CN212153614U - Intelligent closestool with drying function on flushing part - Google Patents

Abstract

The utility model provides an intelligent closestool who has stoving effect to washing part installs the washing part on the closestool body, the washing part is connected with water container through washing pipeline and hot water heating part, still integrated the installing has the wind regime part that plays stoving effect on the closestool body, a stoving pipeline has between wind regime part and the washing part, and this stoving pipeline is used for accomplishing the inside stoving to washing part whole pipeline after finishing washing work, and this stoving pipeline specifically does, and wind regime part is through two and way water container, hot water heating part and washing pipeline of stoving pipeline, finally is connected with the washing part. The utility model discloses can thoroughly wash and dry the inside and outside of washing partial whole pipeline, stop bacterial growing.

Description

Intelligent closestool with drying function on flushing part

Technical Field

The utility model relates to an intelligent closestool that has stoving effect to washing part belongs to health and cleaners and polishes technical field.

Background

In some family toilets, some common toilets which are common to people are replaced by intelligent toilets, and the intelligent toilets bring people not only convenience in use but also a health idea.

People enjoy the intelligent closestool, and meanwhile, some hidden dangers brought by the intelligent closestool are accompanied by people all the time.

The flushing function is one of essential basic functions of the intelligent closestool, the inside of a flushing pipeline for conveying flushing water is soaked in water for a long time, various bacteria are easily generated inside the pipeline, and particularly under the condition of low use frequency.

The producer of intelligent closestool relatively pays attention to the dry and sterilization condition that expose at the external surface, eyes can see the part, but neglected inside the washing pipeline that can not see, and the inside breed bacterium of washing pipeline brings the potential safety hazard for people more easily.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides an intelligent closestool who has stoving effect to the flush part, the purpose thoroughly washes and dries the inside and outside of the whole pipeline of flush part, stops bacterial growing.

In order to realize the technical purpose, the utility model adopts the following technical scheme: an intelligent closestool with a drying function on a flushing part is characterized in that the flushing part is arranged on a closestool body and is connected with a water storage container through a flushing pipeline and a water heating part, an air source part with the drying function is further integrally arranged on the closestool body, a drying pipeline is arranged between the air source part and the flushing part and is used for drying the inside of the whole pipeline of the flushing part after the flushing work is finished, and the drying pipeline is specifically characterized in that the air source part is connected with the flushing part through a drying pipeline II and passes through the water storage container, the water heating part and the flushing pipeline; and electronic components adopted by the air source part, the water heating part, the washing part and the water storage container and electromagnetic valves arranged on pipelines are all connected with the single chip microcomputer.

Preferably, another drying pipeline is further arranged between the air source part and the washing part and used for drying the human body part, and the drying pipeline is specifically characterized in that the air source part is directly connected with the washing part through the first drying pipeline.

Preferably, the wind regime part is still connected with the seat circle heating part through the coupling hose that admits air, is provided with seat circle heating solenoid valve on the admission line, seat circle heating part and seat circle heating solenoid valve all are connected with the singlechip.

Preferably, the flushing part comprises a supporting pipe fixed on the toilet body, a movable pipe is connected in the supporting pipe in an axial sliding manner, the movable pipe is connected with a driving motor so as to realize axial movement of the movable pipe relative to the supporting pipe, an air outlet and a water outlet are arranged at the front end of the movable pipe, and the air outlet is connected with the air source part through a drying connecting hose and a drying pipeline I so as to finish drying of a human body part and the drying pipeline; the water outlet is connected with a water storage container through a water outlet connecting hose and a flushing electromagnetic valve and a water heating part, and the water storage container is connected with an air source part through an air inlet connecting pipe and a drying pipeline II so as to complete flushing and drying of the inside and the outside of the whole pipeline of the flushing part.

Preferably, the tail end of the supporting tube is provided with an external interface, and the external interface is connected with the water storage container through an external connecting hose and an external electromagnetic valve and a water heating part so as to finish washing or drying the outside of the movable tube of the washing part.

Preferably, a human body drying electromagnetic valve is arranged on the drying pipeline I, and a waterway drying electromagnetic valve is arranged on the drying pipeline II.

Preferably, the water heating part comprises a flow meter, a water pump, a heater, and a water inlet temperature sensor and a water outlet temperature sensor which are integrated on the conveying pipeline and are arranged at two ends of the heater.

Preferably, the top of the water storage container is provided with an air inlet which is connected with an air inlet connecting pipe; the water storage container is connected with an external water source through a water inlet pipe, and a water inlet electromagnetic valve is arranged on the water inlet pipe; a water level sensor is also arranged in the water storage container.

Preferably, the seat ring heating part is provided with an air outlet and a human body detection sensor on the seat ring, and an air temperature sensor is arranged at the air inlet of the seat ring.

The technical effects of the utility model: in the working process of the existing intelligent closestool, water in a pipeline is replenished at any time when being used at any time, always automatically filled and kept until the next time of use; the intelligent closestool of the utility model can automatically cut off the water source after one-time use, then drain the water in the pipeline, simultaneously connect the air source for drying and dry the whole interior of the flushing pipeline; the water source is not connected until the next use, so that the internal and external environments of the flushing pipeline are kept consistent, and no condition is created for bacterial breeding; the utility model discloses collect and wash, dry and seat circle heating function in an organic whole, provide the most comfortable, sanitary condition for people like the lavatory.

Drawings

Fig. 1 is a block diagram of the present invention.

Fig. 2 is a schematic view of the connection relationship between the components in the present invention.

Fig. 3 is a circuit control block diagram of the present invention.

Fig. 4 is a schematic diagram of the seat ring temperature measuring circuit of the present invention.

Fig. 5 is a block diagram of the water level detecting circuit of the present invention.

Fig. 6 is a schematic diagram of the temperature measuring circuit in the water heating part of the present invention.

Fig. 7 is a schematic view of the structure principle of the flow sensor of the present invention.

Fig. 8 is a schematic view of the flow measurement of the present invention.

Fig. 9 is a circuit control block diagram of the electromagnetic valve of the present invention.

Fig. 10 is a circuit control block diagram of the water heater of the present invention.

Fig. 11 is a block diagram of a plurality of low-power ceramic heaters and corresponding control circuits after the decomposition of the present invention.

Fig. 12 is a schematic view of the gas heating apparatus of the present invention.

Fig. 13 is a circuit control block diagram of the driving motor of the present invention.

Fig. 14 is a circuit control block diagram of the keyboard and display of the present invention.

Fig. 15 is a functional block diagram of the remote controller of the present invention.

Fig. 16 is a circuit control block diagram of the water pump or the fan of the present invention.

In the figure:

1. movable tube 22, human body drying electromagnetic valve

2. Temperature sensor for air outlet 23 and water inlet

3. Water outlet 24 and water outlet temperature sensor

4. External interface 25, flushing solenoid valve

5. External connecting hose 26 and water outlet connecting hose

6. External electromagnetic valve 27 and drying connecting hose

7. Flowmeter 28 and drive motor

8. Water pump 29, support pipe

9. Conveying pipeline 30, seat ring

10. Heater 31, air outlet

11. Water storage container 32, air inlet

12. Water 33, air intake connecting hose

13. Water inlet solenoid valve 34, human body detection sensor

14. Water inlet pipe 35, gas temperature sensor

15. Water level sensor 36 and magnet

16. Air inlet 37 and rotor assembly

17. Air inlet connecting pipe 38 and Hall element

18. Waterway drying electromagnetic valve

19. Fan with cooling device

20. Gas heating device

21. Seat ring heating electromagnetic valve

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

As shown in fig. 1, two drying pipelines are formed between the air source part and the washing part, one of which is that the air source part is directly connected with the washing part through a first drying pipeline to complete the drying of the human body part; the wind source part passes through the water storage container, the water heating part and the flushing pipeline through the drying pipeline II and is finally connected with the flushing part so as to finish drying the inside of the whole pipeline of the flushing part after the flushing work is finished; and electronic components adopted by the air source part, the water heating part, the washing part and the water storage container and electromagnetic valves arranged on pipelines are all connected with the single chip microcomputer.

The wind source part is composed of a fan 19, a gas heater device, a gas temperature sensor and the like.

Additionally, in fig. 1, the utility model discloses utilize the hot-blast of stoving, except accomplishing the utility model discloses an inside stoving of flushing line and human body need position two functions of drying, still control its pipeline that flows through the seat circle inside, heat for the seat circle.

As shown in FIG. 2, the working process of the intelligent toilet is divided into the following stages: firstly, heating a seat ring; secondly, preparing water for washing; thirdly, flushing an external pipeline of the movable pipe before use; fourthly, discharging cold water at the front end inside the flushing pipeline; fifthly, washing the body part with hot water; sixthly, drying the body part by hot air; seventhly, flushing the pipeline outside the movable pipe after use; eighthly, drying the inside of the washing pipeline, and drying the inside of the drying pipeline; and tenthly, drying the pipeline outside the movable pipe.

Firstly, heating a seat ring: in fig. 2, a human body detecting sensor 34, i.e., a seat detecting sensor, is provided on the seat 30 for detecting whether a user is seated on the seat 30; when the user is judged to be seated on the seat ring 30, the utility model starts to heat the seat ring.

In addition, also can be on the utility model discloses install independent human response or measuring device additional, confirm whether someone will use this equipment.

In order to increase comfort and preferably in the neutral state, the seat ring is in contact with the skin of the person, with an absolute sense of safety. The utility model adopts hot air as heat source, which flows through the pipeline designed inside the seat ring to heat the seat ring.

In fig. 2, the seat ring heating electromagnetic valve 21 is opened, the other electromagnetic valves are closed, the fan 19 is powered on, the motor rotates to generate a wind source, and the gas heating device 20 is powered on to generate a heat source; the wind source drives heat from the heat source along the air inlet connection hose 33, at the air inlet 32, into the pipe inside the seat 30, and finally out of the air outlet 31. The hot gas transfers heat to the seat ring 30 as it flows through the internal duct of the seat ring 30. The air inlet 32 is provided with an air temperature sensor 35 for detecting the air temperature at the air inlet, and the singlechip memory appropriately adjusts the rotating speed of the fan 19 or the input power of the air heating device 20 according to the temperature value, so that the seat ring temperature preset by a user becomes the actual temperature for heating the rear seat ring.

Secondly, preparing water for washing: because the utility model discloses an intelligent closestool uses the completion back last time, and the inside of washing the pipeline both is in vacant state, consequently, before this use, wash the pipeline inside and rather than the container of connecting, need pour into the water of capacity into to satisfy this whole use.

In fig. 2, at the water inlet of the inlet pipe 14, in one case the port itself is connected to the external inlet pipe; another situation is where the port is open, no plumbing is required, and the port is manually filled with flush water.

When water is injected under any one of the conditions, the water inlet electromagnetic valve 13 is required to be opened, the external electromagnetic valve 6 and the flushing electromagnetic valve 25 are closed, injected water flows downstream and is filled in a pipeline below the water inlet electromagnetic valve, the water level gradually moves upwards, the water level sensor 15 measures the water level height in the container 11 constantly, prompt is made at any time, and after the water level reaches the specified height, the water inlet electromagnetic valve 13 is closed, water supply is stopped, and a water storage task is completed.

Thirdly, flushing an external pipeline of the movable pipe before use: before each use, all wash the outer pipeline of activity pipe, ensure user's safety in utilization.

Before use, the movable pipe 1 is nested in the supporting pipe 29, an external interface 4 is fixed on the supporting pipe 29, one end of the external interface 4 is in an opening shape and is inwards opposite to the outer surface of the movable pipe 1 in the supporting pipe 29, the other end of the external interface 4 is connected with an interface at the front end of the conveying pipeline 9 through an external connecting hose 5, and an external electromagnetic valve 6 is arranged in the interface.

The external electromagnetic valve 6, the water inlet electromagnetic valve 13 and the water pump 8 are respectively powered, the external electromagnetic valve 6 and the water inlet electromagnetic valve 13 are opened, the water pump 8 rotates to drive water to flow to the external interface 4 along the pipeline, and the outer surface of the movable pipe 1 in the supporting pipe 29 is washed at the external interface 4.

Fourthly, discharging the cold water at the front end inside the flushing pipeline: in the initial stage of each time of starting the washing, a small section of water which can not be heated exists in the pipeline at the front end of the heater, and the water is discharged before use, otherwise, the washing effect is influenced.

The flushing electromagnetic valve 25 is powered on, the water inlet electromagnetic valve 13 is powered on, the heater 10 is powered on, other electromagnetic valves are closed, the water pump 8 is controlled to rotate at a low speed, cold water in the conveying pipeline 9 and the water outlet connecting hose 26 flows out of the water outlet 3, flowing water can drive the flowmeter 7 to rotate, and whether the cold water flows out completely or not can be judged according to the numerical value output by the flowmeter 7.

Fifthly, hot water flushing of body parts: after the cold water at the front end is discharged, the movable pipe 1 extends out of the supporting pipe 29 under the action of the driving motor 28 and a matching mechanism, and the preparation work before the hot water is discharged is completed.

The water pump 8 rotates in an accelerated way, the flow meter 7 continuously measures the amount of hot water flowing through, and the water inlet temperature sensor 23 and the water outlet temperature sensor 24 respectively measure the temperature of water before and after entering the heater 10; according to the water outlet temperature value and the flow value of the water outlet set by a user, the singlechip memory respectively controls the input power of the heater 10 and the rotating speed of the water pump 8, so that the temperature and the flow of the flushing water sprayed from the water outlet 3 meet the requirements of the user.

In the washing process, under the action of the driving motor 28 and the matching mechanism, a part of the movable tube 1 reciprocates in the supporting tube 29, so as to drive the water outlet 3 on the movable tube 1 outside the supporting tube 29 to move synchronously, realize the hot water sprayed from the water outlet 3, and dynamically wash a certain part of the body.

Sixthly, drying the body part by hot air: after the body part is rinsed with hot water, the part then needs to be dried with hot air.

After the flushing electromagnetic valve 25, the heater 10 and the water pump 8 of the water path are closed, the human body drying electromagnetic valve 22 of the air path is opened, the fan 19 and the air heating device 20 work simultaneously, and the generated hot air is sprayed out from the air outlet 2 through the drying connecting hose 27.

In the drying process, under the action of the driving motor 28 and the matching mechanism, a part of the movable tube 1 reciprocates in the supporting tube 29, so as to drive the air outlet 2 on the movable tube 1 outside the supporting tube 29 to move synchronously, realize the hot air sprayed out of the air outlet 2, and dynamically dry a certain part of a body.

The air output and the air temperature at the air outlet 2 can be controlled by adjusting the rotation speed of the fan 19 or the input power of the air heating device 20.

Seventhly, flushing the movable pipeline outside the pipeline after use: after the washing and drying tasks are completed, the movable tube 1 retracts into the supporting tube 29, and further cleaning work is carried out after the use is completed.

The external electromagnetic valve 6, the water inlet electromagnetic valve 13 and the water pump 8 are respectively powered, the electromagnetic valve 6 and the water inlet electromagnetic valve 13 are opened, the water pump 8 rotates to drive water to flow to the external interface 4 along the pipeline, the external interface 4 is flushed with the outer surface of the movable pipe 1 in the supporting pipe 29, and the work is finished after a period of time.

Eighthly, washing the inside of the pipeline for drying: the interior of the flushing pipeline must be kept in a dry state from the end of one use to the beginning of the next use, and no conditions for the propagation of bacteria are created.

The flushing electromagnetic valve 25 and the waterway drying electromagnetic valve 18 are opened, the other electromagnetic valves are closed, the fan 19 and the gas heating device 20 are sequentially powered on, hot air enters the container 11 at the air inlet 16 along the air inlet connecting pipe 17 to press the residual water 12 inside, the hot air flows out at the water outlet 3 along the conveying pipeline 9, the incoming hot air is sprayed out from the water outlet 3 after the water 12 is exhausted, and after a period of time, the container 11 and the humidity inside the pipeline along the pipeline are all dried.

Ninthly, drying the inside of the drying pipeline: in order to prevent water from flowing into the drying pipeline along the air outlet 2 in the process of using water, water in the drying pipeline is remained, and at the moment, the inside of the drying pipeline needs to be dried.

The human body drying electromagnetic valve 22 is opened, the other electromagnetic valves are closed, the fan 19 and the gas heating device 20 are sequentially electrified, hot air is blown out from the air outlet 2 along the drying connecting hose 27, and if water exists in the hot air, the hot air is taken out.

Tenthly, drying the pipeline outside the movable pipe: external solenoid valve 6 and water route stoving solenoid valve 18 get the electricity and open, and all the other solenoid valves are all closed, and fan 19 and gas heating device 20 get the electricity in proper order, and hot-blast following conveying pipeline 9 and external coupling hose 5 spout from external interface 4, weather the moisture on the movable tube 1 surface.

After the outer surface of the movable tube 1 is dried, the whole working process is finished.

If the inlet pipe 14 is connected to an external inlet pipe and the water pressure in the inlet pipe is sufficient, this can also be done by using the external water pressure instead of the water pump.

The utility model provides an intelligent closestool, its circuit control block diagram is shown in figure 3. The circuit control part mainly comprises the following parts.

1. A singlechip memory; 2. detecting a seat; 3. measuring the water level; 4. measuring the temperature of water; 5. measuring the gas temperature; 6. Measuring water flow; 7. a fan; 8. an electromagnetic valve; 9. a water heater; 10. a gas heating device; 11. a drive motor; 12. A water pump; 13. a keyboard and a display; 14. a remote control, etc.

1. A singlechip memory: the single chip microcomputer memory is the utility model discloses a control center, the utility model discloses the instruction source of all actions is accomplished by single chip microcomputer memory.

2. Seat detection: the seat detection part on the seat ring is used for determining whether a user is on the seat ring or not, and the seat detection part is used for checking by adopting a temperature sensor temperature measurement principle. When no one sits on the seat ring, the temperature measuring point measures the air temperature, and when one sits on the seat ring, the temperature measuring point measures the skin temperature of the user.

The temperature measuring part adopts DS18B20 as a temperature measuring element, and a specific temperature measuring circuit is shown in figure 4.

When a certain part of the skin of the user is contacted with the temperature measuring element at the temperature measuring point on the seat ring, the temperature measuring element DS18B20 starts to measure the skin temperature. After the measurement is finished, the measured temperature value is transmitted to the singlechip memory. The singlechip memory can judge whether a user sits on the seat or not according to the obtained numerical value.

The seat detection can also adopt the principles of travel switches, light-emitting diodes, infrared rays, electrodes and the like to carry out detection judgment.

3. Water level measurement: the water level in the container 11, i.e. the water level measuring part, is determined by ultrasonic distance measurement, and the block diagram is shown in fig. 5.

The singlechip memory controls the ultrasonic transmitter to transmit ultrasonic waves to the water surface direction; and when the ultrasonic waves are transmitted, the singlechip memory starts to time. In the process of transmission, if the ultrasonic waves touch the water surface, the ultrasonic waves return; after the ultrasonic receiver receives the reflected wave, the singlechip memory stops timing immediately. The real height of the water surface can be calculated by the singlechip memory according to the time difference between the two and the wave propagation speed.

The distance measurement can also be done in an infrared mode or a radar ranging mode.

4. Measurement of water temperature: the temperature measurement of water is become by water inlet temperature measurement and delivery port temperature measurement, the utility model provides a water inlet temperature sensor and delivery port temperature sensor all adopt DS18B20 as temperature measuring element, the circuit schematic, as shown in FIG. 6.

According to the requirement, the single chip microcomputer memory can respectively obtain the temperature value from any one of the sensors at any time, and then corresponding processing is carried out.

The water temperature sensor can also adopt temperature measurement components of other principles or modes.

5. And (3) measuring the gas temperature: the gas temperature sensor and the measurement principle used in the gas temperature measurement are the same as the water temperature measurement circuit, as shown in fig. 6, and will not be described again.

The gas temperature sensor can be implemented by temperature measurement components of other principles or modes.

6. Measuring water flow: the water flow measurement mainly comprises a flow sensor and a corresponding measurement circuit.

The flow sensor is schematically shown in fig. 7.

The flow sensor mainly comprises a rotor assembly 37, a magnet 36 and a hall element 38 adjacent to the rotor assembly, when water flows through the rotor assembly, the rotor rotates and drives the magnet on the rotor to rotate together, the rotating speed changes along with the change of the flow, and the hall sensor outputs corresponding pulses.

In fig. 8, the pulse output from the hall element is shaped and amplified by the pulse shaping and amplifying circuit, and then sent to the memory of the single chip for flow calculation.

7. A fan: the working principle is shown in a block diagram in fig. 16. The single chip microcomputer memory adjusts the rotating speed of the motor by controlling the motor part in the fan, and the change of the output air quantity of the fan is realized.

The single chip microcomputer memory generates PWM pulses, the PWM pulses are sent to the motor driving circuit, the rotation speed of the direct current motor is controlled after the PWM pulses are amplified, meanwhile, the current rotation speed of the motor is fed back to the single chip microcomputer memory through the rotation speed detection circuit, and the single chip microcomputer memory realizes the control of the rotation speed of the motor, namely the air volume, by changing the duty ratio of the output PWM pulses.

In practical application, an alternating current motor or a direct current motor can be used as a power source of the fan. The wind source can also be a fan, an air pump, an air source box or the combination of the above modes.

8. Electromagnetic valve: the utility model discloses total 6 solenoid valves that play different effects respectively carry out work. A path will now be described as an example. And a circuit control block diagram is shown in fig. 9.

The output port of the singlechip memory outputs a trigger signal, the triode amplifies the trigger signal, the singlechip memory controls the on-off of the optocoupler controlled silicon K1 through the triode, further controls the controlled silicon K2, indirectly controls the electrifying state of the electromagnetic valve RL, and controls the on-off of a pipeline through the electromagnetic valve.

The electromagnetic valve can be a direct current electromagnetic valve or an alternating current electromagnetic valve.

9. A water heater: the MCH ceramic heating element is used as the heating source for generating hot water, and the block diagram is shown in figure 10.

The utility model discloses a singlechip memory passes through drive circuit, removes the trigger end of control silicon controlled rectifier, through changing two utmost points of silicon controlled rectifier switch on and the mode that ends, removes the power supply situation of control ceramic heat-generating body to the realization produces thermal control to the ceramic heat-generating body.

In order to more exquisite and accurate control the utility model discloses a go out the water temperature, the utility model discloses with original output's ceramic heat-generating body, decomposed into the ceramic heat-generating body of a plurality of miniwatt and its corresponding control circuit, the block diagram is shown as figure 11.

The singlechip memory controls each small-power ceramic heating element respectively and combines the output power of different small-power ceramic heating elements, thereby realizing accurate outlet water temperature control.

The heating element of the heat-generating body may also include: MCH ceramic heating element, PTC ceramic heating element, silicon nitride ceramic heating element, nano ceramic heating element, heating film element, coating element, heating pipe and the like.

10. A gas heating device: the utility model discloses can adopt a gas heating element, also can adopt a plurality of gas heating element's combination, realize the effective control of gas heating, gas heating device schematic diagram, as shown in fig. 12.

The singlechip memory controls the trigger end of the controllable silicon through the drive circuit, and controls the power supply condition of the gas heating element by changing the conduction and cut-off modes of two poles of the controllable silicon, thereby realizing the control of generating heat of the gas heating element.

The single-chip microcomputer memory is used for controlling each gas heating element respectively and realizing accurate gas temperature control through output power combination among different gas heating elements.

The gas heating element may also include: MCH ceramic heating element, PTC ceramic heating element, silicon nitride ceramic heating element, nano ceramic heating element, heating film element, coating element, heating pipe, heating wire, heating rod, etc.

11. Driving a motor: in fig. 13, the memory of the single chip outputs PWM pulses, which are amplified by the driving circuit to control the driving motor, so as to provide power for the movable tube 1 to move back and forth in the supporting tube 29.

The driving motor can adopt a direct current motor, an alternating current motor or a gas driving mode.

12. A water pump: the control of the motor in the water pump, and the description of the contents, are the same as those of the motor part in the fan, as shown in fig. 16, and will not be described.

13. Keyboard and display: in order to better communicate with the device of the present invention, the user can display related information and know related content, especially the housing surface of the present invention is provided with a keyboard and a display part to provide the user with operation. The block diagram is shown in fig. 14.

The keyboard and display portions are conventional in use and control technology and therefore their contents are not described again.

14. Remote controller: the functional block diagram of the remote control part is shown in fig. 15.

In fig. 15, the left one-chip microcomputer memory is connected with a communication module, which belongs to the equipment part; the right side is that the controller and the communication module are combined into a whole, namely a remote controller part. The two communication modules are a bridge for information interaction between the equipment shell part and the remote controller. The signal on the remote controller can be transmitted to the equipment shell part through the communication module, and the data of the equipment shell part can also be transmitted to the display on the remote controller for displaying through the communication module.

The wireless transmission work of data can adopt infrared ray component, also can adopt bluetooth module, and WIFI module or other communication module that have communication function accomplish.

In addition, the control mode of the device by the user, including direct control on the device or control on the remote controller, may be performed in various manners, such as a key mode, a voice control mode, a touch control mode, a gesture control mode, an emotion control mode, or a combination of the above control modes.

Use the utility model discloses a technique is the core, cooperates different components, can make corresponding product for the crowd of various different grade types. For example, some artificial intelligence technologies are added and an interesting shape is matched to make the infant intelligent closestool; the intelligent closestool is matched with a wheelchair and the like and is used for the old; the portable intelligent closestool can be used as an intelligent closestool on mobile tools such as a motor home and the like and a conventional intelligent closestool and the like.

Claims (9)

1. The utility model provides an intelligent closestool who has stoving effect to washing part installs the washing part on closestool body, the washing part is connected its characterized in that through washing pipeline and hot water heating part and water storage container: the closestool is characterized in that an air source part playing a drying role is further integrally installed on the closestool body, a drying pipeline is arranged between the air source part and the flushing part and used for drying the inside of the whole pipeline of the flushing part after flushing work is finished, and the drying pipeline is specifically characterized in that the air source part is connected with the flushing part finally through a water storage container (11), a water heating part and a flushing pipeline in parallel through a drying pipeline II; and electronic components adopted by each part of the air source part, the water heating part, the washing part and the water storage container (11) and electromagnetic valves arranged on each pipeline are all connected with the single chip microcomputer.

2. The intelligent toilet with drying function for the washing part according to claim 1, wherein: another drying pipeline is arranged between the air source part and the washing part and used for drying human body parts, and the drying pipeline is specifically characterized in that the air source part is directly connected with the washing part through the first drying pipeline.

3. The intelligent toilet with drying function for the washing part according to claim 1, wherein: the wind regime part is still connected with the seat circle heating part through admit air coupling hose (33), is provided with seat circle heating solenoid valve (21) on the intake pipe way, seat circle heating part and seat circle heating solenoid valve (21) all are connected with the singlechip.

4. The intelligent toilet with drying function for the washing part according to claim 1, wherein: the flushing part comprises a supporting pipe (29) fixed on the closestool body, a movable pipe (1) is connected in the supporting pipe (29) in a sliding mode along the axial direction, the movable pipe (1) is connected with a driving motor (28) to enable the movable pipe (1) to move axially relative to the supporting pipe (29), an air outlet (2) and a water outlet (3) are arranged at the front end of the movable pipe (1), and the air outlet (2) is connected with an air source part through a drying connecting hose (27) and a drying pipeline I to finish drying of a human body part and the drying pipeline; the water outlet (3) is connected with the water storage container (11) through a water outlet connecting hose (26) and a flushing electromagnetic valve (25) and a water heating part, and the water storage container (11) is connected with the air source part through an air inlet connecting pipe (17) and a drying pipeline II so as to complete flushing and drying of the inside and the outside of the whole pipeline of the flushing part.

5. The intelligent toilet bowl with drying function for the washing part according to claim 4, wherein: the tail end of the supporting pipe (29) is provided with an external interface (4), and the external interface (4) is connected with a water storage container (11) through an external connecting hose (5) and an external electromagnetic valve (6) and a water heating part so as to finish washing or drying the outside of the movable pipe (1) of the washing part.

6. The intelligent toilet with drying function for the washing part according to claim 1, wherein: a human body drying electromagnetic valve (22) is arranged on the drying pipeline I, and a waterway drying electromagnetic valve (18) is arranged on the drying pipeline II.

7. The intelligent toilet with drying function for the washing part according to claim 1, wherein: the water heating part comprises a flow meter (7), a water pump (8), a heater (10) and a water inlet temperature sensor (23) and a water outlet temperature sensor (24) which are integrated on a conveying pipeline (9) and are arranged at two ends of the heater (10).

8. The intelligent toilet with drying function for the washing part according to claim 1, wherein: the top of the water storage container (11) is provided with an air inlet (16), and the air inlet (16) is connected with an air inlet connecting pipe (17); the water storage container (11) is connected with an external water source through a water inlet pipe (14), and a water inlet electromagnetic valve (13) is arranged on the water inlet pipe (14); a water level sensor (15) is also arranged in the water storage container (11).

9. The intelligent toilet with drying function for the washing part according to claim 3, wherein: the seat ring heating part is characterized in that an air outlet (31) and a human body detection sensor (34) are arranged on the seat ring (30), and a gas temperature sensor (35) is arranged at an air inlet (32) of the seat ring (30).

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