CN205372998U - Complementary water heater of scene - Google Patents

Abstract

The utility model discloses a wind-solar complementary water heater, which comprises a water storage device, a support for elevating the water storage device, a heat collecting tube, an electric heating element, a wind power generator, a control box and a group of sensors. The control box includes a core controller, the first relay, the second relay, the third relay, the AC/DC conversion module and the storage battery, etc., the core controller controls the three relays respectively to select the wind and light hybrid water heater, wind and no light, The four working states of no wind and light and no wind and no light can automatically switch various working states according to the weather conditions to ensure that users can use hot water under different weather conditions, effectively solving the problem of traditional solar energy. Disadvantages of water heaters.

Description

A wind-solar complementary water heater

technical field

The utility model relates to a water heater, in particular to a wind-solar complementary water heater.

Background technique

With the development of science and technology, the application of new energy is more and more extensive. The application of solar water heater is born under the strong market demand. Its birth facilitates people's life. Its working environment is simple. The water in the water heater is heated through the heat collecting tube for users to use. However, the weather is changeable, and the solar water heater loses its advantages in the weather with insufficient sunlight. In this case, the user will not be able to use the hot water in the water heater. caused great inconvenience.

In this case, the lack of sunlight is often due to the influence of cold air or typhoons. Such weather is prone to wind, especially in coastal areas, where wind energy is more abundant. If wind energy can be applied to water heaters, it is planned to supplement The defect that the solar water heater is limited by the weather is eliminated.

At present, there is a solar wind energy water heater with patent number ZL200720186059.X. The water heater includes a wind power generation system, a solar battery, a storage battery, a connecting rod and a water heater. The bottom end of the water heater is fixedly connected to the water heater. Both the wind power generation system and the solar battery are connected to the battery located inside the connecting rod. The wind power generation system consists of a set of fan blades and a generator. The fan blades are installed on the main shaft of the generator in a horizontal state. It is 3/4 spherical. Due to the 3/4 spherical blades, the wind power generation system can also generate electricity under the condition of breeze. The wind power generation system and solar cells are combined to charge the battery, and the battery provides electric energy to the water heater to heat the water. Effect.

The solar water heater described above can effectively solve the unsatisfactory problem of the hot water provided by the existing solar water heaters. At present, almost every household in most areas has installed solar water heaters. If the above-mentioned solar water heaters are used, then The user needs to eliminate the original geothermal water heater, which will cause a waste of cost and resources for the user. Moreover, the original water heater must be removed during installation, which is time-consuming and labor-intensive; moreover, a 1kW solar panel can generate electricity for one day The temperature is about 4 degrees. In the case of only sunshine and no wind, it is difficult to heat the water only by generating electricity from solar panels. The use effect is not as good as that of heat collectors, and the area of 1kW solar panels has reached 6 square meters. Left and right, if a higher power solar panel is used, the area of the panel will be larger and it will be more difficult to install.

Utility model content

Purpose of the utility model: In order to overcome the deficiencies in the prior art, the utility model provides a wind-solar complementary water heater, which is simple in structure, easy to use, suitable for popularization and use, and solves the drawbacks of traditional solar water heaters limited by weather.

Technical solution: In order to achieve the above purpose, the wind-solar complementary water heater of the utility model includes a water storage, a bracket for overhead the water storage, a heat collecting tube, an electric heating element, a wind power generator, a control box and a set of sensors. The heat collecting tube is placed on the outer surface of the bracket, the control box is placed inside the bracket, the electric heating element is placed inside the water storage, and the wind generator is placed on the top side of the water storage , the sensor includes a wind speed sensor and a light sensor, the wind speed sensor and the light sensor are placed on the other side of the top of the water storage;

The control box includes a core controller, a first relay, a second relay, a third relay, an AC/DC conversion module, a storage battery, a wind power generator interface, a wind speed sensor interface, a light sensor interface, a lower liquid level sensor interface, and a temperature sensor interface and electric heating element interface, wherein the wind speed sensor interface, light sensor interface, lower liquid level sensor interface and temperature sensor interface are all electrically connected to the core controller, and the core controller is respectively connected to the first relay, The second relay and the third relay are electrically connected, the interface of the wind power generator is respectively connected to the first relay and the second relay by wires, the first relay is connected to the interface of the electric heating element by wires, and the first relay is connected to the interface of the electric heating element by wires. A transformer is connected between a relay and the interface of the heating element, and the second relay is connected to the interface of the heating element through the AC/DC conversion module, the storage battery and the third relay in sequence;

The wind power generator is connected to the control box through the wind power generator interface, the electric heating element is connected to the control box through the electric heating element interface, and the wind speed sensor is connected to the control box through the wind speed sensor interface. The light sensor is connected to the control box through the light sensor interface.

Further, the sensor includes a lower liquid level sensor and a temperature sensor, the lower liquid level sensor is placed on the bottom side of the inside of the water storage, and the temperature sensor is placed on the top side of the inside of the water storage. side, the lower liquid level sensor is connected to the control box through the lower liquid level sensor interface, and the temperature sensor is connected to the control box through the temperature sensor interface; the current liquid level sensor detects When the water in the water is lower than the minimum liquid level, it is necessary to stop the power supply to the heating element at this time to protect the heating element. The core controller controls the first relay to be disconnected, so that the wind turbine does not supply power to the heating element. At the same time, the core controller Control the third relay to be disconnected, so that the battery does not supply power to the heating element, thereby cutting off the power supply to the heating element, thereby protecting the heating element. In the above situation, if there is wind, the core controller should control the second relay to close and work, wind power generation The generator works and stores the generated power in the battery through the AC/DC conversion module;

When the temperature sensor detects that the water temperature in the water reservoir has reached the usage requirement, the electric heating element is not needed to heat the water at this time, and the core controller controls the first relay to be disconnected, so that the wind turbine does not supply power to the electric heating element, and at the same time the core controller Control the third relay to be disconnected, so that the battery does not supply power to the heating element. In the above situation, if there is wind, the core controller should control the second relay to close and work, and the wind power generator will generate electricity through the AC/DC conversion module stored in the battery.

Further, a water inlet is provided on the upper side of one end of the water storage, and a water outlet is provided on the lower side of one end of the water storage.

Further, an air outlet is provided above the top of the water storage near the water inlet.

Further, the control box includes a capacitance compensation module, and the capacitance compensation module is placed between the transformer and the first relay; the wind power generator system is affected by the wind speed, and the power of the generated electricity fluctuates. When the machine directly supplies power to the heating element, it will affect the service life of the heating element. In order to avoid this situation, a capacitance compensation module is added between the transformer and the first relay to keep the electric power in a stable state.

Beneficial effects: compared with the prior art, the utility model has the following advantages:

1. The utility model can automatically switch the heating mode according to the weather conditions to ensure that users can use hot water under different weather conditions, and has strong weather adaptability, which solves the disadvantages of traditional solar water heaters limited by the weather;

2. The utility model can switch the working mode to store the electricity generated by the wind power generator system in the battery when the water temperature meets the requirements, which is more energy-saving;

3. The utility model has good interchangeability, can be applied to traditional solar water heaters, and will not cause economical waste of cost and resources;

4. The utility model is simple in structure, easy to use, and suitable for popularization and use.

Description of drawings

Fig. 1 is a structural schematic diagram of a wind-solar hybrid water heater of the present invention.

Fig. 2 is a structural schematic diagram of a control box of a wind-solar hybrid water heater.

Fig. 3 is a flow chart of the steps of the method for implementing the wind-solar hybrid water heater.

detailed description

Below in conjunction with accompanying drawing, the utility model is described further.

As shown in Figure 1, a wind-solar hybrid water heater proposed by the utility model includes a water storage device 1, a support 2 for overhead the water storage device 1, a heat collecting tube 3, an electric heating element 4, a wind generator 5, a control Box 6 and a set of sensors, the upper side of one end of the water storage 1 is provided with a water inlet 11, the lower side of one end of the water storage 1 is provided with a water outlet 12, and the top of the water storage 1 is close to the water inlet 11 There is an exhaust port 13 on one side of the upper side, the heat collecting tube 3 is placed on the outer surface of the support 2, the control box 6 is placed inside the support 2, and the electric heating element 4 is placed in the water storage 1, the wind generator 5 is placed on the top side of the water storage 1, and the sensors include a wind speed sensor 7 and a light sensor 8, and the wind speed sensor 7 and light sensor 8 are placed in the water storage 1 On the other side of the top, the sensor includes a lower liquid level sensor 9 and a temperature sensor 10, the lower liquid level sensor 9 is placed on the bottom side of the water storage 1, and the temperature sensor 10 is placed on the The top side of the interior of the water storage device 1;

The water storage 1 is mainly used for water storage, the water inlet 11 is to add cold water to the water storage 1, the water outlet 12 is to discharge the hot water in the water storage 1 for use by users, and the exhaust port 13 is to Discharge the hot air in the water storage when heating;

Both the heat collecting tube 3 and the electric heating element 4 are used to heat the water in the water storage 1, and the heat collecting tube 3 converts solar energy into thermal energy to achieve the effect of heating water; the electric heating element 4 is installed inside the water storage 1, It converts the received electric energy into heat energy to achieve the effect of heating water;

The wind-driven generator 5 is installed on the upper end of the water storage 1, and the wind-driven generator 5 is controlled by the control box 6. On the one hand, the electricity generated by the wind-driven generator 5 can directly supply power to the electric heating element 4, and the electric heating element directly heats the water. On the one hand, the generated electricity can charge the storage battery, and store the generated power in the storage battery;

The wind speed sensor 7 is installed on the top of the water storage 1, and is mainly used to detect the wind speed and transmit the data to the control box 6;

The light sensor 8 is also installed on the top of the water storage 1, which is mainly used to detect the light intensity and transmit the data to the control box 6;

The lower liquid level sensor 9 is installed inside the water storage 1 to detect the liquid level in the water storage 1 and transmit the data to the control box 6;

As shown in Figure 2, the control box 6 is installed at the rear end of the heat collecting tube 3, and the control box 6 includes a core controller 600, a first relay 601, a second relay 602, a third relay 603, an AC/DC conversion Module 604, storage battery 605, wind power generator interface 606, wind speed sensor interface 607, light sensor interface 608, lower liquid level sensor interface 609, temperature sensor interface 610 and electric heating element interface 611, wherein the wind speed sensor interface 607, light sensor interface 608, the lower liquid level sensor interface 609 and the temperature sensor interface 610 are all electrically connected to the core controller 600, and the core controller 600 is respectively connected to the first relay 601, the second relay 602 and the third relay 603 Electrically connected, the wind power generator interface 606 is respectively connected to the first relay 601 and the second relay 602 by wires, the first relay 601 is connected to the electric heating element interface 611 by wires, and the first relay 601 A transformer 612 is connected to the heating element interface 611, and the second relay 602 is connected to the heating element interface 611 through the AC/DC conversion module 604, the storage battery 605 and the third relay 603 in sequence. The DC conversion module 604 converts the AC current generated by the wind power generator into a DC current so as to be stored in the storage battery 605;

The wind power generator 5 is connected to the control box 6 through the wind power generator interface 606, the electric heating element 4 is connected to the control box 6 through the electric heating element interface 611, and the wind speed sensor 7 is connected to the control box 6 through the electric heating element interface 611. The wind speed sensor interface 607 is connected to the control box 6, the light sensor 8 is connected to the control box 6 through the light sensor interface 608, and the lower liquid level sensor 9 is connected to the control box 6 through the lower liquid level sensor interface 609. The control box 6 is connected, and the temperature sensor 10 is connected to the control box 6 through the temperature sensor interface 610 . The control box 6 includes a capacitance compensation module 613, and the capacitance compensation module 613 is placed between the transformer 612 and the first relay 601. The above-mentioned core controller 600 is the core of the entire control box, and controls the first relay 601, the second The second relay 602 and the third relay 603 are used to select the working state of the wind power generator;

The wind speed sensor detects the wind speed, and the light sensor detects the light intensity. The wind speed sensor and the light sensor respectively transmit the collected data to the control box. The control box judges which method to use for water heating according to the received data. The water heating methods include:

The electric heating element converts electrical energy into thermal energy, thus heating the water;

There are two ways of how the heating element obtains electric energy:

One is that the wind generator works to generate electricity to directly supply power to the electric heating element, and the other is to supply power to the electric heating element by the battery;

The heat collecting tube directly converts the solar energy into heat energy, thereby heating the water;

When there is wind, the wind generator works to generate electricity. The wind generator can not only supply power to the heating element, but also charge the battery. The final choice of whether to supply power to the heating element or to charge the battery is realized through the core controller to control the relays. of;

Specifically: use the core controller to select the four working states of the wind-solar hybrid water heater;

1. When the wind speed reaches the minimum requirement for wind turbine power generation, and the light intensity cannot meet the requirements, that is, when there is wind and no light, the electric heating element is needed to heat the water, and the wind turbine works to generate electricity. The core controller controls the first relay to close and work. Thus, the wind generator supplies power to the electric heating element, and the electric heating element is directly powered by the wind turbine to heat the water;

2. If the light intensity can meet the requirements and the wind speed does not meet the minimum requirements for wind turbine power generation, that is, when there is light and no wind, the heat collecting tube can be used to heat the water at this time, and the water in the water storage will be converted into solar energy by the heat collecting tube Afterheating for thermal energy;

3. If the wind speed meets the minimum requirements for wind power generator power generation, and the light intensity can meet the requirements, that is, when there is wind and light, the heat collecting tube can be used to heat the water at this time, and the water in the water storage will be converted into solar energy by the heat collecting tube. After heat energy is heated, at the same time, the wind generator is also working to generate electricity. The core controller controls the second relay to close and work, so that the wind generator works and stores the generated electricity in the battery through the AC/DC conversion module;

4. If the wind speed does not meet the minimum requirements for wind turbine power generation, and the light intensity cannot meet the requirements, that is, when there is no wind and no light, the electric heating element is required to heat the water, and the battery is required to supply power to the electric heating element. The core controller controls The third relay is closed to work, so that the battery supplies power to the electric heating element, and the electric heating element heats the water;

When the lower liquid level sensor detects that the water in the water reservoir is lower than the minimum liquid level, it is necessary to stop supplying power to the heating element to protect the heating element. The core controller controls the first relay to be disconnected, so that the wind turbine Do not supply power to the heating element, and at the same time, the core controller controls the third relay to disconnect, so that the battery does not supply power to the heating element, thereby cutting off the power supply to the heating element, thereby protecting the heating element. In the above situation, if there is wind, the core should control The controller controls the second relay to close and work, and the wind generator works to store the generated electricity in the battery through the AC/DC conversion module;

When the temperature sensor detects that the water temperature in the water reservoir has reached the usage requirement, the electric heating element is not needed to heat the water at this time, and the core controller controls the first relay to be disconnected, so that the wind turbine does not supply power to the electric heating element, and at the same time the core controller Control the third relay to be disconnected, so that the battery does not supply power to the heating element. In the above situation, if there is wind, the core controller should control the second relay to close and work, and the wind power generator will generate electricity through the AC/DC conversion module stored in accumulators;

The wind power generator system is affected by the wind speed, and the power of the generated electricity fluctuates. When the wind generator directly supplies power to the heating element, it will affect the service life of the heating element. In order to avoid this situation, the transformer and the first A capacitor compensation module is added between the relays to keep the electric power in a stable state.

To sum up, the realization method of the wind-solar hybrid water heater proposed by the utility model, as shown in Figure 3, includes the following steps:

S1 The wind speed sensor 7 and the illumination sensor 8 collect data respectively, and transmit the collected data to the core controller 600;

The core controller 600 of S2 judges according to the collected data whether the wind speed meets the minimum requirements for generating electricity by the wind turbine 5 and whether the light intensity meets the requirements of the heat collecting tube 3; If the requirements of the heat pipe 3 are met, enter S3; if the wind speed reaches the minimum requirement of wind turbine 5 for power generation, and the light intensity cannot meet the requirements of heat collector 3, then enter S4; if the wind speed does not meet the minimum requirement of wind turbine 5 for power generation, If the intensity meets the requirements of the heat collecting tube 3, go to S5; if the wind speed does not meet the minimum requirement of wind power generator 5 for power generation, and the light intensity cannot meet the requirements of the heat collecting tube 3, go to S6;

S3 The heat collector 3 converts solar energy into thermal energy to heat water, while the wind generator 5 works to generate electricity and the core controller 600 controls the second relay 602 to close and work, so that the wind generator 5 converts the electric energy stored in the storage battery 605 through the AC/DC conversion module 604;

S4 The wind generator 5 works to generate power and the core controller 600 controls the first relay 601 to close and work, so that the wind generator 5 directly supplies power to the electric heating element 4, and the electric heating element 4 converts electric energy heating water for thermal energy;

The heat collecting tube 3 of S5 converts solar energy into thermal energy so as to heat water;

S6 The core controller 600 controls the third relay 603 to close and work, the storage battery 605 supplies power to the electric heating element 4, and the electric heating element 4 converts electric energy into thermal energy to heat water.

The above is only a preferred embodiment of the utility model, it should be pointed out that for those skilled in the art, without departing from the principle of the utility model, some improvements and modifications can also be made, these improvements and modifications It should also be regarded as the protection scope of the present utility model.

Claims (5)

1. A wind-solar complementary water heater, characterized in that: it comprises a water storage device (1), a support (2) for overhead the water storage device (1), a heat collecting tube (3), an electric heating element (4), a wind power generator (5), control box (6) and a set of sensors, the heat collecting tube (3) is placed on the outer surface of the support (2), and the control box (6) is placed inside the support (2) , the electric heating element (4) is placed inside the water storage (1), the wind generator (5) is placed on the top side of the water storage (1), and the sensor includes a wind speed sensor (7 ) and light sensor (8), the wind speed sensor (7) and light sensor (8) are placed on the other side of the top of the water reservoir (1); The control box (6) includes a core controller (600), a first relay (601), a second relay (602), a third relay (603), an AC/DC conversion module (604), a storage battery (605), Wind power generator interface (606), wind speed sensor interface (607), light sensor interface (608), lower liquid level sensor interface (609), temperature sensor interface (610) and electric heating element interface (611), wherein the wind speed sensor The interface (607), the light sensor interface (608), the lower liquid level sensor interface (609) and the temperature sensor interface (610) are all electrically connected to the core controller (600), and the core controller (600) is respectively It is electrically connected with the first relay (601), the second relay (602) and the third relay (603), and the wind power generator interface (606) is respectively connected with the first relay (601) and the second relay (602) connected by electric wires, the first relay (601) is connected to the electric heating element interface (611) by electric wires, and a transformer is connected between the first relay (601) and the electric heating element interface (611) (612), the second relay (602) is sequentially connected to the electric heating element interface (611) through the AC/DC conversion module (604), the storage battery (605) and the third relay (603); The wind power generator (5) is connected to the control box (6) through the wind power generator interface (606), and the electric heating element (4) is connected to the control box ( 6) connection, the wind speed sensor (7) is connected to the control box (6) through the wind speed sensor interface (607), and the light sensor (8) is connected to the control box through the light sensor interface (608) Box (6) is connected. 2. The wind-solar hybrid water heater according to claim 1, characterized in that: the sensor includes a lower liquid level sensor (9) and a temperature sensor (10), and the lower liquid level sensor (9) is placed in the water storage The bottom side of the interior of the water tank (1), the temperature sensor (10) is placed on the top side of the interior of the water storage (1), and the lower liquid level sensor (9) passes through the lower liquid level sensor The interface (609) is connected with the control box (6), and the temperature sensor (10) is connected with the control box (6) through the temperature sensor interface (610). 3. The wind-solar hybrid water heater according to claim 1 or 2, characterized in that: a water inlet (11) is provided on the upper side of one end of the water storage (1), and a water inlet (11) is provided on the lower side of one end of the water storage (1). There is a water outlet (12). 4. The wind-solar hybrid water heater according to claim 3, characterized in that an air outlet (13) is provided above the top of the water storage (1) near the water inlet (11). 5. The wind-solar hybrid water heater according to claim 1, characterized in that: the control box (6) includes a capacitance compensation module (613), and the capacitance compensation module (613) is placed between the transformer (612) and the second Between one relay (601).