FR2979423A1 - SOLAR DRYING GLASS WITH HEATED FLOOR HEATED THROUGH SOLAR ENERGY - Google Patents

Abstract

A sludge drying installation comprises a greenhouse 3 provided with a heating floor 4 equipped with a set of pipes 6 supplied with a heat transfer fluid. The installation further comprises a solar heating device 7 of the heat transfer fluid which makes it possible to maximize the use of solar energy 10 in the drying operation and various heating devices in parallel. This combination of heating devices can be particularly interesting in case of malfunction of one of the heating systems, for example in case of low sunlight.

Description

TECHNICAL FIELD OF THE INVENTION [001] The present invention relates to a sludge drying device as well as to a sludge drying method combining solar drying in a greenhouse with a greenhouse. heated floor supplied with a heat transfer fluid. STATE OF THE ART [2] Sludge is the result of the treatment of wastewater and liquid effluents. Their production, and consequently their volume, have steadily increased in recent years: this is why solutions have been developed to eliminate these sludges and if possible to develop them. Several processes exist for this, such as incineration or co-incineration, storage or agricultural upgrading. However, for these processes to be implemented, the sludge must first be dried, totally or partially according to the processes, in order to reduce their volume, to facilitate their handling, to improve their appearance, to hygienize them or to increase their dryness. [3] Various processes for sludge drying have therefore been developed: in this field, there is solar drying which consists of placing the sludge in greenhouses. This technique is particularly advantageous, especially in sunny areas, because it allows for simple, economical and ecological installations. However, it has the disadvantage of requiring large areas of greenhouses, resulting in significant costs and implementation difficulties. In addition, the drying is dependent on the diurnal cycles, and the overall profitability of this type of installation is low. [004] In order to reduce the area of the greenhouses and to increase their productivity, the greenhouse sludge drying technique has therefore been associated with sludge heating by underfloor heating. This floor can be heated by various means such as geothermal, or boilers of different types. Thus the document FR2843957 describes a greenhouse sludge drying system associated with heating underfloor heating, heated by wind turbines generating energy which is degraded as heat and then returned to the floor. The prior art also knows the document FR2873680 which describes a heating floor heated by the evaporated steam of the sludge whose calories are recovered via a water / water or air / water heat exchanger. However, these two heating floor heating processes require heavy, complicated and expensive installations. [005] These different solutions can overcome a lack of sun or insufficient length of the diurnal cycle. However, they do not make it possible to optimize the solar yield of the installation.

OBJECT OF THE INVENTION [6] The present invention aims to overcome the drawbacks of the state of the art by proposing a sludge drying process combining the use of a solar greenhouse and a floor heating comprising a network. It is powered by water heated with solar water heaters, so as to make the most of the solar energy available on the site, without unduly increasing the greenhouse area. [7] The present invention is directed to sludges from the treatment of wastewater and effluents, but also to any other material containing water and solids in suspension or in a homogeneous mixture in water, which have a liquid to pasty consistency, such as silt, mud or droppings. In the following, the term "sludge" will also refer, by extension, these materials. [8] More particularly, the present invention relates to a sludge drying installation, comprising a greenhouse provided with a floor heating comprising a set of pipes supplied by a heat transfer fluid, the installation comprising a heating system comprising at least one device solar heating of the coolant. [9] The solar heating devices make it possible to heat the heating floor at a lower cost, in an ecological manner, by a method that is simple to implement. Thus, the heating floor conductive heats the lower layers of the sludge that covers it, which accelerates the drying of the sludge and thus reduce the required greenhouse area. This combination of techniques therefore makes it possible to optimize the use of solar energy for sludge drying without incurring significant additional costs. It is therefore particularly adapted to sites with strong sunshine, especially in intertropical areas. According to different embodiments of the present invention, the solar heating devices can be arranged outside the greenhouse or in the greenhouse. Advantageously, the heating system further comprises a device for heating the heat transfer fluid by geothermal energy. It then takes advantage of another heat source used especially during the night so as to regulate the temperature cycle of the sludge for example to maintain a constant temperature. Advantageously, the heating system also comprises a heat transfer fluid heating device using a heat pump whose cold source is located outside the greenhouse. This heat pump can be powered by any suitable energy source, including a wind turbine coupled to an electric generator. Advantageously, the heating system further comprises a heat transfer fluid heating device using the heat stored by the air inside the greenhouse, via a heat exchanger. Indeed, the combination of several different heating devices optimizes the heating of the heat transfer fluid. By arranging 5 different heating devices in parallel, it is possible to increase the flow rate of the coolant for a given temperature differential between the inlet and the outlet of the heating floor. This combination of heating devices can also be particularly advantageous in the event of a malfunction of one of the heating systems, for example in the case of low sunlight. According to one embodiment of the present invention, the solar heating device further comprises at least one heat exchanger between a heat transfer circuit internal to one of the solar heating devices and the heat transfer fluid. The solar heater can then be designed and optimized independently of the size of the pipeline assembly. Alternatively, it is also possible to directly heat the heat transfer fluid of the underfloor heating in the solar water heater without intermediate circuit. [0016] Advantageously, one of the heat exchangers uses the air contained in the greenhouse to heat the heat transfer fluid. Advantageously, the heat transfer fluid is a liquid. Furthermore, the installation also preferably comprises a device for cleaning the air contained in the greenhouse and a device for evacuating the water vapor produced during the drying of the sludge. [0019] The cleansing of the air and in particular the treatment of odors emanating from the sludge make it possible to minimize the environmental nuisances of the greenhouses while the evacuation of the water vapor makes it possible to accelerate the drying of the sludge and therefore reduce the surface area and volume of greenhouses. [0020] The invention also relates to a sludge drying process combining solar drying in a greenhouse with a heated floor, in which the heating floor is fed with a heat transfer fluid heated by at least one solar heating device. According to a particular embodiment, the heat transfer fluid is further heated by a geothermal source. [0022] Advantageously, the coolant can be further heated by the air flowing inside the greenhouse, via a heat exchanger. BRIEF DESCRIPTION OF THE FIGURES [0023] Other characteristics and advantages of the invention will emerge on reading the description which follows, with reference to the appended figures, which represent: FIG. 1 is a schematic perspective view of a greenhouse associated with a floor heating according to a first embodiment of the present invention; Figure 2 is a schematic representation of a floor heating and heating system according to a second embodiment of the present invention. EXEMPLARY EMBODIMENT [0024] With reference to FIG. 1, a sludge drying installation according to the present invention comprises a storage device 8 for the sludges 1 making it possible to feed the greenhouse 3 with sludge thanks to a feeding device 2 The greenhouse 3 consists of transparent walls 9 which make it possible to increase the efficiency of the solar energy 10. The greenhouse 3 also comprises a heating floor 4 which comprises a set of ducts 6 arranged between an inlet 61 and an outlet 62 connected to an external circuit 11. In the pipes 6 and the external circuit 11 flows water entrained by a pump 14. The outer circuit 11 comprises a plurality of solar water heaters 7 arranged in parallel and providing heating of the water. Naturally, there may be provided isolation valves 30 of each water heater, activated in case of failure of a water heater. Furthermore, the installation also comprises a sludge reversal device 5 for homogenizing the sludge drying. [0025] Figure 2 schematically shows a set of ducts 6 and a heating system 13 according to a second embodiment of the present invention. The pipe assembly 6 forms with an external circuit a closed circuit 6, containing a heat transfer fluid, which runs through a heating floor 4 and a heating system 13. The heat transfer fluid is set in motion in the circuit 6 using pump 14. The heating system 13 has in series a first heating device 15 for heating the water by geothermal energy, followed by a second heating device 16 using the heat stored in the air 12 to the inside of the greenhouse, through a heat exchanger 26, for heating the coolant flowing through the circuit 6. The heat transfer fluid then travels in parallel three heat exchangers 17, 18, 19 to gradually heat the heat transfer fluid through the energy stored by three internal heat transfer circuits 20, 21 and 22 to three solar heating devices 23, 24 and 25. [0027] This heating system 13 comprising a succession of heating devices 15 to 26 of the heat transfer fluid allows to combine day heating modes and night heating modes. It also allows heating the heat transfer fluid in stages to reach higher temperatures at the entrance of the heating floor. Of course, many variants are possible: the fluid heating system may, for example, contain many other heat transfer fluid heating devices, such as for example one or more electric boilers or wind energy heating devices such as those described in the patent FR2843957, which may be useful when the rate of sunshine decreases or nighttime. In addition, the heat transfer fluid can be of any kind, including gaseous and it is also possible to consider using two different heat transfer fluids in the heating system depending on the heating devices used. Furthermore, the sludge drying installation may also include a convective sludge drying device circulating another heat transfer fluid directly into the greenhouse.

Claims (14)

REVENDICATIONS1. Sludge drying installation, comprising a greenhouse provided with a heated floor comprising a plurality of pipes supplied with a heat transfer fluid, characterized in that the installation comprises a heating system comprising at least one solar heating device for the coolant and in that the installation comprises different heating devices in parallel. 2. Sludge drying plant according to claim 1, characterized in that at least one of the solar heating devices is disposed outside the greenhouse. 3. sludge drying installation according to claim 1, characterized in that at least one of the solar heating devices is disposed in the greenhouse. 15 4. Sludge drying installation according to any one of the preceding claims, characterized in that the heating system further comprises a heating device of the heat transfer fluid geothermal. Sludge drying plant according to one of the preceding claims, characterized in that the heating system further comprises a heating fluid heating medium using a heat pump whose cold source is located outside. from the greenhouse. Sludge drying installation according to one of the preceding claims, characterized in that the heating system further comprises a heat transfer fluid heating device using the heat stored by the air inside the greenhouse. , via a heat exchanger. 7. Sludge drying installation according to any one of the preceding claims, characterized in that the solar heating device further comprises at least one heat exchanger between a heat transfer circuit internal to one of the solar heating devices and the heat transfer fluid. . 8. Sludge drying installation according to any one of the preceding claims, characterized in that the heat transfer fluid is a liquid. 9. Sludge drying plant according to any one of the preceding claims, characterized in that the installation further comprises a sludge reversal device. 10. Sludge drying installation according to any one of the preceding claims, characterized in that the installation further comprises a device for cleaning the air contained in the greenhouse. 15 11. Sludge drying installation according to any one of the preceding claims, characterized in that the installation further comprises a device for evacuating the water vapor produced during the drying of the sludge. 12. Sludge drying process associating a greenhouse drying under a greenhouse underfloor heating, characterized in that the heating floor is fed with a heat transfer fluid heated by at least one solar heating device. 13. Method of drying sludge according to claim 12, characterized in that the coolant is further heated by a geothermal source. 14. Method of drying sludge according to any one of claims 12 or 13, characterized in that the heat transfer fluid is outresheated by the air flowing inside the greenhouse.