RU2783112C1 - Automatic water supply system for home appliances - Google Patents

Abstract

FIELD: automated water supply.

SUBSTANCE: inventions group relates to the field of automated water supply for household appliances. The design of the water supply system includes a drinking water supply unit, a distribution unit consisting of a housing, shut-off solenoid valves and a control module. The control module is made in the form of a board on which a power supply, power elements for controlling electromagnetic valves and a module for receiving and transmitting signals over a wireless network are integrated, the number of valves is n-1, where n is the number of terminal devices connected to the system. The water supply to the terminal devices is carried out through water pipes. Terminal bases are equipped with sealed connectors for supplying water to tanks, as well as sensors for the amount of water in the tank and wireless signal reception and transmission boards. A method for automatically supplying water to household appliances tanks consists in using the system described above, where the water level in each tank is determined using water quantity sensors. Information from the water quantity sensors is sent to the data transmission and reception board, from where it is transmitted wirelessly to a common control server, which, in the event of an insufficient water level in the terminal devices, generates a control signal transmitted wirelessly to the water supply system, which tops up water into the tanks up to until the water quantity sensors register the achievement of the set level and the control server sends a signal to stop topping up. After that, the water supply is stopped.

EFFECT: creation of a single system with wireless control, which would provide water supply simultaneously to all household devices using water or water vapor in their work, as well as increase the safety of using these household devices.

38 cl, 5 dwg

Description

Technical field

The invention relates to small household appliances for the home, in particular to systems and methods for automated water supply for household appliances such as kettles, coffee machines, humidifiers and other devices that use water or water vapor during operation.

State of the art

At the moment, a number of technical solutions are known from the prior art, aimed at maintaining the required water level in the tanks of household appliances.

In particular, from the patent document CN 103284591 A, a device for automatically adding water to a kettle is known, which ensures the supply of water through an opening made on the bottom of the kettle. The kettle itself is placed on the base, and water is supplied inside using a pump.

The closest analogues are the system and method for maintaining the required level of water in the kettle, disclosed in the document CN 103431769 A. The system described in this document supplies water to the kettle using a pump connected to a bottle or water supply. The kettle is equipped with a water level sensor, which allows you to avoid exceeding the required level. The water supply system is controlled by the control board, and powered by the kettle's power system in between water heating procedures.

The advantage of the proposed technical solution is the presence of a distribution unit that allows topping up water in several devices at once, as well as the transmission of control signals over a wireless network, which avoids the inclusion of a large number of wires in the system design and at the same time provides communication between the system and all terminal devices at the same time. .

Thus, the objective of the present invention is to develop a method and a single system for automated water supply for all household appliances simultaneously using water or water vapor during operation. This will ensure the continuous operation of devices such as air humidifiers, the constant readiness for operation of such devices as coffee makers and ironing systems, as well as improve the safety of using household appliances, in particular, exclude the possibility of switching on devices without water.

The technical result of the claimed invention is the creation of a single system with wireless control, which would provide water supply simultaneously to all household devices that use water or water vapor in their work, as well as a method for maintaining the water level implemented using this system. Another objective of the proposed invention is to improve the safety of using household devices.

Disclosure of invention

The set goal, the technical result required and obtained by using the invention are achieved by the fact that the proposed water supply system for household appliances includes a drinking water supply unit, a distribution unit consisting of a housing, shut-off solenoid valves, and a control module. At the same time, the control module is made in the form of a board on which a power supply unit, power elements for controlling electromagnetic valves and a module for receiving and transmitting a signal over a wireless network are integrated. The number of valves is equal to n-1, where n is the number of end devices connected to the system, and water is supplied to the end devices through water pipes. Terminal bases are equipped with sealed connectors for supplying water to tanks, as well as sensors for the amount of water in the tank and wireless signal reception and transmission boards.

The control board of the distribution unit can be powered from a standard power supply network or from an independent power source.

A section of a cold water pipe connected directly or through a reverse osmosis filter can act as a drinking water supply unit.

In the event that a tank acts as a water source, the water supply unit includes a tank and an electric pump. In particular, it can be an electromagnetic pump, the input of which is connected with a supply tube to a reservoir - a source of water, and the output - to a distribution unit.

The distribution block and the pump can be made in different housings. In this case, their operation is controlled using a single control board, similar to the control board of the distribution unit, with the difference that it additionally contains a power element for controlling the pump.

In the case of execution in different housings, a control board is additionally installed in the pump housing, on which a power supply, a power element for controlling the pump, and a module for receiving and transmitting signals over a wireless network are integrated. The pump control board can be powered from a standard power supply or from an independent power source.

The water pipes connecting the distribution unit and the terminal devices can be made in the form of flexible PVC or in the form of rigid metal pipes.

Both devices with a fixed water tank and devices with a removable water tank can act as terminal devices. In the latter case, water tanks are equipped with hermetically sealed valves to avoid spilling water when removing the tank from the base. As said valves, mechanical or electromechanical valves can be used.

All end devices are equipped with water quantity sensors and boards for receiving and transmitting signals via a wireless network. Piezo sensors, capacitive water level analysis systems, water level analysis systems based on electrical conductivity can be used as water quantity sensors. Sensors and receiving-transmitting boards can be powered from a standard power supply network or from an independent source.

The method for automatically supplying water to domestic household appliances intended for this purpose consists in determining the water level using water quantity sensors and transmitting information from the water quantity sensors to a signal receiving-transmitting board, from where the information is transmitted wirelessly to a common control server. If the water level in the terminal devices is insufficient, the server generates a control signal transmitted via a wireless network to the water supply system, which tops up water into the tanks until the water quantity sensors register the achievement of the set level and the control server sends a signal to stop topping up , after which the water supply is stopped.

In the event that the system includes only the distribution unit and does not turn on the pump, signals from the control server are sent to the control board of the distribution unit, which sends control pulses to open or close the required solenoid valves.

If the system includes both a distribution unit and a pump, signals from the control server are sent to the pump control board, which sends control pulses to start or stop pumping water from the source tank, and to the distribution unit control board, which sends control pulses to open or close required solenoid valves.

If the pump and the distribution unit are made in a single housing, the signals from the control server are sent to a single control board for the pump and the distribution unit.

Brief description of the drawings

The essence of the proposed technical solution is illustrated by drawings.

Figure 1 shows the automatic water supply system for the embodiment, according to which water is supplied from the tank, and the distribution unit and the pump are made in different housings.

The elements of the system are numbered as follows:

1 - reservoir acting as a source of water;

2 - electric pump;

3 - pump housing 2;

4 - pump control board 2;

5 - power supply of the control board 4;

6 - supply tube from tank 1;

7 - distribution block;

8 - shutoff solenoid valves;

9 - control board of the distribution block 7;

10 - power supply of the control board 9 of the distribution unit 7;

11 - water pipes to terminal devices.

Figure 2 shows two examples of connecting the water supply system to the tank of the kettle (top) and coffee machine (bottom). The following notation is used here:

12 - terminal device base (kettle / coffee machine);

13 - water tank of the terminal device;

14 - sealed detachable connection;

15 - valve preventing water from pouring out of the tank 13;

16 - Water filling tube

17 - board for receiving and transmitting signals over a wireless network;

18 - board power supply 17.

Figure 3 shows the electromechanical diagram of the pump and distribution unit. This diagram contains the following elements:

4.1 - pump power supply;

9.1 - power supply unit of the distribution unit;

4.2 - boards for receiving and transmitting signals over a wireless network and power controls for the pump;

9.2 - boards for receiving and transmitting signals over a wireless network and power control elements of the distribution unit.

Figure 4 shows the electromechanical diagram of the connection of the system of automatic topping up of water with the tank terminal device. Here:

19 - sensors for the amount of water in the tank of the terminal device,

20 - power supply unit of the terminal device.

Implementation of the invention

The proposed water supply system can be connected to a special tank or directly to the water supply. The main water tank 1 can be any large capacity container, such as a drinking water bottle with a standard volume of 19 liters. The body of the electric pump 2 is attached to its neck, which can operate according to any principle of pumping water, for example, it can be an electromagnetic pump. Also, in the housing 3 of the electric pump 2, there is a control board 4, including a power supply 4.1, for example, from a standard power supply network 5 or from an autonomous power source (electric battery), a power control module for receiving and transmitting a Wi-Fi signal 4.2.

Water through the supply tube 6, placed inside the water tank, is supplied under pressure to the outlet of the pump 2 and then enters the distribution unit 7, consisting of a housing, shut-off solenoid valves 8 and a control module 9. The number of solenoid valves 8 is equal to n-1 , where n is the number of end devices connected to the system. The control module 9 consists of a power supply unit 9.1, power control elements for shut-off solenoid valves and a module for receiving and transmitting a Wi-Fi signal 9.2. Power can be supplied from a standard power supply network 10 or from an independent power source (batteries).

In one embodiment, the housings of the electric pump and the distribution unit are connected by a detachable connection, which allows connection directly to the water supply. In this case, the body of the electromagnetic pump with all its components is excluded from the system, and the distribution unit is mounted directly on the outlet of the water pipe.

In another embodiment, the housing of the electromagnetic pump and the distribution unit are combined into one unit. In this embodiment, the pump and solenoid valves are controlled from one common control board.

Shut-off solenoid valves turn on or off the water supply to the terminal devices through the water-carrying tubes 11, which can be made in the form of flexible PVC tubes, or in the form of rigid metal ones. Water is supplied to the bases of 12 end devices, which are equipped with sealed detachable connections 14 for supplying water to the tanks of 13 end devices.

Kettles, in which the body of the kettle itself is the water reservoir, various coffee makers and coffee machines equipped with a removable or stationary water reservoir, steamers and steam generators, humidifiers, as well as other devices that include a reservoir for water. The water tanks of the terminal devices must contain hermetically sealed mechanical or electromechanical valves 15 that prevent water from pouring out of the tank when it is removed from the base.

All terminal devices must be equipped with water quantity sensors in the tank and Wi-Fi 17 signal reception and transmission boards. Piezo sensors that determine the weight of the water tank, capacitive water level analysis systems, or water level analysis systems based on electrical conductivity. Power supply of sensors and boards of reception-transmission can be carried out from the power supply unit connected to a standard power supply network 18 or to an independent source (electric battery).

Information from the sensors of the amount of water in the tank 13 is sent to the Wi-Fi signal receiving-transmitting board 17, from where it is wirelessly transmitted to a common control server that performs general system management. All terminal devices, as well as pump 2 and distribution unit 7, are connected to the server via Wi-Fi.

If the water level in the end devices is insufficient, the server generates a control signal to the control boards of the pump body and/or to the corresponding valve of the distribution unit, including the water supply to the end devices. When the predetermined water level in the reservoir of the terminal device is reached, the water supply is stopped according to the scheme described above.

The system is managed on the application's cloud server based on information received from the water sensors installed in the devices, device usage statistics by the user, as well as personal scenarios specified by the user in the application.

In the above embodiment of the invention, a Wi-Fi network is used for data transmission, however, data exchange between devices can also be carried out via satellite communications, mobile communications, in particular, GSM, 3G, 4G, LTE; and/or via ultra-low power data links forming complex wireless networks with a mesh topology, such as ZigBee and/or LoRa and/or LoRaWAN and/or LPWAN and/or 6LoWPAN and/or Z wave.

As follows from the description of possible implementations of the claimed invention, the proposed water supply system ensures the achievement of the claimed technical result, namely, it provides water supply simultaneously to all household devices that use water or water vapor in their work, provides the ability to send control signals over a wireless network and improves security. use of these household devices.

The analysis shows that all general and particular features of the invention are essential, since each of them is necessary for the industrial implementation of the invention, and together they allow to achieve the claimed technical result.

Thus, in the sections "Level of technology" and "Disclosure of the invention" it was shown that all the general and particular features of the proposed device are essential and in the aggregate satisfy the criterion of patentability "novelty". In the "Implementation of the invention" section, it was shown that the claimed invention is technically feasible, allows solving the set inventive problems and confidently achieving the required technical result when using it (the invention), which indicates the industrial applicability of the proposed device. Based on the foregoing, we believe that the claimed water supply system for household appliances meets all the requirements for patentability for inventions.

Claims (38)

1. A water supply system for household appliances, characterized in that its design includes a drinking water supply unit, a distribution unit consisting of a housing, shut-off solenoid valves and a control module, while the control module is made in the form of a board on which the unit is integrated power supply, power controls for electromagnetic valves and a module for receiving and transmitting signals over a wireless network, the number of valves is n-1, where n is the number of terminal devices connected to the system, and water is supplied to the terminal devices through water pipes; terminal bases are equipped with sealed connectors for supplying water to tanks, as well as sensors for the amount of water in the tank and boards for receiving and transmitting signals over a wireless network. 2. Water supply system according to claim 1, characterized in that the control board of the distribution unit is powered from a standard power supply network. 3. The water supply system according to claim 1, characterized in that the control board of the distribution unit is powered from an independent power source. 4. The water supply system according to any one of paragraphs. 1-3, characterized in that a section of a cold water supply pipe is used as a water supply unit. 5. The water supply system according to claim 4, characterized in that the distribution unit is connected to the section of the cold water supply pipe through a reverse osmosis filter. 6. The water supply system according to any one of paragraphs. 1-3, characterized in that the drinking water supply unit consists of an electric pump and a water source tank, which is connected to the pump inlet by means of a supply tube, the output of which is connected to the distribution unit. 7. The water supply system according to claim 6, characterized in that the electric pump is an electromagnetic pump. 8. The water supply system according to any one of paragraphs. 6, 7, characterized in that the pump and the distribution unit are made in different housings. 9. The water supply system according to claim 8, characterized in that the pump housing contains a control board on which the power supply, the pump power control element and the module for receiving and transmitting signals over a wireless network are integrated. 10. Water supply system according to claim 9, characterized in that the control board is powered from a standard power supply network. 11. The water supply system according to claim 9, characterized in that the control board is powered from an independent power source. 12. The water supply system according to any one of paragraphs. 6, 7, characterized in that the pump and the distribution unit are made in a single housing. 13. The water supply system according to claim 12, characterized in that a power pump control element is additionally integrated on the control board of the distribution unit. 14. The water supply system according to any one of paragraphs. 1-13, characterized in that the water-conducting tubes connecting the distribution unit and terminal devices are made in the form of flexible PVC tubes. 15. The water supply system according to any one of paragraphs. 1-13, characterized in that the water-conducting tubes connecting the distribution unit and terminal devices are made in the form of metal tubes. 16. The water supply system according to any one of paragraphs. 1-15, characterized in that devices with a stationary water tank act as terminal devices. 17. The water supply system according to any one of paragraphs. 1-15, characterized in that devices with a removable water tank equipped with hermetically closing valves act as terminal devices. 18. The water supply system according to claim 17, characterized in that mechanical valves are used as hermetically closing valves. 19. The water supply system according to claim 17, characterized in that electromechanical valves are used as hermetically closing valves. 20. The water supply system according to any one of paragraphs. 1-19, characterized in that piezo sensors are used as sensors for the amount of water. 21. The water supply system according to any one of paragraphs. 1-19, characterized in that capacitive water level analysis systems are used as water quantity sensors. 22. The water supply system according to any one of paragraphs. 1-19, characterized in that water level analysis systems based on electrical conductivity are used as water quantity sensors. 23. The water supply system according to any one of paragraphs. 1-22, characterized in that the water quantity sensors and the boards for receiving and transmitting signals of the terminal devices are powered from a standard power supply network. 24. The water supply system according to any one of paragraphs. 1-22, characterized in that the power supply of the sensors of the amount of water and the boards for receiving and transmitting signals of the terminal devices is carried out from an independent source. 25. The water supply system according to any one of paragraphs. 1-24, characterized in that a Wi-Fi network is used as a wireless network through which data is transmitted. 26. The water supply system according to any one of paragraphs. 1-24, characterized in that a satellite communication network is used as a wireless network through which data is transmitted. 27. The water supply system according to any one of paragraphs. 1-24, characterized in that a mobile communication network is used as a wireless network through which data is transmitted. 28. The water supply system according to claim 27, characterized in that GSM cellular communications are used as a mobile network. 29. The water supply system according to claim 27, characterized in that 3G technology is used as a mobile network. 30. The water supply system according to claim 27, characterized in that 4G technology is used as a mobile network. 31. The water supply system according to claim 27, characterized in that LTE technology is used as a mobile network. 32. The water supply system according to any one of paragraphs. 1-24, characterized in that as a wireless network through which data is transmitted, data transmission channels with ultra-low power consumption are used, forming complex wireless networks with a mesh topology. 33. The water supply system according to claim 32, characterized in that ZigBee is used as a data transmission channel. 34. The water supply system according to claim 32, characterized in that LoRa is used as a data transmission channel. 35. The water supply system according to claim 32, characterized in that LoRaWAN is used as a data transmission channel. 36. The water supply system according to claim 32, characterized in that 6L0WPAN is used as a data transmission channel. 37. The water supply system according to claim 32, characterized in that Z wave is used as a data transmission channel. 38. A method for automatically supplying water to dedicated household appliances tanks using the system according to claim 1, which consists in determining the water level in each tank using water quantity sensors, and characterized in that further information from water quantity sensors arrives at the data reception-transmission board, from where it is transmitted wirelessly to a common control server, which, in case of insufficient water level in the terminal devices, generates a control signal transmitted wirelessly to the water supply system, which tops up water into the tanks until the sensors the amount of water will not register the achievement of the set level and the control server will not send a signal to stop topping up, after which the water supply stops.

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