaped, and the motor mounting frame (13) is fixedly arranged at the top of a second concave frame (5).

6. The green building energy-saving wallboard installation auxiliary structure according to claim 1, wherein: the adjusting component comprises a vertical plate (19) and a first air cylinder (20), wherein the vertical plate (19) is fixedly arranged at the bottom end of the transverse rectangular rod, the first air cylinder (20) is fixedly arranged on the vertical plate (19), and the output end of the first air cylinder (20) penetrates through the vertical plate (19) to be fixedly connected with the back surface of the concave connecting block (26).

7. The green building energy-saving wallboard installation auxiliary structure according to claim 1, wherein: the top both sides fixed mounting of frame (1) have multiunit shrink subassembly, shrink subassembly setting is between spill frame one (4) and spill frame two (5), shrink subassembly is including fixed circle piece (8) and flexible circle piece (9) of pegging graft together, and the inside fixed mounting of fixed circle piece (8) has the spring, and the upper end and the flexible circle piece (9) fixed connection of spring are in the same place.