CN114689020B

CN114689020B - Wallboard perpendicularity monitoring equipment for assembly type building construction

Info

Publication number: CN114689020B
Application number: CN202210380453.6A
Authority: CN
Inventors: 陈凤琴
Original assignee: Shanghai Simu Mechanical And Electrical Equipment Installation Engineering Co ltd
Current assignee: Shanghai Simu Mechanical And Electrical Equipment Installation Engineering Co ltd
Priority date: 2022-04-12
Filing date: 2022-04-12
Publication date: 2023-05-05
Anticipated expiration: 2042-04-12
Also published as: CN114689020A

Abstract

The invention discloses wallboard verticality monitoring equipment for assembly type building construction, which relates to the technical field of assembly type building construction and comprises a chassis and a calibration component, wherein an embedded groove is formed in the upper surface of the chassis, a rotating plate is connected in the embedded groove in a jogged mode, an adjusting frame is fixedly connected above the rotating plate, a locking bolt is connected in the sliding groove in a sliding mode, a sliding rail is arranged on the inner surface of the adjusting frame, an adjusting ring is fixedly connected between sliding blocks, a fastening bolt is connected in the sliding groove in a sliding mode, a guide rail is arranged on the inner surface of the adjusting ring, a bottom plate is fixedly connected between clamping blocks, an indicating frame is fixedly connected in front of the upper surface and in right of the bottom plate, and a moving groove is symmetrically formed in the middle of the upper surface and the lower surface of the bottom plate, and the calibration component for detecting the verticality of the wallboard is arranged in the moving groove. This wallboard straightness monitoring facilities that hangs down for assembled building construction compares with current straightness monitoring mode that hangs down, has promoted monitoring accuracy, and is convenient for carry the device.

Description

Wallboard perpendicularity monitoring equipment for assembly type building construction

Technical Field

The invention relates to the technical field of assembly type building construction, in particular to wallboard verticality monitoring equipment for assembly type building construction.

Background

The fabricated building mainly comprises a prefabricated fabricated concrete structure, a steel structure, a modern wood structure building and the like, is representative of a modern industrialized production mode, and is characterized in that a large amount of field operation work in a traditional construction mode is transferred to a factory, and structural members and accessories (such as floors, wallboards, stairs, balconies and the like) for the building are manufactured in the factory, transported to a building construction site, and assembled and installed on site in a reliable connection mode, so that verticality monitoring of the wallboards is required in the construction process.

The existing verticality monitoring mode mainly uses a horizontal guiding rule to detect the wallboard, the accuracy is lower and detection errors are easy to occur because of the levelness problem of the guiding rule, and therefore, the wallboard verticality monitoring equipment for the assembled building construction is provided.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides wallboard verticality monitoring equipment for assembly type building construction, and solves the problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: wallboard straightness supervisory equipment that hangs down for assembly type construction, including chassis and calibration subassembly, the caulking groove has been seted up to the chassis upper surface, and the caulking groove internal engagement is connected with the revolving plate, revolving plate top fixedly connected with adjusts the frame, and adjusts the frame surface and seted up the spout, sliding connection has locking bolt in the spout, and is provided with the packing ring between locking bolt and the adjusting frame, the slide rail has been seted up to adjusting frame internal surface, and the upper and lower bilateral symmetry gomphosis is connected with the slider in the slide rail, fixedly connected with adjusting ring between the slider, and the guide slot has been seted up to adjusting ring surface, sliding connection has fastening bolt in the guide slot, and be provided with the cushion between fastening bolt and the adjusting ring, guide rail has been seted up to adjusting ring internal surface, and the symmetrical gomphosis of left and right sides is connected with the fixture block in the guide rail, fixedly connected with bottom plate between the fixture block, bottom plate upper surface place ahead and right fixedly connected with instruction frame, and the internal rotation is connected with the pointer, the bottom plate upper and lower surface middle part symmetry has been seted up and has been moved the groove, and has been provided with scale bar for detecting wallboard straightness calibration subassembly sets up in moving the groove.

Preferably, the adjusting frame is rotationally connected with the chassis through the rotating plate and the caulking groove, the sliding block is in sliding connection with the adjusting frame through the sliding rail, the locking bolt penetrates through the sliding groove and the sliding rail to be in threaded connection with the sliding block, the adjusting ring is rotationally connected with the adjusting frame through the sliding block, the clamping block is in sliding connection with the adjusting ring through the guide rail, the fastening bolt penetrates through the guide groove and the guide rail to be in threaded connection with the clamping block, and the bottom plate is rotationally connected with the adjusting ring through the clamping block.

Preferably, the calibration assembly comprises a moving block, a shell, an indicating needle, an emitter, an interface, a connector and a lens, wherein the shell is fixedly connected to the outer side of the moving block, the indicating needle is fixedly connected to the left side of the shell, the emitter is mounted in the shell, the interface is fixedly connected to the right side of the shell, the connector is sleeved on the right side of the interface, and the lens is fixedly connected to the right end of the connector.

Preferably, the moving block is connected with the moving groove in a jogged manner, the shell is connected with the bottom plate in a sliding manner through the moving block and the moving groove, the shell is vertically distributed with the scale strips, the indicating needle is distributed in parallel with the scale strips through the shell, the connector is connected with the connector through threads, the connector is connected with the shell through the connector in a rotating manner, the lens is connected with the connector through the connector in a rotating manner, and the center line of the lens coincides with the center line of the emitter.

Preferably, the chassis four corners symmetry has seted up the change groove, and change inslot fixedly connected with pivot, pivot outside gomphosis is connected with the screw rod for limiting the screw rod spacing subassembly sets up in the change inslot, the landing leg has been cup jointed in the screw rod outside, and the landing leg inboard has seted up the tongue-and-groove, the gomphosis is connected with the shrouding in the tongue-and-groove, the landing leg upper end is provided with the apron, and the apron four corners has seted up logical groove for fixed leg fixed subassembly sets up in logical groove outside, the recess has been seted up to the apron upper surface, and fixedly connected with bull stick in the recess, the bull stick outside gomphosis is connected with the carrying handle.

Preferably, the screw is rotationally connected with the chassis through a rotating shaft and a rotating groove, the supporting legs are in threaded connection with the screw, the sealing plate is in embedded connection with the supporting legs through the mortises, the sealing plate is in sliding connection with the supporting legs through the mortises, the supporting legs are in embedded connection with the cover plate through the through grooves, the sealing plate is attached to the cover plate and the chassis, the handle is rotationally connected with the grooves through the rotating rods, and the handle is in embedded connection with the cover plate through the grooves.

Preferably, the spacing subassembly includes card chamber, draw-in groove, jump ring, draw-in lever, buckle and card hole, the card chamber outside is provided with the draw-in groove, and card intracavity fixedly connected with jump ring, the one end fixedly connected with draw-in lever in card chamber is kept away from to the jump ring, and the fixedly connected with buckle in the draw-in lever outside, one side that the jump ring was kept away from to the draw-in lever is provided with the card hole.

Preferably, the clamping cavity is vertically distributed with the rotary groove, the clamping rod is elastically connected with the clamping cavity through the clamping spring, the clamping rod is slidably connected with the chassis through the clamping cavity, the clamping rod is in embedded connection with the chassis through the clamping hole, the clamping buckle is in embedded connection with the clamping groove, and the clamping buckle is in sliding connection with the chassis through the clamping groove.

Preferably, the fixed subassembly includes fixed chamber, spring, fixed block, fixed slot, pull rod and arm-tie, fixed intracavity fixedly connected with spring, and the inboard fixedly connected with fixed block of spring, the fixed block inboard is provided with the fixed slot, and fixed block middle part fixedly connected with pull rod, the pull rod outside fixedly connected with arm-tie.

Preferably, the fixed block is elastically connected with the fixed cavity through a spring, and is connected with the supporting leg in a jogged manner through a fixed groove, the fixed block is connected with the cover plate in a sliding manner through a pull rod and a pull plate, and the fixed block is connected with the supporting leg in a sliding manner through the fixed groove and the pull rod.

The invention provides wallboard perpendicularity monitoring equipment for assembly type building construction, which has the following beneficial effects: the wallboard verticality monitoring equipment for the assembled building construction improves the monitoring accuracy and is convenient to carry;

1. according to the invention, through the arrangement of the indication frame, the bottom plate and the adjusting ring can be adjusted according to the state of the pointer in the indication frame, the bottom plate rotates along the guide rail in the adjusting ring through the clamping block, meanwhile, the fastening bolt is driven to slide on the adjusting ring through the guide groove, when the pointer in the front indication frame is overlapped with the central line of the indication frame, the fastening bolt is screwed in the clamping block to fix the bottom plate, then the adjusting ring is rotated along the sliding rail in the adjusting frame through the sliding block, and meanwhile, the locking bolt is driven to slide on the adjusting frame through the sliding groove, when the pointer in the right indication frame is overlapped with the central line of the indication frame, the locking bolt is screwed in the sliding block to fix the adjusting ring, the adjustment of the bottom plate is completed, the bottom plate can be in a horizontal state when the wall body is checked, and the detection accuracy is improved.

2. According to the invention, through the arrangement of the calibration assembly, when the wall body is detected, the transmitter can emit laser outwards through the interface and the connector, the lens can refract and disperse the light to form a line on the wall board, the display direction of the light on the wall board can be changed when the connector is rotated on the interface, when the perpendicularity is tested, the connector is screwed to enable the light to be transversely displayed, then the distance between the light is measured, if the longitudinal distance between the light and the connector is the deviation value of the perpendicularity of the wall board, and when the light is longitudinally displayed, the levelness of the wall board can be measured, the indicator needle can read the horizontal distance between the connectors through the scale bar, and the applicability and the accuracy of the device are improved.

3. According to the invention, through the arrangement of the supporting legs, when the device is used, the screw rod can be downwards rotated to be in a vertical state in the rotary groove through the rotary shaft, then the supporting legs are used for supporting the device, and the heights of the device can be adjusted through rotating the supporting legs on the screw rod, so that different parts of the wall body are detected.

4. According to the invention, through the arrangement of the limiting assembly, when the screw rod is rotated down, the screw rod can apply pressure to the clamping rod, so that the clamping rod is pressed to move, the clamping rod compresses and slides into the clamping cavity, after the screw rod rotates to a vertical state, the screw rod is separated from contact with the clamping rod, the clamping rod rebounds under the action of the clamping spring and is embedded into the clamping hole, the screw rod is limited, the screw rod is prevented from being supported unstably due to rotation of the screw rod when the device is used, and the clamping rod can be driven to move by sliding the clamping buckle in the clamping groove after the device is used, so that the clamping rod is free from limiting the screw rod, and the screw rod is convenient to reset.

5. According to the invention, through the arrangement of the fixing component, when the cover plate is installed, the pull plate can be pulled outwards, the fixing block can be driven to slide in the fixing cavity through the pull rod, the spring is compressed, then the cover plate is inserted into the supporting leg through the through groove, when the cover plate is attached to the sealing plate, the pull plate is loosened, the fixing block can rebound under the action of the spring and slide into the embedding groove to be embedded with the supporting leg, the installation of the cover plate is completed, and the cover plate is prevented from falling off the supporting leg to cause damage of the device when the device is carried.

Drawings

FIG. 1 is a schematic cross-sectional front view of a wall panel verticality monitoring device for fabricated building construction according to the present invention;

FIG. 2 is an enlarged schematic view of the wall panel verticality monitor apparatus for fabricated building construction of the present invention at the position A in FIG. 1;

FIG. 3 is an enlarged schematic view of the wall panel verticality monitor apparatus for fabricated building construction of the present invention at B in FIG. 1;

FIG. 4 is a schematic diagram of a cross-sectional left side view of the wall panel verticality monitoring device for fabricated building construction of the present invention;

FIG. 5 is an enlarged schematic view of the wall panel verticality monitor apparatus for fabricated building construction of the present invention at C in FIG. 4;

FIG. 6 is a schematic diagram of a cross-sectional right side view of a base plate of the wallboard verticality monitoring device for fabricated building construction of the present invention;

FIG. 7 is a schematic cross-sectional top view of the wall panel verticality monitoring device for fabricated building construction of the present invention;

FIG. 8 is a schematic diagram of a cross-sectional top view of a spacing assembly of the wallboard verticality monitoring device for use in fabricated building construction of the present invention;

in the figure: 1. a chassis; 2. a caulking groove; 3. a rotating plate; 4. an adjusting frame; 5. a chute; 6. a locking bolt; 7. a gasket; 8. a slide rail; 9. a slide block; 10. an adjusting ring; 11. a guide groove; 12. a fastening bolt; 13. a cushion block; 14. a guide rail; 15. a clamping block; 16. a bottom plate; 17. an indication frame; 18. a pointer; 19. shifting the groove; 20. a scale bar; 21. a calibration assembly; 2101. moving the block; 2102. a housing; 2103. an indicator needle; 2104. a transmitter; 2105. an interface; 2106. a joint; 2107. a lens; 22. a rotary groove; 23. a rotating shaft; 24. a screw; 25. a limit component; 2501. a cavity is blocked; 2502. a clamping groove; 2503. clamping springs; 2504. a clamping rod; 2505. a buckle; 2506. a clamping hole; 26. a support leg; 27. a tongue and groove; 28. a sealing plate; 29. a cover plate; 30. a through groove; 31. a fixing assembly; 3101. a fixed cavity; 3102. a spring; 3103. a fixed block; 3104. a fixing groove; 3105. a pull rod; 3106. pulling a plate; 32. a groove; 33. a rotating rod; 34. a carrying handle.

Detailed Description

Referring to fig. 1 to 8, the present invention provides a technical solution: wallboard verticality monitoring equipment for assembly type building construction comprises a chassis 1 and a calibration component 21, wherein a caulking groove 2 is formed on the upper surface of the chassis 1, a rotating plate 3 is connected in the caulking groove 2 in a jogged manner, an adjusting frame 4 is fixedly connected above the rotating plate 3, a sliding groove 5 is formed on the outer surface of the adjusting frame 4, a locking bolt 6 is connected in a sliding manner in the sliding groove 5, a gasket 7 is arranged between the locking bolt 6 and the adjusting frame 4, a sliding rail 8 is formed on the inner surface of the adjusting frame 4, sliding blocks 9 are symmetrically connected in the sliding rail 8 in a jogged manner on the upper side and the lower side, an adjusting ring 10 is fixedly connected between the sliding blocks 9, a guide groove 11 is formed on the outer surface of the adjusting ring 10, a fastening bolt 12 is connected in a sliding manner in the guide groove 11, a cushion block 13 is arranged between the fastening bolt 12 and the adjusting ring 10, a guide rail 14 is formed on the inner surface of the adjusting ring 10, and clamping blocks 15 are connected in a jogged manner on the left side and the right side in the guide rail 14, a bottom plate 16 is fixedly connected between the clamping blocks 15, an indication frame 17 is fixedly connected in front of and on the right of the upper surface of the bottom plate 16, a pointer 18 is rotationally connected in the indication frame 17, a moving groove 19 is symmetrically arranged in the middle of the upper surface and the lower surface of the bottom plate 16, a scale bar 20 is arranged on the front side of the moving groove 19, a calibration component 21 for detecting the perpendicularity of the wallboard is arranged in the moving groove 19, the adjusting frame 4 is rotationally connected with the chassis 1 through a rotating plate 3 and a caulking groove 2, a sliding block 9 is slidingly connected with the adjusting frame 4 through a sliding rail 8, a locking bolt 6 is rotationally connected with the sliding block 9 through the sliding groove 5 and the sliding rail 8, an adjusting ring 10 is rotationally connected with the adjusting frame 4 through the sliding block 9, the clamping block 15 is rotationally connected with the adjusting ring 10 through a guide rail 14, a fastening bolt 12 is rotationally connected with the clamping block 15 through the guide groove 11 and the guide rail 14, and the bottom plate 16 is rotationally connected with the adjusting ring 10 through the clamping blocks 15;

the method comprises the specific operations that through the arrangement of the indication frame 17, the bottom plate 16 and the adjusting ring 10 can be adjusted according to the state that the pointer 18 is in the indication frame 17, the bottom plate 16 rotates along the guide rail 14 in the adjusting ring 10 through the clamping block 15, meanwhile, the fastening bolt 12 is driven to slide on the adjusting ring 10 through the guide groove 11, when the pointer 18 in the front indication frame 17 is overlapped with the central line of the indication frame 17, the fastening bolt 12 is screwed in the clamping block 15 to fix the bottom plate 16, then the adjusting ring 10 is rotated along the sliding rail 8 in the adjusting frame 4 through the sliding block 9, meanwhile, the locking bolt 6 is driven to slide on the adjusting frame 4 through the sliding groove 5, when the pointer 18 in the right indication frame 17 is overlapped with the central line of the indication frame 17, the locking bolt 6 is screwed in the sliding block 9 to fix the adjusting ring 10, the adjustment of the bottom plate 16 is completed, the bottom plate 16 can be in a horizontal state when the wall body is checked, and the detection accuracy is improved;

referring to fig. 1, 4, 6 and 7, the calibration assembly 21 includes a moving block 2101, a housing 2102, an indicator needle 2103, an emitter 2104, an interface 2105, a connector 2106 and a lens 2107, wherein the outer side of the moving block 2101 is fixedly connected with the housing 2102, the indicator needle 2103 is fixedly connected with the left side of the housing 2102, the emitter 2104 is mounted in the housing 2102, the interface 2105 is fixedly connected with the right side of the housing 2102, the connector 2106 is sleeved on the right side of the interface 2105, the right end of the connector 2106 is fixedly connected with the lens 2107, the moving block 2101 is connected with the moving groove 19 in a jogged manner, the housing 2102 is connected with the bottom plate 16 in a sliding manner through the moving block 2101 and the moving groove 19, the housing 2102 is vertically distributed with the scale bar 20, the indicator needle 2103 is parallel to the scale bar 20 through the housing 2102, the connector 2106 is in threaded connection with the interface 2105, the connector 2106 is rotationally connected with the housing 2102 through the connector 2105, the lens 2107 is rotationally connected with the connector 2105 through the connector 2106, and the center line of the lens 2107 coincides with the center line of the emitter 2104;

the device specifically comprises the following steps that through the arrangement of the calibration assembly 21, when the wall body is detected, the emitter 2104 can emit laser outwards through the interface 2105 and the connector 2106, the lens 2107 can refract and disperse the light to form a line on the wall plate, the display direction of the light on the wall plate can be changed when the connector 2106 is rotated on the interface 2105, when the perpendicularity is tested, the connector 2106 is screwed first to enable the light to be transversely displayed, then the distance between the light is measured, if the longitudinal distance between the light and the connector 2106 is the deviation value of the perpendicularity of the wall plate, and when the light is longitudinally displayed, the levelness of the wall plate can be measured, the indicator 2103 can read the horizontal distance between the connectors 2106 through the scale bars 20, and the applicability and the accuracy of the device are improved;

referring to fig. 1, 4 and 7, a rotary groove 22 is symmetrically formed at four corners of a chassis 1, a rotary shaft 23 is fixedly connected in the rotary groove 22, a screw 24 is jogged and connected at the outer side of the rotary shaft 23, a limit component 25 for limiting the screw 24 is arranged in the rotary groove 22, a supporting leg 26 is sleeved at the outer side of the screw 24, a mortise 27 is formed at the inner side of the supporting leg 26, a sealing plate 28 is jogged and connected in the mortise 27, a cover plate 29 is arranged at the upper end of the supporting leg 26, through grooves 30 are formed at four corners of the cover plate 29, a fixing component 31 for fixing the supporting leg 26 is arranged at the outer side of the through grooves 30, a groove 32 is formed at the upper surface of the cover plate 29, a rotating rod 33 is fixedly connected in the groove 32, a lifting handle 34 is connected to the outer side of the rotating rod 33 in a jogged manner, the screw 24 is connected with the chassis 1 in a rotating manner through the rotating shaft 23 and the rotating groove 22, the supporting leg 26 is connected with the screw 24 in a threaded manner, the sealing plate 28 is connected with the supporting leg 26 in a jogged manner through the mortise 27, the sealing plate 28 is connected with the supporting leg 26 in a sliding manner through the mortise 27, the supporting leg 26 is connected with the cover plate 29 in a jogged manner through the through groove 30, the sealing plate 28 is attached to the cover plate 29 and the chassis 1, the lifting handle 34 is connected with the groove 32 in a rotating manner through the rotating rod 33, and the lifting handle 34 is connected with the cover plate 29 in a jogged manner through the groove 32;

the device has the specific operation that through the arrangement of the support legs 26, when the device is used, the screw 24 can be downwards rotated to be in a vertical state in the rotary groove 22 through the rotary shaft 23, then the support legs 26 are used for providing support for the device, and the height of the device can be adjusted through rotating the support legs 26 on the screw 24, so that different parts of the wall body can be detected, when the device is not used, the support legs 26 can be reset, then the screw 24 is rotated back, the sealing plate 28 is inserted into the tenon groove 27, then the cover plate 29 is installed on the support legs 26 through the through grooves 30, at the moment, the device is closed, the device can be conveniently carried by the carrying handle 34, and the sealing plate 28 can avoid damage to the device caused by collision of foreign objects on the device when the device is moved;

referring to fig. 1, 4 and 8, the limiting component 25 includes a clamping cavity 2501, a clamping groove 2502, a clamping spring 2503, a clamping rod 2504, a clamping buckle 2505 and a clamping hole 2506, wherein the clamping groove 2502 is arranged at the outer side of the clamping cavity 2501, the clamping spring 2503 is fixedly connected in the clamping cavity 2501, the clamping rod 2504 is fixedly connected at one end of the clamping spring 2503 far away from the clamping cavity 2501, the clamping buckle 2505 is fixedly connected at the outer side of the clamping rod 2504, the clamping hole 2506 is arranged at one side of the clamping rod 2504 far away from the clamping spring 2503, the clamping cavity 2501 is vertically distributed with the rotary groove 22, the clamping rod 2504 is elastically connected with the clamping cavity 2501 through the clamping spring 2503, the clamping rod 2504 is in sliding connection with the chassis 1 through the clamping cavity 2501, the clamping rod 2504 is in embedded connection with the chassis 1 through the clamping hole 2506, the clamping buckle 5 is in embedded connection with the clamping groove 2502, and the clamping buckle 2505 is in sliding connection with the chassis 1 through the clamping groove 2502;

the device specifically comprises the following operations that through the arrangement of the limiting component 25, when the screw 24 is rotated down, the screw 24 can apply pressure to the clamping rod 2504, so that the clamping rod 2504 is pressed to move, the clamping rod 2504 compresses and slides the clamping spring 2503 into the clamping cavity 2501, after the screw 24 is rotated to a vertical state, the screw 24 is separated from the clamping rod 2504, the clamping rod 2504 rebounds under the action of the clamping spring 2503 and is embedded into the clamping hole 2506, the screw 24 is limited, the unstable support caused by the rotation of the screw 24 when the device is used is avoided, and after the device is used, the clamping rod 2504 can be driven to move by the clamping buckle 2505 which can slide in the clamping groove 2502, so that the clamping rod 2504 releases the limitation on the screw 24, and the screw 24 is convenient to reset;

referring to fig. 1, 4, 5 and 7, the fixing assembly 31 includes a fixing cavity 3101, a spring 3102, a fixing block 3103, a fixing groove 3104, a pull rod 3105 and a pull plate 3106, the spring 3102 is fixedly connected in the fixing cavity 3101, the fixing block 3103 is fixedly connected inside the spring 3102, the fixing groove 3104 is arranged inside the fixing block 3103, the pull rod 3105 is fixedly connected in the middle of the fixing block 3103, the pull plate 3106 is fixedly connected outside the pull rod 3105, the fixing block 3103 is elastically connected with the fixing cavity 3101 through the spring 3102, the fixing block 3103 is in jogged connection with the supporting leg 26 through the fixing groove 3104, the fixing block 3103 is in sliding connection with the cover plate 29 through the pull rod 3105 and the pull plate 3106, and the fixing block 3103 is in sliding connection with the supporting leg 26 through the fixing groove 3104 and the pull rod 3105;

the fixing assembly 31 is arranged, so that when the cover plate 29 is installed, the pull plate 3106 can be pulled outwards, the fixing block 3103 can be driven to slide in the fixing cavity 3101 through the pull rod 3105, the spring 3102 is compressed, then the cover plate 29 is inserted into the supporting leg 26 through the through groove 30, after the cover plate 29 is attached to the sealing plate 28, the pull plate 3106 is loosened, the fixing block 3103 can rebound under the action of the spring 3102 and slide into the caulking groove 2 to be embedded with the supporting leg 26, the installation of the cover plate 29 is completed, and the cover plate 29 is prevented from falling off the supporting leg 26 to be damaged due to loosening of the cover plate 29 when the device is carried.

Working principle: when the wallboard verticality monitoring device for the assembled building construction is used, firstly, the screw 24 is downwards rotated to be in a vertical state in the rotary groove 22 through the rotary shaft 23, then, the support is provided for the device through the supporting legs 26, the height of the device can be adjusted through rotating the supporting legs 26 on the screw 24, so that different parts of a wall body can be detected, when the screw 24 is rotated down, the screw 24 can apply pressure to the clamping rod 2504, so that the clamping rod 2504 is pressed to move, the clamping rod 2504 compresses and slides the clamping spring 2503 into the clamping cavity 2501, after the screw 24 is rotated to be in a vertical state, the screw 24 is separated from the clamping rod 2504, the clamping rod 2504 rebounds under the action of the clamping spring 2503 and is embedded into the clamping hole 2506, the screw 24 is limited, the situation that the support is unstable due to the rotation of the screw 24 when the device is used is avoided, after the device is used, the clamping rod 2505 can be slid in the clamping groove 2502 to drive the clamping rod 2504 to move, the clamping rod 2504 releases the restriction of the screw 24 so as to facilitate the screw 24 to reset, then the bottom plate 16 and the adjusting ring 10 are adjusted according to the state of the pointer 18 in the indicating frame 17, the bottom plate 16 rotates along the guide rail 14 in the adjusting ring 10 through the clamping block 15, simultaneously the fastening bolt 12 is driven to slide on the adjusting ring 10 through the guide groove 11, when the pointer 18 in the indicating frame 17 in front is overlapped with the central line of the indicating frame 17, the fastening bolt 12 is screwed in the clamping block 15 to fix the bottom plate 16, then the adjusting ring 10 is rotated along the slide rail 8 in the adjusting frame 4 through the sliding block 9, simultaneously the locking bolt 6 is driven to slide on the adjusting frame 4 through the sliding groove 5, when the pointer 18 in the indicating frame 17 in the right side is overlapped with the central line of the indicating frame 17, the locking bolt 6 is screwed in the sliding block 9 to fix the adjusting ring 10, the adjustment of the bottom plate 16 is completed, the bottom plate 16 is guaranteed to be in a horizontal state when the wall body is inspected, the detection precision is improved, when the wall body is detected, the transmitter 2104 can outwards transmit laser through the interface 2105 and the connector 2106, the lens 2107 can refract and disperse light to enable the light to be linear on the wall plate, the display direction of the light on the wall plate can be changed when the connector 2106 is rotated on the interface 2105, when the perpendicularity is tested, the connector 2106 is screwed to enable the light to be transversely displayed, the distance between the light is measured, if the longitudinal distance between the light and the connector 2106 is the deviation value of the perpendicularity of the wall plate, the levelness of the wall plate can be measured when the light is longitudinally displayed, the indicator needle 2103 can read the horizontal distance between the connectors 2106 through the scale bars 20, the applicability and the precision of the device are improved, and when the device is not used, the support leg 26 can be reset and then the screw 24 is turned back, the sealing plate 28 is inserted into the mortise 27, then the cover plate 29 is installed on the support leg 26 through the through groove 30, at the moment, the device is closed, the device can be conveniently carried by the lifting handle 34, the cover plate 28 can avoid damage to the device caused by collision of external objects to the device when the device is moved, when the cover plate 29 is installed, the pull plate 3106 can be pulled outwards, the fixing block 3103 can be driven by the pull rod 3105 to slide in the fixing cavity 3101 and compress the spring 3102, then the cover plate 29 is inserted into the support leg 26 through the through groove 30, after the cover plate 29 is attached to the sealing plate 28, the pull plate 3106 is released, the fixing block 3103 can rebound under the action of the spring 3102 and slide into the embedding groove 2 to the support leg 26, the installation of the cover plate 29 is completed, the device falling damage caused by loosening of the cover plate 29 from the support leg 26 when the device is carried, this is the theory of operation of this wallboard straightness monitoring facilities that hangs down for assembled building construction.

Claims

1. Wallboard straightness monitoring facilities that hangs down for assembled building construction, including chassis (1) and calibration subassembly (21), its characterized in that, chassis (1) upper surface has been seted up caulking groove (2), and the gomphosis is connected with rotating plate (3) in caulking groove (2), rotating plate (3) top fixedly connected with adjusting frame (4), and spout (5) have been seted up to adjusting frame (4) surface, sliding connection has locking bolt (6) in spout (5), and is provided with packing ring (7) between locking bolt (6) and adjusting frame (4), slide rail (8) have been seted up to adjusting frame (4) internal surface, and slide rail (8) upper and lower both sides symmetry gomphosis is connected with slider (9), fixedly connected with adjusting ring (10) between slider (9), and adjusting ring (10) surface has been seted up guide slot (11), sliding connection has fastening bolt (12) in guide slot (11), and be provided with cushion (13) between fastening bolt (12) and adjusting ring (10), sliding connection has locking bolt (14) in spout (5), guide rail (14) internal surface has been seted up, and the interior (16) of slide rail is connected with between right side (15) and the gomphosis is connected with fixture block (15), the utility model discloses a wallboard, including bottom plate (16) upper surface place ahead and right side fixedly connected with instruction frame (17), and instruct frame (17) internal rotation and be connected with pointer (18), move groove (19) have been seted up to bottom plate (16) upper and lower surface middle part symmetry, and move groove (19) front side to be provided with scale strip (20), be used for detecting wallboard straightness that hangs down calibration subassembly (21) set up in moving groove (19).

2. The wallboard verticality monitoring device for fabricated building construction according to claim 1, wherein: the utility model discloses a chassis, including chassis (1) and chassis, chassis (1) are connected in rotation, and chassis (4) are connected in rotation through rotating plate (3) and caulking groove (2), and slider (9) pass through slide rail (8) and regulation frame (4) sliding connection, locking bolt (6) pass spout (5) and slide rail (8) and slider (9) threaded connection, and adjusting ring (10) are connected in rotation through slider (9) and regulation frame (4), fixture block (15) pass through guide rail (14) and adjusting ring (10) sliding connection, and fastening bolt (12) pass guide slot (11) and guide rail (14) and fixture block (15) threaded connection, bottom plate (16) pass through fixture block (15) and adjusting ring (10) and rotate to be connected.

3. The wallboard verticality monitoring device for fabricated building construction according to claim 1, wherein: calibration subassembly (21) is including moving piece (2101), shell (2102), pilot pin (2103), transmitter (2104), interface (2105), joint (2106) and lens (2107), move piece (2101) outside fixedly connected with shell (2102), and shell (2102) left side fixedly connected with pilot pin (2103), shell (2102) internally mounted has transmitter (2104), and shell (2102) right side fixedly connected with interface (2105), joint (2106) have been cup jointed on interface (2105) right side, and joint (2106) right-hand member fixedly connected with lens (2107).

4. The wallboard verticality monitoring device for fabricated building construction according to claim 3, wherein: move piece (2101) and move groove (19) gomphosis and be connected, and shell (2102) are through moving piece (2101) and move groove (19) and bottom plate (16) sliding connection, shell (2102) and scale strip (20) perpendicular distribution, and pilot needle (2103) pass through shell (2102) and scale strip (20) parallel distribution, connect (2106) and interface (2105) threaded connection, and connect (2106) and shell (2102) rotation connection through interface (2105), lens (2107) rotate with interface (2105) through connect (2106) and be connected, and lens (2107) central line and transmitter (2104) central line coincidence.

5. The wallboard verticality monitoring device for fabricated building construction according to claim 1, wherein: the chassis (1) four corners symmetry has seted up change groove (22), and change groove (22) internal fixation has pivot (23), pivot (23) outside gomphosis is connected with screw rod (24) for spacing subassembly (25) of restriction screw rod (24) set up in change groove (22), landing leg (26) have been cup jointed in the screw rod (24) outside, and have seted up tongue-and-groove (27) in landing leg (26) inboard, the gomphosis is connected with shrouding (28) in tongue-groove (27), landing leg (26) upper end is provided with apron (29), and apron (29) four corners has seted up logical groove (30), and fixed subassembly (31) for fixed landing leg (26) set up in logical groove (30) outside, recess (32) are seted up to apron (29) upper surface, and fixedly connected with bull stick (33) in recess (32), bull stick (33) outside gomphosis is connected with carrying handle (34).

6. The wallboard verticality monitoring device for fabricated building construction according to claim 5, wherein: screw rod (24) are connected with chassis (1) rotation through pivot (23) and rotary groove (22), and landing leg (26) and screw rod (24) threaded connection, shrouding (28) are connected with landing leg (26) gomphosis through tongue-and-groove (27), and shrouding (28) are connected with landing leg (26) sliding connection through tongue-and-groove (27), landing leg (26) are connected with apron (29) gomphosis through logical groove (30), and shrouding (28) are laminated with apron (29) and chassis (1), handle (34) are connected with recess (32) rotation through bull stick (33), and handle (34) are connected with apron (29) gomphosis through recess (32).

7. The wallboard verticality monitoring device for fabricated building construction according to claim 5, wherein: spacing subassembly (25) are including card chamber (2501), draw-in groove (2502), jump ring (2503), card pole (2504), buckle (2505) and card hole (2506), the card chamber (2501) outside is provided with draw-in groove (2502), and fixedly connected with jump ring (2503) in card chamber (2501), the one end fixedly connected with card pole (2504) of card chamber (2501) are kept away from to jump ring (2503), and the outside fixedly connected with buckle (2505) of card pole (2504), the one side that jump ring (2503) was kept away from to card pole (2504) is provided with card hole (2506).

8. The wallboard verticality monitoring device for fabricated building construction according to claim 7, wherein: the clamping cavities (2501) are vertically distributed with the rotating grooves (22), clamping rods (2504) are elastically connected with the clamping cavities (2501) through clamping springs (2503), the clamping rods (2504) are slidably connected with the chassis (1) through the clamping cavities (2501), the clamping rods (2504) are in embedded connection with the chassis (1) through clamping holes (2506), the clamping rods (2505) are in embedded connection with the clamping grooves (2502), and the clamping rods (2505) are in sliding connection with the chassis (1) through the clamping grooves (2502).

9. The wallboard verticality monitoring device for fabricated building construction according to claim 5, wherein: the fixing assembly (31) comprises a fixing cavity (3101), a spring (3102), a fixing block (3103), a fixing groove (3104), a pull rod (3105) and a pull plate (3106), wherein the spring (3102) is fixedly connected in the fixing cavity (3101), the fixing block (3103) is fixedly connected with the inner side of the spring (3102), the fixing groove (3104) is formed in the inner side of the fixing block (3103), the pull rod (3105) is fixedly connected with the middle part of the fixing block (3103), and the pull plate (3106) is fixedly connected with the outer side of the pull rod (3105).

10. The wallboard verticality monitoring device for fabricated building construction according to claim 9, wherein: the fixed block (3103) is elastically connected with the fixed cavity (3101) through a spring (3102), the fixed block (3103) is connected with the supporting leg (26) in a jogged mode through a fixed groove (3104), the fixed block (3103) is connected with the cover plate (29) in a sliding mode through a pull rod (3105) and a pull plate (3106), and the fixed block (3103) is connected with the supporting leg (26) in a sliding mode through the fixed groove (3104) and the pull rod (3105).