CN213274024U - Hydraulic engineering crack changes quantitative monitoring devices - Google Patents

Abstract

The utility model discloses a hydraulic engineering crack changes quantitative monitoring devices, including guide rail, base, body, solar panel and guide block, the slider is installed to the below of body, install the base on the body, the adjustable shelf is installed in the top of base, states the top of adjustable shelf and installs the link, and installs the transmitter outward of link, the battery is installed to the inboard of base, the mounting groove has been seted up in the middle of the adjustable shelf, and has seted up the guide way in the mounting groove, the guide block is installed in the upper end of leading-in strip, and the leading-in strip surface is carved with the scale, the ejector is installed at the rear of guide block, the link is installed to the top of adjustable shelf. This hydraulic engineering crack changes quantitative monitoring devices is provided with the guide rail, and the setting of this part for the device can be under the condition of being controlled, inspects the place of different positions, thereby has reduced the input volume of device, has increased the practicality of device, has reduced the waste of resource.

Description

Hydraulic engineering crack changes quantitative monitoring devices

Technical Field

The utility model relates to a monitoring technology field specifically is a hydraulic engineering crack changes quantitative monitoring devices.

Background

Along with the development of the prior art, water is used as the essential precious resource for human production and life, but the naturally existing state of the water does not completely meet the needs of human beings, and therefore the water conservancy project is required to control water flow, and the water conservancy project usually needs to construct dams to store water flow and the like, and the dams can intercept water flow, but the dams are impacted by water flow for a long time or operated by the earth crust, and cracks and other phenomena can occur, and some cracks can not influence the overall safety, but need to be monitored constantly, so that the cracks are prevented from being enlarged, and the water flow can be repaired in time.

But present monitoring facilities, the installation is inconvenient, and is fixed insecure, when the crack enlarges easily, leads to the device to relax the dislocation, and battery continuation of the journey ability is not strong, and it is difficult to switch on or change in some installation region to current monitoring devices adopts the fixed point to measure mostly, and a monitoring devices can't monitor on a large scale, need arrange a plurality of devices and monitor, thereby has increased the cost of using.

We therefore propose a hydraulic engineering crack change quantitative monitoring device to facilitate the solution to the problems set out above.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a hydraulic engineering crack changes quantitative monitoring devices to solve above-mentioned background art and propose current monitoring devices can't be to carrying out the problem of monitoring on a large scale.

In order to achieve the above object, the utility model provides a following technical scheme: a hydraulic engineering crack change quantitative monitoring device comprises a guide rail, a base, a body, a solar panel and a guide block, wherein a slide block is installed below the body, a slide groove is installed outside the slide block and is formed in the guide rail, the base is installed on the body, a control rod is installed in the base, a movable frame is installed above the control rod and is installed above the base, a detector is installed on the side face of the movable frame, a monitor is installed below the detector, a connecting frame is installed above the movable frame, a transmitter is installed outside the connecting frame, the solar panel is installed above the transmitter, a storage battery is installed on the inner side of the base, a mounting groove is formed in the middle of the movable frame, a guide groove is formed in the mounting groove, the guide block is installed in the guide groove and is installed at the upper end of a guide bar, and the surface of the guide-in strip is carved with a graduated scale, the guide-in strips are connected by a spring, an ejector is arranged behind the guide block, and a connecting frame is arranged above the movable frame.

Preferably, the guide rail is internally and vertically provided with a sliding groove which is not a through groove, the central line of the sliding groove is superposed with the central line of the sliding block, the contact surfaces of the sliding groove and the sliding block are parallel, and the sliding groove and the sliding block form sliding connection.

Preferably, the movable frame is horizontally arranged above the base, the central line of the movable frame and the central line of the base are overlapped, and the inner diameter of the base is larger than the outer diameter of the movable frame.

Preferably, the solar panel is vertically arranged above the movable frame, and the unfolded diameter of the solar panel 6 is larger than that of the base.

Preferably, the leading-in strips are horizontally arranged in the mounting groove, and the springs between the leading-in strips are movably connected.

Preferably, guide blocks are vertically arranged on two sides above the guide bar, the central line of each guide block is overlapped with the central line of each guide groove, and the outer diameter of each guide block is smaller than the inner diameter of each guide groove.

Compared with the prior art, the beneficial effects of the utility model are that: the hydraulic engineering crack change quantitative monitoring device;

1. the guide rail is arranged, and the arrangement of the components enables the device to check different positions under the controlled condition, so that the putting amount of the device is reduced, the practicability of the device is increased, and the waste of resources is reduced;

2. the movable frame is arranged, so that the device can be used for inspecting places with different heights, and when the signal of the transmitter is poor, the movable frame can be lifted, so that the signal of the device is improved, and the practicability of the device is improved;

3. be provided with leading-in strip, the setting of this part, leading-in strip can carry out a preliminary survey to the size of crack to can also carry out a measurement to the degree of depth of crack, launch information through the device, increased the functionality of device.

Drawings

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

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

FIG. 3 is a schematic view of the installation structure of the guide block and the movable frame of the present invention;

fig. 4 is a schematic view of the installation structure of the movable frame and the base of the present invention.

In the figure: 1. a guide rail; 2. a connecting frame; 3. a body; 4. a base; 5. a movable frame; 6. a solar panel; 7. a transmitter; 8. a detector; 9. a monitor; 10. a storage battery; 11. a spring; 12. a graduated scale; 13. introducing a strip; 14. a slider; 15. a chute; 16. a guide block; 17. a guide groove; 18. a control lever; 19. mounting grooves; 20. and (4) an ejector.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a hydraulic engineering crack change quantitative monitoring device comprises a guide rail 1, a connecting frame 2, a body 3, a base 4, a movable frame 5, a solar panel 6, an emitter 7, a detector 8, a monitor 9, a storage battery 10, a spring 11, a graduated scale 12, a leading-in strip 13, a slide block 14, a slide groove 15, a guide block 16, a guide groove 17, a control rod 18, a mounting groove 19 and an ejector 20, wherein the slide block 14 is mounted below the body 3, the slide groove 15 is mounted outside the slide block 14, the slide groove 15 is arranged in the guide rail 1, the body 3 is provided with the base 4, the control rod 18 is mounted in the base 4, the movable frame 5 is mounted above the control rod 18, the movable frame 5 is mounted above the base 4, the detector 8 is mounted on the side surface of the movable frame 5, the monitor 9 is mounted below the detector 8, the connecting frame 2 is mounted above the movable frame 5, and the transmitter 7 is installed to the outside of link 2, and solar panel 6 is installed to the top of transmitter 7, battery 10 is installed to the inboard of base 4, mounting groove 19 has been seted up in the middle of adjustable shelf 5, and guide way 17 has been seted up in mounting groove 19, and install guide block 16 in the guide way 17, guide block 16 is installed in the upper end of leading-in strip 13, and leading-in strip 13 surface is carved with scale 12, and adopt spring 11 to connect between the leading-in strip 13, ejector 20 is installed to the rear of guide block 16, link 2 is installed to the top of adjustable shelf 5.

The guide rail 1 is internally and vertically provided with a sliding groove 15, the sliding groove 15 is not a through groove, the central line of the sliding groove 15 is superposed with the central line of the sliding block 14, simultaneously, the contact surfaces of the sliding groove 15 and the sliding block 14 are parallel to each other, and the sliding groove 15 and the sliding block 14 are in sliding connection, so that the device can move within a certain range.

The movable frame 5 is horizontally arranged above the base 4, the central line of the movable frame 5 and the central line of the base 4 are overlapped, and the inner diameter of the base 4 is larger than the outer diameter of the movable frame 5, so that the height of the device can be lifted.

Solar panel 6 is installed perpendicularly in the top of adjustable shelf 5, and solar panel 6 expandes the diameter and is greater than the diameter of base 4, when can providing power source to the device, plays a guard's effect to the device.

The leading-in strips 13 are horizontally arranged in the mounting groove 19, the springs 11 between the leading-in strips 13 are movably connected, and the leading-in strips 13 can normally work.

The guide blocks 16 are vertically arranged on two sides above the guide strip 13, the central line of each guide block 16 is overlapped with the central line of each guide groove 17, the outer diameter of each guide block 16 is smaller than the inner diameter of each guide groove 17, and the guide strip 13 can stretch and retract, so that measurement is convenient.

The working principle is as follows: when the quantitative monitoring device for hydraulic engineering crack change is used, firstly, the device is placed at a place needing to be monitored, the device is started, as shown in figure 2, the device circularly detects around a guide rail 1 through a sliding block 14, a solar panel 6 provides a power source for the device, when the device detects that cracks occur in hydraulic engineering for a certain time, as shown in figure 4, the device is lifted through a movable frame 5, as shown in figure 2, a detector 8 detects the cracks, a guide strip 13 extends into the cracks through a guide block 16, one detection is carried out on the length of the cracks, a monitor 9 photographs the extending scales, the device memorizes the positions of the points, detected data is transmitted into a control room through a transmitter 7, if signals of the transmitter 7 are not carried out, the movable frame 5 continuously rises to a certain height, the signals are enhanced, so that the transmitter 7 can transmit the data, the monitoring personnel keeps track of the point and the device continues to check.

To thereby carry out a series of tasks, the contents of which are not described in detail in the present specification are prior art well known to those skilled in the art.

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 modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a hydraulic engineering crack changes quantitative monitoring device, includes guide rail (1), base (4), body (3), solar panel (6) and guide block (16), its characterized in that: the guide rail structure is characterized in that a sliding block (14) is installed below the body (3), a sliding groove (15) is installed outside the sliding block (14), the sliding groove (15) is arranged in the guide rail (1), a base (4) is installed on the body (3), a control rod (18) is installed in the base (4), a movable frame (5) is installed above the control rod (18), the movable frame (5) is installed above the base (4), a detector (8) is installed on the side face of the movable frame (5), a monitor (9) is installed below the detector (8), a connecting frame (2) is installed above the movable frame (5), an emitter (7) is installed outside the connecting frame (2), a solar panel (6) is installed above the emitter (7), a storage battery (10) is installed on the inner side of the base (4), a mounting groove (19) is formed in the middle of the movable frame (5), and set up guide way (17) in mounting groove (19) to install guide block (16) in guide way (17), guide block (16) are installed in the upper end of leading-in strip (13), and leading-in strip (13) surface is carved with scale (12), and adopt spring (11) to connect between leading-in strip (13), ejector (20) are installed to the rear of guide block (16), link (2) are installed to the top of adjustable shelf (5).

2. The hydraulic engineering crack change quantitative monitoring device of claim 1, characterized in that: a sliding groove (15) is vertically formed in the guide rail (1), the sliding groove (15) is not a through groove, the central line of the sliding groove (15) and the central line of the sliding block (14) are overlapped, meanwhile, the contact surfaces of the sliding groove (15) and the sliding block (14) are parallel to each other, and the sliding groove (15) and the sliding block (14) are in sliding connection.

3. The hydraulic engineering crack change quantitative monitoring device of claim 1, characterized in that: the top horizontal installation of base (4) has adjustable shelf (5), and the central line of adjustable shelf (5) and the central line of base (4) coincide each other to the internal diameter of base (4) is greater than the external diameter of adjustable shelf (5).

4. The hydraulic engineering crack change quantitative monitoring device of claim 1, characterized in that: solar panel (6) are installed perpendicularly in the top of adjustable shelf (5), and solar panel (6) expand the diameter and are greater than the diameter of base (4).

5. The hydraulic engineering crack change quantitative monitoring device of claim 1, characterized in that: the leading-in strips (13) are horizontally arranged in the mounting groove (19), and the springs (11) between the leading-in strips (13) are movably connected.

6. The hydraulic engineering crack change quantitative monitoring device of claim 1, characterized in that: guide blocks (16) are vertically arranged on two sides above the guide bar (13), the center line of each guide block (16) is overlapped with the center line of each guide groove (17), and the outer diameter of each guide block (16) is smaller than the inner diameter of each guide groove (17).

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