阅读说明：本技术 太阳能热水器控制系统及控制方法 (Solar water heater control system and control method ) 是由 周金孝 杨汉伟 杜于龙 高瑞鑫 王上元 陈硕 于 2020-12-18 设计创作，主要内容包括：本申请涉及一种太阳能热水器控制系统及控制方法。该控制系统包括太阳能热水器；保温装置,通过第一管路与太阳能热水器连接,第一管路上设置有第一电磁阀；补水装置,连接有第一补水管路和第二补水管路,第一补水管路与太阳能热水器连接且设置有第二电磁阀,第二补水管路与保温装置连接且设置有第三电磁阀；空气源热泵,通过加热管路与保温装置连接；控制器,与所述空气源热泵、所述第一电磁阀、所述第二电磁阀和所述第三电磁阀连接。上述太阳能热水器控制系统极大地扩展了太阳能热水器的功能和适用范围,具有广阔的应用前景。(The application relates to a solar water heater control system and a control method. The control system comprises a solar water heater; the heat preservation device is connected with the solar water heater through a first pipeline, and a first electromagnetic valve is arranged on the first pipeline; the water replenishing device is connected with a first water replenishing pipeline and a second water replenishing pipeline, the first water replenishing pipeline is connected with the solar water heater and is provided with a second electromagnetic valve, and the second water replenishing pipeline is connected with the heat preservation device and is provided with a third electromagnetic valve; the air source heat pump is connected with the heat preservation device through a heating pipeline; and the controller is connected with the air source heat pump, the first electromagnetic valve, the second electromagnetic valve and the third electromagnetic valve. The solar water heater control system greatly expands the functions and the application range of the solar water heater and has wide application prospect.)

1. A solar water heater control system, comprising:

the solar water heater is used for carrying out solar heating on the filled water;

the heat preservation device is connected with the solar water heater through a first pipeline, and a first electromagnetic valve is arranged on the first pipeline;

the water replenishing device is connected with the solar water heater through a first water replenishing pipeline and is connected with the heat preservation device through a second water replenishing pipeline, the first water replenishing pipeline is provided with a second electromagnetic valve, and the second water replenishing pipeline is provided with a third electromagnetic valve;

the air source heat pump is connected with the heat preservation device through a heating pipeline;

the controller is connected with the air source heat pump, the first electromagnetic valve, the second electromagnetic valve and the third electromagnetic valve and is used for controlling the first electromagnetic valve and the second electromagnetic valve to be opened and the third electromagnetic valve to be closed when the water in the solar water heater reaches a preset temperature, the solar water heater conveys hot water to the heat preservation device through the first pipeline, and the water replenishing device replenishes water to the solar water heater through the first water replenishing pipeline; and a process for the preparation of a coating,

the water replenishing device is used for controlling the first electromagnetic valve and the second electromagnetic valve to be closed when water in the solar water heater is continuously lower than the preset temperature within a first preset time, the third electromagnetic valve and the air source heat pump are opened, the water replenishing device replenishes water to the heat preservation device through the second water replenishing pipeline, and the air source heat pump heats the water in the heat preservation device through the heating pipeline.

2. The solar water heater control system of claim 1, wherein the first predetermined time is greater than or equal to 1 day.

3. The solar water heater control system according to claim 1, wherein the heat retaining device is further connected with a second pipeline for conveying hot water to the outside, and the second pipeline is provided with a hot water pressurizing pump for pressurizing the hot water in the second pipeline.

4. The solar water heater control system according to claim 3, further comprising a return line, wherein one end of the return line is connected to a water outlet end of the hot water pressurizing pump, the other end of the return line is connected to the heat preservation device, a return solenoid valve is disposed on the return line, and the return solenoid valve is connected to the controller, and is controlled to be opened by the controller when the hot water pressurizing pump is started, and is closed after a second preset time.

5. The solar water heater control system of claim 4, wherein the second preset time is 5-10 s.

6. A solar water heater control system according to claim 3, wherein the hot water pressurizing pump is connected to the controller, and the control system further comprises a flow meter provided on the second pipe and connected to the controller to control self-locking of the power supply of the hot water pressurizing pump by the controller when hot water flows through the flow meter.

7. The solar water heater control system of claim 3, further comprising a cold water delivery device connected to the second conduit for delivering cold water to the second conduit.

8. The solar water heater control system according to any one of claims 1-7, wherein the capacity range of the temperature maintaining device comprises 50L-1450L.

9. The solar water heater control system of claim 8, wherein the solar water heater has two or more.

10. A control method of a solar water heater control system according to claim 1, comprising:

s100, detecting the water temperature in the solar water heater;

s200, if the water temperature reaches a preset value, opening the first electromagnetic valve and the second electromagnetic valve, closing the third electromagnetic valve, enabling the solar water heater to convey hot water to the heat preservation device through the first pipeline, and enabling the water supplementing device to supplement water to the solar water heater through the first water supplementing pipeline, and executing the step S300; if the water temperature is continuously lower than the preset value within the first preset time, closing the first electromagnetic valve and the second electromagnetic valve, opening the third electromagnetic valve and the air source heat pump, enabling the water supplementing device to supplement water to the heat preservation device through the second water supplementing pipeline, enabling the air source heat pump to heat the water in the heat preservation device through the heating pipeline, and executing the step S500;

s300, detecting the water level in the heat preservation device;

s400, if the water level reaches a preset value, closing the first electromagnetic valve and the second electromagnetic valve;

s500, detecting the water level and the water temperature in the heat preservation device;

s600, if the water level and/or the water temperature reach respective preset values, closing the third electromagnetic valve and/or the air source heat pump.

Technical Field

The invention relates to the technical field of solar water heaters, in particular to a solar water heater control system and a solar water heater control method.

Background

Solar water heaters began to move into china in the 70 s of the twentieth century. The common water storage capacity of the household solar water heater is 80 liters to 620 liters.

However, this is far from sufficient for a large family with many people or a rental house, and the solar water heater often fails to function in winter or in a long overcast and rainy day.

Disclosure of Invention

In view of the above, there is a need to provide an improved solar water heater control system for solving the problems of small capacity and incapability of functioning in rainy days of the traditional solar water heater.

A solar water heater control system comprising:

the solar water heater is used for carrying out solar heating on the filled water;

the heat preservation device is connected with the solar water heater through a first pipeline, and a first electromagnetic valve is arranged on the first pipeline;

the water replenishing device is connected with the solar water heater through a first water replenishing pipeline and is connected with the heat preservation device through a second water replenishing pipeline, the first water replenishing pipeline is provided with a second electromagnetic valve, and the second water replenishing pipeline is provided with a third electromagnetic valve;

the air source heat pump is connected with the heat preservation device through a heating pipeline;

the controller is connected with the air source heat pump, the first electromagnetic valve, the second electromagnetic valve and the third electromagnetic valve and is used for controlling the first electromagnetic valve and the second electromagnetic valve to be opened and the third electromagnetic valve to be closed when the water in the solar water heater reaches a preset temperature, the solar water heater conveys hot water to the heat preservation device through the first pipeline, and the water replenishing device replenishes water to the solar water heater through the first water replenishing pipeline; and a process for the preparation of a coating,

the water replenishing device is used for controlling the first electromagnetic valve and the second electromagnetic valve to be closed when water in the solar water heater is continuously lower than the preset temperature within a first preset time, the third electromagnetic valve and the air source heat pump are opened, the water replenishing device replenishes water to the heat preservation device through the second water replenishing pipeline, and the air source heat pump heats the water in the heat preservation device through the heating pipeline.

The solar water heater control system can enlarge the storage capacity of the solar water heater by using the heat preservation device, thereby meeting the water demand of large families and residents, and can fully utilize solar energy resources while avoiding the phenomenon of pipe explosion by designing the pipeline which stores and supplements water; in addition, the air source heat pump can avoid the failure of the solar water heater in winter or rainy days, thereby ensuring the hot water supply of residents. The control system can be controlled by one controller, so that the control concentration ratio is improved, and the inconvenience caused by the spliced control of the traditional solar water heater is avoided.

In one embodiment, the first predetermined time is greater than or equal to 1 day.

In one embodiment, the heat preservation device is further connected with a second pipeline for conveying hot water to the outside, and a hot water pressurizing pump is arranged on the second pipeline and used for pressurizing the hot water in the second pipeline.

In one embodiment, the water heater further comprises a return pipeline, one end of the return pipeline is connected with the water outlet end of the hot water pressurizing pump, the other end of the return pipeline is connected with the heat preservation device, a return electromagnetic valve is arranged on the return pipeline, and the return electromagnetic valve is connected with the controller, is controlled to be opened by the controller when the hot water pressurizing pump is started, and is closed after a second preset time.

In one embodiment, the second preset time is 5s to 10 s.

In one embodiment, the hot water pressurizing pump is connected with the controller, and the control system further comprises a flow meter which is arranged on the second pipeline and connected with the controller, so that when hot water flows through the flow meter, the controller controls the power supply of the hot water pressurizing pump to be self-locked.

In one embodiment, the system further comprises a cold water conveying device, wherein the cold water conveying device is connected with the second pipeline and is used for conveying cold water to the second pipeline.

In one embodiment, the capacity range of the heat preservation device comprises 50L-1450L.

In one embodiment, the solar water heater has two or more.

The application also provides a control method of the solar water heater control system.

A control method of a solar water heater control system comprises the following steps:

s100, detecting the water temperature in the solar water heater;

s200, if the water temperature reaches a preset value, opening the first electromagnetic valve and the second electromagnetic valve, closing the third electromagnetic valve, enabling the solar water heater to convey hot water to the heat preservation device through the first pipeline, and enabling the water supplementing device to supplement water to the solar water heater through the first water supplementing pipeline, and executing the step S300; if the water temperature is continuously lower than the preset value within the first preset time, closing the first electromagnetic valve and the second electromagnetic valve, opening the third electromagnetic valve and the air source heat pump, enabling the water supplementing device to supplement water to the heat preservation device through the second water supplementing pipeline, enabling the air source heat pump to heat the water in the heat preservation device through the heating pipeline, and executing the step S500;

s300, detecting the water level in the heat preservation device;

s400, if the water level reaches a preset value, closing the first electromagnetic valve and the second electromagnetic valve;

s500, detecting the water level and the water temperature in the heat preservation device;

s600, if the water level and/or the water temperature reach respective preset values, closing the third electromagnetic valve and/or the air source heat pump.

According to the control method of the solar water heater control system, the hot water in the solar water heater is transferred to the heat preservation device for storage, so that the storage capacity of the solar water heater can be remarkably improved, and the water demand of large families and residents can be met; moreover, the water can be replenished while storing by controlling the opening and closing of the electromagnetic valve, and the solar energy resource can be fully utilized while the pipe explosion phenomenon is avoided; in addition, the air source heat pump can avoid the failure of the solar water heater in winter or rainy days, thereby ensuring the hot water supply of residents.

Drawings

In order to more clearly illustrate the embodiments of the present specification or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only some embodiments described in the specification, and other drawings can be obtained by those skilled in the art without inventive labor.

FIG. 1 is a schematic structural diagram of a control system according to an embodiment of the present application;

fig. 2 is a flowchart illustrating a control method according to an embodiment of the present application.

100. The control system is used for controlling the system,

10. a solar water heater 101, a water heater electromagnetic valve 11, a first pipeline 111, a first electromagnetic valve,

20. a heat preservation device 201, a hot water pressure pump 202, a flowmeter 21, a second pipeline 22, a return pipeline 221, a return electromagnetic valve,

30. a water supplementing device 301, a water pump 31, a first water supplementing pipeline 311, a second electromagnetic valve 32, a second water supplementing pipeline 321, a third electromagnetic valve,

40. air source heat pump, 41, heating pipeline.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. As used herein, the terms "vertical," "horizontal," "left," "right," "upper," "lower," "front," "rear," "circumferential," and the like are based on the orientation or positional relationship shown in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the present invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The household solar water heater usually has a small capacity (at most about 500L), and in the practical use process, many problems are encountered, which are mainly shown in the following aspects:

(1) the water storage capacity of the solar water heater is not enough, and the solar water heater is only suitable for families of 3-4 people;

(2) in winter or in rainy days for a long time, the solar water heater cannot play a role;

(3) when the water heater is actually used, a long distance is usually reserved between the hot water pipeline and a faucet, hot water in the pipeline can be cooled due to the influence of external temperature, and a user can wait for a long time to discharge cold water and hot water, so that the use is inconvenient;

(4) most users need to add a hot water pump to pressurize hot water to obtain good cooling effect. At present, the automatic starting/stopping of the hot water pump by using the pressure valve is not good in effect, because the pressure valve is automatically closed when the hot water is closed, and the hot water pump stops running. Thereby, the phenomenon of hot or cold occurs, namely the control effect of the small-flow hot water is poor;

(5) in a traditional solar water heater system, a controller is arranged on a solar water heater, air can be provided with the controller, hot water can be obtained only by respectively controlling the controller, and the integration degree is low.

In view of the above-mentioned deficiencies, the present application provides an improved solar water heater control system 100, as shown in fig. 1. The control system 100 includes a solar water heater 10, a thermal insulation device 20, a water replenishing device 30, an air source heat pump 40, and a controller (not shown).

Specifically, the solar water heater 10 is pre-filled with water, and the water can be heated by solar energy. Specifically, if the control system 100 is applied in a city, the water in the solar water heater 10 may be tap water, and if the control system 100 is applied in a rural area or a mountain area, the water in the solar water heater 10 may be spring water.

The heat preservation device 20 is connected with the solar water heater 10 through a first pipeline 11, a first electromagnetic valve 111 is arranged on the first pipeline 11, and the first electromagnetic valve 111 can be used for controlling the on-off of the first pipeline 11. Specifically, the capacity of the heat preservation device needs to be as large as possible, for example, the capacity can be 50L to 1450L, and further, the capacity can be 500L to 1000L. The shape of the heat retaining device 20 may be a cylindrical shape or a cubic shape, and may be determined specifically according to the actual installation environment of the heat retaining device.

The water replenishing device 30 is connected with the solar water heater 10 through a first water replenishing pipeline 31 and is connected with the heat preservation device 20 through a second water replenishing pipeline 32, the first water replenishing pipeline 31 is provided with a second electromagnetic valve 311, and the second water replenishing pipeline 32 is provided with a third electromagnetic valve 321. Specifically, the water replenishing device 30 may include a water pump 301 and a water source, which may be tap water or stored spring water. The water inlet ends of the first water replenishing pipeline 31 and the second water replenishing pipeline 32 are commonly connected to the water outlet end of the water replenishing device 30, and for example, as shown in fig. 1, may be commonly connected to the water outlet end of the water pump 301. The second solenoid valve 311 may be used to control the on/off of the first water replenishing pipe 31, and the third solenoid valve 321 may be used to control the on/off of the second water replenishing pipe 32.

The air source heat pump 40 is connected to the heat retaining device 20 through a heating line 41. The air source heat pump 40 can use the air energy present in the air to heat the liquid flowing through the heat pump. Taking fig. 1 as an example, after the air source heat pump 40 is started, water in the thermal insulation device 20 can flow through the air source heat pump 40 via the heating pipeline 7 to be heated, and the heated water continuously flows back to the thermal insulation device 20 via the heating pipeline 7.

The controller (not shown) is connected to the air source heat pump 40, the first solenoid valve 111, the second solenoid valve 311, and the third solenoid valve 321, and is mainly used for controlling the air source heat pump 40 and opening or closing of the solenoid valves, so as to deliver hot water to the outside through the thermal insulation device 20. The controller can adopt a modular design, thereby being beneficial to reducing devices, reducing the complexity of a circuit and improving the reliability of control.

Specifically, when the water in the solar water heater 10 reaches the preset temperature, the controller may control the first electromagnetic valve 111 and the second electromagnetic valve 311 to open, the third electromagnetic valve 321 to close, the solar water heater 10 transmits hot water to the heat preservation device 20 through the first pipeline 11, and the water supplement device 30 supplements water to the solar water heater 10 through the first water supplement pipeline 31. At this time, it indicates that the external sunlight is sufficient, the solar water heater can utilize the solar energy to make the water therein reach the preset temperature, so that the controller controls the electromagnetic valve to perform the above-mentioned actions, so that the hot water in the solar water heater 10 is delivered to the heat preservation device 20 for storage, and meanwhile, as the water amount in the solar water heater 10 decreases, the water inlet of the solar water heater 10 is also opened, so that the water replenishing device 30 timely pumps water to compensate the water amount of the solar water heater 10, thereby preventing the pipe explosion phenomenon of the solar water heater 10 due to overhigh temperature, and also continuously utilizing the solar energy to heat the replenished water, thereby realizing the uninterrupted utilization of the external solar energy resources. In addition, when the water in the solar water heater 10 is lower than a preset temperature at a certain time or the water in the temperature keeping device 20 reaches an upper limit water level, the first solenoid valve 111 and the second solenoid valve 311 are closed, and the pumping of the water into the solar water heater 10 is stopped. By doing so, the hot water in the plurality of batches of solar water heaters 10 can be delivered to the heat preservation device 20 for storage, thereby significantly increasing the storage capacity of the hot water. Further, the preset temperature may be any value of 40 to 60 ℃, and further, may be any value of 45 to 55 ℃, so that a balance between the temperature of the hot water and the full utilization of the solar energy resource may be ensured.

In another embodiment, when the water in the solar water heater 10 is continuously lower than the preset temperature for the first preset time, the first electromagnetic valve 111 and the second electromagnetic valve 311 are controlled to be closed, the third electromagnetic valve 321 and the air source heat pump 40 are controlled to be opened, the water replenishing device 30 replenishes water to the heat preservation device 20 through the second water replenishing pipeline 32, and the air source heat pump 40 heats the water in the heat preservation device 20 through the heating pipeline 41. At this time, the sunlight outside the surface is insufficient, for example, in winter, the sunlight is weak, or in continuous rainy days, the water in the solar water heater 10 will be continuously lower than the preset temperature for a certain period (for example, at least 1 day) and will not work basically, and the water level and the water temperature of the water in the thermal insulation device 20 cannot be maintained at the minimum level and the minimum water temperature. In this case, the controller controls the solenoid valves to perform the above operation, so that the water amount can be supplied to the heat retaining device 20 in time, and the air-source heat pump 40 can be activated to heat the water in the heat retaining device 20. When the water in the heat preservation device 20 reaches the upper limit water level, stopping water supplement, and when the water level is lower than the lower limit water level, continuing water supplement; when the water in the heat preservation device 20 reaches the upper limit temperature, the air source heat pump 40 is closed, heating is stopped, and when the water temperature is lower than the lower limit water temperature, the air source heat pump 40 is opened again, and heating is continued. So as to reciprocate, thereby maintaining the water level and the water temperature in the warming device 20. Further, the upper limit temperature of the water in the heat-preserving bucket is less than or equal to the preset temperature.

The solar water heater control system 100 can enlarge the storage capacity of the solar water heater (at least 5-8 times enlarged compared with the traditional solar water heater) by using the heat preservation device, thereby meeting the water demand of large families and residents, and can fully utilize solar energy resources while avoiding the phenomenon of pipe explosion by designing the pipeline which stores and replenishes water; in addition, the air source heat pump can avoid the failure of the solar water heater in winter or rainy days, thereby ensuring the hot water supply of residents. The control system can be controlled by one controller, so that the control concentration ratio is improved, and the inconvenience caused by the spliced control of the traditional solar water heater is avoided.

In an exemplary embodiment, as shown in fig. 1, a second pipeline 21 for supplying hot water to the outside is further connected to the heat retaining device 20, and a hot water pressurizing pump 201 is provided on the second pipeline 21 for pressurizing the hot water in the second pipeline 21. Specifically, the hot water pressure pump 201 is disposed at a position where the second pipeline 21 is close to an external hot water faucet, when water in the solar water heater 10 reaches a preset temperature, hot water flows through a valve of the hot water pressure pump 201, and the hot water pressure pump 201 can be automatically started to pressurize the hot water in the second pipeline 21, so that a hot water spraying effect at a water outlet of the hot water faucet is improved.

Further, with reference to fig. 1, the control system 100 further includes a return line 22, one end of the return line 22 is connected to the water outlet end of the hot water pressure pump 201, the other end of the return line is connected to the heat preservation device 20, a return solenoid valve 221 is disposed on the return line 22, and the return solenoid valve 221 is connected to the controller, and is controlled by the controller to be opened when the hot water pressure pump 201 is started, and is closed after a second preset time. Because when in actual use, hot water pipeline often has a very long distance to tap, and the hot water in the pipeline can be cold because of the ambient temperature influence, and the user can wait for a long period of time to have put cold water hot water and just can come, brings inconveniently for the use. Therefore, by adding a return line at the water outlet end of the hot water pressure pump 201, most of the second pipeline 21 can be preheated by hot water, then the cooled hot water can quickly flow back to the heat preservation device 20 through the return line 22 under the pressure action of the hot water pressure pump 201, and finally the return solenoid valve 221 is closed after a second preset time, so that the preheating effect of the second pipeline 21 is achieved, and the hot water output from the heat preservation device 20 can not be cooled due to the temperature reduction of the external pipeline, thereby greatly saving the waiting time of the hot water and simultaneously playing a role in saving water. Furthermore, the second preset time is 5-10 s, which is favorable for balancing the prevention of the cold of the hot water and the quick use of the hot water.

In an exemplary embodiment, the hot water pressurizing pump 201 is connected to the controller, and as shown in fig. 1, the control system 100 further includes a flow meter 202, and the flow meter 202 is disposed on the second pipe 21 and connected to the controller to control the power supply of the hot water pressurizing pump 201 to be self-locked by the controller when the hot water flows through the flow meter 202. Because the traditional solar water heater can not well control the small-flow hot water, the phenomena of sudden cooling and sudden heating are easy to occur. Therefore, by adding a flow meter 202 to the second pipe 21, it is possible to easily determine whether or not hot water flows through the second pipe 21. Preferably, the flow meter 202 is provided between the external hot water tap and the hot water pressurizing pump 201. When the flowmeter 202 detects that hot water flows through, the controller controls the power supply of the hot water pressurizing pump 201 to be self-locked, so that the hot water pressurizing pump 201 is kept in an open state, and the situation that the hot water pressurizing pump 201 is powered off and closed due to the fact that a pressure valve of the hot water pressurizing pump 201 is closed due to small flow is avoided. In this way, the hot water pressurizing pump 201 can be powered off and turned off only when the faucet is completely turned off (i.e. when no hot water flows through the flow meter 202), so that the use experience of small flow hot water is ensured.

In an exemplary embodiment, the control system 100 further comprises a cold water delivery device (not shown) connected to the second pipe 21 for delivering cold water to the second pipe to be mixed with the hot water in the second pipe 21 to achieve the user desired water temperature. Specifically, the cold water conveying device can comprise a water storage tank for storing cold water; and a cold water pipeline, one end of which is connected with the reservoir and the other end of which is connected with the second pipeline 21, wherein a cold water pressure pump is arranged on the cold water pipeline and is used for pumping cold water in the reservoir into the second pipeline 21 by pressure. In another embodiment, the cold water line has two ports, one of which is connectable to the second line 21 and the other of which is connectable to a cold water tap to facilitate use of the cold water in the reservoir.

In an exemplary embodiment, as shown in fig. 1, the solar water heater 10 has two or more, so as to meet the water storage requirement of the large-capacity thermal insulation device 20 as much as possible. Specifically, two adjacent solar water heaters 10 may be communicated with each other through a pipeline, and the first water replenishing pipeline 31 may also have a plurality of pipelines respectively connected to the pipelines between the adjacent solar water heaters 10.

In another embodiment, the control system 100 further comprises a communication module, thereby facilitating remote control and alarm of the mobile phone of the operator. In addition, the control system 100 may also be provided with a touch screen to implement touch screen control.

The application also provides a control method of the solar water heater control system 100. As shown in fig. 2, the control method includes the steps of:

s100, detecting the water temperature in the solar water heater 10.

Specifically, a temperature sensor may be provided in the solar water heater 10 for detection.

S200, if the water temperature reaches a preset value, opening the first electromagnetic valve 111 and the second electromagnetic valve 311, closing the third electromagnetic valve 321, enabling the solar water heater 10 to convey hot water to the heat preservation device 20 through the first pipeline 11, and enabling the water supplementing device 30 to supplement water to the solar water heater 10 through the first water supplementing pipeline 31, and executing the step S300; if the water temperature is continuously lower than the preset value within the first preset time, the first electromagnetic valve 111 and the second electromagnetic valve 311 are closed, the third electromagnetic valve 321 and the air source heat pump 40 are opened, the water replenishing device 40 replenishes water to the heat preservation device 20 through the second water replenishing pipeline 32, and the air source heat pump 40 heats water in the heat preservation device 30, and step S500 is executed.

For example, when the external sunlight is sufficient, the water temperature is easy to reach the preset value, and at this time, the first electromagnetic valve 111 and the second electromagnetic valve 311 are opened, and the third electromagnetic valve 321 is closed, so that the hot water in the solar water heater 10 can be stored in the heat preservation device; when the external sunlight is continuously insufficient and the water temperature cannot reach the preset value all the time, the first electromagnetic valve 111 and the second electromagnetic valve 311 are closed, the third electromagnetic valve 321 and the air source heat pump 40 are opened, so that the water in the heat preservation device 20 can be rapidly heated and the water in the heat preservation device 20 can be maintained at a certain water volume, and the hot water supply is guaranteed.

And S300, detecting the water level in the heat preservation device 20.

And S400, if the water level reaches a preset value, closing the first electromagnetic valve 111 and the second electromagnetic valve 311.

In this way, the control system 100 is prevented from being affected by excessive water in the thermal insulation device 20.

S500, detecting the water level and the water temperature in the heat preservation device 20.

And S600, if the water level and/or the water temperature reach respective preset values, closing the third electromagnetic valve 321 and/or the air source heat pump 40.

In this way, the control system 100 can be prevented from being affected by too high water temperature or too much water in the heat preservation device 20.

In the control method of the solar water heater control system 100, the storage capacity of the solar water heater 10 can be significantly increased by transferring the hot water in the solar water heater 10 to the heat preservation device 20 for storage, so as to meet the water demand of large families and social residents; moreover, the water can be replenished while storing by controlling the opening and closing of the electromagnetic valve, and the solar energy resource can be fully utilized while the pipe explosion phenomenon is avoided; in addition, the air source heat pump 40 can prevent the solar water heater 10 from being out of service in winter or rainy days, thereby ensuring the hot water supply of residents.

The solar water heater has better universality, greatly expands the functions and the application range of the solar water heater, is suitable for remote rural areas and busy cities, and has wide application prospect.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.