• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A remote controllable intelligent cleaning device includes at least one of: a water tank, a spraying device, an ozone generating device, a heat generating device, ultraviolet and an ultrasound generating device. The spraying device and the ozone generating device are respectively in communication with the water tank, the ultraviolet device is turned inwardly of the water tank and the ultrasonic generating device is disposed on a wall outside of the water tank. The spraying device, the ozone generating device, the ultraviolet device and the ultrasonic generating device are each electrically connected to a microcontroller (MCU) and the MCU is also connected to a communication module. wireless. The MCU is connected to a remote control terminal via the wireless communication module. The invention realizes the integration of a plurality of independent functional purification devices, with the addition of an automatic control function and the realization of a remote control, so that the items to be cleaned can be completely purified at one time, without wasting time and at low cost, while avoiding the problems associated with manual operation.
    公开号:FR3047678A3
    申请号:FR1700155
    申请日:2017-02-10
    公开日:2017-08-18
    发明作者:Yiheng Zhong;Jinfu Zhong
    申请人:Shenzhen Yousun Tech Ind Co Ltd;
    IPC主号:
    专利说明:

    Intelligent and remotely controllable cleaning device
    TECHNICAL FIELD OF THE INVENTION The invention relates to the field of cleaning devices, and in particular a remotely controllable intelligent cleaning device having several cleaning functions.
    Prior art
    With the gradual improvement of the quality of life, various cleaning devices are starting to emerge on the market. However, conventional cleaning devices often have the defect of a single functionality and a low degree of automation. Because of their unique functionality, the items to be cleaned can not be cleaned and purified in many ways and in all directions, and their low degree of automation reduces their ergonomics and leads to a time permitting. In addition, the desirability and duration of each purification operation can not be manually controlled precisely, weakening the effectiveness of cleaning to some extent. Summary of the invention
    To meet the drawbacks of the prior art, the invention is intended to provide an intelligent cleaning device remotely controllable. A plurality of independent purification functional devices is integrated, with the addition of an automatic control functionality remote control is achieved so that the items to be cleaned can be completely purified at a time, thereby avoiding the problems of time loss and the high costs associated with a plurality of separate cleaning and purification devices. And we avoid the problems resulting from manual operation.
    To achieve this objective, the technical solutions recommended by the invention are the following:
    A remotely controllable intelligent cleaning device may include a water reservoir and may further include at least one of: a spraying device, an ozone generating device, an ultraviolet generating device, and a generator device; ultrasound. The spraying device and the ozone generating device can be respectively connected to the water tank, the ultraviolet generating device being able to face the inside of the water tank and the ultrasonic generating device being able to be arranged on a water tank. outer wall of the water tank. The spraying device, the ozone generating device, the ultraviolet generating device and the ultrasonic generating device can be electrically connected to a microcontroller (MCU) and the MCU can also be connected to a module. wireless communication. The MCU can be connected to a remote control terminal via the wireless communication module.
    It is important to note that one operating principle of the remotely controllable intelligent cleaning device relates to this: a plurality of groups of cleaning and purification modes are pre-set within the MCU and are stored beforehand, each group of cleaning and purification modes including opportunity and duration for each purification mode (spray, ozone, ultraviolet and ultrasound). A user transmits via the remote control terminal to the MCU a command instruction corresponding to the selected cleaning and purification mode and the MCU receives the command instruction via the wireless communication module and controls the spraying device, the generating device and the ozone, the ultraviolet generating device, the ultrasonic generating device and the like to be turned on and operated at a given time depending on the selected cleaning and purification mode.
    Preferably, a WIFI wireless module can be used as a wireless communication module.
    Preferably, the MCU may also be electrically connected to a control panel, and instruction input keys electrically connected to the MCU may be disposed on the control panel. One of the instruction input keys corresponding to the predefined cleaning and purification modes can be operated directly to select the corresponding cleaning and purification mode, thereby providing the user with a choice of several operating modes.
    Preferably, the spraying device may comprise a spray head and a water circulation component. The water circulation component may consist mainly of a four-way junction with four channels and a pressurizing water pump, the four-way junction being connectable via the four channels respectively to the input and output of the pressurized water pump, a water inlet valve and a drain valve, and the water inlet valve and the drain valve which can be communicated via an inlet pipe of water and a water drain pipe, respectively. The water circulation component may be disposed on an outer bottom of the water tank, and the spray head may be disposed on an interior bottom of the water tank. A plurality of water outlets may be formed in the middle of a surface of the spray head, a plurality of water spray holes may be formed in the periphery of each water outlet, and the outlets of water and the water spray ports that may be in communication with the four-way junction. The water spray holes may be inclined. The pressurized water pump, the water inlet valve and the drain valve can be electrically connected to the MCU.
    It is important to note that a vortex can be formed in the water tank by means of the designed spray apparatus, so that an article to be cleaned swirls within the water tank, with obtaining a better cleaning. According to a more specific operating principle, the MCU controls the opening of the water inlet valve to activate a water supply, the water passes sequentially through the water inlet pipe, the valve of water inlet and the four-way junction and flows into the water tank through the water outlets of the spray head, the drain valve is closed via the MCU, preventing the drain of the tank to water through the drain hose; and after filling the water tank, the pressurized water pump is started under the control of the MCU and pumps water from the water tank, the water being pressurized and then sprayed from the spray ports of the water tank. water from the spray head. Due to the inclination of the water spray holes, a water vortex may be formed by a number of water spray holes in the upper periphery of the spray head, allowing cleaning and swirling. with optimal cleaning efficiency.
    Preferably, the ozone generating device may comprise an ozone generator, an air pump and a high pressure generator, the ozone generator may be in communication with the air pump via a pipe of air, the high pressure generator can be electrically connected to the ozone generator, and the high pressure generator and the air pump can be connected to an alternating current supply of 220V; the ozone generator can be communicated to the water tank via a non-return valve; and the air pump, the high pressure generator and the ozone generator each electrically connectable to the MCU.
    It is important to note that in a process of oxygen generation by the ozone generating device and oxygen transport within the water tank, the MCU controls the air pump to pump air into the tank. the ozone generator, the high pressure generator and the start of the ozone generator. Under the action of the high pressure generator, the air of the ozone generator is ionized under high pressure to generate ozone, the generated ozone enters the water tank and dissolves in the water, thus allowing the decomposition of toxins and preservation of freshness.
    Preferably, a face cover may be deployed at an opening of the water tank, and the ultraviolet generating device may be disposed on a surface, facing the interior of the water tank, on the lid of the water tank. face.
    In addition, preferably, an ultraviolet lamp may be adopted as an ultraviolet device and may be electrically connected to the MCU. When ultraviolet irradiation is required, the MCU controls the illumination of the ultraviolet lamp.
    Preferably, the ultrasound generating device may comprise a relay, a control unit of an ultrasonic transducer and a plurality of ultrasonic transducers, and the relay and the ultrasonic transducers each being electrically connected to the control unit. ultrasonic transducer; the ultrasonic transducers can be arranged on the outer wall of the water tank, and one of the ultrasonic transducer can be electrically connected to the MCU.
    It is important to note that the MCU controls the start of the ultrasonic transducer drive unit, the relay providing power to the ultrasonic transducer drive unit, the ultrasonic transducer drive unit controlling the ultrasonic transducers to generate a longitudinal wave transmitted in water to exert an action of breaking bonds of water molecules. Ozone is convenient for being in complete contact with toxins, ensuring significant oxidative decomposition.
    Preferably, activated carbon may also be available. The invention has the following beneficial effects: The plurality of independent purification functional devices can be integrated, with the addition of an automatic control function and the realization of a remote control in such a way that one can realize at one time, cleaning and complete purification of items to be cleaned. The loss of time and the high costs resulting from separate cleaning and purification operations via a plurality of devices are avoided. Various problems related to manual operation are avoided.
    Description of figures
    Figure 1 is a composition diagram of the invention.
    Fig. 2 is an overall structure diagram of a spray apparatus of Fig. 1.
    FIG. 3 is a separation structure diagram of a four-way junction of a spray head of FIG.
    Figure 4 is a sectional diagram of a spray head of Figures 2 and 3.
    FIG. 5 is a connection diagram between a pressurizing water pump of a spraying device and an MCU of FIG. 1.
    FIG. 6 is a connection diagram between a water inlet valve of a spraying device and an MCU unit of FIG. 1.
    FIG. 7 is a connection diagram between a discharge valve of a spraying device and an MCU of FIG. 1.
    FIG. 8 is a connection diagram of an ozone generator device of FIG. 1.
    FIG. 9 is a connection diagram of an ozone generator and an MCU of FIG. 8.
    FIG. 10 is a circuit diagram of an ultraviolet lamp of FIG. 1.
    Fig. 11 is a circuit diagram of connection between an ultraviolet lamp and an MCU of Fig. 1 and Fig. 10.
    FIG. 12 is a connection diagram of an ultrasound generating device of FIG. 1; and
    Fig. 13 is a connection diagram between a driver unit of an ultrasonic transducer and an MCU unit of Fig. 13. 12.
    DETAILED DESCRIPTION OF THE EMBODIMENTS The invention is described in more detail below with reference to the drawings. It is important to note that in the discussion of the preferred technical solution a detailed description of the embodiments and procedures is presented, but that the scope of protection is not limited to these embodiments. .
    As shown in FIG. 1, a remotely controllable intelligent cleaning device comprises a water tank 1 and furthermore comprises at least two of the following elements: a spraying device 2, an ozone generating device 3, an ultraviolet generating device 4 and a device The spraying device 2 and the ozone generating device 3 are respectively in communication with the water tank 1, the ultraviolet generating device 4 being turned towards the inside of the water tank 1 and the ultrasonic generating device 5 being disposed on an outer wall of the water tank 1. The spraying device 2, the ozone generating device 3, the ultraviolet generating device 4 and the ultrasound generating device 5 are each electrically connected to an MCU 6 and the MCU 6 is also connected to a wireless communication module 7. The MCU 6 is connected e to a remote terminal 8 via the wireless communication module 7.
    It is important to note that a principle of operation of the remotely controllable intelligent cleaning device is as follows: a plurality of groups of cleaning and purification modes are pre-set within the MCU and are previously stored therein. Each group of cleaning and purification modes including the opportunity and the duration of operation for each mode of purification (spraying, ozone, ultraviolet and ultrasound). A user sends to the MCU via the remote control terminal a command instruction corresponding to the selected cleaning and purification mode and the MCU receives the command instruction via the wireless communication module and controls the spraying device, ozone generation, the ultraviolet device, the ultrasound generating device and the like to be turned on and operated at a specific time depending on the selected cleaning and purification mode.
    Preferably, a WIFI module is adopted as a wireless communication module 7.
    Preferably, the MCU 6 is also electrically connected to a control panel 9 and instruction input keys electrically connected to the MCU 6 are arranged on the control panel 9. One of the input keys instructions corresponding to the predefined cleaning and purification modes can be pressed directly to select the corresponding cleaning and purification mode, thus offering the user various choices and operating modes.
    Preferably, as shown in FIGS. 2 to 4, the spray device 2 comprises a spray head 21 and a water circulation component 22. The water circulation component 22 is composed mainly of a four-way junction lanes 221 with four channels, and a pressurized water pump 222. The four-way junction 221 communicates respectively via the four channels to the water inlet and outlet of the pressurizing water pump, to a water inlet valve 23 and to a drain valve 24. the water inlet 23 and the drain valve 24 are connected to a water inlet pipe and a drain pipe, respectively. The water circulating component 22 is disposed at an outer bottom of the water tank 1, and the spray head 21 is disposed at an inner bottom of the water tank 1. A plurality of outlets of water 211 are disposed in the middle of a surface of the spray head 21, a plurality of water spray holes 212 being formed in the periphery of each water outlet 211, and the water outlets 211 and Water spray ports communicate with the four-way junction. As shown in FIG. 4, the water spray holes are inclined at an inclination angle of 30 to 45 degrees. The pressurizing water pump, the water inlet valve and the water drain valve are each electrically connected to the MCU, and the circuit structures are shown in Figures 5 to 7, respectively.
    It is important to note that a vortex can be formed in the water tank by means of the designed spray device, so that an article to be cleaned swirls within the water tank, with obtaining a reinforced cleaning . According to a specific operating principle, the MCU controls the opening of the water inlet valve for the water supply. The water flows sequentially through the intake pipe, water inlet valve and four-way junction, and flows into the water tank from the water outlets of the water head. spray. The drain valve is closed via the MCU, which prevents draining of the water tank. When the water tank is full, the pressurized water pump is started under the control of the MCU and pumps the water from the water tank. The water is pressurized and then sprayed through the water spray holes of the spray head. Due to the inclination of the spray ports, a swirling water flow may be formed by a number of water spray holes disposed in the upper periphery of the spray head, providing cleaning and vortex, and an optimal cleaning effect.
    Preferably, as shown in FIG. 8, the ozone generating device 3 comprises an ozone generator 31, an air pump 32 and a high pressure generator 33. The ozone generator 31 communicates with the air pump 32 via an air pipe 34 The high pressure generator 33 is electrically connected to the ozone generator 31 via a high pressure link 36, and the high pressure generator 33 and the air pump 32 are connected to an AC supply of 220V respectively. The ozone generator 31 communicates with the water tank via a check valve 35, and the ozone generator, the air pump and the high pressure generator are each electrically connected to the MCU. A connection circuit structure between the ozone generator and the MCU is shown in FIG. 9.
    It is important to note that in a process of oxygen generation by the ozone generator and transporting oxygen into the water container, the MCU controls the air pump to pump air in the ozone generator and controls the high pressure generator and the start of the ozone generator. Under the action of the high pressure generator, the air of the ozone generator is ionized under high pressure to generate ozone, the generated ozone enters the water tank and dissolves in water. The result is a decomposition of toxins and the preservation of freshness.
    Preferably, a front cover is deployed at an opening of the water tank, and the ultraviolet generating apparatus is disposed on a surface, facing the interior of the water tank, on the front cover. . When ultraviolet sterilization is required, the face cover is closed, the ultraviolet generating device is started and ultraviolet light can be emitted into the water tank. A circuit structure of an ultraviolet lamp is shown in FIG. 10.
    Further, preferably, the ultraviolet lamp is used for the ultraviolet generating device 4 and is electrically connected to the MCU. A circuit structure is shown in FIG. 11.
    Preferably, as shown in FIG. 12, the ultrasound generating device 5 comprises a relay 51, a control unit of an ultrasonic transducer 52 and a plurality of ultrasonic transducers 53, and the relay 51 and the ultrasonic transducers 53 are each electrically connected to the drive unit of the ultrasonic transducer 52. And the ultrasonic transducers 53 are arranged on the outer wall of the water tank 1. The ultrasonic transducer control unit 52 mainly comprises a power amplification unit. 521, a filter unit 522, an adaptation unit 523 and a sampling unit 524 and a control signal is generated in sequence by power amplification, filtering, matching and sampling. A connection circuit of the ultrasonic transducer control unit 52 and the MCU is shown in FIG. 13.
    It is important to note that the MCU controls the start of the ultrasonic transducer driver unit, the relay supplying power to the ultrasonic transducer driver unit. The ultrasonic transducer drive unit controls the ultrasonic transducers to generate a longitudinal wave transmitted in water to exert an action of breaking bonds of the water molecules. Ozone is convenient for contact with toxins, allowing strong oxidative decomposition.
    Preferably, activated carbon is also available. Those skilled in the art can make various variations and modifications corresponding to the solutions and technical concepts above, and all these variations and modifications fall within the scope of protection of the invention.
    Specific description of Figures 5-7 and 9-11:
    Figure 5:
    FIG. 5 shows a transistor Q5 - for example of type 8550 - having a base connected to the MCU via a resistor R5 of value equal to 2Kohms. The collector of transistor Q5 is connected to ground. The emitter of the transistor Q5 is connected to a first terminal 5 of a control solenoid of the relay J5, whose second terminal 4 is connected to a power supply 5V. The pump 222 comprises a first electrode connected to the ground and a second electrode connected to a third terminal 3 of the relay J5, a fourth terminal 2 of this relay being connected to a voltage 24V.
    Figure 6:
    FIG. 6 shows a transistor Q1 - for example of type 8550 - having a base connected to the MCU via a resistor R1 of value equal to 2Kohms. The collector of transistor Q1 is connected to ground. The emitter of the transistor Q1 is connected to a first terminal 5 of a control solenoid of the relay J1, a second terminal 4 of which is connected to a power supply 5V. The solenoid valve 223 comprises a first electrode connected to a phase of the 220V supply, while gu a second electrode of the valve 223 is connected to a third terminal 3 of the relay J1, a fourth terminal 2 of this relay being connected to a second 220V power phase.
    Figure 7:
    FIG. 7 shows a transistor Q3 - for example of type 8550 - having a base connected to the MCU via a resistor R3 of value equal to 2Kohms. The collector of transistor Q3 is connected to ground. The emitter of the transistor Q3 is connected to a first terminal 5 of a control solenoid of the relay J3, whose second terminal 4 is connected to a power supply 5V. The drain solenoid valve 24 comprises a first electrode connected to ground and a second electrode connected to a third terminal 3 of the relay J3, a fourth terminal 2 of this relay being connected to a voltage 24V.
    Figure 9:
    FIG. 9 shows a transistor Q2 - for example of type 8550 - having a base connected to the MCU via a resistor R2 of value equal to 2Kohms. The collector of transistor Q2 is connected to ground. The emitter of the transistor Q2 is connected to a first terminal 5 of a control solenoid of the relay J2, a second terminal 4 of which is connected to a power supply 5V. The ozone generator 31 comprises a first electrode connected to a phase of the 220V supply, while a second electrode of the ozone generator is connected to a third terminal 3 of the relay J2, a fourth terminal 2 of this relay being connected to a second phase of the 220V power supply.
    Figure 11.
    FIG. 11 shows a transistor Q4 - for example of type 8550 - having a base connected to the MCU via a resistor R4 of value equal to 2Kohms. The collector of transistor Q4 is connected to ground. The emitter of the transistor Q4 is connected to a first terminal 5 of a control solenoid of the relay J4, whose second terminal 4 is connected to a power supply 5V. The ultraviolet lamp 31 comprises a first electrode connected to ground and a second electrode connected to a third terminal 3 of the relay J4, a fourth terminal 2 of this relay being connected to a voltage 24V.
    权利要求:
    Claims (9)
    [1" id="c-fr-0001]
    claims
    A remotely controllable intelligent cleaning device, comprising a water tank, and further comprising at least one of: a spraying device, an ozone generating device, an ultraviolet generating device and a ultrasonic generating device, wherein the spraying device and the ozone generating device are in communication with the water tank, respectively, the ultraviolet generating device facing the interior of the water tank and the ultrasonic generating device being disposed on an outer wall of the water tank; wherein the spraying device, the ozone generating device, the ultraviolet generating device and the ultrasonic generating device are each electrically connected to a microcontroller (MCU) and the MCU is also connected a wireless communication module; wherein the MCU is connected to a remote control terminal via the wireless communication module.
    [2" id="c-fr-0002]
    The remotely controllable intelligent cleaning device according to claim 1, wherein a wireless WIFI module is adopted as a wireless communication module.
    [3" id="c-fr-0003]
    The remotely controllable intelligent cleaning device according to claim 1, wherein the MCU is also electrically connected to a control panel, and instruction input keys electrically connected to the MCU are disposed on the control panel. .
    [4" id="c-fr-0004]
    The remotely controllable intelligent cleaning device according to claim 1, wherein the spraying device comprises a spray head and a water circulation component; wherein the water circulation component is composed mainly of a four-way four-channel junction and a pressurizing water pump, in which the four-way junction communicates via the four channels with the ends of the four-way junction. inlet and outlet of the pressurizing water pump, a water inlet valve and a water drain valve; wherein the water inlet valve and the water drain valve are respectively connected to a water inlet pipe and a water drain pipe; wherein the water circulation component is disposed at an outer bottom of the water tank and the spray head is disposed at an interior bottom of the water tank; wherein a plurality of water outlets are formed in the middle of a surface of the spray head, a plurality of water spray holes are formed in the periphery of each water outlet, and the outlets of water and the water spray ports are in communication with the four-way junction; wherein the water spray ports are inclined and the pressurizing water pump, the water inlet valve and the water drain valve are each electrically connected to the MCU.
    [5" id="c-fr-0005]
    5. The remotely controllable intelligent cleaning device according to claim 1, characterized in that the ozone generating apparatus comprises an ozone generator, an air pump and a high pressure generator, the ozone generator communicating with the air pump via an air hose Is electrically connected to the ozone generator and the high pressure generator and the air pump are connected to a 220V ac supply; The ozone generator is communicated to the water tank via a check valve; And the air pump, the high pressure generator and the ozone generator are each electrically connected to the MCU.
    [6" id="c-fr-0006]
    The remotely controllable intelligent cleaning device according to claim 1, characterized in that the face cover is deployed at an opening of the water tank and the ultraviolet generating apparatus is arranged on a surface facing inside the water tank, on the front cover.
    [7" id="c-fr-0007]
    The remotely controllable intelligent cleaning device according to claim 1 or 6, wherein an ultraviolet lamp is adopted as an ultraviolet device and is electrically connected to the MCU.
    [8" id="c-fr-0008]
    The remotely controllable intelligent cleaning device according to claim 1, characterized in that the ultrasound generating device comprises a relay, an ultrasonic transducer driving unit and a plurality of ultrasonic transducers, and the relay and the transducers. ultrasound are each electrically connected to the ultrasonic transducer driver unit; wherein the ultrasonic transducers are arranged on the outer wall of the water tank and the ultrasonic transducer drive unit is electrically connected to the MCU.
    [9" id="c-fr-0009]
    9. remotely controllable intelligent cleaning device according to claim 1, characterized in that it also has activated carbon.
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    引用文献:
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    法律状态:
    优先权:
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