CN217876071U - Indoor temperature regulating system - Google Patents

Abstract

The application discloses indoor temperature governing system, this system is including setting gradually in heat accumulation wall body and the porous solar wall in the building envelope outside. A cold air chamber is arranged between the building enclosure structure and the heat storage wall body. The air inlet of the cold air chamber is communicated with the interior of the basement through an underground air channel, and the air outlet of the cold air chamber is communicated with the outside through an air exhaust channel. A hot air chamber is arranged between the heat storage wall body and the porous solar wall. The hot air chamber is communicated with the interior of the building envelope structure through a hot air channel. An underground air inlet fan is arranged in the underground air channel. An air outlet machine is arranged in the air exhaust channel. A warm air inlet machine is arranged in the hot air channel. The detection assembly includes a thermometer. The control assembly includes a controller. The basement air inlet fan, the air outlet fan, the warm air inlet fan and the thermometer are electrically connected with the controller. Adopt this application to adjust indoor temperature among the prior art, and then lead to adjusting the problem that the energy that the cost is high and utilize among the accommodation process can not be palingenetic.

Description

Indoor temperature regulating system

Technical Field

The application belongs to the technical field of building energy conservation, and particularly relates to an indoor temperature adjusting system.

Background

In winter, the heating energy consumption in the north of China is an important part of the energy consumption of buildings, and the cold air infiltration heat load is also the main component of the heating load in winter. Among them, in the heating process, it is required that the building has good sealing property to prevent rapid loss of indoor heat. This results in insufficient fresh air in the winter and leads to poor air circulation in the building, which in turn causes the air quality in the building to be reduced. Meanwhile, in summer, the temperature of the surface of the building wall gradually rises under the long-term irradiation of the sun, and then the indoor temperature gradually rises. Therefore, there is a need for conditioning indoor environments to improve the comfort of residential environments.

At present, people often adopt equipment such as air conditioners or ventilation fans to adjust indoor environment. However, although the temperature in a room is mainly controlled by energy sources such as gas and electric energy, these energy sources have problems of high cost and non-renewable energy.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides an indoor temperature governing system, has solved and has consumed the non-renewable energy source to adjust indoor temperature among the prior art, and then leads to adjusting the energy that utilizes among the costly height and the accommodation process non-renewable problem.

In order to achieve the above object, an embodiment of the present invention provides an indoor temperature adjusting system, which includes a heat collecting and storing assembly, an air flow conveying assembly, a detecting assembly, and a control assembly.

The heat collection and storage component is arranged on the outer side of at least one layer of building envelope structure. The heat collection and heat storage component comprises a heat storage wall body and a porous solar wall which are arranged on the outer side of the building envelope structure in sequence.

A cold air chamber is arranged between the building envelope and the heat storage wall. The air inlet of the cold air chamber is communicated with the interior of the basement through an underground air channel, and the air outlet of the cold air chamber is communicated with the outside through an air exhaust channel.

A hot air chamber is arranged between the heat storage wall body and the porous solar wall. The hot air chamber is communicated with the interior of the building envelope structure through a hot air channel.

The airflow conveying assembly comprises a basement air inlet fan, an air outlet fan and a warm air inlet fan.

And a basement air inlet machine is arranged in the basement air channel. An air outlet machine is arranged in the air exhaust channel. A warm air inlet machine is arranged in the hot air channel.

The detection assembly includes a thermometer disposed on the building envelope. The control assembly includes a controller.

The basement air inlet machine, the air outlet machine, the warm air inlet machine and the thermometer are electrically connected with the controller.

With reference to the first aspect, in one possible implementation manner, the system further includes a hot water storage tank.

And a water supply pipeline is arranged in the heat storage wall body. The water inlet of the water supply pipeline is connected with a water source, and the water outlet of the water supply pipeline is connected with the water inlet of the heat storage water tank. The water outlet of the heat storage water tank is connected with the water inlet of the domestic water pipeline of the user.

With reference to the first aspect, in one possible implementation manner, the system further includes a heating pipeline.

The control assembly also includes an electrically operated three-way valve electrically connected to the controller.

The water inlet of the electric three-way valve is connected with the water outlet of the heat storage water tank, the first water outlet of the electric three-way valve is connected with the first water inlet of the heating pipeline, and the second water outlet of the electric three-way valve is connected with the water inlet of the heating furnace. The water outlet of the heating furnace is connected with the second water inlet of the heating pipeline.

Further, a black heat collecting layer is arranged on the outer surface of the porous solar wall.

With reference to the first aspect, in one possible implementation, the system further includes a gas filtering device disposed adjacent to the basement air intake fan.

The air filtering device is arranged at an air inlet of the air channel of the underground chamber.

The gas filtering device is electrically connected with the controller.

With reference to the first aspect, in one possible implementation manner, the system further includes a solar photovoltaic module disposed on the top of the building envelope.

The basement air inlet machine, the air outlet machine and the warm air inlet machine are electrically connected with the power output end of the solar photovoltaic module.

With reference to the first aspect, in a possible implementation manner, the power output end of the solar photovoltaic module is further connected to the power utilization input end of a user.

The embodiment of the utility model provides an in the one or more technical scheme that provide, have following technological effect or advantage at least:

the embodiment of the utility model provides an indoor temperature governing system, the heat that the thermal-arrest heat accumulation subassembly that this system set up through building envelope's the outside produced solar radiation is collected to provide the heat source for the building. Meanwhile, the temperature inside the building envelope is adjusted and controlled through the airflow conveying assembly. More recently, the porous solar wall absorbs heat generated by solar radiation, so that heat is generated in a hot air chamber between the porous solar wall and the heat storage wall, and at the moment, the heat storage wall stores part of the heat to prevent the heat from being greatly lost. Wherein, the cold air chamber between the heat storage wall and the building envelope is communicated with the interior of the basement. More closely, the airflow delivery assembly directs the air within each chamber and controls the temperature of the building interior structure.

Specifically, in cold winter, when the solar radiation condition is good, fresh air with low temperature enters the hot air chamber through the gap of the porous solar wall, and is collected in the hot air chamber and absorbs certain heat from the heat storage wall. At the moment, the controller controls the warm air inlet fan to be started, and fresh air with temperature enters the room through the hot air channel and the warm air inlet fan, so that the indoor air is improved, and the indoor temperature is increased.

In hot summer, fresh air with high temperature enters the hot air chamber through the gap of the porous solar wall, is collected in the hot air chamber, transmits part of heat to the heat storage wall, transmits the heat of the heat storage wall to the building enclosure structure under the action of heat conduction, and transmits the heat to the indoor through heat conduction and natural convection, so that the indoor cold load can be increased, and the temperature of the building maintenance structure is controlled through the automatic control system. The method comprises the following specific steps: the thermometer monitors the temperature on the building enclosure structure, when the temperature measured by the thermometer on the building enclosure structure is larger than a certain numerical value, the controller controls the opening of the basement air inlet machine and the air outlet machine, and introduces air with the bottom of the basement temperature into the cold air chamber, so that the wall body outside the building enclosure structure is cooled to ensure the indoor temperature. Adopt the utility model provides an among the prior art, consume can not palingenetic energy source to adjust indoor temperature, and then lead to adjusting the problem that the energy that utilizes in with high costs and the accommodation process can not palingenetic.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings used in the description of the embodiments will be briefly introduced below. It is obvious that the drawings in the following description are only some of the embodiments described in the present application, and that other drawings can be derived from these drawings by a person skilled in the art without inventive effort.

Fig. 1 is a connection diagram of an indoor temperature adjustment system according to an embodiment of the present invention.

Fig. 2 is a structural connection diagram of a heating pipeline according to an embodiment of the present invention.

Reference numerals are as follows: 100-a heat collection and storage component; 110-heat storage wall; 111-a cold blast chamber; 111 a-basement wind channel; 111 b-exhaust channel; 120-porous solar wall; 121-hot air chamber; 121 a-hot air channel; 200-an airflow delivery assembly; 210-basement air intake fan; 220-air outlet machine; 230-a warm air inlet fan; 300-a detection component; 310-a thermometer; 400-a control component; 410-a controller; 420-electric three-way valve; 421-water inlet; 422-a first water outlet; 423-a second water outlet; 500-building envelope; 600-a heat storage water tank; 700-heating pipe; 710-a heating furnace; 800-a gas filtration device; 900-user living water pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience of describing the embodiments of the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. The terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Furthermore, the terms "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the embodiments of the present invention can be understood by those skilled in the art according to specific situations.

As shown in fig. 1 and fig. 2, an indoor temperature adjusting system according to an embodiment of the present invention includes a heat collecting and storing assembly 100, an airflow conveying assembly 200, a detecting assembly 300, and a control assembly 400.

The heat collecting and accumulating assembly 100 is arranged outside at least one layer of building envelope 500. The heat collecting and storing assembly 100 comprises a heat storing wall 110 and a porous solar wall 120 which are sequentially arranged at the outer side of the building envelope 500.

A cold air chamber 111 is arranged between the building envelope 500 and the heat accumulation wall 110. An air inlet of the cold air chamber 111 is communicated with the interior of the basement through the basement air passage 111a, and an air outlet of the cold air chamber 111 is communicated with the outside through the air exhaust passage 111 b.

A hot air chamber 121 is arranged between the heat storage wall body 110 and the porous solar wall 120. The hot air chamber 121 communicates with the interior of the building envelope 500 through the hot air passage 121 a.

The airflow delivery assembly 200 includes a basement air intake fan 210, an air outlet fan 220, and a warm air intake fan 230.

A basement air inlet fan 210 is installed in the basement air passage 111 a. An air outlet machine 220 is installed in the air exhaust channel 111 b. A warm air inlet fan 230 is installed in the hot air passage 121 a.

The detection assembly 300 includes a thermometer 310 disposed on the building envelope 500. The control assembly 400 includes a controller 410.

The basement air inlet fan 210, the air outlet fan 220, the warm air inlet fan 230 and the thermometer 310 are electrically connected with the controller 410.

It should be noted that, the system collects heat generated by solar radiation through the heat collecting and storing assembly 100 arranged outside the building envelope 500, and provides a heat source for the building. At the same time, the temperature inside the building envelope 500 is regulated and controlled by the airflow delivery assembly 200. Further, the porous solar wall 120 absorbs heat generated by solar radiation, so that heat is generated in the hot air chamber 121 between the porous solar wall 120 and the heat storage wall 110, and at this time, the heat storage wall 110 stores part of the heat, so as to prevent the heat from being greatly lost. The cold air chamber 111 between the heat storage wall 110 and the building envelope 500 is communicated with the interior of the basement. Further, airflow delivery assembly 200 directs the air within each chamber and controls the temperature of the building interior.

Specifically, in cold winter, when the solar radiation condition is good, the fresh air with a lower temperature enters the hot air chamber 121 through the gap of the porous solar wall 120, and is collected in the hot air chamber 121 and absorbs a certain amount of heat from the heat storage wall 110. At this time, the controller 410 controls the warm air inlet fan 230 to be turned on, and fresh air with temperature enters the room through the hot air channel 121a and the warm air inlet fan 230, so that the indoor air is improved and the indoor temperature is increased.

In hot summer, the fresh air with higher temperature enters the hot air chamber 121 through the gap of the porous solar wall 120, and is collected in the hot air chamber 121 to transfer part of heat to the heat storage wall 110. The thermometer 310 monitors the temperature of the building envelope 500, and when the temperature of the building envelope 500 measured by the thermometer 310 is higher than a certain value, the controller 410 controls the opening of the basement air inlet fan 210 and the air outlet fan 220, and introduces air with lower basement temperature into the cold air chamber 111, so as to cool the wall outside the building envelope 500 to ensure the indoor temperature.

In addition, in rainy season or when the air humidity is high, the controller 410 controls the opening of the basement air inlet fan 210 and the air outlet fan 220, and conducts and dehumidifies the air in the basement to prevent the internal environment of the basement from dewing, so that on one hand, the basement air inlet fan 210 is prevented from being damaged due to the fact that the air flow contains large water drops, and on the other hand, the air in the basement is prevented from breeding mold.

Adopt the utility model provides an among the prior art, consume can not palingenetic energy source to adjust indoor temperature, and then lead to adjusting the problem that the energy that utilizes in with high costs and the accommodation process can not palingenetic.

Referring to fig. 1, in the present embodiment, the indoor temperature adjusting system further includes a hot water storage tank 600.

A water supply pipeline is arranged in the heat storage wall body 110. The water inlet of the water supply pipeline is connected with a water source, and the water outlet of the water supply pipeline is connected with the water inlet of the hot water storage tank 600. The water outlet of the hot water storage tank 600 is connected to the water inlet of the user living water pipeline 900.

It should be noted that a certain amount of heat is collected in the heat storage wall 110 to heat water in the water supply pipeline inside the heat storage wall 110, so as to provide a heat source for the user and provide hot water. And further reduces the energy consumption of the user when heating water, and achieves the purpose of saving cost.

Referring to fig. 2, further, the room temperature conditioner system further includes a heating pipe 700.

The control assembly 400 also includes an electric three-way valve 420 electrically connected to the controller 410.

A water inlet 421 of the electric three-way valve 420 is connected with a water outlet of the hot water storage tank 600, a first water outlet 422 of the electric three-way valve 420 is connected with a first water inlet of the heating pipeline 700, and a second water outlet 423 of the electric three-way valve 420 is connected with a water inlet of the heating furnace 710. The water outlet of the heating furnace 710 is connected with the second water inlet of the heating pipeline 700.

In winter, it is necessary to heat the indoor space. The water supply temperature of the radiant floor heating is 35-45 ℃, so that the heat collected by the heat storage wall body 110 can be used for heating.

Specifically, after the hot water in the hot water storage tank 600 is detected by the water temperature meter, when the detected value meets the heating requirement, the controller 410 controls the water inlet 421 of the electric three-way valve 420 and the first water outlet 422 of the electric three-way valve 420 to be opened, and the second water outlet 423 of the electric three-way valve 420 to be closed, so as to provide hot water for the heating pipeline 700; when the detected value does not meet the heating requirement, the controller 410 controls the water inlet 421 of the electric three-way valve 420 and the second water outlet 423 of the electric three-way valve 420 to be opened, and the first water outlet 422 of the electric three-way valve 420 to be closed. At this time, the heating furnace 710 further heats the hot water to ensure that the water temperature meets the water supply requirement, and then supplies the hot water to the heating pipeline 700. Compared with the prior art in which the cold water is directly heated to the temperature required by heating through the heating furnace 710, the system is energy-saving and environment-friendly.

Further, in the present embodiment, a black heat collecting layer is disposed on the outer surface of the porous solar wall 120.

It should be noted that the black collector layer can collect more solar radiation onto the porous solar wall 120.

With continued reference to fig. 1, in this embodiment, the indoor temperature conditioning system further includes a gas filtering device 800 disposed adjacent to the basement air inlet fan 210.

The air filter 800 is disposed at the air inlet of the basement air passage 111 a.

The gas filtering device 800 is electrically connected to the controller 410.

It should be noted that the gas filtering device 800 is used for filtering gas in the basement to prevent toxic gas such as automobile exhaust from being discharged into the atmosphere or the building envelope 500, which causes the problem of air pollution. In this embodiment, the indoor temperature adjusting system further comprises a solar photovoltaic module disposed on top of the building envelope 500.

The basement air inlet fan 210, the air outlet fan 220 and the warm air inlet fan 230 are electrically connected with the power output end of the solar photovoltaic module.

It should be noted that the solar photovoltaic module converts solar energy into required electric energy, and the electric energy is supplied to the basement air inlet fan 210, the air outlet fan 220, and the warm air inlet fan 230. Further, the utilization of solar energy is improved, so that the purposes of environmental protection and energy conservation are achieved.

Further, the power output end of the solar photovoltaic module is also connected with the power utilization input end of a user.

It should be noted that the electric energy converted by the solar photovoltaic module can be used by users for other purposes, so that the indoor temperature adjusting system is relatively more energy-saving and environment-friendly.

In the present embodiment, it is apparent to those skilled in the art that the present invention is not limited to the details of the above-described exemplary embodiments, but can be embodied in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (7)

1. An indoor temperature governing system which characterized in that: the system comprises a heat collection and storage component (100), an airflow conveying component (200), a detection component (300) and a control component (400);

the heat collection and storage component (100) is arranged on the outer side of at least one layer of building envelope (500); the heat collection and storage component (100) comprises a heat storage wall body (110) and a porous solar wall (120) which are arranged on the outer side of the building envelope (500) in sequence;

a cold air chamber (111) is arranged between the building enclosure structure (500) and the heat storage wall body (110); the air inlet of the cold air chamber (111) is communicated with the interior of the basement through an air passage (111 a) of the basement, and the air outlet of the cold air chamber (111) is communicated with the outside through an air exhaust passage (111 b);

a hot air chamber (121) is arranged between the heat storage wall body (110) and the porous solar wall (120); the hot air chamber (121) is communicated with the interior of the building envelope (500) through a hot air channel (121 a);

the airflow conveying assembly (200) comprises a basement air inlet machine (210), an air outlet machine (220) and a warm air inlet machine (230);

the basement air inlet fan (210) is installed in the basement air channel (111 a); the air outlet machine (220) is arranged in the air exhaust channel (111 b); the warm air inlet machine (230) is arranged in the hot air channel (121 a);

the detection assembly (300) comprises a thermometer (310) arranged on the building envelope (500); the control assembly (400) comprises a controller (410);

the basement air inlet fan (210), the air outlet fan (220), the warm air inlet fan (230) and the thermometer (310) are electrically connected with the controller (410).

2. The indoor temperature adjusting system according to claim 1, wherein: the device also comprises a heat storage water tank (600);

a water supply pipeline is arranged in the heat storage wall body (110); the water inlet of the water supply pipeline is connected with a water source, and the water outlet of the water supply pipeline is connected with the water inlet of the heat storage water tank (600); the water outlet of the heat storage water tank (600) is connected with the water inlet of the user living water pipeline (900).

3. The indoor temperature adjusting system according to claim 2, wherein: also comprises a heating pipeline (700);

the control assembly (400) further comprises an electric three-way valve (420) electrically connected to the controller (410);

a water inlet (421) of the electric three-way valve (420) is connected with a water outlet of the hot water storage tank (600), a first water outlet (422) of the electric three-way valve (420) is connected with a first water inlet of the heating pipeline (700), and a second water outlet (423) of the electric three-way valve (420) is connected with a water inlet of the heating furnace (710); and a water outlet of the heating furnace (710) is connected with a second water inlet of the heating pipeline (700).

4. The indoor temperature adjusting system according to any one of claims 1 to 3, wherein: and a black heat collecting layer is arranged on the outer surface of the porous solar wall (120).

5. The indoor temperature adjusting system according to claim 1, wherein: the device also comprises a gas filtering device (800) which is arranged close to the basement air inlet fan (210);

the gas filtering device (800) is arranged at an air inlet of the basement air channel (111 a);

the gas filtration device (800) is electrically connected to the controller (410).

6. The indoor temperature adjusting system according to claim 1, wherein: the solar photovoltaic module is arranged at the top of the building envelope (500);

the basement air inlet machine (210), the air outlet machine (220) and the warm air inlet machine (230) are electrically connected with the power output end of the solar photovoltaic module.

7. The indoor temperature adjusting system according to claim 6, wherein: and the power output end of the solar photovoltaic module is also connected with the power utilization input end of a user.

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