CN114995211A - Water outlet control system and water outlet control method - Google Patents

Abstract

The application discloses a water outlet control system and a water outlet control method. The water outlet control system comprises a water outlet control device and a heating control device, and the water outlet control device comprises a first electric connector and a motor. The first electrical connection port is connectable with an energy storage device. The motor can utilize the electric energy of first electric connection mouth access to carry out pressurization operation to water. The heating control device comprises a heating module which can heat water. The utility model provides a play water control system includes play water controlling means and heating controlling means, goes out water controlling means and can carry out the pressurization operation in order to realize the play water function to water, and heating controlling means can heat the operation in order to realize the heating function to water, so play water control system's function is abundanter, can improve user and use experience.

Description

Water outlet control system and water outlet control method

Technical Field

The present application relates to the field of consumer electronics, and more particularly, to a water discharge control system and a water discharge control method.

Background

In order to enrich the outdoor activity scene, the outdoor cooling device is more and more favored by people. In the correlation technique, the outdoor cooling device only has the function of water outlet, and the function is single, and the use experience effect is not good enough.

Disclosure of Invention

The embodiment of the application relates to a water outlet control system and a water outlet control method.

The water outlet control system comprises a water outlet control device and a heating control device, wherein the water outlet control device comprises a first electric connector and a motor. The first electrical connection port is connectable with an energy storage device. The motor can utilize the electric energy accessed by the first electric connection port to pressurize the water. The heating control device comprises a heating module which can heat water.

In some embodiments, the water outlet control device comprises a first controller for controlling the operation of the motor.

In some embodiments, the water outlet control device further includes a first power control circuit, the first power control circuit connects the first electrical connection port and the motor, and the first controller controls the output power of the motor through the first power control circuit.

In some embodiments, the water outlet control device further includes a first button, and the first controller is configured to control a working mode of the motor according to a state of the first button.

In some embodiments, the water outlet control device further comprises a first voltage stabilizing circuit, and the first voltage stabilizing circuit is used for converting the voltage of the first electrical connection port into a first preset voltage to be provided for the first controller to work.

In some embodiments, the first controller may be configured to control the motor to operate after the water outlet control device is successfully communicated with the energy storage device.

In some embodiments, the water outlet control device further includes a first communication interface, and the first communication interface is used for realizing communication between the water outlet control device and the energy storage device.

In some embodiments, the effluent control system includes a plurality of spray heads, each spray head corresponding to an operating mode of the effluent control system.

In some embodiments, the water outlet control device comprises a first water inlet port that is operable to connect with a heated water outlet port of a heating control device.

In some embodiments, the heating control device includes a second electrical connection port, the second electrical connection port is connectable to the energy storage device, and the heating module is capable of performing a heating operation on water by using electrical energy input through the second electrical connection port.

In certain embodiments, the heating control apparatus further comprises a second controller for controlling the operation of the heating module.

In some embodiments, the heating control device comprises a heating water inlet, a heating zone and a heating water outlet, the heating zone is used for connecting the heating water inlet and the heating water outlet, and the heating module is used for heating the heating zone.

In some embodiments, the heating control device further comprises a temperature detection element for detecting the temperature of the heating water inlet, the temperature of the heating area or the temperature of the heating water outlet, and the second controller is used for controlling the operation of the heating module according to the temperature of the heating water inlet, the temperature of the heating area or the temperature of the heating water outlet.

In some embodiments, the heating control device further comprises a second power control circuit, the second power control circuit connects the second electrical connection port with the heating module, and the second controller controls the heating power of the heating module through the second power control circuit.

In some embodiments, the heating control device further comprises a second button, and the second controller is configured to control an operating mode of the heating module according to a state of the second button.

In some embodiments, the heating control device further comprises a second voltage stabilizing circuit, and the second voltage stabilizing circuit is used for converting the voltage of the second electric connection port into a second preset voltage to be supplied to the second controller for operation.

In certain embodiments, the second controller may be configured to control operation of the heating module after the heating control device has successfully communicated with the energy storage device.

In some embodiments, the heating control device further comprises a second communication interface for enabling communication between the heating control device and the energy storage device.

In some embodiments, the water outlet control system further comprises the energy storage device, and the energy storage device can be detachably connected with the water outlet control device and the heating control device.

In some embodiments, the water egress control system further comprises the energy storage device, the energy storage device comprising a vehicle emergency start output interface, the vehicle emergency start output interface being operable to interface with a vehicle to assist the vehicle in achieving ignition.

In some embodiments, the heating control device is detachably connected with the water outlet control device, or a part of the heating control device is detachably connected with the water outlet control device.

In some embodiments, the water outlet control device is a portable water outlet control device.

The water outlet control method can be used for a water outlet control system, the water outlet control system comprises a water outlet control device and a heating control device, the water outlet control device comprises a first electric connecting port and a motor, the first electric connecting port can be connected with an energy storage device, and the heating control device comprises a heating module; the water outlet control method comprises the following steps: controlling the motor to perform pressurization operation on water by using the electric energy accessed by the first electric connection port; and controlling the heating module to heat the water.

In the water outlet control system and the water outlet control method in the embodiment of the application, the water outlet control system comprises the water outlet control device and the heating control device, the water outlet control device can pressurize water to realize a water outlet function, the heating control device can heat water to realize a heating function, so that the water outlet control system is richer in function, and the use experience of a user can be improved.

Additional aspects and advantages of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic circuit diagram of a water control system according to some embodiments of the present disclosure.

Fig. 2 and 3 are schematic structural diagrams of a water outlet control system according to some embodiments of the present disclosure.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present application and should not be construed as limiting the present application.

In order to enrich outdoor activity scenes, outdoor cooling devices are increasingly favored by people. In the correlation technique, the outdoor cooling device only has the function of water outlet, and the function is single, and the use experience effect is not good enough.

Referring to fig. 1, a water outlet control system 100 according to an embodiment of the present disclosure includes a water outlet control device 20 and a heating control device 40, wherein the water outlet control device 20 includes a first electrical connection port 212 and a motor 22. The first electrical connection port 212 is connectable with the energy storage device 60. The motor 22 can pressurize the water using the power received through the first electrical connection port 212. The heating control device 40 includes a heating module 41, and the heating module 41 is capable of performing a heating operation on water.

The water outlet control system 100 of the embodiment of the application comprises the water outlet control device 20 and the heating control device 40, the water outlet control device 20 can pressurize water to realize a water outlet function, the heating control device 40 can heat water to realize a heating function, so that the water outlet control system 100 with the heating function can be combined into a set, the outdoor water cooling can be achieved, the functions of the water outlet control system 100 are richer, and the use experience of a user can be improved.

The first electrical connection port 212 may include a Direct Current (DC) input port, and the first electrical connection port 212 is connected to the energy storage device 60 and is configured to receive electrical energy output from the energy storage device 60.

The motor 22 may comprise a motor in a water pump, and the motor 22 can utilize the electric power received by the first electric connection port 212 to pressurize the water to control the water flow output.

The heating module 41 is capable of performing a heating operation on water. In some embodiments, the heating control device 40 may be integrated with the water outlet control device 20, wherein the heating control device 40 may share the first electrical connection port 212 in the water outlet control device 20, that is, the heating module 41 can perform a heating operation on water by using the electrical energy received by the first electrical connection port 212.

In some embodiments, the water outlet control device 20 includes a first controller 23, and the first controller 23 is used for controlling the operation of the motor 22.

The first controller 23 may include a driving board. The driver board may include a Central Processing Unit (CPU), a Micro Control Unit (MCU), other general purpose processors, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, and so forth. The structure of the first controller 23 is only an example, and any type of control module that can implement the function of the first controller 23 is within the scope of the embodiments of the present application.

The first controller 23 may intelligently control the motor 22, for example, the first controller 23 may be used to control the motor 22 to turn on or off.

In some embodiments, the heating control device 40 may be integrated with the water outlet control device 20, wherein the heating control device 40 may share the first controller 23 in the water outlet control device 20, that is, the first controller 23 may also be used to control the operation of the heating module 41.

In some embodiments, the water outlet control device 20 further includes a first power control circuit 24, the first power control circuit 24 connects the first electrical connection port 212 and the motor 22, and the first controller 23 controls the output power of the motor 22 through the first power control circuit 24.

In this way, the first controller 23 can control the output power of the motor 22 through the first power control circuit 24, so that the water outlet control device 20 outputs water flow with a proper water outlet amount.

The first power control circuit 24 is connected to the first electrical connection port 212 and the motor 22, the electric energy of the first electrical connection port 212 is transmitted to the motor 22 through the first power control circuit 24, and the first power control circuit 24 is controlled by the first controller 23 and can be used for adjusting the output power of the motor 22.

In some embodiments, the water outlet control device 20 further includes a first button 25, and the first controller 23 is configured to control the operation mode of the motor 22 according to a state of the first button 25.

In this manner, the user can control the operation mode of the motor 22 by operating the first button 25.

Specifically, different operation modes of the motor 22 correspond to different output powers of the motor 22, for example, the first button 25 may be used to set the operation mode of the motor 22, so that the first controller 23 may determine a power setting value of the motor 22 according to the operation mode input by the first button 25, and control the first power control circuit 24 to control the output power of the motor 22 according to the power setting value of the motor 22, so that the motor 22 may enter different operation modes, and the output power of the motor 22 can meet the user requirements. For example, the operation modes of the motor 22 include a car washing operation mode and a cooling operation mode, the car washing operation mode corresponds to a first power, the cooling operation mode corresponds to a second power, and the first power is greater than the second power. For another example, the operation modes of the motor 22 include a high-voltage operation mode, a medium-voltage operation mode, and a low-voltage operation mode, and the power corresponding to each mode is sequentially reduced.

In some embodiments, the water outlet control device 20 further includes a first voltage regulator circuit 26, and the first voltage regulator circuit 26 is configured to convert the voltage of the first electrical connection port 212 into a first preset voltage to be provided to the first controller 23 for operation.

In this manner, the first controller 23 can operate based on the first preset voltage. Specifically, the first regulator 26 is, for example, an LDO (low dropout linear regulator) regulator, and the first regulator 26 may, for example, convert the voltage of the first electrical connection port 212 into a first preset voltage of 5V to be supplied to the first controller 23 for operation.

In some embodiments, the first controller 23 can be used to control the operation of the motor 22 after the successful communication between the effluent control device 20 and the energy storage device 60.

Specifically, the successful communication between the water outlet control device 20 and the energy storage device 60 indicates that the water outlet control device 20 and the energy storage device 60 are legal and adaptive components, and therefore, after the successful communication between the water outlet control device 20 and the energy storage device 60, the first controller 23 can normally operate and control the motor 22.

In some embodiments, after the water outlet control device 20 successfully communicates with the energy storage device 60, the first electrical connection port 212 may receive operation information (voltage information, temperature information) of the energy storage device 60, and the like, and the first controller 23 is configured to control the operation of the motor 22 according to the operation information of the energy storage device 60, for example, when the temperature of the energy storage device 60 is higher than a temperature threshold, the first controller 23 may decrease the output power of the motor 22.

In some embodiments, the water outlet control device 20 further includes a first communication interface 214, and the first communication interface 214 is used for communication between the water outlet control device 20 and the energy storage device 60.

Thus, the communication between the water outlet control device 20 and the energy storage device 60 can be realized through the first communication interface 214 to determine whether the communication between the water outlet control device 20 and the energy storage device 60 is successful.

The first communication interface 214 may be integrated with the first electrical connection port 212, or the first communication interface 214 may be independent from the first electrical connection port 212, which is not particularly limited herein.

In some embodiments, after the first electrical connection port 212 is connected to the energy storage device 60, if the first electrical connection port 212 can receive the power of the energy storage device 60, the first controller 23 can be used to control the operation of the motor 22 (without determining whether the water control device 20 and the energy storage device 60 are successfully communicated).

In the related technology, the outdoor cooling device is not flexible in collocation, the outdoor cooling device can only be used for cooling and cannot be used for other purposes, the application scene is single, and the use is not flexible.

Referring to fig. 2 and 3, in some embodiments, the effluent control system 100 includes a plurality of spray heads 30, each spray head 30 corresponding to an operating mode of the effluent control system 100.

Therefore, different spray heads 30 can be adopted to enable the water outlet control system 100 to be in different working modes, so that the water outlet control system 100 can have other purposes, application scenes are richer, and the water outlet control system can be flexibly used according to actual needs of users.

In some embodiments, the spray heads 30 include, for example, a bath spray head and a car washer spray head, and the outlet control system 100 may be changed from an outdoor shower system to an outdoor car washer system by changing the bath spray head to the car washer spray head. In one embodiment, the number of water outlet holes of the shower nozzle is greater than the number of car washer nozzles, and/or the aperture of the water outlet holes of the shower nozzle is larger than the aperture of the car washer nozzles.

Referring to fig. 2, in some embodiments, the water outlet control device 20 includes a first water inlet 282, and the first water inlet 282 can be used to connect with a heated water outlet 446 of the heating control device 40. In this way, the water flow can be heated by the heating control device 40 and pressurized by the water outlet control device 20.

Referring to fig. 3, in some embodiments, the water outlet control device 20 includes a first water outlet 284, and the first water outlet 284 can be used to connect with the heating water inlet 442 of the heating control device 40. In this way, the water flow can be pressurized by the water outlet control device 20 and then heated by the outlet heating control device 40.

Referring to fig. 1, in some embodiments, the heating control device 40 includes a second electrical connection port 422, the second electrical connection port 422 is capable of being connected to the energy storage device 60, and the heating module 41 is capable of performing a heating operation on the water by using the electrical energy input through the second electrical connection port 422.

Wherein, the heating control device 40 can be independent from the water outlet control device 20, and the second electrical connection port 422 can supply power to the heating module 41 so that the heating module 41 can heat water.

Second electrical connection 422 may include a Direct Current (DC) input interface, and second electrical connection 422 may be coupled to energy storage device 60 and configured to receive electrical energy output by energy storage device 60.

In some embodiments, the heating control device 40 further includes a second controller 43, and the second controller 43 is used for controlling the operation of the heating module 41.

The second controller 43 may comprise a finger drive board. The driver board may include a Central Processing Unit (CPU), a Micro Control Unit (MCU), other general purpose processors, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, and so forth. The structure of the second controller 43 is only an example, and any type of control module that can implement the functions of the second controller 43 is within the scope of the embodiments of the present application.

The second controller 43 may intelligently control the heating module 41, for example, the second controller 43 may be used to control the heating module 41 to be turned on or off.

In some embodiments, the heating control device 40 may be independent of the water outlet control device 20, with the first controller 23 controlling the motor 22 and the second controller 43 controlling the heating module 41.

Referring to fig. 2 and 3, in some embodiments, the heating control device 40 includes a heating water inlet 442, a heating area 444 and a heating water outlet 446, the heating area 444 is used for connecting the heating water inlet 442 and the heating water outlet 446, and the heating module 41 is used for heating the heating area 444.

As such, the heating zone 444 may be heated by the heating module 41 to heat the water in the heating zone 444.

Specifically, the heating control device 40 may be an instantaneous heating device, the heating zone 444 may be composed of a heating tube, and the heating module 41 may heat the heating tube to heat water in the heating tube.

Referring to fig. 1 to 3, in some embodiments, the heating control device 40 further includes a temperature detecting element 45, the temperature detecting element 45 is used for detecting the temperature of the heating water inlet 442, the temperature of the heating area 444 or the temperature of the heating water outlet 446, and the second controller 43 is used for controlling the operation of the heating module 41 according to the temperature of the heating water inlet 442, the temperature of the heating area 444 or the temperature of the heating water outlet 446.

In this way, the second controller 43 can control the operation of the heating module 41 more accurately according to the temperature of the heating water inlet 442, the temperature of the heating zone 444, or the temperature of the heating water outlet 446 detected by the temperature detecting element 45 as negative feedback.

Specifically, for example, when the heating control device 40 is to output a water flow at 43 ℃, the temperature detection element 45 may detect the temperature of the heating region 444 or the temperature of the heating water outlet 446, wherein the temperature of the heating region 444 or the temperature of the heating water outlet 446 may reflect the temperature of the water flow, and therefore, when the temperature of the heating region 444 or the temperature of the heating water outlet 446 is less than 43 ℃, the heating module 41 may be controlled to be turned on, and the heating power of the heating module 41 may be in a negative correlation with the temperature of the heating region 444 or the temperature of the heating water outlet 446; when the temperature of the heating zone 444 or the temperature of the heating outlet 446 is greater than or equal to 43 ℃, the heating module 41 may be controlled to be turned off.

For another example, when the heating control device 40 is to output a water flow at 43 ℃, the temperature detecting element 45 may detect the temperature of the heating water inlet 442, and control the heating module 41 to operate according to a difference between the temperature of the water flow to be output and the temperature of the heating water inlet 442, wherein the heating power of the heating module 41 may be in positive correlation with the temperature difference, and in one embodiment, when the temperature of the heating water inlet 442 is much lower than the temperature of the water flow to be output (for example, the temperature difference is greater than 15 ℃), the heating module 41 may be controlled to operate at the first heating power; when the temperature of the heating water inlet 442 approaches the temperature of the water flow to be output (e.g., the temperature difference is less than 5 ℃), the heating module 41 may be controlled to operate at the second heating power, and the first heating power is greater than the second heating power.

With continued reference to fig. 1, in some embodiments, the heating control device 40 further includes a second power control circuit 46, the second power control circuit 46 connects the second electrical connection port 422 to the heating module 41, and the second controller 43 controls the heating power of the heating module 41 through the second power control circuit 46.

In this manner, the second controller 43 can control the heating power of the heating module 41 through the second power control circuit 46, thereby causing the heating control device 40 to output the water flow at an appropriate temperature.

The second power control circuit 46 is connected to the second electrical connection port 422 and the heating module 41, the electric energy of the second electrical connection port 422 is transmitted to the heating module 41 after passing through the second power control circuit 46, and the second power control circuit 46 is controlled by the second controller 43 and can be used for adjusting the heating power of the heating module 41.

In some embodiments, the heating control device 40 further comprises a second button 47, and the second controller 43 is configured to control the operating mode of the heating module 41 according to the state of the second button 47.

In this manner, the user can control the operation mode of the heating module 41 by operating the second key 47.

Specifically, different operating modes of the heating module 41 correspond to different heating powers of the heating module 41, for example, the second button 47 may be used to set the operating mode of the heating module 41, so that the second controller 43 may determine the power setting value of the heating module 41 according to the operating mode input by the second button 47, and control the second power control circuit 46 to control the heating power of the heating module 41 according to the power setting value of the heating module 41, so that the heating module 41 may enter different operating modes, and the heating power of the heating module 41 can meet the user requirements.

In some embodiments, the heating control device 40 further comprises a second regulator circuit 48, and the second regulator circuit 48 is configured to convert the voltage of the second electrical connection port 422 into a second preset voltage to be supplied to the second controller 43 for operation.

In this manner, the second controller 43 can operate based on the second preset voltage. Specifically, the second controller 43 is, for example, an LDO (low dropout linear regulator) regulator, and the second controller 43 can convert the voltage of the second electrical connection port 422 into a second preset voltage of 5V to provide the second controller 43 for operation.

In certain embodiments, the second controller 43 may be configured to control the operation of the heating module 41 after the heating control device 40 has successfully communicated with the energy storage device 60.

Specifically, the successful communication between the heating control device 40 and the energy storage device 60 indicates that the heating control device 40 and the energy storage device 60 are legal and adaptive components, so that the second controller 43 can operate normally and control the heating module 41 after the successful communication between the two devices.

In some embodiments, after the heating control device 40 successfully communicates with the energy storage device 60, the second electrical connection port 422 may receive operation information (voltage information, temperature information) of the energy storage device 60, and the like, and the second controller 43 is configured to control the operation of the heating module 41 according to the operation information of the energy storage device 60, for example, when the temperature of the energy storage device 60 is higher than a temperature threshold, the second controller 43 may decrease the heating power of the heating module 41.

In some embodiments, the heating control device 40 further includes a second communication interface 424, and the second communication interface 424 is used for communication between the heating control device 40 and the energy storage device 60.

Thus, the communication between the heating control device 40 and the energy storage device 60 can be realized through the second communication interface 424 to determine whether the communication between the heating control device 40 and the energy storage device 60 is successful.

The second communication interface 424 may be integrated with the second electrical connection port 422, or the second communication interface 424 may be independent from the second electrical connection port 422, which is not particularly limited herein.

In some embodiments, after the second electrical connection port 422 is connected to the energy storage device 60, if the second electrical connection port 422 can receive the power of the energy storage device 60, the second controller 43 can be used to control the operation of the heating module 41 (without determining whether the communication between the heating control device 40 and the energy storage device 60 is successful).

In some embodiments, as shown in fig. 1, the heating control device 40 and the water outlet control device 20 may be directly connected to the energy storage device 60, in other embodiments, the water outlet control device 20 may be directly connected to the energy storage device 60, and the heating control device 40 is connected to the energy storage device 60 through the water outlet control device 20, or alternatively, the heating control device 40 is directly connected to the energy storage device 60, and the water outlet control device 20 is connected to the energy storage device 60 through the heating control device 40. The present application is not limited to the above embodiments as long as the connection mode of the heating control device 40 and the water outlet control device 20 based on the electric energy provided by the energy storage device 60 can be realized.

In some embodiments, the water outlet control system 100 further comprises an energy storage device 60, wherein the energy storage device 60 can be detachably connected with the water outlet control device 20 and the heating control device 40.

Energy storage device 60 can be connected with play water controlling means 20 and heating controlling means 40 can be dismantled, therefore, energy storage device 60 can carry out the physics separation, can well solve different application scenes and use portability and nimble collocation problem. When the water outlet control function is not needed, the energy storage device 60 can be separated, and the energy storage device 60 can be used alone (wherein, the energy storage device 60 can be used alone as an outdoor mobile power supply). When the water outlet control function needs to be used, the energy storage device 60 can be connected with the water outlet control device 20 and the heating control device 40, so that the energy storage device 60 can supply power to the water outlet control device 20 and the heating control device 40. Therefore, the portability of product use is greatly improved and the use scene is enriched.

Of course, in other embodiments, the energy storage device 60 can also be fixedly connected to the water outlet control device 20 and the heating control device 40, and is not limited herein.

In some embodiments, the water outlet control device 20 and the heating control device 40 may be powered by the same energy storage device 60, or may be powered by two or more energy storage devices 60, respectively, for example, wherein at least one energy storage device 60 powers the water control device 20 and at least one energy storage device 60 powers the heating control device 40. The different energy storage devices 60 may be removably or non-removably connected.

In some embodiments, the effluent control system 100 further includes an energy storage device 60, the energy storage device 60 including a vehicle emergency start output interface 612, the vehicle emergency start output interface 612 being operable to interface with a vehicle to assist the vehicle in achieving ignition.

Specifically, energy storage device 60 may include a vehicle emergency initiation output interface 612, an electronic switch 614, and energy storage assembly 62. The electronic switch 614 may include a high-power electronic switch, the vehicle emergency starting output interface 612 is a high-current output interface, and the energy storage component 62 can directly output through the electronic switch 614 and the vehicle emergency starting output interface 612. Energy storage device 60 may include devices such as a starting power supply, an emergency power supply, an outdoor energy storage power supply, a portable power supply, etc., and energy storage device 60 may be used to assist the vehicle in ignition. In one embodiment, energy storage device 60 may provide power to the vehicle to assist with ignition via electronic switch 614 and vehicle emergency start output interface 612.

The energy storage assembly 62 may include at least one of a battery (battery pack), a super capacitor, and the like. In some embodiments, the operating voltage of the energy storage assembly 62 ranges from 12V to 16.8V. The energy storage device 60 is, for example, an energy storage element formed by a plurality of super capacitors, in one embodiment, the voltage of one super capacitor is 3V, and the energy storage assembly 62 can be formed by connecting a preset number of super capacitors in series, for example, four, five or six.

In some embodiments, energy storage device 60 also includes charge control circuitry 63. After the energy storage device 60 is connected to the charger, the charging control circuit 63 can be used for charging management of the energy storage assembly 62, so that constant-voltage and constant-current charging of the energy storage assembly 62 is realized.

In certain embodiments, energy storage device 60 also includes Battery Management (BMS) circuitry 64. The battery management circuit 64 is used to determine the state of the energy storage component 62, for example, determine whether the energy storage component 62 is at least one of overcharged, overdischarged, overcurrent, short-circuited, over-high temperature, under-low temperature, and so on, and perform safety protection for each state. For example, if it is determined that the energy storage assembly 62 is in an overcharged state, control stops charging the energy storage assembly 62. And for example, if the energy storage assembly 62 is determined to be in an over-discharge state, an over-current state, a short-circuit state, an over-temperature state, an under-temperature state, or the like, the energy storage assembly 62 is controlled to stop discharging.

In certain embodiments, energy storage device 60 further includes an energy storage device controller 65. Energy storage device controller 65 may include a finger drive plate. The driver board may include a Central Processing Unit (CPU), and may also include other general purpose processors, Digital Signal Processors (DSP), Application Specific Integrated Circuits (ASIC), Field-Programmable Gate arrays (FPGA) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components, and the like. The energy storage device controller 65 may intelligently control the energy storage device 60, for example, the energy storage device controller 65 can receive the detection result of the detection unit 66 and output a corresponding control signal according to the detection result of the detection unit 66 to control the energy storage device 60 to operate.

The detection unit 66 is used for detecting the working state of the energy storage device 60 to obtain a detection result. The detection unit 66 can be used for detecting voltage, current, temperature of the energy storage device 60, and the like, and is not particularly limited herein. In one embodiment, the temperature of the energy storage device 60 may be used to determine whether the energy storage assembly 62 is in an over-temperature state, an under-temperature state, or the like, so that the energy storage device controller 65 may protect the energy storage assembly 62 through the battery management circuit 64.

In some embodiments, energy storage device 60 further includes a display module 67, and display module 67 may be used to display the operating status or other information of energy storage device 60. The information displayed by the display module 67 can facilitate the user to quickly and accurately grasp the related information of the energy storage device 60.

In some embodiments, energy storage device 60 further includes a button 68. Energy storage device controller 65 is configured to control the operating mode of energy storage device 60 based on the state of key 68. In this manner, energy storage device 60 is enabled to perform more functions through the provision of keys 68. In one embodiment, the energy storage device 60 may be turned on and off via the button 68. In another embodiment, energy storage device 60 includes a lighting element, and keys 68 may be used to control the lighting element, such as a light emitting diode or the like, to emit light to provide light to a user.

In some embodiments, the energy storage device 60 further includes a USB output circuit 692, the USB output circuit 692 configured to convert the voltage of the energy storage component 62 into a USB output voltage.

In some embodiments, the energy storage device 60 further includes a type _ c circuit 694 for converting the voltage of the energy storage component 62 to a type _ c output voltage.

In some embodiments, the energy storage device 60 further includes a first dc output circuit 696, the first dc output circuit 696 is used for converting the voltage of the energy storage component 62 into a first predetermined dc power, and the first electrical connection port 212 may be connected to the first dc output circuit 696. The first dc output circuit 696 may also include a communication interface coupled to the first communication interface 214.

In some embodiments, the energy storage device 60 further includes a second dc output circuit 698, the second dc output circuit 698 is used for converting the voltage of the energy storage component 62 into a second preset dc power, and the second electrical connection port 422 may be connected to the second dc output circuit 698. The second dc output circuit 698 may also include a communication interface coupled to the second communication interface 424.

The USB output circuit 692, the type _ c circuit 694, the first dc output circuit 696, and the second dc output circuit 698 may include circuit structures such as a voltage boosting circuit and a voltage dropping circuit, which are not limited herein.

In some embodiments, the heating control device 40 is detachably connected to the water outlet control device 20, or a part of the heating control device 40 is detachably connected to the water outlet control device 20.

Therefore, the whole or part of the heating control device 40 can be physically separated from the water outlet control device 20, and the problems of portability and flexible collocation in different application scenes can be well solved. When the heating function is not needed, the heating control device 40 can be separated, so that the water outlet control device 20 can realize the functions of cold water cooling, a cold water car washer and the like; when a heating function is needed, the heating control device 40 can be connected with the water outlet control device 20, so that the heating control device 40 can heat water, functions of hot water cooling, hot water car washing machines and the like are realized, products can be adapted to different application scenes through different combination modes, and the use is flexible and convenient.

In some embodiments, the water outlet control device 20 is a portable water outlet control device 20.

Specifically, the volume of the portable outlet control device 20 is smaller than the predetermined volume, so that the portable outlet control device 20 can be conveniently stored in a portable toolbox, and compared with a large car washing device in a car washing shop, the portable outlet control device 20 can be conveniently carried by a user and used outdoors.

The water outlet control method according to the embodiment of the present application can be applied to the water outlet control system 100 according to any one of the above embodiments, the water outlet control system 100 includes a water outlet control device 20 and a heating control device 40, the water outlet control device 20 includes a first electrical connection port 212 and a motor 22, the first electrical connection port 212 can be connected to the energy storage device 60, and the heating control device 40 includes a heating module 41; the water outlet control method comprises the following steps:

01: the control motor 22 utilizes the electric energy accessed by the first electric connector 212 to pressurize the water;

02: the heating module 41 is controlled to perform a heating operation on the water.

The effluent control method of the embodiment of the present application can be implemented by the effluent control system 100 of the embodiment of the present application, wherein step 01 can be implemented by the first controller 23, and step 02 can be implemented by the second controller 43. Of course, in other embodiments, step 01 and step 02 may be implemented in other manners, for example, step 01 and step 02 may also be implemented by the first controller 23, and are not limited herein.

In the water outlet control method according to the embodiment of the application, the water outlet control system 100 comprises the water outlet control device 20 and the heating control device 40, the water outlet control device 20 can pressurize water to realize a water outlet function, the heating control device 40 can heat water to realize a heating function, so that the water outlet control system 100 with the heating function can be combined, the water outlet control system can be used for outdoor cooling, the functions of the water outlet control system 100 are richer, and the use experience of a user can be improved.

In some embodiments, the water outlet control device 20 further includes a first power control circuit 24, the first power control circuit 24 connects the first electrical connection port 212 and the motor 22, and the step 01 includes:

012: the output power of the motor 22 is controlled by a first power control circuit 24.

Step 012 may be implemented by first controller 23.

In some embodiments, the water outlet control device 20 further includes a first button 25, and the water outlet control method includes:

03: the operation mode of the motor 22 is controlled according to the state of the first button 25.

Wherein step 03 may be implemented by the first controller 23.

In certain embodiments, step 01 comprises:

014: after the first electrical connection port 212 is successfully communicated with the energy storage device 60, the motor 22 is controlled to operate.

Wherein step 014 may be implemented by the first controller 23.

In some embodiments, the heating control device 40 further includes a temperature detecting element 45, and the water outlet control method includes:

04: controlling the temperature detection element 45 to detect the temperature of the heating area 444 or the heating water outlet 446;

step 02 includes:

022: the operation of the heating module 41 is controlled according to the temperature of the heating zone 444 or the heating water outlet 446.

Wherein step 04 and step 022 may be implemented by the second controller 43.

In certain embodiments, the heating control device 40 further comprises a second power control circuit 46, the second power control circuit 46 connects the second electrical connection port 422 with the heating module 41, and the step 02 comprises:

024: the heating power of the heating module 41 is controlled by the second power control circuit 46.

Wherein step 024 may be implemented by the second controller 43.

In some embodiments, the heating control device 40 further includes a second button 47, and the water outlet control method includes:

05: the operation mode of the heating module 41 is controlled according to the state of the second button 47.

Wherein step 05 may be implemented by the second controller 43.

In certain embodiments, step 02 comprises:

026: after the second electrical connection port 422 is successfully communicated with the energy storage device 60, the heating module 41 is controlled to work.

Wherein step 026 can be implemented by second controller 43.

The above explanation of the effluent control system 100 is also applicable to the effluent control method, and is not repeated herein.

In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Moreover, various embodiments or examples and features of various embodiments or examples described in this specification can be combined and combined by one skilled in the art without being mutually inconsistent.

Furthermore, the term "connected" is to be understood broadly, and may include, for example, a fixed connection, a removable connection, or an integral connection; may include direct connection, indirect connection through an intermediary, and communication between the two elements. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps in the process, and alternate implementations are included within the scope of the preferred embodiment of the present application in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present application.

Although embodiments of the present application have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present application, and that variations, modifications, substitutions and alterations may be made to the above embodiments by those of ordinary skill in the art within the scope of the present application.

Claims (23)

1. The utility model provides a go out water control system which characterized in that, it includes goes out water controlling means and heating controlling means to go out water controlling means, it includes to go out water controlling means:

a first electrical connection port connectable with an energy storage device;

the motor can utilize the electric energy accessed by the first electric connection port to pressurize the water;

the heating control device comprises a heating module which can heat water.

2. The effluent control system of claim 1, wherein said effluent control means includes a first controller for controlling operation of said motor.

3. The water outlet control system of claim 2, further comprising a first power control circuit, wherein the first power control circuit is connected to the first electrical connection port and the motor, and the first controller controls the output power of the motor through the first power control circuit.

4. The water outlet control system of claim 2, wherein the water outlet control device further comprises a first button, and the first controller is configured to control an operating mode of the motor according to a state of the first button.

5. The water outlet control system of claim 2, further comprising a first voltage regulator circuit for converting the voltage of the first electrical connector into a first preset voltage to be supplied to the first controller for operation.

6. The water outflow control system of claim 2 wherein the first controller is operable to control operation of the motor after the water outflow control device has successfully communicated with the energy storage device.

7. The water outflow control system of claim 6 wherein the water outflow control device further comprises a first communication interface for enabling communication between the water outflow control device and the energy storage device.

8. The water egress control system according to claim 1, wherein the water egress control system comprises a plurality of spray heads, each spray head corresponding to an operating mode of the water egress control system.

9. The water egress control system according to claim 1, wherein the water egress control device comprises a first water inlet port operable to connect with a heated water outlet port of a heating control device.

10. The water outlet control system of claim 1, wherein the heating control device comprises a second electrical connection port, the second electrical connection port is connectable with the energy storage device, and the heating module is capable of heating water by using electrical energy input through the second electrical connection port.

11. The water outflow control system of claim 10 wherein the heating control device further comprises a second controller for controlling operation of the heating module.

12. The water outlet control system of claim 11, wherein the heating control device comprises a heating water inlet, a heating zone and a heating water outlet, the heating zone is used for connecting the heating water inlet and the heating water outlet, and the heating module is used for heating the heating zone.

13. The water outlet control system as claimed in claim 12, wherein the heating control device further comprises a temperature detecting element for detecting the temperature of the heating water inlet, the heating zone or the heating water outlet, and the second controller is configured to control the operation of the heating module according to the temperature of the heating water inlet, the heating zone or the heating water outlet.

14. The water discharge control system of claim 11, wherein the heating control device further comprises a second power control circuit, the second power control circuit connects the second electrical connection port with the heating module, and the second controller controls the heating power of the heating module through the second power control circuit.

15. The water outlet control system of claim 11, wherein the heating control device further comprises a second button, and the second controller is configured to control an operation mode of the heating module according to a state of the second button.

16. The water outlet control system of claim 11, wherein the heating control device further comprises a second voltage regulator circuit for converting the voltage of the second electrical connector into a second preset voltage to be supplied to the second controller for operation.

17. The water egress control system of claim 11, wherein the second controller is operable to control operation of the heating module after the heating control device has successfully communicated with the energy storage device.

18. The effluent control system of claim 17, wherein said heating control means further comprises a second communication interface for enabling communication between said heating control means and said energy storage means.

19. The water outflow control system of claim 1 further comprising the energy storage device, wherein the energy storage device is removably connectable with the water outflow control device and the heating control device.

20. The water egress control system according to claim 1, further comprising the energy storage device, wherein the energy storage device comprises a vehicle emergency start output interface, the vehicle emergency start output interface being operable to interface with a vehicle to assist the vehicle in achieving ignition.

21. The effluent control system of claim 1, wherein said heating control means is removably connected to said effluent control means, or wherein a portion of said heating control means is removably connected to said effluent control means.

22. The egress control system of claim 1, wherein the egress control device is a portable egress control device.

23. A water outlet control method is used for a water outlet control system and is characterized in that the water outlet control system comprises a water outlet control device and a heating control device, the water outlet control device comprises a first electric connecting port and a motor, the first electric connecting port can be connected with an energy storage device, and the heating control device comprises a heating module; the water outlet control method comprises the following steps:

controlling the motor to perform pressurization operation on water by using the electric energy accessed by the first electric connection port;

and controlling the heating module to heat the water.

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