CN219866949U - Remote sensing monitoring device for soil and water conservation - Google Patents

Abstract

The utility model discloses a water and soil conservation remote sensing monitoring device, and relates to the technical field of water and soil conservation remote sensing monitoring. The damping rotating shaft and the limiting block are symmetrically arranged on the left side and the right side of the counterweight mounting block, the supporting rod is arranged above the counterweight mounting block, and the sliding block is arranged on the inner side of the mounting ring. This soil and water conservation remote sensing monitoring devices is provided with collar, carousel and transmission shaft, starts servo motor, and servo motor passes through the output shaft and drives the transmission shaft rotation, and then the transmission shaft drives the dwang through connecting belt and rotates, and the dwang drives the carousel and rotates, and then the carousel can drive the connecting plate and rotate, and then the connecting plate drives the collar rotation of below to be convenient for adjust the monitoring angle of remote sensing detector on the collar, monitor the soil and water conservation condition in different regions, need not to remove whole soil and water conservation remote sensing monitoring devices, labour saving and time saving more.

Description

Remote sensing monitoring device for soil and water conservation

Technical Field

The utility model relates to the technical field of water and soil conservation remote sensing monitoring, in particular to a water and soil conservation remote sensing monitoring device.

Background

The water and soil conservation condition of the region is monitored through a water and soil conservation remote sensing monitoring device.

The utility model discloses a water and soil conservation remote sensing monitoring facilities of publication number CN213903519U, including the monitor, a support rack, the connecting rod, the photovoltaic board, the conveyer, strutting arrangement, through inserting the cutting of stabilizing piece behind the earth depths by lug and the deep earth of its interior both sides mutually adhesion and then make stabilizing piece fixed firm, even the loose stabilizing piece of earth around the monitoring facilities still can be firm fixed with the soil layer inside, and at the bracing piece through the spring post cooperation at block cover outer wall, by block cover and the spliced pole sliding fit of positive center, the stability that the equipment still can be kept to the collapse of slightly. However, the device has certain defects;

monitor and connecting rod direct fixed connection can't adjust the monitoring angle of monitor, can only detect the soil and water conservation condition in fixed region, when need monitor for the soil and water conservation condition in different positions, need remove strutting arrangement, waste time and energy more.

We have therefore proposed a remote sensing monitoring device for soil and water conservation in order to solve the problems set out above.

Disclosure of Invention

The utility model aims to provide a water and soil conservation remote sensing monitoring device, which aims to solve the problems that the existing water and soil conservation monitoring equipment monitors in the current market provided by the background technology are directly and fixedly connected with a connecting rod, the monitoring angle of the monitors cannot be adjusted, only the water and soil conservation conditions of a fixed area can be detected, and when the water and soil conservation conditions of different positions are required to be monitored, a supporting device is required to be moved, and more time and labor are wasted.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a soil and water conservation remote sensing monitoring devices, includes counter weight installation piece, bracing piece, collar, hollow chamber, and dwang, damping pivot and stopper are installed to the left and right sides symmetry of counter weight installation piece, and the symmetry is installed in the damping pivot and is located the pole, the bracing piece is installed to the top of counter weight installation piece, and has seted up the spout on the bracing piece, and the outside of spout is provided with the collar, the slider is installed to the inboard of collar, and collar outside surface mounting has the remote sensing detector, the connecting rod is installed to the top rear side of bracing piece, and hollow chamber has been seted up to the inside of bracing piece, and hollow chamber's internally mounted has the backup pad moreover, the dwang is installed to the top of backup pad, and the carousel is installed to the top of dwang, servo motor is installed to the top of bracing piece, the connecting plate is installed to the upper surface symmetry of collar.

Preferably, the locating rod is of an inverted L-shaped structural design, the locating rod is provided with a ratchet block, and the bottom of the locating rod is of a conical structural design.

By adopting the structural design, when the remote sensing monitoring device is required to be used on the flat land, the positioning rods at the left side and the right side are rotated upwards along the damping rotating shaft, then the counterweight mounting blocks are directly placed at the positions to be monitored horizontally, when the remote sensing monitoring device is required to be used on the land, the positioning rods at the left side and the right side are rotated downwards along the damping rotating shaft to the positions of the limiting blocks, then the positioning rods are inserted into the land until the counterweight mounting blocks are abutted against the land surface, and due to the fact that the soil is sticky, under the action of the ratchet blocks, the longer time is, the stronger tensile force is provided between the positioning rods and the soil, so that the positioning rods are fixed more stably.

Preferably, the sliding groove and the sliding block are of annular structure design, and a sliding structure is formed between the sliding groove and the sliding block.

By adopting the structural design, the sliding block in the mounting ring can slide along the sliding groove when the mounting ring rotates, so that the mounting ring is more stable when rotating, and no deviation occurs.

Preferably, the rain-proof board is installed to the top of connecting rod, and the rain-proof board is symmetrical slope structural design.

By adopting the structural design, rainwater is convenient to slide on the rain-proof plate, and the rain-proof plate plays a protective role on the remote sensing detector and the servo motor below.

Preferably, a rotating structure is formed between the rotating rod and the supporting plate, and the central line of the rotating rod is mutually overlapped with the central line of the mounting ring.

By adopting the structural design, the rotating rod can rotate when being stressed, so that the turntable above the rotating rod is driven to rotate.

Preferably, the servo motor is located on the right side of the rotary table, a transmission shaft is installed below the servo motor through an output shaft, and the transmission shaft is connected with the rotary rod through a connecting belt.

By adopting the structural design, the servo motor is started, the servo motor drives the transmission shaft to rotate through the output shaft, and then the transmission shaft drives the rotating rod to rotate through the connecting belt.

Preferably, the connecting plate and the mounting ring are in a fixed connection structure, and the upper part of the connecting plate is fixedly connected with the turntable.

By adopting the structural design, when the rotating rod rotates, the rotating rod can drive the connecting plate to rotate through the turntable, and then the connecting plate drives the mounting ring below to rotate, so that the monitoring angle of the remote sensing detector on the mounting ring can be conveniently adjusted.

Compared with the prior art, the utility model has the beneficial effects that: this soil and water conservation remote sensing monitoring devices:

1. the device comprises a counterweight mounting block, a damping rotating shaft, a positioning rod and a ratchet block, wherein when the device is required to be used on the flat ground, the positioning rods on the left side and the right side are rotated upwards along the damping rotating shaft, then the counterweight mounting block is directly placed at a position to be monitored horizontally, when the device is required to be used on the land, the positioning rods on the left side and the right side are rotated downwards along the damping rotating shaft to the position of a limiting block, then the positioning rods are inserted into the land until the land surface of the counterweight mounting block is abutted, and under the action of the ratchet block, the longer the time is, the stronger tensile resistance is provided between the positioning rods and the soil, so that the positioning rods are fixed more stably, and the device is applicable to different terrains;

2. be provided with collar, carousel and transmission shaft, start servo motor, servo motor passes through the output shaft and drives the transmission shaft rotation, and then the transmission shaft drives the dwang through connecting belt and rotates, and the dwang drives the carousel and rotates, and then the carousel can drive the connecting plate and rotate, and then the connecting plate drives the collar of below and rotate to be convenient for adjust the monitoring angle of remote sensing detector on the collar, monitor the soil and water conservation condition in different regions, need not to remove whole soil and water conservation remote sensing monitoring devices, labour saving and time saving more.

Drawings

FIG. 1 is a schematic view of a partial cross-sectional structure of the present utility model;

FIG. 2 is a schematic diagram of a front view structure of the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1B according to the present utility model;

FIG. 5 is an enlarged schematic view of the structure of FIG. 1 at C according to the present utility model;

FIG. 6 is a schematic view of the mounting ring structure of the present utility model.

In the figure: 1. a counterweight mounting block; 2. damping the rotating shaft; 3. a limiting block; 4. a positioning rod; 5. a ratchet block; 6. a support rod; 7. a chute; 8. a mounting ring; 9. a slide block; 10. a remote sensing detector; 11. a connecting rod; 12. rain-proof board; 13. a hollow cavity; 14. a support plate; 15. a rotating lever; 16. a turntable; 17. a servo motor; 18. a transmission shaft; 19. a connecting belt; 20. and (5) connecting a plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides a technical solution: the utility model provides a soil and water conservation remote sensing monitoring devices, including counter weight installation piece 1, damping pivot 2, stopper 3, locating lever 4, ratchet piece 5, bracing piece 6, spout 7, collar 8, slider 9, remote sensing detector 10, connecting rod 11, weather shield 12, hollow chamber 13, backup pad 14, dwang 15, carousel 16, servo motor 17, transmission shaft 18, connecting belt 19 and connecting plate 20, damping pivot 2 and stopper 3 are installed to the left and right sides symmetry of counter weight installation piece 1, and install locating lever 4 on the damping pivot 2 symmetry, locating lever 4 is the structural design of falling "L", and installs ratchet piece 5 on the locating lever 4, and the bottom of locating lever 4 is the conical structural design, when the remote sensing monitoring device is required to be used on the land, the positioning rods 4 on the left side and the right side are rotated upwards along the damping rotating shaft 2, then the counterweight mounting block 1 is directly placed at the position to be monitored horizontally, when the remote sensing monitoring device is required to be used on the land, the positioning rods 4 on the left side and the right side are rotated downwards along the damping rotating shaft 2 to the position of the limiting block 3, then the positioning rods 4 are inserted into the land until the counterweight mounting block 1 abuts against the land surface, and due to the fact that the soil is sticky, under the action of the ratchet block 5, the longer the time, the stronger tensile resistance is provided between the positioning rods 4 and the soil, so that the positioning rods 4 are fixed more stably.

The bracing piece 6 is installed to the top of counter weight installation piece 1, and the spout 7 has been seted up on the bracing piece 6, spout 7 and slider 9 all are annular structural design, and constitute sliding structure between spout 7 and the slider 9, make collar 8 when rotating, slider 9 in the collar 8 can slide along spout 7, thereby make collar 8 more stable when rotating, can not take place the skew, and the outside of spout 7 is provided with collar 8, slider 9 is installed to the inboard of collar 8, and install collar 8 outside surface mounting has remote sensing detector 10, connecting rod 11 is installed to the top rear side of bracing piece 6, weather guard 12 is installed to the top of connecting rod 11, and weather guard 12 is symmetrical slope structural design, be convenient for the rainwater to slide on weather guard 12, weather guard 12 plays the guard action to remote sensing detector 10 and the servo motor 17 of below, and hollow chamber 13 has been seted up to the inside of bracing piece 6, moreover, the internally mounted of hollow chamber 13 has backup pad 14, dwang 15 is installed to the top of backup pad 14, constitute rotating structure between dwang 15 and the backup pad 14, and the center line of dwang 15 and the backup pad 15, and the center line of dwang 15 and the coincidence each other of collar 8 make and the center line of rotation 15 rotate on the carousel 15, thereby rotate 16 when rotating 16.

The carousel 16 is installed to the top of dwang 15, servo motor 17 is installed to the top of bracing piece 6, servo motor 17 is located the right side of carousel 16, and the below of servo motor 17 is installed through the output shaft and is passed through transmission shaft 18, and be connected through connecting belt 19 between transmission shaft 18 and the dwang 15, start servo motor 17, servo motor 17 passes through the output shaft and drives the rotation of transmission shaft 18, then transmission shaft 18 passes through connecting belt 19 and drives dwang 15 rotation, connecting plate 20 is installed to the upper surface symmetry of collar 8, connecting plate 20 is fixed connection structure with collar 8, and the top and the carousel 16 fixed connection of connecting plate 20, when dwang 15 rotates, dwang 15 can drive connecting plate 20 through carousel 16 and rotate, then connecting plate 20 drives the collar 8 rotation of below, thereby be convenient for adjust the monitoring angle of remote sensing detector 10 on the collar 8.

Working principle: when the remote sensing monitoring device for water and soil conservation is used, firstly, when the remote sensing monitoring device is required to be used on the ground, the positioning rods 4 on the left side and the right side are downwards rotated to the position of the limiting block 3 along the damping rotating shaft 2, and then the positioning rods 4 are inserted into the ground until the water and soil surfaces of the counterweight mounting blocks 1 are abutted.

When the position angle of the remote sensing detector 10 needs to be adjusted, the servo motor 17 is started, the servo motor 17 drives the transmission shaft 18 to rotate through the output shaft, the transmission shaft 18 drives the rotating rod 15 to rotate through the connecting belt 19, the rotating rod 15 drives the rotating disc 16 to rotate, the rotating disc 16 can drive the connecting plate 20 to rotate, and the connecting plate 20 drives the mounting ring 8 below to rotate, so that the remote sensing detector 10 on the mounting ring 8 can be adjusted to the position needing to be monitored. Thereby completing a series of works. What is not described in detail in this specification is prior art known to those skilled in the art.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (4)

1. The utility model provides a soil and water conservation remote sensing monitoring devices, includes counter weight installation piece (1), bracing piece (6), collar (8), hollow chamber (13) and dwang (15), its characterized in that: the device is characterized in that a damping rotating shaft (2) and a limiting block (3) are symmetrically arranged on the left side and the right side of the counterweight installation block (1), a positioning rod (4) is symmetrically arranged on the damping rotating shaft (2), a supporting rod (6) is arranged above the counterweight installation block (1), a sliding groove (7) is formed in the supporting rod (6), an installation ring (8) is arranged on the outer side of the sliding groove (7), a sliding block (9) is arranged on the inner side of the installation ring (8), a remote sensing detector (10) is arranged on the outer side surface of the installation ring (8), a connecting rod (11) is arranged on the rear side of the top of the supporting rod (6), a hollow cavity (13) is formed in the supporting rod (6), a supporting plate (14) is arranged in the hollow cavity (13), a rotating rod (15) is arranged above the supporting plate (14), a turntable (16) is arranged above the rotating rod (15), a servo motor (17) is arranged above the supporting rod (6), and a connecting plate (20) is symmetrically arranged on the upper surface of the installation ring (8).

A rotating structure is formed between the rotating rod (15) and the supporting plate (14), and the central line of the rotating rod (15) is mutually overlapped with the central line of the mounting ring (8);

the servo motor (17) is positioned on the right side of the turntable (16), a transmission shaft (18) is arranged below the servo motor (17) through an output shaft, and the transmission shaft (18) is connected with the rotating rod (15) through a connecting belt (19);

the connecting plate (20) and the mounting ring (8) are in a fixed connection structure, and the upper part of the connecting plate (20) is fixedly connected with the turntable (16).

2. The soil and water conservation remote sensing and monitoring device of claim 1, wherein: the locating rod (4) is of an inverted L-shaped structural design, the locating rod (4) is provided with a ratchet block (5), and the bottom of the locating rod (4) is of a conical structural design.

3. The soil and water conservation remote sensing and monitoring device of claim 1, wherein: the sliding groove (7) and the sliding block (9) are of annular structural design, and a sliding structure is formed between the sliding groove (7) and the sliding block (9).

4. The soil and water conservation remote sensing and monitoring device of claim 1, wherein: the rain-proof plate (12) is arranged above the connecting rod (11), and the rain-proof plate (12) is of a symmetrical inclined structure design.