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CN-224216485-U - Concrete hardness detection device for building has safeguard function

CN224216485UCN 224216485 UCN224216485 UCN 224216485UCN-224216485-U

Abstract

The utility model relates to the technical field of building material detection and construction safety, and discloses a concrete hardness detection device with a protection function for a building, which comprises the following components: a base; the concrete block hardness testing device comprises a base, a support, a protection component and a detection component, wherein the base is arranged on the base, the protection component is arranged between the base and the support and used for shielding and protecting fragments generated during concrete block detection, and the detection component is arranged on the base and the support and used for detecting the hardness of the concrete block. Through setting up the protection component, conveniently shelter from the fragment that splashes when carrying out intensity detection to the concrete, further realize shelter from the effect of protection to the staff, prevent to be hit by the fragment that splashes and hinder, reduced the potential safety hazard, improved the practicality of equipment, be favorable to actual application and operation.

Inventors

  • XU NIANMING

Assignees

  • 淄博源丰诚新型建材有限公司

Dates

Publication Date
20260508
Application Date
20250527

Claims (6)

  1. 1. A concrete hardness detection device with protection function for building is characterized by comprising: a base (1); the bracket (2) is arranged on the base (1); The protection component (3) is arranged between the base (1) and the bracket (2) and is used for shielding and protecting fragments generated during concrete block detection; The detection assembly (4) is arranged on the base (1) and the bracket (2) and is used for detecting the hardness of the concrete block; the protective assembly (3) comprises: the protective cylinder (301) is arranged between the top of the base (1) and the top of the inner side of the bracket (2); An inlet and outlet groove (309) arranged on the protective cylinder (301); the toughened glass (304) is in sliding fit with the protective cylinder (301); an annular groove (306) which is arranged at the top of the inner side of the bracket (2); a ring gear (308) mounted inside the annular groove (306); the L-shaped rods (305) are equidistantly arranged at the top of the outer side of the toughened glass (304); The gears (307) are in running fit with the L-shaped rods (305), and a plurality of the gears (307) are in meshed connection with the gear ring (308).
  2. 2. The device for detecting the hardness of concrete for construction according to claim 1, wherein the protective assembly (3) further comprises: the annular grooves (302) are formed in the outer side of the protective cylinder (301), and the annular grooves (302) are positioned on two sides of the inlet and outlet grooves (309); The sliding blocks (303) are in sliding fit with the annular grooves (302), and four sliding blocks (303) are fixedly connected with four corners of the inner side of the toughened glass (304).
  3. 3. The device for detecting the hardness of concrete for construction according to claim 1, wherein the detecting assembly (4) comprises: the accommodating cavity (401) is arranged in the base (1); a pressing plate (402), wherein the pressing plate (402) is in sliding fit with the accommodating cavity (401); the connecting rods (403) are equidistantly arranged at the top of the pressing plate (402), and a plurality of the connecting rods (403) are in sliding fit with the base (1); A placement plate (404) mounted between top ends of the plurality of placement plates (404); The springs (405) are sleeved on the outer sides of the connecting rods (403), and the springs (405) are positioned between the base (1) and the placing plate (404); a cylinder (407) mounted on the top of the inside of the bracket (2), and the cylinder (407) is positioned on the inside of the casing (301); A round hammer (408) mounted on a piston rod of the cylinder (407), and the round hammer (408) is positioned above the placement plate (404); the pressure sensors (406) are equidistantly arranged at the bottom of the inner wall of the accommodating cavity (401).
  4. 4. The device for detecting the hardness of concrete for construction according to claim 3, further comprising a clamping assembly (5) provided on the detecting assembly (4), wherein the clamping assembly (5) comprises: a fixed plate (501) which is arranged on the top of the placing plate (404); A screw (502), the screw (502) being in threaded engagement with the fixed plate (501); And clamping plates (503), wherein the clamping plates (503) are in rotating fit with the screw rods (502), and the two clamping plates (503) are in sliding fit with the fixing plate (501).
  5. 5. The device for detecting the hardness of concrete for construction with a protection function according to claim 1, further comprising a monitoring assembly (6) arranged on the bracket (2), wherein the monitoring assembly (6) comprises: The support rod (601) is arranged at the top of the inner wall of the bracket (2), and the support rod (601) is positioned at one side of the air cylinder (407); the camera (602) is arranged at the bottom end of the supporting rod (601).
  6. 6. The device for detecting the hardness of the concrete for the building, which has the protection function, is characterized in that a control panel (7) is fixedly arranged on the outer side of the base (1), and self-locking wheels (8) are fixedly arranged at four corners of the bottom of the base (1).

Description

Concrete hardness detection device for building has safeguard function Technical Field The utility model relates to the technical field of building material detection and construction safety, in particular to a concrete hardness detection device with a protection function for a building. Background Building appliances are a generic term for various tools, devices, machines, etc. used in the construction process of a building. They play an important role in various links of building construction, including but not limited to measurement, cutting, drilling, stirring, transportation, detection, etc., and when the intensity of the building soil is detected, the hardness of the concrete is periodically detected in the building construction process, so that the quality of the concrete is ensured to meet the design requirement, and quality problems are timely found and measures are taken. The defects of the prior art are that in the process of detecting the hardness of the concrete, the concrete body can be crushed, fragments are splashed to staff around the equipment, potential safety hazards can be caused, irrecoverable injuries can occur, the practicability of the equipment is reduced, and the practical application and operation are not facilitated. Disclosure of utility model In order to overcome the defects in the prior art, the utility model provides a device for detecting the hardness of concrete for building, which has a protection function, so as to solve the problems in the prior art. The utility model provides a concrete hardness detection device with a protection function for a building, which comprises the following technical scheme: A base; The bracket is arranged on the base; The protection assembly is arranged between the base and the bracket and is used for shielding and protecting fragments generated during concrete block detection; The detection assembly is arranged on the base and the bracket and is used for detecting the hardness of the concrete block; The guard assembly includes: The protective cylinder is arranged between the top of the base and the top of the inner side of the bracket; the inlet and outlet groove is formed in the protective cylinder; The toughened glass is in sliding fit with the protective cylinder; the annular groove is formed in the top of the inner side of the bracket; The gear ring is arranged in the annular groove; The L-shaped rods are equidistantly arranged at the top of the outer side of the toughened glass; The gears are in running fit with the L-shaped rods, and a plurality of gears are in meshed connection with the gear rings. Preferably, the protection assembly further comprises: The annular grooves are formed in the outer sides of the protective cylinder, and are positioned on two sides of the inlet and outlet grooves; And the sliding blocks are in sliding fit with the annular grooves, and four sliding blocks are fixedly connected with four corners of the inner side of the toughened glass. Preferably, the detection assembly includes: the accommodating cavity is formed in the base; The pressing plate is in sliding fit with the accommodating cavity; the connecting rods are equidistantly arranged at the top of the pressing plate, and a plurality of the connecting rods are in sliding fit with the base; a placing plate installed between top ends of the plurality of placing plates; springs are sleeved on the outer sides of the connecting rods and are positioned between the base and the placing plate; the cylinder is arranged at the top of the inner side of the bracket and is positioned at the inner side of the protective cylinder; The round hammer is arranged on a piston rod of the air cylinder and is positioned above the placing plate; the pressure sensors are equidistantly arranged at the bottom of the inner wall of the cavity. Preferably, still include the clamping assembly that sets up on detecting the subassembly, the clamping assembly includes: The fixing plates are arranged at the top of the placing plate; the screw rod is matched with the fixed plate through threads; and the clamping plates are in running fit with the screw rods, and the two clamping plates are in sliding fit with the fixing plates. Preferably, still including setting up monitoring component on the support, monitoring component includes: The support rod is arranged at the top of the inner wall of the bracket and is positioned at one side of the air cylinder; The camera is installed in the bottom of branch. Preferably, a control panel is fixedly arranged on the outer side of the base, and self-locking wheels are fixedly arranged at four corners of the bottom of the base. The beneficial effects of the utility model are as follows: 1. According to the utility model, the protective component is arranged, so that splashed fragments can be conveniently shielded when the strength of the concrete is detected, the shielding and protecting effect on workers is further realized, the splashed fragments