CN110158795B

CN110158795B - Building temperature adjusting method

Info

Publication number: CN110158795B
Application number: CN201910421428.6A
Authority: CN
Inventors: 刘一平; 曹紫娟
Original assignee: Shenzhen Yiruikang Technology Co ltd
Current assignee: Shenzhen Yiruikang Technology Co ltd
Priority date: 2019-05-21
Filing date: 2019-05-21
Publication date: 2021-03-02
Anticipated expiration: 2039-05-21
Also published as: CN110158795A

Abstract

The invention belongs to the technical field of building temperature regulation, and particularly relates to a building temperature regulation method, which can regulate the indoor temperature by regulating the direction of air flow and prevent a large amount of heat from being absorbed or lost due to outdoor climate change or temperature difference; the first air port, the second air port, the third air port and the fourth air port are arranged on the first wall body of the heat insulation house located on the sunny side, the fifth air port, the sixth air port, the seventh air port and the eighth air port are arranged on the second wall body of the shady side and communicated through the first ventilation cavity, and therefore the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port can be adjusted according to the external climate, the temperature and the weather, the opening and closing of the seventh air port and the eighth air port can be controlled, the flowing direction of cold and hot air flow can be controlled, and the temperature adjustment and the ventilation can be effectively achieved on the inside of the house.

Description

Building temperature adjusting method

Technical Field

The invention belongs to the technical field of building temperature regulation, and particularly relates to a building temperature regulation method.

Background

The house is a building for people or storing things and is a base body for production and life of people. The house building has various forms according to different use requirements of people. In the house used for living, people need the house to have a good shielding waterproof function, and need the house to have a good ventilation structure, so that the people can discharge dirty air in the house in time and introduce external fresh air into the room. Meanwhile, houses used for living need to have good heat insulation performance, the houses can be kept warm in cold winter, and can be kept cool in summer with burning sun.

Disclosure of Invention

The invention aims to provide a building temperature adjusting method, and aims to solve the technical problem that the house in the prior art cannot realize temperature adjustment and keep ventilation.

In order to achieve the purpose, the invention adopts the technical scheme that: a building temperature adjusting method is applied to temperature adjustment of a heat insulation house made of heat insulation materials, and comprises the following steps:

providing the heat-insulation house, wherein the heat-insulation house comprises a first wall body and a second wall body which are opposite, the first wall body is positioned on the sunny side, the second wall body is positioned on the shady side, the first wall body is provided with a hollow first ventilation cavity, and the second wall body is provided with a second ventilation cavity;

the first wall body is provided with a first vent hole and a second vent hole which penetrate through the first wall body and are communicated with the first ventilation cavity, the first vent hole is formed in the top end of the first wall body, the second vent hole is formed in the bottom end of the first wall body, the first vent hole is provided with a first air port located in the heat insulation house and a second air port located outside the heat insulation house, and the second vent hole is provided with a third air port located in the heat insulation house and a fourth air port located outside the heat insulation house;

the second wall body is provided with a third vent hole and a fourth vent hole which penetrate through the second wall body and are communicated with the second vent cavity, the third vent hole is formed in the top end of the second wall body, the fourth vent hole is formed in the bottom end of the second wall body, the third vent hole is provided with a fifth air port located in the heat insulation house and a sixth air port located outside the heat insulation house, and the fourth vent hole is provided with a seventh air port located in the heat insulation house and an eighth air port located outside the heat insulation house;

and the opening and closing of the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port are regulated and controlled according to the outside climate and weather.

Furthermore, a control system is further arranged in the heat-insulating house, and the control system can respectively and independently control the opening and closing of the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port.

Further, when the sun is in the daytime and sunny days, the control system controls the first air port to be opened, the second air port to be closed, the third air port to be closed, the fourth air port to be opened, the fifth air port to be closed, the sixth air port to be opened, the seventh air port to be opened, and the eighth air port to be closed.

Further, when the winter is at night or on rainy and snowy days, the control system controls the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port to be closed.

Further, when the sun is in the daytime and sunny days in summer, the control system controls the first air port to be closed, the second air port to be opened, the third air port to be opened, the fourth air port to be closed, the fifth air port to be opened, the sixth air port to be closed, the seventh air port to be closed, and the eighth air port to be opened.

Further, when summer night or rainy day, control system control first gas port is opened, the second gas port is closed, the third gas port is closed, the fourth gas port is opened, the fifth gas port is closed, the sixth gas port is opened, the seventh gas port is opened, the eighth gas port is closed.

Further, when daytime in summer and when the air conditioner in the heat-insulated house, control system control first gas port is closed, the second gas port is opened, the third gas port is closed, the fourth gas port is opened, the fifth gas port is closed, the sixth gas port is opened, the seventh gas port is closed, the eighth gas port is opened.

Further, the top of the heat-insulation house is an inclined plane.

The invention has the beneficial effects that: according to the building temperature adjusting method, the temperature of the room can be adjusted by adjusting the direction of the airflow through the heat insulation house, and a large amount of heat absorption or loss caused by outdoor climate change or temperature difference in the room is prevented; the first air port, the second air port, the third air port and the fourth air port are arranged on the first wall body of the heat insulation house located on the sunny side, the fifth air port, the sixth air port, the seventh air port and the eighth air port are arranged on the second wall body of the shady side and communicated through the first ventilation cavity, and therefore the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port can be adjusted according to the external climate, the temperature and the weather, the opening and closing of the seventh air port and the eighth air port can be controlled, the flowing direction of cold and hot air flow can be controlled, and the temperature adjustment and the ventilation can be effectively achieved on the inside of the house. In addition, the temperature regulation and control in the invention controls the flow direction of the cold and hot air flow, and the temperature regulation is realized without using energy, thus having higher environmental protection and economy.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

FIG. 1 is a schematic flow diagram of a method for building temperature regulation according to an embodiment of the present invention;

FIG. 2 is a cut-away view of a thermal insulation house for a building temperature regulating method according to an embodiment of the present invention;

fig. 3 is an airflow direction of a heat-insulated house in a winter day and a sunny day according to the building temperature adjusting method provided by the embodiment of the invention;

FIG. 4 shows the airflow direction of a thermal insulation house in winter at night or in rainy and snowy days according to the method for regulating the temperature of the building provided by the embodiment of the invention;

FIG. 5 is a schematic diagram illustrating an airflow direction of a heat-insulated building in a daytime in summer and on a sunny day according to the building temperature adjusting method provided by the embodiment of the invention;

FIG. 6 is a schematic diagram illustrating the airflow direction of a thermal insulation house in the summer night or in a rainy day according to the method for adjusting the temperature of a building provided by the embodiment of the invention;

fig. 7 shows the airflow direction of the thermal insulation house when the air conditioner is installed in the thermal insulation house in the daytime in summer by the building temperature regulating method according to the embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

10 — a first wall; 11-a first ventilation chamber;

12 — a first gas port; 13-second gas port; 14-third gas port;

15-fourth gas port;

20-a second wall; 21-a second venting chamber;

22-fifth port; 23-sixth port; 24-seventh port;

25-eighth port.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to fig. 1-7 are exemplary and intended to be used to illustrate the invention, but are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

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

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Note that the direction of the arrow in fig. 3 to 7 is the direction of the airflow flowing inside the heat-insulated house.

The first embodiment.

As shown in fig. 1 to 3, an embodiment of the present invention provides a building temperature adjustment method, which is applied to temperature adjustment of a heat insulation house made of a heat insulation material, and is characterized in that: the method comprises the following steps:

s01: providing a heat insulation house, wherein the heat insulation house comprises a first wall body 10 and a second wall body 20 which are opposite, the first wall body 10 is positioned on the sunny side, the second wall body 20 is positioned on the shady side, the first wall body 10 is provided with a hollow first ventilation cavity 11, and the second wall body 20 is provided with a second ventilation cavity 21;

s02: the first wall 10 is provided with a first vent hole and a second vent hole which penetrate through the first wall 10 and are communicated with the first ventilation cavity 11, the first vent hole is arranged at the top end of the first wall 10, the second vent hole is arranged at the bottom end of the first wall 10, the first vent hole is provided with a first air port 12 positioned in the heat insulation house and a second air port 13 positioned outside the heat insulation house, and the second vent hole is provided with a third air port 14 positioned in the heat insulation house and a fourth air port 15 positioned outside the heat insulation house;

s03: the second wall body 20 is provided with a third vent hole and a fourth vent hole which penetrate through the second wall body 20 and are communicated with the second vent cavity 21, the third vent hole is formed in the top end of the second wall body 20, the fourth vent hole is formed in the bottom end of the second wall body 20, the third vent hole is provided with a fifth air port 22 positioned in the heat insulation house and a sixth air port 23 positioned outside the heat insulation house, and the fourth vent hole is provided with a seventh air port 24 positioned in the heat insulation house and an eighth air port 25 positioned outside the heat insulation house;

s04: the opening and closing of the first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24 and the eighth air port 25 are regulated according to the external climate and weather.

According to the building temperature adjusting method provided by the embodiment of the invention, the temperature in the room can be adjusted by adjusting the direction of the airflow by providing the heat-insulating house, and a large amount of heat absorption or flow caused by the outdoor climate or problem in the room is prevented; and then through setting up the first air port 12, the second air port 13, the third air port 14 and the fourth air port 15 on the first wall 10 of this heat insulation house that is located the sunny side, and communicate through the first ventilation chamber 11, the fifth air port 22, the sixth air port 23, the seventh air port 24 and the eighth air port 25 on the second wall 20 of the shady side, and communicate through the second ventilation chamber 21, in this way, just can adjust the opening and closing of first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24 and the eighth air port 25 according to the change of outside weather, temperature and weather, and then control the flow direction of cold and warm air current, and then effectively realize temperature regulation and ventilation to the house inside. In addition, the temperature regulation and control in the invention controls the flow direction of the cold and hot air flow, and the temperature regulation is realized without using energy, thus having higher environmental protection and economy.

Further, in this embodiment, a control system (not shown) is further provided in the heat-insulated building, and the control system can independently control the opening and closing of the first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24, and the eighth air port 25. Through setting up control system, and each control system is provided with a plurality of gas baffles, and first gas port 12, second gas port 13, third gas port 14, fourth gas port 15, fifth gas port 22, sixth gas port 23, seventh gas port 24 and eighth gas port 25 all correspond and are equipped with a gas baffle, and like this, the user just can be according to the opening and closing of outside weather, temperature etc. regulation first gas port 12, second gas port 13, third gas port 14, fourth gas port 15, fifth gas port 22, sixth gas port 23, seventh gas port 24 and eighth gas port 25.

Specifically, the control system in this embodiment may control the opening and closing of each air port by using different types of control methods such as manual mechanical control, semi-automatic mode control, or full-automatic intelligent control, and the like.

Further, in the present embodiment, as shown in fig. 3, during the daytime and sunny day of winter, the control system controls the first air port 12 to be opened, the second air port 13 to be closed, the third air port 14 to be closed, the fourth air port 15 to be opened, the fifth air port 22 to be closed, the sixth air port 23 to be opened, the seventh air port 24 to be opened, and the eighth air port 25 to be closed. Because the hot air can flow upwards in the space, the cold air can descend, so that the temperature of the sunny side of the heat insulation house is higher in winter and sunny days, the air outside the heat insulation house enters from the fourth air port 15 at the moment, the hot air flow rises and enters the heat insulation house from the first air port 12, at the moment, the cold air inside the heat insulation house is located below the house, and then enters the second wall body 20 from the seventh air port 24 on the back and the back of the sun and is extruded out from the sixth air port 23, and therefore ventilation can be guaranteed, the hot air flow enters the room, and the cold air is discharged from the room.

Further, in the present embodiment, as shown in fig. 2 to 7, the top of the heat-insulated house is an inclined surface. Through setting up the top into the slope, can effectively reduce the windage, promote the service life in house.

Example two.

Further, in the present embodiment, as shown in fig. 4, when the winter night or the rainy or snowy day, the control system controls the first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24, and the eighth air port 25 to be closed. When the house is used in winter, at night or in rainy and snowy days, the first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24 and the eighth air port 25 are all closed because the outside of the heat-insulating house is cold air or the air humidity of the heat-insulating house is high, at the moment, the air in the first ventilation cavity 11 and the second ventilation cavity 21 does not flow, and the inside of the house is kept warm and dry because the air is a heat-insulating medium next to vacuum.

The rest of this embodiment is the same as the first embodiment, and the unexplained features in this embodiment are explained by the first embodiment, which is not described herein again.

Example three.

Further, in the present embodiment, as shown in fig. 5, during the daytime in summer and on a sunny day, the control system controls the first air port 12 to be closed, the second air port 13 to be opened, the third air port 14 to be opened, the fourth air port 15 to be closed, the fifth air port 22 to be opened, the sixth air port 23 to be closed, the seventh air port 24 to be closed, and the eighth air port 25 to be opened. Because the temperature of the sunny side is higher in summer and the temperature of the sunny side is far higher than that of the shady side, the air in the first ventilation cavity 11 rises due to the temperature conduction of the first wall 10 and is exhausted from the second air port 13, so that the indoor air is supplemented into the first ventilation cavity 11 from the third air port 14, and a large amount of heat generated by solar radiation absorbed by the sunny side of the first wall 10 is continuously taken away; meanwhile, the low-temperature air on the shady side enters from the eighth air port 25, and when the air is supplemented into the room from the fifth air port 22 through the second ventilation cavity 21, the effects of ventilation and cooling can be brought, so that the stability of the indoor temperature can be kept, air flow is formed, and the body sensing temperature suitable for human production and life can be created.

Example four.

Further, in the present embodiment, as shown in fig. 6, when the summer night or rainy day occurs, the control system controls the first air port 12 to be opened, the second air port 13 to be closed, the third air port 14 to be closed, the fourth air port 15 to be opened, the fifth air port 22 to be closed, the sixth air port 23 to be opened, the seventh air port 24 to be opened, and the eighth air port 25 to be closed. At night, the outdoor temperature is lower than the indoor temperature, and therefore, the cold air outside the room enters from the fourth air port 15 and enters the room from the first air port 12, and the heat inside the room is transferred from the seventh air port 24 to the sixth air port 23, so that the indoor temperature can be continuously and gradually lowered and the air flow is formed to generate weak wind, and the device is suitable for rest.

Example five.

Further, in the present embodiment, as shown in fig. 7, when the air conditioner is to be opened in a temperature-insulated house in the daytime in summer, the control system controls the first air port 12 to be closed, the second air port 13 to be opened, the third air port 14 to be closed, the fourth air port 15 to be opened, the fifth air port 22 to be closed, the sixth air port 23 to be opened, the seventh air port 24 to be closed, and the eighth air port 25 to be opened. Because the time is summer, turn on the air conditioner promptly for the cooling demand, it has the air conditioner to open indoor, just will keep off outside temperature or reduce external temperature, therefore, because the outdoor cold air is in the below, and hot-air is above, like this, open fourth gas port 15 and second gas port 13, the air current can flow in first ventilation cavity 11 but can not get into indoorly, and can take away the heat on the outer wall, and in the same way, after sixth gas port 23 and eighth gas port 25 opened, the air current can flow in second ventilation cavity 21 but can not get into indoorly, and can take away the heat on the outer wall.

Of course, the user can also adjust the control component according to the actual use requirement, and then control the opening and closing of the first air port 12, the second air port 13, the third air port 14, the fourth air port 15, the fifth air port 22, the sixth air port 23, the seventh air port 24 and the eighth air port 25, so as to meet the actual requirement of the user.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A building temperature adjusting method is applied to temperature adjustment of a heat insulation house made of heat insulation materials, and is characterized in that: the method comprises the following steps:

the first wall body is provided with a first vent hole and a second vent hole which penetrate through the first wall body and are communicated with the first ventilation cavity, the first vent hole is formed in the top end of the first wall body, the second vent hole is formed in the bottom end of the first wall body, the first vent hole is provided with a first air port located in the heat-insulation house and a second air port located outside the heat-insulation house, and the second vent hole is provided with a third air port located in the heat-insulation house and a fourth air port located outside the heat-insulation house;

the second wall body is provided with a third vent hole and a fourth vent hole which penetrate through the second wall body and are communicated with the second vent cavity, the third vent hole is formed in the top end of the second wall body, the fourth vent hole is formed in the bottom end of the second wall body, the third vent hole is provided with a fifth air port located in the heat-insulation house and a sixth air port located outside the heat-insulation house, and the fourth vent hole is provided with a seventh air port located in the heat-insulation house and an eighth air port located outside the heat-insulation house;

the opening and closing of the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port are regulated and controlled according to the outside climate and weather; still be equipped with control system in the heat-insulating house room, control system includes a plurality of gas baffles, first gas port the second gas port, the third gas port, the fourth gas port, the fifth gas port, the sixth gas port, the seventh gas port and the eighth gas port all correspond and are equipped with one the gas baffles, control system can independent control respectively first gas port the second gas port, the third gas port, the fourth gas port the fifth gas port the sixth gas port, the seventh gas port and the opening and closing of eighth gas port.

2. The building temperature adjustment method according to claim 1, characterized in that: when the air conditioner is used in winter and sunny days, the control system controls the first air port to be opened, the second air port to be closed, the third air port to be closed, the fourth air port to be opened, the fifth air port to be closed, the sixth air port to be opened, the seventh air port to be opened and the eighth air port to be closed.

3. The building temperature adjustment method according to claim 1, characterized in that: when the night in winter or during rainy and snowy days, the control system controls the first air port, the second air port, the third air port, the fourth air port, the fifth air port, the sixth air port, the seventh air port and the eighth air port to be closed.

4. The building temperature adjustment method according to claim 1, characterized in that: when the air conditioner is used in summer and on sunny days, the control system controls the first air port to be closed, the second air port to be opened, the third air port to be opened, the fourth air port to be closed, the fifth air port to be opened, the sixth air port to be closed, the seventh air port to be closed and the eighth air port to be opened.

5. The building temperature adjustment method according to claim 1, characterized in that: when summer night or rainy day, control system control first gas port is opened, the second gas port is closed, the third gas port is closed, the fourth gas port is opened, the fifth gas port is closed, the sixth gas port is opened, the seventh gas port is opened, the eighth gas port is closed.

6. The building temperature adjustment method according to claim 1, characterized in that: when daytime in summer just during the air conditioner in the heat insulation house, control system control first gas port is closed, the second gas port is opened, the third gas port is closed, the fourth gas port is opened, the fifth gas port is closed, the sixth gas port is opened, the seventh gas port is closed, the eighth gas port is opened.

7. The building temperature adjustment method according to claim 1, characterized in that: the top of the heat insulation house is an inclined plane.