CN116296613A - Cement detection sampling device for building supervision - Google Patents

Abstract

The utility model discloses a cement detection sampling device for building supervision, and relates to the technical field of detection sampling equipment. The utility model comprises a device main body, wherein the top surface of the device main body is provided with a belt, the belt is in transmission connection with an output end of an external motor, the inner side of the belt is rotationally connected with a hollow pipe, the bottom of the hollow pipe is fixedly connected with a conical sleeve group, the device also comprises a sampling device, a shielding device, a scraping device and an anti-adhesion device, the sampling device is arranged above the top of the device main body, the shielding device is arranged above the sampling device, the scraping device is arranged below the sampling device, the anti-adhesion device is arranged at the bottom of the device main body, the sampling device comprises an L-shaped rod, and the right side of the L-shaped rod is slidingly arranged on the right side of the inner wall of the hollow pipe. The utility model enables the sampling box to synchronously collect cement samples with different depths, thereby avoiding the occurrence of mixing phenomenon of deep cement and shallow cement.

Description

Cement detection sampling device for building supervision

Technical Field

The utility model relates to the technical field of detection sampling equipment, in particular to a cement detection sampling device for building supervision.

Background

In the daily building construction process, the contractor unit should adopt various specified detection modes and advanced equipment construction quality to detect at each stage of the construction period, so as to ensure the engineering quality and safety, and meanwhile, the supervision unit adopts own equipment to carry out parallel detection, including material equipment entrance acceptance, engineering hidden inspection and the like, so as to provide reference data for judging the engineering quality. The most important part is the sampling of the cement quality.

The utility model with the patent publication number of CN216349709U relates to the technical field of building supervision and discloses

The utility model provides a cement sampling device for building supervision, includes the work box and removes the wheel, fixedly connected with fixed plate on one side inner wall of work box, the top fixedly connected with ball of fixed plate is first, one side fixedly connected with advancing device of fixed plate is kept away from to ball one, advancing device is at one side fixedly connected with sampling device of work box outside, quick-witted case fixed mounting is kept away from on one side inner wall of fixed plate on the work box, the output of cylinder runs through the machine case and extends to the outside and the fly leaf fixed connection of machine case, the one end and the spring fixed connection of fly leaf, the one end and the machine case fixed connection of fly leaf are kept away from to the spring, through setting up a sliding connection in the slide hole on the fly leaf of ball, set up two springs simultaneously, hold the one end of fly leaf, provide two stress points so for the one end that the motor was kept away from to the fly leaf can steady operation.

But the device still exists the not enough at present, and the device just simply goes up the decline through the telescopic link and takes a sample to cement, causes the extravagant phenomenon of cement easily and can not be to the sample of different degree of depth cement for the sampling process efficiency is lower, and stirs cement easily, thereby leads to sample data accuracy to have the deviation, consequently, we propose a cement detection sampling device for building supervision.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a cement detection sampling device for building supervision, which solves the problem that the accuracy of sampling data is deviated in the background art.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: the utility model provides a cement detection sampling device for building supervision, includes the device main part, device main part top surface is provided with the belt, the belt is connected with external motor output transmission, the inboard rotation of belt is connected with the hollow tube, hollow tube bottom fixedly connected with toper cover group, it rotates to drive the belt through external motor output rotation, it rotates to drive the hollow tube when the belt rotates, it rotates to drive toper cover group when the hollow tube rotates, can drive the hollow tube and go deep into the cement depths and take a sample when toper cover group rotates, prevent to be limited in the cement top layer, lead to sample data to have the deviation, still include get sample device, shelter from the device, scrape movable device and antiseize the device, the sample device sets up in device main part top, shelter from the device setting in sample device top, scrape movable device setting in sample device below, the anti-adhesion device is arranged at the bottom of the device main body, the sampling device comprises an L-shaped rod and a sampling box, the right side of the L-shaped rod is slidingly arranged on the right side of the inner wall of the hollow tube, the sampling box is arranged on the left side of the L-shaped rod, the sampling device further comprises a hinging rod and an arc baffle, the top of the hinging rod is hinged on the left side surface of the L-shaped rod, the bottom of the hinging rod is hinged with the top of the right side of the sampling box, the right side of the arc baffle is fixedly arranged on the left side surface of the sampling box, the output end of the electric telescopic rod can prop against the top of the L-shaped rod when being descended, thereby pushing the L-shaped rod to slide downwards along the inner wall of the hollow tube, pushing the hinging rod to translate leftwards when the L-shaped rod translates, pushing the sampling box and the arc baffle to translate leftwards, namely move away from the left side surface of the L-shaped rod, so that the sampling box can synchronously collect cement samples with different depths, thereby avoiding the occurrence of mixing phenomenon of deep cement and shallow cement, and effectively improving the accuracy of cement sample detection.

Preferably, shielding device is including shielding shell and electric telescopic handle, shielding shell bottom fixed mounting is at hollow tube top surface, and shielding shell inner wall is provided with the spout, electric telescopic handle top and shielding shell inner wall top fixed connection, shielding device still includes L shape push pedal, sunshade and slide bar, L shape push pedal top surface and electric telescopic handle bottom fixed connection, sunshade right side top surface is articulated with L shape push pedal bottom, the slide bar runs through and fixed mounting is on the sunshade right side, and slide bar both ends slidable mounting is in shielding shell inner wall spout department, and the sunshade just is located the sample box directly over when left horizontal migration, shields the protection to the cement sample of sample box top, prevents that the cement of upper strata from dropping to the sample box when taking a sample to can guarantee the accurate cement of collecting the different degree of depth of sample box, guarantee the accuracy of testing result.

Preferably, scrape and move the device and include back shape frame, bottom plate, montant and scraper blade, back shape frame top runs through and fixed mounting is in articulated lever center department, bottom plate right side openly center department is run through and fixed mounting is in back shape frame bottom, montant top and bottom plate top fixed surface connection, a plurality of scraper blade right side and bottom plate left side fixed surface connection, scrape and move the device and still include square frame and arc piece, square frame back and the positive fixed connection of sample box, a plurality of arc piece is fixed and equidistant to be distributed in square frame inside openly, and the arc piece is located montant motion trail, and when articulated lever descends, can drive back shape frame top simultaneously and descend, can promote back shape frame bottom and carry out horizontal migration left when back shape frame bottom carries out horizontal migration left, can promote bottom plate and scraper blade simultaneously still can drive the arc piece surface at square frame inside and carry out left sliding to make the sample box can more quick completion collect the cement sample work of different degree of depth, effectual improvement sample time has saved the sample time.

Preferably, the anti-adhesion device comprises a ring plate, an anti-adhesion block and an L-shaped fixing clamp, wherein the inner wall of the ring plate is sleeved at the bottom of the outer wall surface of the hollow tube, the top of the anti-adhesion block is fixedly arranged at the bottom of the ring plate, the inner side of the anti-adhesion block is in contact with the outer wall surface of the hollow tube, a plurality of L-shaped fixing clamps are equidistant and fixedly arranged at the bottom of the device main body, the top surface on the right side of the L-shaped fixing clamp is in contact with the outer edge surface of the bottom of the ring plate, the L-shaped fixing clamp can prevent the ring plate from falling off from the bottom of the device main body due to centrifugal force generated by the hollow tube during rotation, and the anti-adhesion device can be used for a long time; the hollow tube drives the antiseized piece in the annular plate and rotates at the hollow tube outer wall, and the antiseized piece is scraped remaining cement sample on the hollow tube outer wall under the effect of centrifugal force, prevents that long-time cement sample from can causing corrosivity to the hollow tube to shorten the life of hollow tube to and long-time untimely clearance to the cement sample of adhesion, make the cement sample harden, thereby increase later stage clean degree of difficulty.

Preferably, the anti-adhesion device further comprises a spring plate and a knocking ball, the outer side surface of the spring plate is fixedly connected with the inner side surface of the L-shaped fixing clamp, the top surface of the knocking ball is in contact with the bottom surface of the inner edge of the annular plate, a spring is fixedly connected between the bottom of the knocking ball and the top surface of the spring plate, the anti-adhesion block can collide with the bottom of the knocking ball in the continuous rotation process, the spring can continuously shrink and deform through the collision force of the anti-adhesion block and the knocking ball, the spring plate is pushed to slightly bend upwards, the spring and the spring plate can be pulled to deform downwards under the action of gravity of the knocking ball, so that the knocking ball can continuously knock the bottom of the annular plate, the spring plate and the spring are matched, the knocking force is larger, the annular plate vibrates and shakes down a cement sample adhered on the hollow pipe, and the cleaning effect of the hollow pipe is further improved.

The utility model provides a cement detection sampling device for building supervision. The beneficial effects are as follows:

(1) According to the utility model, through the arrangement of the sampling device and the cooperation of the external motor, the belt and the conical sleeve, the hollow pipe can be driven to penetrate deep into cement for sampling when the conical sleeve rotates, so that the sampling data are prevented from being deviated due to limitation to the cement surface layer; through hollow tube, electric telescopic link, L shape pole, sampling box, articulated pole and arc baffle's cooperation for the sampling box can carry out synchronous collection to the cement sample of different degree of depth, thereby avoids causing deep and shallow cement mixing phenomenon to take place, thereby effectually promoted the accuracy that the cement sample detected.

(2) According to the utility model, through the arrangement of the shielding device, through the cooperation of the shielding shell, the electric telescopic rod, the L-shaped push plate, the shielding plate and the sliding rod, the shielding plate cannot deviate and can only horizontally move when horizontally moving leftwards, so that the shielding plate is positioned right above the sampling box when horizontally moving leftwards, the cement sample above the sampling box is shielded and protected, the cement on the upper layer is prevented from falling into the sampling box when the sampling box is used for sampling, the accurate collection of the cement with different depths by the sampling box can be ensured, and the accuracy of the detection result is ensured.

(3) According to the utility model, through the arrangement of the scraping device, through the cooperation of the hinged rod, the square frame, the bottom plate, the scraping plate, the vertical rod, the square frame and the arc block, the bottom plate and the scraping plate can be driven to swing back and forth when the arc block surface inside the square frame slides leftwards, and cement samples with different depths touched by the bottom plate and the scraping plate can be scraped when the bottom plate and the scraping plate swing leftwards and rightwards, so that the sampling box can more quickly finish the collection work of the cement samples with different depths, the sampling efficiency is effectively improved, and the sampling time is saved.

(4) According to the anti-adhesion device, through the arrangement of the L-shaped fixing clamp, the ring plate can be prevented from falling off from the bottom of the device main body by centrifugal force generated when the hollow tube rotates, and the anti-adhesion device can be used for a long time; through the cooperation of the hollow tube, the annular plate, the anti-sticking block, the striking ball, the spring plate and the spring, when the hollow tube is taken out from the cement sample, the anti-sticking block scrapes the residual cement sample on the outer wall of the hollow tube under the action of centrifugal force, so that the long-time corrosion of the cement sample to the hollow tube is prevented, the service life of the hollow tube is shortened, and the adhered cement sample is not cleaned in time for a long time, so that the cement sample is hardened, and the later cleaning difficulty is increased; and the cooperation of spring plate and spring for the dynamics of beating is bigger, thereby makes the annular plate vibration shake off the cement sample of adhesion on the hollow tube, has further improved the clean effect of hollow tube.

Drawings

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

FIG. 2 is a schematic view of the entire bottom view of the present utility model;

FIG. 3 is a schematic view of the overall internal structure of the present utility model;

FIG. 4 is a schematic diagram of a sampling device according to the present utility model;

FIG. 5 is a schematic view of a shielding device according to the present utility model;

FIG. 6 is a schematic view of a scraping device according to the present utility model;

fig. 7 is a schematic view of an anti-adhesion device of the present utility model.

In the figure: 1. a device body; 2. a belt; 21. a hollow tube; 3. sampling the sample device; 31. an L-shaped rod; 32. a sampling box; 33. a hinge rod; 34. an arc baffle; 4. a shielding device; 41. a shielding housing; 42. an electric telescopic rod; 43. an L-shaped push plate; 44. a shutter; 45. a slide bar; 5. a scraping device; 51. a shape-returning frame; 52. a bottom plate; 53. a vertical rod; 54. a scraper; 55. a square frame; 56. an arc block; 6. an anti-adhesion device; 61. a ring plate; 62. an anti-sticking block; 63. an L-shaped fixing clip; 64. a spring plate; 65. striking the ball.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Examples

Referring to fig. 1-5, the present utility model provides a technical solution: the utility model provides a cement detection sampling device for building supervision, including device main part 1, device main part 1 top surface is provided with belt 2, belt 2 and external motor output transmission are connected, belt 2 inboard rotates and is connected with hollow tube 21, hollow tube 21 bottom fixedly connected with toper cover group, it rotates to drive belt 2 through external motor output rotation, drive hollow tube 21 when belt 2 rotates, drive toper cover group rotation when hollow tube 21 rotates, can drive hollow tube 21 and take a sample in the cement depths when toper cover group rotates, prevent to be limited in the cement top layer, lead to sampling data to have the deviation, still include getting sample device 3, shelter from device 4, scrape movable device 5 and antiseized device 6, the setting of sample device 3 is in device main part top 1 top, shelter from device 4 setting is in sample device 3 top, scrape movable device setting in 5 sample device 3 below, the anti-adhesion device 6 is arranged at the bottom of the device main body 1, the sampling device 3 comprises an L-shaped rod 31 and a sampling box 32, the right side of the L-shaped rod 31 is slidingly arranged on the right side of the inner wall of the hollow tube 21, the sampling box 32 is arranged on the left side of the L-shaped rod 31, the sampling device 3 further comprises a hinging rod 33 and an arc baffle 34, the top of the hinging rod 33 is hinged on the left side surface of the L-shaped rod 31, the bottom of the hinging rod 33 is hinged with the right side top of the sampling box 32, the right side of the arc baffle 34 is fixedly arranged on the left side surface of the sampling box 32, the top of the L-shaped rod 31 is propped against when the output end of the electric telescopic rod 42 descends, so that the L-shaped rod 31 is pushed to slide downwards along the inner wall of the hollow tube 21, the hinging rod 33 is pushed to move leftwards when the L-shaped rod 31 slides downwards, the hinging rod 33 is pushed to move leftwards when the hinging rod 33 is translated leftwards, the sampling box 32 and the arc baffle 34 are pushed to move leftwards, namely away from the left side surface of the L-shaped rod 31, the sampling box 32 can synchronously collect cement samples with different depths, so that the phenomenon of mixing deep cement and shallow cement is avoided, and the accuracy of cement sample detection is effectively improved.

The shielding device 4 comprises a shielding shell 41 and an electric telescopic rod 42, wherein the bottom of the shielding shell 41 is fixedly arranged on the top surface of the hollow tube 21, a chute is formed in the inner wall of the shielding shell 41, the top of the electric telescopic rod 42 is fixedly connected with the top of the inner wall of the shielding shell 41, the shielding device 4 further comprises an L-shaped push plate 43, a shielding plate 44 and a sliding rod 45, the top surface of the L-shaped push plate 43 is fixedly connected with the bottom of the electric telescopic rod 42, the right side top surface of the shielding plate 44 is hinged to the bottom of the L-shaped push plate 43, the sliding rod 45 penetrates through and is fixedly arranged on the right side of the shielding plate 44, two ends of the sliding rod 45 are slidably arranged at the chute of the inner wall of the shielding shell 41, the shielding plate 44 is just above the sampling box 32 when moving leftwards, cement samples above the sampling box 32 are shielded and protected, the upper cement is prevented from falling into the sampling box 32 when the sampling box 32, so that the accurate collection of the cement with different depths of the sampling box 32 can be ensured, and the accuracy of the detection results can be ensured.

When the device is used, the belt 2 is driven to rotate through the rotation of the output end of the external motor, the hollow pipe 21 is driven to rotate when the belt 2 rotates, the conical sleeve group is driven to rotate when the hollow pipe 21 rotates, the hollow pipe 21 can be driven to penetrate deep into cement to sample when the conical sleeve group rotates, and the phenomenon that sampling data are limited on the cement surface layer and have deviation is avoided; when hollow tube 21 goes deep into sample cement depths, external motor stops rotating, belt 2, hollow tube 21 and toper cover group stop rotating in step, the sampler starts electric telescopic handle 42, can jack L shape pole 31 top when electric telescopic handle 42 output descends to promote L shape pole 31 and slide downwards along hollow tube 21 inner wall, can promote articulated pole 33 translation left when L shape pole 31 slides downwards, can promote sample box 32 and arc baffle 34 translation left when articulated pole 33 translates, and promptly keep away from L shape pole 31 left side surface direction motion, make sample box 32 can carry out synchronous collection to the cement sample of different depths, thereby avoid causing deep and shallow cement mixing phenomenon to take place, thereby effectually promoted the accuracy that the cement sample detected.

Before the L-shaped rod 31 is pushed to slide downwards, the electric telescopic rod 42 in the shielding shell 41 pushes the L-shaped push plate 43 to move horizontally leftwards, when the L-shaped push plate 43 moves horizontally leftwards, the shielding plate 44 is synchronously pushed to move horizontally leftwards, the shielding plate 44 drives the sliding rod 45 to move horizontally leftwards synchronously, the sliding rod 45 is limited to slide grooves in the shielding shell 41, the sliding rod 45 cannot deviate and can only move horizontally when moving horizontally leftwards, the shielding plate 44 is located right above the sampling box 32 when moving horizontally leftwards, cement samples above the sampling box 32 are shielded and protected, the cement on the upper layer is prevented from falling into the sampling box 32 when the sampling box 32 is used for sampling, the accurate collection of the cement with different depths of sampling can be ensured, and the accuracy of detection results is ensured.

Examples

Referring to fig. 1-7, in this embodiment, based on embodiment 1, the scraping device 5 and the anti-adhesion device 6 are further included

The scraping device 5 comprises a square frame 51, a bottom plate 52, a vertical rod 53 and scraping plates 54, wherein the top of the square frame 51 penetrates through and is fixedly arranged at the center of a hinging rod 33, the right front center of the bottom plate 52 is penetrated through and is fixedly arranged at the bottom of the square frame 51, the top of the vertical rod 53 is fixedly connected with the top surface of the bottom plate 52, the right sides of the scraping plates 54 are fixedly connected with the left side surface of the bottom plate 52, the scraping device 5 further comprises a square frame 55 and arc blocks 56, the back of the square frame 55 is fixedly connected with the front surface of the sampling box 32, the arc blocks 56 are fixedly and equidistantly distributed on the front surface of the inside of the square frame 55, the arc blocks 56 are positioned on the movement track of the vertical rod 53, when the hinging rod 33 descends, the top of the square frame 51 descends synchronously, the bottom of the square frame 51 is pushed to move horizontally leftwards, the bottom of the square frame 51 is pushed to move horizontally when the bottom of the square frame 54 moves horizontally, and simultaneously the vertical rod 52 and the scraping plates 54 are also driven to slide horizontally leftwards, and the arc blocks 56 inside the square frame 55 are driven to slide leftwards, so that the sampling box 32 can complete cement at different depths, the sampling work, and the sampling time is effectively saved.

The anti-adhesion device 6 comprises a ring plate 61, an anti-adhesion block 62 and an L-shaped fixing clamp 63, wherein the inner wall of the ring plate 61 is sleeved at the bottom of the outer wall surface of the hollow tube 21, the top of the anti-adhesion block 62 is fixedly arranged at the bottom of the ring plate 61, the inner side of the anti-adhesion block 62 is in contact with the outer wall surface of the hollow tube 21, a plurality of L-shaped fixing clamps 63 are equidistant and fixedly arranged at the bottom of the device main body 1, the top surface on the right side of the L-shaped fixing clamp 63 is in contact with the outer edge surface of the bottom of the ring plate 61, the L-shaped fixing clamp 63 can prevent the ring plate 61 from falling off from the bottom of the device main body 1 due to centrifugal force generated by the hollow tube 21 during rotation, and the anti-adhesion device 6 can be used for a long time; the hollow tube 21 drives the anti-sticking block 62 in the annular plate 61 to rotate on the outer wall of the hollow tube 21, the anti-sticking block 62 scrapes residual cement samples on the outer wall of the hollow tube 21 under the action of centrifugal force, the long-time cement samples are prevented from corroding the hollow tube 21, the service life of the hollow tube 21 is shortened, and the adhered cement samples are not cleaned timely for a long time, so that the cement samples are hardened, and the later cleaning difficulty is increased.

The anti-adhesion device 6 further comprises a spring plate 64 and a knocking ball 65, the outer side surface of the spring plate 64 is fixedly connected with the inner side surface of the L-shaped fixing clamp 63, the top surface of the knocking ball 65 is in contact with the bottom surface of the inner edge of the annular plate 61, a spring is fixedly connected between the bottom of the knocking ball 65 and the top surface of the spring plate 64, the anti-adhesion block 62 can collide with the bottom of the knocking ball 65 in the continuous rotation process, the spring can continuously shrink and deform through the collision force of the anti-adhesion block 62 and the knocking ball 65, the spring plate 64 is pushed to slightly bend upwards, the spring and the spring plate 64 can be pulled to deform downwards under the action of gravity of the knocking ball 65, the knocking ball 65 can continuously knock the bottom of the annular plate 61, the matching of the spring plate 64 and the spring is enabled to enable the knocking force to be larger, so that the annular plate 61 vibrates and a cement sample adhered on the hollow tube 21 is shaken off, and the cleaning effect of the hollow tube 21 is further improved.

When the hinging rod 33 descends, the top of the square frame 51 is synchronously driven to descend, the bottom of the square frame 51 is pushed to horizontally move leftwards when the top of the square frame 51 descends, the bottom of the square frame 51 is pushed to horizontally move leftwards when horizontally moving leftwards, meanwhile, the vertical rod 53 is driven to horizontally slide leftwards on the surface of the arc block 56 inside the square frame 55, when the vertical rod 53 slides leftwards on the surface of the arc block 56 inside the square frame 55, the bottom plate 52 and the scraping plate 54 are driven to swing forwards and backwards, when the bottom plate 52 and the scraping plate 54 swing leftwards and rightwards, cement samples with different depths are scraped, so that the sampling box 32 can quickly collect cement samples with different depths, the sampling efficiency is effectively improved, and the sampling time is saved.

The L-shaped fixing clamp 63 can prevent the ring plate 61 from falling off from the bottom of the device main body 1 due to the centrifugal force generated when the hollow tube 21 rotates, so that the anti-adhesion device 6 can be used for a long time; after the sampling is finished, when the hollow tube 21 is taken out of the cement samples, the hollow tube 21 is in a rotating state, the hollow tube 21 drives the anti-sticking blocks 62 in the annular plate 61 to rotate on the outer wall of the hollow tube 21, and the anti-sticking blocks 62 scrape the residual cement samples on the outer wall of the hollow tube 21 under the action of centrifugal force, so that the hollow tube 21 is prevented from being corroded by the long-time cement samples, the service life of the hollow tube 21 is shortened, and the adhered cement samples are not cleaned in time for a long time, so that the cement samples are hardened, and the later cleaning difficulty is increased; meanwhile, the anti-sticking block 62 can collide with the bottom of the knocking ball 65 in the continuous rotation process, the spring can continuously shrink and deform upwards through the collision force of the anti-sticking block 62 and the knocking ball 65, so that the top-moving spring plate 64 slightly bends upwards, the spring and the spring plate 64 can be pulled to deform downwards under the action of gravity of the knocking ball 65, the knocking ball 65 can continuously knock the bottom of the annular plate 61, the spring plate 64 is matched with the spring, so that the knocking force is larger, the annular plate 61 vibrates and shakes off cement samples adhered to the hollow pipe 21, and the cleaning effect of the hollow pipe 21 is further improved.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (8)

1. The utility model provides a cement detection sampling device for building supervision, includes device main part (1), device main part (1) top surface is provided with belt (2), belt (2) are connected with external motor output transmission, the inboard rotation of belt (2) is connected with hollow tube (21), hollow tube (21) bottom fixedly connected with toper cover group, its characterized in that: still including getting sample device (3), shielding device (4), scrape and move device (5) and antiseized attached device (6), sample this device (3) set up in device main part top (1) top, shielding device (4) set up in sample this device (3) top, scrape and move the device setting in (5) sample this device (3) below, antiseized attached device (6) set up in device main part (1) bottom, sample this device (3) include L shape pole (31) and sampling box (32), L shape pole (31) right side sliding mounting is on hollow tube (21) inner wall right side, sampling box (32) set up in L shape pole (31) left side.

2. The cement detection sampling device for building supervision according to claim 1, wherein: sample book device (3) still include articulated pole (33) and arc baffle (34), articulated pole (33) top articulates in L shape pole (31) left side surface, and articulated pole (33) bottom and sample box (32) right side top are articulated, arc baffle (34) right side fixed mounting is in sample box (32) left side surface.

3. The cement detection sampling device for building supervision according to claim 1, wherein: the shielding device (4) comprises a shielding shell (41) and an electric telescopic rod (42), wherein the bottom of the shielding shell (41) is fixedly arranged on the top surface of the hollow tube (21), a sliding groove is formed in the inner wall of the shielding shell (41), and the top of the electric telescopic rod (42) is fixedly connected with the top of the inner wall of the shielding shell (41).

4. A cement detection sampling device for building supervision according to claim 3, wherein: the shielding device is characterized in that the shielding device (4) further comprises an L-shaped push plate (43), a shielding plate (44) and a sliding rod (45), the top surface of the L-shaped push plate (43) is fixedly connected with the bottom of the electric telescopic rod (42), the top surface of the right side of the shielding plate (44) is hinged to the bottom of the L-shaped push plate (43), the sliding rod (45) penetrates through and is fixedly mounted on the right side of the shielding plate (44), and two ends of the sliding rod (45) are slidably mounted at the sliding grooves of the inner wall of the shielding shell (41).

5. A cement detection sampling device for building supervision according to claim 2, wherein: the scraping device (5) comprises a square frame (51), a bottom plate (52), a vertical rod (53) and a scraping plate (54), wherein the top of the square frame (51) penetrates through and is fixedly installed at the center of a hinging rod (33), the center of the right front of the bottom plate (52) is penetrated through and is fixedly installed at the bottom of the square frame (51), the top of the vertical rod (53) is fixedly connected with the top surface of the bottom plate (52), and a plurality of scraping plates (54) are fixedly connected with the left surface of the bottom plate (52).

6. The cement detection sampling device for building supervision according to claim 1, wherein: the scraping device (5) further comprises a square frame (55) and arc blocks (56), the back of the square frame (55) is fixedly connected with the front of the sampling box (32), a plurality of the arc blocks (56) are fixedly and equidistantly distributed on the front of the inside of the square frame (55), and the arc blocks (56) are located on the movement track of the vertical rod (53).

7. The cement detection sampling device for building supervision according to claim 1, wherein: the anti-adhesion device (6) comprises a ring plate (61), anti-adhesion blocks (62) and L-shaped fixing clamps (63), wherein the inner wall of the ring plate (61) is sleeved at the bottom of the outer wall surface of the hollow tube (21), the top of each anti-adhesion block (62) is fixedly arranged at the bottom of the ring plate (61), the inner side of each anti-adhesion block (62) is in contact with the outer wall surface of the hollow tube (21), a plurality of L-shaped fixing clamps (63) are equidistant and fixedly arranged at the bottom of the device main body (1), and the top surface on the right side of each L-shaped fixing clamp (63) is in contact with the outer edge surface of the bottom of the ring plate (61).

8. The cement detection sampling device for building supervision according to claim 7, wherein: the anti-adhesion device (6) further comprises a spring plate (64) and a knocking ball (65), the outer side surface of the spring plate (64) is fixedly connected with the inner side surface of the L-shaped fixing clamp (63), the top surface of the knocking ball (65) is in contact with the bottom surface of the inner edge of the annular plate (61), and a spring is fixedly connected between the bottom of the knocking ball (65) and the top surface of the spring plate (64).

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