CN117168503B - Detection device for laser level meter - Google Patents

Abstract

The invention relates to the technical field of laser level meter detection, in particular to a detection device for a laser level meter, which comprises a workbench, wherein a first lifting component is arranged at the lower side of one end of the workbench, a second lifting component is arranged at the lower side of the other end of the workbench, a bottom plate is arranged below the workbench, the upper part of the first lifting component is rotationally connected with the lower side of one end of the workbench, the lower part of the first lifting component is fixedly connected with the bottom plate, the upper part of the second lifting component is rotationally and slidingly connected with the lower side of the other end of the workbench, and the lower part of the second lifting component is in sliding contact with the bottom plate. According to the invention, the first lifting assembly and the second lifting assembly are respectively connected with the lower sides of two ends of the workbench in a rotating way, and then the height of the first lifting assembly or the second lifting assembly is independently adjusted, so that the height difference between the first lifting assembly and the second lifting assembly occurs, the workbench is inclined, and the inclination angle is precisely adjusted, so that the use effect of the level meter under different angles is detected.

Description

Detection device for laser level meter

Technical Field

The invention relates to the technical field of laser level meter detection, in particular to a detection device for a laser level meter.

Background

The laser level meter can emit laser rays, project the laser rays on a target object, generate horizontal or vertical lines for reference, and has wide application in the fields of engineering, construction, decoration and the like. The angle of the laser beam emitted by the laser level meter is the angle formed by the laser beam and the horizontal plane or the vertical plane of the emitting point, is an important index for measuring the precision of the laser level meter, and is usually used as a final inspection item on a laser level meter production line to ensure that the product has qualified quality after being processed and assembled. At present, the laser level gauge produced at home is judged by a mode of artificial naked eye observation, the accuracy and repeatability are difficult to be ensured, and the detection efficiency is quite low.

In the process of detecting the laser level, the laser level needs to be quickly adjusted according to the deviation condition, and the existing detection device of the laser level has the following defects:

1. the prior Chinese patent with the application number of CN202221026761.0 discloses a laser level detector, which comprises an operation desk and an adjusting unit; the upper surface of the operation table is provided with an information acquisition unit, a PLC (programmable logic controller) and a bracket, and the input end of the PLC is electrically connected with the output end of an external control switch group; the adjusting unit comprises a handle, a rotary table, a first screw rod, a sliding block, a fixing plate, a motor and a mounting frame, wherein the first screw rod is rotationally connected to the support, the rotary table is arranged at the upper end of the first screw rod, the handle is arranged at the eccentric position of the rotary table, the sliding block is connected with the sliding block in a threaded mode, the sliding block is connected with the support in a sliding mode, two fixing plates and one motor are arranged on the side face of the sliding block, the motor is located between the two fixing plates, and the two fixing plates are fixedly connected with the motor. However, when the height of the laser level in the prior art is adjusted, the higher the laser level is, the more easily the center of gravity is unstable, and the laser level is easy to incline, so that the use of the laser level is affected;

2. in the prior art, when the angle of the laser level is adjusted, a plurality of angles are needed to be adjusted, however, the existing detection device of the laser level cannot be used for adjusting a plurality of angles rapidly, so that the angle adjustment efficiency of the laser level is low, and the detection efficiency of the laser level is affected;

3. when the laser level is required to be detected in the prior art, only the mounting head assembly on one side of the laser level can be detected, and when other mounting head assemblies are required to be detected, the laser level is required to be taken out and the rotation direction is required to be re-fixed, so that the efficiency of detecting the laser level is reduced.

Disclosure of Invention

The object of the present invention is to provide a detection device for a laser level, which is used for overcoming the above-mentioned drawbacks of the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a detection device for laser level meter, includes the workstation, the one end downside of workstation is equipped with first lifting unit, the other end downside of workstation is equipped with second lifting unit, the below of workstation is equipped with the bottom plate, be connected between first lifting unit and the second lifting unit and be equipped with two hydraulic telescoping rods, the upside of bottom plate is fixed and is equipped with two first flexible bracing pieces, two the fixed water tank that is equipped with of stretching out end of first flexible bracing piece, the inside both sides of water tank are the sliding respectively are equipped with two piston plates, two the outside of hydraulic telescoping rod is overlapped respectively and is equipped with two ring pieces, two fixedly connected with two push rods between ring piece and the two piston plates respectively, the upper portion of first lifting unit and the one end downside of workstation rotate to be connected, the lower part and the bottom plate fixed connection of first lifting unit, the upper portion and the other end downside of workstation rotate and sliding connection of second lifting unit, the lower part and bottom plate sliding contact.

The first lifting assembly and the second lifting assembly are respectively connected with the lower sides of two ends of the workbench in a rotating mode, the height of the first lifting assembly or the height of the second lifting assembly are independently adjusted, so that the height difference between the first lifting assembly and the second lifting assembly is formed, the workbench is inclined, the inclination angle is precisely adjusted, the use effect of the level meter under different angles is detected, and the stability of the laser level meter under different angles can be detected.

Preferably, each push rod is in sliding contact with the water tank, each push rod is internally communicated with the annular piece, each push rod is internally communicated with the water tank and is provided with a first through hole, each first through hole is positioned in the middle of the piston plate, each hydraulic telescopic rod is internally communicated with the annular piece, an elastic piece is connected between the extending part of the hydraulic telescopic rod and the fixed seat, the fixed seat of the hydraulic telescopic rod is fixed on the first moving block, and the extending part of the hydraulic telescopic rod is in sliding contact with the second moving block.

Preferably, the first lifting assembly comprises a fixed plate, the fixed plate is fixed on the bottom plate, two first fixed frames are fixedly arranged on the upper sides of two ends of the fixed plate respectively, two first movable blocks are fixedly arranged above the first fixed frames respectively, two first movable blocks are rotatably connected between the first fixed frames and the two first movable blocks respectively, two second fixed frames are arranged above the first movable blocks respectively, two second movable plates are rotatably connected between the second fixed frames and the two first movable blocks respectively, two first double-threaded screw rods are arranged between the first movable blocks in a threaded contact manner, one end of each first double-threaded screw rod is fixedly provided with a first operation block, two first movable blocks are fixedly connected between the second fixed frames, the first movable blocks are rotatably connected with the lower side of the workbench, a first groove is formed in the lower side of one end of the workbench, and a first rotating shaft is rotatably connected between the first groove and the first movable blocks.

Preferably, the second lifting assembly comprises a first moving plate, the first moving plate slides on the upper side of the bottom plate, two third fixed frames are fixedly arranged on the upper sides of two ends of the first moving plate respectively, two second moving blocks are fixedly arranged above the third fixed frames respectively, two third rotating plates are rotatably connected between the second moving blocks and the two third fixed frames respectively, two fourth fixed frames are arranged above the second moving blocks respectively, two fourth fixed frames are rotatably connected with the two second moving blocks respectively, two fourth rotating plates are arranged on the fourth fixed frames in a threaded manner, a second double-threaded screw rod is arranged between the two second moving blocks in a threaded manner, a second operating block is fixedly arranged at one end of the second double-threaded screw rod, two second rotating blocks are fixedly connected between the fourth fixed frames, a first sliding groove is arranged on the lower side of the other end of the workbench, the second rotating blocks slide in the first sliding groove, two second sliding grooves are respectively arranged on two sides of the first sliding grooves, two fourth sliding grooves are respectively, two second rotating shafts are respectively arranged on the second sliding shafts are arranged on the two ends of the second sliding shafts.

Preferably, the fixed slider that is equipped with of downside of first movable plate, the fixed four first supporting shoes that are equipped with of downside of bottom plate, upper portion one side of bottom plate is equipped with the third spout, the slider slides in the third spout, be equipped with compression spring between slider and the third spout.

Preferably, two second telescopic supporting rods are fixedly arranged on the upper side of one end of the bottom plate, laser receiving plates are fixedly arranged at the extending ends of the two second telescopic supporting rods, and a display is arranged on the upper side of the bottom plate. The laser receiving plate is used for receiving and analyzing the laser emitted by the laser level meter, so that the laser emission angle of the laser level meter is rapidly detected and compared, the detection accuracy and speed are effectively improved, and the detection error is reduced.

Preferably, the upper portion of workstation is equipped with the second recess, it is equipped with the plectane to rotate in the second recess, the lower part outside cover of plectane is equipped with the solid fixed ring, gu fixed ring is in the annular slip of workstation, one side of plectane slides and is equipped with the fixture block, the inside circumference array of second recess is equipped with a plurality of draw-in grooves, the one end and the draw-in groove sliding contact of fixture block.

Preferably, a placing plate is fixedly arranged on the upper side of the circular plate, and three second through holes are formed in the placing plate in a circumferential array.

Preferably, the inner circumference array of each second through hole is slidably provided with three push rods, one end of each push rod is fixedly provided with a clamping block, the other end of each push rod is connected with a placing plate, a spring is arranged between the other end of each push rod and the placing plate, and the upper end of the inner side of each clamping block is of an inclined surface structure.

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

the first lifting component and the second lifting component are respectively connected with the lower sides of two ends of the workbench in a rotating way, and the heights of the first lifting component or the second lifting component are independently adjusted, so that the height difference between the first lifting component and the second lifting component is generated, the workbench is inclined, the inclination angle is precisely adjusted, the use effect of the level meter under different angles is detected, and the stability of the laser level meter under different angles can be detected.

The laser emitted by the laser level meter is received and analyzed through the laser receiving plate, so that the laser emission angle of the laser level meter is rapidly detected and compared, the detection accuracy and speed are effectively improved, and the detection error is reduced.

The circular plate rotates in the second groove, so that the horizontal direction of the laser level is adjusted, a plurality of mounting head assemblies on the laser level are conveniently detected, and the detection efficiency of the laser level is improved; and the circular plate is limited and fixed in the clamping groove through the clamping block so as to conveniently detect the laser level in multiple directions.

Drawings

The invention is further explained below with reference to the drawings and examples:

FIG. 1 is a schematic view of an isometric structure of the present invention.

FIG. 2 is a schematic isometric view of the related structure of the interior of the workbench according to the invention.

FIG. 3 is a schematic view of an isometric view of a related structure on the upper side of a table according to the present invention.

Fig. 4 is a schematic top view of fig. 1.

FIG. 5 is a schematic cross-sectional view of the structure at A-A in FIG. 4.

Fig. 6 is a schematic view of a partial enlarged structure at D in fig. 5.

FIG. 7 is a schematic cross-sectional view of the structure at B-B in FIG. 4.

Fig. 8 is a schematic diagram of an isometric structure of a first lifting assembly and a second lifting assembly according to the present invention.

Fig. 9 is a schematic diagram of an isometric structure of a first lifting assembly and a second lifting assembly according to the present invention.

Fig. 10 is a schematic diagram of the front view structure of fig. 8.

FIG. 11 is a schematic cross-sectional view of the structure at C-C in FIG. 10.

In the drawing, a table 10, a first elevating assembly 11, a second elevating assembly 12, a fixed plate 13, a first fixed frame 14, a first moving block 15, a first rotating plate 16, a second fixed frame 17, a second rotating plate 18, a first moving plate 19, a third fixed frame 20, a second moving block 21, a third rotating plate 22, a fourth fixed frame 23, a fourth rotating plate 24, a first rotating block 25, a second rotating block 26, a slider 27, a first double-threaded screw rod 28, a first operating block 29, a hydraulic telescoping rod 30, a ring 31, a water tank 32, a push rod 33, a piston plate 34, a first telescoping support rod 35, a bottom plate 36, a second double-threaded screw rod 37, a second operating block 38, a first support plate 39, a second groove 42, a clamping groove 43, 44, a fixed ring 45, a clamping block 46, a first sliding groove 47, a second sliding groove 48, a placing plate 49, a second through hole 50, a third sliding groove 51, a clamping block 52, a push rod 53, a spring 54, a second telescoping support rod 55, a receiving plate 56, a spring 57, a first compression spring 58, a first compression instrument 58, a first laser leveling instrument 62, a second laser rotating shaft 64, a first rotating shaft 64, a second laser rotating shaft 60, and a first rotating shaft 64.

Detailed Description

The technical solutions of the embodiments of the present invention will be clearly and completely described below in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making any inventive effort based on the embodiments of the present invention are within the scope of protection of the present invention.

In order that the invention may be readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are, however, not limited to the embodiments described herein, but are to be provided for the purpose of making the disclosure of the invention more thorough.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may also be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms used herein in this description of the invention are for the purpose of describing particular embodiments only and are not intended to be limiting of the invention, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

Referring to fig. 1-11, a detection device for a laser level meter includes a workbench 10, a first lifting assembly 11 is disposed at one end lower side of the workbench 10, a second lifting assembly 12 is disposed at the other end lower side of the workbench 10, a bottom plate 36 is disposed below the workbench 10, the first lifting assembly 11 is disposed between the workbench 10 and the bottom plate 36, the second lifting assembly 12 is in sliding contact between the workbench 10 and the bottom plate 36, two hydraulic telescopic rods 30 are connected between the first lifting assembly 11 and the second lifting assembly 12, two first telescopic support rods 35 are fixedly disposed at the upper side of the bottom plate 36, a water tank 32 is fixedly disposed at the extending end of the two first telescopic support rods 35, two annular pieces 31 are respectively disposed at two inner sides of the water tank 32 in a sliding manner, two push rods 33 are respectively disposed between the two annular pieces 31 and the two annular pieces 34 in a fixed connection manner, the upper portion of the first lifting assembly 11 is rotationally connected with one end lower side of the workbench 10, the lower portion of the first lifting assembly 11 is fixedly connected with the bottom plate 36, the upper portion of the second lifting assembly 12 is rotationally connected with the lower side of the workbench 10, and the lower side of the second lifting assembly 12 is rotationally connected with the other end 12.

Further, as shown in fig. 1 and fig. 6 to 11, each push rod 33 is in sliding contact with the water tank 32, the inside of each push rod 33 is communicated with the inside of the annular member 31, the inside of each push rod 33 is communicated with the inside of the water tank 32, a first through hole 58 is arranged, each first through hole 58 is positioned in the middle of the piston plate 34, the inside of each hydraulic telescopic rod 30 is communicated with the inside of the annular member 31, an elastic member 60 is connected between the extending part of each hydraulic telescopic rod 30 and the fixed seat, the fixed seat of the hydraulic telescopic rod 30 is fixed on the first moving block 15, and the extending part of the hydraulic telescopic rod 30 is in sliding contact with the second moving block 21.

Further, as shown in fig. 6-11, the first lifting assembly 11 includes a fixing plate 13, the fixing plate 13 is fixed on a bottom plate 36, two first fixing frames 14 are respectively and fixedly arranged at the upper sides of two ends of the fixing plate 13, two first moving blocks 15 are respectively and fixedly arranged above the two first fixing frames 14, two first rotating plates 16 are respectively and rotatably connected between the two first fixing frames 14 and the two first moving blocks 15, two second fixing frames 17 are respectively arranged above the two first moving blocks 15, two second rotating plates 18 are respectively and rotatably connected between the two second fixing frames 17 and the two first moving blocks 15, a first double-threaded screw rod 28 is arranged between the two first moving blocks 15 in a threaded contact manner, a first operating block 29 is fixedly arranged at one end of the first double-threaded screw rod 28, a first rotating block 25 is fixedly connected between the two second fixing frames 17, a first groove 62 is rotatably connected with the lower side of the workbench 10, a first rotating shaft 63 is arranged between the first groove 62 and the first rotating block 25.

Further, as shown in fig. 6-11, the second lifting assembly 12 includes a first moving plate 19, the first moving plate 19 slides on the upper side of the bottom plate 36, two third fixed frames 20 are fixedly arranged on the upper sides of two ends of the first moving plate 19 respectively, two second moving blocks 21 are respectively arranged above the two third fixed frames 20, two third rotating plates 22 are rotatably connected between the two second moving blocks 21 and the two third fixed frames 20 respectively, two fourth fixed frames 23 are respectively arranged above the two second moving blocks 21, two fourth rotating plates 24 are respectively rotatably connected with the two fourth fixed frames 23 and the two second moving blocks 21 respectively, a second double-threaded screw 37 is arranged between the two second moving blocks 21 in a threaded contact manner, one end of the second double-threaded screw 37 is fixedly provided with a second operating block 38, a second rotating block 26 is fixedly connected between the two fourth fixed frames 23, a first sliding groove 47 is arranged on the lower side of the other end of the workbench 10, the second rotating block 26 slides in the first sliding groove 47, two second sliding grooves 48 are respectively arranged on two second sliding grooves 48, and two rotating shafts 48 are respectively arranged on two second rotating shafts 48 and two rotating shafts 48.

Further, as shown in fig. 1 to 10, a sliding block 27 is fixedly arranged at the lower side of the first moving plate 19, four first supporting blocks 39 are fixedly arranged at the lower side of the bottom plate 36, a third sliding groove 51 is arranged at one side of the upper part of the bottom plate 36, the sliding block 27 slides in the third sliding groove 51, and a compression spring 57 is connected between the sliding block 27 and the third sliding groove 51.

Further, as shown in fig. 1, two second telescopic support rods 55 are fixedly arranged on the upper side of one end of the bottom plate 36, laser receiving plates 56 are fixedly arranged on the extending ends of the two second telescopic support rods 55, and a display 61 is arranged on the upper side of the bottom plate 36.

Further, as shown in fig. 2-4, the upper portion of the workbench 10 is provided with a second groove 42, a circular plate 44 is rotatably arranged in the second groove 42, a fixed ring 45 is sleeved outside the lower portion of the circular plate 44, the fixed ring 45 slides in a ring shape in the workbench 10, a clamping block 46 is slidably arranged on one side of the circular plate 44, a plurality of clamping grooves 43 are arranged in a circumferential array in the second groove 42, and one end of the clamping block 46 is slidably contacted with the clamping groove 43.

Further, as shown in fig. 2-7, a placement plate 49 is fixedly provided on the upper side of the circular plate 44, and three second through holes 50 are provided on the placement plate 49 in a circumferential array.

Further, as shown in fig. 2 to 7, three push rods 53 are slidably disposed in the inner circumferential array of each second through hole 50, a clamping block 52 is fixedly disposed at one end of each push rod 53, a spring 54 is connected between the other end of each push rod 53 and the placement plate 49, and an upper end of an inner side of each clamping block 52 is in an inclined surface structure.

When the laser leveling instrument is used, a worker places three supporting blocks on the laser leveling instrument 59 in the three second through holes 50 respectively, the supporting blocks of the laser leveling instrument 59 enter the second through holes 50, the supporting blocks of the laser leveling instrument 59 are contacted with the inclined surface structures at the top ends of the clamping blocks 52, so that the clamping blocks 52 are extruded and pushed to move outwards along the radial direction, the springs 54 are stressed and compressed until the supporting blocks of the laser leveling instrument 59 are fully inserted, and at the moment, the clamping blocks 52 move inwards along the radial direction by the elasticity of the springs 54 on the push rods 53, so that the supporting blocks on the laser leveling instrument 59 are clamped and fixed by the movement of the three clamping blocks 52 inwards along the radial direction. The staff starts the laser level 59, makes the laser level 59 emit laser, receives the laser of the laser level 59 through the laser receiving plate 56, and transmits the result to the display 61, and the staff observes the condition of the laser level 59 emitting laser through the display 61, so as to adjust the height or angle of the laser level 59 in time.

When the angle adjustment is required to be performed on the laser level 59, the operator drives the second operation block 38 to rotate, the second operation block 38 rotates to drive the second double-threaded screw rod 37 to rotate, and the second double-threaded screw rod 37 rotates clockwise to be in threaded contact with the two second moving blocks 21 respectively through two external threads with opposite thread directions at the two ends of the second double-threaded screw rod 37, so that the second double-threaded screw rod 37 can drive the two second moving blocks 21 to move in opposite directions simultaneously during the clockwise rotation; the second double-threaded screw rod 37 rotates to drive the two second moving blocks 21 to move in opposite directions, the second moving blocks 21 move in opposite directions and rotate through the two third rotating plates 22, so that the distance between the third fixed frame 20 and the second moving blocks 21 is continuously enlarged, and meanwhile, the second moving blocks 21 move in opposite directions and rotate through the two fourth rotating plates 24, so that the distance between the fourth fixed frame 23 and the second moving blocks 21 is continuously enlarged, and the height of the second lifting assembly 12 is adjusted; the second lifting component 12 is rotationally connected with the first groove 62 through the first rotating block 25 and is rotationally connected with the second rotating shaft 64 and the second rotating block 26 in a matched mode when in height adjustment, so that the workbench 10 is inclined through the height difference between the first lifting component 11 and the second lifting component 12, the inclination angle is precisely adjusted, the use effect of the laser level meter under different angles is detected, and the stability of the laser level meter under different angles can be detected.

When the laser level 59 needs to be adjusted in height, the worker drives the first operating block 29 and the second operating block 38 to rotate at the same time, the first operating block 29 rotates to drive the first double-threaded screw rod 28 to rotate clockwise, and the first double-threaded screw rod 28 rotates clockwise to be in threaded contact with the two first moving blocks 15 through the external threads with opposite thread directions at the two ends of the first double-threaded screw rod 28 respectively, so that the first double-threaded screw rod 28 can drive the two first moving blocks 15 to move in opposite directions at the same time by rotating clockwise; the two first moving blocks 15 move in opposite directions and are rotated by the two first rotating plates 16, so that the distance between the first moving blocks 15 and the first fixed frame 14 is continuously enlarged, and simultaneously the two first moving blocks 15 move in opposite directions and are rotated by the two second fixed frames 17, so that the distance between the first moving blocks 15 and the second fixed frames 17 is continuously enlarged, and the workbench 10 is continuously lifted.

Simultaneously, the second operation block 38 rotates to drive the second double-threaded screw rod 37 to rotate, and the second double-threaded screw rod 37 rotates clockwise to be in threaded contact with the two second moving blocks 21 through two external threads with opposite thread directions at two ends of the second double-threaded screw rod 37, so that the second double-threaded screw rod 37 can drive the two second moving blocks 21 to move in opposite directions simultaneously; the second double-threaded screw rod 37 rotates to drive the two second moving blocks 21 to move in opposite directions, the second moving blocks 21 move in opposite directions and rotate through the two third rotating plates 22, so that the distance between the third fixed frame 20 and the second moving blocks 21 is continuously enlarged, meanwhile, the second moving blocks 21 move in opposite directions and rotate through the two fourth rotating plates 24, so that the distance between the fourth fixed frame 23 and the second moving blocks 21 is continuously enlarged, and the first lifting assembly 11 and the second lifting assembly 12 lift simultaneously, so that the workbench 10 stably lifts and moves.

At this time, the two hydraulic telescopic rods 30 move in opposite directions, the two piston plates 34 are respectively moved in opposite directions by the two push rods 33, the two piston plates 34 move in opposite directions to squeeze the solution in the water tank 32, the solution in the water tank 32 enters the push rods 33 through the first through holes 58, the solution in the push rods 33 enters the hydraulic telescopic rods 30 through the annular pieces 31, and the solution in the hydraulic telescopic rods 30 pushes the hydraulic telescopic rods 30 to extend; the two hydraulic telescopic rods 30 extend to push the second lifting assembly 12 to move, and the second lifting assembly 12 moves to enable the second lifting assembly 12 to slide between the workbench 10 and the bottom plate 36, so that the distance between the first lifting assembly 11 and the second lifting assembly 12 is continuously enlarged, the position supported by the second lifting assembly 12 is changed, the situation that the gravity center is unstable when the workbench 10 is lifted is avoided, and the use of the laser level 59 is prevented from being influenced. The second lifting assembly 12 moves through the second rotating block 26 to slide in the first sliding groove 47 in cooperation with the second rotating shaft to slide in the second sliding groove 48 and the sliding block 27 to slide in the third sliding groove 51, so that the second lifting assembly 12 moves stably between the workbench 10 and the bottom plate 36, and the supporting position of the second lifting assembly 12 is adjusted, so that the higher the lifting height of the workbench 10 is, the smaller the adjusting amplitude is, and the accuracy required by the detection of the laser level 59 can be adjusted conveniently according to the requirement.

When the detection of one side of the laser level 59 is completed, the worker takes the clamping block 46 out of the corresponding clamping groove 43, at the moment, the worker rotates the laser level 59 to enable the circular plate 44 to rotate in the second groove 42, so that the horizontal direction of the laser level 59 is adjusted to facilitate the detection of the other side of the laser level 59, and after the circular plate 44 is rotated and adjusted, the worker inserts the clamping block 46 into the corresponding clamping groove 43, so that the circular plate 44 is limited and fixed in the clamping groove 43 through the clamping block 46; to facilitate detection of the laser level 59 in multiple directions.

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

Claims (7)

1. A detection device for laser level meter, includes workstation, its characterized in that: the lower side of one end of the workbench is provided with a first lifting component, the lower side of the other end of the workbench is provided with a second lifting component, the lower side of the workbench is provided with a bottom plate, two hydraulic telescopic rods are connected between the first lifting component and the second lifting component, the upper side of the bottom plate is fixedly provided with two first telescopic supporting rods, the extending ends of the two first telescopic supporting rods are fixedly provided with a water tank, two piston plates are respectively and slidably arranged on two inner sides of the water tank, two annular pieces are respectively sleeved on the outer sides of the two hydraulic telescopic rods, two push rods are respectively and fixedly connected between the annular pieces and the two piston plates, the upper part of the first lifting component is rotationally connected with the lower side of one end of the workbench, the lower part and the bottom plate fixed connection of first lifting unit, the upper portion and the other end downside of workstation of second lifting unit rotate and sliding connection, the lower part and the bottom plate sliding contact of second lifting unit, the fixed two flexible bracing pieces of second that are equipped with of one end upside of bottom plate, two the fixed laser receiving board that is equipped with of the end that stretches out of flexible bracing piece of second, the upside of bottom plate is equipped with the display, the upper portion of workstation is equipped with the second recess, the rotation is equipped with the plectane in the second recess, the lower part outside cover of plectane is equipped with solid fixed ring, gu fixed ring is in workstation annular slip, one side slip of plectane is equipped with the fixture block, the inside circumference array of second recess is equipped with a plurality of draw-in grooves, the one end and the draw-in groove sliding contact of fixture block.

2. A detection device for a laser level according to claim 1, wherein: every push rod and water tank sliding contact, every the inside of push rod communicates with the inside of ring, every the inside of push rod communicates with the inside of water tank and is equipped with first through-hole, every first through-hole is located the centre of piston plate, every the inside of hydraulic telescoping rod communicates with the inside of ring, every be connected between hydraulic telescoping rod's extension and the fixing base and be equipped with the elastic component, the fixing base of hydraulic telescoping rod is fixed on first movable block, hydraulic telescoping rod's extension and second movable block contact.

3. A detection device for a laser level according to claim 1, wherein: the first lifting assembly comprises a fixed plate, the fixed plate is fixed on the bottom plate, two first fixed frames are fixedly arranged on the upper sides of two ends of the fixed plate respectively, two first movable blocks are arranged above the first fixed frames respectively, two first movable blocks are rotatably connected between the first fixed frames and the two first movable blocks respectively, two second fixed frames are arranged above the first movable blocks respectively, two second movable frames are rotatably connected between the second fixed frames and the two first movable blocks respectively, two first double-threaded screw rods are arranged between the two first movable blocks in a threaded contact mode, one end of each first double-threaded screw rod is fixedly provided with a first operation block, two first movable blocks are fixedly connected between the second fixed frames, the first movable blocks are rotatably connected with the lower side of the workbench, one end lower side of the workbench is provided with a first groove, and a first rotating shaft is rotatably connected between the first groove and the first movable blocks.

4. A detection device for a laser level according to claim 1, wherein: the second lifting assembly comprises a first moving plate, the first moving plate slides on the upper side of a bottom plate, two third fixed frames are respectively and fixedly arranged on the upper sides of two ends of the first moving plate, two second moving blocks are respectively arranged above the third fixed frames, two second moving blocks are respectively and rotatably connected with the two third fixed frames, two third rotating plates are respectively arranged between the second moving blocks and the two third fixed frames, two fourth fixed frames are respectively arranged above the second moving blocks, two fourth fixed frames are respectively and rotatably connected with the two second moving blocks and are provided with two fourth rotating plates, two second double-thread screw rods are arranged between the second moving blocks in a threaded contact mode, one end of each second double-thread screw rod is fixedly provided with a second operating block, two second rotating blocks are fixedly connected between the fourth fixed frames, a first sliding groove is formed in the lower side of the other end of the workbench, the second rotating blocks slide in the first sliding groove, two second sliding grooves are respectively formed in the two sides of the first sliding groove, two second rotating blocks are respectively arranged on the two second sliding grooves, and two second rotating shafts are respectively arranged at the two ends of the second sliding grooves.

5. A detection device for a laser level according to claim 4, wherein: the sliding block is fixedly arranged on the lower side of the first moving plate, four first supporting blocks are fixedly arranged on the lower side of the bottom plate, a third sliding groove is formed in one side of the upper portion of the bottom plate, the sliding block slides in the third sliding groove, and a compression spring is arranged between the sliding block and the third sliding groove.

6. A detection device for a laser level according to claim 1, wherein: the upper side of plectane is fixed and is equipped with places the board, place the board and go up circumference array and be equipped with three second through-hole, three the second through-hole corresponds with the three supporting legs of laser level meter one by one.

7. A detection device for a laser level according to claim 6, wherein: every the inside circumference array of second through-hole slides and is equipped with three push rod, every the fixed clamp splice that is equipped with of one end of push rod, every the other end of push rod is connected between placing the board and is equipped with the spring, every the inboard upper end of clamp splice is inclined plane structure.