CN213783179U - Air circulation and humidification system of complementary power supply of environment self-adaptation scene - Google Patents

Abstract

The utility model discloses an environment self-adaptive wind-solar complementary power supply air circulation and humidification system, which mainly relates to the technical field of new energy; the air humidity monitoring device comprises a bus, wherein a wind generating set, a photovoltaic array, an air temperature monitor and an air humidity monitor are connected to the bus, the air temperature monitor is connected with a first circuit switch controller and a second circuit switch controller, the first circuit switch controller and the second circuit switch controller are both connected with an air conditioner, the air humidity monitor is connected with a third circuit switch controller and a fourth circuit switch controller, the third circuit switch controller is connected with a humidifier, and the fourth circuit switch controller is connected with a dehumidifier; the utility model discloses can be according to the operating condition of each equipment of people's needs automatically regulated, each equipment operating time of intelligent control reduces the energy extravagant, satisfies in people daily work and the study life requirement to air temperature and humidity, increases work efficiency.

Description

Air circulation and humidification system of complementary power supply of environment self-adaptation scene

Technical Field

The utility model relates to a new forms of energy technical field specifically is an air cycle and humidification system of complementary power supply of environment self-adaptation scene.

Background

At present, the living temperature of people can not be improved by an air conditioner, and the air conditioner is also suitable for hot summer and cold winter; in dry areas, the humidity of the air is seriously affecting people's health: when the Humidity of air is reduced to 40 RH% (RH), the nasal mucosa and respiratory tract mucosa are abnormally dried due to water loss, and bacteria are more easily attached to cause respiratory diseases, so that the humidifier has gradually become a part of human life.

In order to meet the requirements of people on indoor temperature and humidity, an air conditioner and a humidifier need to be equipped at the same time, in the prior art, the air conditioner and the humidifier are usually separated, and the following three defects can be caused by the mode:

firstly, the current power supply mode for an air conditioner and a humidifier mainly adopts thermal power generation, the cleaning technology of the thermal power generation is not mature enough, and a large amount of harmful gas can be generated;

secondly, the air conditioner and the humidifier are usually started when people feel untimely, which can cause the rapid change of the surrounding environment, thereby causing harm to the human body;

finally, people often forget to turn off both devices when leaving the work area, resulting in a waste of energy.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems in the prior art, and provides an environment self-adaptive wind-solar hybrid power supply air circulation and humidification system, which can automatically adjust the working state of each device according to the needs of people, intelligently control the working time of each device, reduce energy waste, meet the requirements of people on air temperature and humidity in daily work and study life, and increase the working efficiency; and wind and light complementary power supply is adopted, so that the emission of harmful gas is reduced, and the national green development call is responded.

The utility model discloses a realize above-mentioned purpose, realize through following technical scheme:

the air circulation and humidification system comprises a bus, wherein a wind generating set, a photovoltaic array, an air temperature monitor and an air humidity monitor are connected to the bus, the air temperature monitor is connected with a first circuit switch controller and a second circuit switch controller, the first circuit switch controller and the second circuit switch controller are both connected with an air conditioner, the first circuit switch controller controls heating of the air conditioner, the second circuit switch controller controls cooling of the air conditioner, the air humidity monitor is connected with a third circuit switch controller and a fourth circuit switch controller, the third circuit switch controller is connected with a humidifier, and the fourth circuit switch controller is connected with a dehumidifier.

Preferably, the bus bar is an alternating current bus bar.

Preferably, a first rectifier and a first inverter are connected between the wind generating set and the bus, and a second inverter is connected between the photovoltaic array and the bus.

Preferably, the bus is connected with a storage battery, an input end of the storage battery is connected with the bus through a second rectifier, and an output end of the storage battery is connected with the bus through a third inverter.

Preferably, the bus bar is connected with an unloader.

Contrast prior art, the beneficial effects of the utility model reside in that:

the utility model integrates the air conditioner, the dehumidifier and the humidifier into a system, and users can close and open the equipment without manual operation if the users have no special requirements; the utility model can greatly improve the life quality of people, ensure the room temperature to be constant at about 21 ℃ and the humidity to be about 60RH percent, and meet the health requirements of people; in the aspect of energy utilization, the wind energy and the solar energy are used as power generation sources, and wind-solar complementary power supply is adopted, so that the consumption of fossil fuel is reduced, the emission of harmful gas is reduced, and the national green development call is responded; the working state of each equipment can be automatically adjusted according to the needs of people, the working time of each equipment is intelligently controlled, the energy waste is reduced, the requirements on the air temperature and the humidity in daily work and study and life of people are met, and the working efficiency is improved.

Drawings

Fig. 1 is a schematic diagram of the system of the present invention.

The reference numbers in the drawings: 1. a bus bar; 2. a wind generating set; 3. a photovoltaic array; 4. an air temperature monitor; 5. an air humidity monitor; 6. a first circuit switch controller; 7. a second circuit switch controller; 8. a third circuit switch controller; 9. a fourth circuit switch controller; 10. a humidifier; 11. a dehumidifier; 12. a first rectifier; 13. a first inverter; 14. a second inverter; 15. a storage battery; 16. a second rectifier; 17. a third inverter; 18. an unloader.

Detailed Description

The present invention will be further described with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teachings of the present invention, and these equivalents also fall within the scope defined in the present application.

Example (b): as shown in the attached drawing 1, the utility model relates to an air circulation and humidification system of complementary power supply of environment self-adaptation scene, including the generating line 1, preferably, the generating line 1 is the interchange generating line. The photovoltaic air conditioning system is characterized in that the bus 1 is connected with a wind generating set 2, a photovoltaic array 3, an air temperature monitor 4 and an air humidity monitor 5, specifically, a first rectifier 12 and a first inverter 13 are connected between the wind generating set 2 and the bus 1, and a second inverter 14 is connected between the photovoltaic array 3 and the bus 1. The air temperature monitor 4 is connected with a first circuit switch controller 6 and a second circuit switch controller 7, the first circuit switch controller 6 and the second circuit switch controller 7 are both connected with an air conditioner, the first circuit switch controller 6 controls heating of the air conditioner, the second circuit switch controller 7 controls refrigeration of the air conditioner, the air humidity monitor 5 is connected with a third circuit switch controller 8 and a fourth circuit switch controller 9, the third circuit switch controller 8 is connected with a humidifier 10, and the fourth circuit switch controller 9 is connected with a dehumidifier 11.

Preferably, the bus 1 is connected with a storage battery 15, an input end of the storage battery 15 is connected with the bus 1 through a second rectifier 16, an output end of the storage battery 15 is connected with the bus 1 through a third inverter 17, and the storage battery 15 can be a lead-acid storage battery and used for storing electric energy.

Preferably, the bus bar 1 is connected with an unloader 18 for consuming excess electricity.

The utility model discloses an operation mode as follows:

firstly, alternating current generated by the wind generating set 2 firstly passes through the first rectifier 12 and then enters the first inverter 13 to be converged into the alternating current bus 1, direct current generated by the photovoltaic array 3 passes through the second inverter 14 to be converged into the alternating current bus 1, and two power generation devices provide electric energy required by the system;

secondly, the generated electric energy firstly meets the requirement of air temperature, the air temperature monitor 4 starts to work after power supply, when the room temperature is lower than 15 ℃, the first circuit switch controller 6 is closed, the second circuit switch controller 7 is opened, and the air conditioner heats to 21 ℃;

when the room temperature is higher than 26 ℃, the first circuit switch controller 6 is switched off, the second circuit switch controller 7 is switched on, and the air conditioner cools to 21 ℃;

the air humidity requirement is met after the air temperature requirement is met, the air humidity monitor 5 works, when the indoor air humidity is lower than 45 RH%, the third circuit switch controller 8 is closed, the fourth circuit switch controller 9 is disconnected, and at the moment, the humidifier 10 works to raise the air humidity to 60 RH%; when the indoor air humidity is higher than 75 RH%, the third circuit switch controller 8 is turned off, the fourth circuit switch controller 9 is turned on, and at this time, the dehumidifier 11 works to reduce the air humidity to 60 RH%;

if the excess electric quantity exists after the two devices are met, the excess electric quantity enters the storage battery 15 for storage, and when the electric quantity is insufficient, the storage battery 15 discharges electricity for energy supply; if the storage capacity of the storage battery 15 reaches the upper limit, the surplus capacity enters the unloader 18 to be consumed.

The utility model discloses a first circuit switch controller 6, second circuit switch controller 7, third circuit switch controller 8, fourth circuit switch controller 9 all install indoor to have according to the function of time control, set up operating time 8:00-24:00 daily, the user also can manually close this 4 controllers as required. In addition, the humidifier 10 may be directly connected to a building water pipe, and the water supply amount may be automatically set according to the remaining water amount of the humidifier 10.

The utility model integrates the air conditioner, the dehumidifier and the humidifier into a system, and users can close and open the equipment without manual operation if the users have no special requirements; the utility model can greatly improve the life quality of people, ensure the room temperature to be constant at about 21 ℃ and the humidity to be about 60RH percent, and meet the health requirements of people; in the aspect of the energy utilization, the utility model discloses a wind energy and solar energy are used to the electricity generation source, can reduce fossil fuel's consumption, respond the call of national green development.

Claims (5)

1. An air circulation and humidification system of complementary power supply of environment self-adaptation scene, characterized by: comprises a bus (1), wherein the bus (1) is connected with a wind generating set (2), a photovoltaic array (3), an air temperature monitor (4) and an air humidity monitor (5), the air temperature monitor (4) is connected with a first circuit switch controller (6) and a second circuit switch controller (7), the first circuit switch controller (6) and the second circuit switch controller (7) are both connected with an air conditioner, the first circuit switch controller (6) controls heating of the air conditioner, the second circuit switch controller (7) controls cooling of the air conditioner, the air humidity monitor (5) is connected with a third circuit switch controller (8) and a fourth circuit switch controller (9), the third circuit switch controller (8) is connected with a humidifier (10), and the fourth circuit switch controller (9) is connected with a dehumidifier (11).

2. The environment-adaptive wind-solar hybrid power supply air circulation and humidification system according to claim 1, wherein: the bus (1) is an alternating current bus.

3. The environment-adaptive wind-solar hybrid power supply air circulation and humidification system according to claim 2, wherein: a first rectifier (12) and a first inverter (13) are connected between the wind generating set (2) and the bus (1), and a second inverter (14) is connected between the photovoltaic array (3) and the bus (1).

4. The environment-adaptive wind-solar hybrid power supply air circulation and humidification system according to claim 2, wherein: the bus (1) is connected with a storage battery (15), the input end of the storage battery (15) is connected with the bus (1) through a second rectifier (16), and the output end of the storage battery (15) is connected with the bus (1) through a third inverter (17).

5. The environment adaptive wind-solar hybrid power supply air circulation and humidification system according to claim 1 or 2, wherein: the bus (1) is connected with an unloader (18).

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