CN112062296A

CN112062296A - Micro-nano bubble generating device based on remote control technology

Info

Publication number: CN112062296A
Application number: CN202010961142.XA
Authority: CN
Inventors: 封丽; 封雷; 廖伟伶; 李子未; 姚源
Original assignee: Chongqing Academy Of Eco-Environmental Sciences
Current assignee: Chongqing Academy Of Eco-Environmental Sciences
Priority date: 2020-09-14
Filing date: 2020-09-14
Publication date: 2020-12-11

Abstract

A micro-nano bubble generating device based on a remote control technology comprises a floating box, wherein the floating box is provided with a motor, the motor is provided with a paddle wheel, the floating box is provided with a water suction pump, an air suction pump, a bubble generator and a storage battery, the water suction pump is provided with a water inlet pipe, the water outlet end of the bubble generator is connected with a water discharge pipe penetrating through the lower end of the floating box, the lower end of the water discharge pipe is connected with a water distribution pipe, one side, away from the water inlet pipe, of the water distribution pipe is provided with a plurality of spray heads, the upper end of the floating box is provided with a; the device can the whole device of remote control move on the surface of water for whole device can pour into the bubble into to other positions of water, lets whole water can obtain effectual processing, and wherein when the device gos forward on the surface of water, the reaction force that can rely on the shower nozzle water spray to form gos forward as thrust, and is energy-concerving and environment-protective.

Description

Micro-nano bubble generating device based on remote control technology

Technical Field

The invention belongs to the technical field of micro-nano bubble generating devices, and particularly relates to a micro-nano bubble generating device based on a remote control technology.

Background

Researches show that the micro-nano bubbles are applied to the field of sewage treatment, have very remarkable advantages, can quickly improve the dissolved oxygen degree in water, promote the growth of aerobic bacteria, and quickly decompose organic matters in the water by the aerobic bacteria; meanwhile, anaerobic bacteria breeding is inhibited, water body deterioration is effectively controlled, and the water body is kept clean; secondly, the micro-nano bubbles have electric charges on the surface, so that organic matters in water can be adsorbed, and the micro-nano bubbles float or sink on the surface, and can be quickly cleaned; can also reduce eutrophication caused by organic matter deposition, effectively treat water pollution, petroleum pollution and other problems; moreover, compared with the conventional river aeration oxygenation mode, a large amount of micro-nano bubbles are mixed into river water, so that the detention of the bubbles in the water is prolonged by many times, the adding amount of a medicament can be reduced, the medicament input cost is reduced, and the secondary pollution and the post-treatment cost of the medicament to the environment are reduced.

However, when the existing micro-nano bubble generating device is used, bubbles can only be injected into a water body on the bank, the working range is very limited, other positions of the water body are inconvenient to inject the bubbles, the whole water body cannot be effectively treated, and the micro-nano bubble generating device based on the remote control technology is provided for solving the problems.

Disclosure of Invention

The purpose of the invention is: aims to provide a micro-nano bubble generating device based on a remote control technology, which is used for solving the problems existing in the background technology.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows:

a micro-nano bubble generating device based on a remote control technology comprises a buoyancy tank, wherein the left side and the right side inside the buoyancy tank are fixedly connected with motors, the rotating shafts of the two motors are fixedly connected with paddle wheels, the buoyancy tank is provided with two paddle wheel covers matched with the two paddle wheels, the bottom of the inner side of the buoyancy tank is fixedly connected with a water suction pump, an air suction pump, a bubble generator and a storage battery, the water suction pump and the air suction pump are arranged on the front side of the upper end inside the buoyancy tank, the bubble generator is arranged on the rear side of the upper end inside the buoyancy tank, the pumping end of the water suction pump is connected with a water inlet pipe penetrating through the lower end of the buoyancy tank, the pumping end of the water suction pump is connected with a water inlet end pipe of the bubble generator, the pumping end of the air suction pump is connected with a water inlet end pipe of the bubble generator, the water outlet end of the bubble generator is connected with, the utility model discloses a solar water heater, including inlet tube, flotation tank, air pump, signal receiver, suction pump, bubble generator and storage battery electricity, the inlet tube is kept away from to the distributive pipe one side and is equipped with a plurality of shower nozzles, the flotation tank upper end is equipped with the apron, the air pump is gone into the end and is connected with the intake pipe that upwards runs through the apron, the apron upper end is equipped with signal receiver, signal receiver is.

By adopting the technical scheme of the invention, when the buoyancy tank is placed on the water surface, the whole device can float on the water surface under the buoyancy of water, and the storage battery is used for supplying power to each electric appliance; when the device is used, the whole device is placed in a water body needing inflation treatment, then a signal can be transmitted to a signal receiver through a remote controller, the specifically transmitted signal comprises an inflation working signal, an inflation stop signal, a left steering signal, a right steering signal, an auxiliary forward signal and a backward signal, when the signal receiver receives the inflation working signal, a water suction pump, an air suction pump and a bubble generator are electrified to work, the water suction pump pumps water through a water inlet pipe and pumps the water into the bubble generator, the air suction pump sucks the air through an air inlet pipe and pumps the air into the bubble generator, the bubble generator produces water mixed with micro-nano bubbles, the micro-nano water mixed with the bubbles sequentially flows through a water discharge pipe and a water distribution pipe, and finally the micro-nano water mixed with the bubbles is sprayed out through each spray head, the sprayed out water body can be inflated, and simultaneously, the spray heads can generate a thrust opposite to the, the thrust can push the whole device to move forward on the water surface, and when the signal receiver receives an inflation stop signal, the water suction pump, the air suction pump and the bubble generator are powered off to stop working, so that the device cannot perform inflation treatment on the water body; when the signal receiver receives a left steering signal, the motor on the left side is electrified to drive the paddle wheel to rotate backwards, and the motor on the right side is electrified to drive the paddle wheel to rotate forwards, so that the left side of the buoyancy tank is subjected to backward thrust, the right side of the buoyancy tank is subjected to forward thrust, and the whole device can steer leftwards; when the signal receiver receives a right steering signal, the motor on the left side is electrified to drive the paddle wheel to rotate forwards, and the motor on the right side is electrified to drive the paddle wheel to rotate backwards, so that the left side of the buoyancy tank is pushed forwards, the right side of the buoyancy tank is pushed backwards, and the whole device can steer rightwards; when the signal receiver receives the auxiliary advancing signal, the two motors on the left side and the right side are electrified to drive the two paddle wheels to rotate forwards simultaneously, so that the left side and the right side of the buoyancy tank are simultaneously pushed forwards, the whole device can be assisted to move forwards, and the device can conveniently move forwards in an environment with rapid water flow; when the signal receiver receives a retreat signal, the two motors on the left side and the right side are electrified to drive the two paddle wheels to rotate backwards simultaneously, so that the left side and the right side of the buoyancy tank are subjected to backward thrust simultaneously, the whole device can move backwards, and when the signal receiver receives the retreat signal, the water suction pump, the air suction pump and the bubble generator are powered off and stop working, so that interference influence on retreat is avoided; the whole device can be remotely controlled to move on the water surface through signals given by the remote controller, so that bubbles can be injected into other positions of the water body by the whole device, and the whole water body can be effectively treated;

the invention provides a micro-nano bubble generating device based on a remote control technology, which can remotely control the whole device to move on the water surface, so that the whole device can inject bubbles into other positions of a water body, the whole water body can be effectively treated, when the device moves forwards on the water surface, the device can move forwards by taking the reaction force formed by spraying water by a spray head as a thrust, and the micro-nano bubble generating device is energy-saving and environment-friendly.

Further inject, the inlet tube lower extreme is connected with first filter screen. Such structure can filter water, avoids the impurity of aquatic to enter into the inlet tube.

Further inject, the intake pipe upper end is equipped with the second filter screen. Such structure can filter the air, avoids the impurity in the air to enter into the intake pipe.

Further limit, the upper end of the second filter screen is provided with a rain baffle. Such structure can keep off the rain to the second filter screen, avoids the second filter screen to be drenched by the rainwater.

Further limiting, the outer side of the buoyancy tank is fixedly connected with an annular air bag. By adopting the structure, the buoyancy force borne by the whole device can be increased, and the floating box is prevented from accidentally entering water and sinking.

Further inject, four supporting legss of flotation tank lower extreme fixedly connected with, four the supporting legs lower extreme all is equipped with the backup pad. Such a structure can provide support when the entire device is placed on the ground.

Further limit, adopt between apron and the flotation tank can dismantle fixed connection. Such connected mode, the convenience is torn down the apron and is overhauld the flotation tank is inside.

Compared with the prior art, the invention has the following advantages:

Drawings

The invention is further illustrated by the non-limiting examples given in the accompanying drawings;

fig. 1 is a schematic structural diagram of a micro-nano bubble generating device based on a remote control technology according to an embodiment of the invention;

FIG. 2 is a schematic structural diagram II of an embodiment of a micro-nano bubble generating device based on a remote control technology according to the present invention;

fig. 3 is a schematic view of a partial structure of an embodiment of a micro-nano bubble generating device based on a remote control technology.

The main element symbols are as follows:

the device comprises a buoyancy tank 1, a motor 2, a paddle wheel 21, a paddle wheel cover 22, a water suction pump 23, an air suction pump 24, an air bubble generator 25, a storage battery 26, a water inlet pipe 27, a water discharge pipe 3, a water distribution pipe 31, a spray head 32, a cover plate 33, an air inlet pipe 34, a signal receiver 35, a first filter screen 4, a second filter screen 41, a rain baffle 42, an annular air bag 43, supporting legs 44 and a supporting plate 45.

Detailed Description

In order that those skilled in the art can better understand the present invention, the following technical solutions are further described with reference to the accompanying drawings and examples.

As shown in fig. 1-3, the micro-nano bubble generating device based on the remote control technology of the present invention comprises a floating box 1, wherein the left and right sides inside the floating box 1 are both fixedly connected with motors 2, the rotating shafts of the two motors 2 are both fixedly connected with paddle wheels 21, the floating box 1 is provided with two paddle wheel covers 22 matched with the two paddle wheels 21, the bottom inside the floating box 1 is fixedly connected with a water suction pump 23, an air suction pump 24, a bubble generator 25 and a storage battery 26, the water suction pump 23 and the air suction pump 24 are arranged on the front side of the upper inside end of the floating box 1, the bubble generator 25 is arranged on the rear side of the upper inside end of the floating box 1, the pumping end of the water suction pump 23 is connected with a water inlet pipe 27 penetrating through the lower end of the floating box 1, the pumping end of the water suction pump 23 is connected with a water inlet pipe of the bubble generator 25, the pumping end of the air suction pump 24 is connected with a water inlet pipe of the bubble generator, the lower extreme of drain pipe 3 is connected with distributive pipe 31, and distributive pipe 31 is kept away from inlet tube 27 one side and is equipped with a plurality of shower nozzles 32, and the flotation tank 1 upper end is equipped with apron 33, and the pump pumping end of aspiration pump 24 is connected with the intake pipe 34 that upwards runs through apron 33, and the apron 33 upper end is equipped with signal receiver 35, and signal receiver 35 is connected with two motors 2, suction pump 23, bubble generator 25 and battery 26 electricity.

By adopting the technical scheme of the invention, when the buoyancy tank 1 is placed on the water surface, the whole device can float on the water surface under the buoyancy of water, and the storage battery 26 is used for supplying power to each electric appliance; when the device is used, the whole device is placed in a water body needing inflation treatment, then signals can be transmitted to the signal receiver 35 through the remote controller, specifically transmitted signals comprise inflation working signals, inflation stop signals, left steering signals, right steering signals, auxiliary forward signals and backward signals, when the signal receiver 35 receives the inflation working signals, the water suction pump 23, the air suction pump 24 and the bubble generator 25 are electrified to work, the water suction pump 23 pumps water through the water inlet pipe 27 and pumps the water into the bubble generator 25, the air suction pump 24 sucks the air through the air inlet pipe 34 and pumps the air into the bubble generator 25, the bubble generator 25 produces water mixed with micro-nano bubbles, the water mixed with the micro-nano bubbles sequentially flows through the water discharge pipe 3 and the water distribution pipe 31 and is finally sprayed out through the spray heads 32, the sprayed water mixed with the micro-nano bubbles can be inflated to the water body, and meanwhile when the spray heads 32 spray water, a thrust opposite to the water spraying direction is generated, the thrust can push the whole device to advance on the water surface, when the signal receiver 35 receives an inflation stop signal, the water suction pump 23, the air suction pump 24 and the bubble generator 25 are powered off to stop working, and the device cannot perform inflation treatment on the water body; when the signal receiver 35 receives a left steering signal, the motor 2 on the left side is electrified to drive the paddle wheel 21 to rotate backwards, and the motor 2 on the right side is electrified to drive the paddle wheel 21 to rotate forwards, so that the left side of the buoyancy tank 1 is subjected to backward thrust, and the right side of the buoyancy tank is subjected to forward thrust, and the whole device can steer left; when the signal receiver 35 receives a right steering signal, the motor 2 on the left side is electrified to drive the paddle wheel 21 to rotate forwards, and the motor 2 on the right side is electrified to drive the paddle wheel 21 to rotate backwards, so that the left side of the buoyancy tank 1 is pushed forwards, the right side of the buoyancy tank is pushed backwards, and the whole device can steer rightwards; when the signal receiver 35 receives the auxiliary advancing signal, the two motors 2 on the left and right sides are electrified to drive the two paddle wheels 21 to rotate forwards at the same time, so that the left and right sides of the buoyancy tank 1 are simultaneously subjected to forward thrust, the whole device can be assisted to move forwards, and the device can conveniently move forwards in an environment with rapid water flow; when the signal receiver 35 receives a retreat signal, the two motors 2 on the left and right sides are electrified to drive the two paddle wheels 21 to rotate backwards at the same time, so that the left and right sides of the buoyancy tank 1 are subjected to backward thrust at the same time, the whole device can move backwards, and when the signal receiver 35 receives the retreat signal, the water suction pump 23, the air suction pump 24 and the bubble generator 25 are powered off to stop working, so that the interference influence on the retreat is avoided; the whole device can be remotely controlled to move on the water surface through signals given by the remote controller, so that bubbles can be injected into other positions of the water body by the whole device, and the whole water body can be effectively treated;

Preferably, the lower end of the water inlet pipe 27 is connected with the first filter 4. With the structure, water can be filtered, and impurities in the water are prevented from entering the water inlet pipe 27. In fact, other structures capable of filtering water to prevent impurities in water from entering the water inlet pipe 27 may be used according to the situation.

Preferably, the upper end of the intake pipe 34 is provided with a second filter 41. With such a structure, air can be filtered, and impurities in the air can be prevented from entering the intake pipe 34. In fact, other structures capable of filtering the air to prevent impurities in the air from entering the air inlet pipe 34 may be used according to the circumstances.

Preferably, a rain shield 42 is disposed at the upper end of the second filter 41. With such a structure, the second filter 41 can be kept off the rain, and the second filter 41 is prevented from being drenched by the rain. In fact, other structures capable of shielding the second filter 41 from rain and preventing the second filter 41 from being drenched by rain water may be considered according to the circumstances.

Preferably, an annular air bag 43 is fixedly connected to the outer side of the buoyancy tank 1. By adopting the structure, the buoyancy force borne by the whole device can be increased, and the floating box 1 is prevented from accidentally entering water and sinking. In fact, other buoyancy which can increase the whole device can be considered according to the situation, and the floating box 1 is prevented from accidentally entering water and sinking.

Preferably, the lower end of the buoyancy tank 1 is fixedly connected with four supporting legs 44, and the lower ends of the four supporting legs 44 are respectively provided with a supporting plate 45. Such a structure can provide support when the entire device is placed on the ground. In fact, other structures that can support the entire device when it is placed on the ground are also contemplated.

Preferably, the cover plate 33 is detachably and fixedly connected with the buoyancy tank 1. Such a connection mode facilitates the removal of the cover plate 33 for the maintenance of the interior of the buoyancy tank 1. In fact, other connection modes which facilitate the detachment of the cover plate 33 for maintenance of the interior of the buoyancy tank 1 may be used according to circumstances.

The foregoing embodiments are merely illustrative of the principles of the present invention and its efficacy, and are not to be construed as limiting the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims

1. The utility model provides a micro-nano bubble generating device based on remote control technique, includes flotation tank (1), its characterized in that: the floating box is characterized in that motors (2) are fixedly connected to the left side and the right side inside the floating box (1), paddle wheels (21) are fixedly connected to two rotating shafts of the motors (2), the floating box (1) is provided with two paddle wheel covers (22) matched with the two paddle wheels (21), a water suction pump (23), an air suction pump (24), a bubble generator (25) and a storage battery (26) are fixedly connected to the bottom of the inner side of the floating box (1), the water suction pump (23) and the air suction pump (24) are arranged on the front side of the upper end inside the floating box (1), the bubble generator (25) is arranged on the rear side of the upper end inside the floating box (1), the pumping end of the water suction pump (23) is connected with a water inlet pipe (27) penetrating through the lower end of the floating box (1), the pumping end of the water suction pump (23) is connected with a water inlet end pipeline of the bubble generator (25), and the pumping end of the air suction pump (24) is connected with a gas, the water outlet end of the bubble generator (25) is connected with a drain pipe (3) penetrating through the lower end of the floating box (1), the lower end of the drain pipe (3) is connected with a water distribution pipe (31), one side of the water distribution pipe (31) far away from the water inlet pipe (27) is provided with a plurality of spray heads (32), the upper end of the floating box (1) is provided with a cover plate (33), the pumping end of the air pump (24) is connected with an air inlet pipe (34) penetrating through the cover plate (33) upwards, the upper end of the cover plate (33) is provided with a signal receiver (35), and the signal receiver (35) is electrically connected with two motors (2), a water suction pump (23), the bubble generator.

2. The micro-nano bubble generating device based on the remote control technology according to claim 1, characterized in that: the lower end of the water inlet pipe (27) is connected with a first filter screen (4).

3. The micro-nano bubble generating device based on the remote control technology according to claim 1, characterized in that: and a second filter screen (41) is arranged at the upper end of the air inlet pipe (34).

4. The micro-nano bubble generating device based on the remote control technology according to claim 3, characterized in that: and a rain baffle (42) is arranged at the upper end of the second filter screen (41).

5. The micro-nano bubble generating device based on the remote control technology according to claim 1, characterized in that: the outer side of the buoyancy tank (1) is fixedly connected with an annular air bag (43).

6. The micro-nano bubble generating device based on the remote control technology according to claim 1, characterized in that: the lower end of the buoyancy tank (1) is fixedly connected with four supporting legs (44), and supporting plates (45) are arranged at the lower ends of the four supporting legs (44).

7. The micro-nano bubble generating device based on the remote control technology according to claim 1, characterized in that: the cover plate (33) is detachably and fixedly connected with the buoyancy tank (1).