CN215677905U - Concrete test block maintenance and compression resistance test system - Google Patents

Abstract

The application relates to a concrete test block maintenance and compression resistance test system which comprises a first conveying device, a maintenance area, a second conveying device, a transfer device and a compression resistance test device; be provided with test block handling device and store the frame in the maintenance district, test block handling device can remove in the maintenance district, be used for carrying the test block to storing on the frame by first conveyor, and can also be with storing on the frame the maintenance completion the test block carry to the second conveyor, utilize transfer device to carry the test block on the second conveyor to the resistance to compression testing device in order to carry out the compression test, in this system, whole working procedure can be accomplished through above-mentioned mechanical equipment is automatic, reduce staff's intensity of labour, the efficiency of experiment has been promoted.

Description

Concrete test block maintenance and compression resistance test system

Technical Field

The utility model relates to the technical field of bridge construction engineering, in particular to a concrete test block maintenance and compression resistance testing system.

Background

As is known, a concrete test block is also called a cubic test block and is used for measuring the compressive strength of concrete, the compressive strength test blocks of the concrete in China all adopt the cubic test blocks to reflect the construction quality of a concrete structure, the compressive strength of the concrete test block is a key index for reflecting the construction quality of engineering concrete, whether a test block manufacturing method and a test block manufacturing program are appropriate or not is important, and at present, a large number of concrete test blocks are required to be maintained and subjected to compressive strength detection every day in a building industry laboratory or a building material detection unit.

When the concrete test block is maintained, workers often carry the gloves to directly carry the concrete test block, and the concrete test block is placed on the maintenance frame in sequence. The test block is not only inconvenient to carry, but also the labor intensity of workers is increased, and the test progress is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a concrete test block maintenance and compression resistance testing system which is used for solving the technical problems in the prior art.

In order to achieve the above purpose of the utility model, the following technical scheme is adopted:

the application provides a concrete test block maintenance and compression resistance test system which comprises a first conveying device, a maintenance area, a second conveying device, a transfer device and a compression resistance test device;

the first conveying device is used for conveying the test blocks to the maintenance area;

the second conveying device is used for conveying the test blocks in the maintenance area to the outside of the maintenance area;

a test block carrying device and a storage rack are arranged in the maintenance area, the test block carrying device can move in the maintenance area and is used for carrying the test block to the storage rack through the first conveying device and carrying the test block on the storage rack to the second conveying device;

the transfer device is used for carrying the test block on the second conveying device to the compression testing device for compression testing.

Further, the test block carrying device comprises a first supporting seat, a vertical supporting frame, a second supporting seat and a carrying mechanism;

the vertical support frame is arranged on the first support seat, the second support seat is connected with the vertical support frame through a lifting moving mechanism so that the second support seat can move vertically, and the carrying mechanism is connected with the upper end of the second support seat through a horizontal moving mechanism so that the carrying mechanism can move horizontally;

transport mechanism includes shell, transport drive arrangement, transmission, dwang and layer board, transport drive arrangement, transmission and a part of dwang is located in the shell, transport drive arrangement with connect through transmission between the dwang, another part of dwang stretches out to the shell is outside, and with the layer board is connected, is used for ordering about the layer board rotates.

Further, the vertical support frame includes first support frame and is located the collateral branch support frame of first support frame both sides, be provided with first rack on the first support frame, lift moving mechanism includes first driving motor and first drive gear, first driving motor installs inside the second supporting seat, first driving motor passes through first drive gear connects first rack, be provided with first guide rail on the collateral branch support frame, the side of second supporting seat is provided with the direction slider, the direction slider with first guide rail cooperation is connected.

Furthermore, horizontal migration mechanism includes two second guide rails, second rack, second driving motor and second drive gear, second guide rail and second rack setting are in the upper end of second supporting seat, second driving motor sets up in the shell, second driving motor passes through second drive gear with the second rack is connected.

Furthermore, still be provided with the third guide rail in the maintenance district, first supporting seat with be connected through first moving mechanism between the third guide rail, so that first supporting seat can move along the length direction of third guide rail.

Further, the first conveying device and the second conveying device adopt a belt conveying structure or a roller conveying structure.

Furthermore, the storage rack is provided with at least one storage rack, and a plurality of storage lattices for placing test blocks are arranged on the storage rack.

Furthermore, the transfer device comprises a first base body, a second base body, a first mechanical arm assembly, a second mechanical arm assembly and a clamping assembly;

the first seat body can rotate horizontally;

the second seat body is arranged on the first seat body;

the first mechanical arm assembly is connected with the second base body and can swing relative to the second base body, a rotating assembly is arranged at the tail end of the first mechanical arm assembly, the second mechanical arm assembly is connected with the rotating assembly, and the tail end of the second mechanical arm assembly is connected with the clamping assembly and used for clamping and carrying the test block.

Furthermore, the compression-resistant testing device comprises a press machine and a pneumatic pushing mechanism;

the press machine is provided with a workbench for placing test blocks, the pneumatic pushing mechanism comprises a pushing support frame, a pushing cylinder and a pushing plate, the pushing cylinder is arranged on the pushing support frame, the pushing plate is connected with a telescopic rod of the pushing cylinder, and the pushing plate is positioned on the workbench.

Further, the device comprises a third conveying device, wherein the third conveying device is positioned at the downstream of the workbench, and an inclined conveying channel is arranged between the third conveying device and the workbench.

Adopt above-mentioned technical scheme, compare in prior art, this application has following beneficial effect:

the concrete test block maintenance and compression resistance test system comprises a first conveying device, a maintenance area, a second conveying device, a transfer device and a compression resistance test device; the first conveying device is used for conveying test blocks into the curing area, the second conveying device is used for conveying the test blocks in the curing area to the outside of the curing area, a test block conveying device and a storage rack are arranged in the curing area, the test block conveying device can move in the curing area and is used for conveying the test blocks to the storage rack from the first conveying device to perform curing of concrete test blocks, the test block conveying device can also convey the cured test blocks on the storage rack to the second conveying device, the test blocks on the second conveying device are conveyed to the compression testing device by the aid of the conveying device to perform compression testing, in the system, the first conveying device plays a role in conveying the test blocks to be cured, the test block conveying device plays a role in conveying the test blocks to be cured and the cured test blocks, the second conveying device plays a role in conveying the cured test blocks, and finally the test blocks are conveyed to the compression testing device by the conveying device to complete compression strength detection, the whole work can be automatically finished through mechanical equipment, the labor intensity of workers is reduced, and the test progress is improved.

Drawings

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

FIG. 1 is a top view of a concrete block curing and compression testing system provided in an embodiment of the present disclosure;

fig. 2 is a schematic perspective view of a concrete test block maintenance and compression resistance testing system provided in an embodiment of the present application;

fig. 3 is a front view of a test block handling apparatus according to an embodiment of the present application;

fig. 4 is a side view of a test block carrying device according to an embodiment of the present application (the third rail is omitted);

FIG. 5 is a schematic structural diagram of a vertical support frame provided in an embodiment of the present application;

FIG. 6 is an enlarged schematic view at A in FIG. 1;

FIG. 7 is an enlarged schematic view at B of FIG. 3;

FIG. 8 is an enlarged schematic view at C of FIG. 4;

FIG. 9 is a schematic structural diagram of a transfer device provided in an embodiment of the present application;

FIG. 10 is an enlarged schematic view at D of FIG. 9;

fig. 11 is a schematic structural diagram of a compression testing apparatus provided in an embodiment of the present application.

Reference numbers: 100-a first conveyor; 110-a second conveyor;

200-maintenance area;

201-test block conveying device; 202-a storage rack; 210-a first support; 220-vertical support frame; 221-a first support frame; 222-side support brackets; 223-a first rack; 224-a first guide rail; 230-a second support seat; 240-a handling mechanism; 241-a housing; 242-transport drive; 243-transmission device; 244-rotating levers; 245-a pallet; 250-a lifting moving mechanism; 251-a first drive motor; 260-horizontal moving mechanism; 261-a second guide rail; 262-a second rack; 263-second drive motor; 264-a second drive gear; 270-a third guide rail; 271-a sliding track; 280-a first movement mechanism; 281-a support base; 282-a third drive motor; 283-a third rack; 284-a roller support assembly; 285-a first roller; 286-a second roller;

300-a transfer device;

310-a first seat body; 311-upper base body; 312-lower base; 313-a rotary drive assembly; 314-a limiting seat; 315-a stop lever; 320-a second seat body; 330-a first robot arm assembly; 331-a first drive assembly; 332-a first robot arm; 340-a second robot arm assembly; 341-a second drive assembly; 342-a second mechanical arm; 343-a third drive assembly; 350-a clamping assembly; 351-a first cylinder; 352-clamping plate; 360 rotating the assembly;

400-compression resistance testing device;

410-a press; 411-a workbench; 420-pushing material supporting frame; 421-material pushing cylinder; 422-a material pushing plate;

500-a third conveyor; 600-conveying channel.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The embodiment of the application provides a concrete test block maintenance and resistance to compression test system can accomplish transportation, maintenance and the compressive strength's of test block test work automatically, compares and adopts artificial mode among the prior art, and intensity of labour reduces by a wide margin, and work efficiency obtains promoting.

Specifically, as shown in fig. 1 to 5, the concrete test block curing and compression testing system in this embodiment includes a first conveying device 100, a curing area 200, a second conveying device 110, a transfer device 300, and a compression testing device 400;

the first conveying device 100 is used for conveying test blocks to be maintained to the maintenance area 200;

the second conveying device 110 is used for conveying the test block which is cured in the curing area 200 to the outside of the curing area 200 for subsequent compression strength test;

a test block carrying device 201 and a storage rack 202 are arranged in the maintenance area 200, the test block carrying device 201 can move in the maintenance area 200 and is used for carrying a test block to be maintained to the storage rack 202 from the first conveying device 100 for maintenance and carrying the test block which is maintained on the storage rack 202 to the second conveying device 110;

the transfer device 300 is used for transferring the cured test block on the second conveyor 110 to the compression testing device 400 for compression testing.

In a preferred embodiment, the first conveying device 100 and the second conveying device 110 may adopt a belt conveying structure or a roller conveying structure, so as to automatically convey the concrete test block, and the belt conveying structure or the roller conveying structure is in the category of conventional technologies, and the structure thereof will not be described in detail in this embodiment.

In a preferred embodiment, as shown in fig. 3 to 5, the test block carrying device 201 includes a first support base 210, a vertical support base 220, a second support base 230 and a carrying mechanism 240;

the vertical support frame 220 is arranged on the first support seat 210, the second support seat 230 is connected with the vertical support frame 220 through the lifting moving mechanism 250, so that the second support seat 230 can move vertically relative to the first support seat 210, and the carrying mechanism 240 is connected with the upper end of the second support seat 230 through the horizontal moving mechanism 260, so that the carrying mechanism 240 can move horizontally relative to the second support seat 230;

specifically, the conveying mechanism 240 includes a housing 241, a conveying driving device 242, a transmission device 243, a rotating rod 244 and a supporting plate 245, wherein the conveying driving device 242, the transmission device 243 and a part of the rotating rod 244 are located in the housing 241, the conveying driving device 242 and the rotating rod 244 are connected through the transmission device 243, the top and the position close to the lower part of the rotating rod 244 are assembled with the housing 241 through a bearing, and the other part (i.e., the lower part) of the rotating rod 244 extends to the outside of the housing 241 and is connected with the supporting plate 245 for driving the supporting plate 245 to rotate. The carrying driving device 242 adopts a motor, the carrying driving device 242 drives the rotating rod 244 to rotate through a rotating device, and then the supporting plate 245 can be driven to rotate, and the supporting plate 245 can be used for bearing the concrete test block.

In a preferred embodiment, the vertical support frame 220 comprises a first support frame 221 and side support frames 222 positioned at both sides of the first support frame 221, a first rack 223 is arranged on the first support frame 221, the first rack 223 extends along the height direction of the first support frame 221, the lifting and moving mechanism 250 comprises a first driving motor 251 and a first driving gear, the first driving motor 251 is installed inside the second support base 230, the first driving motor 251 is connected with the first rack 223 through the first driving gear, so that the first driving motor 251 is communicated with the second support base 230 to move along the height direction of the first support frame 221; in addition, in order to improve the stability of the support, the side support frame 222 is provided with a first guide rail 224, and the side surface of the second support seat 230 is provided with a guide slider, which is connected with the first guide rail 224 in a matching manner, so as to play a role in guiding and improving the stability when the second support seat 230 moves.

In a preferred embodiment, referring to fig. 8, the horizontal movement mechanism 260 includes two second guide rails 261, a second rack 262, a second driving motor 263 and a second driving gear 264, the second guide rails 261 and the second rack 262 are disposed at the upper end of the second support base 230, the second driving motor 263 is disposed in the housing 241 of the carrying mechanism 240, the second driving motor 263 is connected to the second rack 262 through the second driving gear 264, and the bottom of the housing 241 is fittingly connected to the second guide rails 261, so that the carrying mechanism 240 can move in the length direction of the second guide rails 261 relative to the second support base 230.

In a preferred embodiment, the storage rack 202 is provided with two rows, at least one row is provided in each row, and a plurality of storage compartments for storing test blocks are provided on the storage rack 202.

In a preferred embodiment, referring to fig. 1 to 3 and 6, a third rail 270 is further disposed in the maintenance area 200, the third rail 270 is disposed between the two rows of storage racks 202, and the first support base 210 and the third rail 270 are coupled by a first moving mechanism 280, so that the first support base 210 can move along the length direction of the third rail 270.

The first moving mechanism 280 includes a supporting base 281, a third driving motor 282 and a third rack 283, the third driving motor 282 is disposed on the supporting base 281, the upper end of the supporting base 281 is connected with the first supporting seat 210, the third rack 283 is connected with the inner side of the third guiding rail 270, the third driving motor 282 is connected with the third rack 283 through a gear, a plurality of roller supporting assemblies 284 are respectively disposed at both sides of the bottom of the supporting base 281, each roller supporting assembly 284 includes a roller bracket, a first roller 285 and a second roller 286, the roller bracket is connected with the supporting base 281, the first roller 285 and the second roller 286 are respectively connected with the roller bracket through a shaft, and the rotation axis of the first roller 285 is horizontal, the rotation axis of the second roller 286 is vertical, the first roller 285 can roll on the sliding rail 271 at the side of the third guiding rail 270, and the first roller 285 plays a bearing role on the supporting base 281, the second roller 286 abuts against the side surface of the sliding track 271 and can move along the side surface of the sliding track 271, so as to limit the moving direction of the supporting base 281.

In a preferred embodiment, referring to fig. 9 and 10, the transfer device 300 comprises a first base 310, a second base 320, a first robot assembly 330, a second robot assembly 340, and a clamping assembly 350;

the first base 310 can rotate horizontally;

the second seat 320 is arranged on the first seat 310;

the first robot arm assembly 330 is connected to the second base 320, the first robot arm assembly 330 can swing relative to the second base 320, the end of the first robot arm assembly 330 is provided with a rotating assembly 360, the second robot arm assembly 340 is connected to the rotating assembly 360 under the driving of the rotating assembly 360, the second robot arm assembly 340 can swing relative to the first robot arm assembly 330, and the end of the second robot arm assembly 340 is connected to a clamping assembly 350 for clamping and transporting the test block.

The first seat 310 comprises an upper seat 311, a lower seat 312 and a rotary driving component 313, the second seat 320 is connected with the upper seat 311, the upper seat 311 is rotatably arranged on the lower seat 312, the upper seat 311 is connected with the lower seat 312 through a shaft, and the rotary driving component can drive the upper seat 311 to rotate in the horizontal direction by taking the z-axis as a central axis;

the rotation driving assembly 313 includes a motor and a gear transmission mechanism, the gear transmission mechanism has a plurality of gears engaged with each other, wherein one gear is sleeved on the shaft, the inner wall of the upper seat 311 is provided with gear teeth, and the motor drives the upper seat 311 to rotate relative to the lower seat 312 through the gear transmission mechanism.

The first base 310 further includes a first limiting mechanism, the first limiting mechanism includes a limiting seat 314 disposed on one side of the lower base 312 and a limiting rod 315 disposed on the lower side of the first base 310, the limiting rod 315 can be driven by the first base 310 to synchronously rotate, the limiting seat 314 is disposed on the rotation track of the limiting rod 315, two ends of the limiting seat 314 are disposed with arc-shaped accommodating grooves, and are used for limiting the moving position of the limiting rod 315, and further limiting the rotation angle of the first base 310.

The first robot arm assembly 330 includes a first driving assembly 331 and a first robot arm 332, wherein the first driving assembly 331 is disposed on the second base 320 and can drive the first robot arm 332 to rotate about the Y-axis as a central axis;

the rotating assembly 360 includes a motor, a shaft of the motor is rotatably connected to the end of the first arm 332, the motor can rotate relative to the first arm 332, the second arm assembly 340 is connected to the rotating assembly 360, and the second arm assembly 340 can swing relative to the first arm assembly 330 under the driving of the rotating assembly 360.

The second mechanical arm assembly 340 includes a second driving assembly 341 and a second mechanical arm 342, the second driving assembly 341 is disposed on the housing of the rotating assembly 360, the second driving assembly 341 is connected to the second mechanical arm 342 to drive the second mechanical arm 342 to rotate around the X-axis, the second driving assembly 341 includes a motor and a gear transmission mechanism, the motor is connected to the second mechanical arm 342 through the gear transmission mechanism, and the second mechanical arm 342 is driven to rotate around the X-axis.

A third driving assembly 343 is rotatably connected to a distal end portion of the second mechanical arm 342, the third driving assembly 343 may include a dual-axis motor, two rotation axes of the dual-axis motor are connected to the second mechanical arm, and the third driving assembly 343 may rotate about the Y axis;

the clamping assembly 350 includes a first cylinder 351, the first cylinder 351 is a bidirectional cylinder having at least two rods, clamping plates 352 are connected to piston rods on two sides of the first cylinder 351, and the test block is clamped by the clamping plates 352.

In a preferred embodiment, referring to fig. 11, the compression testing apparatus 400 includes a press 410 and a pneumatic pushing mechanism;

the press machine 410 is provided with a workbench 411 for placing test blocks, the pneumatic pushing mechanism comprises a pushing support frame 420, a pushing cylinder 421 and a pushing plate 423, the pushing cylinder 421 is arranged on the pushing support frame 420, the pushing plate 423 is connected with an expansion link of the pushing cylinder 421, and the pushing plate 423 is located on the workbench 411.

A third conveyor 500 is disposed downstream of the work table 411, and an inclined conveyor path 600 is disposed between the third conveyor 500 and the work table 411. The third conveyor 500 has the same structure as the first conveyor 100 and the second conveyor 110, and may have a belt conveyor structure or a roller conveyor structure.

During operation, the transfer device 300 transports the test block to the workbench 411, the press machine 410 is used for pressure testing of the test block, after the test is completed, the material pushing cylinder 421 drives the material pushing plate 423 to move, the test block is moved to the third conveying device 500 through the workbench 411 and the conveying channel, and then the test block is moved to a designated area through the third conveying device 500.

The concrete test block maintenance and resistance to compression test system that this application embodiment provided, whole theory of operation as follows:

conveying the test block to be maintained to the maintenance area 200 by the first conveying device 100;

the test block transporting device 201 can move on the third track, transport the test block to be cured by using the pallet 245, place the test block on the designated storage rack 202 for curing,

when the pressure strength test needs to be performed on the test block after the maintenance, similarly, the test block carrying device 201 moves on the third rail, carries the maintained test block by using the supporting plate 245, and places the test block on the second conveying device 110 for conveying to the transfer area;

the test block is conveyed to a compression testing device 400 through a transfer device 300 to complete compression strength detection;

after the test is completed, the material pushing cylinder 421 drives the material pushing plate 423 to move, so that the test block is moved to the third conveying device 500 through the workbench 411 and the conveying channel, and then moved to the designated area through the third conveying device 500.

Through the concrete test block maintenance and the resistance to compression test system that this embodiment provided, the maintenance of test block, transport and the whole work of resistance to compression test can be accomplished through mechanical equipment is automatic, reduces staff's intensity of labour, has promoted experimental progress.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. A concrete test block maintenance and compression resistance test system is characterized by comprising a first conveying device, a maintenance area, a second conveying device, a transfer device and a compression resistance test device;

the first conveying device is used for conveying the test blocks to the maintenance area;

the second conveying device is used for conveying the test blocks in the maintenance area to the outside of the maintenance area;

a test block carrying device and a storage rack are arranged in the maintenance area, the test block carrying device can move in the maintenance area and is used for carrying the test block to the storage rack through the first conveying device and carrying the test block on the storage rack to the second conveying device;

the transfer device is used for carrying the test block on the second conveying device to the compression testing device for compression testing.

2. The concrete test block maintenance and compression testing system of claim 1, wherein the test block handling device comprises a first support seat, a vertical support frame, a second support seat and a handling mechanism;

the vertical support frame is arranged on the first support seat, the second support seat is connected with the vertical support frame through a lifting moving mechanism so that the second support seat can move vertically, and the carrying mechanism is connected with the upper end of the second support seat through a horizontal moving mechanism so that the carrying mechanism can move horizontally;

transport mechanism includes shell, transport drive arrangement, transmission, dwang and layer board, transport drive arrangement, transmission and a part of dwang is located in the shell, transport drive arrangement with connect through transmission between the dwang, another part of dwang stretches out to the shell is outside, and with the layer board is connected, is used for ordering about the layer board rotates.

3. The system for maintaining and resisting compression of concrete test blocks as claimed in claim 2, wherein the vertical support frame comprises a first support frame and side support frames located at two sides of the first support frame, the first support frame is provided with a first rack, the lifting and moving mechanism comprises a first driving motor and a first driving gear, the first driving motor is installed inside the second support seat, the first driving motor is connected with the first rack through the first driving gear, the side support frames are provided with first guide rails, the side surfaces of the second support seat are provided with guide sliders, and the guide sliders are connected with the first guide rails in a matching manner.

4. The concrete test block curing and pressure-resisting testing system of claim 2, wherein the horizontal moving mechanism comprises two second guide rails, a second rack, a second driving motor and a second driving gear, the second guide rails and the second rack are arranged at the upper end of the second supporting seat, the second driving motor is arranged in the housing, and the second driving motor is connected with the second rack through the second driving gear.

5. The concrete test block curing and pressure-resisting testing system of claim 2, wherein a third guide rail is further arranged in the curing area, and the first supporting seat is connected with the third guide rail through a first moving mechanism, so that the first supporting seat can move along the length direction of the third guide rail.

6. The concrete test block curing and compression testing system of claim 1, wherein the first and second conveying devices are belt-type conveying structures or roller-type conveying structures.

7. The concrete test block curing and pressure-resisting testing system of claim 1, wherein at least one storage rack is arranged, and a plurality of storage lattices for placing test blocks are arranged on the storage rack.

8. The concrete test block curing and pressure-resistant testing system as recited in claim 1, wherein the transfer device comprises a first base, a second base, a first robotic arm assembly, a second robotic arm assembly and a clamping assembly;

the first seat body can rotate horizontally;

the second seat body is arranged on the first seat body;

the first mechanical arm assembly is connected with the second base body and can swing relative to the second base body, a rotating assembly is arranged at the tail end of the first mechanical arm assembly, the second mechanical arm assembly is connected with the rotating assembly, and the tail end of the second mechanical arm assembly is connected with the clamping assembly and used for clamping and carrying the test block.

9. The concrete test block curing and compression testing system of claim 1, wherein the compression testing device comprises a press and a pneumatic pushing mechanism;

the press machine is provided with a workbench for placing test blocks, the pneumatic pushing mechanism comprises a pushing support frame, a pushing cylinder and a pushing plate, the pushing cylinder is arranged on the pushing support frame, the pushing plate is connected with a telescopic rod of the pushing cylinder, and the pushing plate is positioned on the workbench.

10. The concrete test block curing and pressure-resistant testing system according to claim 9, comprising a third conveying device located downstream of the workbench, wherein an inclined conveying channel is provided between the third conveying device and the workbench.

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