CN111829884A

CN111829884A - Tensile property detection device is used in production of printing opacity heat-insulating film based on energy-conserving building

Info

Publication number: CN111829884A
Application number: CN202010767963.XA
Authority: CN
Inventors: 胡秀凤
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-03
Filing date: 2020-08-03
Publication date: 2020-10-27

Abstract

The invention discloses a tensile property detection device for producing a light-transmitting heat-insulating film based on an energy-saving building, which comprises a workbench main body, a support frame and a sliding groove, wherein the support frame is fixed on the upper surface of the workbench main body through screws, the sliding groove is formed in the inner side surface of the left side surface and the inner side surface of the right side surface of the support frame, the sliding groove is clamped and connected with a sliding block in a sliding mode, a pressing plate is fixed on the inner end of the sliding block through screws, an installation groove is formed in the middle of the upper surface of the workbench main body, a threaded rod is placed in the installation groove, the left end and the right end of the threaded rod are connected with a workbench main body bearing, a first torsion spring is nested on the outer side of the left end of the threaded rod, the left. This printing opacity is tensile nature detection device for thermal-insulated film production based on energy-conserving building is provided with two sets of hydraulic stems and detects the piece, is convenient for carry out tensile strength contrast detection, convenient operation to two films from this.

Description

Tensile property detection device is used in production of printing opacity heat-insulating film based on energy-conserving building

Technical Field

The invention relates to the technical field of energy-saving buildings, in particular to a tensile property detection device for producing a light-transmitting heat-insulating film based on an energy-saving building.

Background

Along with the continuous development of science and technology, we are more and more paying attention to energy conservation and environmental protection in the aspect of urban building, consider energy-conserving factor in the in-process of building construction, combine external solar energy, wind energy and geothermal energy etc. to design the building, make the building energy-conserving environmental protection, roof and outer wall glass need keep warm and insulate against heat at the in-process of energy-conserving building construction, consequently can be equipped with printing opacity thermal-insulated film and use, printing opacity thermal-insulated film need detect its tensile strength when producing, in order to detect whether printing opacity thermal-insulated film is qualified, although the tensile strength detection device of printing opacity thermal-insulated film on the market is many types, but still have some weak points, for example:

1. the existing tensile detection device can only detect one film at a time, when the detection needs to be compared, the detection needs to be carried out one by one, and then the comparison is carried out, so that the operation is complex, and time and labor are wasted;

2. the existing tensile property detection device has single function, can only detect the tensile property of the film, has single function and lower practicability, and cannot well detect a plurality of indexes at the same time;

therefore, we propose a tensile strength detection device for producing a light-transmitting heat-insulating film based on an energy-saving building so as to solve the problems proposed in the above.

Disclosure of Invention

The invention aims to provide a tensile property detection device for producing a light-transmitting heat-insulating film based on an energy-saving building, which solves the problems that the existing tensile property detection device in the market can only detect one film at a time, needs to detect one film at a time when comparison and detection are needed, then compares the films, is complex in operation, wastes time and labor, has single function, can only detect the tensile property of the film, has single function and low practicability, and cannot well detect a plurality of indexes at the same time.

In order to achieve the purpose, the invention provides the following technical scheme: a tensile detection device for producing a light-transmitting heat-insulating film based on an energy-saving building comprises a workbench main body, a support frame and sliding grooves, wherein the support frame is fixed on the upper surface of the workbench main body through screws, the sliding grooves are formed in the inner side surfaces of the left side surface and the right side surface of the support frame, the sliding grooves are clamped and slidably connected with sliding blocks inside, pressing plates are fixed on the inner ends of the sliding blocks through screws, a mounting groove is formed in the middle of the upper surface of the workbench main body, a threaded rod is placed inside the mounting groove, the left end and the right end of the threaded rod are connected with a bearing of the workbench main body, a first torsion spring is nested outside the left end of the threaded rod, the left end of the first torsion spring is connected with the workbench main body through screws, the right end of the first torsion spring is connected with the threaded rod through screws, a mounting block, the hydraulic rod is fixed in the front end and the rear end of the support frame through screws, the detection block is installed on the output end of the hydraulic rod through screws, the inner bearing of the detection block is connected with the vertical rod, the first containing groove and the limiting groove are formed in the upper surface of the front end of the workbench main body, the second containing groove and the limiting groove are formed in the upper surface of the rear end of the workbench main body, the detection plate is placed in the first containing groove and the second containing groove, the limiting groove is formed in the outer side of the first containing groove and the outer side of the second containing groove, the first reset spring is fixed in the outer side of the first containing groove and the outer side of the limiting groove through screws, the convex block is fixed on the outer side of the convex block in a clamping and sliding mode, the first reset spring is fixed on the bottom end of the convex block through screws, the bulge is installed on the bottom surface of the pressing plate through screws, and, and the inside of constant head tank has placed the arch, the outside of slider is seted up flutedly, both ends are inside all to run through and are provided with the kelly about the support frame, and the outside nestification of kelly is provided with second reset spring to second reset spring's outer end and support frame screw connection, second reset spring's the inner and kelly screw connection, the inside block of recess is connected with the kelly, the bottom fix with screw of montant has the horizontal piece, and the bottom surface bonding of horizontal piece is fixed with the rubber pad.

Preferably, the clamp plate passes through the slider and constitutes elevation structure with the workstation main part, and the number of clamp plate and workstation main part is 2: 1 set.

Preferably, the left end outside key-type of threaded rod has first wire winding dish, and the outside winding of first wire winding dish is connected with first connecting rope to the top of first connecting rope and the output end screw connection of the inside hydraulic stem of support frame front end, threaded rod simultaneously.

Preferably, the detection blocks are symmetrically provided with 2 detection blocks relative to the cutting knife, the detection blocks and the detection plate are arranged in a one-to-one correspondence mode, and the lowest point of each detection block is higher than the lowest point of the rubber pad.

Preferably, the outside key of the upper end of the vertical rod is connected with a second rope winding disc, the outside of the second rope winding disc is wound and connected with a second connecting rope, a second torsion spring is arranged on the outer side of the lower portion of the vertical rod in an embedded mode, the top end of the second torsion spring is connected with the vertical rod through a screw, and the bottom end of the second torsion spring is connected with the detection block through a screw.

Preferably, the depth of the first accommodating groove is greater than that of the second accommodating groove, and the vertical center lines of the first accommodating groove and the second accommodating groove are coincident with the vertical center line of the detection block.

Preferably, the detection plate is arranged in a U-shaped structure, and the detection plate and the workbench main body form a lifting structure through a bump, and the detection plate and the detection block are in concave-convex fit.

Preferably, the arch is unsmooth cooperation with the constant head tank, and the arch all is the arc column structure setting with the constant head tank to the arch is the one-to-one setting with the constant head tank.

Preferably, the horizontal block and the rubber pad pass through the montant and constitute revolution mechanic with detecting the piece, and horizontal block and rubber pad are the one-to-one setting.

Compared with the prior art, the invention has the beneficial effects that: this printing opacity is tensile detection device for heat-insulating film production based on energy-conserving building:

(1) the two groups of hydraulic rods and the detection blocks are arranged, and a first containing groove and a second containing groove are formed at the same time, and due to the fact that the depths of the first containing groove and the second containing groove are different, the two groups of hydraulic rods and the detection blocks are matched for use, the descending heights of the two groups of detection blocks are different, and the two groups of detection blocks are convenient to perform downward tension on two films differently, so that tensile property comparison detection on the two films is facilitated, the operation is convenient, and meanwhile, one film is convenient to transversely cut into two parts through the movement of a cutting knife, so that comparison detection work on the same type of film is facilitated;

(2) be fixed with montant and horizontal piece, detect the piece and drive the montant through the cooperation that the rope was connected to the second and second was coiled the rope dish and rotate when descending, make the montant drive the horizontal piece and rotate from this, consequently make to detect the piece and drive the rubber pad and together rotate the surface of film and rub when pressing down the film to be convenient for detect the antifriction performance of film.

Drawings

FIG. 1 is a schematic main sectional view of the present invention;

FIG. 2 is a right sectional view of the present invention;

FIG. 3 is a schematic left sectional view taken along line A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic sectional view of the main connection between the platen and the main body of the workbench according to the present invention;

FIG. 5 is a schematic view of the main cross-sectional structure of the detection block of the present invention;

FIG. 6 is a schematic top view of the main body of the workbench according to the present invention;

fig. 7 is a schematic front view of the present invention.

In the figure: 1. a table main body; 2. a support frame; 3. a chute; 4. a clamping rod; 5. pressing a plate; 6. mounting grooves; 7. a threaded rod; 71. a first rope winding disc; 72. a first connecting rope; 8. a first torsion spring; 9. mounting blocks; 10. a cutting knife; 11. a hydraulic lever; 12. a detection block; 13. a vertical rod; 131. a second connecting rope; 132. a second rope winding disc; 133. a second torsion spring; 14. a first accommodating groove; 15. a second accommodating groove; 16. detecting a plate; 17. a bump; 18. a limiting groove; 19. a first return spring; 20. a protrusion; 21. a slider; 22. a groove; 23. a second return spring; 24. positioning a groove; 25. a transverse block; 26. and (7) a rubber pad.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: a tensile detection device for producing a light-transmitting heat-insulating film based on an energy-saving building comprises a workbench main body 1, a support frame 2, a sliding groove 3, a clamping rod 4, a pressing plate 5, a mounting groove 6, a threaded rod 7, a first rope winding disc 71, a first connecting rope 72, a first torsion spring 8, a mounting block 9, a cutting knife 10, a hydraulic rod 11, a detection block 12, a vertical rod 13, a second connecting rope 131, a second rope winding disc 132, a second torsion spring 133, a first accommodating groove 14, a second accommodating groove 15, a detection plate 16, a lug 17, a limiting groove 18, a first return spring 19, a protrusion 20, a sliding block 21, a groove 22, a second return spring 23, a positioning groove 24, a transverse block 25 and a rubber pad 26, wherein the support frame 2 is fixed on the upper surface of the workbench main body 1 through screws, the sliding groove 3 is formed in the left inner side surface and the right side surface of the support frame 2, the sliding groove 3 is, a pressing plate 5 is fixed on the inner end of the sliding block 21 through a screw, a mounting groove 6 is formed in the middle of the upper surface of the workbench main body 1, a threaded rod 7 is placed in the mounting groove 6, the left end and the right end of the threaded rod 7 are in bearing connection with the workbench main body 1, a first torsion spring 8 is nested on the outer side of the left end of the threaded rod 7, the left end of the first torsion spring 8 is in screw connection with the workbench main body 1, the right end of the first torsion spring 8 is in screw connection with the threaded rod 7, the outer side of the right end of the threaded rod 7 is in screw connection with a mounting block 9, a cutting knife 10 is fixed on the top end of the mounting block 9, hydraulic rods 11 are fixed on the inner portions of the front end and the rear end of the support frame 2, a detection block 12 is installed on the output end of the hydraulic rods 11 through a screw, a vertical rod 13 is connected with an inner bearing of, a second containing groove 15 and a limiting groove 18 are arranged on the upper surface of the rear end of the workbench main body 1, a detection plate 16 is arranged in each of the first containing groove 14 and the second containing groove 15, the limiting groove 18 is arranged on the outer sides of the first containing groove 14 and the second containing groove 15, a first return spring 19 is fixed in the limiting groove 18 through screws, a lug 17 is fixed on the outer side of the periphery of the detection plate 16 through screws, the limiting groove 18 is clamped and connected on the outer side of the lug 17 in a sliding manner, a first return spring 19 is fixed on the bottom end of the lug 17 through screws, a bulge 20 is fixed on the bottom surface of the pressure plate 5 through screws, positioning grooves 24 are arranged on the upper surfaces of the left end and the right end of the workbench main body 1, the bulge 20 is arranged in the positioning grooves 24, grooves 22 are arranged on the outer side of the slide block 21, clamping rods 4 are arranged in the left end and the right end of, the outer end of the second return spring 23 is in screw connection with the support frame 2, the inner end of the second return spring 23 is in screw connection with the clamping rod 4, the clamping rod 4 is connected with the inside of the groove 22 in a clamping mode, a cross block 25 is fixed to the bottom end of the vertical rod 13 through a screw, and a rubber pad 26 is fixedly bonded to the bottom surface of the cross block 25;

the pressing plate 5 forms a lifting structure with the workbench main body 1 through the sliding block 21, and the number of the pressing plate 5 and the workbench main body 1 is 2: 1, so that the left end and the right end of the film can be conveniently extruded and fixed through the lifting of a pressing plate 5;

a first rope winding disc 71 is connected to the outer side key of the left end of the threaded rod 7, a first connecting rope 72 is wound and connected to the outer side of the first rope winding disc 71, the top end of the first connecting rope 72 is in screw connection with the output end of the hydraulic rod 11 in the front end of the support frame 2, and therefore the first connecting rope 72 can drive the threaded rod 7 to rotate through the first rope winding disc 71;

the number of the detection blocks 12 is 2, the detection blocks 12 are symmetrically arranged about the cutting knife 10, the detection blocks 12 are arranged in one-to-one correspondence with the detection plate 16, the lowest point of each detection block 12 is higher than the lowest point of the rubber pad 26, and the detection blocks 12 are arranged in one-to-one correspondence with the detection plate 16, so that the detection blocks 12 push the detection plate 16 to descend in the later period, and further the tensile property detection of a film between the detection blocks 12 and the detection plate 16 is facilitated;

a second rope winding disc 132 is connected to the outer side of the upper end of the vertical rod 13 through a key, a second connecting rope 131 is wound and connected to the outer side of the second rope winding disc 132, a second torsion spring 133 is nested on the outer side of the lower portion of the vertical rod 13, the top end of the second torsion spring 133 is in screw connection with the vertical rod 13, and the bottom end of the second torsion spring 133 is in screw connection with the detection block 12, so that the vertical rod 13 can be driven to rotate through the second rope winding disc 132 and the second torsion spring 133;

the depth of the first accommodating groove 14 is greater than that of the second accommodating groove 15, the vertical center lines of the first accommodating groove 14 and the second accommodating groove 15 are coincident with the vertical center line of the detection block 12, and the descending heights of the detection plates 16 in the first accommodating groove 14 and the second accommodating groove 15 are different due to the fact that the depth of the first accommodating groove 14 is greater than that of the second accommodating groove 15, and comparison and detection are facilitated;

the detection plate 16 is arranged in a U-shaped structure, the detection plate 16 and the workbench main body 1 form a lifting structure through a bump 17, the detection plate 16 and the detection block 12 are in concave-convex fit, and therefore the detection plate 16 is arranged in the U-shaped structure so that the detection block 12 can push a film of the detection plate 16 to perform tensile detection;

the protrusions 20 are in concave-convex fit with the positioning grooves 24, the protrusions 20 and the positioning grooves 24 are both arranged in an arc-shaped structure, the protrusions 20 and the positioning grooves 24 are arranged in one-to-one correspondence, and then the protrusions 20 and the positioning grooves 24 are in concave-convex fit, so that the protrusions 20 and the positioning grooves 24 are matched with each other to extrude and fix the film;

horizontal piece 25 and rubber pad 26 constitute revolution mechanic through montant 13 with detect piece 12, and horizontal piece 25 and rubber pad 26 are the one-to-one setting, can detect the frictional behavior of film through the rotation of horizontal piece 25 and rubber pad 26.

The working principle of the embodiment is as follows: when the tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building is used, firstly, the whole apparatus is moved into the working area as shown in fig. 7, and after reaching the working area, the film is laid on the upper surface of the table body 1, at which time the cutter 10 penetrates the film, then the pressing plates 5 above the upper surfaces of the left and right sides of the table main body 1 are slid downward as shown in fig. 1 and 4, meanwhile, the clamping rod 4 is pulled outwards, so that the clamping rod 4 extrudes the second return spring 23 to store force, at the moment, the pressing plate 5 drives the sliding block 21 to slide in the sliding groove 3, when the pressure plate 5 descends to the lowest point, the clamping rod 4 is released, the clamping rod 4 is inserted into the groove 22 in the slide block 21 under the action of the accumulated force of the second return spring 23, therefore, the pressing plate 5 is well fixed, and the bulges 20 made of rubber materials on the bottom surface of the pressing plate 5 are in concave-convex fit with the positioning grooves 24 to extrude and fix the left end and the right end of the film;

then, as shown in fig. 2, two hydraulic rods 11 are started simultaneously, the output end of the hydraulic rod 11 drives the detection block 12 to descend, and as shown in fig. 2, fig. 4 and fig. 6-7, when the hydraulic rod 11 in the front of the support frame 2 descends, the output end drives the top end of the first connecting rope 72 to move downwards, so that the bottom end of the first connecting rope 72 drives the first rope winding disc 71 to rotate, thereby the first rope winding disc 71 drives the threaded rod 7 with internal key connection to rotate, the threaded rod 7 drives the mounting block 9 with right-end external thread connection to move in the mounting groove 6 when rotating, at this time, the guide block at the bottom end of the mounting block 9 slides in the guide groove in the workbench main body 1, so as to ensure that the mounting block 9 moves stably, the mounting block 9 drives the mounting block 10 with the top end fixed by a screw to move together when the cutting knife moves, therefore, the film is well cut by the cutting knife 10, the film is divided into two parts, and the later comparison and detection work is facilitated;

when the detection block 12 presses the film downwards into the detection plate 16, and then continues to press downwards to drive the detection plate 16 to move downwards in the first accommodation groove 14 and the second accommodation groove 15, the bump 17 on the outer side of the detection plate 16 moves downwards in the limiting groove 18 to extrude the first return spring 19 for storing force, because the heights of the first accommodation groove 14 and the second accommodation groove 15 are different, the descending heights of the two detection plates 16 are different, and further the two cut films are conveniently compared and detected, at this time, the detection block 12 pulls the second connecting rope 131 when descending, so that the bottom end of the second connecting rope 131 drives the second rope winding disc 132 to rotate, as shown in fig. 3 and fig. 5, the second rope winding disc 132 drives the vertical rod 13 connected with the internal key to rotate when rotating, the horizontal block 25 at the bottom end and the rubber pad 26 rotate together when the vertical rod 13 rotates, and then make rubber pad 26 carry out rotary friction to the film of laminating to detect frictional behavior in step when detecting tensile property, convenient operation is simple, thereby accomplishes a series of works.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a production of printing opacity heat-insulating film is with pull resistance detection device based on energy-conserving building, includes workstation main part (1), support frame (2) and spout (3), its characterized in that: the upper surface of the workbench main body (1) is fixed with a support frame (2) through screws, the inner side surfaces of the left side and the right side of the support frame (2) are provided with sliding grooves (3), the sliding grooves (3) are clamped and slidably connected with sliding blocks (21) inside the sliding grooves (3), pressing plates (5) are fixed through screws at the inner ends of the sliding blocks (21), a mounting groove (6) is formed in the middle of the upper surface of the workbench main body (1), a threaded rod (7) is placed inside the mounting groove (6), the left end and the right end of the threaded rod (7) are connected with bearings of the workbench main body (1), a first torsion spring (8) is nested outside the left end of the threaded rod (7), the left end of the first torsion spring (8) is connected with the workbench main body (1) through screws, the right end of the first torsion spring (8) is connected with the threaded rod (7) through screws, and a mounting block (, a cutting knife (10) is fixed at the top end of the mounting block (9), hydraulic rods (11) are fixed at the front end inside and the rear end inside of the support frame (2) through screws, a detection block (12) is installed at the output end of the hydraulic rods (11) through screws, a vertical rod (13) is connected to an inner bearing of the detection block (12), a first accommodating groove (14) and a limiting groove (18) are formed in the upper surface of the front end of the workbench main body (1), a second accommodating groove (15) and a limiting groove (18) are formed in the upper surface of the rear end of the workbench main body (1), detection plates (16) are placed in the first accommodating groove (14) and the second accommodating groove (15), the limiting grooves (18) are arranged on the outer sides of the first accommodating groove (14) and the second accommodating groove (15), and a first reset spring (19) is fixed in the limiting groove (18) through screws, the outer sides of the periphery of the detection plate (16) are all fixed with convex blocks (17) through screws, the outer sides of the convex blocks (17) are clamped and slidably connected with limit grooves (18), first reset springs (19) are fixed at the bottom ends of the convex blocks (17) through screws, bulges (20) are installed on the bottom surfaces of the pressing plates (5) through screws, positioning grooves (24) are formed in the upper surfaces of the left end and the right end of the workbench main body (1), the bulges (20) are placed in the positioning grooves (24), grooves (22) are formed in the outer sides of the sliding blocks (21), clamping rods (4) are arranged in the left end and the right end of the support frame (2) in a penetrating mode, second reset springs (23) are nested in the outer sides of the clamping rods (4), the outer ends of the second reset springs (23) are in screw connection with the support frame (2), and the inner ends of the second reset springs (23) are, the inside block of recess (22) is connected with kelly (4), the bottom fix with screw of montant (13) has horizontal piece (25), and the bottom surface bonding of horizontal piece (25) is fixed with rubber pad (26).

2. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: clamp plate (5) constitute elevation structure through slider (21) and workstation main part (1), and the number of clamp plate (5) and workstation main part (1) is 2: 1 set.

3. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the left end outside key-type of threaded rod (7) is connected with first rope winding dish (71), and the outside winding of first rope winding dish (71) is connected with first connecting rope (72) to the top of first connecting rope (72) and the output end screw connection of the inside hydraulic stem (11) of support frame (2) front end, threaded rod (7) simultaneously.

4. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the detecting blocks (12) are symmetrically arranged in 2 relative to the cutting knife (10), the detecting blocks (12) and the detecting plate (16) are arranged in a one-to-one correspondence mode, and the lowest point of each detecting block (12) is higher than the lowest point of the rubber pad (26).

5. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the outer side key in the upper end of the vertical rod (13) is connected with a second rope winding disc (132), the outer side of the second rope winding disc (132) is connected with a second connecting rope (131) in a winding mode, a second torsion spring (133) is arranged on the outer side of the lower portion of the vertical rod (13) in a nested mode, the top end of the second torsion spring (133) is connected with the vertical rod (13) through screws, and meanwhile the bottom end of the second torsion spring (133) is connected with the detection block (12) through screws.

6. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the depth of the first accommodating groove (14) is greater than that of the second accommodating groove (15), and the vertical center lines of the first accommodating groove (14) and the second accommodating groove (15) are coincident with the vertical center line of the detection block (12).

7. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the detection plate (16) is arranged in a U-shaped structure, the detection plate (16) and the workbench main body (1) form a lifting structure through a bump (17), and the detection plate (16) and the detection block (12) are in concave-convex fit.

8. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: protruding (20) are unsmooth cooperation with constant head tank (24), and protruding (20) all are the arc column structure setting with constant head tank (24) to protruding (20) are the one-to-one setting with constant head tank (24).

9. The tensile property detection device for producing the light-transmitting heat-insulating film based on the energy-saving building as claimed in claim 1, wherein: the transverse blocks (25) and the rubber pads (26) form a rotating structure with the detection blocks (12) through the vertical rods (13), and the transverse blocks (25) and the rubber pads (26) are arranged in a one-to-one correspondence mode.