CN215064461U

CN215064461U - Flatness detection device for building engineering

Info

Publication number: CN215064461U
Application number: CN202121243541.9U
Authority: CN
Inventors: 邓赣东
Original assignee: Dongce Testing Technology Jilin Province Co ltd
Current assignee: Dongce Testing Technology Jilin Province Co ltd
Priority date: 2021-06-04
Filing date: 2021-06-04
Publication date: 2021-12-07
Anticipated expiration: 2031-06-04

Abstract

The utility model relates to a detection device especially relates to a roughness detection device for building engineering. The technical problem is as follows: the flatness detection device for the building engineering is accurate in measurement, low in manufacturing cost, convenient to carry, economical and applicable. A flatness detection device for constructional engineering comprises wheels, a support frame, a shell, a first movable rod, a clamping rod, a push handle and the like; the equal rotary type in support frame left and right sides is connected with the wheel, and the support frame upside is connected with the shell, and shell upside slidingtype is connected with first movable rod, and the shell left side is connected with the kelly, and the shell rear side is connected with and pushes away the handle. Push away the handle through promoting for it drives the wheel rotation to push away the handle, and the second movable rod slides backward when contacting through dysmorphism piece and wall, makes slewing mechanism rotate forward, and the side material goes out the wall and whether levels.

Description

Flatness detection device for building engineering

Technical Field

The utility model relates to a detection device especially relates to a roughness detection device for building engineering.

Background

In the building engineering detection work, the wall surface flatness is always used as a part of the detection engineering quality, so the wall surface flatness is often used as a part of the detection work. The leveling instrument is a measuring instrument which utilizes the principle of liquid level to directly display angular displacement by a level bubble and measure the deviation degree of the measured surface relative to the horizontal position, the vertical position and the inclined position.

The utility model relates to a roughness detection device for building engineering measures accurately, and the cost is low, convenient to carry, economy is suitable for. The short-distance measurement of the existing level ruler cannot be carried out remotely, the short-distance measurement can be carried out remotely, the measurement on narrow ground cannot be carried out remotely, the measurement is very inconvenient, and the measurement of the flatness at the corner of the ground is very inconvenient.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of inaccurate measurement and inconvenient carrying, the technical problems are as follows: the flatness detection device for the building engineering is accurate in measurement, low in manufacturing cost, convenient to carry, economical and applicable.

The technical scheme of the utility model is that: the utility model provides a roughness detection device for building engineering, including the wheel, the support frame, and a housing, first movable rod, the kelly, push away the handle, the dead lever, dysmorphism piece, the second movable rod, first spring, slewing mechanism and deposit the mechanism, the equal rotary type in support frame left and right sides is connected with two wheels, the support frame upside is connected with the shell, shell upside slidingtype is connected with first movable rod, the shell left side is connected with the kelly, the shell rear side is connected with and pushes away the handle, first movable rod front side internal connection has the dead lever, be connected with dysmorphism piece on the dead lever, first movable rod front side is connected with slewing mechanism, slidingtype is connected with the second movable rod between slewing mechanism front side and the dysmorphism piece inboard, be connected with first spring between slewing mechanism front side and the dysmorphism piece upside, first movable rod left side is connected with deposits the mechanism.

Preferably, slewing mechanism is including the support column, the pilot lamp, the torsional spring, first wedge, the second spring, second wedge and third spring, first movable rod upside is connected with the support column, the rotary type is connected with the pilot lamp in the middle of the support column, be connected with the torsional spring between support column and the pilot lamp, the dynamic formula that sideslips before the first movable rod is connected with first wedge, be connected with the second spring between first movable rod front side and the first wedge, the inboard upper portion of first movable rod is connected with the second wedge, second wedge downside and first movable rod upside are connected with the third spring.

Preferably, deposit the mechanism including deposit case, pull handle, fourth spring and fixed block, first movable rod left side sliding type is connected with deposits the case, deposits the case upside and is connected with the pull handle, deposits the case front and back both sides and all is connected with the fixed block, is connected with the fourth spring between fixed block right side and the first movable rod left side.

Preferably, the first movable bar is cylindrical.

Preferably, the first spring is a return spring.

Preferably, the pull handle is made of stainless steel.

The utility model has the advantages that: 1. the push handle is pushed to drive the wheels to rotate, and the second movable rod slides backwards when the special-shaped block is contacted with the wall, so that the rotating mechanism rotates forwards, and the side material is discharged out of the wall to be flat or not, and the effect of measuring the building engineering such as the wall can be realized;

2. when the wall is contacted with the second movable rod, the second movable rod slides backwards and is contacted with the first wedge-shaped block, and then the first wedge-shaped block is contacted with the second wedge-shaped block, so that the second wedge-shaped block slides upwards and is contacted with the detection lamp, and the effect of measuring the building can be realized;

3 through the pulling pull handle for the pull handle drives and deposits the case and slide left, so can realize depositing the effect to article.

Drawings

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

Fig. 2 is a schematic view of the three-dimensional structure of the rotating mechanism of the present invention.

Fig. 3 is a schematic view of the three-dimensional structure of the storage mechanism of the present invention.

Description of reference numerals: 1_ wheel, 2_ support frame, 3_ shell, 4_ first movable rod, 5_ clamping rod, 6_ push handle, 7_ fixed rod, 8_ special-shaped block, 9_ second movable rod, 10_ first spring, 11_ rotating mechanism, 111_ support column, 112_ detection lamp, 113_ torsion spring, 114_ first wedge-shaped block, 115_ second spring, 116_ second wedge-shaped block, 117_ third spring, 12_ storage mechanism, 121_ storage box, 122_ pull handle, 123_ fourth spring and 124_ fixed block.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the following detailed description.

Example 1

A flatness detecting device for building engineering, as shown in figures 1-3, comprises wheels 1, a support frame 2, a housing 3, a first movable rod 4, a clamping rod 5, a push handle 6, a fixed rod 7, a special-shaped block 8, a second movable rod 9, a first spring 10, a rotating mechanism 11 and a storage mechanism 12, wherein the left side and the right side of the support frame 2 are rotatably connected with the two wheels 1, the upper side of the support frame 2 is connected with the housing 3, the upper side of the housing 3 is slidably connected with the first movable rod 4, the left side of the housing 3 is connected with the clamping rod 5, the rear side of the housing 3 is connected with the push handle 6, the fixed rod 7 is connected with the front side of the first movable rod 4, the special-shaped block 8 is connected with the fixed rod 7, the front side of the first movable rod 4 is connected with the rotating mechanism 11, the second movable rod 9 is connected between the front side of the rotating mechanism 11 and the inner side of the special-shaped block 8, the first spring 10 is connected between the front side of the rotating mechanism 11 and the upper side of the special-shaped block 8, the left side of the first movable rod 4 is connected with a storage mechanism 12.

When the device needs to be used, a user can push the push handle 6 to enable the push handle 6 to drive the wheel 1 to slide forwards, then enable the wheel 1 to drive the detection device to slide forwards, then push the detection device to a position needing to be detected, when the special-shaped block 8 is in contact with the wall, the second movable rod 9 is extruded through the wall, the second movable rod 9 is enabled to slide backwards, then the user can pull the clamping rod 5 to enable the clamping rod 5 to be not in contact with the first movable rod 4, then the user can pull the first movable rod 4 upwards to enable the first movable rod 4 to slide upwards to a height which the user wants, then the user can push the clamping rod 5 again to enable the clamping rod 5 to clamp the first movable rod 4, the special-shaped block 8 is in contact with the wall, and the device drives the second movable rod 9 to slide, if the wall surface is provided with a bulge, the second movable rod 9 can be extruded, at this moment, the first spring 10 is compressed, so that the rotating mechanism 11 moves, and a certain prompt is given to people, after the measurement is finished, a user can push the wheel 1 again, so that the wheel 1 drives the equipment to slide backwards, then, when the special-shaped block 8 is not in contact with the wall, under the reset action of the first spring 10, the second movable rod 9 is reset, then, the special-shaped block 8 is not in contact with the rotating mechanism 11, so that the rotating mechanism 11 recovers the original position, when the object needs to be stored, the user can pull the storing mechanism 12, so that the storing mechanism 12 slides forwards, then, the user can place the object in the storing mechanism 12, then, the storing mechanism 12 is pushed again, so that the effect of measuring the building engineering such as the wall can be realized.

The rotating mechanism 11 comprises a supporting column 111, a detection lamp 112, a torsion spring 113, a first wedge-shaped block 114, a second spring 115, a second wedge-shaped block 116 and a third spring 117, the supporting column 111 is connected to the upper side of the first movable rod 4, the detection lamp 112 is rotatably connected to the middle of the supporting column 111, the torsion spring 113 is connected between the supporting column 111 and the detection lamp 112, the first wedge-shaped block 114 is movably connected to the front side of the first movable rod 4, the second spring 115 is connected between the front side of the first movable rod 4 and the first wedge-shaped block 114, the second wedge-shaped block 116 is connected to the upper portion of the inner side of the first movable rod 4, and the third spring 117 is connected to the lower side of the second wedge-shaped block 116 and the upper side of the first movable rod 4.

When the special-shaped block 8 is contacted with the wall, the second movable rod 9 is pressed by the protruded wall, so that the second movable rod 9 slides backwards and is contacted with the first wedge-shaped block 114, then the first wedge-shaped block 114 slides backwards and is contacted with the second wedge-shaped block 116, at this time, the second spring 115 is compressed, then the second wedge-shaped block 116 slides upwards to be contacted with the detection lamp 112, at this time, the third spring 117 is stretched, so that the detection lamp 112 rotates, and the user is prompted, at this time, the torsion spring 113 is deformed, after the measurement is finished, the user can push the wheel 1 again, so that the special-shaped block 8 is not contacted with the wall, so that the second movable rod 9 resets forwards, then the first wedge-shaped block 114 slides forwards to reset under the resetting action of the second spring 115, and then the second wedge-shaped block 116 resets downwards under the resetting action of the third spring 117, the second wedge-shaped block 116 is no longer in contact with the detection lamp 112, and the detection lamp 112 is rotated backwards to be reset under the reset action of the torsion spring 113, so that the effect of measuring the building can be achieved.

Deposit mechanism 12 including depositing case 121, pull handle 122, fourth spring 123 and fixed block 124, first movable rod 4 left side sliding connection has deposits case 121, deposits case 121 upside and is connected with pull handle 122, deposits case 121 front and back both sides and all is connected with fixed block 124, is connected with fourth spring 123 between fixed block 124 right side and the first movable rod 4 left side.

When the user needs to deposit an article, the pull handle 122 can be pulled, so that the pull handle 122 drives the storage box 121 to slide leftwards, then the storage box 121 drives the fixing block 124 to slide leftwards, the fourth spring 123 is stretched at the moment, then the user places the article in the storage box 121, when the user does not apply force to the pull handle 122 any more, under the resetting action of the third spring 117, the storage box 121 slides rightwards to reset, and thus the effect of storing the article can be realized.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and variations can be made in the embodiments or in part of the technical features of the embodiments without departing from the spirit and the scope of the invention.

Claims

1. The utility model provides a roughness detection device for building engineering which characterized in that: comprises wheels (1), a support frame (2), a shell (3), a first movable rod (4), a clamping rod (5), a push handle (6), a fixed rod (7), a special-shaped block (8), a second movable rod (9), a first spring (10), a rotating mechanism (11) and a storage mechanism (12), wherein the left side and the right side of the support frame (2) are rotatably connected with the two wheels (1), the upper side of the support frame (2) is connected with the shell (3), the upper side of the shell (3) is slidably connected with the first movable rod (4), the left side of the shell (3) is connected with the clamping rod (5), the rear side of the shell (3) is connected with the push handle (6), the fixed rod (7) is connected inside the front side of the first movable rod (4), the special-shaped block (8) is connected on the fixed rod (7), the rotating mechanism (11) is connected with the front side of the first movable rod (4), the second movable rod (9) is slidably connected between the front side of the rotating mechanism (11) and the inner side of the special-shaped block (8), a first spring (10) is connected between the front side of the rotating mechanism (11) and the upper side of the special-shaped block (8), and a storage mechanism (12) is connected to the left side of the first movable rod (4).

2. The flatness detecting apparatus for construction engineering according to claim 1, wherein: slewing mechanism (11) is including support column (111), pilot lamp (112), torsional spring (113), first wedge (114), second spring (115), second wedge (116) and third spring (117), first movable rod (4) upside is connected with support column (111), rotary type is connected with pilot lamp (112) in the middle of support column (111), be connected with torsional spring (113) between support column (111) and pilot lamp (112), first movable rod (4) preceding side sliding type is connected with first wedge (114), be connected with second spring (115) between first movable rod (4) front side and first wedge (114), first movable rod (4) inboard upper portion is connected with second wedge (116), second wedge (116) downside and first movable rod (4) upside are connected with third spring (117).

3. The flatness detecting apparatus for construction engineering according to claim 2, wherein: deposit mechanism (12) including depositing case (121), pull handle (122), fourth spring (123) and fixed block (124), first movable rod (4) left side sliding type is connected with deposits case (121), deposits case (121) upside and is connected with pull handle (122), deposits case (121) front and back both sides and all is connected with fixed block (124), is connected with fourth spring (123) between fixed block (124) right side and first movable rod (4) left side.

4. The flatness detecting apparatus for construction engineering according to claim 1, wherein: the first movable rod (4) is cylindrical.

5. The flatness detecting apparatus for construction engineering according to claim 1, wherein: the first spring (10) is a return spring.

6. The flatness detecting apparatus for construction engineering according to claim 3, wherein: the pull handle (122) is made of stainless steel.