CN111521166A - Highway engineering measuring device based on solar technology - Google Patents

Abstract

The invention discloses a solar technology-based highway engineering measuring device which comprises an engineering measuring instrument, wherein the engineering measuring instrument comprises a triangular support positioned at the bottom and a measuring instrument body arranged at the top of the triangular support, the lower end of the triangular support is provided with a guide groove, three groups of conical rods are uniformly arranged at the bottom of the triangular support, guide blocks are fixed at the upper ends of the conical rods and movably arranged in the guide groove, an electric regulator is arranged between the conical rods and the triangular support, the electric regulator comprises an electric push rod with the upper end fixed on the outer side of the triangular support and a connecting sheet fixed at the tail end of the electric push rod, the connecting sheet is fixed on the conical rods through bolts, an installation top disc is horizontally arranged at the top of the triangular support, an electronic gyroscope is arranged at the bottom of the installation top disc, the measuring instrument body is arranged on the installation. The automatic adjusting mechanism is designed at the bottom of the triangular supporting rod, and automatically adjusts the levelness of the triangular supporting rod.

Description

Highway engineering measuring device based on solar technology

Technical Field

The invention relates to the technical field of engineering measuring devices, in particular to a road engineering measuring device based on a solar technology.

Background

The measuring instrument is a third-party standard required for measuring in order to obtain certain attribute values of a target object, the measuring instrument generally has units such as scales and volumes, and the measuring instrument is required to be frequently used for measuring in order to improve the construction accuracy in the construction process of highway engineering, wherein the measuring instrument comprises an engineering level measuring instrument.

However, the conventional engineering level gauge has the following problems in the use process: (1) the leveling instrument generally comprises a triangular supporting rod and a level instrument body, the levelness of the level instrument needs to be kept due to uneven ground in the working process, repeated adjustment is mainly carried out in a manual adjustment mode, and the adjustment mode is inconvenient and poor in effect; (2) in order to improve the safety of the level body, the level body is usually installed at the top of the triangular support rod by using a fixing structure, and the level body is inconvenient to detach and install. For this reason, a corresponding technical scheme needs to be designed to solve the existing technical problems.

Disclosure of Invention

The invention aims to provide a road engineering measuring device based on a solar technology, which solves the problems in the background technology and meets the actual use requirements.

In order to achieve the purpose, the invention provides the following technical scheme: a road engineering measuring device based on a solar technology comprises an engineering measuring instrument, wherein the engineering measuring instrument comprises a triangular support positioned at the bottom and a measuring instrument body arranged at the top of the triangular support, the lower end of the triangular support is provided with a guide groove, three groups of conical rods are uniformly arranged at the bottom, guide blocks are fixed at the upper ends of the conical rods and movably arranged in the guide groove, an electric regulator is arranged between the conical rods and the triangular support, the electric regulator comprises an electric push rod with the upper end fixed outside the triangular support and a connecting sheet fixed at the tail end of the electric push rod, the connecting sheet is fixed on the conical rods through bolts, an installation top disc is horizontally arranged at the top of the triangular support, an electronic gyroscope is arranged at the bottom of the installation top disc, the measuring instrument body is arranged on the installation top disc, and a solar power supply structure is arranged outside the measuring instrument body, the solar power supply structure comprises solar cell panel, dc-to-ac converter, transformer and reserve battery, solar cell panel passes through the hinge symmetry and installs in the both sides of measuring apparatu body and be connected with the dc-to-ac converter electricity, the dc-to-ac converter is connected with the transformer electricity, the transformer is connected with reserve battery, reserve battery installs in the one end of measuring apparatu body and one side installs main battery, reserve battery and the main battery outside are fixed with the shell, install the display screen on the shell, be connected with the PLC controller between display screen and the electron gyroscope, the PLC controller is connected with electric putter.

As a preferred embodiment of the present invention, a butt joint mounting seat is mounted at the bottom of the mounting top disk and the measuring instrument body, the butt joint mounting seat is of a two-section structure and includes a lower disk fixed on the mounting top disk and an upper disk located above the lower disk, and the upper disk is fixed at the bottom of the measuring instrument body.

As a preferred embodiment of the present invention, the middle of the lower tray is provided with a butt-joint groove, six sets of L-shaped clamping plates are uniformly arranged on the periphery of the butt-joint groove, and the bottom of the upper tray is provided with six sets of clamping grooves used in cooperation with the L-shaped clamping plates.

As a preferred embodiment of the present invention, two sets of L-shaped snap-gauge are symmetrically disposed and have elastic limiting pieces mounted on one side thereof, and the elastic limiting pieces are formed with bumps.

As a preferred embodiment of the present invention, two sets of symmetrically disposed slots are provided with a limiting opening at one side, the limiting opening is located on the upper surface of the upper disc, and the protrusion is buckled in the limiting opening.

As a preferred embodiment of the present invention, the engineering measurement instrument is further controlled by a measurement instrument control system, the measurement instrument control system is divided into a power supply system, an operating system, a display module, a balance measurement module, a control module, and a driving adjustment module, and the power supply system includes an external charging module and a solar charging module.

As a preferred embodiment of the present invention, the power supply system provides a power supply for the operation of the operation system, the display module, the balance degree measurement module, the control module and the driving adjustment module, the display module displays the data information of the operation system and the data information of the balance degree measurement module, and the control module controls the driving adjustment module to operate and display in real time through the reality module.

In a preferred embodiment of the invention, the engineering measuring instrument is powered by the main battery preferentially and the standby battery as an auxiliary power supply.

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

1. the scheme has automatic regulating mechanism in the bottom design of triangular support pole this year, can measure the levelness of spirit level body and show data transmission to the display screen on through the electron gyroscope of top, and the control data that the staff can be clear observes the levelness of triangular support pole and predetermine through the PLC controller controls electric putter and operates to reach and carry out automatically regulated to the levelness of triangular support pole, improve the degree of automation of device.

2. Install solar energy power supply structure on the measuring apparatu and can gather and the storage utilizes the sunlight under the better condition of light, improve the functionality of device to improved at the measuring apparatu body and the overhead structure of triangular support pole, made things convenient for the measuring apparatu body to carry out rotation type installation and dismantlement, easy operation convenient to use.

Drawings

FIG. 1 is an overall block diagram of the present invention;

FIG. 2 is a top view of the lower plate of the present invention;

FIG. 3 is a bottom structural view of the upper tray according to the present invention;

fig. 4 is a schematic diagram of a control system of the surveying instrument according to the present invention.

In the figure, the device comprises a triangular support 1, a measuring instrument body 2, a guide groove 3, a conical rod 4, a guide block 5, an electric push rod 6, a connecting sheet 7, a mounting top plate 8, an electronic gyroscope 9, a solar panel 10, an inverter 11, a transformer 12, a spare storage battery 13, a main storage battery 14, a shell 15, a display screen 16, a PLC 17, a butt joint mounting seat 18, a lower plate 19, an upper plate 20, a butt joint groove 21, an L-shaped clamping plate 22, a clamping groove 23, an elastic limiting sheet 24, a convex block 25 and a limiting port 26.

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. 1-4, the present invention provides a technical solution: a road engineering measuring device based on a solar technology comprises an engineering measuring instrument, wherein the engineering measuring instrument comprises a triangular support 1 positioned at the bottom and a measuring instrument body 2 arranged at the top of the triangular support 1, the triangular support 1 adopts a triangular support 1 which operates synchronously, a guide groove 3 is formed in the lower end of the triangular support 1, three groups of conical rods 4 are uniformly arranged at the bottom of the triangular support 1, guide blocks 5 are fixed at the upper ends of the conical rods 4, the guide blocks 5 are movably arranged in the guide grooves 3, an electric regulator is arranged between each conical rod 4 and the triangular support 1, the electric regulator comprises an electric push rod 6 of which the upper end is fixed on the outer side of the triangular support 1 and a connecting sheet 7 fixed at the tail end of the electric push rod 6, the connecting sheet 7 is fixed on the conical rods 4 through bolts, an installation top disc 8 is horizontally arranged at the top of the triangular support, the measuring instrument body 2 is installed on the installation top plate 8, a solar power supply structure is arranged outside the installation top plate, the solar power supply structure is composed of a solar cell panel 10, an inverter 11, a transformer 12 and a standby storage battery 13, the solar cell panel 10 is symmetrically installed on two sides of the measuring instrument body 2 through hinges and is electrically connected with the inverter 11, the inverter 11 is electrically connected with the transformer 12, the transformer 12 is connected with the standby storage battery 13, the standby storage battery 13 is installed at one end and one side of the measuring instrument body 2 and is provided with a main storage battery 14, a shell 15 is fixed on the outer sides of the standby storage battery 13 and the main storage battery 14, a display screen 16 is installed on the shell 15, a PLC 17 is connected between the display screen 16 and the electronic gyroscope 9, and the.

Further improved, as shown in fig. 1: the installation top disc 8 and the bottom of the measuring instrument body 2 are provided with a butt joint installation seat 18, the butt joint installation seat 18 is of a two-section structure and comprises a lower disc 19 fixed on the installation top disc 8 and an upper disc 20 positioned above the lower disc 19, and the upper disc 20 is fixed at the bottom of the measuring instrument body 2.

Further improved, as shown in fig. 2 and 3: the middle part of the lower disc 19 is provided with a butt joint groove 21, six groups of L-shaped clamping plates 22 are uniformly arranged on the periphery of the butt joint groove 21, and the bottom of the upper disc 20 is provided with six groups of clamping grooves 23 matched with the L-shaped clamping plates 22 for use.

Further improved, as shown in fig. 2: wherein, one side of two sets of L-shaped clamping plates 22 which are symmetrically arranged is provided with an elastic limiting sheet 24, and a convex block 25 is formed on the elastic limiting sheet 24.

In a further improvement, as shown in fig. 3: wherein, one side of two sets of draw-in grooves 23 that the symmetry set up is seted up spacing mouth 26, and spacing mouth 26 is located the upper surface of hanging wall 20, and lug 25 buckle and spacing mouth 26 are interior, correspond to block in spacing mouth 26 through lug 25 and can reach the purpose to hanging wall 20 and lower wall 19 butt joint installation.

Further improved, as shown in fig. 4: the engineering measuring instrument is further controlled by a measuring instrument control system, the measuring instrument control system is divided into a power supply system, an operation system, a display module, a balance degree measuring module, a control module and a driving adjusting module, and the power supply system comprises an external charging module and a solar charging module.

Further improved, as shown in fig. 4: the power supply system provides power for the operation of the operation system, the display module, the balance degree measuring module, the control module and the driving adjusting module, the display module displays data information of the operation system and data information of the balance degree measuring module, and the control module controls the driving adjusting module to operate and display the data information in real time through the reality module.

Specifically, the engineering measuring instrument uses the main storage battery 14 to supply power preferentially and uses the standby storage battery 13 to supply power as auxiliary power, and the power source of the main storage battery 14 is mainly charged through an external power supply.

When in use: when the engineering measuring instrument needs to be used, firstly, the measuring instrument body 2 is erected at the top of the triangular bracket 1, the upper disc 20 is correspondingly clamped into the butt joint groove 21 of the lower disc 19, the L-shaped clamping plate 22 is correspondingly clamped into the clamping groove 23, then the upper disc 20 is rotated, the lug 25 is clamped into the limiting opening 26, so that the purpose of fixed installation is achieved, when the engineering measuring instrument needs to be disassembled, only the lug 25 needs to be pressed downwards and rotated reversely, a user can open the triangular bracket 1 and place the triangular bracket at a position needing to be placed, the electronic gyroscope 9 measures the levelness of the triangular bracket 1 and transmits data to the display screen 16, the display screen 16 visually displays the data and controls the corresponding electric push rod 6 to perform height adjustment through the PLC 17 according to the data, the upper ends of three support rods of the triangular bracket 1 are positioned at the same horizontal plane, so that the purpose of horizontal adjustment of the triangular bracket 1 is achieved, when light is better, the user can open solar cell panel 10, and solar cell panel 10 absorbs solar energy and turns into the electric energy through inverter 11, through transformer 12 regulation voltage and storage at reserve battery 13, the energy-conservation nature of improvement device.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a highway engineering measuring device based on solar energy technique, includes engineering measuring apparatu, its characterized in that: the engineering measuring instrument comprises a triangular support (1) positioned at the bottom and a measuring instrument body (2) arranged at the top of the triangular support (1), wherein a guide groove (3) is formed in the lower end of the triangular support (1), three groups of conical rods (4) are uniformly arranged at the bottom, a guide block (5) is fixed at the upper end of each conical rod (4), the guide blocks (5) are movably arranged in the guide groove (3), an electric regulator is arranged between each conical rod (4) and the triangular support (1), the electric regulator comprises an electric push rod (6) and a connecting piece (7), the upper end of the electric push rod is fixed on the outer side of the triangular support (1), the connecting piece (7) is fixed at the tail end of the electric push rod (6), the connecting piece (7) is fixed on the conical rods (4) through bolts, an installation top plate (8) is horizontally arranged at the top of the triangular support (1), and an electronic gyroscope (9) is, the measuring instrument is characterized in that the measuring instrument body (2) is installed on an installation top disc (8) and a solar power supply structure is arranged outside the measuring instrument body, the solar power supply structure is composed of a solar cell panel (10), an inverter (11), a transformer (12) and a standby storage battery (13), the solar cell panel (10) is symmetrically installed on two sides of the measuring instrument body (2) through hinges and is electrically connected with the inverter (11), the inverter (11) is electrically connected with the transformer (12), the transformer (12) is connected with the standby storage battery (13), the standby storage battery (13) is installed at one end and one side of the measuring instrument body (2) and is provided with a main storage battery (14), a shell (15) is fixed on the outer side of the standby storage battery (13) and the main storage battery (14), a display screen (16) is installed on the shell (15), and a PLC (17) is connected between the display screen (16) and an electronic gyroscope, the PLC (17) is connected with the electric push rod (6).

2. A solar technology based road engineering measuring device according to claim 1, characterized in that: the butt joint mounting seat (18) is installed with the bottom of measuring apparatu body (2) in installation top dish (8), butt joint mounting seat (18) are two segmentation structures and including lower wall (19) and the hanging wall (20) that are located the lower wall (19) top that are fixed in installation top dish (8), hanging wall (20) are fixed in the bottom of measuring apparatu body (2).

3. A solar technology based road engineering measuring device according to claim 2, characterized in that: the middle part of the lower disc (19) is provided with a butt joint groove (21), six groups of L-shaped clamping plates (22) are uniformly arranged on the periphery of the butt joint groove (21), and six groups of clamping grooves (23) matched with the L-shaped clamping plates (22) for use are formed in the bottom of the upper disc (20).

4. A solar technology based road engineering measuring device according to claim 3, characterized in that: wherein one side of two sets of L type cardboard (22) of symmetry setting is installed elasticity spacing piece (24), processing shaping has lug (25) on elasticity spacing piece (24).

5. A solar technology based road engineering measuring device according to claim 3, characterized in that: wherein, one side of the two groups of symmetrically arranged clamping grooves (23) is provided with a limiting opening (26), the limiting opening (26) is positioned on the upper surface of the upper disc (20), and the convex block (25) is buckled in the limiting opening (26).

6. A solar technology based road engineering measuring device according to claim 1, characterized in that: the engineering measuring instrument is further controlled by a measuring instrument control system, the measuring instrument control system is divided into a power supply system, an operation system, a display module, a balance degree measuring module, a control module and a driving adjusting module, and the power supply system comprises an external charging module and a solar charging module.

7. A solar technology based road engineering measuring device according to claim 6, characterized in that: the power supply system provides a power supply for the operation of the operation system, the display module, the balance degree measuring module, the control module and the driving adjusting module, the display module displays data information of the operation system and data information of the balance degree measuring module, and the control module controls the driving adjusting module to operate and display the data information in real time through the reality module.

8. A solar technology based road engineering measuring device according to claim 1, characterized in that: the engineering measuring instrument is powered by a main storage battery (14) in a priority mode and is powered by a standby storage battery (13) in an auxiliary mode.

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