CN219201111U - Concrete strength detection device - Google Patents

Abstract

The utility model provides a concrete strength detection device, belongs to concrete detection technical field, includes the check out test set main part, still includes control panel, detection mechanism, pushing mechanism and concrete sample, and control panel installs on the outer wall of check out test set main part; the detection mechanism is assembled at the top end of the inner cavity of the detection equipment main body; the pushing mechanism is assembled in the middle of the inner cavity of the detection equipment main body; the number of the concrete samples is multiple, and the concrete samples are respectively placed in the inner cavity of the pushing mechanism; the detection mechanism comprises a screw, a chain wheel, a chain, a first motor, a sliding block, a lifting plate and a pressure sensor. The device can realize the simultaneous detection of a plurality of samples once only, is convenient for realize multiunit data's visual observation and contrast more, when having improved detection efficiency, has made things convenient for staff's observation and record more, can realize detecting the back sample automatic collection clearance moreover, has reduced staff's intensity of labour greatly, and the practicality of equipment is stronger.

Description

Concrete strength detection device

Technical Field

The utility model belongs to the technical field of concrete detection, and particularly relates to a concrete strength detection device.

Background

Concrete is a mixture prepared by mixing cementing materials, granular aggregates, water, chemical additives and mineral admixtures which are required to be added according to a proper proportion, or a composite material with a stacking structure is formed after hardening, and the concrete is widely applied to construction and civil engineering, and the strength of the concrete is critical in view of safety problems, so that the strength of the concrete needs to be detected after the concrete is solidified.

Through retrieving, patent application number is CN202021427692.5, the patent name is "a concrete strength detection device", wherein "a concrete strength detection device" is disclosed, which comprises a machine bod, organism one side top is equipped with the pneumatic cylinder, the pneumatic cylinder bottom passes the organism roof, the output of pneumatic cylinder is equipped with the briquetting, the briquetting bottom is equipped with pressure sensor, organism one side aligns the latter half and is equipped with the guard shield, the organism bottom is equipped with front end bilateral symmetry and is equipped with the gyro wheel, organism bottom surface rear end bilateral symmetry is equipped with the universal wheel, the utility model solves current concrete strength detection device and removes inconveniently, makes the flexibility degree that concrete strength detection device used lower, and current concrete is the problem that the cracked concrete injury people appears easily to appear in the detection pressure simultaneously, through improving and optimizing the structure of concrete strength detection device, makes concrete strength detection device be convenient for remove according to the user demand when using, and this kind of concrete detection device can block the concrete in the in-process that concrete was pressed.

In the existing market, detection comparison is often needed for a plurality of groups of samples so as to avoid inaccurate detection results caused by a single sample, however, in the above patent cases, the detection of a plurality of concrete samples together at one time cannot be realized, the detection steps can only be carried out one by one, the detection speed is slow, and meanwhile, the observation and the recording of various detection data cannot be intuitively carried out; moreover, the concrete sample after detection can be destroyed to different degrees, the collection of the sample after detection is very inconvenient, manual cleaning is needed, the labor intensity of staff is increased, and the maintenance of multiple experiments and experimental equipment is inconvenient.

Disclosure of Invention

Aiming at the problems that the existing detection equipment in the prior art cannot detect a plurality of concrete samples at one time, can only detect one by one, has complicated detection steps, is low in detection speed, cannot intuitively observe and record a plurality of detection data, and the like, the utility model provides the concrete strength detection device. The specific technical scheme is as follows:

the concrete strength detection device comprises a detection equipment main body, a control panel, a detection mechanism, a pushing mechanism and a concrete sample, wherein the control panel is arranged on the outer wall of the detection equipment main body; the detection mechanism is assembled at the top end of the inner cavity of the detection equipment main body; the pushing mechanism is assembled in the middle of the inner cavity of the detection equipment main body; the number of the concrete samples is multiple, and the concrete samples are respectively placed in the inner cavity of the pushing mechanism;

the detection mechanism comprises two screws, a chain wheel, a chain, a first motor, a sliding block, a lifting plate and a pressure sensor, wherein the screws are respectively rotatably arranged at the left side and the right side of the inner wall of the detection equipment main body; the chain wheel is arranged at the top end of the outer wall of the screw rod; the chain is connected to the outer wall of the chain wheel in a meshed manner; the first motor is arranged at the top end of the outer wall of the detection equipment main body, the output end of the first motor is connected with the top end of one screw rod, and the first motor is electrically connected with the control panel; the sliding block is connected to the outer wall of the screw rod in a threaded manner; the lifting plate is arranged on the inner side of the outer wall of the sliding block; the pressure sensors are multiple in number, are respectively installed at the bottom end of the outer wall of the lifting plate, and are electrically connected with the control panel.

In the above technical scheme, the pushing mechanism comprises a shell, a door body, a second motor, a rotary drum, a sliding groove, a sliding ball, a first connecting block and a pushing plate, wherein the shell is arranged at the bottom end of the inner wall of the detection equipment main body, and the concrete samples are respectively placed in the inner cavity of the shell; the door body is rotatably arranged on the front side of the outer wall of the shell; the second motor is arranged at the rear side of the outer wall of the shell and is electrically connected with the control panel; one end of the rotary drum is rotatably arranged on the front side of the inner wall of the shell, and the other end of the rotary drum is connected with the output end of the second motor; the chute is arranged on the circumference of the outer wall of the rotary drum; one side of the sliding ball slides and is embedded in the inner cavity of the sliding groove; the first connecting block is arranged on the other side of the sliding ball; the push plate is arranged on the outer wall of the first connecting block.

In the technical scheme, the sliding grooves are formed in the outer wall of the rotary drum in a head-to-tail communication mode.

In the above technical scheme, the pushing mechanism further comprises a limiting groove, a second connecting block and a roller, wherein the limiting groove is formed in the left side of the inner wall of the shell; one side of the second connecting block is arranged on the left side of the outer wall of the push plate; the roller is arranged on the other side of the second connecting block, and is embedded in the inner cavity of the limiting groove in a sliding manner.

In the technical scheme, the vertical distance of the sliding groove is matched with the width of the inner cavity of the shell.

In the above technical scheme, a plurality of through holes are formed in the top end of the outer wall of the shell, and the number of the through holes corresponds to the number of the pressure sensors.

In the above technical scheme, the concrete strength detection device further comprises a collecting box, wherein the collecting box is embedded in the bottom end of the inner cavity of the detection equipment main body in a sliding manner.

In the technical scheme, the outer wall of the collecting box is provided with a handle.

Compared with the prior art, the concrete strength detection device has the beneficial effects that:

1. through the cooperation of the first motor, the chain wheel, the chain, the screw rod and the sliding block, the lifting plate can be driven to drive the pressure sensor to be close to the concrete sample downwards, so that the simultaneous intensity detection of a plurality of groups of concrete samples is realized, the observation and the record of a plurality of groups of data can be realized simultaneously through the cooperation of the concrete sample, the pressure sensor and the control panel, the device respectively tests the plurality of groups of concrete samples together through the plurality of pressure sensors, the plurality of groups of data are simultaneously displayed at the control panel, the concrete detection speed is improved, the record and the comparison of the plurality of groups of data are more convenient, and the practicability of the device is stronger;

2. through the cooperation of second motor, the rotary drum, the spout, slide ball and first linkage piece, can make the push pedal along the inner chamber of casing forward side remove, can realize the propelling movement to the concrete sample through the push pedal, make the concrete sample drive the door body forward and rotate, can collect the concrete sample that goes out the casing inner chamber to the front removal through the collecting box, the device is convenient for more realize detecting the collection arrangement of back concrete sample through push pedal and collecting box, the manual trouble of clearing up one by one to the concrete sample of having solved the manual work, staff's intensity of labour has been reduced, more do benefit to the multiple experiments and the maintenance of equipment.

In conclusion, the device can realize the simultaneous detection of a plurality of samples once only, is convenient for realize multiunit data's visual observation and contrast more, when having improved detection efficiency, has made things convenient for staff's observation and record more, can realize detecting the back sample automatic collection clearance moreover, has reduced staff's intensity of labour greatly, and the practicality of equipment is stronger.

Drawings

FIG. 1 is a front view of a concrete strength detecting apparatus according to the present utility model;

FIG. 2 is a front view of a chain of a concrete strength testing device of the present utility model;

FIG. 3 is a left side view of a drum of a concrete strength measuring apparatus of the present utility model;

FIG. 4 is an enlarged view of the slide ball of FIG. 2;

fig. 5 is an enlarged view of the roller of fig. 2.

In fig. 1-5, wherein: 1. the detection device comprises a detection device main body, 2, a control panel, 3, a detection mechanism, 31, a screw rod, 32, a chain wheel, 33, a chain, 34, a first motor, 35, a sliding block, 36, a lifting plate, 37, a pressure sensor, 4, a pushing mechanism, 41, a shell, 42, a door body, 43, a second motor, 44, a rotary drum, 45, a sliding groove, 46, a sliding ball, 47, a first connecting block, 48, a push plate, 49, a limit groove, 410, a second connecting block, 411, a roller, 5, a concrete sample, 6 and a collecting box.

Detailed Description

The utility model will be further described with reference to specific embodiments and figures 1-5, but the utility model is not limited to these embodiments.

Example 1

1-5, the concrete strength detection device comprises a detection equipment main body 1, a control panel 2, a detection mechanism 3, a pushing mechanism 4 and a concrete sample 5, wherein the control panel 2 is arranged on the outer wall of the detection equipment main body 1; the detection mechanism 3 is assembled at the top end of the inner cavity of the detection equipment main body 1; the pushing mechanism 4 is assembled in the middle position of the inner cavity of the detection equipment main body 1; the number of the concrete samples 5 is four, and the concrete samples are respectively placed in the inner cavity of the pushing mechanism 4;

the detection mechanism 3 comprises two screws 31, a chain wheel 32, a chain 33, a first motor 34, a sliding block 35, a lifting plate 36 and a pressure sensor 37, wherein the screws 31 are respectively rotatably arranged on the left side and the right side of the inner wall of the detection equipment main body 1 through bearings; the chain wheel 32 is arranged at the top end of the outer wall of the screw 31; the chain 33 is in meshed connection with the outer wall of the chain wheels 32, and when one chain wheel 32 rotates, the chain 33 can be driven to rotate, so that the other chain wheel 32 can be driven to rotate together; the first motor 34 is arranged at the top end of the outer wall of the detection equipment main body 1, the output end of the first motor 34 is connected with the top end of one screw 31 through a coupler, the first motor 34 is electrically connected with the control panel 2, the control panel 2 is operated to control the first motor 34 to be started, the first motor 34 drives the screw 31 connected with the first motor to rotate, and further drives the chain wheel 32 of the outer wall of the first motor to rotate, and the two chain wheels 32 and the two screw 31 rotate together through the chain wheel 32 and the chain 33; the sliding block 35 is in threaded connection with the outer wall of the screw 31, and the rotating screw 31 causes the sliding block 35 to move downwards along the outer wall of the screw 31; the lifting plate 36 is arranged on the inner side of the outer wall of the sliding block 35, and the sliding block 35 which moves downwards drives the lifting plate 36 to descend together; the number of the pressure sensors 37 is four, and the pressure sensors 37 are respectively installed at the bottom end of the outer wall of the lifting plate 36 and are electrically connected with the control panel 2, and the lifting plate 36 which moves downwards drives the pressure sensors 37 to move downwards together.

The pushing mechanism 4 comprises a shell 41, a door body 42, a second motor 43, a rotary drum 44, a sliding groove 45, a sliding ball 46, a first connecting block 47 and a pushing plate 48, wherein the shell 41 is arranged at the bottom end of the inner wall of the detection equipment main body 1, and concrete samples 5 are respectively placed in the inner cavities of the shell 41; the door body 42 is rotatably mounted on the front side of the outer wall of the housing 41 through a pin shaft, and can swing outwards along the rotation connection position when the door body 42 is acted by external force; the second motor 43 is installed at the rear side of the outer wall of the housing 41 and is electrically connected with the control panel 2; one end of the rotary drum 44 is rotatably mounted on the front side of the inner wall of the shell 41 through a bearing, the other end of the rotary drum 44 is connected with the output end of the second motor 43 through a connecting key, the second motor 43 is controlled to be started by the operation control panel 2, and the started second motor 43 drives the rotary drum 44 to rotate; the chute 45 is arranged on the circumference of the outer wall of the rotary drum 44; one side of the sliding ball 46 slides and is embedded in the inner cavity of the sliding groove 45; the first connecting block 47 is installed at the other side of the slide ball 46; the push plate 48 is mounted on the outer wall of the first connecting block 47, the rotating rotary drum 44 drives the sliding ball 46 to move along the inner cavity of the sliding groove 45, and then drives the first connecting block 47 and the push plate 48 to move outwards along the inner wall of the shell 41, so that the push plate 48 is used for pushing the concrete sample 5, and the concrete sample 5 is enabled to be attached to the outer wall of the door body 42 and fall downwards.

The sliding groove 45 is arranged on the outer wall of the rotary drum 44 in a head-to-tail mode, and the sliding ball 46 can reciprocate back and forth through the sliding groove 45 in the head-to-tail mode, so that the first connecting block 47 and the push plate 48 can be reset backwards.

The vertical distance that spout 45 offered is adapted with the inner chamber width of casing 41 to guarantee that the smooth ball 46 that removes along spout 45 can drive first connecting block 47 and push pedal 48 and remove sufficient distance, further guarantee that can drive concrete sample 5 outside under the effect of push pedal 48 and drop.

Four through holes are formed in the top end of the outer wall of the shell 41, and the number of the through holes corresponds to that of the pressure sensors 37, so that the pressure sensors 37 can act on the concrete samples 5 downwards through the through holes formed in the top end of the shell 41.

The concrete strength detection device of the embodiment comprises the following steps:

step one: four concrete samples 5 are respectively placed into the inner cavity of the shell 41, the control panel 2 is operated to control the first motor 34 to be started, the first motor 34 drives the chain wheel 32 connected with the first motor to rotate, then drives the chain 33 on the outer wall of the chain wheel 32 to rotate, drives the other chain wheel 32 to rotate together, simultaneously drives the screw 31 to rotate together by the two rotating chain wheels 32, further drives the sliding block 35 to move downwards along the outer wall of the screw 31, drives the lifting plate 36 and the pressure sensor 37 to move downwards together by the sliding block 35 which moves downwards, and when the pressure sensor 37 moves downwards to a through hole formed in the top end of the shell 41 and contacts with the concrete samples 5 at corresponding positions, the pressure sensor 37 can transmit detection results to the control panel 2, and the control panel 2 is used for displaying final data results of the four groups of detection, so that a worker can observe and record a plurality of groups of data simultaneously by observing the control panel 2;

step two: after the detection is finished, the control panel 2 is operated to control the second motor 43 to be started, the second motor 43 drives the rotary drum 44 to perform circular motion, the rotary drum 44 performing circular motion drives the sliding ball 46 to move along the inner cavity of the sliding groove 45, meanwhile, the first connecting block 47 drives the pushing plate 48 to gradually move forward along the inner wall of the shell 41, the gradually moving pushing plate 48 can push four groups of concrete samples 5, the concrete samples 5 are gradually moved along the inner wall of the shell 41 to be attached to the door body 42, the continuously moving pushing plate 48 and the concrete samples 5 drive the door body 42 to rotate by taking the joint as an axis, and at the moment, the concrete samples 5 can drop downwards under the pushing of the pushing plate 48, so that the concrete samples 5 are collected.

The concrete strength detection device is applied to a construction site concrete sampling detection site in a test mode, the device can realize simultaneous detection of a plurality of samples at one time, visual observation and comparison of a plurality of groups of data are more convenient to realize, detection efficiency is improved, observation and recording of workers are more convenient, automatic collection and cleaning of the detected samples can be realized, labor intensity of the workers is greatly reduced, and the practicability of the equipment is stronger.

Example 2

1-5, the concrete strength detection device comprises a detection equipment main body 1, a control panel 2, a detection mechanism 3, a pushing mechanism 4 and a concrete sample 5, wherein the control panel 2 is arranged on the outer wall of the detection equipment main body 1; the detection mechanism 3 is assembled at the top end of the inner cavity of the detection equipment main body 1; the pushing mechanism 4 is assembled in the middle position of the inner cavity of the detection equipment main body 1; the number of the concrete samples 5 is four, and the concrete samples are respectively placed in the inner cavity of the pushing mechanism 4;

the detection mechanism 3 comprises two screws 31, a chain wheel 32, a chain 33, a first motor 34, a sliding block 35, a lifting plate 36 and a pressure sensor 37, wherein the screws 31 are respectively rotatably arranged on the left side and the right side of the inner wall of the detection equipment main body 1 through bearings; the chain wheel 32 is arranged at the top end of the outer wall of the screw 31; the chain 33 is in meshed connection with the outer wall of the chain wheels 32, and when one chain wheel 32 rotates, the chain 33 can be driven to rotate, so that the other chain wheel 32 can be driven to rotate together; the first motor 34 is arranged at the top end of the outer wall of the detection equipment main body 1, the output end of the first motor 34 is connected with the top end of one screw 31 through a coupler, the first motor 34 is electrically connected with the control panel 2, the control panel 2 is operated to control the first motor 34 to be started, the first motor 34 drives the screw 31 connected with the first motor to rotate, and further drives the chain wheel 32 of the outer wall of the first motor to rotate, and the two chain wheels 32 and the two screw 31 rotate together through the chain wheel 32 and the chain 33; the sliding block 35 is in threaded connection with the outer wall of the screw 31, and the rotating screw 31 causes the sliding block 35 to move downwards along the outer wall of the screw 31; the lifting plate 36 is arranged on the inner side of the outer wall of the sliding block 35, and the sliding block 35 which moves downwards drives the lifting plate 36 to descend together; the number of the pressure sensors 37 is four, and the pressure sensors 37 are respectively installed at the bottom end of the outer wall of the lifting plate 36 and are electrically connected with the control panel 2, and the lifting plate 36 which moves downwards drives the pressure sensors 37 to move downwards together.

The pushing mechanism 4 comprises a shell 41, a door body 42, a second motor 43, a rotary drum 44, a sliding groove 45, a sliding ball 46, a first connecting block 47 and a pushing plate 48, wherein the shell 41 is arranged at the bottom end of the inner wall of the detection equipment main body 1, and concrete samples 5 are respectively placed in the inner cavities of the shell 41; the door body 42 is rotatably mounted on the front side of the outer wall of the housing 41 through a pin shaft, and can swing outwards along the rotation connection position when the door body 42 is acted by external force; the second motor 43 is installed at the rear side of the outer wall of the housing 41 and is electrically connected with the control panel 2; one end of the rotary drum 44 is rotatably mounted on the front side of the inner wall of the shell 41 through a bearing, the other end of the rotary drum 44 is connected with the output end of the second motor 43 through a connecting key, the second motor 43 is controlled to be started by the operation control panel 2, and the started second motor 43 drives the rotary drum 44 to rotate; the chute 45 is arranged on the circumference of the outer wall of the rotary drum 44; one side of the sliding ball 46 slides and is embedded in the inner cavity of the sliding groove 45; the first connecting block 47 is installed at the other side of the slide ball 46; the push plate 48 is mounted on the outer wall of the first connecting block 47, the rotating rotary drum 44 drives the sliding ball 46 to move along the inner cavity of the sliding groove 45, and then drives the first connecting block 47 and the push plate 48 to move outwards along the inner wall of the shell 41, so that the push plate 48 is used for pushing the concrete sample 5, and the concrete sample 5 is enabled to be attached to the outer wall of the door body 42 and fall downwards.

The sliding groove 45 is arranged on the outer wall of the rotary drum 44 in a head-to-tail mode, and the sliding ball 46 can reciprocate back and forth through the sliding groove 45 in the head-to-tail mode, so that the first connecting block 47 and the push plate 48 can be reset backwards.

The pushing mechanism 4 further comprises a limiting groove 49, a second connecting block 410 and a roller 411, wherein the limiting groove 49 is formed in the left side of the inner wall of the shell 41; the second connecting block 410 is installed on the left side of the outer wall of the push plate 48; the roller 411 is mounted on the other side of the second connecting block 410, and is slidably embedded in the inner cavity of the limiting groove 49, when the push plate 48 moves forward, the second connecting block 410 and the roller 411 can be driven to move together, so that the roller is driven to move along the inner cavity of the limiting groove 49, and the moving stability of the push plate 48 is further ensured.

The vertical distance that spout 45 offered is adapted with the inner chamber width of casing 41 to guarantee that the smooth ball 46 that removes along spout 45 can drive first connecting block 47 and push pedal 48 and remove sufficient distance, further guarantee that can drive concrete sample 5 outside under the effect of push pedal 48 and drop.

Four through holes are formed in the top end of the outer wall of the shell 41, and the number of the through holes corresponds to that of the pressure sensors 37, so that the pressure sensors 37 can act on the concrete samples 5 downwards through the through holes formed in the top end of the shell 41.

The utility model provides a concrete strength detection device, still includes collection box 6, and collection box 6 gliding embedded is in the inner chamber bottom of check out test set main part 1, and concrete sample 5 that drops down in the inner chamber of collection box 6, can accomplish the collection to concrete sample 5 from this.

The outer wall of the collecting box 6 is provided with a handle, and the collecting box 6 can be pulled out conveniently through the handle, so that the concrete sample 5 in the inner cavity of the collecting box 6 can be collected later.

The concrete strength detection device of the embodiment comprises the following steps:

step one: four concrete samples 5 are respectively placed into the inner cavity of the shell 41, the control panel 2 is operated to control the first motor 34 to be started, the first motor 34 drives the chain wheel 32 connected with the first motor to rotate, then drives the chain 33 on the outer wall of the chain wheel 32 to rotate, drives the other chain wheel 32 to rotate together, simultaneously drives the screw 31 to rotate together by the two rotating chain wheels 32, further drives the sliding block 35 to move downwards along the outer wall of the screw 31, drives the lifting plate 36 and the pressure sensor 37 to move downwards together by the sliding block 35 which moves downwards, and when the pressure sensor 37 moves downwards to a through hole formed in the top end of the shell 41 and contacts with the concrete samples 5 at corresponding positions, the pressure sensor 37 can transmit detection results to the control panel 2, and the control panel 2 is used for displaying final data results of the four groups of detection, so that a worker can observe and record a plurality of groups of data simultaneously by observing the control panel 2;

step two: after the detection is finished, the control panel 2 is operated to control the second motor 43 to be started, the second motor 43 drives the rotary drum 44 to perform circular motion, the rotary drum 44 performing circular motion drives the sliding ball 46 to move along the inner cavity of the sliding groove 45, meanwhile, the first connecting block 47 drives the pushing plate 48 to gradually move forward along the inner wall of the shell 41, the gradually moving pushing plate 48 can push four groups of concrete samples 5, the concrete samples 5 are gradually moved to be attached to the door body 42 along the inner wall of the shell 41, the continuously moving pushing plate 48 and the concrete samples 5 drive the door body 42 to rotate by taking the connecting part as an axis, at this time, the concrete samples 5 can drop downwards to be collected in the inner cavity of the collecting box 6 under the pushing of the pushing plate 48, the collecting box 6 is pulled outwards manually, and the concrete samples 5 collected in the inner cavity of the collecting box 6 can be uniformly processed.

The concrete strength detection device is applied to a construction site concrete sampling detection site in a test mode, the device can realize simultaneous detection of a plurality of samples at one time, visual observation and comparison of a plurality of groups of data are more convenient to realize, detection efficiency is improved, observation and recording of workers are more convenient, automatic collection and cleaning of the detected samples can be realized, labor intensity of the workers is greatly reduced, and the practicability of the equipment is stronger.

Claims (8)

1. The utility model provides a concrete strength detection device, includes check out test set main part (1), its characterized in that still includes:

a control panel (2) mounted on the outer wall of the detection apparatus main body (1);

the detection mechanism (3) is assembled at the top end of the inner cavity of the detection equipment main body (1);

the pushing mechanism (4) is assembled in the middle of the inner cavity of the detection equipment main body (1);

the number of the concrete samples (5) is multiple, and the concrete samples are respectively placed in the inner cavity of the pushing mechanism (4);

the detection mechanism (3) comprises:

the number of the screws (31) is two, and the screws are respectively rotatably arranged at the left side and the right side of the inner wall of the detection equipment main body (1);

a sprocket (32) mounted on the top end of the outer wall of the screw (31);

a chain (33) engaged and connected to the outer wall of the sprocket (32);

the first motor (34) is arranged at the top end of the outer wall of the detection equipment main body (1), the output end of the first motor is connected with the top end of one screw rod (31), and the first motor (34) is electrically connected with the control panel (2);

the sliding block (35) is in threaded connection with the outer wall of the screw rod (31);

a lifting plate (36) mounted on the inner side of the outer wall of the slider (35);

the pressure sensors (37) are arranged at the bottom end of the outer wall of the lifting plate (36) in a plurality, and are electrically connected with the control panel (2).

2. A concrete strength detection apparatus according to claim 1, characterized in that the pushing mechanism (4) comprises:

the shell (41) is arranged at the bottom end of the inner wall of the detection equipment main body (1), and the concrete samples (5) are respectively placed in the inner cavities of the shell (41);

a door body (42) rotatably installed at the front side of the outer wall of the housing (41);

the second motor (43) is arranged at the rear side of the outer wall of the shell (41) and is electrically connected with the control panel (2);

a rotary drum (44) with one end rotatably mounted on the front side of the inner wall of the housing (41) and the other end connected with the output end of the second motor (43);

a chute (45) arranged on the circumference of the outer wall of the rotary drum (44);

a sliding ball (46) with one side sliding is embedded in the inner cavity of the sliding groove (45);

a first connecting block (47) mounted on the other side of the slide ball (46);

a push plate (48) mounted on the outer wall of the first connecting block (47).

3. A concrete strength detecting device according to claim 2, wherein the chute (45) is formed in the outer wall of the drum (44) in end-to-end communication.

4. A concrete strength detection apparatus according to claim 2, wherein the pushing mechanism (4) further comprises:

a limit groove (49) which is arranged on the left side of the inner wall of the shell (41);

a second connecting block (410), one side of which is arranged on the left side of the outer wall of the push plate (48);

the roller (411) is arranged on the other side of the second connecting block (410) and is embedded in the inner cavity of the limiting groove (49) in a sliding mode.

5. A concrete strength detecting device according to claim 2, wherein the vertical distance of the opening of the chute (45) is adapted to the width of the inner cavity of the housing (41).

6. A concrete strength detecting device according to claim 2, wherein a plurality of through holes are provided at the top end of the outer wall of the housing (41), and the number of through holes corresponds to the number of the pressure sensors (37).

7. A concrete strength detecting device according to claim 1, further comprising a collecting box (6), wherein the collecting box (6) is slidably embedded in the bottom end of the inner cavity of the detecting apparatus body (1).

8. A concrete strength detecting device according to claim 7, characterized in that the outer wall of the collecting box (6) is provided with a handle.

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