WO1998038457A1

WO1998038457A1 - Solar power station, specially a solar power station with parabolic troughs

Info

Publication number: WO1998038457A1
Application number: PCT/DE1998/000416
Authority: WO
Inventors: Wolfgang Köhler; Reinhard Rippel; Holger Schmidt
Original assignee: Siemens Aktiengesellschaft
Priority date: 1997-02-26
Filing date: 1998-02-13
Publication date: 1998-09-03
Also published as: MA24487A1

Abstract

The present solar power station (2) comprises at least one absorption duct (6) for guiding and heating operating materials such as water. Said absorption duct (6)comprises at least two duct sections (8, 12) which are arranged in a substantially horizontal position. A third duct section (10) is placed between the first (8) and second (12) duct sections, the level (14) thereof being higher than the respective highest level (16, 18) of the interiors (20, 22) of the first (8) and second (12) duct sections, thus considerably preventing overheating of the wall in the upper area of the absorption duct (6).

Description

description

Solar power plant, in particular parabolic nominal solar power plant

The invention relates to a solar power plant, in particular to a parabolic nominal solar power plant.

From the article "Solar Farm Power Plants and Direct Evaporation m Parabolic Solar Collectors" by M. Muller, Research Association Solar Energy: "Themes 93/94", DLR, Cologne, it is known that m parabolic solar power plants worldwide generate more than 90% of the currently produced Solar electricity are produced. To further improve the market opportunities for parabolic power plants, the existing potential for increasing efficiency and reducing costs must be exploited. Around 70% of the costs of a solar power plant are caused by the collector field. The remaining 30% is accounted for by conventional plant components. This means that a reduction in costs for the collector field has a decisive impact on the total costs of the solar power plant.

Collector fields consist of a larger number of collectors, each comprising a parabolic tube for bundling the sunlight and an absorber line, for example an absorber tube, for absorbing the bundled sunlight. If the equipment to be evaporated is evaporated directly in the absorber line, this is referred to as direct evaporation.

Since the absorber line carrying an operating medium, for example water, is laid almost horizontally, with certain operating parameters, for example a low mass flow density or a high system pressure, gravity-related separation phenomena of the liquid-steam mixture of the operating medium can occur. As a consequence, that the heat transfer in the upper area of the absorber line, where steam flows preferentially, deteriorates. For this reason, for example, the temperature of the wall rises to an undesirable extent in the upper region of the absorber line. This leads to bending of the absorber line and to thermal stresses in the same.

This problem is solved in the prior art, see for example "Flow phenomena in direct evaporation in parabolic trough solar power plants" by M. Müller, VDI Progress Reports, Series 6, No. 335, 1995, in that the absorber line with a predetermined angle of inclination is installed. Since the collectors have great lengths, for example several 100 m, the costs are significantly increased by this construction with the predefined angle of inclination for the absorber line - due to the associated mechanical support for the absorber line. Since the parabolic trough solar power plant consists of a large number of such collectors, this also increases the total costs for the parabolic trough solar power plant.

Another way of reducing the temperature rise in the upper region of the wall of the absorber line is to install displacement bodies in the interior of the absorber line. Although this improves the heat transfer, it also increases the pressure loss in the interior.

The invention is therefore based on the object of specifying a solar power plant in which overheating of the wall in the upper region of the absorber line is largely avoided without pressure loss occurring in the interior of the absorber line as a result of the installation of displacement bodies. According to the invention, the stated object is achieved by a solar power plant with at least one absorber line for guiding and heating an operating medium, which comprises at least a first and a second line section, which is in each case essentially arranged horizontally, a third between the first and the second line section Line section is arranged, the level of which is higher than the highest level of the interiors of the first and second line section.

The third line section ensures that, during the operation of the parabolic trough solar power plant, sufficient resources, for example water, are present in the upper region of the first line section of the absorber line due to the accumulation of the equipment in the increase in the third line section. This largely prevents overheating of the wall in the upper region of the first line section of the absorber line. Since the first and second line sections are laid essentially horizontally, cost-intensive mechanical support for an absorber line with a predetermined angle of inclination is no longer required. In addition, displacement bodies are no longer used in the interior of the line sections, as a result of which additional pressure losses over the length of the absorber line are avoided.

The absorber line is preferably arranged in a parabolic trough. The parabolic trough and the absorber line together form a collector. Thus, in this embodiment, the third line section is arranged inside the collector. The collectors used in the prior art generally have a large length. By installing the third line section at one or more positions within the collector, overheating of the wall in the upper region of the absorber line is thus avoided. In particular, the first line section is arranged in a first parabolic trough, the second line section in a second parabolic trough and the third line section between the spatially separated parabolic troughs. In this embodiment, the third line section is arranged between two collectors. This ensures that overheating in the upper wall area of the absorber line is avoided with relatively short absorber lines and thus relatively small collectors. With larger and thus longer collectors, overheating in the last section of the absorber line of the respective collector is avoided.

In a further embodiment, the level of the third line section is approximately Im above the highest level of the interiors of the first and the second line section. This level difference ensures that there is sufficient equipment in the first power section to avoid overheating. This results in an additional pressure loss of at most 0.1 bar.

The first line section is preferably arranged in the parabolic trough and the second line section is designed as a steam separator. As a result of this measure, the operating medium, after flowing through a collector, for example the last of a series of collectors arranged one behind the other, is fed directly via the third line section into the second line section designed as a steam separator.

In particular, the angle (α) between a horizontal and the rise of the third line section is at least 10 °. Overheating is avoided above this value for the angle (α). In a further embodiment, the inside diameter of the third line section is at least equal to the inside diameter of the other line sections. This measure ensures that the speed of the operating medium, ie in other words the liquid-vapor mixture, in the third line section is equal to or less than the speed of the operating medium in the line sections which are arranged essentially horizontally. The lower the speed of the equipment in the third line section, the more equipment is jammed in the third line section. As a result, more resources are retrospectively available in the first line section to avoid overheating in the same.

The third line section is preferably formed in an arc at a transition to the first line section. This measure avoids a restriction of the flow and thus an increase in the speed of the equipment during the deflection in the third line section.

In particular, a joint that can be rotated about the longitudinal axis of the first or second line section is arranged between the third and the first or second line section. The parabolic trough and the absorber line are rotated around the longitudinal axis of the absorber line according to the position of the sun. By installing these joints, rotation of the third line section is avoided and the level difference is thus maintained.

For a further explanation of the invention, reference is made to the exemplary embodiments of the drawing. Show it:

1 shows a side view of a section of a parabolic trough solar power plant in a schematic representation; 2 and 3 show further sections from a parabolic trough solar power plant in a perspective view.

According to FIG. 1, a parabolic trough solar power plant 2 comprises a parabolic trough 4 and an absorber line 6, for example an absorber tube, arranged largely in its focal line for guiding and heating an operating medium, for example water. The absorber line 6 comprises three line sections 8, 10, 12 and is mechanically connected to the parabolic trough 4. A first 8 and a second line section 12 are arranged essentially horizontally, a third line section 10 being arranged between these two 8, 12, the level 14 of which is higher than the highest level 16, 18 of the interiors 20, 22 of the first 8 and the second Line section 12 lies. The equipment flows in the direction of arrows 24 through the absorber line 6, i.e. in other words in succession through the first 8, the third 10 and the second line section 12.

The third line section 10 thus ensures that, during the operation of the parabolic trough solar power plant 2, sufficient operating resources are also available in the upper region of the first line section 8 of the absorber line 6 due to the fact that it is stowed in a rise 26 in the third line section 10. As a result, overheating of the wall in the upper region of the first line section 8 of the absorber line 6 is largely avoided.

The operating medium, for example water, usually flows during operation with a mass flow density M of less than 1000 kg / m ² s. The value for the speed of the water v _w when the evaporation starts is less than 1 m / s. The inside diameter of the absorber line 6 is chosen between 50 and 100 mm. The inside diameter of the third line Section 10 is at least equal to the inside diameter of the line sections 8, 12.

When the parabolic trough solar power plant 2 is operated, steam forms in the water flowing in the absorber line 6. Without the presence of the third line section 10 in the absorber line 6, below a predetermined velocity v _{D of} the steam, which depends on the total pressure within the absorber line 6, gravitational separation of the water-steam mixture would occur in the same. As a result, there is only steam and no water in the upper area of the absorber line 6, which would result in overheating of the wall and poorer heat transfer in this upper area. By arranging the third line section 10 between the line sections 8 and 12, the at least partially caused backflow of the water means that water is also present in the upper region of the first line section 8 during operation, as a result of which the wall is prevented from overheating and consequently Heat transfer is improved in contrast to the collectors known from the prior art.

Depending on the size of the collector, several of these third line sections can be arranged in the parabolic trough 4, each of which is separated from one another by the essentially horizontal line section 8, 12. As a result, an inclination of the absorber line or of the entire collector to avoid overheating is no longer required, and costs for appropriate mechanical support are thus saved.

The level 14 of the third line section 10 is approximately Im above the highest level 16, 18 of the interiors 20, 22 of the first 8 and the second line section 12. This level difference ensures that Most pipe section 8 has enough water to avoid overheating. There is an additional pressure loss of at most 0.1 bar in the third line section 10.

The angle (α) 30 between a horizontal 32 and the rise 26 of the third line section 10 is at least 10 °. Overheating is avoided above this value for the angle (α).

The third line section 10 is arched at a transition 34 to the first line section 8. This measure prevents the flow from being constricted when the equipment is deflected in the third line section 10.

Between the third 10 and the first 8 or second line section 12 there is arranged a joint 36, 38 which can be rotated about the longitudinal axis of the first 8 or second line section 12. The parabolic trough 4 is rotated around the longitudinal axis of the absorber line 6 in accordance with the incident solar radiation. It may be useful that in addition to the parabolic trough 4, the absorber line 6 is rotated. By installing the joints 36, 38, rotation of the third line section 10 is avoided and the level difference is thus maintained.

In an embodiment not shown, the jacket of the third line section 10 is made of a material that ensures mechanical mobility of the third line section 10. In this embodiment, the joints 36, 38 are not required. In the section from a parabolic trough power plant 2 shown in FIG. 2, the first line section 8 of the absorber line 6 is in a first parabolic trough 50, the second line section 12 in a second parabolic trough 52 and the third line section 10 between the spatially separated parabolic troughs 50 , 52 arranged. In this embodiment, the third line section 10 is thus arranged between two collectors 54, 56. The collectors 54, 56 each comprise a line section 8 or 12 of the absorber line 6 and a parabolic trough 50 or 52. This ensures that with relatively short line sections 8, 12 and thus relatively small collectors 54, 56, the overheating in the upper one Wall area of the absorber line 6 is avoided. In the case of longer collectors, see FIG. 1, overheating in the second line section 2 and thus in the last partial section of the absorber line 6 of the respective collector is avoided.

According to FIG. 3, the first line section 8 is arranged in the parabolic trough 52. In contrast to FIG 2 is the second

Line section 12 designed as a steam separator 60. The resource, i.e. the liquid-vapor mixture, after flowing through the collector 54, is fed directly into the vapor separator 60 via the third line section 10 for processing. In embodiments that are not shown, other devices for storing and processing the operating fluid can be used instead of the steam separator 60.

Claims

claims

1. Solar power plant (2) with at least one absorber line (6) for guiding and heating an operating medium, which comprises at least a first and a second line section (8, 12), each arranged essentially horizontally, between the first (8) and the second line section (12) is arranged a third line section (10), the level (14) of which is higher than the highest level (16, 18) of the interior spaces (20, 22) of the first (8) and second line sections (12) lies.

2. Solar power plant (2) according to claim 1 with a number of parabolic troughs (4), in which the absorber line (6) is arranged within one of the parabolic troughs (4).

3. Solar power plant (2) according to claim 1, wherein the first line section (8) in a first parabolic trough (50), the second line section (12) in a second parabolic trough (52) and the third line section (10) between the spatially separate parabolic troughs (50, 52) is arranged.

4. Solar power plant (2) according to claim 1 or 2, in which the level (14) of the third line section (8) approximates 1

Meters above the highest level (16, 18) of the interiors (20, 22) of the first (8) and second line section (12).

5. Solar power plant (2) according to claim 2 or 4, wherein the first line section (8) in the parabolic trough (50) and the second line section (12) is designed as a steam separator (60).

6. Solar power plant (2) according to one of the preceding claims, wherein the angle (α) between the horizontal (32) and the rise (26) of the third line section is at least 10 °.

7. Solar power plant (2) according to one of the preceding claims, wherein the inner diameter of the third line section (10) is at least equal to the inner diameter of the first and second line section (8, 12).

8. Solar power plant (2) according to one of the preceding claims, wherein the third line section (10) at an interface (34) to the first line section (8) is arcuate.

9. Solar power plant (2) according to one of the preceding claims, in which between the third (10) and the first (8) or second line section (12) in each case around the longitudinal axis of the first (8) or second line section (12) rotatable joint (36,38) is arranged.