CN219915183U - Self preservation temperature building block intensity testing arrangement - Google Patents

Abstract

The utility model discloses a self-heat-preservation building block strength testing device which comprises a frame, a conveying belt and a positioning detection mechanism, wherein the conveying belt extends to one side of the outer part of the conveying belt from the inside of the frame, a lifting cylinder is arranged at the upper part of the frame, the positioning detection mechanism is arranged on a piston rod of the lifting cylinder, and the positioning detection mechanism comprises a detection frame and a positioning mechanism.

Description

Self preservation temperature building block intensity testing arrangement

Technical Field

The utility model relates to the field of building material detection equipment, in particular to a self-heat-preservation building block strength testing device.

Background

The self-insulating building block is one new kind of building material and is used mainly in building wall in frame structure. Although self-insulating blocks in buildings are not load-bearing, their outer cement layers need to have a certain strength to meet the stability of the attachments thereon in use. At present, the self-heat-preservation building block adopts industrial batch production, the strength detection is carried out in a batch sampling detection mode, the manual detection is mainly carried out by using a multifunctional concrete strength detector, the positioning of main detection points is inaccurate and the efficiency is low during the manual detection, the detection error can be generated due to uneven pressing force during the test, and the self-heat-preservation building block strength testing device is provided for the purpose.

Disclosure of Invention

The utility model aims to provide a self-heat-preservation building block strength testing device which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a self preservation temperature building block intensity testing arrangement, includes frame, conveyer belt and location detection mechanism, the conveyer belt extends to its one side from the inside of frame, the upper portion of frame is provided with lift cylinder, location detection mechanism sets up on the piston rod of lift cylinder, location detection mechanism includes detection frame and positioning mechanism, the detection frame includes the support body, positioning mechanism sets up in the lower part of support body, be provided with screw rod, detection slide bar and servo motor on the support body, servo motor's output shaft is connected with the screw rod, be provided with the detection extension board between the two of the mutual parallel arrangement of screw rod and detection slide bar, the one end and the screw rod threaded connection of detection extension board, the other end and detection slide bar sliding connection, be provided with probe sliding sleeve and sideslip cylinder on the detection extension board, the cylinder body and the detection extension board fixed connection of sideslip cylinder, the vertical probe and the lift cylinder that are provided with on the probe sliding sleeve, the piston rod and the detection extension cylinder are connected.

Still further, positioning mechanism includes two parallel arrangement's clamp slide bar, clamp slide bar's both ends and support body fixed connection, two be provided with two symmetrical horizontal splint on the clamp slide bar, horizontal splint and clamp slide bar sliding connection, two be provided with horizontal clamp cylinder between the horizontal splint, horizontal clamp cylinder's cylinder body and piston rod respectively with two horizontal splint are connected, two clamp slide bar's the outside is provided with indulges clamp cylinder, two indulge clamp cylinder mirror image sets up its cylinder body and support body fixed connection, it is provided with indulges clamp plate on the piston rod of indulging clamp cylinder and clamp slide bar are perpendicular.

Further, a vertical guide rod is arranged on the frame, the frame body is connected with the guide rod in a sliding mode, and the frame body is connected with a piston rod of the lifting cylinder.

Further, pushing cylinders are arranged on two sides of the conveying belt below the positioning detection mechanism.

The beneficial effects of the utility model are as follows:

according to the utility model, the positioning detection mechanism comprising the detection frame and the positioning mechanism is arranged on the frame, so that the automatic positioning and detection of the concrete strength of the self-heat-preservation building block are realized, compared with the manual operation detection point, the positioning is accurate, the detection efficiency is high, the consistent error of the downward pressure degree of each detection point probe is small, and the self-heat-preservation building block is suitable for popularization and application.

Drawings

Fig. 1 is a schematic structural diagram of a self-heat-preservation building block strength testing device provided by the utility model.

Fig. 2 is a schematic structural diagram of a positioning detection mechanism of the self-heat-preservation building block strength testing device provided by the utility model.

Fig. 3 is a schematic structural diagram of a positioning mechanism of the self-heat-preservation building block strength testing device provided by the utility model.

In the figure: the device comprises a frame 1, a guide rod 101, a conveying belt 2, a lifting cylinder 3, a detection frame 4, a frame body 401, a screw 402, a detection slide bar 403, a detection support plate 404, a probe sliding sleeve 405, a detection probe 406, a lifting cylinder 407, a traversing cylinder 408, a servo motor 409, a positioning mechanism 5, a clamping slide bar 501, a transverse clamping plate 502, a transverse clamping cylinder 503, a longitudinal clamping cylinder 504, a longitudinal clamping plate 505 and a pushing cylinder 6.

Detailed Description

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

Example 1

Referring to fig. 1, the present utility model provides a technical solution: the utility model provides a self preservation temperature building block intensity testing arrangement, including frame 1 and conveyer belt 2, the outside that the conveyer belt 2 extends to its one side by the inside of frame 1, the internally mounted of frame 1 has detection frame 4 and lift cylinder 3, the cylinder body fixed mounting of lift cylinder 3 is in frame 1, detection frame 4 sets up in the top of conveyer belt 2, install vertical guide bar 101 on the frame 1, detection frame 4 installs on guide bar 101 and is connected with the piston rod of lift cylinder 3, positioning mechanism 5 is installed to the lower extreme of detection frame 4, pushing cylinder 6 is installed to the both sides of conveyer belt 2 of detection frame 4 below.

During operation, the building block to be detected is placed on the conveyer belt 2 and is conveyed to the lower side of the detection frame 4 by the conveyer belt, the pushing cylinder 6 centers the building block on the conveyer belt 2, the lifting cylinder 3 drives the detection frame 4 to descend to clamp and position the building block by the positioning mechanism 5 on the lifting cylinder, and after the detection is finished, the detection frame 4 ascends the building block and is sent out of the frame 1 by the conveyer belt 2.

Referring to fig. 2, the detection frame 4 includes a frame body 401, a screw 402, a detection slide bar 403 and a servo motor 409 are installed on the frame body 401, the output end of the servo motor 409 is connected with the screw 402, a detection support plate 404 is installed on the screw 402 and the detection slide bar 403, one end of the detection support plate 404 is in threaded connection with the screw 402, the other end of the detection support plate 404 is in sliding connection with the detection slide bar 403, the servo motor 409 drives the detection support plate 404 to move along the screw 402, a probe sliding sleeve 405 is installed on the detection support plate 404 in a sliding manner, a detection probe 406 and a tight-propping cylinder 407 are vertically installed on the probe sliding sleeve 405, a piston rod of the tight-propping cylinder 407 is connected with the detection probe 406 to drive the tight-propping block to be detected, a transverse moving cylinder 408 is installed on the detection support plate 404, and the piston rod of the transverse moving cylinder 408 is connected with the probe sliding sleeve 405 to drive the probe sliding sleeve 405 to slide along the detection support plate 404.

Referring to fig. 3, the positioning mechanism 5 includes two clamping slide bars 501, two clamping slide bars 501 are provided with two cross clamping plates 502, two ends of each cross clamping plate 502 are respectively connected with the two clamping slide bars 501 in a sliding manner, a cross clamping cylinder 503 is arranged between the two cross clamping plates 502, a cylinder body and a piston rod of each cross clamping cylinder 503 are respectively connected with the two cross clamping plates 502, longitudinal clamping cylinders 504 are arranged on the outer sides of the two clamping slide bars 501, the piston rod of each longitudinal clamping cylinder 504 is perpendicular to the corresponding clamping slide bar 501, a longitudinal clamping plate 505 is arranged on the piston rod, and the cylinder body of each longitudinal clamping cylinder 504 is fixedly arranged on the frame body 401.

When the concrete strength detection device works, after the detection frame 4 descends, the longitudinal clamping air cylinder 504 and the transverse clamping air cylinder 503 respectively drive the longitudinal clamping plate 505 and the transverse clamping plate 502 to clamp and position the building blocks of the conveying belt 2, and the detection probe 406 on the detection support plate 404 is driven by the abutting air cylinder 407 and the servo motor 409 to abut against preset measuring points on the building blocks to detect the concrete strength.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (4)

1. The utility model provides a self preservation temperature building block intensity testing arrangement, includes frame, conveyer belt and location detection mechanism, its characterized in that: the conveyer belt extends to one side outside thereof from the inside of frame, the upper portion of frame is provided with the lift cylinder, location detection mechanism set up in on the piston rod of lift cylinder, location detection mechanism includes detection frame and positioning mechanism, the detection frame includes the support body, positioning mechanism set up in the lower part of support body, be provided with screw rod, detection slide bar and servo motor on the support body, servo motor's output shaft with the screw rod is connected, the screw rod with be provided with the detection extension board between the detection slide bar mutual parallel arrangement two, the one end of detection extension board with screw threaded connection, the other end of detection extension board with detection slide bar sliding connection, be provided with probe sliding sleeve and sideslip cylinder on the detection extension board, the probe sliding sleeve with detection extension board sliding connection, the cylinder body of sideslip cylinder with detection extension board fixed connection, the piston rod of sideslip cylinder with probe sliding sleeve is connected, the vertical detection probe and the lift cylinder that is provided with on the probe sliding sleeve, the one end with the detection piston rod.

2. The self-heat-preservation building block strength testing device according to claim 1, wherein: the positioning mechanism comprises two clamping slide bars which are arranged in parallel, two ends of the clamping slide bars are fixedly connected with the frame body, two symmetrical transverse clamping plates are arranged on the clamping slide bars, the transverse clamping plates are in sliding connection with the clamping slide bars, transverse clamping cylinders are arranged between the transverse clamping plates, cylinder bodies and piston rods of the transverse clamping cylinders are respectively connected with the two transverse clamping plates, longitudinal clamping cylinders are arranged on the outer sides of the clamping slide bars, two longitudinal clamping cylinders are arranged in mirror images, the cylinder bodies of the longitudinal clamping cylinders are fixedly connected with the frame body, and the piston rods of the longitudinal clamping cylinders are perpendicular to the clamping slide bars and provided with longitudinal clamping plates.

3. The self-heat-preservation building block strength testing device according to claim 1 or 2, wherein: the lifting device is characterized in that a vertical guide rod is arranged on the frame, the frame body is connected with the guide rod in a sliding mode, and the frame body is connected with a piston rod of the lifting cylinder.

4. The self-heat-preservation building block strength testing device according to claim 3, wherein: and pushing cylinders are arranged on two sides of the conveying belt below the positioning detection mechanism.