ES1262841U - PARABOLIC CYLINDER TYPE SOLAR CONCENTRATION INSTALLATION TO COMPENSATE THE THERMAL EXPANSION OF AT LEAST ONE HEAT COLLECTOR TUBE (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Parabolic cylinder type solar concentrating installation to compensate for the thermal expansion of at least one heat collecting tube (4), comprising: - a solar collector (1) provided with a structure (2) to which are connected a plurality of parabolic cylinder mirrors (3) that concentrate the solar radiation towards a heat collector tube (4) arranged substantially in the defined optical focal line by the parabolic cylinder mirrors (3), where said heat collecting tube (4) comprises a heat transfer fluid and is supported and operatively connected to the structure (2) by means of a plurality of support elements (5), - a mounting module (6) comprising a plurality of solar collectors (1) connected to each other and in fluid communication of the heat transfer fluid inside the heat collection tube (4), where said installation is characterized in that it also comprises one or more supports (7B, 7C) that join the heat collector tube (4) to the support elements (5) at one or more different mounting heights (h1, h2) at the height of the optical focal line (F), said one or more supports (7) presenting a clearance (10) in a lower portion to allow the thermal expansion of the heat collecting tube (4), so that, the one or more mounting heights (h1, h2) are dimensioned to compensate for the thermal expansion of the heat collecting tube (4) and the consequent deviation from the optical focal line (F) along a mounting module (6) . (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

PARABOLIC CYLINDER TYPE SOLAR CONCENTRATION INSTALLATION FOR

COMPENSATE FOR THE THERMAL EXPANSION OF AT LEAST ONE COLLECTOR PIPE

HOT

OBJECT OF THE INVENTION

The present invention falls within the technical field of solar concentrating installations of the type that uses parabolic trough reflectors. More in particular, the present invention describes an installation whose object is to compensate the deviations of one or more heat collecting tubes with respect to the focal line due to the thermal expansions and expansions suffered by said tubes due to the different temperatures reached by the fluid. heat transfer in different sections of the installation.

BACKGROUND OF THE INVENTION

Within the broad spectrum of renewable resources and technologies called upon to complete the global energy supply map are thermosolar plants, the one based on the parabolic cylinder technique being the most established, in which and by means of parabolic cylinder mirrors - with orientation Continuous to the Sun from East to West - solar radiation is concentrated in a heat collector element or tube, located in the collector's optical focal line that is defined by parabolic trough mirrors. A heat transfer fluid circulates inside the heat collector tubes and transports the absorbed energy to a conventional power block where electrical energy is generated.

Based on current strong competition and increasingly narrow margins, one of the necessary strategies with which to maintain competitiveness and market position in the energy sector focuses on being able to minimize the level cost of the kilowatt-hour generated, is that is to say, increase the total efficiency of the plant during its useful life.

In the case of CSP technology, one of the fundamental design criteria with a direct impact on said objective is the thermal efficiency of the solar field, the value of which will depend in turn on the so-called peak optical efficiency, defined as the relationship between the power radiant absorbed by the receiver tube or heat collector tube and the useful radiant solar power in the parabolic trough collector.

In the state of the art, the heat collector tubes suffer significant deviations with respect to the focal line due to thermal expansions due to the different temperatures reached by the heat transfer fluid in different sections of the installation.

Thus, what is previously known in operation proposes an assumption of the deviation detected to the detriment of a lower optical and thermal efficiency, as a consequence, presenting a higher cost per kilowatt-hour generated.

Rotating joints or "Ball Joints" connect different rows of solar collectors joined together, normally forming a solar loop or loop in U, ensuring fluid communication or continuity of the heat transfer fluid. These rotating joints are one of the auxiliary components of greater responsibility for the dynamic and thermal stresses to which they are subjected, statistically presenting a failure rate higher than 10%.

An important cause of failure of these rotating unions is thermal expansion, forcing them to work in a plane that is not straight between connections.

Regarding the problems related to the mechanical behavior of rotating unions, although advances have been proposed, for example, in the matter described by document ES2302485, these have been based on complex alternatives and not focused on also providing an improvement to the system from an optical point of view.

DESCRIPTION OF THE INVENTION

The present invention aims to solve some of the problems mentioned in the state of the art. More particularly, the present invention describes a parabolic cylinder type solar concentrating installation to compensate for the thermal expansion of at least one heat collecting tube, comprising:

- a solar collector provided with a structure to which a plurality of parabolic cylinder mirrors are connected that concentrate the solar radiation towards a heat collecting tube arranged substantially in the optical focal line defined by the parabolic cylinder mirrors, where said heat collecting tube it comprises a heat transfer fluid and is supported and operatively connected to the structure by means of a plurality of support elements, - a mounting module comprising a plurality of solar collectors connected to each other and in fluid communication of the heat transfer fluid inside the tube heat collector,

wherein said installation further comprises one or more supports that join the heat collector tube to the support elements at one or more mounting heights other than the height of the optical focal line, said one or more supports presenting a clearance in a lower portion to allow thermal expansion of the heat sink tube, such that the one or more mounting heights are dimensioned to compensate for the thermal expansion of the heat sink tube and the consequent deviation from the optical focal line along of a mounting module.

The installation may comprise collector circuits or a solar loop comprising two or more solar concentrating assemblies each with a plurality of solar collectors. Such solar loops are generally arranged connected in a U-shape by joining two rows of concentrating solar mounts. Said union or connection is made by means of rotating joints that allow fluid communication of the heat transfer fluid between different solar concentrating tubes.

Once certain operating parameters have been set, the thermodynamic process in the installation requires raising the temperature of the heat transfer fluid, optimally, from a temperature equal to 293 ° C at the inlet of a loop or circuit, to a temperature equal to 393 ° C at the outlet of this. There is therefore a process in which said final temperature is reached progressively, thus finding sections of the solar collector tube with heat transfer fluid inside at different temperatures. Due to thermal expansion we have as a consequence, a deformation of the tube that is variable in its path and that causes at each point a different deviation with respect to its ideal design position, that is, the focal line of the parabola defined by the reflecting mirrors.

For this, in a preferred embodiment, it is proposed to vary in each mounting element only the element in direct contact with the tube, namely the element called support in the present invention.

In a preferred embodiment, the mounting heights can be varied by simply changing the interior geometry of each support depending on the height required in each section to compensate for the thermal expansions of the heat collecting tube.

Maintaining criteria of standardization of components, economy of manufacture and simplicity in assembly, it is intended to correct the deviation described by using solar collector tubes arranged at different heights (in mounting position) depending on the expected temperature value in the heat transfer fluid. at each point of the installation.

By using one or more brackets with different mounting heights conscientiously arranged to compensate for thermal expansions along each mounting module, the optical efficiency of the installation is increased. More in particular, it has been possible to quantify said improvement in optical efficiency in more than 0.2% for each mounting module. Presenting a resulting interception factor greater than 97%.

In addition, as mentioned above, the rotating joints or the connection elements between collector tubes that allow continuity to the heat transfer fluid, are one of the auxiliary components with greater responsibility for the dynamic and thermal stresses to which they are subjected, presenting themselves statistically a failure rate greater than 10%.

The existence of a smaller deviation in the position of the heat collector tube with respect to its theoretical optical focal position increases the useful life of these rotating unions by remaining operating in a plane close to 0o.

On the basis of the pertinent thermal, structural and optical calculations and simulations, the reference position of the heat collection tube can be associated with an average temperature value determined between the limit values along the path of the fluid.

As an example, for a solar loop made up of four mounting modules and nine solar collectors for each mounting module, a study carried out determined to use three different positions of the solar collector tube along the solar loop.

As a consequence, in a preferred embodiment the installation comprises two or more supports that join the heat collector tube to the support elements at two or more different mounting heights with respect to the height of the optical focal line.

One of the supports can join the solar collector tube to the support element at the height of the focal line.

However, the selection of the number of supports that provide different mounting heights can be a compromise between ease of mounting and / or manufacture vs. increase in energy production and / or decrease in rotary joint failures for a certain installation with a certain configuration of mounting modules and solar loops.

Preferably, the one or more supports surround at least partially the heat collecting tube and have an internal geometric configuration provided with at least two support projections that define the mounting height.

In a preferred embodiment, two or more supports have an internal geometric configuration provided with at least two support projections, where each support has support projections arranged at different heights with respect to the perimeter of the heat collector tube to provide two different mounting heights. depending on the needs.

Note that, in this way, the installation presents a bracket configured for a mounting height equal to the optimal focal height, and two or more brackets configured to present a mounting height different from the optical focal height, thus allowing the height to be varied. mounting of the heat collector tube in each of the support elements in order to maximize the capture of heat and avoid damage to the rotating unions.

Instead of using three brackets or more brackets, namely one bracket where the mounting height equals the optical focal height and two or more brackets with a different height, in an alternative embodiment of the present invention, each bracket is provided of at least two fixed or movable support projections along the inner perimeter of the support, thus allowing the same type of support to be used to vary the mounting heights throughout a mounting module. For example, each bracket may have a slider on the inner perimeter and a locking mechanism to lock the boss in the desired position.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of a practical embodiment thereof, a set of drawings is attached as an integral part of said description. where, with an illustrative and non-limiting nature, the following has been represented:

Figure 1.- Shows a perspective view of a solar collector, where it is clearly illustrated that it comprises support elements, a structure and parabolic trough mirrors

Figure 2.- Shows a schematic elevation view of a mounting module comprising nine solar collectors as shown in figure 1, with a heat transfer fluid inside a solar collector tube.

Figure 3.- Shows a perspective view of a support that joins the heat collector tube to the support elements at a mounting height substantially equal to the height of the optical focal line.

Figure 4A.- Shows an elevation view of the support of figure 3.

Figure 4B.- Shows an elevation view of a support according to an embodiment of the present invention, where said support joins the heat collector tube to the support elements at a first mounting height other than the height of the focal line optical and has a clearance (10) to allow thermal expansion.

Figure 4C.- Shows an elevation view of a support according to an embodiment of the present invention, where said support joins the heat collector tube to the support elements at a second mounting height other than the height of the focal line optical (F) and has a clearance to allow thermal expansion.

Figure 5.- Shows a schematic view of a preferred embodiment of the present invention where an optimized parabolic-trough type solar concentrating installation is illustrated with different mounting heights by means of two supports and a third support configured to mount the collector tube at a height equal to the height of the optical focal line.

PREFERRED EMBODIMENT OF THE INVENTION

A detailed description of a preferred embodiment of the object of the invention is provided below, with the aid of the attached figures 1-5 described above.

The object of the invention refers to a parabolic cylinder type solar concentrating installation to compensate for the uneven thermal expansion of heat collector tubes (4) as a consequence of the different temperatures of the heat transfer fluid in different sections of the installation.

To this end, as illustrated in Figure 1 and Figure 2, a solar concentrating installation of the type comprising a solar collector (1) provided with a structure (2) to which a plurality of parabolic trough mirrors (3) is connected is described. ) that concentrate the solar radiation towards a heat collecting tube (4) arranged substantially in the optical focal line defined by the parabolic trough mirrors (3), where said heat collecting tube (4) comprises a heat transfer fluid and is supported and operatively connected to the structure (2) by means of a plurality of support elements (5).

Furthermore, the installation comprises mounting modules (6) connected to each other, where each mounting module (6) as shown in figure 2 comprises a plurality of solar collectors (1) connected to each other and in fluid communication of the heat transfer fluid by the inside of the heat collector tube (4),

Furthermore, Figure 3 and Figure 4A illustrate by way of example a support (7A) that joins the heat collecting tube (4) to the support elements (5) at substantially the height of the optical focal line (F).

As shown in figure 4, to solve the problem described above, in a preferred embodiment the present invention provides two supports (7B, 7C) that join the heat collector tube (4) to the support elements (5) to a or more mounting heights (h1, h2) other than the height of the optical focal line (F), said one or more supports (7B, 7C) presenting a clearance (10) in a lower portion to allow for thermal expansion of the heat collector tube (4), so that the one or more mounting heights (h1, h2) are dimensioned to compensate for the thermal expansion of the heat collector tube (4) and the consequent deviation from the optical focal line (F) along a mounting module (6).

More particularly, as shown in figure 4B and 4C, the (7B, 7C) partially surround the heat collector tube (4) and present an internal geometric configuration provided with two support projections (8), where each support ( 7A, 7B) has support projections (8) arranged at different heights with respect to the perimeter of the heat collecting tube (4).

Figure 5 shows a schematic view of a preferred embodiment of an optimized parabolic-trough type solar concentrating installation with different heights (F, h1, h2) by using the three supports (7A, 7B, 7C). More in particular, the installation comprises four mounting modules (6) connected to each other in a U-shaped configuration defining a collector circuit (9), where each mounting module (6) in turn comprises nine solar collectors (1) being the heat transfer fluid in fluid communication of each heat collector tube (4) thanks to the rotating joints (11).

In the preferred embodiment illustrated in figure 5, the optimized installation with different heights (F, h1, h2) of the heat collection tube (4) to compensate for thermal expansions and increase performance makes use of three supports (7A, 7B, 7C) in the configuration and arrangement illustrated there, namely, each solar collector (1) uses one type of support (7A, 7B or 7C). In other words, a bracket (7A) that provides a height equal to the height of the optical focal line (F) and two brackets with different mounting heights (h1, h2).

The mounting modules (6) near the outlet and the inlet require three heights (f, h1, h2) while the two mounting modules (6) furthest away make use of only two supports (7A, 7B).

Claims (6)

1. - Parabolic cylinder type solar concentrating installation to compensate for the thermal expansion of at least one heat collecting tube (4), comprising: - a solar collector (1) provided with a structure (2) to which are connected a plurality of parabolic cylinder mirrors (3) that concentrate the solar radiation towards a heat collecting tube (4) arranged substantially in the defined optical focal line by the parabolic cylinder mirrors (3), where said heat collector tube (4) comprises a heat transfer fluid and is supported and operatively connected to the structure (2) by means of a plurality of support elements (5), - an assembly module (6) comprising a plurality of solar collectors (1) connected to each other and in fluid communication of the heat transfer fluid inside the heat collection tube (4), where said installation is characterized in that it also comprises one or more supports (7B, 7C) that join the heat collector tube (4) to the support elements (5) at one or more different mounting heights (h1, h2) at the height of the optical focal line (F), said one or more supports (7) presenting a gap (10) in a lower portion to allow the thermal expansion of the heat collecting tube (4), so that the one or more mounting heights (h1, h2) are dimensioned to compensate for the thermal expansion of the heat collecting tube (4) and the consequent deviation from the optical focal line (F) along a mounting module (6) . 2. - The installation of claim 1, comprising two or more supports (7B, 7C) that join the heat collector tube (4) to the support elements (5) at two or more mounting heights (h1, h2 ) other than the height of the optical focal line (F) along a mounting module (6). 3. - The installation of claim 1, in which the one or more supports (7B, 7C) surround at least partially the heat collector tube (4) and present an internal geometric configuration provided with at least two support projections ( 8). 4. - The installation of claim 1, comprising two or more supports (7B, 7C) adapted to surround at least partially the heat collection tube (4) and have an internal geometric configuration equipped with a support projection (8), where each support (7B, 7C) has support projections (8) arranged at different heights with respect to the perimeter of the heat collecting tube (4). 5. - The installation of claim 1, in which the one or more supports (7B, 7C) have an internal geometric configuration equipped with at least two support projections (8) fixed or movable along the perimeter, thus allowing that the same type of support (7B, 7C) can be used to vary the heights along a mounting module (6). 6. - The installation of claim 1, comprising a collector circuit (9) comprising two or more solar concentration assemblies (6) with a fluid connection of the heat transfer fluid between different solar concentration tubes (4) by means of joints rotary (11).