CN214200128U

CN214200128U - Building engineering is with straightness detection device that hangs down

Info

Publication number: CN214200128U
Application number: CN202120584758.XU
Authority: CN
Inventors: 丁建民
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-03-23
Filing date: 2021-03-23
Publication date: 2021-09-14
Anticipated expiration: 2031-03-23

Abstract

The utility model discloses a perpendicularity detection device for construction engineering, which comprises a perpendicularity detector body and a clamping mechanism, wherein the clamping mechanism is arranged at the upper end position of the perpendicularity detector body, a rotating column is twisted to drive a second rope pulley to rotate, so that a second connecting rope is tightened or loosened to drive a clamping block to move, the space between two groups of clamping blocks can be adjusted, so that an object to be measured is clamped, when a detection assembly measures the object to be measured, a rotating disc can be rotated to adjust the direction of the object to be measured, the operation steps are simple, the adjusting column is twisted to tighten or loosen the first connecting rope, the extrusion block is pulled to lift, the height of a reset spring is adjusted, the height of a telescopic rod is changed, the heights of the rotating disc and the object to be measured are adjusted, the perpendicularity of the object under different heights can be conveniently measured, and under the condition that the positions of the detection assembly are the same, and providing different lifting positions with the same object verticality so as to observe whether the data of the detection assembly is correct or not.

Description

Building engineering is with straightness detection device that hangs down

Technical Field

The utility model relates to a building technical field specifically is a straightness detection device that hangs down for building engineering.

Background

Architecture is a subject spanning both engineering and human arts. Architectural arts and techniques involved in architecture, and aesthetic and practical aspects included as architectural arts of practical arts, are clearly different but closely related, and their components are very different depending on the specific situation and building.

The traditional verticality detection device for the construction engineering is not provided with a clamping structure capable of lifting and rotating, so that a detected object cannot be flexibly adjusted, and the complexity of a detection step is increased.

To the problem, a perpendicularity detection device for construction engineering is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a building engineering is with straightness detection device that hangs down, including straightness detector body and fixture that hangs down, fixture sets up in straightness detector body upper end position that hangs down, has set up liftable pivoted clamping structure to the problem in the background art has been solved.

In order to achieve the above object, the utility model provides a following technical scheme: a perpendicularity detection device for building engineering comprises a perpendicularity detector body and a clamping mechanism, wherein the clamping mechanism is arranged at the upper end position of the perpendicularity detector body;

the clamping mechanism is provided with a fixed disc, a rotating disc and a fixed block, the fixed disc is arranged at the upper end of the verticality detector body, the fixed block is arranged at the upper end of the fixed disc, and the rotating disc is movably arranged at the upper end of the fixed block;

the fixed block is provided with cooperation groove and buckle swivelling chute, and the cooperation groove sets up four groups, and the cooperation groove runs through to be seted up in fixed block upper end position.

Preferably, the fixed disk is provided with guide pillars, telescopic rods and adjusting members, the guide pillars are arranged in four groups, and the guide pillars are arranged at the upper end of the fixed disk and penetrate through the rotating disk and the fixed block.

Preferably, the telescopic link is provided with reset spring, extrusion piece, compartment groove and clearance, and reset spring sets up inside the telescopic link, and extrusion piece activity block is in the inside top position of telescopic link, and is connected with reset spring top position, and the compartment groove sets up inside the telescopic link, and the clearance sets up at compartment groove side.

Preferably, the adjusting member is provided with an adjusting column, a first rope wheel and a first connecting rope, the adjusting column is arranged on the side face of the first rope wheel, the position of the adjusting column is located on the outer side of the fixed disc, the position of the first rope wheel is located inside the fixed disc, one end of the first connecting rope is arranged on the outer side of the first rope wheel in a surrounding mode, and the other end of the first connecting rope is arranged on the outer side of the extrusion block.

Preferably, the first connecting rope is provided with a rope body and a thin rope part, the rope body is positioned in the partition groove, and the thin rope part is arranged on the side face of the rope body and penetrates through the gap to be connected with the extrusion block.

Preferably, the rotary disk is provided with an annular groove, clamping groove blocks and clamping assemblies, the annular groove penetrates through the upper end of the rotary disk, the clamping groove blocks are arranged at the lower end of the rotary disk, the clamping assemblies are arranged in two groups, and the clamping assemblies are arranged inside the rotary disk.

Preferably, the clamping assembly is provided with a rotating column, a second rope wheel, a clamping block, a second connecting rope and a compression spring, the rotating column is arranged on the side face of the second rope wheel, the rotating column is arranged on the outer side of the rotating disc, the clamping block is movably clamped inside the rotating disc, one end of the second connecting rope is wound on the outer side of the second rope wheel, the other end of the second connecting rope is arranged on the outer side of the clamping block, the compression springs are arranged in two groups, one end of each compression spring is arranged on the side face of the clamping block, and the other end of each compression spring is arranged inside the rotating disc.

Preferably, the buckle rotating groove is matched with the buckle groove block.

Compared with the prior art, the beneficial effects of the utility model are as follows:

1. the utility model provides a pair of straightness detection device that hangs down for building engineering, put into the rotary disk with required measurand object inside, twist and move the rotation post, it rotates to drive the second rope sheave, thereby tighten up or relax the second and connect the rope, drive the removal of grip block, the interval of adjustable two sets of grip block, thereby the centre gripping is lived and is needed the measurand object, when detecting component measures the measurand object, rotatable rotary disk, thereby adjustment measurand position, operation steps have been simple and easy, and the buckle swivelling chute is connected with the buckle of buckle groove piece, the rotation angle has been precisely.

2. The utility model provides a pair of straightness detection device that hangs down for building engineering, rotatable rotary disk, the adjustment is surveyed the position, twist and move the regulation post, tighten up or loosen first connecting rope, the lift of pulling extrusion piece, adjust reset spring's height, change the height of telescopic link, adjust the height of rotary disk and measurand object, conveniently measure the straightness that hangs down under the object co-altitude, and can be under the condition that the determine module position is the same, provide the different elevating position that the object hangs down straightness the same, whether the data of observing determine module is correct.

3. The utility model provides a pair of straightness detection device that hangs down for building engineering, rope body position are in the inslot portion between the partition, and string portion sets up in rope side, and has run through the clearance and be connected with the extrusion piece, when tightening up or loosening first connecting rope, can not influence reset spring's lift, and the setting of the guide post of four groups, can guarantee that the lift of rotary disk is steady.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the verticality detector body of the present invention;

fig. 3 is a schematic view of the three-dimensional structure of the fixing disc of the present invention;

FIG. 4 is a schematic plan view of the fixing plate of the present invention;

fig. 5 is a schematic structural view of the first connecting rope and the gap of the present invention;

FIG. 6 is a schematic structural view of the rotating disk and the fixed block of the present invention;

fig. 7 is a schematic structural view of the clamping assembly of the present invention.

In the figure: 1. a perpendicularity detector body; 11. a chassis; 12. a vertical rod; 13. a detection component; 2. a clamping mechanism; 21. fixing the disc; 211. a guide post; 212. a telescopic rod; 2121. a return spring; 2122. extruding the block; 2123. a partition groove; 2124. a gap; 213. an adjustment member; 2131. an adjustment column; 2132. a first sheave; 2133. a first connecting rope; 21331. a rope body; 21332. a thin rope portion; 22. rotating the disc; 221. an annular groove; 222. a buckle groove block; 223. a clamping assembly; 2231. rotating the column; 2232. a second sheave; 2233. a clamping block; 2234. a second connecting rope; 2235. a compression spring; 23. a fixed block; 231. a mating groove; 232. the buckle rotates the groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, a perpendicularity detecting apparatus for construction engineering includes a perpendicularity detecting apparatus body 1 and a clamping mechanism 2, wherein the clamping mechanism 2 is disposed at an upper end of the perpendicularity detecting apparatus body 1.

Referring to fig. 2, a verticality detecting apparatus for construction engineering, a verticality detecting apparatus body 1 is provided with a chassis 11, a vertical rod 12 and a detecting component 13, wherein the vertical rod 12 is disposed at an upper end of the chassis 11, and the detecting component 13 is movably disposed at a side surface of the vertical rod 12.

Referring to fig. 3-7, a verticality detecting apparatus for construction engineering, a clamping mechanism 2 is provided with a fixed disc 21, a rotating disc 22 and a fixed block 23, the fixed disc 21 is disposed at the upper end of a verticality detecting apparatus body 1, the fixed block 23 is disposed at the upper end of the fixed disc 21, the rotating disc 22 is movably disposed at the upper end of the fixed block 23, the fixed disc 21 is provided with four sets of guide posts 211, an expansion link 212 and an adjusting member 213, the guide posts 211 are disposed at the upper end of the fixed disc 21 and penetrate through the rotating disc 22 and the fixed block 23, the expansion link 212 is provided with a return spring 2121, an extrusion block 2122, a compartment slot 2123 and a gap 2124, the return spring 2121 is disposed inside the expansion link 212, the extrusion block 2122 is movably clamped at the top end of the expansion link 212 and connected with the uppermost end of the return spring 2121, the compartment slot 2123 is disposed inside the expansion link 212, the gap 2124 is disposed at the side of the compartment slot 2123, the adjusting member 213 is provided with an adjusting column 2131, a first rope pulley 2132 and a first connecting rope 2133, the adjusting column 2131 is arranged on the side surface of the first rope pulley 2132 and is positioned outside the fixed disc 21, the first rope pulley 2132 is positioned inside the fixed disc 21, one end of the first connecting rope 2133 is arranged outside the first rope pulley 2132 in a surrounding way, the other end of the first connecting rope 2133 is arranged outside the extrusion block 2122, the first connecting rope 2133 is provided with a rope 21331 and a thin rope portion 21332, the rope 21331 is positioned inside the compartment groove 2123, the thin rope portion 21332 is arranged on the side surface of the rope 21331 and is connected with the extrusion block 2122 through a gap 2124, the rotating disc 22 is provided with an annular groove 221, a buckle groove block 222 and a clamping component 223, the annular groove 221 is arranged at the upper end position of the rotating disc 22 in a penetrating way, the clamping groove block 222 is arranged at the lower end position of the rotating disc 22, the clamping component 223 is provided with two groups, the clamping component 223 is arranged inside the rotating disc 22, the rotating disc 223 is arranged inside the rotating disc 22, the rotating component 223 is provided with a rotating column 2231, The rotating column 2231 is arranged on the side surface of the second rope pulley 2232, the rotating column 2231 is arranged outside the rotating disc 22, the clamping block 2233 is movably clamped inside the rotating disc 22, one end of the second connecting rope 2234 is wound outside the second rope pulley 2232, the other end of the second connecting rope 2232 is arranged outside the clamping block 2233, two groups of compression springs 2235 are arranged, one end of each compression spring 2235 is arranged on the side surface of the clamping block 2233, the other end of each compression spring 2233 is arranged inside the rotating disc 22, the fixing block 23 is provided with four groups of matching grooves 231 and a buckling rotation groove 232, the matching grooves 231 are arranged in four groups, and the matching grooves 231 are arranged at the upper end position of the fixing block 23 in a penetrating manner.

The object to be measured is placed in the rotating disc 22, the rotating column 2231 is screwed to drive the second rope wheel 2232 to rotate, so as to tighten or loosen the second connecting rope 2234 to drive the clamping blocks 2233 to move, the distance between the two groups of clamping blocks 2233 can be adjusted, so as to clamp the object to be measured, when the detecting component 13 measures the object to be measured, the rotating disc 22 can be rotated to adjust the measured direction, the operation steps are simplified, the clamping rotating groove 232 is connected with the clamping of the clamping groove block 222, the rotating angle is accurate, the rotating disc 22 can be rotated to adjust the measured direction, the adjusting column 2131 is screwed, the first connecting rope 2133 is tightened or loosened, the extruding block 2122 is pulled to lift, the height of the return spring 2121 is adjusted, the height of the telescopic rod 212 is changed to adjust the heights of the rotating disc 22 and the object to be measured, so as to conveniently measure the verticality of the object at different heights, and can provide different lifting positions with the same object perpendicularity under the condition that the position of the detection assembly 13 is the same so as to observe whether the data of the detection assembly 13 is correct, the rope 21331 is positioned inside the compartment groove 2123, the thin rope portion 21332 is arranged on the side surface of the rope 21331 and penetrates through the gap 2124 to be connected with the extrusion block 2122, when the first connecting rope 2133 is tightened or loosened, the lifting of the return spring 2121 is not influenced, and the four groups of guide columns 211 can ensure the stable lifting of the rotating disc 22.

The working principle is as follows: the object to be measured is placed in the rotating disc 22, the rotating column 2231 is screwed to drive the second rope wheel 2232 to rotate, the second connecting rope 2234 is tightened or loosened to drive the clamping blocks 2233 to move, the distance between the two groups of clamping blocks 2233 can be adjusted, so that the object to be measured is clamped, when the object to be measured is measured by the detecting assembly 13, the rotating disc 22 can be rotated to adjust the orientation of the object to be measured, the adjusting column 2131 is screwed to tighten or loosen the first connecting rope 2133, the extruding block 2122 is pulled to ascend and descend, the height of the return spring 2121 is adjusted, the height of the telescopic rod 212 is changed, and the heights of the rotating disc 22 and the object to be measured are adjusted.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims

1. The utility model provides a straightness detection device that hangs down for building engineering, includes straightness detector body (1) and fixture (2) that hangs down, fixture (2) set up in straightness detector body (1) upper end position, its characterized in that hangs down: the verticality detector body (1) is provided with a chassis (11), a vertical rod (12) and a detection assembly (13), the vertical rod (12) is arranged at the upper end of the chassis (11), and the detection assembly (13) is movably arranged on the side surface of the vertical rod (12);

the clamping mechanism (2) is provided with a fixed disc (21), a rotating disc (22) and a fixed block (23), the fixed disc (21) is arranged at the upper end of the verticality detector body (1), the fixed block (23) is arranged at the upper end of the fixed disc (21), and the rotating disc (22) is movably arranged at the upper end of the fixed block (23);

the fixed block (23) is provided with a matching groove (231) and a buckle rotating groove (232), the matching grooves (231) are provided with four groups, and the matching grooves (231) penetrate through the upper end of the fixed block (23).

2. The perpendicularity detection device for construction engineering according to claim 1, characterized in that: the fixed disc (21) is provided with four groups of guide posts (211), telescopic rods (212) and adjusting members (213), the guide posts (211) are arranged at the upper end of the fixed disc (21) and penetrate through the rotating disc (22) and the fixed block (23).

3. The perpendicularity detection device for construction engineering according to claim 2, characterized in that: the telescopic rod (212) is provided with a return spring (2121), an extrusion block (2122), a compartment groove (2123) and a gap (2124), the return spring (2121) is arranged inside the telescopic rod (212), the extrusion block (2122) is movably clamped at the top end position inside the telescopic rod (212) and is connected with the uppermost end position of the return spring (2121), the compartment groove (2123) is arranged inside the telescopic rod (212), and the gap (2124) is arranged on the side face of the compartment groove (2123).

4. The perpendicularity detection device for construction engineering according to claim 2, characterized in that: the adjusting member (213) is provided with an adjusting column (2131), a first rope wheel (2132) and a first connecting rope (2133), the adjusting column (2131) is arranged on the side surface of the first rope wheel (2132) and is positioned outside the fixed disc (21), the first rope wheel (2132) is positioned inside the fixed disc (21), one end of the first connecting rope (2133) is arranged outside the first rope wheel (2132) in a surrounding mode, and the other end of the first connecting rope (2133) is arranged outside the extrusion block (2122).

5. The perpendicularity detection device for construction engineering according to claim 4, characterized in that: the first connecting rope (2133) is provided with a rope body (21331) and a thin rope part (21332), the rope body (21331) is positioned in the space groove (2123), the thin rope part (21332) is arranged on the side surface of the rope body (21331), penetrates through the gap (2124) and is connected with the extrusion block (2122).

6. The perpendicularity detection device for construction engineering according to claim 1, characterized in that: the rotary disc (22) is provided with an annular groove (221), a buckle groove block (222) and a clamping assembly (223), the annular groove (221) penetrates through the upper end position of the rotary disc (22), the buckle groove block (222) is arranged at the lower end position of the rotary disc (22), the clamping assembly (223) is provided with two sets, and the clamping assembly (223) is arranged inside the rotary disc (22).

7. The perpendicularity detection device for construction engineering according to claim 6, characterized in that: the clamping assembly (223) is provided with a rotating column (2231), a second rope wheel (2232), a clamping block (2233), a second connecting rope (2234) and a compression spring (2235), the rotating column (2231) is arranged on the side face of the second rope wheel (2232), the rotating column (2231) is arranged on the outer side of the rotating disc (22), the clamping block (2233) is movably clamped inside the rotating disc (22), one end of the second connecting rope (2234) is encircled on the outer side of the second rope wheel (2232), the other end of the second connecting rope is arranged on the outer side of the clamping block (2233), the compression springs (2235) are arranged in two groups, one end of the compression spring (2235) is arranged on the side face of the clamping block (2233), and the other end of the compression spring is arranged inside the rotating disc (22).

8. The perpendicularity detection device for construction engineering according to claim 1, characterized in that: the buckle rotation groove (232) is matched with the buckle groove block (222).