CN115419244A

CN115419244A - ALC wallboard straightness roughness controlling means that hangs down

Info

Publication number: CN115419244A
Application number: CN202211255693.XA
Authority: CN
Inventors: 颜承锋; 孙五一; 谢福美; 孙凯; 刘皓; 程勋明; 郑以健; 赵官庆
Original assignee: China Construction Fifth Engineering Bureau Co Ltd
Current assignee: China Construction Fifth Engineering Bureau Co Ltd
Priority date: 2022-10-13
Filing date: 2022-10-13
Publication date: 2022-12-02

Abstract

The invention discloses an ALC wallboard verticality flatness control device, which belongs to the field of decorative materials and comprises a plate body, a shell and fixed support legs, wherein angle codes are fixedly connected to two sides of each fixed support leg, bolts are meshed and sleeved on the top surfaces of the angle codes, caulking grooves are formed in the top surfaces of the fixed support legs, sliding grooves are formed in the top walls of the caulking grooves, cavities are formed in the bottom ends of the fixed support legs, and moving rods are slidably sleeved on the corresponding surfaces of the cavities.

Description

ALC wallboard straightness roughness controlling means that hangs down

Technical Field

The invention relates to the field of decorative materials, in particular to an ALC wallboard verticality and flatness control device.

Background

ALC refers to autoclaved lightweight concrete, which is a novel building material, and is a fine porous and lightweight aerated block prepared by taking ground quartz sand, cement, lime and gypsum as main production raw materials and aluminum powder as a foaming agent through batching, stirring, film injection, precuring and cutting, and curing for 10 to 12 hours at high temperature (180 to 200 ℃) and high pressure (10 to 12 standard atmospheric pressures), and the ALC is divided into the following components according to the product form: autoclaved lightweight concrete blocks (ALC blocks) and autoclaved lightweight concrete plates (ALC plates);

in modern decoration, the treatment of indoor wall surface increasingly adopts the mode of wallboard, and the characteristics of this mode mainly show: first, a large number of decorative materials can be used; secondly, the method can be produced in a factory; third, can increase the thermal-insulated effect of heat preservation of wall, however, the problem that this kind of mode often met in reality is, the building wall unevenness need make level the wall earlier before dress wallboard, perhaps does fossil fragments earlier, and such processing is both time-wasting and financial resources extravagant.

Through retrieval, chinese patent No. CN201320437375.5 discloses a wallboard with flatness adjustment, although the flatness of the initial wallboard, the module wallboard and the final wallboard are adjusted by the adjusting pins, the adjusting process of the wallboard or ALC wallboard cannot be operated quickly and accurately, the adjusting efficiency of the verticality and flatness of the ALC wallboard is reduced, the ALC wallboard is easy to be misadjusted during use, the verticality and flatness of the ALC wallboard cannot be guaranteed for a long time, and the problem of device defects is caused.

Disclosure of Invention

The invention aims to solve the defects in the prior art, and provides a control device capable of keeping the verticality and the flatness of an ALC wallboard for a long time.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a ALC wallboard straightness roughness controlling means that hangs down, includes plate body, casing and fixed stabilizer blade, the equal rigid coupling in both sides of fixed stabilizer blade has the angle sign indicating number, the bolt has been cup jointed in the top surface meshing of angle sign indicating number, the caulking groove has been seted up to the top surface of fixed stabilizer blade, the spout has been seted up to the roof of caulking groove, and the bottom of fixed stabilizer blade has seted up the cavity, the carriage release lever has been cup jointed in the slip on the corresponding face of cavity, the rigid coupling has the spring between the bottom surface of carriage release lever and cavity, and the top surface rigid coupling of carriage release lever has the kelly, the abaculus has been cup jointed in the caulking groove.

Furtherly, the top surface of kelly is the setting of arc inclined plane, and in the kelly extends to the caulking groove, angle sign indicating number and bolt set up about the bisector symmetry of fixed stabilizer blade respectively, the angle sign indicating number is run through to the cavity, the top of kelly and the bottom surface joint of abaculus.

Furthermore, the clamping rods are symmetrically arranged about the bisector of the moving rod, the fixed support legs drive the clamping rods to move through the moving rod and the springs, and the fixed support legs are distributed on four corners of the rear wall of the plate body.

Further, the top surface rigid coupling of abacus has solid fixed ring, gu fixed ring's internal surface meshing cover has cup jointed the lead screw, the top surface rigid coupling of lead screw has the carousel, the internal surface of carousel overlaps respectively and is equipped with negative pole magnetic ring and anodal magnetic ring, the carousel rotates with the back wall of plate body and cup joints, the top of casing is fixed cup joints respectively and is had data receiving module, calculation module and control module, and installs the motor in the bottom of casing, the rigid coupling has the transmission shaft on the output of motor, the other end rigid coupling of transmission shaft has the revolving rack, the power is installed to the top surface of revolving rack, and the rigid coupling has the magnetic core between the revolving rack, the surface winding of magnetic core has the coil.

Further, gu fixed ring cup joints with the spout slides, the transversal I-shaped setting of personally submitting of carousel, gu fixed ring and lead screw set up about the bisector symmetry of abaculus respectively, the lead screw has auto-lock nature.

Furthermore, the outer surface of the shell is fixedly connected with a positioning clamping plate, the positioning clamping plate is arranged in an L shape, the input end of the data receiving module is electrically connected with the output end of the laser planometer, and the data receiving module is in communication connection with the computing module and the control module.

Further, the magnetic cores are symmetrically arranged about the central axis of the rotating frame, the winding directions of coils on the magnetic cores on two sides are opposite, and the power supply is connected with the coils.

Further, the data receiving module is used for receiving the measurement data of the laser leveling instrument; the calculation module calculates the moving length of the four corners of the plate body according to the measurement data; the control module is used for controlling the motor and the power supply.

Compared with the prior art, the invention has the beneficial effects that:

1. the method comprises the steps of measuring deformation or inclination data of a plate body after installation through a laser planometer, forming measurement data, sending the measurement data to a data receiving module in a shell, analyzing the measurement data by the data receiving module, sending the analyzed measurement data to a calculating module, calculating the distance of the four corners of the plate body to be moved by the calculating module according to the measurement data, forming adjustment data, enabling a positioning clamping plate on the shell to be tightly attached to the side wall of the plate body, enabling the shell to be positioned right above a rotary table, sequentially starting a power supply and a motor through a control module according to the adjustment data, enabling the power supply to supply power to coils together, enabling a magnetic core wound by the coils to generate an induction magnetic field, enabling the induction magnetic field to attract a negative magnetic ring and a positive magnetic ring in the rotary table, enabling the rotary table to move synchronously with a magnetic core, enabling a transmission shaft on the motor to drive the rotary table to rotate, enabling a lead screw on the rotary table to drive the lead screw to extend out or be inserted into an embedded block, and further driving the four corners of the plate body to move, achieving the purpose of quickly and accurately adjusting ALC wallboard, improving the adjustment efficiency of the perpendicularity of the ALC, meanwhile, enabling the rotary table to be positioned in the interior of the wallboard, and further enabling the ALC not to be easily to be touched, so as to be mistakenly adjusted, and ensuring that the wallboard can not be used for a long-time.

2. According to the invention, the fixing support legs are fixed through the bolts on the angle codes, the embedded block indirectly connected with the board body is inserted into one end of the embedded groove, the board body is translated integrally, the board body drives the embedded block to be completely embedded into the embedded groove, the purpose of primarily fixing the embedded block is achieved, and then the board body is primarily fixed.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a schematic diagram of the overall structure of an ALC wallboard verticality and flatness control device provided by the present invention;

FIG. 2 is an enlarged view of the part A in FIG. 1 of the device for controlling the verticality and flatness of the ALC wallboard, according to the present invention;

FIG. 3 is a schematic view of a fixing support leg of the device for controlling the verticality and flatness of the ALC wallboard according to the present invention;

FIG. 4 is an enlarged view of the structure of the portion B in FIG. 1 of the ALC wallboard verticality flatness control apparatus in accordance with the present invention;

FIG. 5 is a sectional view of a casing structure of the ALC wallboard verticality and flatness control device provided by the present invention;

FIG. 6 is a structural cross-sectional view of a fixing leg of the ALC wallboard verticality flatness control device provided by the present invention.

In the figure: 1. a fixed leg; 2. corner connectors; 3. a bolt; 4. caulking grooves; 5. a chute; 6. a cavity; 7. a travel bar; 8. a spring; 9. a clamping rod; 10. an insert block; 11. a fixing ring; 12. a screw rod; 13. a turntable; 14. a negative pole magnetic ring; 15. a positive pole magnetic ring; 16. a plate body; 17. a housing; 18. positioning a clamping plate; 19. a data receiving module; 20. a calculation module; 21. a control module; 22. a motor; 23. a drive shaft; 24. rotating the frame; 25. a power source; 26. a magnetic core; 27. and a coil.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-2 and fig. 4-5, the present invention provides a technical solution: an ALC wallboard verticality flatness control device, the top surface of an embedded block 10 is fixed with a fixed ring 11, the inner surface of the fixed ring 11 is engaged and sleeved with a screw rod 12, the top surface of the screw rod 12 is fixed with a rotary disc 13, the inner surface of the rotary disc 13 is respectively sleeved with a cathode magnetic ring 14 and an anode magnetic ring 15, the rotary disc 13 is rotatably sleeved with the rear wall of a plate body 16, the top end of a shell 17 is respectively fixed and sleeved with a data receiving module 19, a calculation module 20 and a control module 21, a motor 22 is installed in the bottom end of the shell 17, the output end of the motor 22 is fixed with a transmission shaft 23, the other end of the transmission shaft 23 is fixed with a rotary frame 24, the top surface of the rotary frame 24 is installed with a power supply 25, a magnetic core 26 is fixed between the rotary frames 24, and a coil 27 is wound on the outer surface of the magnetic core 26, the fixing ring 11 is sleeved with the sliding groove 5 in a sliding mode, the cross section of the rotating disc 13 is arranged in an I shape, the fixing ring 11 and the lead screw 12 are symmetrically arranged about a bisector of the insert 10 respectively, the lead screw 12 has self-locking performance, a positioning clamping plate 18 is fixedly connected to the outer surface of the shell 17, the positioning clamping plate 18 is arranged in an L shape, the input end of the data receiving module 19 is electrically connected with the output end of the laser planometer, the data receiving module 19 is in communication connection with the computing module 20, the computing module 20 is in communication connection with the control module 21, the magnetic cores 26 are symmetrically arranged about the central axis of the rotating frame 24, the winding directions of the coils 27 on the magnetic cores 26 on two sides are opposite, the power supply 25 is connected with the coils 27, and the data receiving module 19 is used for receiving measuring data of the laser planometer; the calculation module 20 calculates the moving lengths of the four corners of the plate body 16 according to the measurement data; the control module 21 is used to control the motor 22 and the power supply 25.

Specifically, in the process of adjusting the verticality and flatness of the ALC wallboard, deformation or inclination data of the installed board 16 is measured by a laser leveling instrument to form measurement data, the measurement data are sent to a data receiving module 19 in a shell 17, the data receiving module 19 analyzes the measurement data and then sends the measurement data to a calculating module 20, the calculating module 20 calculates the distance that the four corners of the board 16 should move according to the measurement data to form adjustment data, a positioning clamping plate 18 on the shell 17 is tightly attached to the side wall of the board 16, the shell 17 is located right above a turntable 13, a power supply 25 and a motor 22 are sequentially started through a control module 21 according to the adjustment data, the power supply 25 supplies power to a coil 27, a magnetic core 26 wound by the coil 27 generates an induction field, the induction field attracts a negative magnetic ring 14 and a positive magnetic ring 15 in the turntable 13 to synchronously move along with the magnetic core 26, a transmission shaft 23 on the motor 22 drives the turntable 24 to rotate, the magnetic core 26 on the turntable 24 rotates, the turntable 13 rotates, the lead screw 12 on the turntable 13 rotates to drive the lead screw 12 to extend out or insert into the turntable 10, the lead screw to drive the ALC block to drive the turntable 16 to rapidly and the verticality and the wallboard to be capable of accurately and accurately adjust the wallboard, thereby improving the verticality of the wallboard when the panel is touched, and the panel 13 is accurately and the panel.

Example 2:

referring to fig. 1, 3 and 6, the present invention provides a technical solution: the utility model provides a ALC wallboard straightness roughness controlling means that hangs down, which comprises a plate body 16, casing 17 and fixed stabilizer blade 1, the equal rigid coupling in both sides of fixed stabilizer blade 1 has angle sign indicating number 2, bolt 3 has been cup jointed in the top surface meshing of angle sign indicating number 2, caulking groove 4 has been seted up to the top surface of fixed stabilizer blade 1, spout 5 has been seted up to the roof of caulking groove 4, and cavity 6 has been seted up to the bottom of fixed stabilizer blade 1, sliding sleeve has carriage release lever 7 on the corresponding face of cavity 6, the rigid coupling has spring 8 between carriage release lever 7 and the bottom surface of cavity 6, and the top surface rigid coupling of carriage release lever 7 has kelly 9, caulking block 10 has been cup jointed in the caulking groove 4, the top surface of kelly 9 is the setting of arc inclined plane, and kelly 9 extends to in the caulking groove 4, angle sign indicating number 2 and bolt 3 set up about the bisector symmetry of fixed stabilizer blade 1 respectively, cavity 6 runs through angle sign indicating number 2, the top of kelly 9 and the bottom surface joint of abaculus 10, kelly 9 sets up about the bisector symmetry of carriage release lever 7, fixed stabilizer blade 1 drives kelly through carriage release lever 7 and spring 8, 16 on the plate body wall of fixed stabilizer blade.

Specifically, at the in-process of installation ALC wallboard, mark out the position of fixed support leg 1 on the wall in advance, bolt 3 on the rethread angle sign 2 is fixed with fixed support leg 1, the one end of caulking groove 4 is inserted to the abaculus 10 that will be connected with the plate body 16 this moment indirectly, and whole translation plate body 16, make plate body 16 drive abaculus 10 and embed caulking groove 4 completely, reach the purpose of preliminary fixed abaculus 10, and then preliminary fixed plate body 16, in this process, along with the translation of abaculus 10, the bottom surface of abaculus 10 will extrude the arc inclined plane of kelly 9, and kelly 9 receives the unable translation of restriction of caulking groove 4 bottom surface, make kelly 9 can only receive the pressurized decline, and extrude spring 8 through carriage release 7, when abaculus 10 stops moving, the restriction of abaculus 10 is relieved to kelly 9, make kelly 9 reset under the drive of spring 8, thereby make kelly 9 and abaculus 10 joint, make abaculus 10 can's 10 unable return stroke backward move, reach the mesh of abundant fixed abaculus 10, and then accomplish the completion ALC 16, make the ALC dismantle when the wallboard, only need to drive ALC installation ALC and dismantle the keel, make the panel 7 to drive the installation ALC and avoid the keel of ALC to dismantle, and still to dismantle the panel, make the panel, and the panel, and the installation ALC operation can avoid the keel to produce the seam of the panel 7 to dismantle.

The working principle and the using process of the invention are as follows: when the ALC wallboard needs to be installed, the position of the fixed support leg 1 is marked on the wall surface in advance, then the fixed support leg 1 is fixed through the bolt 3 on the angle code 2, at the moment, the embedded block 10 indirectly connected with the plate body 16 is inserted into one end of the embedded groove 4, the plate body 16 is translated integrally, the plate body 16 drives the embedded block 10 to be completely embedded into the embedded groove 4, the purpose of primarily fixing the embedded block 10 is achieved, and then the plate body 16 is primarily fixed, in the process, along with the translation of the embedded block 10, the bottom surface of the embedded block 10 extrudes the arc-shaped inclined surface of the clamping rod 9, the clamping rod 9 cannot translate under the limitation of the bottom surface of the embedded groove 4, the clamping rod 9 can only be pressed to descend, the spring 8 is extruded through the moving rod 7, when the embedded block 10 stops moving, the limitation of the bottom surface of the clamping rod 9 on the embedded block 10 is removed, the clamping rod 9 is reset under the driving of the spring 8, the clamping rod 9 is clamped with the embedded block 10, and the embedded block 10, so that the embedded block 10 cannot move backwards, the purpose of fully fixing the embedded block 10 is achieved, the plate body 16 is further fully fixed, the ALC wallboard is installed, when the ALC wallboard needs to be disassembled, the ALC wallboard can be disassembled only by pressing the moving rod 7 on the side wall of the angle code 2 to enable the moving rod 7 to drive the clamping rod 9 to descend and reversely repeating the operation, the ALC wallboard is simple and convenient to install or disassemble, gaps among the ALC wallboards are avoided, keels are not needed to be installed, the fact that the keels limit the in-and-out direction of the ALC wallboard is avoided, when the verticality and flatness of the ALC wallboard needs to be adjusted, deformation or inclination data of the plate body 16 after being installed are measured through a laser planometer to form measurement data, the measurement data are sent to a data receiving module 19 in the shell 17, the data receiving module 19 analyzes the measurement data and then sends the measurement data to a calculating module 20, the calculating module 20 calculates the distance that four corners of the plate body 16 should move according to the measurement data, the adjustment data is formed, the positioning clamping plate 18 on the housing 17 is tightly attached to the side wall of the plate 16, the housing 17 is located right above the rotary table 13, the control module 21 sequentially starts the power supply 25 and the motor 22 according to the adjustment data, the power supply 25 supplies power to the coil 27, the magnetic core 26 wound by the coil 27 generates an induction magnetic field, the induction magnetic field attracts the negative magnetic ring 14 and the positive magnetic ring 15 in the rotary table 13, the rotary table 13 synchronously moves along with the magnetic core 26, the transmission shaft 23 on the motor 22 drives the rotary table 24 to rotate, the magnetic core 26 on the rotary table 24 rotates, the rotary table 13 rotates, the rotation of the rotary table 13 drives the lead screw 12 on the rotary table to rotate, the lead screw 12 extends out of or is inserted into the embedded block 10, the ALC wallboard 16 is driven to move, the ALC wallboard is quickly and accurately adjusted, the adjusting efficiency of the verticality of the ALC wallboard is improved, meanwhile, the rotary table 13 is located inside the plate 16, the rotary table 13 cannot be touched, the ALC wallboard is not easy to be mistakenly adjusted at the four corners, the ALC wallboard verticality can be ensured for a long time, and the operation is completed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a ALC wallboard straightness roughness controlling means that hangs down, its characterized in that, package rubbing board body (16), casing (17) and fixed stabilizer blade (1), the equal rigid coupling in both sides of fixed stabilizer blade (1) has angle sign indicating number (2), bolt (3) have been cup jointed in the top surface meshing of angle sign indicating number (2), caulking groove (4) have been seted up to the top surface of fixed stabilizer blade (1), spout (5) have been seted up to the roof of caulking groove (4), and just cavity (6) have been seted up to the bottom of fixed stabilizer blade (1), slide on the face that corresponds of cavity (6) and cup jointed carriage release lever (7), the rigid coupling has spring (8) between the bottom surface of carriage release lever (7) and cavity (6), and the top surface rigid coupling of carriage release lever (7) has kelly (9), it has abaculus (10) to cup joint in caulking groove (4).

2. The ALC wallboard perpendicularity flatness control device of claim 1, characterized in that the top surface of the jamming rod (9) is arc-shaped slope setting, and the jamming rod (9) extends into the caulking groove (4), the angle code (2) and the bolt (3) are symmetrically set about the bisector of the fixed support leg (1) respectively, the cavity (6) runs through the angle code (2), and the top end of the jamming rod (9) is clamped with the bottom surface of the embedding block (10).

3. The ALC wallboard perpendicularity flatness control device of claim 1, characterized by that the jamming rod (9) is symmetrically arranged about the bisector of the moving rod (7), the fixed legs (1) drive the jamming rod (9) to move through the moving rod (7) and the spring (8), the fixed legs (1) are distributed on the four corners of the rear wall of the plate body (16).

4. The ALC wallboard perpendicularity flatness control device according to claim 1, characterized in that the top surface of the embedded block (10) is fixedly connected with a fixed ring (11), the inner surface of the fixed ring (11) is meshed with a screw rod (12), the top surface of the screw rod (12) is fixedly connected with a turntable (13), the inner surface of the turntable (13) is respectively sleeved with a cathode magnetic ring (14) and an anode magnetic ring (15), the turntable (13) is rotatably sleeved with the rear wall of the plate body (16), the top end of the casing (17) is respectively fixedly sleeved with a data receiving module (19), a computing module (20) and a control module (21), and the bottom end of the casing (17) is internally provided with a motor (22), the output end of the motor (22) is fixedly connected with a transmission shaft (23), the other end of the transmission shaft (23) is fixedly connected with a rotating frame (24), the top surface of the rotating frame (24) is provided with a power supply (25), a magnetic core (26) is fixedly connected between the rotating frames (24), and the outer surface of the rotating frame (26) is wound with a magnetic core coil (27).

5. The ALC wallboard perpendicularity flatness control device according to claim 4, characterized in that the fixing ring (11) is sleeved with the sliding groove (5) in a sliding manner, the cross section of the rotating disc (13) is arranged in an I shape, the fixing ring (11) and the lead screw (12) are symmetrically arranged about the bisector of the insert (10), and the lead screw (12) has self-locking property.

6. The ALC wallboard perpendicularity flatness control device according to claim 4, characterized in that a positioning card (18) is fixed to the outer surface of the housing (17), the positioning card (18) is L-shaped, the input end of the data receiving module (19) is electrically connected with the output end of the laser leveling instrument, and the data receiving module (19) and the calculating module (20), the calculating module (20) and the control module (21) are all connected through communication.

7. The ALC wallboard perpendicularity flatness control device of claim 4, characterized in that the magnetic cores (26) are symmetrically arranged about the center axis of the turret (24) and the winding directions of the coils (27) on the magnetic cores (26) at both sides are opposite, and the power supply (25) is connected with the coils (27).

8. The ALC wallboard perpendicularity flatness control device of claim 4, characterized by the data receiving module (19) for receiving the laser leveling instrument measurement data; the calculation module (20) calculates the moving lengths of the four corners of the plate body (16) according to the measurement data; the control module (21) is used for controlling the motor (22) and the power supply (25).