CN113624206A - Straightness detection device that hangs down based on portable for building engineering - Google Patents

Abstract

The invention provides a portable verticality detection device based on constructional engineering, relates to the technical field of constructional engineering, and aims to solve the problem that the conventional verticality detection device cannot automatically adjust and support according to different terrains due to the fact that the ground of a construction site is not flat enough when in use; the mounting mechanism is a verticality detection device; the bottom of the mounting mechanism is provided with a supporting mechanism; the rotating piece is meshed with the clamping teeth on the tooth row through the gears on the two sides; the balance weight is arranged in the adjusting groove through the rectangular protrusion. Because the effect of balancing piece and bottom part for the support piece rebound with ground contact, upwards jack-up tooth row, and tensile spring on the locating part, the tooth row meshes with the gear on the rotating member mutually, makes the balancing piece move to the one side not with ground contact, tooth row and the gear engagement of the one side not with ground contact, compresses the spring on the locating part when support piece moves down, makes the main part keep the level, makes to measure more accurately.

Description

Straightness detection device that hangs down based on portable for building engineering

Technical Field

The invention belongs to the technical field of constructional engineering, and particularly relates to a portable verticality detection device based on constructional engineering.

Background

The building engineering refers to an engineering entity formed by the construction of various house buildings and auxiliary facilities thereof and the installation activities of lines, pipelines and equipment matched with the house buildings; the building engineering is the project entity and the supporting line, pipeline, equipment installation project of planning, investigation, design and construction, completion and other various technical works and completion for newly-built, reconstructed or expanded building and affiliated structure facilities, and in the construction process, need carry out the verticality measurement to the project of construction, the content of construction measurement work and the accuracy degree of the completion condition play the vital role to the smooth construction of project ability and quality level, and need use this device when measuring.

Based on prior art discovery, current straightness detection device that hangs down is when using, in the building work progress, the in-process that builds as the wall body needs carry out the straightness measurement that hangs down to it, prevent to produce the condition that produces the skew in the work progress, and some wall bodies adopt unevenness's design for pleasing to the eye surface, it is convenient inadequately when measuring, can't adjust the measurement according to the height of wall body, and current straightness detection device that hangs down is when using, because the job site ground is not level and smooth enough, make when measuring the straightness that hangs down accurate inadequately, can't adjust the support according to the topography automation of difference.

Disclosure of Invention

In order to solve the technical problems, the invention provides a portable verticality detection device for building engineering, which aims to solve the problems that when the conventional verticality detection device is used, in the building construction process, the verticality of a wall needs to be measured in the building process, so that the deflection generated in the construction process is prevented, part of the wall adopts an uneven design for the beautiful surface, so that the measurement is not convenient enough, and the adjustment and measurement cannot be carried out according to the height of the wall, and when the conventional verticality detection device is used, the verticality is not accurate enough when the measurement is carried out due to the fact that the ground of a construction site is not flat enough, and the support cannot be automatically adjusted according to different terrains.

The invention is based on the purpose and the efficacy of the portable verticality detection device for the construction engineering, and is achieved by the following specific technical means: the portable verticality detection device based on the construction engineering comprises an installation mechanism; the mounting mechanism is a verticality detection device, and a sliding mechanism is mounted on the mounting mechanism; the sliding mechanism is provided with a sliding piece which is arranged in a sliding groove on the mounting mechanism; the left side in the sliding mechanism is provided with the moving mechanism; the measuring mechanism is arranged on the left side of the moving mechanism; the bottom of the mounting mechanism is provided with a supporting mechanism; the side edge of the supporting mechanism is provided with a balancing mechanism, and the balancing mechanism is arranged in the mounting mechanism; the balance mechanism includes: the rotary part is of a cylindrical structure, threads are arranged on the rotary part, gears are arranged on two sides of the rotary part, the rotary part is meshed with the clamping teeth on the tooth rows through the gears on the two sides, an auxiliary part is arranged in the middle of the rotary part, and the rotary part is positioned in the installation groove; the balancing piece, the balancing piece is the rectangle structure, and the balancing piece side is equipped with the rectangle arch, is equipped with the screw hole on the balancing piece, and the balancing piece passes through the rectangle arch and installs inside the adjustment tank to screw hole internally mounted on the balancing piece has the rotating member.

Further, the mounting mechanism includes: the main body is of a rectangular structure, and a round hole is formed in the bottom of the main body; the spout, the spout is T shape structure, and the spout is seted up on the inside top of main part.

Further, the mounting mechanism further comprises: the bottom piece is of a rectangular structure and is arranged at the bottom of the main body; the adjusting tank is of a rectangular structure and is arranged on the left side inside the main body. Further, the mounting mechanism further comprises: the mounting groove is of a rectangular structure and is formed in the bottom end inside the main body; the auxiliary member, the auxiliary member is the rectangle structure, is equipped with the round hole on the auxiliary member, and the auxiliary member is installed in the inside bottom of mounting groove.

Further, the slide mechanism includes: the sliding part is of a rectangular structure, a T-shaped bulge is arranged at the bottom of the sliding part, a handle is arranged on the sliding part, and the sliding part is arranged in the sliding groove through the T-shaped bulge at the bottom; the moving groove is of a rectangular structure and is formed in the side edge inside the sliding piece.

Further, the sliding mechanism further includes: the control piece is of a cylindrical structure, a gear is arranged on the control piece, and the control piece is arranged in the moving groove; the auxiliary groove is of a rectangular structure and is formed in two sides of the inner portion of the sliding piece. Further, the moving mechanism includes: the moving piece is of a U-shaped structure, a rectangular bulge is arranged on the moving piece, the right side of the moving piece is provided with a latch, the moving piece is arranged inside the moving groove and is arranged inside the auxiliary groove through the rectangular bulge, and the moving piece is meshed with the control piece through the latch on the right side; the inner groove is of a rectangular structure and is formed in the moving piece; the sliding rod is of a cylindrical structure, a spring is sleeved on the sliding rod, and the sliding rod is installed inside the inner groove.

Further, the measuring mechanism includes: the connecting piece is of a rectangular structure, a round hole is formed in the connecting piece, the connecting piece is installed inside the inner groove, and a sliding rod is installed inside the round hole in the connecting piece; the measuring piece is of a rectangular structure, wedge-shaped protrusions are arranged on the upper portion and the lower portion of the measuring piece, and the measuring piece is connected with the connecting piece through a connecting rod. Further, the support mechanism includes: the supporting piece is of a cylindrical structure, the bottom of the supporting piece is of a round table-shaped structure, and the supporting piece is arranged in a round hole in the main body; the tooth row is of a rectangular structure, rectangular bulges are arranged on two sides of the tooth row, the tooth row is arranged at the top of the supporting piece, and the tooth row is positioned in the mounting groove; the locating part, the locating part is the bellied cylindrical structure in top, and the locating part bottom cover is equipped with the spring, and the locating part is installed in the inside bottom of mounting groove to the locating part is installed inside the round hole on the tooth row.

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

1. in the device, a sliding part and a moving part are arranged, wherein the sliding part is arranged inside a sliding groove through a T-shaped bulge at the bottom, and the moving part is meshed with a gear on a control part through a latch at the right side, so that when in use, wedge-shaped bulges at the upper side and the lower side of the measuring part are inserted into a wall gap through being contacted with a wall, a connecting part is enabled to move inside an inner groove while compressing a spring on a sliding rod, and the verticality of the measuring part is further ensured, the sliding part is enabled to move inside the sliding groove through the T-shaped bulge at the bottom by pushing a handle on the sliding part, so that the wall is measured, when walls with different heights are measured, the connecting part is enabled to compress the spring on the sliding rod through pressing the measuring part, and the gear on the control part is meshed with the latch on the moving part through rotating the control part, so that the moving part moves up and down inside the moving groove, and the auxiliary groove here can play supplementary fixed effect to the moving member, loosens the measuring part here this moment, and the wedge on the measuring part is protruding to be inserted inside the crack, and then fixes the measurement straightness that hangs down to the wall of co-altitude not.

2. In the device, a supporting piece and an adjusting piece are arranged, wherein the supporting piece is arranged in a round hole at the bottom of a main body, the adjusting piece is meshed with clamping teeth on a tooth row through gears at two sides, when the body is installed on the uneven ground, the supporting member and the bottom member are brought into contact with the ground by placing the body on the ground, due to the action of the balance block and the bottom piece, the supporting piece contacted with the ground moves upwards to jack up the tooth row and stretch the spring on the limiting piece, so that the tooth row is meshed with the gear on the rotating piece, so that the balance weight moves to the side which is not contacted with the ground, and the tooth row at the side which is not contacted with the ground is meshed with the gear, and then compress the spring on the locating part when moving downwards with support piece for support piece and ground contact, and then make the main part keep the level, make to measure more accurately.

Drawings

Fig. 1 is a schematic front perspective view of the present invention.

Fig. 2 is a schematic bottom perspective view of the present invention.

Fig. 3 is a schematic view of a partially exploded perspective structure of the present invention.

Fig. 4 is a rear view partially exploded perspective view of the present invention.

Fig. 5 is a schematic view of a main body vertical cut perspective structure of the present invention.

Fig. 6 is a schematic cross-sectional perspective view of the main body of the present invention.

Fig. 7 is an exploded perspective view of the movement mechanism and the measurement mechanism of the present invention.

Fig. 8 is a schematic diagram of a part a enlarged structure of the present invention, which is drawn from fig. 4.

Fig. 9 is a schematic diagram of a part B enlarged from fig. 4 according to the present invention.

Fig. 10 is a schematic diagram of the enlarged structure of part C from fig. 5.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. an installation mechanism; 101. a main body; 102. a chute; 103. a bottom piece; 104. an adjustment groove; 105. mounting grooves; 106. an auxiliary member; 2. a sliding mechanism; 201. a slider; 202. a moving groove; 203. a control member; 204. an auxiliary groove; 3. a moving mechanism; 301. a moving member; 302. an inner tank; 303. a slide bar; 4. a measuring mechanism; 401. a connecting member; 402. a measuring member; 5. a support mechanism; 501. a support member; 502. a tooth row; 503. a limiting member; 6. a balancing mechanism; 601. a rotating member; 602. a balance weight.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The first embodiment is as follows:

as shown in figures 1 to 10:

the invention provides a portable verticality detection device based on constructional engineering, which comprises an installation mechanism 1; the mounting mechanism 1 is a verticality detection device, and a sliding mechanism 2 is mounted on the mounting mechanism 1; a sliding mechanism 2, wherein a sliding piece 201 on the sliding mechanism 2 is arranged in a sliding groove 102 on the mounting mechanism 1; the moving mechanism 3 is arranged on the left side inside the sliding mechanism 2; the measuring mechanism 4 is arranged on the left side of the moving mechanism 3; the supporting mechanism 5 is arranged at the bottom of the mounting mechanism 1; the side edges of the balance mechanism 6 and the supporting mechanism 5 are provided with the balance mechanism 6, and the balance mechanism 6 is arranged in the installation mechanism 1.

As shown in fig. 5 to 6, the mounting mechanism 1 includes: the main body 101 is of a rectangular structure, and a round hole is formed in the bottom of the main body 101; the main body 101 is used for opening the sliding groove 102, so that the sliding part 201 can move in the sliding groove 102, and the whole perpendicularity of the wall can be measured; the sliding chute 102 is of a T-shaped structure, and the sliding chute 102 is arranged at the top end inside the main body 101; the chute 102 is here used for mounting the slider 201; the bottom piece 103, the bottom piece 103 is a rectangular structure, and the bottom piece 103 is arranged at the bottom of the main body 101; the bottom piece 103 is arranged at the middle position of the bottom of the main body 101 so as to ensure the stability of the main body 101; the adjusting groove 104 is of a rectangular structure, and the adjusting groove 104 is formed in the left side inside the main body 101; the adjusting groove 104 is used for embedding a rectangular protrusion on the balance weight 602; the mounting groove 105 is of a rectangular structure, and the mounting groove 105 is formed in the bottom end of the interior of the main body 101; and the mounting groove 105 is used for mounting the supporting mechanism 5 and the balancing mechanism 6; the auxiliary piece 106 is of a rectangular structure, a round hole is formed in the auxiliary piece 106, and the auxiliary piece 106 is installed at the bottom end inside the installation groove 105; and the auxiliary member 106 is used to assist in fixing the rotating member 601.

As shown in fig. 3, the slide mechanism 2 includes: the sliding part 201 is of a rectangular structure, a T-shaped bulge is arranged at the bottom of the sliding part 201, a handle is arranged on the sliding part 201, and the sliding part 201 is installed inside the sliding groove 102 through the T-shaped bulge at the bottom; the sliding piece 201 is used for pushing the handle, so that the sliding piece 201 moves inside the sliding groove 102 through the T-shaped bulge at the bottom, and the sliding piece 201 can play a role of being convenient to carry through the arranged handle; the moving groove 202, the moving groove 202 is a rectangular structure, and the moving groove 202 is arranged on the inner side of the sliding part 201; the moving groove 202 is used for installing the moving part 301; the control piece 203, the control piece 203 is a cylindrical structure, a gear is installed on the control piece 203, and the control piece 203 is installed inside the moving groove 202; the control member 203 is used for engaging with the latch on the moving member 301, so that the moving member 301 moves in the moving groove 202; the auxiliary groove 204, the auxiliary groove 204 is a rectangular structure, and the auxiliary groove 204 is arranged on two sides inside the sliding part 201; the auxiliary groove 204 is used for installing a rectangular protrusion on the moving member 301 in a sliding manner, thereby assisting the moving member 301 in fixing.

As shown in fig. 7, the moving mechanism 3 includes: the moving member 301 is of a U-shaped structure, a rectangular protrusion is arranged on the moving member 301, the right side of the moving member 301 is provided with a latch, the moving member 301 is installed inside the moving groove 202, the moving member 301 is installed inside the auxiliary groove 204 through the rectangular protrusion, and the moving member 301 is meshed with the control member 203 through the latch on the right side; the moving member 301 is engaged with the gear on the control member 203 through the latch, so that the moving member 301 moves up and down in the moving groove 202, and the wall bodies with different heights are measured; an inner groove 302, wherein the inner groove 302 is of a rectangular structure, and the inner groove 302 is arranged inside the moving part 301; here, the inner groove 302 is used for mounting the sliding rod 303 and the sliding mounting connector 401; a sliding rod 303, the sliding rod 303 is a cylindrical structure, a spring is sleeved on the sliding rod 303, and the sliding rod 303 is installed inside the inner groove 302; and the sliding rod 303 is used to assist the fixing of the connecting member 401 installed inside the inner groove 302.

As shown in fig. 1, the measuring mechanism 4 includes: the connecting piece 401 is of a rectangular structure, a round hole is formed in the connecting piece 401, the connecting piece 401 is installed inside the inner groove 302, and a sliding rod 303 is installed inside the round hole in the connecting piece 401; here, the connecting member 401 is used to connect the moving member 301 and the measuring member 402; the measuring part 402 is of a rectangular structure, wedge-shaped protrusions are arranged on the upper portion and the lower portion of the measuring part 402, and the measuring part 402 is connected with the connecting piece 401 through a connecting rod; the measuring member 402 is used to compress the spring of the sliding rod 303 while the connecting member 401 moves inside the inner groove 302 by pressing, so that the wedge-shaped protrusion is inserted into the wall gap.

Example two:

as shown in fig. 1, the control member 203 may be added with a control switch, the control switch controls the moving member 301 to move inside the moving slot 202, and the T-shaped protrusion at the bottom of the sliding member 201 may be replaced by a pulley, which may make the sliding member 201 move more smoothly inside the sliding slot 102, and make the movement smoother inside the sliding slot 102.

Example three:

as shown in fig. 6, the support mechanism 5 includes: the supporting piece 501 is of a cylindrical structure, the bottom of the supporting piece 501 is of a truncated cone-shaped structure, and the supporting piece 501 is installed inside a circular hole in the main body 101; the support 501 is used for stably supporting the main body 101, and the bottom of the support is a truncated cone-shaped structure, so that the contact area with the ground can be increased; the tooth row 502 is of a rectangular structure, rectangular protrusions are arranged on two sides of the tooth row 502, the tooth row 502 is installed at the top of the support 501, and the tooth row 502 is located inside the installation groove 105; the gear row 502 is used for meshing with a gear on the rotating piece 601 through the action of the supporting piece 501, so that the supporting pieces 501 on two sides are contacted with the ground, and a better supporting effect is achieved; the limiting piece 503 is a cylindrical structure with a convex top, a spring is sleeved at the bottom of the limiting piece 503, the limiting piece 503 is installed at the bottom end inside the installation groove 105, and the limiting piece 503 is installed inside a circular hole on the gear row 502; here, the stopper 503 is used to limit the distance that the support 501 and the rack 502 move up and down.

As shown in fig. 6, the balance mechanism 6 includes: the rotating piece 601 is of a cylindrical structure, threads are arranged on the rotating piece 601, gears are arranged on two sides of the rotating piece 601, the rotating piece 601 is meshed with the clamping teeth on the tooth row 502 through the gears on the two sides, the auxiliary piece 106 is arranged in the middle of the rotating piece 601, and the rotating piece 601 is located inside the installation groove 105; the rotating member 601 is used for rotating to enable the balance weight 602 to move inside the adjusting groove 104, thereby playing a better role in stabilizing the main body 101; the balance block 602 is of a rectangular structure, a rectangular protrusion is arranged on the side edge of the balance block 602, a threaded hole is formed in the balance block 602, the balance block 602 is installed inside the adjusting groove 104 through the rectangular protrusion, and the rotating piece 601 is installed inside the threaded hole in the balance block 602; the weight 602 is used to move inside the adjustment groove 104, and thus balance the main body 101.

Example four:

as shown in fig. 6, the auxiliary member 106 can be connected to the main body 101 through a screw thread, so as to better assist and fix the rotating member 601, and the spring sleeved on the limiting member 503 can be replaced by an elastic member made of rubber, so that the compression reset is more sensitive and the practicability is stronger.

When in use: when the device is used, when the main body 101 is installed on uneven ground, the supporting member 501 and the bottom member 103 are in contact with the ground, due to the action of the balance block 602 and the bottom member 103, the supporting member 501 in contact with the ground is moved upwards to jack up the rack 502, and the spring on the limiting member 503 is stretched, so that the rack 502 is engaged with the gear on the rotating member 601, and further the balance block 602 is moved to the side not in contact with the ground, and simultaneously the rack 502 on the side not in contact with the ground is engaged with the gear, and further the spring on the limiting member 503 is compressed while the supporting member 501 is moved downwards, so that the supporting member 501 is in contact with the ground, and further the main body 101 is kept horizontal, so that the measurement is more accurate, when measuring, by pressing the measuring member 402, the measuring member 402 is made to compress the spring on the sliding rod 303 through the connecting member 401, and is inserted into the wall gap through the wedge-shaped protrusions on the upper and lower sides, and then the verticality of the measuring piece 402 is ensured, the sliding piece 201 moves inside the sliding groove 102 through the T-shaped bulge at the bottom by pushing the handle on the sliding piece 201, and then the wall is measured, when the walls with different heights are measured, the spring on the sliding rod 303 is compressed by the connecting piece 401 by pressing the measuring piece 402, the control piece 203 is rotated, the gear on the control piece 203 is meshed with the latch on the moving piece 301, the moving piece 301 moves up and down in the moving groove 202, the measuring piece 402 is loosened at the moment, the wedge-shaped bulge on the measuring piece 402 is inserted into the wall gap, and then the verticality of the walls with different heights is fixedly measured.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (9)

1. Hang down straightness detection device based on portable for building engineering, its characterized in that: comprises a mounting mechanism (1); the mounting mechanism (1) is a verticality detection device, and the mounting mechanism (1) is provided with a sliding mechanism (2); the sliding mechanism (2), a sliding piece (201) on the sliding mechanism (2) is installed in a sliding groove (102) on the installation mechanism (1); the moving mechanism (3) is installed on the left side inside the sliding mechanism (2); the measuring mechanism (4) is installed on the left side of the moving mechanism (3); the supporting mechanism (5) is arranged at the bottom of the mounting mechanism (1); balance mechanism (6), balance mechanism (6) are installed to supporting mechanism (5) side, and balance mechanism (6) install inside installation mechanism (1), and balance mechanism (6) include: the rotary piece (601), the rotary piece (601) is a cylindrical structure, threads are arranged on the rotary piece (601), gears are installed on two sides of the rotary piece (601), the rotary piece (601) is meshed with the clamping teeth on the gear row (502) through the gears on the two sides, the auxiliary piece (106) is installed in the middle of the rotary piece (601), and the rotary piece (601) is located inside the installation groove (105); balance weight (602), balance weight (602) are the rectangle structure, and balance weight (602) side is equipped with the rectangle arch, is equipped with the screw hole on balance weight (602), and balance weight (602) are installed inside adjustment tank (104) through the rectangle arch to screw hole internally mounted on balance weight (602) has rotating member (601).

2. The portable verticality detection device for construction engineering based on claim 1, wherein: the mounting mechanism (1) comprises: the main body (101), the main body (101) is a rectangular structure, and the bottom of the main body (101) is provided with a round hole; the sliding chute (102), the sliding chute (102) is T-shaped structure, and the sliding chute (102) is arranged at the top end of the inner part of the main body (101).

3. The portable verticality detection device for construction engineering based on claim 2, wherein: the mounting mechanism (1) further comprises: the bottom piece (103), the bottom piece (103) is of a rectangular structure, and the bottom piece (103) is installed at the bottom of the main body (101); the adjusting groove (104), adjusting groove (104) are the rectangle structure, and adjusting groove (104) set up in main part (101) inside left side.

4. The portable verticality detection device for construction engineering based on claim 2, wherein: the mounting mechanism (1) further comprises: the mounting groove (105), the mounting groove (105) is of a rectangular structure, and the mounting groove (105) is formed in the bottom end of the interior of the main body (101); auxiliary member (106), auxiliary member (106) are the rectangle structure, are equipped with the round hole on auxiliary member (106), and auxiliary member (106) are installed in the inside bottom of mounting groove (105).

5. The portable verticality detection device for construction engineering based on claim 1, wherein: the slide mechanism (2) includes: the sliding piece (201), the sliding piece (201) is of a rectangular structure, a T-shaped bulge is arranged at the bottom of the sliding piece (201), a handle is arranged on the sliding piece (201), and the sliding piece (201) is installed inside the sliding groove (102) through the T-shaped bulge at the bottom; the moving groove (202), the moving groove (202) is rectangular structure, and the moving groove (202) is arranged on the inner side of the sliding part (201).

6. The portable verticality detection device for construction engineering based on claim 5, wherein: the sliding mechanism (2) further comprises: the control piece (203), the control piece (203) is a cylindrical structure, a gear is installed on the control piece (203), and the control piece (203) is installed inside the moving groove (202); the auxiliary groove (204), the auxiliary groove (204) is rectangular, and the auxiliary groove (204) is arranged on two sides of the inside of the sliding piece (201).

7. The portable verticality detection device for construction engineering based on claim 1, wherein: the moving mechanism (3) includes: the moving piece (301) is of a U-shaped structure, a rectangular protrusion is arranged on the moving piece (301), a latch is arranged on the right side of the moving piece (301), the moving piece (301) is installed inside the moving groove (202), the moving piece (301) is installed inside the auxiliary groove (204) through the rectangular protrusion, and the moving piece (301) is meshed with the control piece (203) through the latch on the right side; the inner groove (302), the inner groove (302) is a rectangular structure, and the inner groove (302) is arranged in the moving part (301);

the sliding rod (303), sliding rod (303) are cylindrical structure, the cover is equipped with the spring on sliding rod (303), and sliding rod (303) are installed in inside groove (302).

8. The portable verticality detection device for construction engineering based on claim 1, wherein: the measuring mechanism (4) comprises: the connecting piece (401), the connecting piece (401) is of a rectangular structure, round holes are formed in the connecting piece (401), the connecting piece (401) is installed inside the inner groove (302), and a sliding rod (303) is installed inside the round hole in the connecting piece (401); the measuring piece (402) is of a rectangular structure, wedge-shaped protrusions are arranged on the upper portion and the lower portion of the measuring piece (402), and the measuring piece (402) is connected with the connecting piece (401) through a connecting rod.

9. The portable verticality detection device for construction engineering based on claim 1, wherein: the support mechanism (5) includes: the supporting piece (501) is of a cylindrical structure, the bottom of the supporting piece (501) is of a circular truncated cone-shaped structure, and the supporting piece (501) is installed inside a circular hole in the main body (101); the tooth row (502) is of a rectangular structure, rectangular protrusions are arranged on two sides of the tooth row (502), the tooth row (502) is installed on the top of the support (501), and the tooth row (502) is located inside the installation groove (105); the limiting piece (503) is of a cylindrical structure with a convex top, the bottom of the limiting piece (503) is sleeved with a spring, the limiting piece (503) is installed at the bottom end inside the installation groove (105), and the limiting piece (503) is installed inside a round hole in the gear row (502).

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