CN219810489U - Civil engineering hydraulic engineering construction quality detection device - Google Patents

Abstract

The utility model provides a civil engineering hydraulic engineering construction quality detection device, which relates to the technical field of hydraulic engineering construction quality detection and comprises a processing mechanism, a sensor mechanism and a solar energy mechanism. According to the utility model, the inclination angle sensor and the displacement sensor are used for detecting and monitoring the inclination conditions of hydraulic engineering buildings, the settlement of the buildings, the deformation of foundations and the like in real time, the pressure sensor is used for detecting the concrete strength and the bearing capacity of the steel bars, the composite design requirement and standard specification are ensured, the vibration sensor is used for monitoring and frequency the vibration condition of a construction site, and then the processed and detected data are transmitted to the detection center through the communication module in real time for real-time detection, monitoring, recording and report generation through the microprocessor, the data acquisition card and the central processing unit, so that human errors are reduced, the measurement accuracy and reliability are improved, the construction efficiency and the management efficiency are improved, potential safety hazards can be timely found and eliminated, and the construction quality is improved.

Description

Civil engineering hydraulic engineering construction quality detection device

Technical Field

The utility model relates to the technical field of hydraulic engineering construction quality detection, in particular to a civil engineering hydraulic engineering construction quality detection device.

Background

The quality of construction engineering refers to the comprehensive requirements of safety, applicability, economy, environmental protection, beautiful appearance and other characteristics of engineering in the national current related laws, regulations, technical standards, design files and contracts, generally any one large and medium-sized engineering construction project can be divided into a plurality of layers, and the quality control of the construction operation process is the most basic quality control, which determines the quality of related inspection lots. In order to ensure the construction quality, various specified detection means and advanced equipment are adopted for detection, and a supervision unit adopts own equipment for parallel detection, so that reference data is provided for judging the engineering quality.

At present, when the construction quality of civil engineering hydraulic engineering is detected, manual cooperation single instrument is generally adopted for detection, the detection direction is generally single, and in order to improve the construction quality, errors caused by manual detection data are reduced, potential safety hazards caused by the fact that the construction quality is not detected in place are reduced, and a novel detection device for the construction quality of the civil engineering hydraulic engineering is provided.

Disclosure of Invention

The utility model mainly provides the civil engineering hydraulic engineering construction quality detection device which is beneficial to improving the construction quality, improving the accuracy of detection data and effectively avoiding potential safety hazards caused by the fact that the construction quality is not detected in place.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: a civil engineering hydraulic engineering construction quality detection device, comprising: processing agency, sensor mechanism and solar energy mechanism, sensor mechanism fixed mounting is at processing agency's right side surface, solar energy mechanism sets up the rear surface at processing agency, processing agency includes the device shell, the top of device shell is close to the position symmetry fixedly connected with buckle of rear surface, the top fixedly connected with handle of device shell, the interior surface wall of device shell is provided with the sponge layer, the front surface fixed mounting of device shell has the panel, the left side surface of device shell is provided with four connection ends, the left side surface of device shell is close to the position of bottom and is provided with the end that charges, has played the effect of holding interior module through setting up the device shell, has played the effect of conveniently taking this device through setting up the handle, has played the effect to interior module protection through setting up the sponge layer.

Further, the position inside the device shell, which is located at the inner side of the sponge layer, is provided with a data acquisition card, a microprocessor, a central processing unit, a communication module and a battery pack in sequence, the microprocessor and the microprocessor are matched with a data acquisition system, the function of transmitting data acquired by the sensor mechanism to the central processing unit is achieved, the central processing unit controls the operation of the sensor mechanism and the work of the data acquisition system through a control system, the data are transmitted to a remote monitoring center or equipment through an Ethernet or 4G communication network mode through the communication module, the quality of each aspect of civil engineering is detected and monitored, the battery pack achieves the function of supplying power, a charging end head achieves the function of charging the battery pack, and a connecting end head achieves the function of electrically connecting the processing mechanism with the sensor mechanism.

Further, the sensor mechanism comprises a storage shell, a sponge interlayer is arranged in the storage shell, the storage shell is fixedly connected to the outer surface of the right side of the device shell, a door plate is arranged on the right side of the storage shell in a matched mode, the storage shell is matched with the sponge interlayer to play a role in placing sensors, and a certain protection effect is achieved through embedded arrangement.

Further, the position of the inner top of the sponge interlayer, which is close to the top, is embedded with an inclination sensor, the position of the inner part of the sponge interlayer, which is positioned below the inclination sensor, is embedded with a pressure sensor, and the pressure sensor is connected with the processing mechanism through a connecting end and is mainly used for detecting the concrete strength, the bearing capacity of the reinforcing steel bars and the like in construction and monitoring the size, the change and the distribution of the pressure in real time.

Further, the inside of sponge interlayer is located the embedded displacement sensor that is provided with in position below the pressure sensor, the inside of sponge interlayer is located the embedded vibration sensor that is provided with in position below the displacement sensor, and vibration sensor is connected the back through connecting the end with processing mechanism, and the vibration condition of mainly used to the job site is monitored and is recorded, guarantees that can not cause the harm to surrounding environment and structure in the work progress.

Further, solar mechanism includes two rotating blocks, two the symmetry fixed connection of rotating block is close to the position of bottom at device shell rear surface, two rotate between the surface of rotating block and be connected with the spliced pole, the outside fixedly connected with solar charging panel of spliced pole, solar charging panel cooperatees with the buckle, has played the effect of fixed solar charging panel through the buckle, and after solar charging panel spacing was relieved, the decurrent back was played through converting light energy into electric energy for the effect that the group battery was charged, has played the effect of energy saving.

Compared with the prior art, the utility model has the advantages and positive effects that,

1. according to the utility model, the inclination angle sensor and the displacement sensor are used for detecting and monitoring the inclination conditions of hydraulic engineering buildings, the settlement of the buildings, the deformation of foundations and the like in real time, the pressure sensor is used for detecting the concrete strength and the bearing capacity of the steel bars, the composite design requirement and standard specification are ensured, the vibration sensor is used for monitoring and controlling the vibration conditions of a construction site, and then the processed and detected data are transmitted to the detection center through the communication module in real time for real-time detection, monitoring, recording and report generation through the microprocessor, the data acquisition card and the central processing unit, so that human errors are reduced, the measurement accuracy and reliability are improved, the construction efficiency and the management efficiency are improved, potential safety hazards can be found and eliminated in time, and the construction quality is improved.

2. According to the utility model, the solar charging plate is fixed through the buckle, and after the limit of the solar charging plate is released, the solar charging plate rotates downwards, and the battery pack is charged through converting light energy into electric energy, so that the effect of saving energy is achieved.

Drawings

Fig. 1 is a perspective view of a device for detecting construction quality of civil engineering hydraulic engineering, which is provided by the utility model;

fig. 2 is a schematic structural diagram of a processing mechanism of a civil engineering hydraulic engineering construction quality detection device according to the present utility model;

fig. 3 is a schematic structural diagram of a sensor mechanism of a civil engineering hydraulic engineering construction quality detection device according to the present utility model;

fig. 4 is a schematic structural diagram of a solar energy mechanism of a civil engineering hydraulic engineering construction quality detection device according to the present utility model.

Legend description: 1. a processing mechanism; 101. a device housing; 102. a handle; 103. a buckle; 104. a sponge layer; 105. a data acquisition card; 106. a microprocessor; 107. a central processing unit; 108. a communication module; 109. a battery pack; 110. a connecting end; 111. a charging end; 112. a panel; 2. a sensor mechanism; 201. a storage case; 202. a sponge interlayer; 203. an inclination sensor; 204. a pressure sensor; 205. a displacement sensor; 206. a vibration sensor; 207. a door panel; 3. a solar energy mechanism; 301. a rotating block; 302. rotating the column; 303. solar charging panel.

Detailed Description

In order that the above objects, features and advantages of the utility model will be more clearly understood, a further description of the utility model will be rendered by reference to the appended drawings and examples. It should be noted that, without conflict, the embodiments of the present utility model and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, however, the present utility model may be practiced otherwise than as described herein, and therefore the present utility model is not limited to the specific embodiments of the disclosure that follow.

Example 1

As shown in fig. 1 to 4, the present utility model provides a civil engineering hydraulic engineering construction quality detection device according to the embodiment shown in fig. 1, including: the device comprises a processing mechanism 1, a sensor mechanism 2 and a solar mechanism 3, wherein the sensor mechanism 2 is fixedly arranged on the outer surface of the right side of the processing mechanism 1, the solar mechanism 3 is arranged on the rear surface of the processing mechanism 1, the processing mechanism 1 comprises a device shell 101, the top of the device shell 101 is close to the rear surface and is symmetrically and fixedly connected with a buckle 103, the top of the device shell 101 is fixedly connected with a handle 102, the inner surface wall of the device shell 101 is provided with a sponge layer 104, the front surface of the device shell 101 is fixedly provided with a panel 112, the outer surface of the left side of the device shell 101 is provided with four connecting ends 110, the position of the outer surface of the left side of the device shell 101 close to the bottom is provided with a charging end 111, and the position of the inside of the device shell 101, which is positioned on the inner side of the sponge layer 104, is sequentially provided with a data acquisition card 105, a microprocessor 106, a central processing unit 107, a communication module 108 and a battery pack 109.

The effect that its whole embodiment 1 reached is, through setting up the effect that device shell 101 played and held inside module, the effect of conveniently taking this device through setting up handle 102, the effect of protecting inside module has been played through setting up sponge layer 104, through data acquisition card 105 and microprocessor 106 cooperation data acquisition system, the effect of giving central processing unit 107 with the data transmission that sensor mechanism 2 gathered, central processing unit 107 passes through the operation of control system control sensor mechanism 2 and the work of data acquisition system, and detect and monitor the quality in each aspect of civil engineering with data transmission to remote monitoring center or the equipment through communication module 108 through ethernet or 4G communication network mode, battery pack 109 has played the effect of supplying power, charge end 111 has played the effect of charging for battery pack 109, connection end 110 has played the effect of handling mechanism 1 and sensor mechanism 2 electric connection.

Example 2

As shown in fig. 1-4, the sensor mechanism 2 includes a storage shell 201, a sponge interlayer 202 is disposed in the storage shell 201, the storage shell 201 is fixedly connected to the outer surface of the right side of the device shell 101, a door plate 207 is disposed on the right side of the storage shell 201 in a matching manner, an inclination sensor 203 is disposed in a position, close to the top, of the inner top of the sponge interlayer 202, a pressure sensor 204 is disposed in a position, located below the inclination sensor 203, of the inner portion of the sponge interlayer 202, a displacement sensor 205 is disposed in a position, located below the pressure sensor 204, of the inner portion of the sponge interlayer 202, and a vibration sensor 206 is disposed in a position, located below the displacement sensor 205, of the inner portion of the sponge interlayer 202.

The effect that its whole embodiment 2 reaches is, put thing shell 201 cooperation sponge interlayer 202 has played the effect of placing each sensor, play certain guard action through embedded setting, tilt sensor 203 is connected through connecting end 110 and processing mechanism 1, the tilting condition of hydraulic engineering building is mainly used to be detected, in time discover the tilting problem and take corresponding measure in time to restore, pressure sensor 204 is connected through connecting end 110 and processing mechanism 1 the back, mainly used detects concrete strength in the construction and the bearing capacity of reinforcing bar etc. and real-time monitoring pressure's size, change and distribution condition, displacement sensor 205 is connected through connecting end 110 and processing mechanism 1 the back, mainly used detects the construction time, sedimentation of building, deformation of foundation etc. through measuring the size, speed and the direction of displacement, in time discover the problem and take the restoration, vibration sensor 206 is connected through connecting end 110 and processing mechanism 1 the back, mainly used to monitor and record the vibrations condition of job site, ensure that can not cause harm to surrounding environment and structure in the work process.

Example 3

As shown in fig. 1-4, the solar energy mechanism 3 includes two rotating blocks 301, the symmetrical fixing connection of the two rotating blocks 301 is at the position of the rear surface of the device housing 101 near the bottom, a rotating column 302 is rotatably connected between the outer surfaces of the two rotating blocks 301, a solar charging plate 303 is fixedly connected to the outer part of the rotating column 302, and the solar charging plate 303 is matched with the buckle 103.

The effect that its whole embodiment 3 reaches is, has played the effect of fixed solar charging panel 303 through buckle 103, and after solar charging panel 303 spacing was relieved, the back of rotating down has played the effect of charging for group battery 109 through converting light energy into electric energy, has played the effect of energy saving.

The application method and the working principle of the device are as follows: when the civil engineering hydraulic engineering is constructed, the device is carried to reach a designated place, then the inclination sensor 203, the pressure sensor 204, the displacement sensor 205 and the vibration sensor 206 are connected with the processing mechanism 1 through the connecting end 110, and each sensor is installed to a position to be detected according to actual conditions, the inclination sensor 203 is mainly used for detecting the inclination condition of the hydraulic engineering building, timely finding the inclination problem and timely taking corresponding measures for repairing, the displacement sensor 205 is mainly used for detecting the settlement of the building, the deformation of the foundation and the like during construction, timely finding the problem and taking measures for repairing by measuring the size, the speed and the direction of displacement, thereby avoiding the occurrence of potential safety hazards, the pressure sensor 204 is mainly used for detecting the concrete strength, the bearing capacity of the reinforcing steel bars and the like during construction, and monitoring the size, the change and the distribution condition of pressure in real time, the vibration sensor 206 is mainly used for monitoring and recording the vibration condition of a construction site, ensuring that the surrounding environment and the structure are not damaged in the construction process, meanwhile, the data acquisition card 105 and the microprocessor 106 are matched with a data acquisition system to play a role in transmitting the data acquired by the sensor mechanism 2 to the central processing unit 107, the central processing unit 107 controls the operation of the sensor mechanism 2 and the work of the data acquisition system through a control system, and transmits the data to a remote monitoring center or equipment through a communication module 108 in an Ethernet or 4G communication network mode to detect and monitor the quality of various aspects of civil engineering, the sensors can automatically measure and record, the human error is reduced, the accuracy and the reliability of measurement are improved, and the processing mechanism 1 and the sensor mechanism 2 are matched with each other, so that data can be processed and analyzed in time to generate corresponding reports, the construction efficiency and the management efficiency are improved, potential safety hazards are found and eliminated in time, and meanwhile, the construction quality is improved.

The present utility model is not limited to the above-mentioned embodiments, and any equivalent embodiments which can be changed or modified by the technical content disclosed above can be applied to other fields, but any simple modification, equivalent changes and modification made to the above-mentioned embodiments according to the technical substance of the present utility model without departing from the technical content of the present utility model still belong to the protection scope of the technical solution of the present utility model.

Claims (6)

1. A civil engineering hydraulic engineering construction quality detection device, comprising: the solar energy treatment device is characterized in that the sensor mechanism (2) is fixedly arranged on the outer surface of the right side of the treatment mechanism (1), and the solar energy mechanism (3) is arranged on the rear surface of the treatment mechanism (1);

the processing mechanism (1) comprises a device shell (101), a buckle (103) is symmetrically and fixedly connected to the top of the device shell (101) close to the rear surface, a handle (102) is fixedly connected to the top of the device shell (101), a sponge layer (104) is arranged on the inner surface of the device shell (101), a panel (112) is fixedly arranged on the front surface of the device shell (101), four connecting ends (110) are arranged on the left outer surface of the device shell (101), and a charging end (111) is arranged at the position, close to the bottom, of the left outer surface of the device shell (101).

2. The civil engineering hydraulic engineering construction quality detection device according to claim 1, wherein: the device is characterized in that a data acquisition card (105), a microprocessor (106), a central processing unit (107), a communication module (108) and a battery pack (109) are sequentially arranged in the device shell (101) at the inner side of the sponge layer (104).

3. The civil engineering hydraulic engineering construction quality detection device according to claim 1, wherein: the sensor mechanism (2) comprises a storage shell (201), a sponge interlayer (202) is arranged in the storage shell (201), the storage shell (201) is fixedly connected to the outer surface of the right side of the device shell (101), and a door plate (207) is arranged on the right side of the storage shell (201) in a matching mode.

4. A civil engineering hydraulic engineering construction quality detection device according to claim 3, characterized in that: the position of the inner top of the sponge interlayer (202) close to the top is embedded to be provided with an inclination sensor (203), and the position of the inner part of the sponge interlayer (202) below the inclination sensor (203) is embedded to be provided with a pressure sensor (204).

5. A civil engineering hydraulic engineering construction quality detection device according to claim 3, characterized in that: the inside of sponge interlayer (202) is located the position of pressure sensor (204) below and is embedded to be provided with displacement sensor (205), the inside of sponge interlayer (202) is located the position of displacement sensor (205) below and is embedded to be provided with vibration sensor (206).

6. The civil engineering hydraulic engineering construction quality detection device according to claim 1, wherein: the solar energy mechanism (3) comprises two rotating blocks (301), the symmetrical fixing connection of the two rotating blocks (301) is arranged at the position, close to the bottom, of the rear surface of the device shell (101), a rotating column (302) is rotatably connected between the outer surfaces of the two rotating blocks (301), a solar charging plate (303) is fixedly connected to the outer portion of the rotating column (302), and the solar charging plate (303) is matched with the buckle (103).