CN215492319U - Engineering quality detection equipment for bridge engineering construction - Google Patents

Abstract

The utility model discloses engineering quality detection equipment for bridge engineering construction, which comprises a base and a buffer seat, wherein the buffer seat is arranged at four angular positions at the bottom end of the base through buffer shafts, universal wheels are arranged at four angular positions at the bottom end of the buffer seat through support columns, a sample storage seat is arranged at one side position at the top end of the base, a handle is arranged at one side position of the base on the sample storage seat, a sample storage groove is arranged at the top end of the sample storage seat, a control box is arranged at the middle position of the top end of the base, which is far away from the sample storage seat, and a solar panel is arranged at the upper end position of the control box at the top end of the base through support rods. The device solves the problems that the conventional device needs to manually measure the relevant size of the bridge, is low in measurement efficiency and poor in measurement accuracy, cannot quickly measure the hollowing parameter of the bridge and is poor in detection effect, and improves the detection accuracy of the device for detecting the knight-errant.

Description

Engineering quality detection equipment for bridge engineering construction

Technical Field

The utility model relates to the technical field of bridge engineering, in particular to engineering quality detection equipment for bridge engineering construction.

Background

The bridge engineering refers to the working processes of bridge surveying, designing, constructing, maintaining, detecting and the like, and in the aspect of bridge construction, the electronic computer is fully utilized for economic and effective management of construction organizations. In the construction technology, new technology and high-efficiency and high-function machine and tool equipment are continuously introduced, so that the quality is improved, the construction period is shortened, and the manufacturing cost is reduced. Such as the use of laser measurements to control the precise positioning of the structure; the self-elevating water platform is introduced to overcome the difficulty of deep water foundation; remote control equipment is utilized to dig a foundation in the open caisson and the caisson so as to reduce labor intensity and avoid personal danger; by utilizing a high-quality welding technology and popularizing construction site welding and the like, quality detection equipment is required in the bridge engineering construction process.

Through the massive search, the typical constructional engineering quality detection equipment disclosed as publication No. CN210862691U of the quality detection equipment in the prior art is found to be capable of conveniently measuring the plate body and the like higher than the head top, the accuracy is high, and meanwhile, whether a cavity exists in the wall body or not is conveniently detected through the arrangement of the rubber hammer.

The existing detection equipment needs to manually measure the relevant size of a bridge, is low in measurement efficiency, poor in measurement accuracy, incapable of quickly measuring the hollowing parameter of the bridge and poor in detection effect, and therefore the engineering quality detection equipment for bridge engineering construction is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide engineering quality detection equipment for bridge engineering construction, which has the advantage of high detection efficiency and solves the problems that the existing device needs to manually measure the relevant dimension of a bridge, the measurement efficiency is low, the measurement accuracy is poor, the hollowing parameter of the bridge cannot be detected, and the detection effect is poor.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a bridge engineering construction is with engineering quality check out test set, includes base and buffering seat, wherein four angular position departments in base bottom all install the buffering seat through the buffering axle, four angular position departments in buffering seat bottom install the universal wheel through the support column, base top one side position department installs and stores up a kind seat, the base is located stores up kind seat one side position department and installs the handle, it is equipped with stores up a kind groove to store up kind seat top position department, the base top deviates from and stores up kind seat one side intermediate position department and installs the control box, the base top is located control box upper end position department and installs solar panel through the bracing piece.

Preferably, the outer surface of the buffer shaft is provided with a buffer spring at a position of a gap between the buffer seat and the base.

Preferably, the base top is located and stores up appearance seat one side intermediate position department and installs radar monitor, radar monitor bottom is close to handle one side intermediate position department and installs the receiver, radar monitor bottom deviates from receiver one side intermediate position department and installs the transmitter.

Preferably, the rotation axis is installed through the bearing in the base top is located control box and radar monitor intermediate position department, rotation axis top position department installs drive wheel A, the rotation axis bottom is located cushion block lower extreme front surface position department and rear surface position department and all installs infrared inductor.

Preferably, a motor is installed at the position, located on the rear surface of the rotating shaft, of the top end of the base, a driving wheel B is installed at the position, located corresponding to the driving wheel A, of an output shaft of the motor, and the driving wheel B is connected with the driving wheel A through a driving belt.

Preferably, the inside top position department that is close to of control box installs the control room through the baffle, the controller is installed to the inside bottom intermediate position department of control room, controller internally mounted has GPS orientation module, data transmission module, central processing unit and data storage module, the group battery is installed to inside bottom one side position department of control room.

Preferably, the inside control box that is located control room lower extreme position department installs the heat dissipation chamber through the baffle, heat dissipation chamber bottom intermediate position department installs the air-blower, air-blower one side intermediate position department is connected in the control room through the blast pipe, the air-blower front surface is close to bottom position department and connects in the control box surface through the exhaust column, exhaust column end position department installs the filter screen.

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

1. according to the utility model, the radar monitor is arranged at the middle position of the top end of the base, which is positioned at one side of the sample storage seat, so that the effect of detecting the bridge hollowing is achieved, the receiver is arranged at the middle position of the bottom end of the radar monitor, which is close to one side of the handle, and the transmitter is arranged at the middle position of the bottom end of the radar monitor, which is far away from one side of the receiver, so that the problems that the detection device cannot detect the parameters of the bridge hollowing and the detection effect is poor are solved, and the detection effect of the utility model is improved.

2. According to the utility model, the sample storage groove is arranged at the top end of the sample storage seat, so that the effect of storing the sampling blocks in a classified manner is achieved, and the sample storage seat is arranged at one side of the top end of the base, so that the problems of disordered placement of the sampling blocks, data detection and easy error occurrence are solved, and the detection accuracy of the utility model is improved.

3. According to the utility model, the infrared sensors are arranged at the bottom end of the rotating shaft, which is positioned at the front surface position and the rear surface position of the lower end of the buffer seat, so that the effect of rapidly measuring the size of the bridge is achieved, the rotating shaft is arranged at the position, which is positioned at the middle position of the control box and the radar monitor, at the top end of the base through the bearing, the driving wheel A is arranged at the top end of the rotating shaft, the motor is arranged at the position, which is positioned at the rear surface position of the rotating shaft, at the top end of the base, the driving wheel B is arranged at the position, which is corresponding to the driving wheel A, of the output shaft of the motor, and the driving wheel B is connected with the driving wheel A through the driving belt, so that the problems of the need of manually measuring the relevant size of the bridge, such as low measuring efficiency and poor measuring accuracy are solved, and the detection accuracy of the utility model is improved.

Drawings

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

FIG. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic side view of the present invention;

fig. 4 is a schematic front view of the control box of the present invention.

In the figure: 1. a universal wheel; 2. a base; 3. a buffer seat; 4. a sample storage tank; 5. a handle; 6. a sample storage seat; 7. a radar monitor; 8. a solar panel; 9. a control box; 10. a support bar; 11. a rotating shaft; 12. a transmitter; 13. a receiver; 14. a buffer spring; 15. a buffer shaft; 16. a transmission wheel A; 17. a transmission belt; 18. a transmission wheel B; 19. a motor; 20. an infrared sensor; 21. a controller; 22. a control room; 23. a battery pack; 24. a heat dissipation chamber; 25. a blast pipe; 26. a blower; 27. an exhaust pipe; 28. and (4) a filter screen.

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 and 2, the technical solution of the engineering quality detection equipment for bridge engineering construction provided by the present invention is as follows: the engineering quality detection equipment for bridge engineering construction comprises a base 2 and a buffer seat 3, wherein the buffer seat 3 is installed at four angular positions at the bottom end of the base 2 through buffer shafts 15, universal wheels 1 are installed at four angular positions at the bottom end of the buffer seat 3 through supporting columns, a sample storage seat 6 is installed at one side position of the top end of the base 2, a handle 5 is installed at one side position of the base 2, which is located at the sample storage seat 6, a sample storage groove 4 is formed at the top end position of the sample storage seat 6 and used for storing sampling blocks in a classified mode, a control box 9 is installed at the middle position, which is away from the sample storage seat 6, of the top end of the base 2, a solar panel 8 is installed at the upper end position, which is located at the top end of the control box 9, and an electric support is provided for the utility model.

The outer surface of the buffer shaft 15 is provided with a buffer spring 14 at the position of the gap between the buffer seat 3 and the base 2, so that the stability of the utility model is improved.

2 tops of base are located and store up appearance seat 6 one side intermediate position department and install radar monitor 7, and radar monitor 7 bottom is close to handle 5 one side intermediate position department and installs receiver 13, and radar monitor 7 bottom deviates from receiver 13 one side intermediate position department and installs transmitter 12 for the accurate detection bridge hollowing parameter.

Referring to fig. 3, the technical solution of the engineering quality detection equipment for bridge engineering construction provided by the present invention is: the utility model provides a bridge engineering construction is with engineering quality check out test set, includes base 2 and cushion socket 3, and rotation axis 11 is installed through the bearing in the position department in the middle of 2 tops on base is located control box 9 and radar monitor 7, and rotation axis 11 top position department installs drive wheel A16, and rotation axis 11 bottom is located cushion socket 3 lower extreme front surface position department and rear surface position department and all installs infrared inductor 20 for the rapid survey bridge parameter.

A motor 19 is arranged at the position of the top end of the base 2, which is positioned on the rear surface of the rotating shaft 11, a driving wheel B18 is arranged at the position of an output shaft of the motor 19, which is positioned corresponding to the driving wheel A16, and the driving wheel B18 is connected with the driving wheel A16 through a driving belt 17.

The rest is the same as in example 1.

Referring to fig. 2 and 4, the technical solution of the engineering quality detection device for bridge engineering construction provided by the present invention is as follows: the utility model provides a bridge engineering construction is with engineering quality check out test set, includes base 2 and cushion 3, and control box 9 is inside to be close to top position department and to install control room 22 through the baffle, and controller 21 is installed to the inside bottom intermediate position department of control room 22, and controller 21 internally mounted has GPS orientation module, data transmission module, central processing unit and data storage module, and group battery 23 is installed to the inside bottom one side position department of control room 22.

The inside heat dissipation room 24 that is located control room 22 lower extreme position department of control box 9 installs through the baffle, and air-blower 26 is installed to heat dissipation room 24 bottom intermediate position department, and air-blower 26 one side intermediate position department passes through blast pipe 25 and connects in control room 22, dispels the heat to control room 22 is inside, and air-blower 26 front surface is close to bottom position department and connects in control box 9 surface through exhaust column 27, and exhaust column 27 end position department installs filter screen 28.

The rest is the same as in example 1.

The working principle is as follows: after the device is installed, the device is pushed to the upper part of a bridge through a handle 5, the bridge is subjected to moving empty drum detection through a radar monitor 7, a transmitter 12 and a receiver 13, a bridge sampling place is sampled at the same time, sample concrete is placed in a sample storage groove 4 at the top end of a sample storage seat 6, subsequent laboratory detection is facilitated, meanwhile, a central processing unit in a controller 21 controls a motor 19 to rotate, a driving wheel B18 is driven to rotate through the motor 19, a driving wheel A16 is driven to rotate through a driving wheel B18 and a driving belt 17, a rotating shaft 11 and an infrared sensor 20 are driven to rotate through a driving wheel A16, the size of a detection point is detected, detection data are stored through a data storage module in the controller 21, in the detection process, external air is pumped out through an air blower 26 and a pumping pipe 27, and is conveyed to a control room 22 through a blast pipe 25, the inside of the control room 22 is radiated, and the work flow of the device is completed.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a bridge engineering construction is with engineering quality check out test set, includes base (2) and cushion socket (3), its characterized in that: base (2) four angular position departments in bottom all install buffer seat (3) through buffering axle (15), four angular position departments in buffer seat (3) bottom install universal wheel (1) through the support column, base (2) top one side position department installs and stores up appearance seat (6), base (2) are located and store up appearance seat (6) one side position department and install handle (5), it is equipped with and stores up appearance groove (4) to store up appearance seat (6) top position department, base (2) top deviates from and stores up appearance seat (6) one side intermediate position department and installs control box (9), base (2) top is located control box (9) upper end position department and installs solar panel (8) through bracing piece (10).

2. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: and the outer surface of the buffer shaft (15) is provided with a buffer spring (14) at the position of the gap between the buffer seat (3) and the base (2).

3. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: base (2) top is located and stores up appearance seat (6) one side intermediate position department and installs radar monitor (7), radar monitor (7) bottom is close to handle (5) one side intermediate position department and installs receiver (13), radar monitor (7) bottom deviates from receiver (13) one side intermediate position department and installs transmitter (12).

4. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: base (2) top is located control box (9) and radar monitor (7) intermediate position department and installs rotation axis (11) through the bearing, rotation axis (11) top position department installs drive wheel A (16), rotation axis (11) bottom is located cushion seat (3) lower extreme front surface position department and rear surface position department and all installs infrared inductor (20).

5. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: the motor (19) is installed at the position, located on the rear surface of the rotating shaft (11), of the top end of the base (2), the driving wheel B (18) is installed at the position, located corresponding to the driving wheel A (16), of an output shaft of the motor (19), and the driving wheel B (18) is connected with the driving wheel A (16) through a driving belt (17).

6. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: control box (9) inside is close to top position department and installs control room (22) through the baffle, controller (21) are installed to the inside bottom intermediate position department of control room (22), controller (21) internally mounted has GPS orientation module, data transmission module, central processing unit and data storage module, battery pack (23) are installed to the inside bottom one side position department of control room (22).

7. The engineering quality detection equipment for bridge engineering construction according to claim 1, characterized in that: control box (9) inside is located control room (22) lower extreme position department and installs heat dissipation chamber (24) through the baffle, heat dissipation chamber (24) bottom intermediate position department installs air-blower (26), air-blower (26) one side intermediate position department connects in control room (22) through blast pipe (25), air-blower (26) front surface is close to bottom position department and connects in control box (9) surface through exhaust column (27), filter screen (28) are installed to exhaust column (27) end position department.

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