CN115213834A - Adsorption equipment and reinforcing bar protective layer check out test set - Google Patents

Abstract

The invention provides an adsorption device and a steel bar protection layer detection device, and particularly relates to the field of engineering equipment. Wherein, the adsorption device comprises a bottom plate; the air inlet pipeline is fixedly connected with the bottom plate and is positioned in the through hole, and one end of the air inlet pipeline extends to the outer side of the bottom plate; the connecting seat is provided with a cavity, and the air inlet pipeline is communicated with the cavity; and an adsorption assembly comprising: the connecting frame is fixedly connected to the connecting seat; the driving gear is rotationally connected with the connecting frame, and a driving piece is connected to the driving gear; the driving blade is fixedly connected to the driving gear; the driving gear comprises a driving wheel and a plurality of driven wheels, the driven wheels are meshed with the driving wheel, the driven wheels are located on the periphery of the driving wheel, and the driven wheels are driven to rotate through the driving wheel. The invention can effectively solve the problems of difficult detection and high safety risk of the concrete reinforcement protective layer in the existing construction process.

Description

Adsorption equipment and reinforcing bar protective layer check out test set

Technical Field

The invention relates to the field of engineering equipment, in particular to an adsorption device and a steel bar protection layer detection device.

Background

In the engineering construction process, the thickness of the concrete reinforcement protective layer is an important index for ensuring the quality of an engineering entity. Therefore, when inspecting the thickness of the steel bar protective layer, a method of non-damage or partial damage is generally adopted. At present, in an engineering entity, the device mainly comprises an integrated reinforcing steel bar protective layer thickness tester and a split reinforcing steel bar protective layer thickness tester.

At present, the structure of the engineering entity is relatively complex, and the position needing to be detected is usually higher from the ground. For example, the detection positions are located at the upper part of the upright column, the bottom of the cover beam and the bottom of the beam plate, and the same distance is between the upper engineering part and the lower engineering part on the ground. Therefore, in the actual detection process of the concrete reinforcement protective layer, detection can be carried out only by means of detection personnel climbing the crawling ladder, and the concrete reinforcement protective layer detection device is high in labor intensity, high in safety risk and large in limitation of detection positions.

Disclosure of Invention

In view of the above disadvantages of the prior art, the present invention provides an adsorption device and a reinforcement protection layer detection apparatus, so as to solve the problems of difficulty in detecting a concrete reinforcement protection layer and a high safety risk in the existing construction process.

To achieve the above and other related objects, the present invention provides an adsorption apparatus comprising:

a bottom plate provided with a plurality of through holes;

the air inlet pipeline is fixedly connected with the bottom plate and is positioned in the through hole, and one end of the air inlet pipeline extends to the outer side of the bottom plate;

the connecting seat is provided with a cavity, the other end of the air inlet pipeline is fixedly connected with the connecting seat, and the air inlet pipeline is communicated with the cavity; and

adsorption component is located on the connecting seat, it includes:

the connecting frame is fixedly connected to the connecting seat;

the driving gear is positioned on the connecting frame, the driving gear is rotationally connected with the connecting frame, and a driving piece is connected to the driving gear; and

the driving blade is fixedly connected to the driving gear;

the driving gear comprises a driving wheel and a plurality of driven wheels, the driven wheels are meshed with the driving wheel, the driven wheels are located on the periphery of the driving wheel, and the driven wheels are driven to rotate through the driving wheel.

In one aspect of the present invention, the driving member includes an absorption motor, which is fixedly connected to the connecting frame, and the absorption motor is in transmission connection with the driving wheel.

In one aspect of the invention, the air conditioner further comprises a filter assembly, which is located in the cavity, and the filter assembly is located between the adsorption assembly and the port of the air inlet pipeline.

In an aspect of the present invention, the filter assembly includes:

the contour of the partition plate is the same as the shape of the cross section of the cavity, and the partition plate is detachably connected with the connecting seat; and

the filter screen is positioned on the clapboard, and the filter screen is fixedly connected with the clapboard.

In one scheme of the invention, a groove is formed in the inner wall of the connecting seat, a protrusion is arranged at the edge position of the partition plate, and the protrusion is clamped with the groove.

The present invention also provides a steel bar protection layer detection apparatus, which includes:

an adsorption device, comprising:

a bottom plate provided with a plurality of through holes;

the air inlet pipeline is fixedly connected with the bottom plate and is positioned in the through hole, and one end of the air inlet pipeline extends to the outer side of the bottom plate;

the connecting seat is provided with a cavity, the other end of the air inlet pipeline is fixedly connected with the connecting seat, and the air inlet pipeline is communicated with the cavity; and

the adsorption component is located on the connecting seat, and the adsorption component comprises:

the connecting frame is fixedly connected to the connecting seat;

the driving gear is positioned on the connecting frame, the driving gear is rotationally connected with the connecting frame, and a driving piece is connected to the driving gear; and

the driving blade is fixedly connected to the driving gear;

the driving gear comprises a driving wheel and a plurality of driven wheels, the driven wheels are meshed with the driving wheel, the driven wheels are positioned on the periphery of the driving wheel, and the driven wheels are driven to rotate by the driving wheel;

the detection device is positioned on the bottom plate; and

and the driving device is positioned on the bottom plate and is used for driving the bottom plate to move.

In one aspect of the present invention, the detection device is a thickness measurement instrument for a steel bar protective layer.

In an aspect of the present invention, the driving device includes a power assembly and a guide assembly, the power assembly is configured to provide power for driving the bottom plate to move, and the guide assembly is configured to adjust a moving direction of the bottom plate.

In an aspect of the present invention, the power module includes:

the two driving wheels are rotationally connected with the bottom plate;

the driving shaft is positioned between the two driving wheels and fixedly connected to the rotating shafts of the driving wheels; and

and the driving motor is fixedly connected with the bottom plate and is in transmission connection with the driving shaft.

In an aspect of the present invention, the guide assembly includes:

the rotating blocks are positioned on the bottom plate and are in rotating connection with the bottom plate;

the guide wheel is rotationally connected to the rotating block; and

the adjusting component is positioned between the bottom plate and the rotating block;

the adjusting assembly drives the rotating blocks to synchronously rotate.

In summary, the invention discloses an adsorption device and a steel bar protection layer detection device, which can solve the problems of difficulty in detection of a concrete steel bar protection layer and high safety risk in the existing construction process. Wherein, at driving vane at the pivoted in-process, produced air current produces the adsorption affinity at the tip of admission line, and a plurality of admission lines can improve this device adsorption effect simultaneously to guarantee the stability of this device in the course of the work. The remote control detection of the building can be realized through the remote control module, and the detection efficiency is greatly improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural diagram of a steel bar protection layer detection apparatus according to an embodiment of the present invention;

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

FIG. 3 is a schematic structural diagram of a floor in an embodiment of an apparatus for inspecting a steel bar protection layer according to the present invention;

FIG. 4 is an enlarged view of view B in FIG. 3;

fig. 5 is a schematic structural diagram of a connecting frame of a device for detecting a steel bar protection layer according to an embodiment of the invention.

Description of the element reference

100. A base plate; 101. a through hole; 110. mounting a box; 111. rotating the block; 112. a guide wheel; 120. a drive disc; 121. a drive rod; 122. adjusting a rod; 123. a chute; 124. a drive block;

200. a housing;

300. a detection device;

400. a drive wheel; 410. a drive motor; 420. a drive shaft;

500. a connecting frame; 510. an adsorption motor; 511. a drive gear; 512. a driving blade; 513. an air intake duct; 520. a connecting seat; 530. a partition plate; 531. a filter screen; 532. and (4) protruding.

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention.

Please refer to fig. 1 to 5. It should be understood that the structures, ratios, sizes, and the like shown in the drawings are only used for matching the disclosure of the present disclosure, and are not used for limiting the conditions of the present disclosure, so that the present disclosure is not limited to the technical essence, and any modifications of the structures, changes of the ratios, or adjustments of the sizes, can still fall within the scope of the present disclosure without affecting the function and the achievable purpose of the present disclosure.

Referring to fig. 1, the present invention provides a steel bar protection layer detection apparatus, which can solve the problems of difficulty in detecting a concrete steel bar protection layer and high safety risk in the existing construction process. The reinforcing steel bar protective layer detection equipment can comprise an adsorption device, a detection device 300, a driving device, a control module and a remote control module. Specifically, the driving device, the detecting device 300 and the control module may allow connection to an adsorption device, so that the steel bar protection layer detecting apparatus is adsorbed on the engineering entity through the adsorption device, and the engineering entity is detected through the detecting device 300. The detection device 300 is electrically connected to the control module, so that the data information detected by the detection device 300 can be transmitted to the control module. It should be noted that the remote control module and the control module are electrically connected, and the specific connection manner is not limited. For example, the remote control module and the control module may allow transmission via WiFi or bluetooth data connection, but not limited thereto, and may allow determination according to actual requirements. The detection device 300 may allow a thickness measuring instrument for the steel bar protection layer to be used, but is not limited to this and may allow determination according to actual requirements. In the prior art, all devices capable of detecting the steel bar protection layer can be used as the detection device 300 and are arranged on the adsorption device. The remote control module at the far end is used as the input end of the signal and can regulate and control the reinforcing steel bar protective layer detection equipment. For example, data acquisition of the detection apparatus 300, position control of the apparatus, and use state control of the apparatus are realized by a remote control device. Wherein a display is also allowed to be connected to the remote control device. Through the display, the related data can be observed more intuitively.

Referring to fig. 1, in an embodiment, the adsorption device may be configured to generate an adsorption force so that the steel bar protection layer detection apparatus can be adsorbed on a surface of an engineering entity. Specifically, the adsorption device may include a bottom plate 100, an air inlet duct 513, a connection seat 520, and an adsorption assembly. Wherein the air inlet duct 513, the connecting seat 520 and the adsorption assembly are located on the bottom plate 100, and the air inlet duct 513 can be allowed to be connected to the adsorption assembly. Therefore, by the adsorption member, an adsorption force can be generated at the inlet position of intake duct 513. Specifically, a plurality of through holes 101 are allowed to be opened in the bottom plate 100, and the diameter of the through holes 101 is the same as that of the air intake duct 513. Thus, air inlet duct 513 may be allowed to be located within through hole 101, and there is a fixed connection between air inlet duct 513 and base plate 100. It should be noted that one end of the air inlet duct 513 is extended to the outer side of the bottom plate 100, so that the air inlet of the air inlet duct 513 is closer to the surface of the engineering entity, so as to improve the adsorption effect of the present device during the actual use. Further, a connecting seat 520 is disposed at the other end of the air inlet duct 513, and the connecting seat 520 is fixedly connected to the air inlet duct 513.

Referring to fig. 1 and 5, in an embodiment, a cavity is allowed to be opened in the connecting seat 520, and the air inlet duct 513 is connected to the cavity. Therefore, the adsorption component can be allowed to be positioned in the cavity, and the adsorption component can generate adsorption force in the adsorption pipeline during operation. Specifically, the suction assembly may include a connection frame 500, a driving gear 511, a driving blade 512, and a driving member, wherein the driving member is drivingly connected to the driving gear 511. Specifically, the connection frame 500 is a frame structure, that is, the connection frame 500 may be formed by connecting a plurality of cross bars to each other, and the specific structure of the connection frame 500 may be determined according to actual requirements. By providing the connecting frame 500 as a frame structure, the air flow can rapidly pass through the connecting frame 500. Wherein, driving gear 511 is located on connecting frame 500, and driving gear 511 is rotatably connected with connecting frame 500. The driving blade 512 is fixedly connected to the driving gear 511, so that the driving blade 512 is driven to rotate by the rotation of the driving gear 511. Therefore, when the driving blade 512 rotates, the generated air flow generates an adsorption force at the end of the air intake duct 513. Specifically, the driving member may allow the suction motor 510 to be used, and the suction motor 510 is fixedly connected to the driving gear 511, and the suction motor 510 is in transmission connection with the driving gear 511. Therefore, the driving gear 511 is further driven to rotate by the adsorption motor 510. It should be noted that the suction motor 510 is electrically connected to the control module, thereby allowing the suction motor 510 to be controlled by a remote control device.

Referring to FIG. 1, in one embodiment, drive gear 511 may include a drive wheel and a plurality of driven wheels, and the number of driven wheels drives the number of blades 512 to be consistent. Specifically, in this embodiment, the driving blades 512 may be allowed to adopt four sets, and the driving blades 512 are connected in the driven wheel. Therefore, by arranging a plurality of groups of driven wheels, the adsorption force generated by the device can be effectively improved. Wherein, four groups of driven wheels are positioned at the periphery of the driving wheel, and the driven wheels are meshed with the driving wheel through gears. Therefore, the four driven wheels can be driven to rotate simultaneously through the rotation of the driving wheel. It can be understood that, in the present embodiment, the absorption motor 510 is in transmission connection with the driving wheel.

It should be noted that it is also allowed that the mounting box 110 is attached to the bottom plate 100, and the opening direction of the mounting box 110 is a direction pointing to the air inlet of the air intake duct 513. Therefore, the detection device 300 and the control module can be fixedly connected in the installation box 110, so that the engineering entity can be detected by the detection device 300. It is noted that it is possible for the control module to make the determination according to the realizable solutions of the prior art. For example, the control module may allow a PLC or a single chip microcomputer to be used, but is not limited thereto, and may be determined according to actual requirements. Meanwhile, the bottom plate 100 is also allowed to be connected with the housing 200, and the outer side of the connecting seat 520 is allowed to be fixedly connected with the housing 200, and all parts of the inside thereof can be protected by the housing 200.

Referring to fig. 1 and 2, in one embodiment, since the device is adsorbed on the surface of the building body, a large amount of dust is brought into the cavity during the adsorption process. Therefore, in order to improve the practical use effect of the device, a filter assembly is allowed to be connected in the cavity. Dust in the air flow is adsorbed by the filter assembly, so that the service life of the adsorption motor 510 is prolonged. Specifically, the filter assembly may include a partition 530, a filter net 531 and a clamping assembly, wherein the partition 530 is detachably connected to the connecting seat 520, so as to replace the filter assembly. Further, the partition 530 has the same contour shape as the cross-sectional shape of the cavity to ensure that the connection holder 520 and the partition 530 maintain a tight connection. The filtering net 531 is disposed on the partition 530, and the aperture of the filtering net 531 can be determined according to actual requirements. Specifically, the clamping assembly may include a protrusion 532 and a groove, and the cross section of the protrusion 532 is the same as the cross section of the groove, so that the protrusion 532 and the groove can be clamped. The protrusion 532 and the groove are respectively disposed on the partition 530 and the connection seat 520, for example, the protrusion 532 is located at an edge of the partition 530, and the groove is located on an inner wall of the connection seat 520. However, the protrusion 532 may be formed on the inner wall of the connection holder 520, and the groove may be formed at the edge of the partition 530. Accordingly, the detachable connection between the partition 530 and the connection holder 520 can be achieved by clipping the groove and the protrusion 532.

Referring to fig. 1, in an embodiment, the steel bar protection layer detection device is adsorbed on the surface of the engineering entity through an adsorption device. Therefore, it is possible to allow the driving means to be connected to the base plate 100 and to allow the reinforcing bar protecting layer detecting apparatus to be moved on the surface of the engineering entity by the driving means. Specifically, the driving device may include a power assembly for providing power to drive the base plate 100 to move and a guide assembly for adjusting the moving direction of the base plate 100.

Referring to fig. 3, in an embodiment, the power assembly may include a plurality of driving wheels 400 and a driving motor 410, and the driving wheels 400 are driven to rotate by the driving motor 410. Specifically, in the present embodiment, two sets of driving wheels 400 are adopted, and the two sets of driving wheels 400 are respectively rotatably connected with the base plate 100. A driving shaft 420 is further connected between the two sets of driving wheels 400, and the driving shaft 420 is fixedly connected to the rotating shafts of the two driving wheels 400. Thus, it is possible to allow the two driving wheels 400 located at both ends of the driving shaft 420 to be rotated in synchronization by driving the driving shaft 420 to rotate. Specifically, the driving motor 410 is fixedly connected to the base plate 100, and the driving motor 410 is in transmission connection with the driving shaft 420, so that the driving shaft 420 is driven to rotate by the driving motor 410. Specifically, the driving motor 410 and the driving shaft 420 may be in transmission connection through a belt, or the driving motor 410 and the driving shaft 420 may be in transmission connection through a bevel gear, but not limited thereto, and the determination may be performed according to actual requirements. It should be noted that the driving motor 410 is electrically connected to the control module, so that the driving motor 410 can be controlled by the control module.

Referring to fig. 3 and 4, in an embodiment, the guide assembly is located on the bottom plate 100, and the guide assembly may be used to adjust a moving direction of the steel bar protection layer detection apparatus during operation. Specifically, the guide assembly may include a plurality of rotating blocks 111, a guide wheel 112, and an adjustment assembly. The rotating blocks 111 are located on the bottom plate 100, and two sets of the rotating blocks 111 may be provided. The adjusting assembly is located on the bottom plate 100, and the adjusting assembly transmission block is connected to drive the two rotating blocks 111 to rotate synchronously. Therefore, the guide wheel 112 is rotatably connected with the rotating block 111, and the rotating axial direction of the guide wheel 112 is perpendicular to the rotating axial direction of the rotating block 111. Specifically, the adjustment assembly may include a driving disc 120, a driving rod 121, an adjustment lever 122, a slide slot 123, and a driving block 124. The driving disk 120 is rotatably connected to the bottom plate 100, and a power member, such as a motor, may be connected to the driving disk 120, and the driving disk 120 is driven to rotate by the motor. Drive rod 121 is located on one side of drive disk 120, and drive rod 121 is slidably connected to base plate 100. It should be noted that, the driving rod 121 is in transmission connection with the driving disc 120, and the driving disc 120 can drive the driving rod 121 to slide relative to the bottom plate 100 during rotation. Specifically, a gear may be allowed to be attached to the periphery of the drive disk 120, and a rack may be allowed to be attached to the drive rod 121, with the gear and the rack being engaged with each other. Therefore, when the driving wheel 400 rotates, the driving rod 121 is driven to move through transmission between the gear and the rack. Furthermore, the adjusting rod 122 is fixedly connected to the rotating block 111, and the sliding slot 123 is formed on the adjusting rod 122. The driving block 124 is fixedly connected to the driving rod 121, and the driving block 124 is located in the sliding slot 123. Therefore, when the driving rod 121 moves relative to the bottom plate 100, the driving block 124 acts on the adjusting rod 122 to rotate the rotating block 111 relative to the bottom plate 100. It should be noted that, a plurality of driving blocks 124 may be allowed to be fixedly connected to the driving rod 121, and the plurality of driving blocks 124 are correspondingly located on different adjusting rods 122, so as to implement synchronous rotation of the plurality of rotating blocks 111, thereby ensuring that the steel bar protection layer detecting apparatus operates stably. It should be noted that, in this embodiment, the motor for driving the driving disc 120 to rotate is electrically connected to the control module, so that the motor can be controlled by the control module, and further the direction adjustment of the apparatus is realized.

In summary, the invention discloses an adsorption device and a steel bar protection layer detection device, which can solve the problems of difficulty in detection of a concrete steel bar protection layer and high safety risk in the existing construction process. Wherein, in the process of driving the blade 512 to rotate, the generated air flow generates the adsorption force at the end of the air inlet duct 513, and meanwhile, the plurality of air inlet ducts 513 can improve the adsorption effect of the device, so as to ensure the stability of the device in the working process. Meanwhile, remote control detection of the building can be achieved through the remote control module, and detection efficiency is greatly improved.

Therefore, the invention effectively overcomes some practical problems in the prior art, thereby having high utilization value and use significance.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and scope of the present invention as defined in the appended claims.

Also, when numerical ranges are given in the examples, it is understood that both endpoints of each numerical range and any number between the two endpoints are optional unless the invention otherwise specified. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs and the description of the present invention, and any methods, apparatuses, and materials similar or equivalent to those described in the examples of the present invention may be used to practice the present invention.

Claims (10)

1. An adsorption device, comprising:

a base plate (100) having a plurality of through holes (101) formed therein;

the air inlet pipeline (513) is fixedly connected with the bottom plate (100), the air inlet pipeline (513) is positioned in the through hole (101), and one end of the air inlet pipeline (513) extends to the outer side of the bottom plate (100);

the connecting seat (520) is provided with a cavity, the other end of the air inlet pipeline (513) is fixedly connected with the connecting seat (520), and the air inlet pipeline (513) is communicated with the cavity; and

the adsorption component is positioned on the connecting seat (520), and comprises:

the connecting frame (500) is fixedly connected to the connecting seat (520);

the driving gear (511) is positioned on the connecting frame (500), the driving gear (511) is rotationally connected with the connecting frame (500), and a driving part is connected to the driving gear (511); and

a driving blade (512) fixedly connected to the driving gear (511);

the driving gear (511) comprises a driving wheel and a plurality of driven wheels, the driven wheels are meshed with the driving wheel, the driven wheels are located on the periphery of the driving wheel, and the driven wheels are driven to rotate through the driving wheel.

2. The suction device as claimed in claim 1, wherein the driving member comprises a suction motor (510) fixedly connected to the connecting frame (500), and the suction motor (510) is in transmission connection with the driving wheel.

3. The sorption arrangement of claim 1, further comprising a filter assembly located within the cavity and between the sorption assembly and the air inlet duct (513).

4. A suction device according to claim 3, characterized in that the filter assembly comprises:

the outer contour of the partition plate (530) is the same as the shape of the cross section of the cavity, and the partition plate (530) is detachably connected with the connecting seat (520); and

and the filter screen (531) is positioned on the partition board (530), and the filter screen (531) is fixedly connected with the partition board (530).

5. The adsorption device according to claim 4, wherein a groove is formed on the inner wall of the connecting seat (520), a protrusion (532) is arranged at the edge position of the partition plate (530), and the protrusion (532) is clamped with the groove.

6. The utility model provides a protective steel bar layer check out test set which characterized in that includes:

the adsorption device of claim 1;

the detection device (300) is positioned on the bottom plate (100); and

the driving device is positioned on the bottom plate (100) and is used for driving the bottom plate (100) to move.

7. The steel bar protection layer detection apparatus according to claim 6, wherein the detection device (300) is a steel bar protection layer thickness measuring instrument.

8. The steel bar protection layer detecting apparatus according to claim 6, wherein the driving means includes:

the power assembly is used for providing power for driving the bottom plate (100) to move; and

a guide assembly for adjusting the moving direction of the base plate (100).

9. The steel bar protection layer detecting apparatus according to claim 8, wherein the power assembly includes:

two driving wheels (400) rotatably connected with the base plate (100);

the driving shaft (420) is positioned between the two driving wheels (400), and the driving shaft (420) is fixedly connected to the rotating shafts of the driving wheels (400); and

the driving motor (410) is fixedly connected with the bottom plate (100), and the driving motor (410) is in transmission connection with the driving shaft (420).

10. The protective steel bar layer detecting apparatus according to claim 8, wherein the guide assembly comprises:

the rotating blocks (111) are positioned on the bottom plate (100), and the rotating blocks (111) are rotatably connected with the bottom plate (100);

the guide wheel (112) is rotatably connected to the rotating block (111); and

the adjusting assembly is positioned between the bottom plate (100) and the rotating block (111);

wherein the adjusting component drives a plurality of rotating blocks (111) to synchronously rotate.

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