CN219914939U - Sampling equipment for quality detection is built in room - Google Patents

Abstract

The utility model relates to the technical field of building construction, in particular to sampling equipment for detecting the quality of a building construction, which comprises a sampling vehicle, a sampling assembly, a placement assembly and a knocking assembly, wherein four movable wheels are arranged at the bottom of the sampling vehicle, a sampling groove is arranged at the center of the sampling vehicle, the sampling assembly is arranged at the top of the sampling vehicle, the placement assembly and the knocking assembly are arranged at the top of the sampling vehicle at intervals, the sampling assembly comprises a portal frame, a lifting frame, a hydraulic push rod, a sampling part, two guide rods and two guide blocks, two sides of the lifting frame are respectively connected with the two guide blocks, the hydraulic push rod is vertically arranged at the top of the portal frame, the output end of the hydraulic push rod is connected with the lifting frame, and the sampling part is arranged on the lifting frame.

Description

Sampling equipment for quality detection is built in room

Technical Field

The utility model relates to the technical field of house construction, in particular to sampling equipment for house construction quality detection.

Background

In the building construction, related detection is required to be carried out on materials, structural accessories and the like of the construction engineering, so that the actual quality, the use function and the like of the engineering can be better judged, the safety of the engineering can be better ensured, concrete is poured in the building construction, and the concrete detection is an important guarantee in the building construction.

The existing concrete sampling equipment generally needs to manually knock the drill core to knock out the sampled concrete after drilling and sampling the concrete, and the drill core needs to be manually and repeatedly knocked during multiple sampling operations, which is very troublesome.

Disclosure of Invention

The utility model aims to provide sampling equipment for detecting the quality of a house building, which aims to solve the problem that in the background technology, concrete sampled in the drilling core needs to be knocked out by manually knocking the drilling core, and the drilling core needs to be knocked repeatedly by manually in the process of multiple sampling operations, so that the problem is very troublesome.

The technical scheme of the utility model is as follows:

the utility model provides a quality test is built with sampling equipment in room, includes the sample car, sampling subassembly, places the subassembly and beats the subassembly, the bottom of sample car is equipped with four and removes the wheel, the center department of sample car is equipped with the sampling groove, sampling subassembly installs the top at the sample car, place the subassembly and beat the subassembly interval and set up the top at the sample car, sampling subassembly includes portal frame, lifting frame, hydraulic putter, sampling part, two guide bars and two guide blocks, the portal frame sets up the top at the sample car, two the guide bar symmetry sets up the top at the sample car to the top and the portal frame of two guide bars are connected, two guide blocks slidable mounting respectively are on two guide bars, the both sides of lifting frame are connected with two guide blocks respectively, the vertical top at the portal frame that sets up of hydraulic putter to hydraulic putter's output is connected with the lifting frame, sampling part installs on the lifting frame.

Further, the sampling part comprises a rotating shaft, a drill core sleeve, a rotating motor, a driving gear and a driven gear, wherein the rotating shaft is rotatably arranged at the bottom end of the lifting frame, the drill core sleeve is vertically arranged at the bottom end of the rotating shaft, the drill core sleeve is located above the sampling groove, the rotating motor is vertically arranged in the lifting frame, the driving gear is arranged on an output shaft of the rotating motor, and the driven gear is arranged at the top end of the rotating shaft and meshed with the driving gear.

Further, place the subassembly and include mobile station, first lead screw slip table, movable plate, rotation axis, rotary disk, rotating electrical machines, first gear, second gear and two sliding tray, two the sliding tray symmetry is seted up at the top of sampling car, mobile station slidable mounting is on two sliding tray, first lead screw slip table level sets up at the top of sampling car, the movable plate is installed on the mobile terminal of first lead screw slip table to the movable plate is connected with the mobile station, the rotation axis rotates the top center department of installing at the mobile station, the top at the rotation axis is installed to the rotary disk, the top of rotary disk is equipped with a plurality of and sets up around its centre of a circle equidistant a section of thick bamboo of placing, the vertical setting of rotating electrical machines is at the top of mobile station, first gear is installed on the output shaft of rotating electrical machines, the second gear is installed on the rotation axis to second gear and first gear engagement.

Further, strike the subassembly and include carrier, L type frame, second lead screw slip table, linkage board, strike part and two guide rails, two the guide rail symmetry sets up the top at the sampling car, carrier slidable mounting is on two guide rails, L type frame is installed at the top of carrier, second lead screw slip table level sets up the top at the sampling car, the linkage board is installed on the mobile terminal of second lead screw slip table to the linkage board is connected with the carrier, strike the part and install on L type frame.

Further, strike the part and include and strike post, installation piece, mount pad, gyro wheel, strike piece, drive seat, drive shaft, cam, driving motor and spring, strike post slidable mounting and be connected at the top of L type frame, the installation piece sets up the tail end at striking the post, the mount pad sets up on the outer wall of mount pad, the gyro wheel rotates and installs in the mount pad, strike the head end that the piece was installed at the post of beating, the drive seat is installed on L type frame, the drive shaft rotates and installs in the drive seat, the cam is installed in the drive shaft to the one end and the gyro wheel conflict of cam, the spring housing is established in the outside of beating the post to the both ends of spring are connected with L type frame and installation piece respectively, driving motor level sets up on the outer wall of drive seat, and driving motor's output shaft and drive shaft connection.

Further, a rubber cushion is arranged on the knocking block.

The utility model provides sampling equipment for detecting the quality of a building through improvement, which has the following improvement and advantages compared with the prior art:

the method comprises the following steps: according to the concrete sampling device, the sampling trolley moves to drive the sampling groove to move to a concrete sampling position, then the hydraulic push rod works to drive the lifting frame to move downwards, the lifting frame drives the sampling component to move downwards, the sampling component works to drill and sample concrete, the hydraulic push rod continues to work to drive the lifting frame to move upwards for resetting after sampling, then the placing component works to move to the lower part of the sampling component, finally the knocking component works to knock the sampling component, dropped concrete samples after knocking fall into the placing component to be collected, the placing component and the knocking component cooperate to continuously collect the concrete samples during multiple sampling operations, the manual knocking is not needed, the automation degree is high, and the use is convenient.

And two,: when the drill core sleeve is used for continuously sampling concrete, the rotating motor works to drive the first gear to rotate, the first gear drives the rotating shaft and the rotating disc to rotate by utilizing the second gear, and the rotating disc drives the other placing cylinder to rotate below the drill core sleeve, so that a plurality of placing cylinders can conveniently collect a plurality of concrete samples.

Drawings

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

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic perspective view of a second embodiment of the present utility model;

FIG. 3 is a schematic perspective view of a third embodiment of the present utility model;

FIG. 4 is a schematic perspective view of a rapping assembly of the present utility model;

fig. 5 is a schematic perspective view of a knocking assembly according to a second embodiment of the present utility model.

Reference numerals illustrate:

sampling carriage 1, sampling tank 11, sampling unit 2, gantry 21, lifting frame 22, hydraulic ram 23, sampling unit 24, rotation shaft 241, drill core sleeve 242, rotation motor 243, driving gear 244, driven gear 245, guide bar 25, guide block 26, placement unit 3, moving table 31, first screw slide 32, moving plate 33, rotation shaft 34, rotating disk 35, placement cylinder 351, rotating motor 36, first gear 37, second gear 38, sliding groove 39, knocking unit 4, carriage 41, l-shaped frame 42, second screw slide 43, linkage plate 44, knocking unit 45, knocking column 451, mounting block 452, mounting block 453, roller 454, knocking block 455, rubber cushion 4551, driving seat 456, driving shaft 457, cam 458, driving motor 459, spring 4591, guide rail 46, and moving wheel 5.

Detailed Description

The following detailed description of the present utility model clearly and fully describes the technical solutions of the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides sampling equipment for detecting house construction quality through improvement, as shown in fig. 1-5, the sampling equipment comprises a sampling car 1, a sampling assembly 2, a placement assembly 3 and a knocking assembly 4, wherein four moving wheels 5 are arranged at the bottom of the sampling car 1, a sampling groove 11 is arranged at the center of the sampling car 1, the sampling assembly 2 is arranged at the top of the sampling car 1, the placement assembly 3 and the knocking assembly 4 are arranged at the top of the sampling car 1 at intervals, the sampling assembly 2 comprises a portal frame 21, a lifting frame 22, a hydraulic push rod 23, a sampling part 24, two guide rods 25 and two guide blocks 26, the portal frame 21 is arranged at the top of the sampling car 1, the two guide rods 25 are symmetrically arranged at the top of the sampling car 1, the top ends of the two guide rods 25 are connected with the portal frame 21, the two guide blocks 26 are respectively and slidably arranged on the two guide rods 25, the two sides of the lifting frame 22 are respectively connected with the two guide blocks 26, the hydraulic push rod 23 is vertically arranged at the top of the portal frame 21, and the output end of the push rod 23 is connected with the lifting frame 24 by the lifting frame 24; the hydraulic pushing rod 23 works to drive the lifting frame 22 to move downwards, the lifting frame 22 drives the sampling component 24 to move downwards, the sampling component 24 works to drill and sample concrete, the hydraulic pushing rod 23 continues to work to drive the lifting frame 22 to move upwards to reset after sampling, the placing component 3 works to move to the lower part of the sampling component 24, the knocking component 4 works to knock the sampling component 24, the dropped concrete sample after knocking falls into the placing component 3 to be collected, the placing component 3 and the knocking component 4 cooperate to continuously collect the concrete sample during multiple sampling operation, the manual knocking is not needed, the degree of automation is high, and the use is convenient.

Specifically, the sampling component 24 includes a rotation shaft 241, a core sleeve 242, a rotation motor 243, a driving gear 244 and a driven gear 245, the rotation shaft 241 is rotatably installed at the bottom end of the lifting frame 22, the core sleeve 242 is vertically disposed at the bottom end of the rotation shaft 241, and the core sleeve 242 is located above the sampling slot 11, the rotation motor 243 is vertically disposed in the lifting frame 22, the driving gear 244 is installed on the output shaft of the rotation motor 243, the driven gear 245 is installed at the top end of the rotation shaft 241, and the driven gear 245 is meshed with the driving gear 244; the hydraulic push rod 23 works to drive the core sleeve 242 to move downwards, the core sleeve 242 moves downwards, the rotating motor 243 works to drive the driving gear 244 to rotate, the driving gear 244 drives the rotating shaft 241 and the core sleeve 242 to rotate by utilizing the driven gear 245, and the core sleeve 242 rotates to drill and sample concrete.

Specifically, the placement component 3 includes a moving table 31, a first screw sliding table 32, a moving plate 33, a rotating shaft 34, a rotating disc 35, a rotating motor 36, a first gear 37, a second gear 38 and two sliding grooves 39, wherein the two sliding grooves 39 are symmetrically arranged at the top of the sampling vehicle 1, the moving table 31 is slidably mounted on the two sliding grooves 39, the first screw sliding table 32 is horizontally arranged at the top of the sampling vehicle 1, the moving plate 33 is mounted on the moving end of the first screw sliding table 32, the moving plate 33 is connected with the moving table 31, the rotating shaft 34 is rotatably mounted at the center of the top of the moving table 31, the rotating disc 35 is mounted at the top of the rotating shaft 34, the top of the rotating disc 35 is provided with a plurality of placement drums 351 which are arranged at equal intervals around the center of the circle, the rotating motor 36 is vertically arranged at the top of the moving table 31, the first gear 37 is mounted on the output shaft of the rotating motor 36, the second gear 38 is mounted on the rotating shaft 34, and the second gear 38 is meshed with the first gear 37; when the core sleeve 242 moves upwards and resets, the first screw sliding table 32 works to drive the moving plate 33 and the moving table 31 to move, the moving table 31 drives the rotating disk 35 to move, the rotating disk 35 drives one of the placing cylinders 351 to move to the lower side of the core sleeve 242, then the knocking component 4 works to knock the core sleeve 242, concrete samples falling after knocking fall into the placing cylinder 351 to be collected, and when the core sleeve 242 continuously samples concrete, the rotating motor 36 works to drive the first gear 37 to rotate, the first gear 37 drives the rotating shaft 34 and the rotating disk 35 to rotate by utilizing the second gear 38, the rotating disk 35 drives the other placing cylinder 351 to rotate to the lower side of the core sleeve 242, and a plurality of placing cylinders 351 are convenient to collect a plurality of concrete samples.

Specifically, the knocking assembly 4 includes a carrying frame 41, an L-shaped frame 42, a second screw sliding table 43, a linkage plate 44, a knocking component 45, and two guide rails 46, where the two guide rails 46 are symmetrically disposed at the top of the sampling carriage 1, the carrying frame 41 is slidably mounted on the two guide rails 46, the L-shaped frame 42 is mounted at the top of the carrying frame 41, the second screw sliding table 43 is horizontally disposed at the top of the sampling carriage 1, the linkage plate 44 is mounted on a moving end of the second screw sliding table 43, and the linkage plate 44 is connected with the carrying frame 41, and the knocking component 45 is mounted on the L-shaped frame 42; the linkage plate 44 and the bearing frame 41 are driven to move through the operation of the second screw rod sliding table 43, the bearing frame 41 drives the knocking component 45 to move to be close to the drill core sleeve 242, then the knocking component 45 works to repeatedly knock the drill core sleeve 242, and concrete samples in the drill core sleeve 242 fall into the placing barrel 351 to be collected after knocking.

Specifically, the knocking component 45 includes a knocking column 451, a mounting block 452, a mounting seat 453, a roller 454, a knocking block 455, a driving seat 456, a driving shaft 457, a cam 458, a driving motor 459 and a spring 4591, the knocking column 451 is slidably mounted at the top end of the L-shaped frame 42, the mounting block 452 is disposed at the tail end of the knocking column 451, the mounting seat 453 is disposed on the outer wall of the mounting block 452, the roller 454 is rotatably mounted in the mounting seat 453, the knocking block 455 is mounted at the head end of the knocking column 451, the driving seat 456 is mounted on the L-shaped frame 42, the driving shaft 457 is rotatably mounted in the driving seat 456, the cam 458 is mounted on the driving shaft 457, and one end of the cam 458 abuts against the roller 454, the spring 4591 is sleeved outside the knocking column 451, and both ends of the spring 4591 are respectively connected with the L-shaped frame 42 and the mounting block 452, the driving motor 459 is horizontally disposed on the outer wall of the driving seat 456, and the output shaft of the driving motor 459 is connected with the driving shaft 457; the driving motor 459 is used for driving the driving shaft 457 and the cam 458 to rotate, the cam 458 drives the knocking column 451 to reciprocate within a certain range by utilizing the roller 454, and the knocking column 451 drives the knocking block 455 to reciprocate within a certain range to repeatedly knock the drill core sleeve 242 without repeatedly knocking the drill core sleeve 242.

Specifically, the knocking block 455 is provided with a rubber cushion 4551; the rubber cushion 4551 prevents the tap block 455 from striking the core sleeve 242.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. Sampling equipment for quality detection is built in room, its characterized in that: including sample car (1), sample subassembly (2), place subassembly (3) and strike subassembly (4), the bottom of sample car (1) is equipped with four removal wheels (5), the center department of sample car (1) is equipped with sample groove (11), the top at sample car (1) is installed in sample subassembly (2), place subassembly (3) and strike subassembly (4) interval setting at the top of sample car (1), sample subassembly (2) include portal frame (21), lifting frame (22), hydraulic push rod (23), sampling part (24), two guide bars (25) and two guide blocks (26), portal frame (21) erect at the top of sample car (1), two guide bars (25) symmetry sets up at the top of sample car (1) to the top and portal frame (21) of two guide bars (25) are connected, and two guide blocks (26) are slidable mounting respectively on two guide bars (25), the both sides of lifting frame (22) are connected with two guide blocks (26) respectively, hydraulic push rod (23) are connected at the lifting frame (23) and are connected with lifting frame (23), the sampling component (24) is arranged on the lifting frame (22).

2. The sampling device for detecting the quality of a building according to claim 1, wherein: the sampling component (24) comprises a rotating shaft (241), a core sleeve (242), a rotating motor (243), a driving gear (244) and a driven gear (245), wherein the rotating shaft (241) is rotatably arranged at the bottom end of the lifting frame (22), the core sleeve (242) is vertically arranged at the bottom end of the rotating shaft (241), the core sleeve (242) is located above the sampling groove (11), the rotating motor (243) is vertically arranged in the lifting frame (22), the driving gear (244) is arranged on an output shaft of the rotating motor (243), the driven gear (245) is arranged at the top end of the rotating shaft (241), and the driven gear (245) is meshed with the driving gear (244).

3. The sampling device for detecting the quality of a building according to claim 1, wherein: the utility model provides a place subassembly (3) including mobile station (31), first lead screw slip table (32), movable plate (33), rotation axis (34), rotary disk (35), rotating electrical machines (36), first gear (37), second gear (38) and two sliding tray (39), two sliding tray (39) symmetry are seted up at the top of sample car (1), mobile station (31) slidable mounting is on two sliding tray (39), first lead screw slip table (32) level sets up at the top of sample car (1), movable plate (33) are installed on the mobile end of first lead screw slip table (32) to movable plate (33) are connected with mobile station (31), rotation axis (34) are rotated and are installed in the top center department of mobile station (31), the top of rotary disk (35) is installed at the top of rotation axis (34), the top of rotary disk (35) is equipped with a plurality of around its equidistant section of thick bamboo (351) of placing of setting, rotary electrical machines (36) vertical setting is at the top of mobile station (31), first gear (37) are installed on the output shaft (37) and second gear (38) are installed on second gear (38).

4. The sampling device for detecting the quality of a building according to claim 1, wherein: the utility model provides a strike subassembly (4) including bearing frame (41), L type frame (42), second lead screw slip table (43), linkage board (44), strike part (45) and two guide rails (46), two guide rails (46) symmetry set up the top at sample car (1), bearing frame (41) slidable mounting is on two guide rails (46), the top at bearing frame (41) is installed to L type frame (42), second lead screw slip table (43) level sets up the top at sample car (1), the linkage board (44) are installed on the mobile end of second lead screw slip table (43) to linkage board (44) are connected with bearing frame (41), strike part (45) and install on L type frame (42).

5. The sampling device for detecting the quality of a building according to claim 4, wherein: the knocking component (45) comprises a knocking column (451), a mounting block (452), a mounting seat (453), a roller (454), a knocking block (455), a driving seat (456), a driving shaft (457), a cam (458), a driving motor (459) and a spring (4591), the knocking post (451) is slidably mounted on the top end of the L-shaped frame (42), the mounting block (452) is arranged at the tail end of the knocking post (451), the mounting seat (453) is arranged on the outer wall of the mounting block (452), the roller (454) is rotatably arranged in the mounting seat (453), the knocking block (455) is arranged at the head end of the knocking column (451), the driving seat (456) is arranged on the L-shaped frame (42), the driving shaft (457) is rotatably arranged in the driving seat (456), the cam (458) is arranged on the driving shaft (457), and one end of the cam (458) is abutted against the roller (454), the spring (4591) is sleeved outside the knocking column (451), and the two ends of the spring (4591) are respectively connected with the L-shaped frame (42) and the mounting block (452), the driving motor (459) is horizontally arranged on the outer wall of the driving seat (456), and an output shaft of the driving motor (459) is connected with the driving shaft (457).

6. The sampling device for detecting the quality of a building according to claim 5, wherein: a rubber cushion (4551) is arranged on the knocking block (455).