FR2629677A1 - Greenhouse installation with recuperation of solar energy - Google Patents

Abstract

Greenhouse installation with recuperation of solar energy. It comprises a greenhouse 2, at least one solar energy collector 8, a storage tank 6 located inside the greenhouse 2, a heat exchange circuit 22, 26, 28 contained inside the greenhouse, means 26 for circulating a heat-transfer fluid between the said heat-exchange circuit and the storage tank on the one hand and between the solar collector 8 and the storage tank 6 on the other hand. The means for circulating the said heat-transfer fluid comprise a series of pipes 30 located inside the greenhouse, these pipes 30 including one end connected to a fluid distributor 26 connected to the tank 6 by a pipeline 22.

Description

SOLAR ENERGY RECOVERY GREENHOUSE INSTALLATION
DESCRIPTION
The present invention relates to a greenhouse installation recovering solar energy.

 To ensure a minimum temperature for plants, greenhouses require auxiliary heating. This heating is generally obtained by fossil fuels or electric heating.

 This results in an increase in the cost of operating the greenhouse. This is why we tried to use solar energy for heating greenhouses.

Greenhouses heated by means of conventional type solar collectors are known, for example. These sensors consist of a metal plate on
which is a heat transfer fluid, generally
the water. However, such greenhouses are expensive to
installation and require significant maintenance and technical support.

There are also greenhouses with thermal accumulation in which a quantity of
heat is stored in the greenhouse floor at
during the day to be returned during the night.

However, these greenhouses do not allow
flexible operation. In particular, it is not
possible to cool the greenhouse during summer.

We also know an installation of
clinatization of a greenhouse which has two transparent walls delimiting an intermediate space filled with a heat-transfer liquid and an accumulation tank. A pump ensures your circulation in
closed circuit of the heat transfer liquid in the spaces
Intermediaries delimited by the two transparent walls. However, a greenhouse of this type has a cost of production which is too high.

 The present invention specifically relates to a greenhouse installation with solar energy recovery which makes it possible to remedy the drawbacks listed above.

 More specifically, the subject of the invention is a greenhouse installation making it possible to obtain partial or even total thermal autonomy, capable of being suitable for isolated geographic areas or areas with low soil value. This greenhouse must have a cost price and an operating cost as low as possible.

More specifically, the invention relates to a greenhouse installation recovering solar energy comprising: - a greenhouse, - at least one solar energy collector, - a storage tank located inside the
greenhouse, - a heat exchange circuit contained in the
greenhouse, - means for ensuring circulation of a fluid
coolant between said heat exchange circuit
and the storage tank on the one hand, and between the
solar collector and other storage tank
go.

 According to a preferred embodiment of the greenhouse installation according to the invention, the means for circulating said heat transfer fluid comprise a series of pipes located inside the greenhouse, these pipes having one end connected to a distributor of fluid connected to the basin by a pipe. Said solar collector comprises a water distributor connected to the basin by a pipe on which is interposed a circulation pump and a collector to ensure the return of the fluid to the storage basin.

 According to another characteristic, the sensors are given a natural slope, which allows them to drain automatically by gravity in the evening, and eliminates any risk of freezing.

Other features and advantages of
The invention will also appear on reading the following description of an embodiment of the installation according to the invention, given by way of illustration and in no way limitative, with reference to the following appended figures:
FIG. 1 is a perspective view of a greenhouse installation in accordance with the present invention,
FIG. 2 is a detailed perspective view showing the end of the pipes arranged under the rows of plants,
FIG. 3 is a perspective view on a larger scale of the solar collectors used in a greenhouse according to the invention,
FIG. 3a is a detail view showing a range of distribution of the water in the solar collector of FIG. 3,
FIG. 4 is a detailed view in section along the longitudinal direction of a solar collector shown in FIG. 3, showing the evacuation of the heat-carrying fluid from the collector,
- Figure 5 is a detail view showing a reduction nozzle -the outlet diameter of a pipe forming part of a sensor. sun in accordance with the invention.

FIG. 1 shows a perspective view of a greenhouse installation according to the invention. The installation includes a greenhouse 2, which can be single-walled or double-walled. Inside the greenhouse 2 there are plants 4 arranged in rows. The rows 4 are separated by aisles which allow circulation. Pipes 30 installed under the plants (see Figure 2) for the circulation of a heat transfer liquid, generally water, provide air conditioning for the greenhouse. On the other hand, inside the greenhouse, there is a storage tank 6 and outside the greenhouse at least one solar collector 8 (four in
The example of embodiment shown).

 The installation includes means for ensuring the circulation of water from the storage tank 6. These means include a first circuit consisting of a pipe 10 plunging into the storage tank 6 and a circulation pump 12 mounted on the pipe 10. At its other end, the pipe 10 is connected to a distributor 14 which makes it possible to distribute the water between each of the four solar collectors 8 then between the different pipes which constitute each of these collectors.

 At the other end of the solar collector, there is a collector 16 which makes it possible to recover the water at the outlet of the pipes 18. The structure of the collector 16 will be explained in more detail in the following description.

 From the collector, a pipe 20 ensures the return of water to the storage tank 6.

As can be seen in FIG. 1, the plane of the sensors is inclined at an angle relative to the horizontal H in order to allow gravity flow of the heat transfer fluid. In addition, air intakes 50 are provided at the head of the sensor, that is to say at the highest part of this sensor. This ensures draining of the gravity sensor when the circulation pump 12 stops. This arrangement avoids having to incorporate an anti-freeze liquid in
The heat transfer fluid.

On the other hand, the installation comprises a second circuit independent of the sensor circuit 8, making it possible to ensure the circulation of water to
The interior of the greenhouse. This circuit consists of a pipe 22 plunging into the storage tank 6 and connected to a dSist-ripper 26 located at the highest part of the greenhouse. The distributor 26 allows the water to be distributed inside the pipes buried in the soil of the greenhouse under the rows of plants 4, or simply placed on the floor of the greenhouse. A circulation pump 24 circulates the heat transfer fluid in the pipe 22.

At the end of the greenhouse opposite to the distributor 26, there is a collector 28 which collects the water at the outlet of the pipes arranged between
The rows of plants. As can be seen in FIG. 1, the collector 28 is inclined at an angle ss relative to the horizontal in order to ensure the return by gravity of the water in the storage basin 6.

 FIG. 2 shows an enlarged perspective view of the end of the pipes, ending in the manifold 28.

 We will now describe in more detail, with reference to Figures 3 to 5, The structure of the solar collector forming part of a greenhouse installation according to the invention.

The pipes 18 rest on an insulating support 32 preferably made of polyethylene, which makes it possible to isolate the pipes from the ground so as to limit the heat losses. As we can see on La
Figure 3, The pipes are arranged in sinuso; on the
support 32. They are distributed in parallel layers. The
sinusoidal shape of the pipes allows them to absorb their
significant thermal expansion due to variations
of temperature.

The pipes 18 are preferably made of
black polyethylene. The inner section of the pipes
will be for example 13 mm and their outside diameter of
16 mm. However, this example is not limiting and it
it goes without saying that smaller or larger pipes
could other used. Their length and
internal roughness have been optimized according to the water flow.

At the outlet of the pipes, the passage section
water has been reduced to obtain a filling
total water while minimizing the
power consumption of pumps. As we can
see in figure S, the section of
passage by means of sheaths 34 mounted on the end
pipes 18 and having a passage section
scaled down. These sheaths 34 are heat-shrinkable nozzles allowing total filling of the pipes 18.

Each of the plies of pipes 18 is
covered with a stretched transparent plastic material 36
on a plurality of arches such as 38 in order to
build a greenhouse tunnel that limits losses
thermal due to wind. At each end of
these tunnels, air circulation orifices 42 have
are designed to eliminate condensation of the vapor
of water on the walls which would cause a loss of
thermal efficiency of the collectors.

Note on Figure 3a the combs of
distribution 44 which allow water supply
pipes 18. The combs 44 are fixed by
clamps at the end of these pipes.

 There is shown in Figure 4 a sectional view of the manifold 16. A concrete discharge pipe 46 is embedded in a concrete block 48 forming a funnel. Holes are drilled in the concrete pipe to allow water to enter. The drain pipe 20 (see Figure 1) brings the water back to the storage tank 6.

Preferably, a black film is placed under the sensor, that is to say between the polystyrene plate 32 and the plies of pipes 18. The purpose of this black film is to avoid the appearance of plants in the sensor. In the same way, we avoid the presence of algae in
Circulating water due to the fact that the pipes are black. Thus, water is sheltered from light. It is not necessary to provide chemicals to avoid the appearance of algae.

 Finally, the installation comprises a temperature sensor 52, disposed at the outlet of the pipes 18 and making it possible to trace the temperature of the water at the outlet of the sensor. Another sensor 54 identifies the temperature of the water in the storage tank.

The data provided by your sensors 52 and 54 are transmitted to a case 56 which makes it possible to control the starting and stopping of the pump 12. The case 56 allows the circulation of the pump 12 to supply one 65th of the sensor per cell twilight to allow the watering of the temperature sensor output sensor. The rest of the solar energy sensor 18 is put into service when the difference between the temperature of the water at the outlet of the sensor as measured by the sensor 52 and the temperature of the water in the storage tank 6 is positive.

The operation of the installation is as follows: during the cold season and during the
day, the heat transfer fluid is circulated inside the circuit defined by the pipe 10, the distributor 14, the pipes 18 of the sensors 8, the collector 16 and the return pipe 20 if the conditions of water temperature at the sensor outlet and basin are filled. Thus, the water contained in the storage tank 6 heats up throughout the day. At the end of the day, an automation boot 56 which controls the stopping and starting of the pumps 12 and 24 interrupts the operation of the pump 12. The water thus ceases to circulate in the sensors which are emptied gently by gravity while the water returns to the basin via the line 20. It goes without saying that this line is arranged in such a way that the return of the water takes place by gravity from the collector 16 to the storage basin 6. Automation 56 is controlled by any known means such as a timer, a photoelectric cell capable of detecting a drop in the brightness of the atmosphere or any other means known to those skilled in the art.

If the temperature of the air inside the greenhouse is lower than the minimum imposed, the pump 24 is put into operation, which makes it possible to circulate the water inside the circuit defined by the pipe 22, the distributor 26, the pipes 30 arranged on the ground surface between the rows 4 of plants or even buried in the soil of the greenhouse between these rows of plants 4, and the collector 28.

The water contained in the storage tank, which has been heated during the day, thus makes it possible to heat the greenhouse throughout the night.

 During the hot season, a reverse operating scheme is used. This is because the heat in the greenhouse may be too high, which may affect plant growth. It is therefore necessary to refresh the interior atmosphere. This is obtained by circulating the water contained in the storage tank 6 overnight å the interior of the collectors 8 which no longer play the rye of solar collectors but The role of heat exchangers to cool the water temperature. During the day, this chilled water contained in the storage basin is circulated by the pump 24 in the pipes 30 arranged between the rows of plants. We thus recover calories, which refreshes the interior atmosphere of the greenhouse.

 The installation which has just been described has many advantages over previously known devices. It allows a good efficiency of capture of the solar radiation, - a simple assembly, a long life, comprising little maintenance, an easy exploitation and a resistance to the wear and the high functioning.

EXAMPLE OF IMPLEMENTATION
We carried out an installation in accordance with
2 the invention comprising a 900 m chapel greenhouse with translucent plastic walls, covered with an inflatable flysheet ensuring good insulation.

3
The water basin has a capacity of 150 a. The first results show that a collection efficiency of 50% can be achieved, making it possible to save 60X on the greenhouse heating station under the Latitude of Pierrclatte and lOOX at lower latitudes.

Claims (7)

 on the other hand.  the solar collector (8) and the storage tank (6)  heat and the storage tank on the one hand, and between  heat transfer fluid between said heat exchange circuit  in the greenhouse, - means (26) for ensuring the circulation of a  greenhouse (2), - a heat exchange circuit (22, 26, 28) contained  t. Solar energy recovery greenhouse installation comprising - a greenhouse (2), - at least one solar energy collector (8), - a storage tank (6) located inside the  2. Installation according to claim 1, characterized in that the means for circulating said heat transfer fluid comprise a series of pipes (30) located inside the greenhouse, these pipes (30) having one end connected to a distributor of fluid (26) connects to the basin (6) by a pipe (22), said solar collector (8) comprising a water distributor (14) connects to the basin (6) by a pipe (10) on which a pump is inserted circulation (12) and a manifold (18) to ensure the return of the fluid to the storage tank (6). 3. Installation according to any one of claims 1 and 2, characterized in that the sensor (8) consists of black plastic pipes (18) arranged in sinusoid and in layers on an insulating support (32).  4. Installation according to claim 3, characterized in that the insulating support (32) is made of poLystyrene.  5. Installation according to any one of claims 1 to 4, characterized in that the sensor (8) comprises a superstructure (36, 38) of cover provided with ventilation openings (42).  6. Installation according to any one of claims 1 to 5, characterized in that the heat transfer fluid is automatically drained by gravity in the storage tank upon stopping the circulation of the fluid contained in the sensor pipes.  7. Installation according to any one of claims I to 6, characterized in that the pipes (18) of the school sensors are terminated by heat-shrinkable ends (34) or other reduction means which allow complete filling of the pipes.