CN220625222U - Building material thickness measuring mechanism for constructional engineering - Google Patents

Abstract

The utility model relates to the technical field of building material thickness measurement, in particular to a building material thickness measurement mechanism for building engineering, which comprises a machine body, wherein a display screen is arranged above the front end surface of the machine body, a button is arranged below the front end surface of the machine body, a connecting wire is fixedly connected in the middle of the upper end surface of the machine body, a detection head is fixedly connected to the top end of the connecting wire, a pressing head is slidingly connected to the upper side of the inner side of the detection head, a left sliding block is slidingly connected to the left sliding block in the detection head, a right sliding block is slidingly connected to the right sliding block in the detection head, compression springs are fixedly connected to the lower end surfaces of the left sliding block and the right sliding block, and a left extending plate is fixedly connected to the left end surface of the left sliding block; through the design cooperation for the device can be before pressing the head and pressing and detecting building material, clear up dust and debris on building material surface in advance, not only prevent to detect the head and carry out the acoustic wave to building material when detecting, dust and debris increase the error of final data.

Description

Building material thickness measuring mechanism for constructional engineering

Technical Field

The utility model relates to the technical field of building material thickness measurement, in particular to a building material thickness measurement mechanism for building engineering.

Background

Building materials are necessary materials for building, and most of building materials are plate-shaped, and thickness detection is carried out on the building materials by a thickness meter to judge whether the building materials reach the installation standard.

The patent specification with the bulletin number of CN218628227U discloses a building material thickness measuring mechanism for constructional engineering, which comprises a metal thickness measuring instrument main body, a circular fixing plate and a circular movable plate, wherein the upper end of the metal thickness measuring instrument main body is provided with a detection line, the other end of the detection line is provided with a detection head, the circular fixing plate is longitudinally fixed at the right end of the metal thickness measuring instrument main body, four sponge clamping grooves are formed in the right end of the metal thickness measuring instrument main body according to the specification, fixed sponges are clamped in the sponge clamping grooves, a miniature ball bearing groove is formed in the middle of the right end of the circular fixing plate, a miniature ball bearing is fixed in the miniature ball bearing groove, and a connecting shaft is fixed in an inner ring of the miniature ball bearing.

However, in the implementation of the related art, it has been found that the above-mentioned building material thickness measuring mechanism for construction works has the following problems: the structure is characterized in that the top end of the detection head is used for automatically smearing the couplant, but when the couplant is used, dust existing on the surface of an object to be detected is required to be cleaned, so that a large error can occur in the result of the thickness gauge, meanwhile, the dust is contacted with the couplant, pollution of the couplant can be caused, the subsequent detection effect is influenced, and in view of the fact, the thickness measuring mechanism for the building material for the building engineering is provided to overcome the defects.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a building material thickness measuring mechanism for building engineering.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides a building material thickness measuring mechanism for building engineering, includes the organism, terminal surface top is provided with the display screen before the organism, terminal surface below is provided with the button before the organism, fixedly connected with connecting wire in the middle of the organism up end, connecting wire top fixedly connected with detects the head, detect the inboard top sliding connection of head, detect the inside left side and slide and be connected with left sliding block, detect the inside right side and slide and be connected with right sliding block, terminal surface all fixedly connected with compression spring under left sliding block and the right sliding block, left sliding block left end face fixedly connected with left extension board, right sliding block right side terminal surface fixedly connected with right extension board, the hole has been seted up in the middle of left extension board and the right extension board is inside, the inside intermediate rotation connection of left extension board and right extension board has the revolving board, terminal surface fixedly connected with bottom plate down the inside left sliding block, terminal surface fixedly connected with right sliding block under the inside right sliding block, the terminal surface fixedly connected with motor under left extension board and the right extension board, the inside dust tank is connected with dust tank in the front of the inside dust tank of the dust tank of extension board, the dust tank is equipped with the dust tank in the inside the back end face of extension board.

As a further description of the above technical solution: compression spring bottom and the inside below left and right sides fixed connection of detecting head, left extension board right-hand member face and right extension board left end face all with detect head outside sliding connection, fixed connection in the middle of motor top output and the terminal surface under the bottom plate, terminal surface and left extension board and right extension board up end contact under the roof, terminal surface and left extension board and right extension board down the terminal surface contact under the bottom plate.

As a further description of the above technical solution: the number of the rotating plates, the top plates and the bottom plates is two, and the rotating plates, the top plates and the bottom plates are distributed in holes in the left extending plate and the right extending plate.

As a further description of the above technical solution: the aperture caliber in the middle of the left extending plate and the right extending plate is the same as the cross section diameter of the rotating plate, the cross section diameters of the top plate and the bottom plate are the same, and the cross section diameters of the top plate and the bottom plate are one five times larger than the cross section diameter of the rotating plate.

As a further description of the above technical solution: the sliding grooves are formed in the top ends of the left side and the right side of the detection head, the cross section of the sliding grooves in the top ends of the left side and the right side of the detection head is identical to that of the left sliding block and the right sliding block, and the cross section diameter of the compression spring is five millimeters shorter than the length of the left sliding block and the right sliding block from front to back.

As a further description of the above technical solution: the inner sides of the sliding grooves at the top ends of the left side and the right side of the detection head are provided with limiting rods, the outer sides of the limiting rods are in sliding connection with the middle part inside the left sliding block, the middle part inside the right sliding block and the middle part inside the compression spring, and the length of the limiting rods is identical to the height of the sliding grooves at the top ends of the left side and the right side of the detection head.

As a further description of the above technical solution: the total number of the dust baffle and the dust storage box is four, the dust baffle and the dust storage box are distributed on the front side of the left extending plate, the rear side of the left extending plate, the front side of the right extending plate and the rear side of the right extending plate, and the middle of the outer end face of the dust storage box is provided with an opening and closing door.

The utility model has the following beneficial effects:

according to the building material thickness measuring mechanism for the building engineering, through design matching, dust and sundries on the surface of a building material can be cleaned in advance before the pressing head presses the building material, so that errors of final data are increased when the sound wave detection is carried out on the building material by the detection head, meanwhile, a couplant is required to be smeared at the position of the pressing head, dust on the surface of the building material is not cleaned, the dust is directly contacted with the couplant, pollution can be caused at the top end of the pressing head, a subsequent detection result is influenced, meanwhile, the dust blocking plate and the dust storage box are arranged at the edge of the broom head, when the broom head cleans the dust, the dust is cleaned by adopting the rotary broom head, and therefore the dust is driven to rotate along with the broom head, and the rotating dust enters the dust storage box through the dust inlet groove of the dust blocking plate, so that the flying range of the dust during cleaning is effectively reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a top plate in a three-dimensional structure according to the present utility model;

FIG. 3 is a schematic side perspective view of a left extension plate of the present utility model;

fig. 4 is a schematic view showing a cross-sectional perspective structure of the dust box of the present utility model.

Legend description:

1. a body; 2. a display screen; 3. a button; 4. a connecting wire; 5. a detection head; 6. pressing head; 7. a left extension plate; 8. a top plate; 9. broom corn ear; 10. a motor; 11. a right extension plate; 12. a rotating plate; 13. a bottom plate; 14. a left slider; 15. a right slider; 16. a compression spring; 17. a dust-blocking plate; 18. a dust storage box; 19. a hole; 20. a dust inlet groove.

Description of the embodiments

Referring to fig. 1-4, the utility model provides a building material thickness measuring mechanism for constructional engineering, which comprises a machine body 1, a display screen 2 is arranged above the front end face of the machine body 1, a button 3 is arranged below the front end face of the machine body 1, a connecting wire 4 is fixedly connected in the middle of the upper end face of the machine body 1, a detecting head 5 is fixedly connected at the top end of the connecting wire 4, a pressing head 6 is slidingly connected above the inner side of the detecting head 5, a left sliding block 14 is slidingly connected at the left side inside the detecting head 5, a right sliding block 15 is slidingly connected at the right side inside the detecting head 5, compression springs 16 are fixedly connected at the lower end faces of the left sliding block 14 and the right sliding block 15, a left extending plate 7 is fixedly connected at the left end face of the left sliding block 14, a right extending plate 11 is fixedly connected at the right end face of the right sliding block 15, a hole 19 is arranged in the middle inside the left extending plate 7 and the right extending plate 11, a rotating plate 12 is rotationally connected in the middle inside the left extending plate 7 and the right extending plate 11, the upper end face of the rotating plate 12 is fixedly connected with the top plate 8, the upper end face of the top plate 8 is fixedly connected with the broom head 9, the lower end face of the rotating plate 12 is fixedly connected with the bottom plate 13, the lower end faces of the left extending plate 7 and the right extending plate 11 are fixedly connected with the motor 10, the front side and the rear side of the upper end faces of the left extending plate 7 and the right extending plate 11 are fixedly connected with the dust baffle 17, the dust inlet groove 20 is arranged in the middle of the inside of the dust baffle 17, the outer end face of the dust baffle 17 is fixedly connected with the dust storage box 18, the bottom end of the compression spring 16 is fixedly connected with the left side and the right side below the inner part of the detection head 5, the right end face of the left extending plate 7 and the left end face of the right extending plate 11 are both slidingly connected with the outer side of the detection head 5, the upper output end of the motor 10 is fixedly connected with the middle of the lower end face of the bottom plate 13, the lower end face of the top plate 8 is contacted with the upper end faces of the left extending plate 7 and the right extending plate 11, the upper end faces of the bottom plate 13 are contacted with the lower end faces of the left extending plate 7 and the right extending plate 11, dust and sundries on the surface of a building material are cleaned in advance, pollution of the couplant at the top end of the pressing head 6 is prevented, cleaned dust is stored in the dust storage box 18 through the dust inlet groove 20 of the dust baffle 17, and the dust is prevented from drifting in the air in a large area, so that the health of surrounding operators is influenced.

As a further embodiment of the above technical solution: the number of the rotating plates 12, the top plates 8 and the bottom plates 13 is two, the rotating plates 12, the top plates 8 and the bottom plates 13 are distributed inside the holes 19 inside the left extending plate 7 and the right extending plate 11, the diameters of the holes 19 in the middle of the left extending plate 7 and the right extending plate 11 are the same as the diameters of the cross sections of the rotating plates 12, the diameters of the cross sections of the top plates 8 and the bottom plates 13 are the same, the diameters of the cross sections of the top plates 8 and the bottom plates 13 are one half time larger than the diameters of the cross sections of the rotating plates 12, the motor 10 is convenient to drive the broom head 9 to rotate through the top plates 8, the rotating plates 12 and the bottom plates 13, and the inside of the left extending plate 7 and the right extending plate 11 is limited during rotation, so that the broom head 9 is prevented from being separated from the positioning of the left extending plate 7 and the right extending plate 11.

As a further embodiment of the above technical solution: the sliding grooves are formed in the top ends of the left side and the right side of the detection head 5, the cross section of the sliding grooves in the top ends of the left side and the right side of the detection head 5 is identical to that of the left sliding block 14 and the right sliding block 15, the cross section diameter of the compression spring 16 is five millimeters shorter than the length of the left sliding block 14 and the length of the right sliding block 15 from front to back, a limiting rod is arranged on the inner side of the sliding grooves in the top ends of the left side and the right side of the detection head 5, the outer side of the limiting rod is in sliding connection with the middle of the inner side of the left sliding block 14, the middle of the inner side of the right sliding block 15 and the middle of the inner side of the compression spring 16, the length of the limiting rod is identical to the height of the sliding grooves in the top ends of the left side and the right side of the detection head 5, the left extending plate 7 and the right extending plate 11 can be driven manually to lift up after the cleaning of a region to be detected by the broom head 9, the detection head 5 and the pressing head 6 are pressed on the surface of a building material, and the top end of the broom head 9 is prevented from affecting detection of the building material.

As a further embodiment of the above technical solution: the total number of the dust baffle 17 and the dust storage box 18 is four, and the dust baffle 17 and the dust storage box 18 are all distributed on the front side of the left extending plate 7, the rear side of the left extending plate 7, the front side of the right extending plate 11 and the rear side of the right extending plate 11, and the middle of the outer end surface of the dust storage box 18 is provided with an opening and closing door, so that dust cleaned by the broom head 9 is conveniently collected.

Working principle:

when the utility model is used, the machine body 1 is taken up, the detection head 5 is found along the connecting wire 4, then an operator manually plans a region of building materials to detect, then the motor 10 below the left extension plate 7 and the right extension plate 11 on the left side and the right side of the detection head 5 is opened, the motor 10 drives the bottom plate 13, the rotating plate 12, the top plate 8 and the ear 9 through the output end to clean the surface of the building materials, the rotating plate 12 is limited by a hole 19 in the middle inside the left extension plate 7 and the right extension plate 11, dust raised during cleaning directly enters the dust storage box 18 through the dust inlet groove 20 of the dust baffle plate 17, after the cleaning is finished, the operator manually presses the left extension plate 7 and the right extension plate 11 downwards, the left sliding block 14 on the right side top end of the left extension plate 7 and the right sliding block 15 on the right side of the left extension plate 11 downwards slide along the sliding grooves on the left side and the right side of the detection head 5, the compression spring 16 deforms, at the moment, the pressing head 6 is aligned with the region to be detected, the dust is pressed at 90 degrees, after the dust is pushed into the dust tank 20, the dust is pushed towards the dust tank, the detection head 6 is pushed towards the display screen 2, and the display screen 2 is pushed by the user, and the display screen 2 is pushed.

Finally, it should be noted that: the foregoing description of the preferred embodiments of the present utility model is not intended to be limiting, but rather, it will be apparent to those skilled in the art that the foregoing description of the preferred embodiments of the present utility model can be modified or equivalents can be substituted for some of the features thereof, and any modification, equivalent substitution, improvement or the like that is within the spirit and principles of the present utility model should be included in the scope of the present utility model.

Claims (7)

1. The utility model provides a building material thickness measuring mechanism for building engineering, includes organism (1), its characterized in that: the utility model discloses a portable electric harvester, including organism (1) including frame (1), terminal surface top is provided with display screen (2), terminal surface below is provided with button (3) before organism (1), fixedly connected with connecting wire (4) in the middle of organism (1) up end, connecting wire (4) top fixedly connected with detects head (5), detect head (5) inboard top sliding connection has push down head (6), detect head (5) inside left side sliding connection has left sliding block (14), detect head (5) inside right side sliding connection has right sliding block (15), terminal surface all fixedly connected with compression spring (16) under left sliding block (14) and right sliding block (15), terminal surface fixedly connected with left sliding block (14) extension board (7) in the middle of right sliding block (15) right side terminal surface fixedly connected with right extending board (11), hole (19) have been seted up in the middle of inside left extending board (7) and right extending board (11) inside middle rotation connection has left sliding block (12), terminal surface (12) in the inside left extending board (5) and right extending board (12), terminal surface (8) are connected with top plate (13) in the fixed connection, terminal surface (8) are connected with top plate (13), the dust collecting device is characterized in that motors (10) are fixedly connected to the lower end faces of the left extending plate (7) and the right extending plate (11), dust baffle plates (17) are fixedly connected to the front side and the rear side of the upper end faces of the left extending plate (7) and the right extending plate (11), a dust inlet groove (20) is formed in the middle of the inside of each dust baffle plate (17), and a dust storage box (18) is fixedly connected to the outer end face of each dust baffle plate (17).

2. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: compression spring (16) bottom and the inside below left and right sides fixed connection of detecting head (5), left side extension board (7) right-hand member face and right extension board (11) left end face all with detect head (5) outside sliding connection, fixed connection in the middle of motor (10) top output and bottom plate (13) lower terminal surface, terminal surface and left extension board (7) and right extension board (11) up end contact under roof (8), bottom plate (13) up end and left extension board (7) and right extension board (11) lower terminal surface contact.

3. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: the number of the rotating plates (12), the top plates (8) and the bottom plates (13) is two, and the rotating plates (12), the top plates (8) and the bottom plates (13) are distributed in holes (19) in the left extending plate (7) and the right extending plate (11).

4. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: the caliber of a hole (19) in the middle of the left extending plate (7) and the right extending plate (11) is the same as the diameter of the cross section of the rotating plate (12), the diameters of the cross sections of the top plate (8) and the bottom plate (13) are the same, and the diameters of the cross sections of the top plate (8) and the bottom plate (13) are one half and five times larger than the diameter of the cross section of the rotating plate (12).

5. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: the sliding grooves are formed in the top ends of the left side and the right side of the detection head (5), the cross section of the sliding grooves in the top ends of the left side and the right side of the detection head (5) is identical to that of the left sliding block (14) and the right sliding block (15), and the cross section diameter of the compression spring (16) is five millimeters shorter than the length of the left sliding block (14) and the length of the right sliding block (15) from front to back.

6. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: the inner sides of the sliding grooves at the top ends of the left side and the right side of the detection head (5) are provided with limiting rods, the outer sides of the limiting rods are in sliding connection with the middle inside the left sliding block (14), the middle inside the right sliding block (15) and the middle inside the compression spring (16), and the length of the limiting rods is identical to the height of the sliding grooves at the top ends of the left side and the right side of the detection head (5).

7. A building material thickness measuring mechanism for construction engineering according to claim 1, wherein: the total number of the dust baffle (17) and the dust storage box (18) is four, the dust baffle (17) and the dust storage box (18) are distributed on the front side of the left extension plate (7), the rear side of the left extension plate (7), the front side of the right extension plate (11) and the rear side of the right extension plate (11), and the middle of the outer end face of the dust storage box (18) is provided with an opening and closing door.