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WO2013089543A1 - Wall for controlling the temperature of a room by evaporation and thermal inertia - Google Patents

Wall for controlling the temperature of a room by evaporation and thermal inertia Download PDF

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Publication number
WO2013089543A1
WO2013089543A1 PCT/MX2011/000167 MX2011000167W WO2013089543A1 WO 2013089543 A1 WO2013089543 A1 WO 2013089543A1 MX 2011000167 W MX2011000167 W MX 2011000167W WO 2013089543 A1 WO2013089543 A1 WO 2013089543A1
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WO
WIPO (PCT)
Prior art keywords
liquid
air
hollow wall
wall
pipe
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Ceased
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PCT/MX2011/000167
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Spanish (es)
French (fr)
Inventor
Bruno Lopez Colinas
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Individual
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Individual
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Priority to PCT/MX2011/000167 priority Critical patent/WO2013089543A1/en
Publication of WO2013089543A1 publication Critical patent/WO2013089543A1/en
Anticipated expiration legal-status Critical
Ceased legal-status Critical Current

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24DDOMESTIC- OR SPACE-HEATING SYSTEMS, e.g. CENTRAL HEATING SYSTEMS; DOMESTIC HOT-WATER SUPPLY SYSTEMS; ELEMENTS OR COMPONENTS THEREFOR
    • F24D5/00Hot-air central heating systems; Exhaust gas central heating systems
    • F24D5/02Hot-air central heating systems; Exhaust gas central heating systems operating with discharge of hot air into the space or area to be heated
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04CSTRUCTURAL ELEMENTS; BUILDING MATERIALS
    • E04C2/00Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels
    • E04C2/44Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by the purpose
    • E04C2/52Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by the purpose with special adaptations for auxiliary purposes, e.g. serving for locating conduits
    • E04C2/521Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by the purpose with special adaptations for auxiliary purposes, e.g. serving for locating conduits serving for locating conduits; for ventilating, heating or cooling
    • E04C2/525Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by the purpose with special adaptations for auxiliary purposes, e.g. serving for locating conduits serving for locating conduits; for ventilating, heating or cooling for heating or cooling
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24DDOMESTIC- OR SPACE-HEATING SYSTEMS, e.g. CENTRAL HEATING SYSTEMS; DOMESTIC HOT-WATER SUPPLY SYSTEMS; ELEMENTS OR COMPONENTS THEREFOR
    • F24D3/00Hot-water central heating systems
    • F24D3/12Tube and panel arrangements for ceiling, wall, or underfloor heating
    • F24D3/14Tube and panel arrangements for ceiling, wall, or underfloor heating incorporated in a ceiling, wall or floor
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]

Definitions

  • the present invention belongs to the technical field of mechanics because it provides a room temperature control wall by evaporation and thermal inertia.
  • Air Conditioning devices These generally use the mechanical compression of a gas.
  • One of the main disadvantages of these devices is their high energy consumption.
  • the liquid lodged inside the barrels will absorb the heat energy of the sun's rays or the heat of the environment, in such a way that the increase in the room temperature will be less than if the barrels filled with liquid were not arranged.
  • the present invention is novel with respect to its closest antecedent, because it provides a device that fulfills the same technical function, that is, controlling the temperature of a room, however, it does so by solving the problems of water stagnation and optimizing The use of space. It also allows an additional function that is not possible with its closest antecedent, which consists of the injection of air into the liquid for later collection. This additional function allows greater control over the room temperature.
  • the present invention consists of a room temperature control wall by evaporation and thermal inertia, the details of which are clearly shown in the following description and in the accompanying figures, which are mentioned by way of example and should not be considered as limiting for the present invention.
  • Figure 1 is a front view of the inner wall of the hollow wall.
  • Figure 2 is a perspective of the outer wall of the hollow wall.
  • Figure 3 is a perspective of the outer wall of the hollow wall where the air compressor and the air inlet to the wall can be seen.
  • Figure 5 is a perspective view of the inner wall of the hollow wall.
  • the room temperature control wall by evaporation and thermal inertia is composed of a hollow wall (1) arranged vertically.
  • This hollow wall (1) may be of the same dimensions as the wall of the room where the system will be placed, or it may be smaller, however in no case should it be less than one meter high by two meters long.
  • the interior of said hollow wall (1) will be filled with liquid (2), this being preferably water. Said liquid (2) will allow to carry out an evaporation and heat exchange process.
  • the liquid (2) is introduced into the hollow wall (1) by means of a liquid circulation system (3).
  • the liquid circulation system (3) controls the level of the liquid (2) inside the hollow wall (1) and allows the filling or purging of the liquid (2).
  • the liquid circulation system (3) consists of a pipe (3a) containing the liquid (2) pressurized by any conventional method. Even said pipe (3a) can be connected to the water supply system of the property. Pressurized liquid (2) circulates through the pipeline (3a), until an inlet flow control valve (3b) is reached, which in turn is connected to a liquid inlet pipe (3c), which reaches up to the hollow wall (1). At the point where the liquid inlet pipe (3c) and the hollow wall (1) make contact, it has a liquid inlet hole (1 a) which allows the entry of liquid (2) into the wall hollow (1).
  • the liquid inlet flow control valve (3b) is responsible for managing liquid filling (2) within the hollow wall (1).
  • the level of the liquid (2) inside the hollow wall (1) can be controlled by filling, by purging or a combination of the two.
  • the purge of the liquid (2) contained in the hollow wall (1) is carried out through a liquid outlet orifice (1 b) located in the lower area of the hollow wall (1).
  • Said liquid outlet port (1 b) is connected to a liquid outlet pipe (3d), which in turn is connected to a liquid outlet flow control valve (3e), which in turn It is connected to a pipe (3f), which conducts the liquid (2) to any known hydraulic bypass method.
  • the liquid outlet flow control valve (3e) is responsible for managing the emptying of liquid contained within the hollow wall (1).
  • the liquid circulation system (3) in addition to fulfilling the functions of filling and purging the liquid (2) housed inside the hollow wall (1), prevents the stagnation of the liquid (2). In the same way, it fulfills an important function with respect to the control of the temperature inside the room.
  • the liquid (2) will receive a greater or lesser amount of heat energy from the sun's rays and the environment. So that, during the summer or hot seasons the liquid (2) can be circulated in such a way that the room's environment will be kept at a lower temperature. Similarly in winter or during cold weather, the circulation of the liquid (2) is suspended, which will cause it to absorb heat energy and slowly radiate it into the room.
  • the present invention also has an air circulation system (4).
  • the air circulation system (4) manages the air flow (5) that will be introduced to the hollow wall (1) and subsequently circulated to the room.
  • the air circulation system (4) consists of an air suction pipe (4a) arranged outside the room, which is connected to an air compressor (4b).
  • an air compressor (4b) In the figures we have illustratively placed the air compressor (4b) on the outside, however, it is not essential that it be placed outside for the proper functioning of the present invention; The only thing that should be outside is the air suction pipe (4a).
  • the air compressor (4b) when ignited by any conventional method, will suck air from the outside environment through the air suction pipe (4a), then pressurize it and push it through a connection pipe (4c).
  • Pressurized air (5) circulates through the connecting pipe (4c), until a control valve (4e) is reached, which in turn is connected to an air inlet pipe (4f), which reaches the lower zone from the wall of the hollow wall (1).
  • a control valve (4e) is reached, which in turn is connected to an air inlet pipe (4f), which reaches the lower zone from the wall of the hollow wall (1).
  • the air inlet pipe (4f) and the hollow wall (1) make contact, it has an air inlet hole (1 c) which allows the entry of air (5) to the lower zone of the hollow wall (1).
  • the air inlet opening (1c) in the outer wall of the hollow wall (1), however, it is not essential that it be placed outside for the proper functioning of the present invention; the only thing that is essential is that the air inlet hole (1 c) is arranged in the lower area of the hollow wall (1).
  • the control valve (4e) prevents the liquid (2) contained within the hollow wall (1) from circulating towards the compressor (4b) when it is not on.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Thermal Sciences (AREA)
  • Physics & Mathematics (AREA)
  • Architecture (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Building Environments (AREA)

Abstract

The invention relates to a wall for controlling the temperature of a room by evaporation and thermal inertia which includes a hollow wall (1) filled with a liquid, with an inlet opening (1a) and an outlet opening (1b) for water and an inlet opening (1e) and an outlet opening (1d) for air; a liquid-circulation system (3) having a liquid-inlet control valve (3b) and an outlet-control valve (3d); and an air-circulation system (4), the inlet of which is connected to an air compressor (4b), with an air-inlet control valve (4e) and an air-outlet valve (4h).

Description

MURO DE CONTROL DE TEMPERATURA DE HABITACIÓN POR EVAPORACIÓN E INERCIA TÉRMICA  WALL TEMPERATURE CONTROL WALL FOR EVAPORATION AND THERMAL INERTIA

CAMPO DE LA INVENCIÓN FIELD OF THE INVENTION

La presente invención pertenece al campo técnico de la mecánica debido a que proporciona un muro de control de temperatura de habitación por evaporación e inercia térmica. ANTECEDENTES The present invention belongs to the technical field of mechanics because it provides a room temperature control wall by evaporation and thermal inertia. BACKGROUND

En la actualidad existen diversos dispositivos que permiten regular la temperatura de una habitación o inmueble, ya sea para calefacción o refrigeración. Los más comunes son los dispositivos de Aire Acondicionado; estos utilizan generalmente la compresión mecánica de un gas. Uno de los principales inconvenientes que presentan estos dispositivos es su alto consumo energético . Currently there are several devices that allow regulating the temperature of a room or building, either for heating or cooling. The most common are Air Conditioning devices; These generally use the mechanical compression of a gas. One of the main disadvantages of these devices is their high energy consumption.

Para contrarrestar los problemas del consumo energético de los dispositivos de Aire Acondicionado, se desarrollo otro concepto que utiliza la inercia térmica del Agua. Este mecanismo consiste en apilar barriles rellenos de líquido (tradicionalmente agua) y colocarlos junto a una pared. To counteract the problems of energy consumption of Air Conditioning devices, another concept was developed that uses the thermal inertia of Water. This mechanism consists of stacking barrels filled with liquid (traditionally water) and placing them next to a wall.

El líquido alojado al interior de los barriles absorberá la energía calorífica de los rayos del sol o el calor del ambiente, de tal suerte que el aumento de la temperatura de la habitación será menor que si no estuvieran dispuestos los barriles rellenos de líquido. The liquid lodged inside the barrels will absorb the heat energy of the sun's rays or the heat of the environment, in such a way that the increase in the room temperature will be less than if the barrels filled with liquid were not arranged.

La energía calorífica acumulada durante el día en el líquido de los barriles, será lentamente irradiada hacia la habitación durante la noche, de tal suerte que la temperatura de la habitación bajará más lentamente durante dicho periodo haciéndola más confortable. Este sistema es el antecedente más cercano a la invención. Una de las principales desventajas del sistema referido es que el líquido (tradicionalmente agua) alojado al interior de los barriles -debido a la falta de circulación- se estanca. El estancamiento del agua la torna una fuente de infecciones y malos olores. Otro inconveniente de este sistema es que los barriles ocuparán un espacio dentro de la habitación, lo cual causará una reducción del espacio utilizable para otros fines. The heat energy accumulated during the day in the liquid of the barrels, will be slowly radiated into the room during the night, in such a way that the temperature of the room will lower more slowly during this period making it more comfortable. This system is the closest antecedent to the invention. One of the main disadvantages of the referred system is that the liquid (traditionally water) housed inside the barrels - due to the lack of circulation - is sealed. The stagnation of water makes it a source of infections and bad odors. Another drawback of this system is that the barrels will occupy a space inside the room, which will cause a reduction of the usable space for other purposes.

La presente invención es novedosa respecto a su antecedente más cercano, debido a que provee un dispositivo que cumple con la misma función técnica, es decir, controlar la temperatura de una habitación, sin embargo, lo efectúa resolviendo los inconvenientes del estancamiento del agua y optimiza la utilización del espacio. También permite una función adicional que no es posible con su antecedente más cercano, la cual consiste en la inyección de aire al líquido para su posterior recolección. Esta función adicional permite tener un mayor control sobre la temperatura de la habitación. The present invention is novel with respect to its closest antecedent, because it provides a device that fulfills the same technical function, that is, controlling the temperature of a room, however, it does so by solving the problems of water stagnation and optimizing The use of space. It also allows an additional function that is not possible with its closest antecedent, which consists of the injection of air into the liquid for later collection. This additional function allows greater control over the room temperature.

DESCRIPCIÓN DESCRIPTION

La presente invención consiste en un muro de control de temperatura de habitación por evaporación e inercia térmica, cuyos detalles se muestran claramente en la siguiente descripción y en las figuras que se acompañan, las cuales se mencionan a manera de ejemplo y no deben considerase como limitativas para la presente invención. The present invention consists of a room temperature control wall by evaporation and thermal inertia, the details of which are clearly shown in the following description and in the accompanying figures, which are mentioned by way of example and should not be considered as limiting for the present invention.

Breve descripción de las figuras: Brief description of the figures:

La figura 1 es una vista frontal de la pared interna del muro hueco. Figure 1 is a front view of the inner wall of the hollow wall.

La figura 2 es una perspectiva de la pared externa del muro hueco. Figure 2 is a perspective of the outer wall of the hollow wall.

La figura 3 es una perspectiva de la pared externa del muro hueco donde se aprecia el compresor de aire y la entrada de aire al muro. Figure 3 is a perspective of the outer wall of the hollow wall where the air compressor and the air inlet to the wall can be seen.

La figura 4 en perspectiva superior de la invención. Figure 4 in top perspective of the invention.

La figura 5 es una vista en perspectiva de la pared interna del muro hueco.  Figure 5 is a perspective view of the inner wall of the hollow wall.

Con referencia en dichas figuras, el muro de control de temperatura de habitación por evaporación e inercia térmica se compone de un muro hueco (1 ) dispuesto verticalmente. Este muro hueco (1 ) podrá ser de las mismas dimensiones que la pared de la habitación donde se colocará el sistema, o podrá ser menor, sin embargo en ningún caso deberá ser menor a un metro de alto por dos metros de largo. El interior de dicho muro hueco (1 ) se rellenará con líquido (2), siendo éste preferentemente agua. Dicho líquido (2) permitirá llevar a cabo un proceso de evaporación e intercambio de calor. El líquido (2) se introduce en el muro hueco (1 ) mediante un sistema de circulación de líquidos (3). El sistema de circulación de líquidos (3) controla el nivel del líquido (2) dentro del muro hueco (1 ) y permite el llenado o purga del líquido(2). El sistema de circulación de líquidos (3), consta de una tubería (3a) que contiene el líquido (2) presurizado por cualquier método convencional. Inclusive dicha tubería (3a) puede estar conectada al sistema alimentación de agua del inmueble. El líquido (2) presurizado circula por la tubería (3a), hasta llegar una válvula de control de flujo de entrada (3b), la cual está a su vez conectada a una tubería de entrada de líquido (3c), la cual llega hasta el muro hueco (1 ). En el punto donde hacen contacto la tubería de entrada de líquido (3c) y el muro hueco (1 ), éste cuenta con un orificio de entrada de líquido (1 a) el cual permite el ingreso del líquido (2) al interior del muro hueco (1 ). With reference in said figures, the room temperature control wall by evaporation and thermal inertia is composed of a hollow wall (1) arranged vertically. This hollow wall (1) may be of the same dimensions as the wall of the room where the system will be placed, or it may be smaller, however in no case should it be less than one meter high by two meters long. The interior of said hollow wall (1) will be filled with liquid (2), this being preferably water. Said liquid (2) will allow to carry out an evaporation and heat exchange process. The liquid (2) is introduced into the hollow wall (1) by means of a liquid circulation system (3). The liquid circulation system (3) controls the level of the liquid (2) inside the hollow wall (1) and allows the filling or purging of the liquid (2). The liquid circulation system (3), consists of a pipe (3a) containing the liquid (2) pressurized by any conventional method. Even said pipe (3a) can be connected to the water supply system of the property. Pressurized liquid (2) circulates through the pipeline (3a), until an inlet flow control valve (3b) is reached, which in turn is connected to a liquid inlet pipe (3c), which reaches up to the hollow wall (1). At the point where the liquid inlet pipe (3c) and the hollow wall (1) make contact, it has a liquid inlet hole (1 a) which allows the entry of liquid (2) into the wall hollow (1).

La válvula de control de flujo de entrada de líquido (3b) es la responsable de la gestión de llenado de líquido (2) dentro del muro hueco (1 ). El nivel del líquido (2) dentro del muro hueco (1 ) puede ser controlado mediante el llenado, mediante la purga o una combinación de los dos. La purga del líquido (2) contenido en el muro hueco (1) se lleva a cabo a través un orificio de salida de líquido (1 b) localizado en la zona inferior del muro hueco (1 ). Dicho orificio de salida de líquido (1 b) está conectado con una tubería de salida de líquido (3d), la cual a su vez está conectada con una válvula de control de flujo de salida de líquido (3e), la cual a su vez está conectada con una tubería (3f), que conduce el liquido (2) hacia cualquier método de derivación hidráulica conocido. Inclusive dicha tubería (3f) puede estar conectada al sistema alimentación de agua del inmueble, de tal suerte que el agua purgada del muro hueco (1 ) pueda ser utilizada para otros fines dentro del inmueble. La válvula de control de flujo de salida de líquido (3e) es la responsable de la gestión del vaciado de líquido contenido dentro del muro hueco (1 ). - The liquid inlet flow control valve (3b) is responsible for managing liquid filling (2) within the hollow wall (1). The level of the liquid (2) inside the hollow wall (1) can be controlled by filling, by purging or a combination of the two. The purge of the liquid (2) contained in the hollow wall (1) is carried out through a liquid outlet orifice (1 b) located in the lower area of the hollow wall (1). Said liquid outlet port (1 b) is connected to a liquid outlet pipe (3d), which in turn is connected to a liquid outlet flow control valve (3e), which in turn It is connected to a pipe (3f), which conducts the liquid (2) to any known hydraulic bypass method. Even said pipe (3f) can be connected to the water supply system of the building, so that the water purged from the hollow wall (1) can be used for other purposes within the building. The liquid outlet flow control valve (3e) is responsible for managing the emptying of liquid contained within the hollow wall (1). -

El sistema de circulación de líquidos (3), además de cumplir con las funciones de llenado y purga del liquido(2) alojado al interior del muro hueco (1 ), evita el estancamiento del líquido (2). Del mismo modo, cumple con una importante función con respecto al control de la temperatura al interior de la habitación. The liquid circulation system (3), in addition to fulfilling the functions of filling and purging the liquid (2) housed inside the hollow wall (1), prevents the stagnation of the liquid (2). In the same way, it fulfills an important function with respect to the control of the temperature inside the room.

Dependiendo de la época del año, el liquido (2) recibirá una mayor o menor cantidad de energía calorífica de los rayos del sol y del ambiente. Así pues, durante el verano o épocas calurosas se puede hacer circular el líquido (2) de tal suerte que el ambiente de la habitación se mantendrá a temperatura más baja. Del mismo modo en invierno o durante épocas de frío, se suspende la circulación del liquido(2), lo que provocará que éste absorba energía calorífica y la irradie lentamente al interior de la habitación. Depending on the time of the year, the liquid (2) will receive a greater or lesser amount of heat energy from the sun's rays and the environment. So that, during the summer or hot seasons the liquid (2) can be circulated in such a way that the room's environment will be kept at a lower temperature. Similarly in winter or during cold weather, the circulation of the liquid (2) is suspended, which will cause it to absorb heat energy and slowly radiate it into the room.

La presente invención también cuenta con un sistema de circulación de aire (4). El sistema de circulación de aire (4) gestiona el flujo de aire (5) que será introducido al muro hueco (1 ) y circulado posteriormente hacia la habitación. The present invention also has an air circulation system (4). The air circulation system (4) manages the air flow (5) that will be introduced to the hollow wall (1) and subsequently circulated to the room.

El sistema de circulación de aire (4), consta de una tubería de succión de aire (4a) dispuesta en el exterior de la habitación, la cual está conectada con un compresor de aire (4b). En las figuras hemos colocado de forma ilustrativa el compresor de aire (4b) en el exterior, sin embargo, no es indispensable que esté colocado en el exterior para el correcto funcionamiento de la presente invención; lo único que sí debe estar en el exterior es la tubería de succión de aire (4a). El compresor de aire (4b) al ser encendido por cualquier método convencional, succionará aire del ambiente exterior a través de la tubería de succión de aire (4a), posteriormente lo presurizará y lo empujará por una tubería de conexión (4c). El aire (5) presurizado circula por la tubería de conexión (4c), hasta llegar una válvula de control (4e), ésta a su vez está conectada a una tubería de entrada de aire (4f), la cual llega hasta la zona inferior de la pared del muro hueco (1 ). En el punto donde hacen contacto la tubería de entrada de aire (4f) y el muro hueco (1 ), éste cuenta con un orificio de entrada de aire (1 c) el cual permite el ingreso del aire (5) a la zona inferior del muro hueco (1 ). En las figuras hemos colocado de forma ilustrativa el orificio de entrada de aire (1c) en la pared exterior del muro hueco (1 ), sin embargo, no es indispensable que esté colocado en el exterior para el correcto funcionamiento de la presente invención; lo único que sí es indispensable es que el orificio de entrada de aire (1 c) esté dispuesto en la zona inferior del muro hueco (1 ). La válvula de control (4e) impide que el líquido (2) contenido dentro del muro hueco (1 ) circule hacia el compresor (4b) cuando este no está encendido. Una vez que el aire (5) es inyectado al interior del muro hueco (1 ) éste viajará -por diferencia de densidad- hacia la zona supenor del muro hueco (1 ). Durante dicho trayecto el aire (5) se saturará de humedad causando una baja en su temperatura. En la zona superior de la pared interna del muro hueco (1 ) se encuentra dispuesto un orificio de salida de aire (1d), a través del cual saldrá el aire(5) enfriado. Posteriormente viajará por una tubería de salida de aire (4g), hasta llegar a una válvula de alivio(4h) la cual permite la salida de aire(5) enfriado hacia el interior de la habitación. The air circulation system (4), consists of an air suction pipe (4a) arranged outside the room, which is connected to an air compressor (4b). In the figures we have illustratively placed the air compressor (4b) on the outside, however, it is not essential that it be placed outside for the proper functioning of the present invention; The only thing that should be outside is the air suction pipe (4a). The air compressor (4b), when ignited by any conventional method, will suck air from the outside environment through the air suction pipe (4a), then pressurize it and push it through a connection pipe (4c). Pressurized air (5) circulates through the connecting pipe (4c), until a control valve (4e) is reached, which in turn is connected to an air inlet pipe (4f), which reaches the lower zone from the wall of the hollow wall (1). At the point where the air inlet pipe (4f) and the hollow wall (1) make contact, it has an air inlet hole (1 c) which allows the entry of air (5) to the lower zone of the hollow wall (1). In the figures we have illustratively placed the air inlet opening (1c) in the outer wall of the hollow wall (1), however, it is not essential that it be placed outside for the proper functioning of the present invention; the only thing that is essential is that the air inlet hole (1 c) is arranged in the lower area of the hollow wall (1). The control valve (4e) prevents the liquid (2) contained within the hollow wall (1) from circulating towards the compressor (4b) when it is not on. Once the air (5) is injected into the inside the hollow wall (1) it will travel - due to density difference - to the upper area of the hollow wall (1). During said journey the air (5) will saturate with humidity causing a decrease in its temperature. In the upper part of the inner wall of the hollow wall (1) there is an air outlet (1d), through which the cooled air (5) will flow out. Later, it will travel through an air outlet pipe (4g), until it reaches a relief valve (4h) which allows the exit of cooled air (5) into the room.

Claims

REIVINDICACIONES Habiendo descrito suficientemente mi invención, la considero como una novedad y por lo tanto reclamo como de mi exclusiva propiedad, lo contenido en las siguientes reivindicaciones: CLAIMS Having sufficiently described my invention, I consider it as a novelty and therefore claim as my exclusive property, the content of the following claims: 1.- Un Muro de control de temperatura de habitación por evaporación e inercia térmica caracterizado porque comprende: a) Un muro hueco con un orificio de entrada de agua, un orificio de salida de agua, un orificio de entrada de aire y un orificio de salida de aire; donde los orificios de salida de agua y entrada de aire están dispuestos en la zona inferior de dicho muro hueco, mientras que el orificio de salida de aire está dispuesto en su zona superior de dicho muro hueco. El interior de este muro hueco se encuentra relleno con líquido. b) Un sistema de circulación de líquido que consta de una tubería que contiene líquido presurizado; conectada con una válvula de control de flujo de entrada de líquido, la cual está a su vez conectada a una tubería de entrada de líquido, la cual llega hasta el orificio de entrada de agua del muro hueco. Este sistema comprende también una tubería de salida de líquido, dispuesta en el orificio de salida de líquido del muro hueco, la cual a su vez está conectada con una válvula de control de flujo de salida de líquido, la cual a su vez está conectada con una tubería que conduce el liquido hacia cualquier método de derivación hidráulica conocido. c) Un sistema de circulación de aire que consta de una tubería de succión de aire dispuesta en el exterior de la habitación, la cual está conectada con un compresor de aire, el cual está conectado con una tubería de conexión, la cual llega hasta una válvula de control, la cual a su vez está conectada a una tubería de entrada de aire, la cual llega hasta el orificio de entrada de aire del muro hueco. Este sistema comprende también una tubería de salida de aire dispuesta en el orificio de salida de aire del muro hueco, la cual conecta con una válvula de alivio. 1.- A wall for room temperature control by evaporation and thermal inertia characterized in that it comprises: a) A hollow wall with a water inlet hole, a water outlet hole, an air inlet hole and a water hole air vent; wherein the water outlet and air inlet holes are arranged in the lower area of said hollow wall, while the air outlet hole is disposed in its upper area of said hollow wall. The interior of this hollow wall is filled with liquid. b) A liquid circulation system consisting of a pipe containing pressurized liquid; connected with a liquid inlet flow control valve, which in turn is connected to a liquid inlet pipe, which reaches the water inlet hole of the hollow wall. This system also comprises a liquid outlet pipe, arranged in the liquid outlet port of the hollow wall, which in turn is connected to a liquid outlet flow control valve, which in turn is connected to a pipe that conducts the liquid to any known hydraulic bypass method. c) An air circulation system consisting of an air suction pipe arranged outside the room, which is connected to an air compressor, which is connected to a connection pipe, which reaches a control valve, which in turn is connected to an air inlet pipe, the which reaches the air inlet hole of the hollow wall. This system also comprises an air outlet pipe disposed in the air outlet hole of the hollow wall, which connects to a relief valve.
PCT/MX2011/000167 2011-12-16 2011-12-16 Wall for controlling the temperature of a room by evaporation and thermal inertia Ceased WO2013089543A1 (en)

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Application Number Priority Date Filing Date Title
PCT/MX2011/000167 WO2013089543A1 (en) 2011-12-16 2011-12-16 Wall for controlling the temperature of a room by evaporation and thermal inertia

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PCT/MX2011/000167 WO2013089543A1 (en) 2011-12-16 2011-12-16 Wall for controlling the temperature of a room by evaporation and thermal inertia

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Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4285332A (en) * 1979-07-09 1981-08-25 Mchugh Thomas Building having solar heating system
US4517958A (en) * 1980-09-25 1985-05-21 Worf Douglas L Heat exchange system
US20040025864A1 (en) * 2000-04-10 2004-02-12 Edwin Aronds Device for heating of liquids
US7549418B1 (en) * 2008-03-23 2009-06-23 Moorman William E Method and device for capture, storage and recirculation of heat energy
WO2010044789A1 (en) * 2008-10-15 2010-04-22 Swift, John Building-integrated solar thermal micro-channel absorber and method of manufacturing thereof

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4285332A (en) * 1979-07-09 1981-08-25 Mchugh Thomas Building having solar heating system
US4517958A (en) * 1980-09-25 1985-05-21 Worf Douglas L Heat exchange system
US20040025864A1 (en) * 2000-04-10 2004-02-12 Edwin Aronds Device for heating of liquids
US7549418B1 (en) * 2008-03-23 2009-06-23 Moorman William E Method and device for capture, storage and recirculation of heat energy
WO2010044789A1 (en) * 2008-10-15 2010-04-22 Swift, John Building-integrated solar thermal micro-channel absorber and method of manufacturing thereof

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