CN112050859A

CN112050859A - Novel building energy-saving detection device and detection method thereof

Info

Publication number: CN112050859A
Application number: CN202010964011.7A
Authority: CN
Inventors: 王争丰
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-15
Filing date: 2020-09-15
Publication date: 2020-12-08

Abstract

The invention discloses a novel building energy-saving detection device which comprises a second shell, wherein a first through groove and a second through groove are respectively formed in the front surface of the second shell, seventh shells are fixedly connected to two sides of the second shell, and pull rods are slidably connected to the inner side walls of the two seventh shells; according to the invention, the hydraulic cylinder is started and the pressing plate is driven to press the building material needing pressure testing, the pressure sensor transmits a data signal to the display through the signal line for displaying, when diameter data of the steel bar or the pipe are detected, the pull rod is pulled open, the steel bar or the pipe needing to be detected is placed in the second through groove, the diameter size is detected and recorded according to the second scale line, when the size of the building material is detected, the two sixth shells or the fifth shell can be pulled, the building material is placed above the first plate body, and the size data of the building material is detected and recorded by observing the first scale line.

Description

Novel building energy-saving detection device and detection method thereof

Technical Field

The invention relates to the technical field of building detection, in particular to a novel building energy-saving detection device and a detection method thereof.

Background

It is well known that the living standard of people is improved. The variety of the building materials is diversified day by day, the performance is greatly improved, and a great deal of convenience is provided for the living and the living of people. However, the quality problem of the building materials is also a focus of attention, so that the quality of the building materials must be ensured in the building construction process, and effective measures are taken to exert the due performance of the building materials, wherein the building material detection plays an important role, the existing building energy-saving detection device is single in detection flow, and various detection technologies are not reasonably combined together, so that detection personnel use various detection devices when detecting the materials, and meanwhile, the existing detection device cannot adapt to the sizes of the detection materials, so that the detection materials of different models and sizes cannot be detected.

Disclosure of Invention

The invention aims to provide a novel building energy-saving detection device and a detection method thereof, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a novel building energy-saving detection device comprises a second shell, wherein a first through groove and a second through groove are respectively formed in the front surface of the second shell, seventh shells are fixedly connected to two sides of the second shell, pull rods are slidably connected to the inner side walls of the two seventh shells, one end of one pull rod penetrates through one side of the second shell and is positioned in the first through groove, one end of the other pull rod penetrates through the other side of the second shell and is positioned in the second through groove, a first spring is sleeved on the outer side walls of the two pull rods, baffles are fixedly connected to the outer side walls of the two pull rods, arc-shaped plates are welded to the adjacent ends of the two pull rods, second scale marks are formed on the outer side walls of the two pull rods, a first plate body is fixedly connected to the top of the second shell, and two sliding grooves are symmetrically formed in the upper surface of the first plate body, two the equal fixedly connected with fixed block of inside wall of spout, two the equal sliding connection of inside wall of spout has the slider, two the equal fixedly connected with second spring in adjacent one side of slider, two the equal fixedly connected with sixth casing of the upper surface of slider, two the equal sliding connection of inside wall of sixth casing has the fifth casing, two first stopper, two all have been welded at the top of fifth casing the front surface and two of sixth casing first scale mark has all been seted up to the front surface of fifth casing, the last surface mounting of first plate body has pressure sensor, the front surface mounting of second casing has the display screen, pressure sensor's signal output part with the signal input part signal connection of display screen.

As further preferable in the present technical solution: the bottom fixedly connected with first casing of second casing, four first pillars of the lower surface symmetry fixedly connected with of first casing, four the lateral wall of first pillar all overlaps and is equipped with the second pillar, four set up threaded hole, four are arranged to the front surface equidistance of first pillar the equal threaded connection in front surface of second pillar has the bolt, two the equal threaded connection in one end of bolt in the inside wall of screw hole, four the bottom of second pillar all welds the bottom plate.

As further preferable in the present technical solution: the upper surface of the second shell is fixedly connected with a third shell, and the top of the third shell is fixedly connected with a fourth shell.

As further preferable in the present technical solution: the upper surface of the third shell is provided with a hydraulic cylinder, the hydraulic cylinder is located inside the fourth shell, and a piston rod of the hydraulic cylinder penetrates through the upper surface of the third shell and is fixedly connected with a pressing plate.

As further preferable in the present technical solution: the top of the inner side wall of the third shell is symmetrically and fixedly connected with two U-shaped plates, and the inner side walls of the U-shaped plates are hinged with illuminating lamps.

As further preferable in the present technical solution: the upper surface of the first plate body is provided with a groove, and a rubber pad is bonded on the inner side wall of the groove.

The invention also provides a novel building energy-saving detection method, which comprises the following steps:

s1, placing a building board or a concrete material needing to be subjected to pressing strength detection in the rubber pad above the first plate body, starting a hydraulic cylinder through a switch group, and driving a pressing plate to move downwards to press the building material by a piston rod of the hydraulic cylinder;

s2, when the building board or concrete material in the rubber pad is extruded by the pressing plate, the pressure sensor in the first plate transmits the pressure-induced data signal to the display screen on the front surface of the second shell, and the display screen displays the data signal after receiving the data signal;

s3, when the building steel bar or the building pipe needs to be detected, the diameter of the first through groove and the diameter of the second through groove can be matched according to the diameter of the steel bar or the pipe, the pull rod is pulled after the matching, the steel bar or the pipe is placed into the second through groove or the first through groove, the pull rod is loosened, the pull rod is driven to retract by the acting force of the first spring, the arc-shaped plate at one end of the pull rod is driven to clamp the steel bar or the pipe, and an operator can observe the second scale line in the pull rod to detect and record the diameter specific data of the steel bar or the pipe at the moment;

s4, when the size of the building board or the concrete material needs to be detected, an operator pulls the two sixth shells or the fifth shells towards the two sides of the device, the sliding block is driven to slide towards the two sides in the sliding groove, the building board or the concrete material is placed above the first board body, after the sixth shells or the fifth shells are loosened, the sliding block can be driven to retract by the acting force of the second spring, the sliding block drives the sixth shells or the fifth shells to reset, and at the moment, the operator can observe the first scale lines in the sixth shells and the fifth shells to detect and record the size data of the building board or the concrete material.

As further preferable in the present technical solution: in S4, since the fifth housing is slidably connected to the sixth housing, the operator can slide the fifth housing up and down to adapt to the detection materials with different heights, wherein the first limiting block can limit the moving distance of the fifth housing.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, the hydraulic cylinder is started and the pressing plate is driven to press the building material needing pressure testing, the pressure sensor transmits a data signal to the display through the signal line for displaying, when diameter data of the steel bar or the pipe are detected, the pull rod is pulled open, the steel bar or the pipe needing to be detected is placed in the second through groove, the diameter size is detected and recorded according to the second scale line, when the size of the building material is detected, the two sixth shells or the fifth shell can be pulled, the building material is placed above the first plate body, and the size data of the building material is detected and recorded by observing the first scale line.

Drawings

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

FIG. 2 is a schematic view of the internal structure of the second housing according to the present invention;

fig. 3 is a schematic view of the internal structure of the first plate body according to the present invention;

fig. 4 is a schematic top view of the first plate of the present invention.

In the figure: 1. a bolt; 2. a display screen; 3. a first housing; 4. a base plate; 5. a threaded hole; 7. a second housing; 8. a pull rod; 9. a first through groove; 10. an arc-shaped plate; 11. a first scale mark; 12. a first stopper; 13. a third housing; 14. a U-shaped plate; 15. a hydraulic cylinder; 16. a fourth housing; 17. an illuminating lamp; 18. a fifth housing; 19. a sixth housing; 20. a first plate body; 21. a second through groove; 22. a second scale mark; 23. a seventh housing; 24. a first support; 25. a first spring; 26. a baffle plate; 27. a slider; 28. a second spring; 29. a fixed block; 30. a chute; 31. a groove; 32. a pressure sensor; 33. a rubber pad; 34. a second support; 35. and (7) pressing a plate.

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.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a novel building energy-saving detection device comprises a second shell 7, wherein a first through groove 9 and a second through groove 21 are respectively formed in the front surface of the second shell 7, seventh shells 23 are fixedly connected to both sides of the second shell 7, pull rods 8 are slidably connected to the inner side walls of the two seventh shells 23, one end of one pull rod 8 penetrates through one side of the second shell 7 and is positioned inside the first through groove 9, one end of the other pull rod 8 penetrates through the other side of the second shell 7 and is positioned inside the second through groove 21, first springs 25 are sleeved on the outer side walls of the two pull rods 8, baffles 26 are fixedly connected to the outer side walls of the two pull rods 8, arc-shaped plates 10 are welded to the adjacent ends of the two pull rods 8, second scale marks 22 are formed on the outer side walls of the two pull rods 8, a first plate body 20 is fixedly connected to the top of the second shell 7, two sliding grooves 30 are symmetrically formed in the upper surface of the first plate body 20, equal fixedly connected with fixed block 29 of inside wall of two spouts 30, the equal sliding connection of inside wall of two spouts 30 has slider 27, the equal fixedly connected with second spring 28 in adjacent one side of two slider 27, the equal fixedly connected with sixth casing 19 of upper surface of two sliders 27, the equal sliding connection of inside wall of two sixth casings 19 has fifth casing 18, first stopper 12 has all been welded at the top of two fifth casings 18, first scale mark 11 has all been seted up to the front surface of two sixth casings 19 and the front surface of two fifth casings 18, the last surface mounting of first plate body 20 has pressure sensor 32, the front surface mounting of second casing 7 has display screen 2, the signal output part of pressure sensor 32 and the signal input part signal connection of display screen 2.

In this embodiment, specifically: the bottom of the second shell 7 is fixedly connected with a first shell 3, the lower surface of the first shell 3 is symmetrically and fixedly connected with four first support columns 24, the outer side walls of the four first support columns 24 are all sleeved with second support columns 34, threaded holes 5 are formed in the front surfaces of the four first support columns 24 in an equidistant arrangement mode, the front surfaces of the four second support columns 34 are all in threaded connection with bolts 1, one ends of the two bolts 1 are all in threaded connection with the inner side walls of the threaded holes 5, and bottom plates 4 are welded at the bottoms of the four second support columns 34; the operator can slide the first support column 24 to increase the height between the first support column 24 and the second support column 34, and fasten the bolt 1 and the threaded hole 5 to fix the height.

In this embodiment, specifically: the upper surface of the second shell 7 is fixedly connected with a third shell 13, and the top of the third shell 13 is fixedly connected with a fourth shell 16; the third housing 13 protects the main body of the device from being exposed to the external environment, and the fourth housing 16 protects the surface of the hydraulic cylinder 15 from being exposed to the external environment.

In this embodiment, specifically: a hydraulic cylinder 15 is mounted on the upper surface of the third shell 13, the hydraulic cylinder 15 is located inside the fourth shell 16, and a piston rod of the hydraulic cylinder 15 penetrates through the upper surface of the third shell 13 and is fixedly connected with a pressing plate 35; after the hydraulic cylinder 15 is started, the piston rod can drive the pressing plate 35 to press the detection material downwards.

In this embodiment, specifically: the top of the inner side wall of the third shell 13 is symmetrically and fixedly connected with two U-shaped plates 14, and the inner side walls of the two U-shaped plates 14 are hinged with illuminating lamps 17; the illuminating lamp 17 can provide proper light illumination when the light is weak, so that an operator can conveniently operate in the environment with weak light.

In this embodiment, specifically: the upper surface of the first plate body 20 is provided with a groove 31, and the inner side wall of the groove 31 is bonded with a rubber pad 33; the rubber pad 33 may increase the friction of the groove 31.

s1, placing the building board or concrete material to be subjected to pressing strength detection in the rubber pad 33 above the first plate body 20, starting the hydraulic cylinder 15 through the switch group, and driving the pressing plate 35 to move downwards to press the building material by the piston rod of the hydraulic cylinder 15;

s2, when the pressing plate 35 presses the building board or concrete material in the rubber pad 33, the pressure sensor 32 in the first plate 20 transmits the data signal of pressure sensing to the display screen 2 on the front surface of the second housing 7, and the display screen 2 displays the data signal after receiving the data signal;

s3, when the building steel bar or the building pipe needs to be detected, the diameter of the first through groove 9 and the diameter of the second through groove 21 can be matched according to the diameter of the steel bar or the pipe, the pull rod 8 is pulled after the matching, the steel bar or the pipe is placed into the second through groove 21 or the first through groove 9, the pull rod 8 is loosened, the pull rod 8 is driven to retract by the acting force of the first spring 25, the arc-shaped plate 10 at one end of the pull rod 8 is driven to clamp the steel bar or the pipe, and an operator can observe the second scale mark 22 in the pull rod 8 to detect and record the diameter specific data of the steel bar or the pipe at the moment;

s4, when the size of the building board or the concrete material needs to be detected, the operator pulls the two sixth casings 19 or the fifth casings 18 to the two sides of the device, and simultaneously drives the sliding block 27 to slide to the two sides in the sliding groove 30, and simultaneously places the building board or the concrete material above the first board 20, after the sixth casing 19 or the fifth casing 18 is loosened, the sliding block 27 can be driven to retract by the acting force of the second spring 28, the sliding block 27 drives the sixth casing 19 or the fifth casing 18 to return, and at this time, the operator can observe the first scale lines 11 in the sixth casing 19 and the fifth casing 18 to detect and record the size data of the building board or the concrete material.

In this embodiment, specifically: in S4, since the fifth housing 18 is slidably connected to the sixth housing 19, the operator can slide the fifth housing 18 up and down to fit the detection materials with different heights, wherein the first stopper 12 can limit the moving distance of the fifth housing 18.

In this embodiment, the hydraulic cylinder 15 is used in the following types: CX-SD50X 50.

In this embodiment, the pressure sensor 32 is used in the following types: GYLF-3000.

In this embodiment, the usage model of the display screen 2 is: 12864BG-1F3WP 10-1S.

In this embodiment, a switch set for controlling the hydraulic cylinder 15, the display screen 2 and the pressure sensor 32 to be turned on or off is installed on one side of the third housing 13, and the switch set is connected to an external commercial power to supply power to the hydraulic cylinder 15, the display screen 2 and the pressure sensor 32.

Working principle or structural principle, when in use, a building board or concrete material needing to be subjected to pressing strength detection is placed in the rubber pad 33 above the first plate body 20, the hydraulic cylinder 15 is started through the switch group, the piston rod of the hydraulic cylinder 15 drives the pressing plate 35 to move downwards to press the building material, when the pressing plate 35 extrudes the building board or concrete material in the rubber pad 33, the pressure sensor 32 in the first plate body 20 transmits a pressure-induced data signal to the display screen 2 on the front surface of the second shell 7, and the display screen 2 displays the data signal after receiving the data signal, so that an operator can conveniently detect and record pressure test data, when a building steel bar or a building pipe needs to be detected, the diameters of the first through groove 9 and the second through groove 21 can be matched according to the diameter of the steel bar or the pipe, the pull rod 8 is pulled after being matched, placing a steel bar or a pipe into the second through groove 21 or the first through groove 9, releasing the pull rod 8, driving the pull rod 8 to retract by the acting force of the first spring 25, driving the arc-shaped plate 10 at one end of the pull rod 8 to clamp the steel bar or the pipe, and allowing an operator to observe the second scale marks 22 in the pull rod 8 to detect and record specific diameter data of the steel bar or the pipe at the moment, when the size of a building board or a concrete material needs to be detected, the operator pulls the two sixth shells 19 or the fifth shells 18 to the two sides of the device, and simultaneously drives the sliding block 27 to slide to the two sides in the sliding groove 30, and simultaneously places the building board or the concrete material above the first plate 20, and after releasing the sixth shell 19 or the fifth shell 18, the sliding block 27 can be driven by the acting force of the second spring 28 to retract, and drives the sixth shell 19 or the fifth shell 18 to reset, and allowing the operator to observe the first scale marks 11 in the sixth shell 19 and the fifth shell 18 to reset the building board 20 at the moment Or the size data of the concrete material is detected and recorded, the invention is convenient for operators to carry out various detection processes on the detection material, and the diversity of the invention is improved, meanwhile, the illuminating lamp 17 can ensure that the device can provide proper light illumination when the light is weak, the operators can conveniently operate in the environment with weak light, the third shell 13 can protect the main body part of the device, the main body part is prevented from being exposed to the external environment, and the fourth shell 16 can protect the surface of the hydraulic cylinder 15, so that the hydraulic cylinder 15 is prevented from being exposed to the external environment.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a novel building energy conservation detects device, includes second casing (7), its characterized in that: the front surface of the second shell (7) is respectively provided with a first through groove (9) and a second through groove (21), both sides of the second shell (7) are fixedly connected with seventh shells (23), the inner side walls of the two seventh shells (23) are respectively connected with a pull rod (8) in a sliding manner, one end of one pull rod (8) penetrates through one side of the second shell (7) and is positioned in the first through groove (9), one end of the other pull rod (8) penetrates through the other side of the second shell (7) and is positioned in the second through groove (21), the outer side walls of the two pull rods (8) are respectively sleeved with a first spring (25), the outer side walls of the two pull rods (8) are respectively and fixedly connected with a baffle (26), the adjacent ends of the two pull rods (8) are respectively welded with an arc-shaped plate (10), the outer side walls of the two pull rods (8) are respectively provided with a second scale mark (22), the top of the second shell (7) is fixedly connected with a first plate body (20), the upper surface of the first plate body (20) is symmetrically provided with two sliding grooves (30), the inner side walls of the two sliding grooves (30) are fixedly connected with fixed blocks (29), the inner side walls of the two sliding grooves (30) are slidably connected with sliding blocks (27), adjacent sides of the two sliding blocks (27) are fixedly connected with second springs (28), adjacent ends of the two second springs (28) are fixedly connected with one sides of the fixed blocks (29), the upper surfaces of the two sliding blocks (27) are fixedly connected with sixth shells (19), the inner side walls of the two sixth shells (19) are slidably connected with fifth shells (18), the tops of the two fifth shells (18) are welded with first limiting blocks (12), the front surfaces of the two sixth shells (19) and the front surfaces of the two fifth shells (18) are provided with first scale marks (11), the upper surface mounting of first plate body (20) has pressure sensor (32), the preceding surface mounting of second casing (7) has display screen (2), the signal output part of pressure sensor (32) with the signal input part signal connection of display screen (2).

2. The novel building energy conservation detects device of claim 1 characterized in that: the bottom fixedly connected with of second casing (7) first casing (3), four first pillar (24) of the lower surface symmetry fixedly connected with of first casing (3), four the lateral wall of first pillar (24) all overlaps and is equipped with second pillar (34), four threaded hole (5), four are seted up to the front surface equidistance of first pillar (24) the equal threaded connection in front surface of second pillar (34) has bolt (1), two the equal threaded connection in one end of bolt (1) in the inside wall of screw hole (5), four bottom plate (4) have all been welded to the bottom of second pillar (34).

3. The novel building energy conservation detects device of claim 1 characterized in that: the upper surface of the second shell (7) is fixedly connected with a third shell (13), and the top of the third shell (13) is fixedly connected with a fourth shell (16).

4. The novel building energy conservation detects device of claim 3 characterized in that: the upper surface mounting of third casing (13) has pneumatic cylinder (15), pneumatic cylinder (15) are located the inside of fourth casing (16), the piston rod of pneumatic cylinder (15) runs through the upper surface and the fixedly connected with clamp plate (35) of third casing (13).

5. The novel building energy conservation detects device of claim 3 characterized in that: the top of the inner side wall of the third shell (13) is symmetrically and fixedly connected with two U-shaped plates (14), and the inner side walls of the U-shaped plates (14) are hinged with illuminating lamps (17).

6. The novel building energy conservation detects device of claim 1 characterized in that: a groove (31) is formed in the upper surface of the first plate body (20), and a rubber pad (33) is bonded to the inner side wall of the groove (31).

7. A novel building energy-saving detection method is characterized by comprising the following steps:

s1, placing a building board or a concrete material which needs to be subjected to pressing strength detection in a rubber pad (33) above the first plate body (20), starting the hydraulic cylinder (15) through a switch group, and driving a pressing plate (35) to move downwards to press the building material by a piston rod of the hydraulic cylinder (15);

s2, when the building board or concrete material in the rubber pad (33) is extruded by the pressing plate (35), the pressure sensor (32) in the first plate body (20) transmits a pressure-induced data signal to the display screen (2) on the front surface of the second shell (7), and the display screen (2) displays the data signal after receiving the data signal;

s3, when the building steel bar or the building pipe needs to be detected, the diameter of the first through groove (9) and the diameter of the second through groove (21) can be matched according to the diameter of the steel bar or the pipe, the pull rod (8) is pulled after matching, the steel bar or the pipe is placed into the second through groove (21) or the first through groove (9), the pull rod (8) is loosened, the pull rod (8) is driven to retract by the acting force of the first spring (25), the arc-shaped plate (10) at one end of the pull rod (8) is driven to clamp the steel bar or the pipe, and an operator can observe the diameter specific data of the steel bar or the pipe detected and recorded by the second scale marks (22) in the pull rod (8);

s4, when the size of the building board or the concrete material needs to be detected, an operator pulls the two sixth shells (19) or the fifth shells (18) towards the two sides of the device, the sliding block (27) is driven to slide towards the two sides in the sliding groove (30) at the same time, the building board or the concrete material is placed above the first plate body (20), after the sixth shell (19) or the fifth shell (18) is loosened, the sliding block (27) can be driven to retract by the acting force of the second spring (28), the sliding block (27) drives the sixth shell (19) or the fifth shell (18) to reset, and at the moment, the operator can observe the first scale marks (11) in the sixth shell (19) and the fifth shell (18) to detect and record the size data of the building board or the concrete material.

8. The novel building energy-saving detection method according to claim 7, characterized in that: in S4, since the fifth shell (18) is connected to the sixth shell (19) in a sliding manner, the operator can slide the fifth shell (18) up and down to adapt to detection materials with different heights, wherein the first limit block (12) can limit the moving distance of the fifth shell (18).