CN220690707U - Building material device that shocks resistance - Google Patents

Abstract

The utility model discloses an impact-resistant device for building materials, which comprises: the sliding mechanism comprises a base, a sliding groove is arranged at the upper end of the base, a first sliding block and a second sliding block are arranged at the upper end of the sliding groove, and a bearing plate is arranged at the upper ends of the first sliding block and the second sliding block. According to the utility model, the sliding wheels and the moving plate are arranged, so that the effect of bearing and moving the plate is realized, namely, the plate is installed at the lower end of the lifting mechanism, and the moving plate moves to the lower end of the lifting mechanism for detection.

Description

Building material device that shocks resistance

Technical Field

The utility model relates to the technical field of building material detection, in particular to an impact-resistant device for building materials.

Background

In the construction engineering, in a very important step of selecting building materials, the building materials can be divided into structural materials, decorative materials and special materials, wherein the structural materials comprise wood, stone slabs, concrete, glass and the like, and when the building materials are purchased, a building manufacturer needs to strictly detect and test whether the building materials are qualified.

The publication authorization number "CN214427188U" discloses a building material impact resistance simulation experiment device, which comprises: base, place board, building materials piece and impact block, place the board and fix on base upper portion, the building materials piece is placing board upper portion, and base upper portion is equipped with a plurality of supports, and a plurality of support tops are equipped with the roof, impact block installs between roof and base, and clamping device is used for conveniently changing the impact block of equidimension, and this building material impact resistance simulation experiment device has solved current building material impact resistance simulation experiment device impact block and is fixed little, can not carry out the selectivity to impact block when the same building material is shocked the realization, the narrower problem of application scope.

The device changes the impact blocks with different sizes through the clamping device, solves the problem of narrow application range, but in the device, because the upper end impact device and the lower end fixing device are fixed, only the center point of the measured stone can be tested, and the impact resistance effect can be determined only through the impact resistance test of the center point, so that the test is not scientific.

Accordingly, there is a need to provide an impact resistant device for building materials that solves the above-mentioned problems.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the building material impact resistance device, which solves the problems that when impact resistance experiments of different positions of thick and heavy stones are required to be tested, the measured materials are inconvenient to move, the measured materials can deviate in angle, and when impacts with different forces are tested, impact blocks with different sizes are required to be replaced by clamping devices, and the operation is complicated, and adopts the following technical scheme:

an impact resistant construction material device comprising: the sliding mechanism comprises a base, a sliding groove is arranged at the upper end of the base, a first sliding block and a second sliding block are arranged at the upper end of the sliding groove, and a bearing plate is arranged at the upper ends of the first sliding block and the second sliding block.

Preferably, the first sliding block is connected with the second sliding block through a connecting rod, and a fixed block and a rotating rod are arranged at the outer ends of the first sliding block and the second sliding block.

Preferably, the inner ends of the first sliding block and the second sliding block are provided with a first threaded rod, and one end of the first threaded rod is provided with a rubber block.

Preferably, the fixed plate is installed to the loading board upper end, rotatory piece is installed to the fixed plate upper end, the second threaded rod is installed to the fixed plate inner, second threaded rod one end fixed connection movable plate.

Preferably, the power box is installed to elevating system one end, power supply box installation power supply switch box, elevating system includes the impact plate, impact plate and lower extreme sliding support fixed connection, the sliding support both sides are equipped with the cylinder, and the upper end is equipped with the motor.

Preferably, the upper end of the impact plate is provided with a threaded rod and a weight, and the weight is in threaded connection with the threaded rod.

Preferably, the upper end of the sliding support is provided with a baffle and a connecting rod, and the motor is arranged at the lower end of the baffle.

Compared with the prior art, the utility model has the following beneficial effects:

(1) According to the utility model, the effect of bearing and moving the plate is realized by arranging the sliding wheels and the moving plates, namely, the plate is arranged at the lower end of the lifting mechanism, and the moving plates are moved to the lower end of the lifting mechanism for detection, so that the impact force can be tested only by fixing one point on the stone in comparison with the prior art;

(2) According to the utility model, the threaded rod is arranged on the impact column, so that when the test stone is required to bear different impact force experiments, the impact force can be changed through weights with different weights, and after downward impact, the weights can be fixed due to the spiral connection of the weights and the threaded rod, so that the weights are prevented from moving after impact.

Drawings

FIG. 1 is a schematic diagram of the front view of an impact-resistant device for building materials according to the present utility model;

FIG. 2 is a schematic structural view of a sliding mechanism of an impact-resistant device for building materials according to the present utility model;

FIG. 3 is an enlarged view of a portion of a sliding mechanism of an impact resistant device for building materials according to the present utility model;

FIG. 4 is a schematic view of the structure of a portion of FIG. 1 of an impact-resistant device for building materials according to the present utility model;

wherein, the names corresponding to the reference numerals are: 100. a sliding mechanism; 101. a base; 102. a chute; 103. a rotating lever; 104. a fixed block; 105. a first push rod; 106. a rubber block; 107. a first slider; 108. a support rod; 109. a second slider; 110. a carrying plate; 111. a rotating block; 112. a second push rod; 113. a moving plate; 114. a fixing plate; 200. a lifting mechanism; 201. an impingement plate; 202. a sliding support; 203. a weight; 204. a threaded rod; 205. a motor; 206. a connecting rod; 207. a baffle; 208. a console; 209. a switch box; 210. and (3) a cylinder.

Detailed Description

The utility model will be further illustrated by the following description and examples, which include but are not limited to the following examples.

As shown in fig. 1 to 4, an impact-resistant device for building materials according to the present utility model comprises: the stone slab testing device comprises a sliding mechanism 100 and a lifting mechanism 200, wherein the sliding mechanism 100 is used for moving a tested stone slab, the lifting mechanism 200 is used for testing how much impact force the stone slab can bear, the lifting mechanism 200 is installed at the upper end of the sliding mechanism 100, the sliding mechanism 100 comprises a base 101, a sliding groove 102 is installed at the upper end of the base 101, a first sliding block 107 and a second sliding block 109 are installed at the upper end of the sliding groove 102, and a bearing plate 110 is installed at the upper ends of the first sliding block 107 and the second sliding block 109.

First embodiment:

as shown in fig. 1-3, the first slide block 107 is connected with the second slide block 109 through the supporting rod 108, the fixed block 104 and the rotating rod 103 are installed at the outer ends of the first slide block 107 and the second slide block 109, the first pushing rod 105 is installed at the inner ends of the first slide block 107 and the second slide block 109, the rubber block 106 is installed at one end of the first pushing rod 105, the fixed plate 114 is installed at the upper end of the bearing plate 110, the rotating block 111 is installed at the upper end of the fixed plate 114, the second pushing rod 112 is fixedly connected with the moving plate 113 at one end, when in use, firstly, the stone to be tested is placed at the upper end of the bearing plate 110, one end of the stone to be tested is attached to the inner side of the fixed plate 114, the second pushing rod 112 is driven to push the inner end through the rotating block 111, the second pushing rod 112 is fixedly connected with the moving plate 113, the moving plate 113 is pushed inwards until the moving plate 113 is attached to one end of the stone, after the stone is fixed, when the bearing plate 110 is required to be fixed, the rotating rod 103 is screwed to drive the second pushing rod 112 to push to the inner end, so that the internal wrench spring is compressed, the wrench piece generates a trend of moving to the other end, when the pushing force counteracts the pressure of the clamp spring, the clamp is retracted, the rubber blocks 106 at the two ends of the second pushing rod 112 are pre-tightened to the inner end of the chute 102, and the fixation is realized, and conversely, when the stone measured at the upper end of the bearing plate 110 is required to be moved, the rotating rod 103 is only required to be screwed outwards, so that the second pushing rod 112 is driven to rotate outwards, the rubber blocks 106 are retracted outwards until the rubber blocks are not contacted with the inner wall of the chute 102, the bearing plate 110 is pushed to move at the upper end of the chute 102, and threaded holes are formed in the upper ends of the first sliding block 107, the second sliding block 109 and the upper end of the bearing plate 110, and the bearing plate 110 are fixed at the upper ends of the first sliding block 107 and the second sliding block 109 through screws.

Through setting up spout 102, first slider 107, second slider 109 and loading board 110, realize bearing and the effect of removal to the panel, at elevating system 200 lower extreme installation promptly, remove elevating system 200 lower extreme detection through loading board 110, can only test its fixed point position for among the prior art, can test stone material different positions, record multiple data for test experiment accuracy is higher.

Second embodiment:

as shown in fig. 1 and 2, the lifting mechanism 200 comprises an impact plate 201, the impact plate 201 is fixedly connected with a lower sliding support 202, a motor 205 is arranged at the upper end of the sliding support 202, a threaded rod 204 and a weight 203 are arranged at the upper end of the impact plate 201, the weight 203 is in spiral connection with the threaded rod 204, a baffle 207 and a connecting rod 206 are arranged at the upper end of the sliding support 202, the motor 205 is arranged at the lower end of the baffle 207, when the lifting mechanism is used, a switch box 209 at the upper end of a control console 208 is firstly opened and started by the control motor 205, movable supports are arranged at the two ends of the sliding support 202, after the movable supports are electrified, an air cylinder 210 converts the pressure energy of compressed air into mechanical energy, a piston moves upwards to push the connecting rod and the crank to rotate, so that the lifting mechanism 200 ascends, the sliding support 202 and the impact plate 201 are driven to ascend to a certain height, then the air pressure in the air cylinder 210 is controlled by the control console 208 to move downwards, and the connecting rod and the crank is pushed to rotate.

The effect that weight 203 does not rebound upwards when the impact plate 201 upper end installation threaded rod 204 is used for realizing downward impact is achieved, and compared with manual movement, the device is simpler and more convenient and labor-saving, when experimental data of different impact forces are acquired, weights 203 with different weights are only required to be stacked on the upper end of the threaded rod 204, and the device is connected to the upper end of the impact plate 201 through the screw, so that the impact strength of a stone plate can be tested more accurately through the weights 203 with different weights in the testing process.

The above embodiment is only one of the preferred embodiments of the present utility model, and should not be used to limit the scope of the present utility model, but all the insubstantial modifications or color changes made in the main design concept and spirit of the present utility model are still consistent with the present utility model, and all the technical problems to be solved are included in the scope of the present utility model.

Claims (7)

1. The building material impact resistance device is characterized by comprising a sliding mechanism (100) and a lifting mechanism (200), wherein the lifting mechanism (200) is arranged at the upper end of the sliding mechanism (100), the sliding mechanism (100) comprises a base (101), a sliding groove (102) is arranged at the upper end of the base (101), a first sliding block (107) and a second sliding block (109) are arranged at the upper end of the sliding groove (102), and a bearing plate (110) is arranged at the upper ends of the first sliding block (107) and the second sliding block (109).

2. The building material impact-resistant device according to claim 1, wherein the first sliding block (107) and the second sliding block (109) are connected through a supporting rod (108), and the outer ends of the first sliding block (107) and the second sliding block (109) are provided with a fixed block (104) and a rotating rod (103).

3. An impact-resistant construction material device according to claim 2, wherein the first slider (107) and the second slider (109) are provided with a first push rod (105) at their inner ends, and wherein the first push rod (105) is provided with a rubber block (106) at one end.

4. The building material impact resistant device according to claim 1, wherein a fixed plate (114) is installed at the upper end of the bearing plate (110), a rotating block (111) is installed at the upper end of the fixed plate (114), a second pushing rod (112) is installed at the inner end of the fixed plate (114), and one end of the second pushing rod (112) is fixedly connected with the moving plate (113).

5. The building material impact resistant device according to claim 1, wherein a console (208) is installed at one end of the lifting mechanism (200), a power supply switch box (209) is installed on the console (208), the lifting mechanism (200) comprises an impact plate (201), the impact plate (201) is fixedly connected with a lower end sliding support (202), air cylinders (210) are arranged at two sides of the sliding support (202), and a motor (205) is arranged at the upper end of the sliding support.

6. The building material impact resistant device according to claim 5, wherein a threaded rod (204) and a weight (203) are installed at the upper end of the impact plate (201), and the weight (203) is in screw connection with the threaded rod (204).

7. The building material impact resistant device according to claim 6, wherein a baffle plate (207) and a connecting rod (206) are installed at the upper end of the sliding bracket (202), and the motor (205) is installed at the lower end of the baffle plate (207).