FR2509023A1 - Greenhouse effect solar panel for air conditioning - has black body formed of internal chicane elements containing air conduits and photovoltaic cells on upper part of solar panel - Google Patents

Abstract

A black body is formed by a series of hollow components fitted with air baffles. This black body is closed, at the front, by a single or multiple glazing, and at the back, by an insulating layer. The air from the room to be conditioned enters through a lower pipe and returns to the room through an upper pipe. Cold air can enter, controlled by a valve. Another valve controls the hot air flow so that part or allof it can leave through an aperture. At the bottom, a channel collects the condensation water and evacuates it through a pipe. A series of photovoltaic cells is mounted at the top of the panel.

Description

 The present invention relates to the field of heating and / or air conditioning of premises for individual or collective dwellings, or the like, and relates to a solar collector, in particular for air conditioning.

 The solar collectors known as “greenhouse effect” currently existing generally consist of a black body containing water or heat transfer fluid pipes, this black body being arranged in a tank-chassis whose front face is closed by a glass, a Insulation being provided at the back of the black body, there are also sensors of this type, in which the heat-transfer fluid is air which heats a heat exchanger.

 However, these known collectors do not allow air conditioning of premises directly from the recovered solar energy, and must always be coupled with exchangers of known type with additional energy consumption.

 The present invention aims to overcome these drawbacks.

 It has, in fact, for its object a solar collector, in particular for air conditioning, characterized in that it is constituted by an air circulation sensor comprising a black body in the form of an assembly of hollow elements with baffles, closed at its front part by a simple or multilayer glazed element, and provided at its rear part with an insulating layer, by a lower air inlet duct to be heated connected to the room to be air conditioned, by a departure duct hot air to the room to be conditioned, by a cold air inlet valve, by a hot air flow control valve, allowing total or partial evacuation of said hot air through an opening of the sensor, by a channel of condensing water extending longitudinally in the lower part of the sensor and connected to a pipe for discharging said water and by one or more sets of photovoltaic cells arranged in the upper part of the sensor and / or above it latest.

 According to a characteristic of the invention, the black body is constituted by corrugated elements of metal or synthetic material mounted on a layer of insulating material and provided on their front face with a coating closing the corrugations in the form of a perforated or not perforated film of transparent or non-transparent synthetic material, under perforated fabric, perforated or not, or in the form of perforated metal or not.

 According to another characteristic of the invention, the glazed element closing the sensor is in the form of a thin layer of glass in the lower part of the sensor and in the form of a thicker layer of double or triple glass in the upper part of the sensor.

 The invention will be better understood thanks to the description below, which relates to preferred embodiments, given by way of nonlimiting examples, and explained with reference to the appended schematic drawings, in which FIG. 1 is a view in side elevation and in section of a solar collector according to the invention in "winter" operating position FIG. 2 is a sectional view, on a larger scale of an example of embodiment of the black body, FIG. 3 is a view similar to that of FIG. 1, slightly simplified, of the sensor in the "summer" position, and FIGS. 4 to 6 are views similar to those of FIGS. 1 and 3 of alternative embodiments of the invention.

 According to the invention, and as shown more particularly, by way of example, Figures 1 and 3 of the accompanying drawings, the solar collector is constituted by an air flow collector 1 comprising a black body 2 in the form of '' hollow elements 3 with baffles, closed at its front part by a single or multilayer glazed element 4, and provided at its rear part with an insulating layer 5, by a lower duct 6 for the air supply to be heated connected to the room to be air conditioned, by a duct 7 for the departure of hot air to the room to be conditioned, by a valve 8 for the arrival of cold air, in the sensor 1, by a valve 9 for adjusting the flow of hot air allowing a total or partial evacuation of this hot air through an opening 10 of the sensor I, by a channel 11 of condensing water extending longitudinally in the lower part of the sensor 1 and connected to a pipe 12 for evacuating said water, and by two sets 13 of voltaic photo batteries arranged in the upper part e of sensor 1 and above it.

 The black body 2 can be constituted, in a known manner, by hollow elements 3 with baffles, in synthetic material, in metal, or in ceramic. This black body 2 can also be constituted, as shown in FIG. 2, by corrugated elements 14 of metal or synthetic material mounted on the layer 5, and which are provided on their front face with a coating 15, which closes the corrugations 14 ′, and which is in the form of a perforated film or not in transparent or non-transparent synthetic material, or in the form of a perforated fabric or not, or also in the form of perforated metal or not.

 The glazed element 4, shown more particularly in FIG. 1 of the accompanying drawings, is advantageously in the form of a thin layer of glass 4 ′ in the lower part of the sensor 1 and of a thicker layer, for example of double glass 4 "in the upper part of the sensor 1, so that the heat losses through the element 4 are uniform.

 The air to be heated is brought from the room into the lower part of the sensor 1 through the duct 6, which can optionally be closed, at least partially, by means of the cold air inlet valve 8, this valve being either with manual control, or with thermostat control reacting to the interior temperature of the room to be air conditioned. In the lower part of the sensor 1 further extends a longitudinal channel 11 for the condensation water which is discharged through the line 12.

 The air heated in the sensor 1, coming from the room to be conditioned or from the outside, is introduced into said room through the duct 7, which can be more or less closed, thanks to the thermostatic valve 9, depending on the interior temperature. from the local. If the maximum heat threshold is exceeded, the valve 9 switches slightly and thus deflects part of the flow of hot air towards the outside of the sensor 1 through its opening 10.

 In addition, as shown in FIG. 3, in "summer" operation, the valve 9 can be pivoted in a position in which it deflects all of the hot air flow from the sensor 1 through the opening 10 and in which the conduit 7 is also in communication with the opening 10, so that the hot air exiting through said opening 10 entrains the air contained in the upper part of the room by suction effect.

 The valve 9 for adjusting the hot air flow can be either manually controlled, or thermostatically controlled by the room temperature, or even assisted.

 The sets 13 of photovoltaic cells are integrated in the sensor 1, for example at the level of the duct 7 and above the sensor 1, for example at the joint between stages, and can be used for the production of the electrical energy necessary for the control of the valves 8 and 9 as well as possibly of air conditioning accessory devices such as fans 22 for circulating the air (FIG. 4), electric resistances for auxiliary heating, and the like.

 FIG. 4 represents an alternative embodiment of the solar collector according to the invention, in which the collector is completed by an internal channel 16 connected to the duct 7 and provided with a fan 17 propelling the hot air down from the room, this fan being able to be supplied with electrical current from the network or coming from the batteries of the assemblies 13, and an electric heating element 18 which can be arranged in front of the air outlet of the channel 16 to serve for the supply of an additional heat, this element 18 can also be powered by the battery assemblies 13, or by the electrical current of the network.

 In its upper part, the channel 16 is connected, by means of a ventilation valve 19, to a ventilation casing 20 containing an air circulation fan 21 making it possible to play on the possibilities of ventilation or air conditioning.

 FIG. 5 represents another variant embodiment of the invention, in which the internal channel 16, provided with a fan 17, is connected to an accumulation radiator 23 provided with an air circulation fan 24, the heating air from the radiator 23 being brought back into the sensor 1 by a return pipe 25. In this embodiment the radiator 23 is advantageously an electric radiator and the circulation of hot air is used for its preheating.

 In the embodiment of FIG. 6, a heat exchanger 26 with water circulation is arranged in the upper part of the sensor 1 before the duct 7 for the departure of hot air towards the room to be conditioned, this exchanger 26 can be connected to a domestic hot water or heating circuit, or to a heat pump.

 The exchanger 26 could also be in circulation of air and form the cold source of a heat pump of the air-air or air-water type.

 Thanks to the invention, it is possible to achieve fully automatic air conditioning of premises with solar energy, while ensuring a good hygrometric degree of said premises, a significant part of the humidity of the air being able to be evacuated in the part bottom of the sensor.

 Of course, the invention is not limited to the embodiments described and shown in the accompanying drawings.

Modifications remain possible, in particular from the point of view of the constitution of the various elements, or by substitution of technical equivalents, without thereby departing from the scope of protection of the invention.

Claims (10)

- R E V E N D I C A T I O N S  1. Solar collector, in particular for air conditioning, characterized in that it is constituted by an air circulation collector (1) comprising a black body (2) in the form of an assembly of hollow elements (3) with baffles , closed at its front part by a glazed element (4) simple or multilayer, and provided at its rear part with an insulating layer (5), by a lower duct (6) of air inlet to be heated connected to the room to be air-conditioned, by a duct (7) for leaving hot air to the room to be air-conditioned, by a valve (8) for the arrival of cold air, by a valve (9) for adjusting the flow of hot air, allowing a total or partial evacuation of said hot air through an opening of the sensor (1), by a channel (11) of condensing water extending longitudinally in the lower part of the sensor (1) and connected to a pipe (12 ) evacuation of said water, and by one or more sets (13) of photovoltaic cells arranged in the upper part of the solar collector (1) and / or above s of the latter.  2. solar collector according to claim 1, characterized in that the black body (2) consists of corrugated elements (14) of metal or synthetic material mounted on a layer of insulating material (5) and provided on their face before a coating (15) closing the corrugations (14 ') in the form of a perforated film or not of transparent or non-transparent synthetic material, in the form of perforated fabric or not, or in the form of perforated metal or not.  3. solar collector according to claim 1, characterized in that the glazed element (4) closing the collector (1) is in the form of a thin layer of glass (4 ') in the lower part of the collector (1) and in the form of a thicker layer (4 ") of double or triple glass in the upper part of the sensor (1).  4. Solar collector according to claim 1, characterized in that the cold air inlet valves (8) and hot air flow adjustment (9) are manually controlled or by thermostat reacting to the temperature of the local, or power-assisted.  5. Solar collector according to claim 1, characterized in that the assemblies (13) of photovoltaic cells are integrated in the collector (1), for example at the level of the duct (7) and above the collector (1), for example at the joint between stages, and can be used for the production of the electrical energy necessary for controlling the valves (8 and 9) as well as possibly of air conditioning accessory devices such as fans (22) for setting air circulation, electric heating resistors, and the like.  6. solar collector according to claim 1, characterized in that it is completed by an internal channel (16) connected to the duct (7) and provided with a fan (17) propelling the hot air down the room , this fan being able to be supplied with electric current from the network or coming from the batteries of the assemblies (13), and an electric heating element (18) which can be arranged in front of the air outlet of the channel (16) to serve for the supply of an additional heat, this element (18) can also be supplied by the battery assemblies (13), or by the electrical current of the network.  7. solar collector according to claim 6, characterized in that, in its upper part, the channel (16) is connected, by means of a ventilation valve (19), to a ventilation casing (20) containing an air circulation fan (21) allowing to play on the possibilities of ventilation or air conditioning.  8. Solar collector according to claim 6, characterized in that the internal channel (16), provided with a fan (17), is connected to an accumulation radiator (23) provided with an air circulation fan (24), the radiator heating air (23) being returned to the sensor (1) by a return line (25).  9. Solar collector according to claim 1, characterized in that a heat exchanger (26) with water circulation is arranged in the upper part of the collector (1) before the duct (7) for the departure of hot air. to the room to be air conditioned, this exchanger (26) can be connected to a domestic hot water or heating circuit, or even to a heat pump.  10. Solar collector according to claim 9, characterized in that a heat exchanger (26) is in air circulation and forms the cold source of a heat pump of the air-air or air-water type.