CN114593720A

CN114593720A - Engineering building construction quality straightness detection system that hangs down

Info

Publication number: CN114593720A
Application number: CN202210193669.1A
Authority: CN
Inventors: 韩欣乐
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-03-01
Filing date: 2022-03-01
Publication date: 2022-06-07

Abstract

The invention discloses an engineering building construction quality verticality detection system which comprises detection equipment and a system control end, wherein the system control end is a main control end, the detection equipment comprises a measuring frame, a hydraulic lifting rod and a main control end, a hydraulic rod connecting end is arranged on the hydraulic lifting rod and is connected with the main control end through a circuit, a support frame is arranged at the bottom of the hydraulic lifting rod, the support frame is of a triangular support structure and is fixedly locked with the bottom of the hydraulic lifting rod through screws, and a telescopic end of the hydraulic lifting rod is fixedly connected with the measuring frame through screws. This building squareness measurement system mainly realizes through measuring equipment and main control end cooperation, and the verticality measurement mode takes a lot of range finding through laser range finder's longitudinal movement at the in-process that removes, through the contrast of many times range finding data, presents the straightness condition of hanging down of building, and measuring speed is fast, efficient.

Description

Engineering building construction quality straightness detection system that hangs down

Technical Field

The invention relates to the technical field of engineering building perpendicularity detection, in particular to an engineering building construction quality perpendicularity detection system.

Background

The construction engineering refers to the installation engineering of various technical works and completed engineering entities such as planning, surveying, designing, constructing and completing for newly building, reconstructing or extending building structures and auxiliary structure facilities, and the lines, pipelines and equipment matched with the engineering entities, and also refers to the construction engineering of various buildings and structures, and is also called the construction workload.

In the building construction process, after the basic building construction is finished, the building needs to be subjected to perpendicularity detection, the traditional detection mode generally adopts a line body vertical detection method, a line body is fixed at the top end of the building, components fixed on the line body are subjected to free falling, measurement is carried out through an angle instrument or a distance measuring instrument, and the line body vertical detection method can realize the perpendicularity detection of the building, but the mode is easily influenced by external factors (wind and external force vibration), meanwhile, the detection mode is complex in flow, needs multiple persons for assistance, and is low in measurement efficiency.

Disclosure of Invention

The invention aims to provide a system for detecting the construction quality verticality of an engineering building, which aims to solve the problems of complicated process and low efficiency of the traditional building verticality measurement method in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a verticality detection system for construction quality of engineering buildings comprises detection equipment and a system control end, wherein the system control end is a main control end, the detection equipment comprises a measuring frame, a hydraulic lifting rod and a main control end, a hydraulic rod connecting end is arranged on the hydraulic lifting rod and is connected with the main control end through a circuit, a support frame is arranged at the bottom of the hydraulic lifting rod, the support frame is of a triangular support structure and is locked and fixed with the bottom of the hydraulic lifting rod through screws, and a telescopic end of the hydraulic lifting rod is fixedly connected with the measuring frame through screws; the measuring frame is of a U-shaped structure, a winding box is fixed to the top of the measuring frame, a first control box is fixed to the top of the winding box, a motor is fixed to the side end of the winding box, a wire spool is arranged inside the winding box, one end of the wire spool is connected with the inner wall of one side of the winding box through a rotating screw, the other end of the wire spool is connected with a transmission end of the motor through a coupler, wire holes are formed in the bottom surface of the inside of the winding box, sliding rods are welded to the two sides of a U-shaped opening of the measuring frame, a measuring carrier plate is embedded between the sliding rods, a laser range finder, a second control box and a wire body fixing buckle are fixed to the measuring carrier plate in a penetrating mode, and the wire body end of the wire spool is locked and fixed to the wire body fixing buckle on the measuring carrier plate.

As a preferred embodiment of the present invention, sliding seats are welded on two sides of the measurement carrier plate, sliding rails are arranged on sliding rods on two sides of the measurement carrier plate, the sliding rails are connected with the sliding seats in an embedded manner, and lubricating oil is sprayed in the sliding rails.

As a preferred embodiment of the present invention, a first infrared receiver, a motor battery and a first main board are arranged in the first control box, the first main board is respectively connected with the first infrared receiver, the motor battery and the motor through circuits, and the first infrared receiver is remotely connected with the main control end through infrared rays.

As a preferred embodiment of the present invention. Be equipped with second infrared receiver, main storage battery, second mainboard and signal transmission ware in the second control box, the second mainboard passes through the circuit and is connected with second infrared receiver, main storage battery, signal transmission ware and laser range finder respectively, signal transmission ware is network signal transmission ware and through network and main control end remote connection, second infrared receiver passes through infrared ray and main control end remote connection.

As a preferred embodiment of the present invention, the first circuit board is provided with a first power interface, a first infrared signal connection port, a first signal analysis module, a motor control module, a first device interface, and a first main control chip, the first power interface is connected to a motor battery through a connection line, the first red signal connection port is respectively connected to a first infrared receiver and the first signal analysis module through a signal line, the first signal analysis module is connected to the first main control chip through a data line, the first main control chip is connected to the motor control module through a data line, the motor control module is connected to the first device interface through a connection line, and the first device interface is connected to the motor through a connection line.

As a preferred embodiment of the present invention, a second power interface, a second infrared signal connection port, an integrated interface, a data transmission interface, a network card, a second signal analysis module, and a second main control chip are disposed on the second motherboard, the second power interface is connected to the main battery through a connection line, the second infrared signal connection port is connected to the second infrared receiver and the second signal analysis module through a signal line, the second signal analysis module is connected to the second main control chip through a data line, the second main control chip is connected to the data transmission interface and the integrated interface through a data line and an integrated line, the data transmission interface is connected to the signal transmitter through a data line, the integrated interface is connected to the laser range finder through an integrated line, and the integrated line is composed of a power line and a data transmission line.

As a preferred embodiment of the present invention, the main control end includes a host, a first infrared signal transmitter, a second infrared signal transmitter, and a signal receiver, the first infrared signal transmitter, the second infrared signal transmitter, and the signal receiver are connected to the host through signal lines, a data processing system is disposed in the host, and the data processing system includes an equipment control unit, a signal transmitting unit, a signal receiving unit, a measured data determining unit, and a display unit.

Compared with the prior art, the invention has the beneficial effects that:

this building straightness measurement system that hangs down, mainly realize through measuring equipment and main control end cooperation, the measurement form adopts the measured form of sectional type, according to the height of building, drive the measuring frame through hydraulic lifting rod and measure the vertical face to building different positions, this measuring mode, can the concrete position interval of skew of accurate building, the pertinence is restoreed, the straightness measurement mode that hangs down simultaneously, longitudinal movement through laser range finder, at the in-process that removes, take many times to find range, through the contrast of many times range finding data, the straightness condition of hanging down of building appears, if the range of being convenient for between the data is great, the condition that the skew appears in this interval-measuring building of description, this measuring equipment's operation and data's transmission simultaneously, the receipt all adopts the remote control mode, measuring speed is fast, high efficiency.

Drawings

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

FIG. 2 is a schematic view of the measuring stand according to the present invention;

FIG. 3 is a schematic view of the structure of the winding box of the present invention;

FIG. 4 is a schematic view of a measurement carrier structure according to the present invention;

FIG. 5 is a control flow chart of the present invention.

In the figure: 1-a measuring frame, 2-a hydraulic lifting rod, 3-a supporting frame, 4-a hydraulic rod connecting end, 5-a measuring carrier plate, 6-a winding box, 7-a sliding rod, 8-a first control box, 9-a motor, 10-a wire reel, 11-a wire hole, 12-a laser range finder, 13-a sliding seat, 14-a second control box and 15-a wire body fixing buckle.

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. 1-5, the present invention provides a technical solution:

a verticality detection system for construction quality of engineering buildings comprises detection equipment and a system control end, wherein the system control end is a main control end, the detection equipment comprises a measuring frame 1, a hydraulic lifting rod 2 and a main control end, a hydraulic rod connecting end 4 is arranged on the hydraulic lifting rod 2, the hydraulic rod connecting end 4 is connected with the main control end through a circuit, a support frame 3 is arranged at the bottom of the hydraulic lifting rod 2, the support frame 3 is of a triangular support structure and is locked and fixed with the bottom of the hydraulic lifting rod 2 through screws, and a telescopic end of the hydraulic lifting rod 2 is fixedly connected with the measuring frame 1 through screws; the measuring frame 1 is of a U-shaped structure, a winding box 6 is fixed at the top of the measuring frame 1, a first control box 8 is fixed at the top of the winding box 6, a motor 9 is fixed at the side end of the winding box 6, a winding disc 10 is arranged in the winding box 6, one end of the winding disc 10 is connected with the inner wall of one side of the winding box 6 through a rotating screw, the other end of the winding disc is connected with a transmission end of the motor 9 through a coupler, a wire hole 11 is arranged on the bottom surface in the winding box 6, slide bars 7 are welded at two sides of a U-shaped opening of the measuring frame 1, a measuring support plate 5 is embedded between the slide bars 7, a laser range finder 12, a second control box 14 and a wire body fixing buckle 15 are fixed on the measuring support plate 5, the end of a wire body of the winding disc 10 penetrates through the wire hole 11 and is locked and fixed with the wire body fixing buckle 15 on the measuring support plate 5, the detecting system is mainly realized by matching with a main control end, and adopts a remote control mode through the main control end, the detection device is controlled in a vertical measurement mode, a wire spool 10 is mainly driven by a motor 9, the wire spool 10 is wound, so that a laser range finder 12 on a measurement support plate 5 longitudinally moves, in the longitudinal movement process, the change condition of the distance between the side face of a construction building and the laser range finder 12 is measured, if the distance change is large and exceeds a standard range, the condition that the construction building deviates is indicated, and the detection mode has high detection speed and high efficiency.

The two sides of the measuring carrier plate 5 are welded with the sliding seats 13, the sliding rods 7 on the two sides of the measuring carrier plate 5 are provided with the sliding ways, the sliding ways are connected with the sliding seats 13 in an embedded mode, lubricating oil is sprayed in the sliding ways, the measuring carrier plate 5 is embedded in the sliding rods 7 through the sliding seats 13, the longitudinal movement of the measuring carrier plate 5 is limited through the sliding rods 7, the influence of external factors is avoided, the position deviation situation is caused, the measuring accuracy is guaranteed, the lubricating oil reduces the friction generated between the sliding seats 13 and the sliding ways, and the sliding smoothness is improved.

A first infrared receiver, a motor storage battery and a first main board are arranged in the first control box 8, the first main board is respectively connected with the first infrared receiver, the motor storage battery and the motor 9 through circuits, the first infrared receiver is remotely connected with a main control end through infrared rays, the first control box 8 mainly realizes the receiving of execution information and the control of the motor 9, the motor storage battery mainly supplies power to the first main board and the motor 9, the first infrared receiver receives execution signals sent by the main control end remotely, the motor 9 is controlled by the first main board through the received signals, so that the winding and unwinding of the winding disc 10 are achieved, the longitudinal movement of the measurement carrier plate 5 is realized, the type of a receiving pipe of the first infrared receiver is HS0038, the type of the first main board is GAMX-2007-T, the type of the motor 9 is ZGA37RG, and a second infrared receiver is arranged in the second control box 14, The main battery jar provides power transmission for the second main board and the laser range finder 12, the second infrared receiver receives an execution signal of the main control end, the second main board controls the laser range finder 12, multiple measured data can be transmitted to the signal transmitter and remotely transmitted to the main control end by the signal transmitter through the network in the longitudinal range finding process, the receiving tube model of the second infrared receiver is HS0038, the model of the second main board is GAMX-2014H, and the model of the signal transmitter is TY-CX 5100.

The first circuit board is provided with a first power interface, a first infrared signal connection port, a first signal analysis module, a motor control module, a first equipment interface and a first main control chip, the first power interface is connected with a motor battery through a connecting wire, the first red wire signal connection port is respectively connected with a first infrared receiver and the first signal analysis module through signal wires, the first signal analysis module is connected with the first main control chip through a data wire, the first main control chip is connected with the motor control module through a data wire, the motor control module is connected with the first equipment interface through a connecting wire, the first equipment interface is connected with the motor 9 through a connecting wire, the first main board is mainly in electric connection and analyzes signals received by infrared rays, the motor control module is used for controlling the motor 9 according to the signals, the motor 9 operates, and therefore the wire collection and the wire release of the measuring plate 5 are realized, the selectable model of the first control chip is STM32F103C8T6, a second power supply interface, a second infrared signal connection port, an integrated interface, a data transmission interface, a network card, a second signal analysis module and a second main control chip are arranged on a second main board, the second power supply interface is connected with a main battery through a connecting line, the second infrared signal connection port is respectively connected with a second infrared receiver and a second signal analysis module through a signal line, the second signal analysis module is connected with the second main control chip through a data line, the second main control chip is respectively connected with the data transmission interface and the integrated interface through a data line and an integrated line, the data transmission interface is connected with a signal transmitter through a data line, the integrated interface is connected with the laser range finder 12 through an integrated line, the integrated line is composed of a power line and a data transmission line, the second main board mainly realizes power communication, analyzes signals received by infrared rays and receives and transmits data measured by the laser range finder 12, in the process of longitudinal movement of the measurement carrier plate 5, the second control chip receives and transmits the measured data in real time, and the measured data is transmitted to the main control end through the signal transmitter through the network, so that real-time uploading of the data is realized, and the selectable model of the second main control chip is ATMEGA 328P-AU.

The main control end comprises a host, a first infrared signal transmitter, a second infrared signal transmitter and a signal receiver, the first infrared signal transmitter, the second infrared signal transmitter and the signal receiver are connected with the host through signal lines, a data processing system is arranged in the host, the data processing system comprises an equipment control unit, a signal sending unit, a signal receiving unit, a measured data judging unit and a display unit, the main control end mainly comprises a PC host, the sending and receiving of signals are realized by a signal transmission device, the first infrared signal transmitter, the second infrared signal transmitter and the signal receiver are all arranged in the host, the hydraulic lifting rod 2 is directly connected to a control port of the host through a circuit, an instruction is sent through hardware input equipment, and the data setting, receiving and judging are realized through the data processing system, the transmitting tubes of the first infrared signal transmitter and the second infrared signal transmitter are both in a SIP3-HS0038BD model, and the signal transmitter and the signal receiver are signal equipment in the same model.

In the process of verticality detection, the laser range finder 12 is restricted by two factors: the vertical moving speed of the measuring carrier plate 5 and the shooting gap time of the laser range finder 12 are measured, therefore, the accurate situation of the contrast data is ensured, the mode of slow moving and fast shooting can be adopted, so that more measurement data can be obtained, under the contrast of various data, the accuracy of measurement and the accuracy of judgment can be ensured, meanwhile, when facing buildings of different types or structures, the rotating speed of the motor 9 and the shooting gap of the laser range finder 12 can be set according to specific measurement standards, and the optimal measurement effect is achieved.

In summary, before measurement, the electric quantity of the motor power supply and the main power supply needs to be ensured, when measurement is performed, the measurement device is moved to a measurement point of a building, the whole measurement device is supported by the support frame 3, meanwhile, the ground of the support frame 3 is also ensured to be flat, the whole device is ensured to be in a vertical state with the ground, the hydraulic lifting rod 2 is controlled by the main control end, the measurement frame 1 is moved to a measurement area by the hydraulic lifting rod 2, then the main control end simultaneously sends execution signals to the first infrared receiver and the second infrared receiver in the first control box 8 and the second control box 14 respectively, the motor 9 is started after the first main board receives the signals, the laser range finder 12 is started after the second main board receives the signals, the motor 9 drives the wire winding disc 10 to rotate to realize wire paying off, the measurement support plate 5 longitudinally moves between the slide bars 7 at two sides of the measurement frame 1, the movement of the measurement support plate 5 and the measurement of the laser range finder 12 are in a synchronous state, laser range finder 12 is at the in-process of measuring support plate 5 longitudinal movement, and measure the range finding to the building many times, and on measuring data transmission arrived the second mainboard, the second mainboard passes through signal transmitter with data with the help of network remote transmission to the main control end, main control end data processing system received data back, contrasts data with the threshold value of settlement in proper order, and contrast structure will present through display device, if the building is higher, only need the lift of accessible hydraulic lifting rod 2 to measure the different regions of building.

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 an engineering construction quality straightness detection system that hangs down which characterized in that: the device comprises detection equipment and a system control end, wherein the system control end is a main control end, the detection equipment comprises a measuring frame (1), a hydraulic lifting rod (2) and a main control end, a hydraulic rod connecting end (4) is arranged on the hydraulic lifting rod (2), the hydraulic rod connecting end (4) is connected with the main control end through a circuit, a support frame (3) is arranged at the bottom of the hydraulic lifting rod (2), the support frame (3) is of a triangular support structure and is locked and fixed with the bottom of the hydraulic lifting rod (2) through a screw, and a telescopic end of the hydraulic lifting rod (2) is fixedly connected with the measuring frame (1) through a screw;

the measuring rack (1) is of a U-shaped structure, a winding box (6) is fixed at the top of the measuring rack (1), a first control box (8) is fixed at the top of the winding box (6), a motor (9) is fixed at the side end of the winding box (6), a winding disc (10) is arranged inside the winding box (6), one end of the winding disc (10) is connected with the inner wall of one side of the winding box (6) through a rotating screw, the other end of the winding disc is connected with the transmission end of the motor (9) through a coupler, a wire hole (11) is formed in the bottom surface inside the winding box (6), two sides of a U-shaped opening of the measuring rack (1) are welded with a support plate (7), a measuring support plate (5) is embedded between the slide plates (7), a laser range finder (12), a second control box (14) and a wire body fixing buckle (15) are fixed on the measuring rack (5), the wire body end penetrating hole (11) of the wire spool (10) is locked and fixed with a wire body fixing buckle (15) on the measuring carrier plate (5).

2. The engineering building construction quality verticality detection system according to claim 1, characterized in that: the welding of the both sides of measuring support plate (5) has slide (13), be equipped with the slide on slide bar (7) of measuring support plate (5) both sides, the slide is connected with slide (13) gomphosis, the spraying has lubricating oil in the slide.

3. The engineering building construction quality verticality detection system according to claim 1, characterized in that: be equipped with first infrared receiver, motor storage battery and first mainboard in first control box (8), first mainboard passes through the circuit and is connected with first infrared receiver, motor storage battery and motor (9) respectively, first infrared receiver passes through infrared ray and main control end remote connection.

4. The engineering building construction quality verticality detection system according to claim 1, characterized in that: be equipped with second infrared receiver, main storage battery, second mainboard and signal transmission ware in second control box (14), the second mainboard passes through the circuit and is connected with second infrared receiver, main storage battery, signal transmission ware and laser range finder (12) respectively, signal transmission ware is network signal transmission ware and through network and main control end remote connection, second infrared receiver passes through infrared ray and main control end remote connection.

5. The engineering building construction quality verticality detection system according to claim 3, wherein: be equipped with first power source, first infrared signal connection port, the analytic module of first signal, motor control module, first equipment interface and first main control chip on the first circuit board, first power source passes through the connecting wire and is connected with the motor storage battery, first red line signal connection port passing signal line respectively with the analytic module of first infrared receiver and first signal, the analytic module of first signal passes through the data line and is connected with first main control chip, first main control chip passes through the data line and is connected with motor control module, motor control module passes through connecting wire and first equipment interface connection, first equipment interface passes through the connecting wire and is connected with motor (9).

6. The engineering building construction quality verticality detection system according to claim 4, wherein: be equipped with second power source, second infrared signal connection port, integrated interface, data transmission interface, network card, the analytic module of second signal and second main control chip on the second mainboard, second power source passes through the connecting wire and is connected with main vase, second infrared signal connection port passes through the signal line and is connected with the analytic module of second infrared receiver and second signal respectively, the analytic module of second signal passes through the data line and is connected with second main control chip, second main control chip passes through the data line and the integrated line respectively with data transmission interface and integrated interface connection, the data transmission interface passes through the data line and is connected with signal transmitter, integrated interface is connected with laser range finder (12) through integrated line, integrated line comprises power line and data transmission line.

7. The engineering building construction quality verticality detection system according to claim 1, characterized in that: the main control end comprises a host, a first infrared signal transmitter, a second infrared signal transmitter and a signal receiver, wherein the first infrared signal transmitter, the second infrared signal transmitter and the signal receiver are connected with the host through signal lines, a data processing system is arranged in the host, and the data processing system is composed of an equipment control unit, a signal sending unit, a signal receiving unit, a measured data judging unit and a display unit.