CN213663566U - Electrolysis turbine integral type cleaner - Google Patents

Abstract

The utility model relates to the technical field of cleaners, in particular to an electrolysis turbine integrated cleaner, which comprises an electrolysis turbine cleaning mechanism, a drainer connected with an external water tank and a power supply device for supplying power to the electrolysis turbine cleaning mechanism; the electrolytic turbine cleaning mechanism is arranged on the drainer; the electrolytic turbine cleaning mechanism comprises a shell, a turbine plate, a containing cavity, an electrolytic driving module, a turbine driving module, an electrolytic cavity communicated with the water tank and an electrolytic module for electrolyzing water; the turbine plate is rotationally connected with the housing; the turbine drive module rotates the turbine plate; the electrolysis chamber is arranged on the shell. The utility model discloses can stir the hydroenergy in the basin fully to soaking be that fruit vegetables bowl dish washs, also can disinfect fruit vegetables and bowl dish, environmental protection health, security are good.

Description

Electrolysis turbine integral type cleaner

Technical Field

The utility model relates to a cleaner technical field, concretely relates to electrolysis turbine integral type cleaner.

Background

Fruits and vegetables contain some vitamins, inorganic salts, dietary fibers and the like which are necessary for human bodies. With the progress and development of society and the improvement of nutrition meaning of people, people want to take more fruits and vegetables, so that different varieties of fruits and vegetables are gradually increased on the market.

At present, people usually put fruits, vegetables and dishes into a water tank, then add clean water into the water tank, then soak the fruits, vegetables and dishes, and then manually clean the fruits, vegetables and dishes. However, such a cleaning method takes a long time and is insufficient in cleaning. The fruits, vegetables and dishes are manually cleaned. However, such a cleaning method is easy to clean incompletely, and has virus, bacteria or pesticide residue, which is harmful to human body.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome above shortcoming provide an electrolysis turbine integral type cleaner, can stir the hydroenergy in the basin and fully wash the fruit vegetables bowl dish to soaking, also can disinfect fruit vegetables and bowl dish, environmental protection health, security are good.

In order to achieve the above purpose, the specific scheme of the utility model is as follows: an electrolysis turbine integrated cleaner comprises an electrolysis turbine cleaning mechanism, a drainer connected with an external water tank and a power supply device for supplying power to the electrolysis turbine cleaning mechanism; the electrolytic turbine cleaning mechanism is arranged on the drainer; the electrolytic turbine cleaning mechanism comprises a shell, a turbine plate, a containing cavity, an electrolytic driving module, a turbine driving module, an electrolytic cavity communicated with the water tank and an electrolytic module for electrolyzing water; the turbine plate is rotationally connected with the housing; the turbine drive module rotates the turbine plate; the electrolysis cavity is arranged on the shell; the electrolysis module is arranged in the electrolysis cavity; the electrolysis driving module is electrically connected with the electrolysis module; the accommodating cavity is arranged inside the shell; the electrolysis driving module and the turbine driving module are arranged in the accommodating cavity; the electrolysis driving module and the turbine driving module are electrically connected with the power supply device.

Further, the power supply device comprises a wireless driving mechanism; the electrolysis turbine cleaning mechanism is detachably connected with the drainer; the wireless driving mechanism comprises a receiving module arranged in the electrolytic turbine cleaning mechanism and a transmitting module arranged in the drainer; the receiving module is coupled with the transmitting module; the receiving module is arranged in the accommodating cavity; the electrolysis driving module and the turbine driving module are electrically connected with the receiving module.

Further, the drainer comprises an inner shell and an outer shell which are connected with each other; the inner wall of the inner shell forms a hollow drainage cavity for draining water in the water tank; the transmitting module is arranged between the inner shell and the outer shell; the receiving framework is arranged in the accommodating cavity.

Furthermore, the receiving module comprises a receiving framework, a receiving magnetic core sleeved on the inner surface of the receiving framework and a receiving coil wound on the outer surface of the receiving framework; the receiving coil is electrically connected with the electrolysis driving module and the turbine driving module; the transmitting module comprises a transmitting framework, a transmitting coil wound on the outer surface of the transmitting framework and a transmitting magnetic core sleeved on the outer surface of the transmitting framework; the emission framework is arranged between the inner shell and the outer shell.

Further, a first placing groove for placing a receiving coil is formed in the outer surface of the receiving framework; and a second placing groove for placing the transmitting coil is formed in the outer surface of the transmitting framework.

Furthermore, a first through hole and a second through hole which are communicated with the electrolytic cavity are arranged on the shell; the first through hole is used for the water in the water supply tank to flow into the electrolysis cavity; the first through hole is formed in the top of the electrolytic cavity; the second through hole is used for supplying water flow to flow out of the electrolysis cavity into the drainer; the second through hole is formed in the bottom of the electrolytic cavity;

the shell comprises a top shell, a waterproof shell and a bottom shell; the top shell is detachably connected with the waterproof shell; the top shell and the waterproof shell form the electrolysis cavity; the waterproof shell is detachably connected with the bottom shell; the accommodating cavity is formed between the waterproof shell and the bottom shell; a first waterproof sealing ring is arranged between the waterproof shell and the bottom shell.

Further, the electrolysis module comprises a first electrolysis electrode and a second electrolysis electrode; the first electrolysis electrode and the second electrolysis electrode are both arranged in the electrolysis cavity; an insulating spacer is arranged between the first electrolytic electrode and the second electrolytic electrode;

the electrolysis driving module is provided with a first conductive column and a second conductive column; the anode output end of the electrolysis driving module is electrically connected with the first electrolysis electrode through a first conductive column; the negative electrode output end of the electrolysis driving module is electrically connected with the second electrolysis electrode through a second conductive column;

the first electrolysis electrode is arranged above the second electrolysis electrode; the second electrolysis electrode is arranged above the electrolysis driving module; the second electrolysis electrode is provided with a first via hole for the first conductive column to pass through; the first conductive pillar penetrates through the first via hole and is electrically connected with the first electrolysis electrode.

Furthermore, a water stirring rib is arranged on the turbine plate; the number of the water stirring ribs is two to eight; all the water stirring convex edges are divergently arranged around the center of the circle of the turbine plate as the axis.

Further, the turbine driving module comprises a turbine motor, a turbine rotating shaft connected with the output end of the turbine motor and a PCB (printed Circuit Board) for driving the turbine motor to work; the shell is provided with a rotating shaft through hole for accommodating the turbine rotating shaft; the turbine plate is arranged above the electrolysis cavity; one end of the turbine rotating shaft penetrates through the electrolysis module and then is connected with the turbine plate; the other end of the turbine rotating shaft is connected with the turbine motor; the PCB is electrically connected with the power supply device; the turbine rotating shaft is sleeved with a rotating shaft waterproof sealing ring used for preventing water from entering the accommodating cavity.

Further, the turbine plate is integrally provided with the top case.

The utility model has the advantages that: through setting up electrolysis chamber and electrolysis module, can the water in the electrolysis basin, disinfect fruit vegetables and bowl dish, environmental protection health. Through setting up wireless power supply mechanism, the security is good. The turbine plate can stir water in the water tank, and can fully clean fruits, vegetables and dishes after soaking.

Drawings

The invention is further described with the aid of the accompanying drawings, in which, however, the embodiments do not constitute any limitation to the invention, and for a person skilled in the art, other drawings can be derived from the following drawings without inventive effort.

Fig. 1 is a schematic structural view of the present invention assembled with a sink;

FIG. 2 is a schematic structural view of the electrolytic turbine cleaning mechanism before assembly with the downcomer;

FIG. 3 is a schematic view showing the internal structure of the electrolytic turbine cleaning mechanism;

FIG. 4 is an exploded view of an electrolytic turbine cleaning mechanism;

FIG. 5 is a schematic view of the internal structure of the assembled bottom shell and the drainer;

FIG. 6 is an exploded view of the transmitter module;

FIG. 7 is an exploded view of the receiving module;

FIG. 8 is an exploded view of the turbine plate, first electrolytic electrode, second electrolytic electrode, insulating separator;

FIG. 9 is a schematic circuit diagram of an electrolytic driving module according to the present invention;

fig. 10 is a schematic circuit diagram of a PCB of the present invention;

fig. 11 is a schematic circuit diagram of a rectifying unit of the electrolytic driving module or a rectifying unit of the PCB of the present invention;

fig. 12 is a schematic circuit diagram of a control unit of the electrolytic driving module or a control unit of the PCB of the present invention;

fig. 13 is a schematic circuit diagram of the constant voltage and constant current unit of the electrolytic driving module or the control unit of the PCB of the present invention;

fig. 14 is a schematic circuit diagram of the voltage reducing unit of the electrolytic driving module or the voltage reducing unit of the PCB of the present invention.

Wherein: 10. a water tank; 1. an electrolytic cleaning mechanism; 11. an accommodating cavity; 12. a top shell; 13. a waterproof shell; 14. a bottom case; 15. a first through hole; 16. a second through hole; 17. a first waterproof seal ring; 18. A second waterproof seal ring; 31. an electrolysis chamber; 32. a first electrolysis electrode; 33. a second electrolysis electrode; 34. an insulating spacer; 35. a first via hole; 36. an electrolysis driving module; 37. a first conductive post; 38. A second conductive post; 19. a turbine plate; 41. water stirring ribs; 42. a turbine motor; 43. a turbine shaft; 44. a PCB board; 45. a through hole of the rotating shaft; 46. a waterproof sealing ring of the rotating shaft; 2. a drainer; 21. An inner shell; 22. a housing; 23. a hollow drainage cavity; 7. a receiving module; 71. receiving a skeleton; 72. Receiving a magnetic core; 73. a receiving coil; 74. a first placing groove; 81. launching the skeleton; 82. a transmitting coil; 83. a transmitting magnetic core; 84. a second placing groove; 30. an electrolysis module.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

As shown in fig. 1 to 14, the electrolytic turbine integrated cleaner according to the present embodiment includes an electrolytic turbine cleaning mechanism 1, a water drainer 2 connected to an external water tank 10, and a power supply device for supplying power to the electrolytic turbine cleaning mechanism 1; the electrolytic turbine cleaning mechanism 1 is arranged on the drainer 2; the electrolytic turbine cleaning mechanism 1 comprises a shell, a turbine plate 19, a containing cavity 1, an electrolysis driving module 36, a turbine driving module, an electrolysis cavity 31 communicated with the water tank 10 and an electrolysis module 30 for electrolyzing water; the turbine plate 19 is in rotational connection with the housing; the turbine drive module rotates the turbine plate 19; the electrolysis cavity 31 is arranged on the shell; the electrolysis module 30 is arranged in the electrolysis cavity 31; the electrolysis driving module 36 is electrically connected with the electrolysis module 30; the accommodating cavity 1 is arranged inside the shell; the electrolysis driving module 36 and the turbine driving module are both arranged in the accommodating cavity 1; the electrolysis driving module 36 and the turbine driving module are electrically connected to the power supply device.

Specifically, the shape of the drainer 2 may be a shape of a common drainer 2, and may be fitted in a tank 10, a water tank, or the like that can hold a body of water. When the fruits, vegetables and dishes need to be disinfected, the electrolytic cleaning mechanism is only required to be placed on the drainer 2, and the transmitting module in the drainer 2 and the receiving module 7 in the electrolytic cleaning mechanism can be well coupled. Then, the fruits, vegetables and dishes can be placed in the water tank 10, then the water tank 10 is filled with enough water, the fruits, vegetables and dishes are soaked by the water body, meanwhile, the water flow can flow into the electrolysis cavity 31 in the shell and fully contact with the electrolysis module 30 in the electrolysis cavity 31, then the external switch can be started, the power supply device starts to work, the electrolysis process starts, and the fruits, vegetables and dishes are disinfected.

The principle of electrolytic disinfection is as follows: the electrolysis driving module may be a conventional constant voltage and constant current circuit for driving the electrolysis module to operate, and includes a rectifying unit for rectifying the electric energy from the receiving module 7, a voltage reducing unit for transforming the current to a voltage (12-24V) required by the electrolysis module, a constant voltage and constant current unit for stably operating the electrolysis module, and a control unit for controlling the operation state of the electrolysis module. In addition, in order to save the product space, the PCB boards in the electrolysis driving module and the turbine driving module share one PCB. After the electrolysis driving module 36 receives the electric energy from the receiving module 7, the electrolysis driving module 36 drives the electrolysis module to start an electrolysis reaction, so as to perform the electrolysis reaction on the water in the electrolysis cavity 31 and sterilize the cleaned objects. The electrolysis mode is adopted for disinfection, so that toxic components are not left, and the method is very safe.

When the water bodies of fruits, vegetables and dishes need to be stirred, the electrolytic turbine cleaning mechanism 1 is only required to be placed on the drainer 2, and the transmitting module in the drainer 2 and the receiving module 7 in the turbine cleaning mechanism 1 can be well coupled. Then, can place fruit vegetables and bowl dish in basin 10, then pour into sufficient water in with basin 10, fruit vegetables and bowl dish this moment will be soaked by the water, and simultaneously, turbine board 19 also can the water soak, we can start outside switch after that, make no power supply unit begin to work, receiving module 7 drive turbine drive module in the wireless power supply mechanism begins to work, turbine drive mechanism drives turbine board 19 clockwise or anticlockwise rotation, thereby realize the stirring effect to the water in basin 10, the water is at the pivoted in-process, can take away the goods and materials of attached to residual pesticide or bowl dish on fruit vegetables, reduce the soak time of fruit vegetables and bowl dish, it is more abundant to wash, wash speed is higher.

As shown in fig. 1 to 9, the power supply device of the electrolytic turbine integrated cleaner according to the present embodiment includes a wireless driving mechanism; the electrolysis turbine cleaning mechanism 1 is detachably connected with the drainer 2; the wireless driving mechanism comprises a receiving module 7 arranged in the electrolytic turbine cleaning mechanism 1 and a transmitting module arranged in the drainer 2; the receiving module 7 is coupled with the transmitting module; the receiving module 7 is arranged in the accommodating cavity 1; the electrolysis driving module 36 and the turbine driving module are electrically connected to the receiving module 7.

The working principle of the wireless power supply module is as follows: in fact, the transmitting module in the drainer 2 is electrically connected to an external power source, and when the external power source supplies power to the transmitting module, the receiving module 7 coupled to the transmitting module generates a corresponding induced electromotive force and an induced current. The receiving module 7 starts to supply power to the electrolysis drive module 36 or the turbine drive module. The transmitting module in the wireless power supply mechanism is arranged on the drainer 2, and the wireless power supply function can be realized by matching with the receiving module 7 in the electrolysis turbine cleaning mechanism 1 detachably connected with the drainer 2. If the traditional wired power supply mode is adopted, the wiring is complicated, when an exposed wiring position exists, the waterproof sealing performance requirement at the wiring position is extremely high, potential safety hazards such as electric leakage exist, the wireless power supply mode is adopted, the induction electromotive force is generated between the drainer 2 and the electrolysis cleaning mechanism in a coupling mode, no current flows between the drainer 2 and the electrolysis cleaning mechanism, and the safety performance is greatly improved.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the drainer 2 includes an inner casing 21 and an outer casing 22 connected to each other; the inner wall of the inner shell 21 forms a hollow drainage cavity 23 for draining water in the water tank 10; the transmitting module is arranged between the inner shell 21 and the outer shell 22; the receiving framework 71 is arranged in the accommodating cavity 1.

Above-mentioned setting can be fine accomodate emission module in hydrophone 2 and accomodate receiving module 7 in the storage tank down, further improve waterproof leakproofness.

As shown in fig. 1 to 9, in the electrolysis and turbine integrated cleaner of the present embodiment, the receiving module 7 includes a receiving frame 71, a receiving core 72 sleeved on an inner surface of the receiving frame 71, and a receiving coil 73 wound on an outer surface of the receiving frame 71; the receiving coil 73 is electrically connected with the electrolysis driving module 36 and the turbine driving module; the transmitting module comprises a transmitting framework 81, a transmitting coil 82 wound on the outer surface of the transmitting framework 81 and a transmitting magnetic core 83 sleeved on the outer surface of the transmitting framework 81; the emission skeleton 81 is disposed between the inner casing 21 and the outer casing 22.

When the body of water is to be electrolyzed or the turbine plate 19 is rotated, the electrolytic cleaning mechanism is assembled with the downcomer 2. Since the transmitting coil 82 is electrically connected to an external power supply mechanism, such as a battery or commercial power, when the transmitting coil 82 is operated, the receiving coil 73 is placed at the inner ring of the receiving framework 71, and the transmitting coil 82 is placed at the outer ring of the transmitting framework 81, so that the receiving coil 73 is coupled with the transmitting coil 82. Further, the receiving coil 73 generates a corresponding induced electromotive force and an induction circuit therein, and the receiving coil 73 correspondingly supplies power to the electrolysis driving module 36 or the turbine driving module, thereby starting the electrolysis process or the agitation process. When electrolysis or agitation is not required, the power interface to the transmit coil 82 is suspended.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the outer surface of the receiving skeleton 71 is provided with a first placing groove 74 for placing the receiving coil 73; the outer surface of the transmitting bobbin 81 is provided with a second placing groove 84 for placing the transmitting coil 82.

The first placement groove 74 and the second placement groove 84 are provided to facilitate the fixed placement of the receiving bobbin 71 and the transmitting bobbin 81 for the receiving coil 73 and the transmitting coil 82, respectively.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the housing is provided with a first through hole 15 and a second through hole 16 which are communicated with the electrolysis chamber 31; the first through hole 15 is used for the water in the water supply tank 10 to flow into the electrolysis chamber 31; the first through hole 15 is arranged at the top of the electrolysis cavity 31; the second through hole 16 is used for supplying water to flow out of the electrolysis cavity 31 to the water drainer 2; the second through hole 16 is arranged at the bottom of the electrolytic cavity 31;

by providing the first through hole 15 at the top, the water in the water tank 10 is facilitated to flow into the electrolysis chamber 31 rapidly to react with the electrolysis module 30. Specifically, the second through hole 16 is arranged on the water-stop sheet; after the shell and the drainer 2 are assembled, during the electrolytic reaction, the water flow sequentially passes through the first through hole 15, the electrolytic cavity 31 and the second through hole 16 during the electrolytic reaction, and the electrolytic reaction is sufficient; at the same time, after the electrolysis reaction is finished, the shell is separated from the lower water device 2, and then the water flows out from the second through hole 16 under the action of gravity, so that the user does not need to turn the whole shell to pour the residual water in the electrolysis cavity 31.

The shell comprises a top shell 12, a waterproof shell 13 and a bottom shell 14; the top shell 12 is detachably connected with the waterproof shell 13; the top shell 12 and the waterproof shell 13 form the electrolysis cavity 31 therebetween; the waterproof shell 13 is detachably connected with the bottom shell 14; the accommodating cavity 1 is formed between the waterproof shell 13 and the bottom shell 14; a first waterproof sealing ring 17 is arranged between the waterproof shell 13 and the bottom shell 14.

Specifically, in order to reduce the number of parts and further reduce the volume of the product, the turbine plate 19 may be used as the top case 12 of the housing; the electrolysis cavity 31 is formed between the turbine plate 19 and the water-stop plate; the first through-holes 15 are provided on the top and side surfaces of the turbine plate 19. Through setting up first waterproof sealing ring 17, can further strengthen the leakproofness between water proof shell 13 and the drain pan 14, prevent that the water in the electrolysis chamber 31 from flowing into holding chamber 1, leading to the electrolysis actuating mechanism to damage. Through making between top shell 12 and the water proof shell 13 and between water proof shell 13 and the drain pan 14 can dismantle the connection, enable every part and separately produce, the production degree of difficulty is low, also convenient to overhaul simultaneously.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the electrolysis module 30 includes a first electrolysis electrode 32 and a second electrolysis electrode 33; the first electrolysis electrode 32 and the second electrolysis electrode 33 are both arranged in the electrolysis cavity 31; an insulating spacer 34 is provided between the first electrolytic electrode 32 and the second electrolytic electrode 33.

By providing the insulating spacer 34, the two electrodes can be effectively prevented from being short-circuited. In operation, the first electrolysis electrode 32 and the second electrolysis electrode 33 respectively serve as an anode and a cathode to electrolyze water, wherein the material of the first electrolysis electrode 32 may be lead dioxide, tin dioxide, platinum or glassy carbon.

As shown in fig. 1 to 9, in the electrolysis driving module 36 of the electrolysis turbine integrated cleaner of the present embodiment, a first conductive pillar 37 and a second conductive pillar 38 are disposed thereon; the positive output end of the electrolysis driving module 36 is electrically connected to the first electrolysis electrode 32 through a first conductive pillar 37; the negative output end of the electrolysis driving module 36 is electrically connected to the second electrolysis electrode 33 through a second conductive pillar 38.

Specifically, by providing the first conductive column 37 and the second conductive column 38, compared with the wire method, the power supply signal of the electrolysis driving module 36 installed in the accommodating chamber 1 can smoothly and reliably reach the first electrolysis electrode 32 and the second electrolysis electrode 33.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the first electrolysis electrode 32 is disposed above the second electrolysis electrode 33; the second electrolysis electrode 33 is arranged above the electrolysis driving module 36; the second electrolysis electrode 33 is provided with a first via hole 35 for the first conductive pillar 37 to pass through; the first conductive pillar 37 passes through the first via hole 35 and is electrically connected to the first electrolysis electrode 32.

Specifically, since the first electrolysis electrode 32 and the second electrolysis electrode 33 are stacked, the volume of the product can be reduced compared with other placement methods. By providing the first conductive pillar 37 and the second conductive pillar 38, compared with the conductive wire method, the power supply signal of the electrolysis driving module 36 installed in the accommodating chamber 1 can smoothly and reliably reach the first electrolysis electrode 32 and the second electrolysis electrode 33, and the first via hole 35 is provided to further reduce the volume of the product. It should be noted that the first via hole 35 and the first conductive pillar 37 are in an insulating state, that is, the second electrolysis electrode 33 and the first conductive pillar 37 are in an insulating state, which not only prevents a short circuit between the two electrolysis electrodes, but also reduces the volume of the product, and facilitates the miniaturization of the product without greatly improving the production process.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the turbine plate 19 is provided with a water-stirring rib 41; the number of the water stirring ribs 41 is two to eight; all the water stirring convex ribs 41 are arranged in a way of dispersing around the center of the circle of the turbine plate 19 as the axis.

Through setting up and stirring water bead 41, can effectively improve turbine plate 19's rotation effect, stir the effect of water better, it is more abundant to wash, and the cleaning speed is higher. As can be seen from the experiment, all the water-stirring ribs 41 have better stirring effect by taking the center of the circle of the turbine plate 19 as the axis and dispersing all around.

As shown in fig. 1 to 9, in the electrolysis turbine integrated cleaner of the present embodiment, the turbine driving module includes a turbine motor 42, a turbine rotating shaft 43 connected to an output end of the turbine motor 42, and a PCB 44 for driving the turbine motor 42 to operate; a rotating shaft through hole 45 for accommodating the turbine rotating shaft 43 is formed in the shell; the turbine plate 19 is arranged above the electrolysis cavity 31; one end of the turbine rotating shaft 43 passes through the electrolysis module 30 and then is connected with the turbine plate 19; the other end of the turbine rotating shaft 43 is connected with the turbine motor 42; the PCB 44 is electrically connected to the power supply device; the turbine rotating shaft 43 is sleeved with a rotating shaft waterproof sealing ring 46 for preventing water from entering the accommodating cavity 1.

Specifically, the rotation principle of the turbine plate 19 is: the PCB board 44 may be a conventional circuit for driving the operation of the turbine motor 42, and includes a rectifying unit for rectifying the electric power from the receiving module 7, a voltage dropping unit for transforming the current to a voltage required by the turbine motor 42, a constant voltage and current unit for stabilizing the operation of the turbine motor 42, and a control unit for controlling the operation state of the turbine motor 42. After the receiving module 7 provides the electric energy for the turbine module, the PCB 44 in the turbine driving module converts the electric energy provided by the receiving module 7 into a voltage adapted to the turbine motor 42, so that the output end of the turbine motor 42 can drive the turbine rotating shaft 43 to rotate clockwise or counterclockwise correspondingly, and thus the turbine plate 19 is driven to rotate clockwise or counterclockwise correspondingly, thereby stirring the water in the water tank 10. After the receiving module 7 provides the electric energy for the turbine module, the PCB 44 in the turbine driving module converts the electric energy provided by the receiving module 7 into a voltage adapted to the turbine motor 42, so that the output end of the turbine motor 42 can drive the turbine rotating shaft 43 to rotate clockwise or counterclockwise correspondingly, and thus the turbine plate 19 is driven to rotate clockwise or counterclockwise correspondingly, thereby stirring the water in the water tank 10.

The above is only a preferred embodiment of the present invention, so all the equivalent changes or modifications made by the structure, features and principles in accordance with the claims of the present invention are included in the protection scope of the present invention.

Claims (10)

1. An electrolysis turbine integral type cleaner which characterized in that: the device comprises an electrolytic turbine cleaning mechanism (1), a drainer (2) connected with an external water tank (10) and a power supply device for supplying power to the electrolytic turbine cleaning mechanism (1);

the electrolytic turbine cleaning mechanism (1) is arranged on the drainer (2);

the electrolytic turbine cleaning mechanism (1) comprises a shell, a turbine plate (19), an accommodating cavity (11), an electrolytic driving module (36), a turbine driving module, an electrolytic cavity (31) communicated with the water tank (10) and an electrolytic module (30) for electrolyzing water;

the turbine plate (19) is in rotational connection with the housing; the turbine drive module rotates the turbine plate (19);

the electrolysis cavity (31) is arranged on the shell; the electrolysis module (30) is arranged in the electrolysis cavity (31); the electrolysis driving module (36) is electrically connected with the electrolysis module (30);

the accommodating cavity (11) is arranged inside the shell; the electrolysis driving module (36) and the turbine driving module are arranged in the accommodating cavity (11); the electrolysis driving module (36) and the turbine driving module are electrically connected with the power supply device.

2. An electrolytic turbine integrated cleaner in accordance with claim 1, wherein: the power supply device comprises a wireless driving mechanism; the electrolysis turbine cleaning mechanism (1) is detachably connected with the water drainer (2); the wireless driving mechanism comprises a receiving module (7) arranged in the electrolytic turbine cleaning mechanism (1) and a transmitting module arranged in the drainer (2); the receiving module (7) is coupled with the transmitting module; the receiving module (7) is arranged in the accommodating cavity (11); the electrolysis driving module (36) and the turbine driving module are both electrically connected with the receiving module (7).

3. An electrolytic turbine integrated cleaner in accordance with claim 2, wherein: the drainer (2) comprises an inner shell (21) and an outer shell (22) which are connected with each other; the inner wall of the inner shell (21) forms a hollow drainage cavity (23) for draining water in the water tank (10); the transmitting module is arranged between the inner shell (21) and the outer shell (22); the receiving module (7) is arranged in the accommodating cavity (11).

4. An electrolytic turbine integrated cleaner in accordance with claim 3, wherein:

the receiving module (7) comprises a receiving framework (71), a receiving magnetic core (72) sleeved on the inner surface of the receiving framework (71) and a receiving coil (73) wound on the outer surface of the receiving framework (71); the receiving coil (73) is electrically connected with the electrolysis driving module (36) and the turbine driving module; the transmitting module comprises a transmitting framework (81), a transmitting coil (82) wound on the outer surface of the transmitting framework (81) and a transmitting magnetic core (83) sleeved on the outer surface of the transmitting framework (81);

the emission framework (81) is arranged between the inner shell (21) and the outer shell (22).

5. An electrolytic turbine integrated cleaner in accordance with claim 4, wherein:

the outer surface of the receiving framework (71) is provided with a first placing groove (74) for placing a receiving coil (73);

the outer surface of the transmitting framework (81) is provided with a second placing groove (84) for placing a transmitting coil (82).

6. An electrolytic turbine integrated cleaner in accordance with claim 1, wherein:

the shell is provided with a first through hole (15) and a second through hole (16) which are communicated with the electrolysis cavity (31); the first through hole (15) is used for water in the water supply tank (10) to flow into the electrolysis cavity (31); the first through hole (15) is arranged at the top of the electrolytic cavity (31); the second through hole (16) is used for supplying water flow to flow out of the electrolysis cavity (31) to the drainer (2); the second through hole (16) is arranged at the bottom of the electrolytic cavity (31);

the shell comprises a top shell (12), a waterproof shell (13) and a bottom shell (14); the top shell (12) is detachably connected with the waterproof shell (13); the top shell (12) and the water-resisting shell (13) form the electrolysis cavity (31); the waterproof shell (13) is detachably connected with the bottom shell (14); the accommodating cavity (11) is formed between the waterproof shell (13) and the bottom shell (14); a first waterproof sealing ring (17) is arranged between the waterproof shell (13) and the bottom shell (14).

7. An electrolytic turbine integrated cleaner in accordance with claim 1, wherein: the electrolysis module (30) comprises a first electrolysis electrode (32) and a second electrolysis electrode (33); the first electrolysis electrode (32) and the second electrolysis electrode (33) are arranged in the electrolysis cavity (31); an insulating spacer (34) is arranged between the first electrolysis electrode (32) and the second electrolysis electrode (33);

the electrolysis driving module (36) is provided with a first conductive column (37) and a second conductive column (38); the positive electrode output end of the electrolysis driving module (36) is electrically connected with the first electrolysis electrode (32) through a first conductive column (37); the negative electrode output end of the electrolysis driving module (36) is electrically connected with the second electrolysis electrode (33) through a second conductive column (38);

the first electrolysis electrode (32) is arranged above the second electrolysis electrode (33); the second electrolysis electrode (33) is arranged above the electrolysis driving module (36); a first through hole (35) for the first conductive column (37) to pass through is formed in the second electrolysis electrode (33); the first conductive pillar (37) passes through the first via hole (35) to be electrically connected with the first electrolysis electrode (32).

8. An electrolytic turbine integrated cleaner in accordance with claim 1, wherein: the turbine plate (19) is provided with a water stirring rib (41); the number of the water stirring ribs (41) is two to eight; all the water stirring convex ribs (41) are arranged in a way of dispersing around by taking the circle center of the turbine plate (19) as the axis.

9. An electrolytic turbine integrated cleaner in accordance with claim 1, wherein: the turbine driving module comprises a turbine motor (42), a turbine rotating shaft (43) connected with the output end of the turbine motor (42) and a PCB (44) for driving the turbine motor (42) to work; a rotating shaft through hole (45) for accommodating the turbine rotating shaft (43) is formed in the shell; the turbine plate (19) is arranged above the electrolysis cavity (31); one end of the turbine rotating shaft (43) penetrates through the electrolysis module (30) and then is connected with the turbine plate (19); the other end of the turbine rotating shaft (43) is connected with the turbine motor (42); the PCB (44) is electrically connected with the power supply device; the turbine rotating shaft (43) is sleeved with a rotating shaft waterproof sealing ring (46) used for preventing water from entering the accommodating cavity (11).

10. An electrolytic turbine integrated cleaner in accordance with claim 6, wherein: the turbine plate (19) is integrally provided with the top case (12).

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