CN111141226A - Cylindrical stone pillar diameter measuring equipment for building construction - Google Patents

Abstract

The invention discloses a cylindrical stone pillar diameter measuring device for building construction, which comprises a measuring box, a measuring space is arranged in the measuring box, a double-shaft motor is fixedly arranged on the left end wall of the measuring space, two moving mechanisms are symmetrically arranged up and down by taking the double-shaft motor as a center, the moving mechanisms comprise driving belt wheels, the right side of the driving belt wheel is provided with a driving belt wheel, the measuring box and the driving belt wheel are in friction transmission through a driving belt, the invention can automatically measure the diameter of the cylindrical stone pillar, so as to facilitate the subsequent construction, the invention has higher integral automation degree and better linkage among all the functions, in the measuring process, the invention can automatically carry out friction treatment on the surface of the cylindrical stone pillar to remove dirt on the surface, the measuring result is more accurate, the measurement can be continuously carried out, and a plurality of data can be rapidly possessed.

Description

Cylindrical stone pillar diameter measuring equipment for building construction

Technical Field

The invention relates to the field of building construction measurement, in particular to a cylindrical stone pillar diameter measuring device for building construction.

Background

Building construction measurement is an important task before and during construction, through a series of measurements, can be to building location, basic construction, to wall body construction, building component installation etc. process very big help, and before the construction to the stone pillar of cylinder type, usually will measure its diameter of co-altitude not, for subsequent processing, and current technique, mostly need with the help of the instrument, let the workman rise to appointed height and carry out manual measurement, it is comparatively troublesome and time-consuming to measure, and because the long-term dirt that accumulates of stone pillar surface, can produce the influence to the measuring result.

Disclosure of Invention

The invention aims to solve the technical problem of providing cylindrical stone pillar diameter measuring equipment for building construction, and overcomes the problems that the direct measurement of cylindrical stone pillars is troublesome and errors may be generated in the measurement result.

The invention is realized by the following technical scheme.

The invention relates to cylindrical stone pillar diameter measuring equipment for building construction, which comprises a measuring box, wherein a measuring space is arranged in the measuring box, and a double-shaft motor is fixedly arranged on the left end wall of the measuring space;

the measuring device is characterized in that the double-shaft motor is used as a center, two moving mechanisms are symmetrically arranged up and down, each moving mechanism comprises a driving belt wheel, a transmission belt wheel is arranged on the right side of each driving belt wheel, the measuring box and the transmission belt wheels are in friction transmission through a transmission belt, a first bevel gear coaxial with the transmission belt wheels is arranged on one side, close to the double-shaft motor, of each transmission belt wheel, a second bevel gear is meshed with the rear side of each first bevel gear, a coaxial rotating wheel is arranged on the rear side of each second bevel gear, and the driving belt wheels can drive the rotating wheels to rotate when rotating, and the measuring box can be driven to move up and;

the right side of the double-shaft motor is provided with a measuring mechanism, the measuring mechanism comprises a containing block arranged in the measuring space, a containing cavity with an opening facing the right is arranged in the right end face of the containing block, a reel is arranged in the containing cavity, a friction belt is wound on the reel, a lock catch is arranged on the front side of the containing block, one end of the friction belt is inserted into the lock catch through a lock tongue, the lock tongue is continuously inserted into the lock catch after being pulled out of the lock catch, and the friction belt is pulled to bind a cylindrical stone column, and can be used for measuring the diameter of the cylindrical stone column;

the measuring mechanism upside is equipped with data record mechanism, data record mechanism include with accomodate piece up end fixed connection's top piece, be equipped with the top chamber in the top piece, the top intracavity is equipped with the data belt, there is the reading in the data belt outer terminal surface, the fixed pointer that is equipped with of top chamber rear end wall, shooting equipment is installed to top chamber upper end wall, shooting equipment can shoot the pointer is in the reading that the outer terminal surface of data belt points out represents the diameter of here cylinder type stone pillar.

Preferably, the movement mechanism further comprises a motor shaft controlled by the double-shaft motor, one end of the motor shaft, which is far away from the double-shaft motor, is fixedly connected with the driving belt wheel, a transmission shaft which is rotatably connected with the end wall of the measurement space is arranged on the right side of the motor shaft, the transmission belt wheel and the first bevel gear are fixedly arranged on the transmission shaft, an output shaft is rotatably arranged on the rear end wall of the measurement space, the second bevel gear and the rotating wheel are fixedly arranged on the output shaft, the right end wall of the measurement space is communicated with the external space through an extending cavity, and the rotating wheel penetrates through the extending cavity.

Preferably, the cleaning mechanism includes a moving cavity arranged in the rear end wall of the measuring space, the opening of the moving cavity faces forward, a moving block is arranged in the moving cavity in a sliding manner, a moving rod with a front end located in the measuring space is fixedly arranged on the front end face of the moving block, the moving rod is fixedly connected with the containing block, a rotating rod is arranged on the front end wall of the measuring space in a rotating manner, a worm wheel is fixedly arranged on the rear end of the rotating rod, a cylindrical pin is fixedly arranged on the rear end face of the worm wheel, a connecting rod is fixedly arranged on the left end face of the containing block, a groove block is fixedly arranged on the left end face of the connecting rod, a connecting groove penetrating through the front end face and the rear end face of the groove block is arranged in the groove block, the cylindrical pin penetrates through the front end wall and the rear end.

Preferably, the measuring mechanism further comprises a movement cavity arranged in the front end wall of the measuring space, the opening of the movement cavity faces backwards, a movement block is arranged in the movement cavity in a sliding manner, a movement rod is fixedly arranged on the rear end face of the movement block, the movement rod is fixedly connected with the lock catch, a first toothed plate is fixedly arranged on the rear end face of the lock catch, a second toothed plate is fixedly arranged on the front end face of the accommodating block, an intermediate shaft is rotatably arranged on the upper end wall of the measuring space, an intermediate gear is fixedly arranged at the lower end of the intermediate shaft, the intermediate gear is simultaneously meshed with the second toothed plate and the first toothed plate, the right end wall of the measuring space is communicated with the external space through two penetrating cavities, a torsion shaft is rotatably arranged on the lower end wall of the accommodating cavity, the upper end of the torsion shaft is located in the top cavity, a torsion spring is arranged between the torsion shaft and the lower end wall of the accommodating, the friction belt penetrates through the two penetrating cavities, a third bevel gear is fixedly arranged at the upper end of the torsion shaft, and the front end wall of the measuring space is communicated with the external space through the cavity.

Preferably, the data recording mechanism includes a first rotating shaft and a second rotating shaft rotatably connected to the rear end wall of the top cavity, the second rotating shaft is located on the right side of the first rotating shaft, a fourth bevel gear and a first belt pulley are fixedly arranged on the first rotating shaft, the first belt pulley is located on the rear side of the fourth bevel gear, the fourth bevel gear is engaged with the third bevel gear, a second belt pulley is fixedly arranged on the second rotating shaft, the second belt pulley and the first belt pulley are in friction transmission through the data belt, and a bulb fixedly arranged on the upper end wall of the second bevel gear is arranged on the right side of the shooting device.

Preferably, a height sensor is mounted on the lower end face of the measuring box.

The invention has the beneficial effects that: the invention can automatically measure the diameter of the cylindrical stone column so as to facilitate subsequent construction, has higher overall automation degree and better linkage among functions of each part, and can automatically carry out friction treatment on the surface of the cylindrical stone column to remove dirt on the surface in the measuring process, so that the measuring result is more accurate, the measurement can be continuously carried out, and a plurality of data can be rapidly possessed.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the embodiment of the present invention at A in FIG. 1;

FIG. 3 is a schematic view of the embodiment of the present invention in the direction B-B in FIG. 1;

FIG. 4 is a schematic view of the embodiment of the present invention in the direction of C-C in FIG. 1;

FIG. 5 is a schematic view of the embodiment of the present invention in the direction D-D in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The cylindrical stone pillar diameter measuring equipment for building construction, which is described in conjunction with the attached drawings 1-5, comprises a measuring box 10, wherein a measuring space 11 is arranged in the measuring box 10, and a double-shaft motor 15 is fixedly arranged on the left end wall of the measuring space 11;

the two movement mechanisms 70 are symmetrically arranged up and down by taking the double-shaft motor 15 as a center, the movement mechanisms 70 comprise a driving belt wheel 19, a driving belt wheel 24 is arranged on the right side of the driving belt wheel 19, the measuring box 10 and the driving belt wheel 24 are in friction transmission through a driving belt 23, a first bevel gear 27 coaxial with the driving belt wheel 24 is arranged on one side of the driving belt wheel 24 close to the double-shaft motor 15, a second bevel gear 29 is meshed with the rear side of the first bevel gear 27, a coaxial rotating wheel 30 is arranged on the rear side of the second bevel gear 29, when the driving belt wheel 19 rotates, the rotating wheel 30 can be driven to rotate, and the measuring box 10 can be driven to move up and down through the rotation of the rotating wheel 30;

the right side of the double-shaft motor 15 is provided with a measuring mechanism 72, the measuring mechanism 72 comprises a containing block 32 arranged in the measuring space 11, a containing cavity 50 with an opening facing to the right is arranged in the right end face of the containing block 32, a reel 14 is arranged in the containing cavity 50, a friction belt 31 is wound on the reel 14, a lock catch 56 is arranged on the front side of the containing block 32, one end of the friction belt 31 is inserted into the lock catch 56 through a lock tongue 52, the lock tongue 52 is pulled out of the lock catch 56, when the friction belt 31 is pulled to bind the cylindrical stone pillar, the lock tongue 52 is continuously inserted into the lock catch 56, and the friction belt 31 can be used for measuring the diameter of the cylindrical stone pillar;

measuring mechanism 72 upside is equipped with data record mechanism 73, data record mechanism 73 include with accomodate piece 32 up end fixed connection's top piece 37, be equipped with top chamber 39 in the top piece 37, be equipped with data belt 40 in the top chamber 39, there is the reading in the data belt 40 outer terminal surface, top chamber 39 rear end wall is fixed to be equipped with pointer 42, shooting equipment 41 is installed to top chamber 39 upper end wall, shooting equipment 41 can shoot pointer 42 is in the reading that the outer terminal surface of data belt 40 points out represents the diameter of here cylinder type stone pillar.

Advantageously, the moving mechanism 70 further comprises a motor shaft 18 controlled by the double-shaft motor 15, one end of the motor shaft 18 far from the double-shaft motor 15 is fixedly connected with the driving pulley 19, a transmission shaft 25 rotatably connected with the end wall of the measuring space 11 is arranged on the right side of the motor shaft 18, the transmission pulley 24 and the first bevel gear 27 are fixedly arranged on the transmission shaft 25, the rear end wall of the measuring space 11 is rotatably provided with an output shaft 28, the second bevel gear 29 and the rotating wheel 30 are fixedly arranged on the output shaft 28, the right end wall of the measuring space 11 is communicated with the external space through an extending cavity 26, and the rotating wheel 30 penetrates through the extending cavity 26.

Advantageously, the cleaning mechanism 71 includes a moving cavity 16 disposed in a rear end wall of the measuring space 11, the moving cavity 16 has a forward opening, a moving block 13 is slidably disposed in the moving cavity 16, a moving rod 60 having a front end located in the measuring space 11 is fixedly disposed on a front end surface of the moving block 13, the moving rod 60 is fixedly connected to the accommodating block 32, a rotating rod 47 is rotatably disposed on the front end wall of the measuring space 11, a worm wheel 21 is fixedly disposed on a rear end of the rotating rod 47, a cylindrical pin 49 is fixedly disposed on a rear end surface of the worm wheel 21, a connecting rod 22 is fixedly disposed on a left end surface of the accommodating block 32, a slot block 20 is fixedly disposed on a left end of the connecting rod 22, a connecting slot 48 is disposed in the slot block 20 and penetrates through front and rear end surfaces of the slot block 20, the cylindrical pin 49 penetrates through front and rear end walls of the connecting slot 48, and, the worm block 17 is engaged with the worm wheel 21.

Beneficially, the measuring mechanism 72 further includes a moving cavity 53 disposed in the front end wall of the measuring space 11, the moving cavity 53 opens backward, a moving block 55 is slidably disposed in the moving cavity 53, a moving rod 54 is fixedly disposed on the rear end surface of the moving block 55, the moving rod 54 is fixedly connected with the latch 56, a first toothed plate 51 is fixedly disposed on the rear end surface of the latch 56, a second toothed plate 59 is fixedly disposed on the front end surface of the accommodating block 32, an intermediate shaft 57 is rotatably disposed on the upper end wall of the measuring space 11, an intermediate gear 58 is fixedly disposed at the lower end of the intermediate shaft 57, the intermediate gear 58 is simultaneously engaged with the second toothed plate 59 and the first toothed plate 51, the right end wall of the measuring space 11 is communicated with the external space through two penetrating cavities 61, a torsion shaft 12 is rotatably disposed on the lower end wall of the accommodating cavity 50, and the upper end of the torsion shaft 12 is located in the top cavity 39, a torsion spring 34 is arranged between the torsion shaft 12 and the lower end wall of the containing cavity 50, the reel 14 is fixedly arranged on the torsion shaft 12, the friction belt 31 penetrates through the two penetrating cavities 61, a third bevel gear 35 is fixedly arranged at the upper end of the torsion shaft 12, and the front end wall of the measuring space 11 is communicated with the external space through a cavity 63.

Advantageously, the data recording mechanism 73 comprises a first rotating shaft 36 and a second rotating shaft 44 rotatably connected to the rear end wall of the top cavity 39, the second rotating shaft 44 is located at the right side of the first rotating shaft 36, a fourth bevel gear 46 and a first pulley 38 are fixedly arranged on the first rotating shaft 36, the first pulley 38 is located at the rear side of the fourth bevel gear 46, the fourth bevel gear 46 is engaged with the third bevel gear 35, a second pulley 45 is fixedly arranged on the second rotating shaft 44, the second pulley 45 is in friction transmission with the first pulley 38 through the data belt 40, and a bulb 43 fixedly arranged on the upper end wall of the second bevel gear 29 is arranged at the right side of the shooting device 41.

Advantageously, the measuring chamber 10 is fitted with a height sensor 33 on its lower end face.

In the initial state, the torsion spring 34 is in a normal state.

The hand is extended into the measuring space 11 through the cavity 63, the bolt 52 is taken out of the lock catch 56, the bolt 52 is taken out of the cavity 61 from the lower side, the friction belt 31 is manually pulled to drive the reel 14 to rotate, the torsion spring 34 is compressed, the cylindrical stone pillar is bound through the friction belt 31, the bolt 52 is extended out of the cavity 61 from the lower side and is inserted into the lock catch 56, the torsion spring 34 is reset, and the measuring box 10 is bound on the cylindrical stone pillar through the two rotating wheels 30 and the friction belt 31;

the double-shaft motor 15 and the height sensor 33 are started through the control terminal, the height sensor 33 can detect the height from the ground and display the height at the control terminal, the double-shaft motor 15 is started to simultaneously drive the two motor shafts 18 to rotate in the same direction, the motor shafts 18 drive the driving belt wheel 19 to rotate, the driving belt wheel 23 is driven to move through the friction transmission between the driving belt wheel 19 and the driving belt wheel 23, the driving belt wheel 24 is driven to rotate through the friction transmission between the driving belt wheel 23 and the driving belt wheel 24, the driving belt wheel 24 drives the driving shaft 25 to rotate, the driving shaft 25 drives the first bevel gear 27 to rotate, the second bevel gear 29 is driven to rotate through the engagement between the first bevel gear 27 and the second bevel gear 29, the second bevel gear 29 drives the output shaft 28 to rotate, the output shaft 28 drives the rotating wheel 30 to rotate, the measuring box 10 is driven to ascend through the friction transmission, the upper motor shaft 18 drives the worm block 17 to rotate, the worm wheel 21 is driven to rotate through the meshing between the worm block 17 and the worm wheel 21, the worm wheel 21 drives the cylindrical pin 49 to rotate, the groove block 20 can be driven to move left and right repeatedly in the rotating process of the cylindrical pin 49, the groove block 20 drives the connecting rod 22 to move, the connecting rod 22 drives the accommodating block 32 to move, the accommodating block 32 drives the second toothed plate 59 to move, the intermediate gear 58 is driven to rotate through the meshing between the second toothed plate 59 and the intermediate gear 58, and the first toothed plate 51 is driven to move in the opposite direction of the second toothed plate 59 through the meshing between the intermediate gear 58 and the first toothed plate 51, so that the friction belt 31 is driven to move along the cylindrical stone column, accumulated dirt on the cylindrical stone column is removed, and the measurement is prevented from being influenced;

when the height sensor 33 detects the height position to be measured, the dual-shaft motor 15 stops working, the friction belt 31 is loosened to a certain degree, the reel 14 is driven to rotate, the reel 14 drives the torsion shaft 12 to rotate, the torsion shaft 12 drives the third bevel gear 35 to rotate, the fourth bevel gear 46 is driven to rotate through the meshing of the third bevel gear 35 and the fourth bevel gear 46, the fourth bevel gear 46 drives the first rotating shaft 36 to rotate, the first rotating shaft 36 drives the first belt pulley 38 to rotate, the rotating wheel 30 is driven to move through the friction transmission of the first belt pulley 38 and the data belt 40, the shooting device 41 and the bulb 43 are started through the control terminal, the bulb 43 is used for illumination, the shooting device 41 can shoot the reading of the pointer 42 on the data belt 40 and send the reading to the control terminal, the reading of the pointer 42 on the data belt 40 is the diameter of the cylindrical stone column at the position, the measurement can be performed continuously.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention. .

Claims (6)

1. The utility model provides a cylindrical stone pillar diameter measuring equipment for construction, includes measuring case, its characterized in that: a measuring space is arranged in the measuring box, and a double-shaft motor is fixedly arranged on the left end wall of the measuring space;

the measuring device is characterized in that the double-shaft motor is used as a center, two moving mechanisms are symmetrically arranged up and down, the moving mechanisms comprise driving belt wheels, driving belt wheels are arranged on the right sides of the driving belt wheels, the measuring box and the driving belt wheels are in friction transmission through driving belts, first bevel gears coaxial with the driving belt wheels are arranged on one sides of the driving belt wheels close to the double-shaft motor, second bevel gears are meshed with the rear sides of the first bevel gears, coaxial rotating wheels are arranged on the rear sides of the second bevel gears, when the driving belt wheels rotate, the rotating wheels can be driven to rotate, and the measuring box can be driven to move up and down through the rotation of the rotating wheels;

the right side of the double-shaft motor is provided with a measuring mechanism, the measuring mechanism comprises a containing block arranged in the measuring space, a containing cavity with an opening facing the right is arranged in the right end face of the containing block, a reel is arranged in the containing cavity, a friction belt is wound on the reel, a lock catch is arranged on the front side of the containing block, one end of the friction belt is inserted into the lock catch through a lock tongue, the lock tongue is continuously inserted into the lock catch after being pulled out of the lock catch, and the friction belt is pulled to bind a cylindrical stone column, and can be used for measuring the diameter of the cylindrical stone column;

the measuring mechanism upside is equipped with data record mechanism, data record mechanism include with accomodate piece up end fixed connection's top piece, be equipped with the top chamber in the top piece, the top intracavity is equipped with the data belt, there is the reading in the data belt outer terminal surface, the fixed pointer that is equipped with of top chamber rear end wall, shooting equipment is installed to top chamber upper end wall, shooting equipment can shoot the pointer is in the reading that the outer terminal surface of data belt points out represents the diameter of here cylinder type stone pillar.

2. The cylindrical stone pillar diameter measuring equipment for building construction as claimed in claim 1, characterized in that: the movement mechanism further comprises a motor shaft controlled by the double-shaft motor, one end of the motor shaft, far away from the double-shaft motor, is fixedly connected with the driving belt wheel, a transmission shaft is arranged on the right side of the motor shaft and is rotatably connected with the end wall of the measuring space, the transmission belt wheel and the first bevel gear are fixedly arranged on the transmission shaft, an output shaft is rotatably arranged on the rear end wall of the measuring space, the second bevel gear and the rotating wheel are fixedly arranged on the output shaft, the right end wall of the measuring space is communicated with the external space through an extending cavity, and the rotating wheel penetrates through the extending cavity.

3. The cylindrical stone pillar diameter measuring equipment for building construction as claimed in claim 1, characterized in that: the cleaning mechanism comprises a moving cavity arranged in the rear end wall of the measuring space, the opening of the moving cavity faces forward, a moving block is arranged in the moving cavity in a sliding mode, a moving rod with the front end located in the measuring space is fixedly arranged on the front end face of the moving block, the moving rod is fixedly connected with the containing block, a rotating stick is arranged on the front end wall of the measuring space in a rotating mode, a worm wheel is fixedly arranged on the rear end of the rotating stick, a cylindrical pin is fixedly arranged on the rear end face of the worm wheel, a connecting rod is fixedly arranged on the left end face of the containing block, a groove block is fixedly arranged on the left end face of the connecting rod, a connecting groove penetrating through the front end face and the rear end face of the groove block is formed in the groove block, the cylindrical pin penetrates through the front end wall and the rear.

4. The cylindrical stone pillar diameter measuring equipment for building construction as claimed in claim 1, characterized in that: the measuring mechanism further comprises a movement cavity arranged in the front end wall of the measuring space, the opening of the movement cavity faces backwards, a movement block is arranged in the movement cavity in a sliding mode, a movement rod is fixedly arranged on the rear end face of the movement block, the movement rod is fixedly connected with the lock catch, a first toothed plate is fixedly arranged on the rear end face of the lock catch, a second toothed plate is fixedly arranged on the front end face of the accommodating block, an intermediate shaft is rotatably arranged on the upper end wall of the measuring space, an intermediate gear is fixedly arranged at the lower end of the intermediate shaft, the intermediate gear is simultaneously meshed with the second toothed plate and the first toothed plate, the right end wall of the measuring space is communicated with the external space through two penetrating cavities, a torsion shaft is rotatably arranged on the lower end wall of the accommodating cavity, the upper end of the torsion shaft is located in the top cavity, a torsion spring is arranged between the torsion shaft and the lower end wall of the, the friction belt penetrates through the two penetrating cavities, a third bevel gear is fixedly arranged at the upper end of the torsion shaft, and the front end wall of the measuring space is communicated with the external space through the cavity.

5. The cylindrical stone pillar diameter measuring equipment for building construction as claimed in claim 4, characterized in that: the data recording mechanism comprises a first rotating shaft and a second rotating shaft which are rotatably connected with the rear end wall of the top cavity, the second rotating shaft is located on the right side of the first rotating shaft, a fourth bevel gear and a first belt pulley are fixedly arranged on the first rotating shaft, the first belt pulley is located on the rear side of the fourth bevel gear, the fourth bevel gear is meshed with the third bevel gear, a second belt pulley is fixedly arranged on the second rotating shaft, the second belt pulley and the first belt pulley are in friction transmission through a data belt, and a bulb fixedly arranged on the upper end wall of the second bevel gear is arranged on the right side of the shooting device.

6. The cylindrical stone pillar diameter measuring equipment for building construction as claimed in claim 1, characterized in that: and a height sensor is arranged on the lower end surface of the measuring box.

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