CN211696341U - Height measuring device - Google Patents

Abstract

The utility model provides an elevation measurement device, including main body cover, fixing device, host computer device, stay cord device and elevation sensing device, be equipped with on the main body cover fixing device, elevation sensing device passes through stay cord device sets up fixing device is last, stay cord device with the host computer device all sets up inside the main body cover, stay cord device elevation sensing device with the host computer device is connected in order to realize elevation measurement's function. The beneficial effects of the utility model are that acquire the length of stay cord, viscosity coefficient, current-voltage's data simultaneously through control elevation sensing device, come the environmental aspect of positioning sensor position and the high geology bottom of the range of awaiting measuring through multiple data, obtain elevation measurement's accurate data, especially outstanding to concrete layer's elevation measurement working effect.

Description

Height measuring device

Technical Field

The utility model relates to an engineering survey field, more specifically say and relate to an elevation measurement device.

Background

In the field of engineering measurement, for high-range measurement operation of dams, sewers and the like, measurement and detection are required to be manually carried out by means of a ruler in most cases. The method not only needs to consume a large amount of manpower, but also cannot obtain accurate measurement data. The measurement speed and the engineering requirements are seriously influenced.

SUMMERY OF THE UTILITY MODEL

The utility model overcomes not enough among the prior art provides an elevation measurement device.

The purpose of the utility model is realized by the following technical scheme.

An elevation measuring device comprises a main body shell, a fixing device, a main machine device, a pull rope device and an elevation sensing device,

the height measuring device is characterized in that the fixing device is arranged on the main body shell, the height sensing device is arranged on the fixing device through the rope pulling device, the rope pulling device and the main machine device are arranged inside the main body shell, and the rope pulling device and the height sensing device are connected with the main machine device to achieve the height measuring function.

The fixing device comprises a fixing rod, a supporting frame and a pulley, one end of the fixing rod is connected with the main body shell, the other end of the fixing rod is connected with the pulley, and the supporting frame is arranged on the fixing rod.

The elevation sensing device comprises a stay cord connecting device, an elevation sensor shell, a resistance wing, a first motor, a rotating shaft and a sensor, wherein the stay cord connecting device is arranged on the elevation sensor shell, the resistance wing is arranged on the elevation sensor shell, the first motor is arranged inside the elevation sensor shell, and the sensor passes through the rotating shaft and the first motor which are connected to realize the rotating function.

The host device comprises a data visualization device, a pull rope sensing device, a metering device and a control device, wherein the data visualization device and the control device are arranged on the main body shell, the metering device is used for observing the measurement data of the elevation in a mode of being connected with the data visualization device, the pull rope sensing device is respectively connected with the pull rope device and the elevation sensing device to acquire the length data of the pull rope and the viscosity, current and voltage data, and the control device is connected with the pull rope device and the elevation sensing device to realize the control of the elevation sensing device.

The rope pulling device comprises a pulling rope, a second motor and a fixed sliding rod, wherein the pulling rope is arranged on the fixed sliding rod, and the fixed sliding rod is driven by the second motor.

The main body shell is provided with a fixing device accommodating groove, and the size of the fixing device accommodating groove is matched with the fixing device and is connected with the fixing device through a rotating shaft.

The main body shell is provided with an elevation device accommodating groove, and the elevation device accommodating groove is a u-shaped groove.

The shell of the elevation sensor is a waterproof shell and is made of stainless steel.

The main body shell is a rectangular shell with the length of 70cm and the width and height of 50 cm.

The sensor is a viscosity testing head, and the resistance wing is of a detachable structure.

The utility model has the advantages that: the method has the advantages that the height sensing device is controlled to simultaneously acquire the length, viscosity coefficient and current and voltage data of the pull rope, the sensor position and the environment condition of the high geological bottom with the measuring range to be measured are positioned through various data, accurate height measurement data are acquired, particularly, the height measurement work effect of the concrete layer is outstanding, and compared with the characteristics of long time consumption and manpower consumption in manual measurement, the method is simple and convenient to operate, visual in output, greatly improves the detection rate and reduces the operation difficulty. Along with the difference of the current return values of the concrete surface elevation sensor, more operation information can be obtained, and not only the elevation data after the concrete surface elevation sensor touches the entity.

Drawings

Fig. 1 is a cross-sectional view of the present invention;

FIG. 2 is a schematic diagram of an elevation sensing apparatus;

FIG. 3 is a cross-sectional view of an elevation sensing apparatus;

fig. 4 is a schematic structural diagram of the present invention;

fig. 5 is a schematic view of the use of the present invention;

in the figure: the height sensor comprises a main body shell 1, a fixing device 2, a host device 3, a pull rope device 4, an elevation sensor device 5, a fixing rod 6, a supporting frame 7, a pulley 8, a fixing device accommodating groove 9, an elevation device accommodating groove 10, an elevation sensor shell 11, a resistance wing 12, a rotating shaft 13, a first motor 14, a sensor 15, a data visualization device 16, a control device 17, a pull rope 18, a fixed slide rod 19 and a pull rope connecting device 20.

Detailed Description

The technical solution of the present invention is further explained by the following specific examples.

Example one

An elevation measuring device comprises a main body shell 1, a fixing device 2, a host machine device 3, a pull rope device 4 and an elevation sensing device 5,

be equipped with fixing device 2 on main body cover 1, elevation sensing device 5 sets up on fixing device 2 through stay cord device 4, and stay cord device 4 and host computer device 3 all set up inside main body cover 1, and stay cord device 4, elevation sensing device 5 are connected in order to realize elevation measurement's function with host computer device 3.

This device is responsible for the processing of information and mechanical controlling by host computer device 3, stay cord device 4, 5 in use of elevation sensing device can gather the tensile length of rope, the viscosity coefficient of geology bottom, current-voltage's real-time change data, with this measurement that realizes the geology elevation, different this device of prior art is not single can only acquire the data of elevation, not only can obtain more accurate elevation data through multiple data comparison, can also listen the geological conditions, it is especially important in the construction, at dykes and dams, the sewer, it is more outstanding in some aspects in the measuring environment on cement layer.

Fixing device 2 includes dead lever 6, support frame 7 and pulley 8, and 6 one end of dead lever is connected with main body cover 1, and the other end is connected with pulley 8, and support frame 7 sets up on dead lever 6.

The support frame 7 supports the fixing rod 6 when the fixing device 2 is completely unfolded, compared with a one-way connection relation, a connection part can bear larger pressure, so that the service life of the device is shortened, and the pulley 8 is matched with the pull rope 18 in use to play a role in lifting the elevation sensing device 5.

The elevation sensing device comprises a stay cord connecting device 20, an elevation sensor shell 11, a resistance wing 12, a first motor 14, a rotating shaft 13 and a sensor 15, wherein the stay cord connecting device 20 is arranged on the elevation sensor shell 11, the resistance wing 12 is arranged on the elevation sensor shell 11, the first motor 14 is arranged inside the elevation sensor shell 11, and the sensor 15 is connected with the first motor through the rotating shaft 13 so as to realize a rotating function.

The working rope connecting device 20 is connected with the pulling rope 18, the pulling rope 18 is a steel rope, the working rope connecting device 20 is a lifting nose, and the sensor 15 is in contact with the ground to collect data.

The working principle of the technical scheme is as follows, the elevation sensing device 5 is taken out in use, the rope connecting device 20 is connected with the pull rope 18, the pull rope 18 is arranged on the pulley 8, the host device 3 controls the retraction of the pull rope and the feedback of length information, the elevation sensing device 5 slowly descends to the bottom of the geological to be detected, the host device 3 controls the first motor 14 on the elevation sensing device 5 to drive the sensor 15 to rotate, the real-time change conditions of the viscosity coefficient of the geological and the power supply and the current on the sensor are detected, the data are fed back to the host device 3 and then output by the data visualization device 16, the judgment and the recording of a worker are facilitated, and the effect of measuring the geological elevation is achieved.

Example two

On the basis of the first embodiment, it is preferable that the host device 3 includes a data visualization device 16, a rope pulling sensing device, a metering device and a control device 17, the data visualization device 16 and the control device 17 are disposed on the main body casing 1, the metering device and the rope pulling sensing device are connected with the data visualization device 16 to observe measured data of elevation, the rope pulling sensing device and the metering device are respectively connected with the rope pulling device 4 and the elevation sensing device 5 to acquire length data and viscosity, current and voltage data of the rope pulling 18, and the control device 17 is connected with the rope pulling device 4 and the elevation sensing device 5 to control the elevation sensing device 5. The device comprises a visualization device 16, a control device 17, a pull rope sensing device and a metering device, wherein the visualization device is an electronic display screen, the control device 17 is an operation button, the pull rope sensing device and the metering device are pcb circuit elements, and the control device 17 controls the retraction of the pull rope device 4 and the rotation of a front end sensor 15 of an elevation sensing device 5, so that a worker can manually control the measurement of the elevation. The visualization device 16 can feed back the data to the working personnel so as to survey the engineering geology with high range and simple and convenient operation.

The pull rope device 4 comprises a pull rope 18, a second motor and a fixed sliding rod 19, wherein the pull rope 18 is arranged on the fixed sliding rod 19, and the fixed sliding rod 19 is driven by the second motor.

Preferably, the main body housing 1 is provided with a fixing device accommodating groove 9, and the size of the fixing device accommodating groove 9 is matched with that of the fixing device 2 and is connected with the fixing device through a rotating shaft. When the machine is not in use, the fixing device 2 is accommodated in the fixing device accommodating groove 9, and the occupied space is reduced.

The main body case 1 is provided with an elevation device storage groove 10, and the elevation device storage groove 10 is a u-shaped groove. The U-shaped groove is good in fixing effect and easy to disassemble elements.

Preferably, the elevation sensor housing 11 is a waterproof housing made of stainless steel. The housing of the elevation sensor is easy to rust due to the fact that the housing of the elevation sensor is in contact with moisture in work, and the stainless steel material is used for prolonging the service life of equipment. Specifically, it is cast from SUS-304 stainless steel.

Preferably, the main body case 1 is a rectangular case having a length of 70cm and a width and a height of 50 cm. The main body shell 1 is small and exquisite and easy to carry, is more convenient to use, and reduces the space occupation.

The sensor 15 is a viscosity testing head, and the resistance wing 12 is a detachable structure. The sensor 15 adopts a viscosity testing head, which is more beneficial to data acquisition. The resistance wings 12 can be detached according to different media to be monitored, can sense different resistances when being detected, and face different environments such as concrete, soil and the like so as to achieve better sensing effect, and the detachable structure is convenient to replace and does not need to prepare a plurality of groups of elevation sensing devices 5.

Spatially relative terms, such as "upper," "lower," "left," "right," and the like, may be used in the embodiments for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. It will be understood that the spatial terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "below" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "lower" can encompass both an upper and a lower orientation. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

Moreover, relational terms such as "first" and "second," and the like, may be used solely to distinguish one element from another element having the same name, without necessarily requiring or implying any actual such relationship or order between such elements.

The embodiments of the present invention have been described in detail, but the description is only for the preferred embodiments of the present invention and should not be construed as limiting the scope of the present invention. All the equivalent changes and improvements made according to the application scope of the present invention should still fall within the patent coverage of the present invention.

Claims (10)

1. Elevation measurement device, its characterized in that: comprises a main body shell, a fixing device, a main machine device, a pull rope device and an elevation sensing device,

the height measuring device is characterized in that the fixing device is arranged on the main body shell, the height sensing device is arranged on the fixing device through the rope pulling device, the rope pulling device and the main machine device are arranged inside the main body shell, and the rope pulling device and the height sensing device are connected with the main machine device to achieve the height measuring function.

2. The elevation measurement apparatus of claim 1, wherein: the fixing device comprises a fixing rod, a supporting frame and a pulley, one end of the fixing rod is connected with the main body shell, the other end of the fixing rod is connected with the pulley, and the supporting frame is arranged on the fixing rod.

3. The elevation measurement apparatus of claim 2, wherein: the elevation sensing device comprises a stay cord connecting device, an elevation sensor shell, a resistance wing, a first motor, a rotating shaft and a sensor, wherein the stay cord connecting device is arranged on the elevation sensor shell, the resistance wing is arranged on the elevation sensor shell, the first motor is arranged inside the elevation sensor shell, and the sensor passes through the rotating shaft and the first motor which are connected to realize the rotating function.

4. The elevation measurement apparatus of claim 3, wherein: the host device comprises a data visualization device, a pull rope sensing device, a metering device and a control device, wherein the data visualization device and the control device are arranged on the main body shell, the metering device is used for observing the measurement data of the elevation in a mode of being connected with the data visualization device, the pull rope sensing device is respectively connected with the pull rope device and the elevation sensing device to acquire the length data of the pull rope and the viscosity, current and voltage data, and the control device is connected with the pull rope device and the elevation sensing device to realize the control of the elevation sensing device.

5. The elevation measurement apparatus of any one of claims 1-4, wherein: the rope pulling device comprises a pulling rope, a second motor and a fixed sliding rod, wherein the pulling rope is arranged on the fixed sliding rod, and the fixed sliding rod is driven by the second motor.

6. The elevation measurement apparatus of claim 5, wherein: the main body shell is provided with a fixing device accommodating groove, and the size of the fixing device accommodating groove is matched with the fixing device and is connected with the fixing device through a rotating shaft.

7. The elevation measurement apparatus of claim 6, wherein: the main body shell is provided with an elevation device accommodating groove, and the elevation device accommodating groove is a u-shaped groove.

8. The elevation measurement apparatus of claim 3, wherein: the shell of the elevation sensor is a waterproof shell and is made of stainless steel.

9. The elevation measurement apparatus of claim 3, wherein: the main body shell is a rectangular shell with the length of 70cm and the width and height of 50 cm.

10. The elevation measurement apparatus of claim 9, wherein: the sensor is a viscosity testing head, and the resistance wing is of a detachable structure.

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