CN219194709U - River water quality detection position self-adjusting aeration device based on water environment treatment - Google Patents

Abstract

The utility model discloses a river water quality detection position self-adjusting aeration device based on water environment treatment, which comprises a mounting assembly and a moving assembly arranged on the mounting assembly; the moving assembly is used for driving the installation assembly to move on the water surface; the mounting assembly includes a photovoltaic module; the moving assembly comprises a moving mechanism, a power mechanism, an anchoring mechanism and an aeration assembly; the power mechanism is used for driving the moving mechanism to drive the installation assembly to move on the water surface, and the anchoring mechanism is used for anchoring the installation assembly on the water surface when the installation assembly stops moving; the photovoltaic module is used for supplying power to the aeration module, the power mechanism and the anchoring mechanism. In the utility model, the moving assembly also comprises a linkage mechanism, aeration and movement can be combined through the linkage mechanism, and the aeration and movement are controlled through one motor, so that the cost and the energy consumption are saved.

Description

River water quality detection position self-adjusting aeration device based on water environment treatment

Technical Field

The utility model belongs to the technical field of river aeration, and particularly relates to a river water quality detection position self-adjusting aeration device based on water environment treatment.

Background

The water environment refers to rivers, lakes and the like in the nature, along with the continuous development of human society, the pollution to the water environment is continuously aggravated, and aquatic plants such as algae are continuously increased, so that the oxygen content of a water body is reduced, the eutrophication of the water body is serious, and the water at the bottom of the water body and the water at the surface of the water body are circularly alternated by utilizing an aeration mode, so that the contact area of the water body and air is increased, the oxygen content of the water body is increased, and the water environment is improved.

Disclosure of Invention

The utility model provides a river water quality detection position self-adjusting aeration device based on water environment treatment.

In order to solve the problems, the utility model adopts the following technical scheme.

River water quality detection position self-adjusting aeration device based on water environment treatment, which is characterized in that: comprises a mounting assembly and a moving assembly arranged on the mounting assembly; the moving assembly is used for driving the installation assembly to move on the water surface; the mounting assembly includes a photovoltaic module; the moving assembly comprises a moving mechanism, a power mechanism, an anchoring mechanism and an aeration assembly; the power mechanism is used for driving the moving mechanism to drive the installation assembly to move on the water surface, and the anchoring mechanism is used for anchoring the installation assembly on the water surface when the installation assembly stops moving; the photovoltaic module is used for supplying power to the aeration module, the power mechanism and the anchoring mechanism.

The moving mechanism comprises four impellers in front, back, left and right, and the power mechanism drives the four impellers in front, back, left and right to rotate.

The anchoring mechanism comprises an anchor rope, a wind-up roller and a balancing weight, one end of the anchor rope is wound on the wind-up roller, and the other end of the anchor rope is connected with the balancing weight; and the wind-up roller is connected with the photovoltaic module to obtain a power supply.

The front, back, left and right impellers are arranged on the balancing weight.

The movable assembly further comprises a linkage mechanism, and the linkage mechanism is connected with the power mechanism and used for driving the aeration assembly to perform aeration.

The power mechanism comprises an aeration motor, a linkage large gear and aeration fan blades; the linkage large gear is fixedly connected to the bottom of the aeration motor, and the aeration fan blade is fixedly connected to the bottom of the linkage large gear; the linkage mechanism comprises a linkage pinion and a belt transmission mechanism, and the linkage pinion drives the belt transmission mechanism; the linkage pinion is meshed with the linkage bull gear; the belt transmission mechanism is connected with the front impeller, the rear impeller, the left impeller and the right impeller.

The belt transmission mechanism comprises a belt, a second belt pulley, a third belt pulley and a belt height adjusting mechanism, and the second belt pulley is arranged on the linkage pinion; the third belt pulley is arranged on the balancing weight and connected with the front impeller, the rear impeller, the left impeller and the right impeller.

The belt height adjusting mechanism comprises two first pulleys and a spring arranged between the two first pulleys.

Advantageous effects

Compared with the prior art, the utility model has the beneficial effects that:

(1) According to the utility model, when the movable assembly needs to move, the power mechanism of the movable assembly drives the movable mechanism to enable the installation assembly to move on the water surface, the power mechanism is powered by the photovoltaic assembly, and the installation assembly can move on the water surface to any direction according to the needs.

(2) The moving assembly also comprises a linkage mechanism, aeration and movement can be combined through the linkage mechanism, and the aeration and movement are controlled through a motor, so that the cost and the energy consumption are saved.

(3) When needs remove, the first motor in one side parallel with the direction of movement rotates and drives photovoltaic board and push pedal and rotate downwards to promote the link gear of adjacent side inwards to remove, thereby accomplish power transmission at the in-process tooth's socket and gear tooth that removes, drive the rotation of third belt pulley through the belt, thereby can drive equipment and remove in water, can lengthen the anchor rope through starting the second and make the balancing weight subside, first belt pulley in both sides and slider inwards move by compression spring when the balancing weight is sunk, can guarantee power transmission.

(4) According to the utility model, the maintenance energy can be converted into electric energy through the photovoltaic panel, and when the impellers on the opposite sides are started to rotate, the equipment can turn around in situ, and the impellers on the opposite sides can move in different directions.

Drawings

FIG. 1 is a schematic diagram of a river water quality detection position self-adjusting aeration device based on water environment treatment in the utility model;

FIG. 2 is a schematic view of a mounting assembly according to the present utility model;

FIG. 3 is a schematic diagram of a linkage mechanism according to the present utility model;

FIG. 4 is a schematic view of a mobile assembly according to the present utility model;

FIG. 5 is a schematic view of a moving mechanism according to the present utility model;

FIG. 6 is a schematic diagram of a power mechanism according to the present utility model.

The correspondence between the reference numerals and the component names in the drawings is as follows:

1. installing an assembly; 11. a mounting plate; 12. a first through hole; 13. a push plate; 14. a photovoltaic panel; 15. a rotating shaft; 16. a first bracket; 17. a first motor; 18. a second through hole; 2. a moving assembly; 21. a moving mechanism; 211. a wind-up roll; 212. a second bracket; 213. a second motor; 214. an anchor rope; 215. balancing weight; 216. an impeller; 217. a third pulley; 22. a power mechanism; 221. an aeration motor; 222. a linkage large gear; 223. aeration fan blades; 23. a linkage mechanism; 231. a plate body; 232. a chute; 233. a spring; 234. a first pulley; 235. a belt; 236. a second pulley; 237. linkage small tooth grooves; 238. a one-way valve.

Detailed Description

As shown in FIG. 1, the river water quality detection position self-adjusting aeration device based on water environment treatment in the embodiment comprises a mounting assembly 1 and a moving assembly 2, wherein the moving assembly 2 is mounted on the mounting assembly 1. The movement of the apparatus is powered by the movement assembly 2.

The structure of the installation assembly 1 is shown in fig. 2, the installation assembly comprises an installation plate 11, a second through hole 18 is formed in the center of the upper end of the installation plate 11, a plurality of first supports 16 are arranged around the second through hole 18, a rotating shaft 15 is rotatably connected in each first support 16, a photovoltaic panel 14 is fixedly connected to the outer wall of each rotating shaft 15, a push plate 13 is obliquely connected to the tail end of each photovoltaic panel 14, a first motor 17 is movably installed on one side of each first support 16, the rotating end of the first motor 17 is fixedly connected with the rotating shaft 15 on the adjacent side, and symmetrical first through holes 12 are formed in the upper end face of the installation plate 11 on two sides of each photovoltaic panel 14.

Specifically, the rotation of the rotating shaft 15 can drive the photovoltaic panel 14 and the push plate 13 to rotate so as to push the linkage mechanism 2 inwards, the solar energy can be converted into electric energy through the photovoltaic panel 14, and the electric energy is used for installing the moving assembly 3 through the first through hole 12 and the second through hole 18.

The structure of the linkage mechanism 23 in the utility model is shown in fig. 3, and the linkage mechanism comprises a plate body 231, wherein a one-way valve 238 is arranged on the plate body 231, a second belt pulley 236 is rotatably connected above the one-way valve 238, a plurality of small linkage tooth grooves 237 are arranged on the outer wall of the tail end of the second belt pulley 336, a sliding groove 232 is arranged on the outer wall of the plate body 231, which is close to the lower part of the one-way valve 238, symmetrical sliding blocks are slidingly connected in the sliding groove 232, symmetrical first belt pulleys 234 are rotatably connected on the outer parts of the sliding blocks at two sides, springs 233 are arranged between the sliding blocks at two sides, and belts 235 are sleeved on the outer walls of the second belt pulley 236 and the first belt pulleys 234 at two sides.

The two adjacent plates 231 are not contacted with each other by the plates 231 which are connected with the bottom of the mounting plate 11 in a sliding way at the positions close to four sides.

In the present utility model, as shown in fig. 4, the moving assembly 2 includes a moving mechanism 21, a power mechanism 22 and a linkage mechanism 23, and a plurality of moving mechanisms 21 are disposed outside the power mechanism 22. The power of the movement is provided by the power mechanism 22 and the water is aerated in cooperation with the one-way valve 238.

The structure of the moving mechanism 2 in the utility model is shown in fig. 5, and the moving mechanism comprises a left-right symmetrical wind-up roller 211, wherein the outer walls of wind-up rollers 2311 on two sides are rotatably connected with a second bracket 212, one side of the second bracket 212 on two sides is movably provided with a second motor 213, the rotating end of the second motor 213 penetrates through the second bracket 212 to be fixedly connected with the wind-up roller 211, the outer walls of the wind-up rollers 311 on two sides are wound with anchor ropes 214, the tail ends of the anchor ropes 214 on two sides are fixedly connected with balancing weights 215, the back surfaces of the balancing weights 215 are rotatably connected with impellers 216, the front surfaces of the balancing weights 215 are rotatably connected with third pulleys 217, and the third pulleys 217 penetrate through the balancing weights 215 to be fixedly connected with the impellers 216. The device is fixed by sleeving the third belt pulley 217 with the belt 235 and generating gravity in water through the balancing weight 215, and can move in water through the impeller 216 matched with the third belt pulley 217 and the belt 235 and the power mechanism 22.

The power mechanism 22 in the utility model is shown in fig. 6, and comprises an aeration motor 221, wherein the bottom of the aeration motor 221 is fixedly connected with a linkage large gear 222, and the bottom of the linkage large gear 222 is fixedly connected with an aeration blade 223. The aeration motor 221 rotates to link the large gear 222 and the aeration blade 223 to rotate, and the one-way valve 238 is matched for aeration. The rotation end of the aeration motor 221 is inserted into the inside of the second through hole 18.

The plate bodies 231 are slidably connected to the bottom of the mounting plate 11 at positions close to four sides, and every two adjacent plate bodies 231 are not contacted.

The anchor rope 214 is inserted into the first through hole 12, the second bracket 212 is fixedly connected to the upper end of the mounting plate 11, and the third pulley 217 is sleeved with the belt 235.

Working principle: when the device needs to move, the first motor 17 on one side parallel to the moving direction rotates to drive the photovoltaic panel 14 and the push plate 13 to rotate downwards, so that the linkage mechanism 23 on the adjacent side is pushed to move inwards, the linkage small tooth groove 237 is meshed with the linkage large gear 222 in the moving process, power transmission is completed, the belt 235 drives the third belt pulley 217 to rotate, the device can be driven to move in water, the second motor 213 is started to enable the anchor rope 214 to be lengthened to enable the balancing weight 215 to sink, and the first belt pulleys 234 on the two sides and the sliding block move inwards to be compressed by the spring 233 when the balancing weight 215 sinks, so that power transmission can be ensured.

Claims (8)

1. The river water quality detection position self-adjusting aeration device based on water environment treatment is characterized by comprising a mounting assembly and a moving assembly arranged on the mounting assembly; the moving assembly is used for driving the installation assembly to move on the water surface; the mounting assembly includes a photovoltaic module; the moving assembly comprises a moving mechanism, a power mechanism, an anchoring mechanism and an aeration assembly; the power mechanism is used for driving the moving mechanism to drive the installation assembly to move on the water surface, and the anchoring mechanism is used for anchoring the installation assembly on the water surface when the installation assembly stops moving; the photovoltaic module is used for supplying power to the aeration module, the power mechanism and the anchoring mechanism.

2. The river water quality detection position self-adjusting aeration device based on water environment treatment according to claim 1, wherein the device is characterized in that: the moving mechanism comprises four impellers in front, back, left and right, and the power mechanism drives the four impellers in front, back, left and right to rotate.

3. The river water quality detection position self-adjusting aeration device based on water environment treatment according to claim 2, wherein the device is characterized in that: the anchoring mechanism comprises an anchor rope, a wind-up roller and a balancing weight, one end of the anchor rope is wound on the wind-up roller, and the other end of the anchor rope is connected with the balancing weight; and the wind-up roller is connected with the photovoltaic module to obtain a power supply.

4. A river water quality detection position self-regulating aeration device based on water environment treatment according to claim 3, wherein: the front, back, left and right impellers are arranged on the balancing weight.

5. A river water quality detection position self-regulating aeration device based on water environment treatment according to claim 3, wherein: the movable assembly further comprises a linkage mechanism, and the linkage mechanism is connected with the power mechanism and used for driving the aeration assembly to perform aeration.

6. The river water quality detection position self-adjusting aeration device based on water environment treatment according to claim 5, wherein the device comprises: the power mechanism comprises an aeration motor, a linkage large gear and aeration fan blades; the linkage large gear is fixedly connected to the bottom of the aeration motor, and the aeration fan blade is fixedly connected to the bottom of the linkage large gear; the linkage mechanism comprises a linkage pinion and a belt transmission mechanism, and the linkage pinion drives the belt transmission mechanism; the linkage pinion is meshed with the linkage bull gear; the belt transmission mechanism is connected with the front impeller, the rear impeller, the left impeller and the right impeller.

7. The river water quality detection position self-adjusting aeration device based on water environment treatment according to claim 6, wherein the device comprises: the belt transmission mechanism comprises a belt, a second belt pulley, a third belt pulley and a belt height adjusting mechanism, and the second belt pulley is arranged on the linkage pinion; the third belt pulley is arranged on the balancing weight and connected with the front impeller, the rear impeller, the left impeller and the right impeller.

8. The river water quality detection position self-adjusting aeration device based on water environment treatment according to claim 7, wherein: the belt height adjusting mechanism comprises two first pulleys and a spring arranged between the two first pulleys.

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