WO2007134770A1

WO2007134770A1 - System for solar drying of substrate

Info

Publication number: WO2007134770A1
Application number: PCT/EP2007/004356
Authority: WO
Inventors: Kurt Spiegel
Original assignee: Asw Anlagenbau Schlamm- Und Wassertechnik Gmbh
Priority date: 2006-05-19
Filing date: 2007-05-16
Publication date: 2007-11-29

Abstract

The invention relates to a system for solar drying of substrate, especially clarified sludge, which has a drying surface (3) that can be impacted by solar energy onto which the substrate to be dried can be applied, and a heating device (8) for heating the substrate to be dried, wherein the heating device (8) has at least one pipe (6) through which a heating medium can be fed. According to the invention, the heating device (8) is constructed as a thermal solar system (8') that has at least one solar collector (9) by which the energy required for heating the heating medium located in the at least one pipe (6) can be produced.

Description

Plant for solar drying of substrate

description

The invention relates to a plant for the solar drying of substrate, in particular of sewage sludge, which can be acted upon by solar energy drying surface on which the substrate to be dried can be applied, and a heater for heating the substrate to be dried, wherein the heater has at least one tube through which a heating medium is conductive, and a method for solar drying of substrate, in particular sewage sludge, in which the substrate located on a drying surface is exposed to solar energy and heated by a heater by a heated heating medium is passed through the drying surface. Such a plant and such a method are known and are used, for example, for drying sewage sludge, which are obtained in large quantities in wastewater treatment and have a high moisture content. In order to reduce the mass of the material to be disposed of and to reduce transport costs, as well as to enable a stable storage on landfills or a subsequent combustion, moisture is removed from the sewage sludge. There are several approaches to choose from: In the case of thermal full drying, the sludge is dried in the oven or by means of hot air, whereby considerable amounts of process water and high energy costs are incurred. In contrast, solar dehumidification uses solar energy to dry sewage sludge. For this purpose, the material to be dried is spread on a surface which is covered by a building that is substantially transparent to the sun's rays. In this way, on the one hand rainwater is held off, on the other hand prevented by using the greenhouse effect, the registered by solar heat energy from escaping and thus increases the drying effect compared to a drying without a greenhouse building. The removal of moist air and the introduction of fresh air takes place by means of a suitable ventilation device, so that the moisture can evaporate on the surface of the material spread on the ground. In cavities between particles of the material to be dried, however, a saturation vapor pressure sets in after a short time. Since this saturated air moves to the surface only very slowly, turning the material can significantly increase the rate of water discharge. For this purpose, different turning and / or transport facilities are used, which either only mix the material or additionally transported through the greenhouse.

However, such solar drying of sludges is disadvantageously strongly dependent on the given and unimpeachable solar radiation and is therefore subject to strong seasonal fluctuations. So Drying, for example, almost completely stops in winter, so that a considerable part of the resulting sludge has to be stored temporarily.

In the known systems for solar drying therefore heaters are often used, for example, by laying in the bottom of the building under the expanded material pipes and these flowing through heated liquid according to the principle of underfloor heating heat the spread material. The energy necessary for heating the liquid is provided in these systems, for example by an oil or gas firing or electric heating available.

However, such known systems have the disadvantage that as a result of the additional heating high energy and thus running costs of the system arise. In addition, occur in the generation of necessary for heating the liquid energy usually significant environmental pollution, since the majority of the burning of fossil primary energy sources is used.

A device for drying moist material is described in DE 195 08 400, in which a drying air stream is passed through solar air collectors before entering a drying device and the air stream thus heated then applied to the moist material or interspersed. In this case, however, there is an adverse identity of heating medium and drying medium, so that the increasingly permeated with moisture air can only be supplied to a limited renewed heating and therefore constantly new outside air must be heated to the desired temperature.

In DE 43 15 321 a device and a method for drying sludges and contaminated liquids are described in which a drying takes place in a transparent building with the aid of solar radiation. To increase the drying process, a device in the form of a floor heating is also proposed. However, no statements are made about the type of heating of a heating medium to be used therein.

Furthermore, in DE 33 12 329 describes a growing soil used as a storage medium heat storage tank for use in building heating, the heat source is only temporarily effective, in particular solar collectors. Among other things, a heat exchanger is provided, whereby different circuits with different pressures and / or different chemical compositions such as antifreeze additive are possible.

It is therefore an object of the present invention, a system and a method of the type mentioned in such a way that a heating of the substrate to be dried in a cost-effective and environmentally friendly manner is possible.

This object is achieved by the system according to the invention in that the heating device is designed as a thermal solar system having at least one solar collector through which the energy required to heat the located in the at least one tube heating medium can be generated.

The inventive method provides that a heating device designed as a thermal solar system is used, through which the energy required for heating the heating medium is obtained.

The measure according to the invention of a heating device designed as a thermal solar system advantageously makes it possible to use the naturally existing solar radiation in two ways. The previous use of solar energy by utilizing the direct sunlight is now additionally supported by the fact that through the at least one solar collector -. and thus likewise by utilizing the natural solar radiation - the heating medium is heated, which then flows through one or more tubes for heating the substrate spread on the drying surface. An advantage of the system according to the invention lies in the low operating costs of the system and the environmentally friendly underlying method.

Another advantage of the system according to the invention is the reduction of the seasonal power fluctuations, since the designed as a solar thermal system heater is operable even at temperatures below the 0 ° C limit. Due to the increased drying performance of the system according to the invention necessary intermediate storage capacities are reduced in an advantageous manner by shortening the drying times, reduced transport costs due to decreasing by increasing dry residue mass and stable storage of the final material in landfills or thermal utilization such as energy for cement kilns allows.

An advantageous development of the invention provides that the heater has a heat storage, which is connected via a primary circuit with the at least one solar collector. As a result, the heating medium heated by the solar collector and the heat energy contained therein can be stored in an advantageous manner. This makes it possible, for example, to store energy during the day when there is a high level of solar radiation and to deliver it to the material at night.

A further advantageous embodiment of the invention provides that the thermal solar system has two separate, coupled by a heat exchanger heating medium circuits for separate operation of heat generation and heat dissipation. A further advantageous development of the invention provides that the pipes of the system through which the heating medium can flow are subdivided into a plurality of separate segments which can be acted upon by the heating medium. This has the advantage that the heating in these segments can be switched on and off separately so that parts of the drying surface can be used as open space and batch or batch operation is made possible.

A further advantageous development of the invention provides that at least one hall-like, preferably greenhouse-like, building is constructed above the drying area, the floor of which preferably forms the drying area. In this way, the greenhouse effect can be used for drying in an advantageous manner, as well as precipitation are kept away from the substrate.

A further advantageous development of the invention provides that the liquid heating medium of at least one circuit is mixed with an antifreeze. In this way, on the one hand prevents freezing of the circuit in winter, on the other hand, the antifreeze usually increases the boiling point of the heating medium, so that boiling of this heat-carrying liquid is prevented even at maximum standstill temperature of the solar panels.

Further advantageous developments of the invention are the subject of the dependent claims.

Further details and advantages of the invention can be taken from the exemplary embodiment, which is described below with reference to the figures. Show it:

FIG. 1 shows a schematic representation of an exemplary embodiment of the installation,

Figure 2: a schematic representation of a heater of the embodiment. In the figures 1 and 2, an embodiment of a plant 1 for the bisolary drying of substrate is shown, which serves as Appendix 1 for the bisolary drying of sewage sludge. The plant 1 includes - in the case described here - two hall-like buildings 2a, 2b, which have at least partially transparent roofs and / or walls for solar radiation. It is clear to the person skilled in the art that the described case of an installation 2 having two buildings 2a, 2b has only an exemplary character. Of course, it is possible to provide even one building 2a or more than two buildings 2a, 2b. It will also be apparent to those skilled in the art from the following description that while the use of indoor buildings 2a, 2b is preferred, it is not necessary. It is sufficient that the system 1 has a drying surface 3, on which the substrate to be dried, here the sewage sludge to be dried, can be applied and thermally acted upon by solar radiation. However, the use of buildings 2a, 2b has the advantage that in the buildings 2a, 2b, the substrate to be dried can be stored protected from environmental influences and it is possible through a greenhouse-like design of buildings 2a, 2b, the greenhouse effect of such a trained building 2a, 2b for drying the sewage sludge to use.

As drying surfaces 3 for the substrate to be dried act here floors 3a, 3b of the building 2a, 2b, in which pipes 6 are arranged, through which a heating medium flows and thus the bottoms 3a, 3b and thus the substrate 3a, 3b mounted on these floors heated in the manner of a floor heating.

In contrast to the known monosolar systems in which the energy input into the substrate to be dried, although also by natural sunlight, the heating of the pipes 6 flowing through the heating medium, however, by conventional energy sources, is provided in the embodiment described here, that the pipes. 6 flowing through the heating medium by a designed as a thermal solar system 8 ¹ heater 8 - ie also by the natural solar radiation - is heated. Such a measure has the advantage that the energy required for heating the bottoms 3a, 3b and the sewage sludge to be dried thereon is provided exclusively by the natural solar radiation. In this way, not only the ongoing energy and operating costs are reduced, but also reduces the environmental impact of such systems by now no longer rely on fossil fuels for heating the pipes 6 flowing through the heating medium.

Another advantage of the system 1 described is that a significant increase in the performance of the system 1 is achieved by this bisolary drying of the system compared to monosolar systems, resulting in a shortening of the drying period and / or an increase in the percentage dry residue in the substrate leads. This has in turn in an advantageous manner the result that at shorter drying periods less delivered sewage sludge must be stored before its drying on a storage space 4 of the system 1. With a higher degree of drying and the concomitant reduction in the mass of the substrate to be dried decrease in an advantageous manner, the cost of its removal. Furthermore, this has the advantage that it is now possible to store the dried sewage sludge stable on landfills or to supply thermal utilization as a result of the lower moisture content.

The solar thermal system 8 'is now shown schematically in Figure 2. It has solar collectors 9, which are arranged in the embodiment described here on the roof of a technical building 5. The heating medium located in a primary circuit 10, preferably a suitable liquid, is heated as it passes through the solar collectors 9 of the solar system 8 ¹ and then passes into a heat accumulator 14, which communicates with a heat exchanger 13. From the heat exchanger 13 is a secondary circuit 12, which directs the heated by the heat exchanger 13 heating medium of the secondary circuit 12 to the tubes 6 of the bottoms 3a, 3b.

The skilled person is apparent from the above description that the formation of the heater 8 with heat storage 14 and heat exchanger 13 is indeed preferred, but not mandatory. It is also possible, for example, to connect the solar collectors 9 directly to the tubes 6 via a single circuit.

The regulation of the primary circuit 12 is preferably carried out by a temperature difference control, by means of a measurement of the temperature of the heating medium in the solar collector 9 and its temperature in the heat storage 14: If the temperature of the heating medium in solar collector 9 above a temperature of the heating medium in the heat storage 14, the Open primary circuit 10 and so introduced via the heating medium heat in the heat storage 14. If the temperature of the heating medium in the solar collector 9 is below that in the heat accumulator 14, an inflow of the cooler heating medium located in the solar collectors 9 to the heat accumulator 14 is prevented in order to avoid cooling thereof.

The regulation of the heat supply of the tubes 6 via the secondary circuit 12 also takes place due to a temperature difference measurement between the temperature of the heating medium in the heat storage 14 and its temperature in the bottoms 3a, 3b: If the temperature in the heat storage 14 is higher than in the bottoms 3a, 3b , the secondary circuit 12 is opened to transfer heat from the heat accumulator 14 to the tubes 6 and thus to the trays 3a, 3b.

In order to be able to apply heat to individual sections of the drying surface 3, it may optionally be provided that the drying surface 3 is divided into several segments 6a - 6e is divided, which are independently acted upon by heat.

As already mentioned, it is preferred that the heating medium is a corresponding liquid, since in terms of safety and handling it has advantages over a likewise possible gaseous heating medium. When using liquid, it is preferred that an antifreeze be added to this liquid. In this way, on the one hand prevents freezing of this liquid in winter, on the other hand, the antifreeze usually increases the boiling point of the liquid, so that boiling of the heat-carrying liquid is prevented even at maximum standstill temperature of the solar panels.

Claims

claims

1. Plant for the solar drying of substrate, in particular of sewage sludge, which has a solar energy acted upon drying surface (3), to which the substrate to be dried can be applied, and a heating device (8) for heating the substrate to be dried, wherein the Heating device (8) has at least one tube (6) through which a heating medium is conductive, characterized in that the heating device (8) is designed as a thermal solar system (8 ¹ ) having at least one solar collector (9) through which the for heating the energy required in the at least one tube (6) heating medium is generated.

2. Installation according to claim 1, characterized in that the heating device (8) has a heat accumulator (14) which is connected via a primary circuit (10) with the at least one solar collector (9).

3. Installation according to one of the preceding claims, characterized in that the system (1) has a secondary circuit (12) for supplying the at least one tube (6) with the heated heating medium.

4. Installation according to one of the preceding claims, characterized in that the primary circuit (10) and the secondary circuit (12) by a heat exchanger (13) are coupled.

5. Installation according to one of the preceding claims, characterized in that the flow-through of the heating medium tubes (6) are divided into a plurality of separate acted upon by the heating medium segments (6a - 6e).

6. Installation according to one of the preceding claims, characterized in that the system comprises at least one hall-like building (2 a, 2 b), which is arranged above the drying surface (3).

7. Plant according to claim 6, characterized in that at least one building (2a, 215) is formed greenhouse-like.

8. Plant according to claim 6, characterized in that a bottom (3a, 3b) of the building (2a, 2b) forms the drying surface (3).

9. Plant according to one of the preceding claims, characterized in that the heating medium is a liquid.

10. Plant according to claim 9, characterized in that the liquid heating medium, an antifreeze is added.

11.Anlage according to one of the preceding claims, characterized in that the heat supply to the heat accumulator (14) and / or to the at least one tube (6) is controlled by a temperature difference measurement.

12. A process for the solar drying of substrate, in particular of sewage sludge, in which the substrate located on a drying surface (3) is acted upon by solar energy and heated by a heating device (8) by a heat-applying, heated heating medium to the substrate to be dried is directed, characterized in that as a solar thermal system (8 ¹ ) formed heating device (8) is used, through which the energy required for heating the heating medium is obtained.