CN114216768A

CN114216768A - Building insulation material tensile compression performance detection equipment

Info

Publication number: CN114216768A
Application number: CN202111450826.4A
Authority: CN
Inventors: 李世芳
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-12-01
Filing date: 2021-12-01
Publication date: 2022-03-22

Abstract

The invention discloses a building insulation material tensile compression resistance detection device which comprises a shell, wherein a detection cavity and a sliding cavity are arranged in the shell, the sliding cavity is positioned on the right side of the detection cavity, a chip storage groove is formed in the inner bottom of the detection cavity, a mounting plate is arranged in the detection cavity, rotating shafts are fixedly connected to two sides of the mounting plate, two ends of each rotating shaft are respectively rotatably connected with the inner walls of two sides of the detection cavity, a compression resistance detection assembly is arranged at the inner top of the detection cavity, a sliding groove is formed in the upper end of the mounting plate, a sliding plate used for sliding up and down is arranged in the sliding groove, and the lower end of the sliding plate is connected with the inner bottom of the sliding groove through a telescopic rod. This equipment can carry out cleaning treatment in the use, the accuracy that detects in the piece that detects to exist on with insulation board, and can also clean the platform when insulation board takes place the breakage, guarantees the clean and tidy nature of platform.

Description

Building insulation material tensile compression performance detection equipment

Technical Field

The invention relates to the field of building material detection, in particular to a building insulation material tensile compression performance detection device.

Background

With the development of society and the advancement of science and technology, the living standard of people is continuously improved, meanwhile, the demand of people for materials is more and more large, wherein the building heat-insulating material is widely applied to the construction industry due to the unique performance of the building heat-insulating material, and before the building heat-insulating material is used, the tensile-compression-resistant performance detection is usually required;

the heated board that present detection mode will need to detect is generally put and is carried out the centre gripping on examining test table, detect, but because panel is gathering in the process of removal and transport, there is probably the piece on it, if not clear away the piece, can influence the accuracy that carries out resistance to compression detection to it, and at foretell in-process, during the detection, if the heated board is unqualified, can take place the breakage, make to detect and have more residue on the mesa, because it is not totally smooth to examine test a surface, so these residues enter into some slit easily, extremely difficult clearance.

Disclosure of Invention

The invention aims to solve the defects in the prior art, and provides the building insulation material tensile compression resistance detection equipment.

In order to achieve the purpose, the invention adopts the following technical scheme:

a detection device for tensile compression resistance of a building heat-insulating material comprises a shell, wherein a detection cavity and a sliding cavity are arranged in the shell, the sliding cavity is located on the right side of the detection cavity, a chip storage groove is formed in the inner bottom of the detection cavity, a mounting plate is arranged in the detection cavity, rotating shafts are fixedly connected to two sides of the mounting plate, two ends of each rotating shaft are respectively rotatably connected with inner walls of two sides of the detection cavity, a compression-resistant detection assembly is mounted at the inner top of the detection cavity, a sliding groove is formed in the upper end of the mounting plate, a sliding plate used for sliding up and down is arranged in the sliding groove, and the lower end of the sliding plate is connected with the inner bottom of the sliding groove through a telescopic rod;

the upper end of the sliding plate is provided with a sliding chute, a tensile detection mechanism is arranged in the sliding chute and comprises two pulling blocks which are connected in the sliding chute in a sliding mode, first hydraulic rods are arranged on the inner walls of the left side and the right side of the sliding chute, the telescopic ends of the two first hydraulic rods are fixedly connected with the two pulling blocks respectively, and limiting assemblies are arranged on the opposite sides of the two pulling blocks;

a rotating mechanism for rotating the mounting plate is arranged in the sliding cavity;

the bottom spaces of the sliding cavity and the detection cavity are provided with a cleaning mechanism together.

Preferably, the limiting assembly comprises a rectangular cavity arranged in the pulling block, the upper end of the pulling block is rotatably connected with a handle, the rotating end of the handle extends into the rectangular cavity and is fixedly connected with a threaded rod, a moving block is in threaded connection with the threaded rod, two transverse plates are arranged on one side, close to the middle of the detection cavity, of the pulling block, the transverse plates located below are fixedly connected with the pulling block, a strip-shaped opening is formed in the right side of the rectangular cavity, and one side, close to the transverse plates, of the moving block penetrates through the strip-shaped opening and is fixedly connected with the transverse plates above.

Preferably, the rotating mechanism comprises a worm rotatably connected to the bottom of the sliding cavity, the right end of the rotating shaft on the right side extends into the sliding cavity, and the worm wheel matched with the worm is fixedly connected with the right end of the rotating shaft on the right side.

Preferably, the cleaning mechanism comprises a reciprocating screw rod which is rotatably connected with the top part in the sliding cavity, the lower end of the reciprocating screw rod is fixedly connected with the upper end of the worm, the reciprocating screw rod is connected with a conductive sliding plate through threads, the conductive sliding plate is connected with the inner wall of the sliding cavity in a sliding manner, a power storage box is arranged on the inner wall of the left side of the sliding cavity, a piston plate used for sliding up and down is arranged in the power storage box, the lower end of the piston plate is elastically connected with the inner bottom of the power storage box through a power storage spring, an air bag is arranged between the lower end of the conductive sliding plate and the upper end of the power storage box, the bottom space of the air bag is communicated with the top space of the power storage box through a one-way air inlet, the bottom space of the air bag is communicated with the inside of the sliding cavity through a one-way connecting port, the rear inner wall of the detection cavity is provided with a hollow strip, the front side of the hollow strip is provided with an air outlet, and the top space of the power storage box is communicated with the hollow strip through an air outlet pipe.

Preferably, all install the check valve in air outlet and the one-way connector, be provided with the solenoid valve in the tuber pipe.

Preferably, external power source is installed in the left side of casing, it is equipped with two first conducting blocks to inlay on the right side wall in slip chamber, external power source's positive pole passes through the wire and the first conducting block electric connection of top, external power source's negative pole, solenoid valve and the first conducting block of below pass through wire electric connection in proper order.

Preferably, the lower extreme fixedly connected with electromagnetic plate of mounting panel, the material of sliding plate is iron, the sliding plate passes through a plurality of shake spring elastic connection with the sliding tray, be provided with the multiunit second conducting block in holding the power box, every group the second conducting block comprises two symmetry second conducting blocks of inlaying on holding the power box inner wall, the piston plate adopts conducting material to make.

Preferably, the first conductive block located below is electrically connected to the second conductive block located on the left side in the multiple groups of second conductive blocks through multiple wires, the second conductive blocks located on the right side in the multiple groups of second conductive blocks are electrically connected to the electromagnetic plate through multiple wires, and the other end of the electromagnetic plate is electrically connected to the negative electrode of the external power supply.

Compared with the prior art, the invention has the beneficial effects that:

1. before using, can overturn the platform that the heated board was located for being stained with the piece that attaches on the heated board and receiving the action of gravity and dropping, and still cooperate the use of holding the power box, the clean effect of promotion to the heated board that can step forward.

2. In the testing process, if the broken condition of panel appears, can the starter motor again make the mounting panel be in the reversal state, receive the action of gravity, the piece on the whole mounting panel all can fall to the chip groove, has avoided the condition that the bits of broken glass is difficult to the clearance to appear in some gaps.

3. When a plurality of air outlets blast air, the sliding plate can drive the heated board of its centre gripping to shake from top to bottom for the heated board piece drops more easily, and the same back is damaged to follow-up panel, clears away the clastic effect that falls into the sliding plate and gap on it and also can be better.

Drawings

FIG. 1 is a schematic structural diagram of an apparatus for detecting tensile strength and compressive strength of a building insulation material according to the present invention;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is an enlarged view of FIG. 1 at B;

FIG. 4 is a state diagram of FIG. 1 during cleaning;

FIG. 5 is a top cross-sectional view of the hollow bar;

FIG. 6 is a schematic structural diagram of embodiment 2 of the present invention;

FIG. 7 is an enlarged view at C of FIG. 6;

FIG. 8 is an enlarged view of the power storage case of FIG. 6.

In the figure: the device comprises a shell 1, a detection cavity 2, a chip storage groove 3, a sliding cavity 4, a conductive sliding plate 5, a motor 6, an air bag 7, a reciprocating screw rod 8, a hollow strip 9, an air outlet 10, a mounting plate 11, a rotating shaft 12, a worm 13, a worm wheel 14, a sliding groove 15, a power storage box 16, an air outlet pipe 17, an electromagnetic valve 18, a piston plate 19, a power storage spring 20, a first conductive block 21, a one-way air inlet 22, a sliding plate 23, a first hydraulic rod 24, a pulling block 25, a limiting component 26, a sliding groove 27, a compression resistance detection component 28, a shaking spring 29, a second conductive block 30, an electromagnetic plate 31 and an external power supply 32.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1

Referring to fig. 1-5, a building insulation material tensile strength performance detection device comprises a casing 1, a detection cavity 2 and a sliding cavity 4 are arranged in the casing 1, a sliding door (not shown) is arranged on the front side of the detection cavity 2, the sliding cavity 4 is positioned on the right side of the detection cavity 2, a chip storage groove 3 is arranged at the inner bottom of the detection cavity 2, a mounting plate 11 is arranged in the detection cavity 2, two sides of the mounting plate 11 are fixedly connected with rotating shafts 12, two ends of each rotating shaft 12 are respectively rotatably connected with inner walls of two sides of the detection cavity 2, a compressive strength detection assembly 28 is arranged at the inner top of the detection cavity 2, the compressive strength detection assembly 28 is the prior art and comprises a second hydraulic rod and a compression plate, a sliding groove 15 is arranged at the upper end of the mounting plate 11, a sliding plate 23 for sliding up and down is arranged in the sliding groove 15, and the lower end of the sliding plate 23 is connected with the inner bottom of the sliding groove 15 through a telescopic rod 33;

as an embodiment of the invention, the upper end of the sliding plate 23 is provided with a sliding groove 27, the sliding groove 27 is internally provided with a tensile detection mechanism, the tensile detection mechanism comprises two pulling blocks 25 which are slidably connected in the sliding groove 27, the inner walls of the left side and the right side of the sliding groove 27 are both provided with first hydraulic rods 24, the telescopic ends of the two first hydraulic rods 24 are respectively and fixedly connected with the two pulling blocks 25, the opposite sides of the two pulling blocks 25 are both provided with a limiting component 26, the limiting component 26 comprises a rectangular cavity arranged in the pulling blocks 25, the upper end of the pulling block 25 is rotatably connected with a handle, the rotating end of the handle extends into the rectangular cavity and is fixedly connected with a threaded rod, the threaded rod is in threaded connection with a moving block, one side of the pulling block 25 close to the middle part of the detection cavity 2 is provided with two transverse plates, the upper end of the transverse plate below is just level with the upper end surface of the sliding plate 23, the transverse plate below is fixedly connected with the pulling blocks 25, a strip-shaped opening is formed in the right side of the rectangular cavity, one side, close to the transverse plate, of the moving block penetrates through the strip-shaped opening and is fixedly connected with the transverse plate above the moving block, and the limiting assembly 26 is a clamping limiting structure commonly used in the prior art and is not specifically explained here;

as an embodiment of the present invention, a rotating mechanism for rotating the mounting plate 11 is arranged in the sliding cavity 4, the rotating mechanism comprises a worm 13 rotatably connected to the bottom in the sliding cavity 4, the right end of a rotating shaft 12 positioned on the right side extends into the sliding cavity 4, and a worm wheel 14 matched with the worm 13 is fixedly connected;

as an embodiment of the invention, the bottom spaces of the sliding chamber 4 and the detection chamber 2 are commonly provided with a cleaning mechanism, the cleaning mechanism comprises a reciprocating screw 8 rotatably connected with the top in the sliding chamber 4, the lower end of the reciprocating screw 8 is fixedly connected with the upper end of a worm 13, a conductive sliding plate 5 is connected with the reciprocating screw 8 through a thread, the conductive sliding plate 5 is connected with the inner wall of the sliding chamber 4 in a sliding way, the inner wall of the left side of the sliding chamber 4 is provided with a power storage box 16, a piston plate 19 used for sliding up and down is arranged in the power storage box 16, the lower end of the piston plate 19 is elastically connected with the inner bottom of the power storage box 16 through a power storage spring 20, an air bag 7 is arranged between the lower end of the conductive sliding plate 5 and the upper end of the power storage box 16, the bottom space of the air bag 7 is communicated with the top space of the power storage box 16 through a one-way air inlet 22, the bottom space of the air bag 7 is communicated with the inside of the sliding chamber 4 through a one-way connector, a hollow bar 9 is arranged on the inner wall of the rear side of the detection cavity 2, an air outlet 10 is arranged on the front side of the hollow bar 9, the top space of the power storage box 16 is communicated with the hollow bar 9 through an air outlet pipe 17, one-way valves are arranged in the air outlet 10 and the one-way connecting port, and an electromagnetic valve 18 is arranged in the air outlet pipe 17;

as an embodiment of the present invention, an external power source 32 is installed on the left side of the housing 1, two first conductive blocks 21 are embedded on the right side wall of the sliding cavity 4, the positive electrode of the external power source 32 is electrically connected to the first conductive block 21 above through a wire, and the negative electrode of the external power source 32, the electromagnetic valve 18 and the first conductive block 21 below are electrically connected in sequence through wires.

In the invention, a sliding door at the front side is opened, then two sides of a heat insulation board to be detected are limited by two limiting assemblies 26, after the limitation is completed, a motor 6 is started, the motor 6 can drive a reciprocating screw rod 8 to rotate after being started, the reciprocating screw rod 8 can drive a worm 13 to rotate, and further a rotating shaft 12 at the right side is driven to rotate by a worm wheel 14, so that a mounting plate 11 is slowly turned over, in the process, the rotating of the reciprocating screw rod 8 can drive a conductive sliding plate 5 to move downwards, the conductive sliding plate 5 can compress an air bag 7 when moving downwards, the air in the air bag 7 is pressed into the top space of an energy storage box 16, a piston plate 19 moves downwards, and the piston plate 19 moves downwards to compress an energy storage spring 20;

when the conductive sliding plate 5 moves downwards to contact the two first conductive blocks 21, the motor 6 is turned off and is just in the state shown in fig. 4, the telescopic rod is in a completely stretched state under the action of gravity, the part of the insulation board, which is originally positioned at the upper end, is now positioned at the lower end, and the scraps on the insulation board fall into the scrap storage groove 3 under the action of gravity, so that the scrap removal effect is achieved;

when the conductive sliding plate 5 moves downwards to contact with the two first conductive blocks 21, the electromagnetic valve 18 is opened, the power storage spring 20 in the power storage box 16 is restored, gas stored in the power storage spring is discharged into the hollow strip 9 through the air outlet pipe 17 and finally discharged from the plurality of air outlets 10 and blown to the surface of the heat insulation plate, some fragments adhered tightly are blown off, after cleaning is completed, the motor 6 is started again to enable the mounting plate 11 to restore to the original state, detection can be carried out, and the detection accuracy is higher through the mode;

it is worth mentioning that, in the above-mentioned testing process, if the situation that the panel is broken appears, the motor 6 can be restarted to make the mounting plate 11 be in the state shown in fig. 4, and under the action of gravity, the chips on the whole mounting plate 11 (testing platform) all fall into the chip storage groove 3, so that the situation that the chips in some gaps are difficult to clean is avoided.

Example 2

Referring to fig. 6 to 8, the present embodiment is different from embodiment 1 in that an electromagnetic plate 31 is fixedly connected to a lower end of the mounting plate 11, the sliding plate 23 is made of iron, the sliding plate 23 is elastically connected to the sliding groove 15 through a plurality of shaking springs 29, a plurality of sets of second conductive blocks 30 are disposed in the power storage box 16, each set of second conductive blocks 30 is composed of two second conductive blocks 30 symmetrically embedded on an inner wall of the power storage box 16, the piston plate 19 is made of a conductive material, the first conductive block 21 located below is electrically connected to the second conductive blocks 30 located on the left side of the plurality of sets of second conductive blocks 30 through a plurality of wires, the second conductive blocks 30 located on the right side of the plurality of sets of second conductive blocks 30 are electrically connected to the electromagnetic plate 31 through a plurality of wires, and the other end of the electromagnetic plate 31 is electrically connected to a negative electrode of the external power supply 32.

In this embodiment, when the piston plate 19 moves upward under the elastic action of the power storage spring 20 (the mounting plate 11 is in an overturned state at this time), the piston plate intermittently contacts with the plurality of second conductive blocks 30, so that the electromagnetic plate 31 is intermittently energized, the electromagnetic plate 31 provides an upward attractive force for the sliding plate 23 after being energized, so that the sliding plate 23 moves upward, and after the electromagnetic plate 31 is de-energized, the sliding plate 23 moves downward under the action of gravity, that is, when the air is blown through the plurality of air outlets 10, the sliding plate 23 drives the heat insulation plate clamped by the sliding plate 23 to shake up and down, so that the heat insulation plate fragments are more likely to fall off, and after subsequent plates are damaged, the effect of removing the fragments falling into the sliding plate 23 and gaps thereon is better.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The equipment for detecting the tensile compression resistance of the building thermal insulation material comprises a shell (1) and is characterized in that, a detection cavity (2) and a sliding cavity (4) are arranged in the shell (1), the sliding cavity (4) is positioned at the right side of the detection cavity (2), a chip groove (3) is arranged at the inner bottom of the detection cavity (2), a mounting plate (11) is arranged in the detection cavity (2), both sides of the mounting plate (11) are fixedly connected with a rotating shaft (12), two ends of the rotating shaft (12) are respectively and rotatably connected with the inner walls of two sides of the detection cavity (2), the inner top of the detection cavity (2) is provided with a compression-resistant detection assembly (28), the upper end of the mounting plate (11) is provided with a sliding groove (15), a sliding plate (23) which can slide up and down is arranged in the sliding groove (15), the lower end of the sliding plate (23) is connected with the inner bottom of the sliding groove (15) through an expansion rod (33);

the upper end of the sliding plate (23) is provided with a sliding groove (27), a tensile detection mechanism is arranged in the sliding groove (27), the tensile detection mechanism comprises two pulling blocks (25) which are connected in the sliding groove (27) in a sliding mode, the inner walls of the left side and the right side of the sliding groove (27) are respectively provided with a first hydraulic rod (24), the telescopic ends of the two first hydraulic rods (24) are respectively fixedly connected with the two pulling blocks (25), and the opposite sides of the two pulling blocks (25) are respectively provided with a limiting component (26);

a rotating mechanism for rotating the mounting plate (11) is arranged in the sliding cavity (4);

the bottom spaces of the sliding cavity (4) and the detection cavity (2) are provided with a cleaning mechanism together.

2. The building insulation material tensile strength performance detection device according to claim 1, wherein the limiting component (26) comprises a rectangular cavity arranged in the pulling block (25), the upper end of the pulling block (25) is rotatably connected with a handle, the rotating end of the handle extends into the rectangular cavity and is fixedly connected with a threaded rod, a moving block is connected to the threaded rod in a threaded manner, two transverse plates are arranged on one side of the pulling block (25) close to the middle of the detection cavity (2), the transverse plate located below is fixedly connected with the pulling block (25), a strip-shaped opening is formed in the right side of the rectangular cavity, and one side of the moving block close to the transverse plates penetrates through the strip-shaped opening and is fixedly connected with the transverse plate above.

3. The equipment for detecting the tension and compression resistance of the building insulation material is characterized in that the rotating mechanism comprises a worm (13) which is rotatably connected to the bottom in the sliding cavity (4), the right end of the rotating shaft (12) on the right side extends into the sliding cavity (4), and a worm wheel (14) matched with the worm (13) is fixedly connected with the right end.

4. The equipment for detecting the tension and compression resistance of the building thermal insulation material according to claim 3, wherein the cleaning mechanism comprises a reciprocating screw rod (8) rotatably connected to the inner top of the sliding cavity (4), the lower end of the reciprocating screw rod (8) is fixedly connected with the upper end of a worm (13), a conductive sliding plate (5) is connected to the reciprocating screw rod (8) in a threaded manner, the conductive sliding plate (5) is connected to the inner wall of the sliding cavity (4) in a sliding manner, a force storage box (16) is installed on the inner wall of the left side of the sliding cavity (4), a piston plate (19) for sliding up and down is arranged in the force storage box (16), the lower end of the piston plate (19) is elastically connected with the inner bottom of the force storage box (16) through a force storage spring (20), and an air bag (7) is arranged between the lower end of the conductive sliding plate (5) and the upper end of the force storage box (16), gasbag (7) bottom space is through one-way air inlet (22) and the headspace intercommunication of holding power box (16), gasbag (7) bottom space is through one-way connector and the inside intercommunication of sliding chamber (4), it has hollow strip (9) to detect the rear side inner wall in chamber (2) to install, the front side of hollow strip (9) is provided with air outlet (10), the headspace of holding power box (16) is through going out tuber pipe (17) and hollow strip (9) intercommunication.

5. The equipment for detecting the tensile compression property of the building insulation material as claimed in claim 4, wherein the air outlet (10) and the one-way connecting port are both provided with one-way valves, and the air outlet pipe (17) is internally provided with an electromagnetic valve (18).

6. The building insulation material tensile strength performance detection equipment according to claim 5, wherein an external power supply (32) is installed on the left side of the casing (1), two first conductive blocks (21) are embedded on the right side wall of the sliding cavity (4), the positive electrode of the external power supply (32) is electrically connected with the first conductive block (21) above through a wire, and the negative electrode of the external power supply (32), the electromagnetic valve (18) and the first conductive block (21) below are electrically connected in sequence through wires.

7. The apparatus for detecting the tension and compression resistance of a building insulation material according to claim 6, wherein the lower end of the mounting plate (11) is fixedly connected with an electromagnetic plate (31), the sliding plate (23) is made of iron, the sliding plate (23) is elastically connected with the sliding groove (15) through a plurality of shaking springs (29), a plurality of sets of second conductive blocks (30) are arranged in the power storage box (16), each set of second conductive blocks (30) is composed of two second conductive blocks (30) symmetrically embedded in the inner wall of the power storage box (16), and the piston plate (19) is made of a conductive material.

8. The equipment for detecting the tensile strength of the building thermal insulation material according to claim 7, wherein the first conductive block (21) located at the lower part is electrically connected to the second conductive block (30) located at the left side of the multiple groups of second conductive blocks (30) through multiple wires, the second conductive block (30) located at the right side of the multiple groups of second conductive blocks (30) is electrically connected to the electromagnetic plate (31) through multiple wires, and the other end of the electromagnetic plate (31) is electrically connected to the negative electrode of the external power supply (32).