阅读说明：本技术 集中式太阳能接收器 (Centralized solar receiver ) 是由 J·R·费希尔 A·柯蒂斯 K·F·德鲁斯 B·A·莱斯利 T·P·约斯特 N·P·巴托斯 于 2018-11-15 设计创作，主要内容包括：一种集中式太阳能热接收器安装在塔架上以从集中式太阳能反射器阵列接收集中的太阳热能。接收器包括单层管阵列,所述单层管阵列被配置为承载诸如钠的传热流体并组合限定露出的集中式太阳热能接收表面。管阵列具有与进口输送管连通的下部流体进口集管,和与出口输送管连通的上部流体出口。这些管以蛇形构造布置,并限定了主要为横向和向上的流体流动路径。接收器包括可在打开位置和关闭位置之间移动的绝热盖,在关闭位置覆盖太阳热能接收表面以阻挡或减少太阳能通量在管上的入射或减少管阵列未运作时的热损失。(A concentrated solar thermal receiver is mounted on a tower to receive concentrated solar thermal energy from an array of concentrated solar reflectors. The receiver includes an array of single-layer tubes configured to carry a heat transfer fluid such as sodium and combine to define an exposed concentrated solar thermal energy receiving surface. The tube array has a lower fluid inlet header in communication with the inlet feed tube, and an upper fluid outlet in communication with the outlet feed tube. The tubes are arranged in a serpentine configuration and define a predominantly lateral and upward fluid flow path. The receiver includes an insulating cover movable between an open position and a closed position covering the solar thermal energy receiving surface to block or reduce incidence of solar flux on the tubes or to reduce heat loss when the array of tubes is not in operation.)

1. A concentrated solar thermal receiver for receiving concentrated solar thermal energy from a concentrated array of solar reflectors, the receiver comprising a single layer array of tubules configured to carry a heat transfer fluid and in combination defining an exposed concentrated solar thermal energy receiving surface, the tubule array having a fluid inlet in communication with at least one inlet duct and a fluid outlet in communication with at least one outlet duct, wherein the tubule array is arranged in a serpentine configuration and the array has predominantly transverse channels or assemblies.

2. The concentrated solar thermal receiver of claim 1 wherein the fluid inlet comprises an operatively lower inlet header and the fluid outlet comprises an operatively upper outlet header, and the array of fine tubes extends between the inlet header and the outlet header.

3. The concentrated solar thermal receiver of claim 2 wherein the array of thin tubes define a predominantly lateral and upward, or single, fluid flow path.

4. The concentrated solar thermal receiver according to any one of the preceding claims 2 or 3 wherein each tubule in the tubule array has vertical or longitudinal components between each successive transverse channel or component.

5. The concentrated solar thermal receiver of claim 4 wherein the transverse assembly or channel is substantially horizontal.

6. The concentrated solar thermal receiver of claim 5 wherein the vertical or longitudinal component is vertical in at least one plane.

7. The concentrated solar thermal receiver of any one of the preceding claims wherein the array comprises a mounting arrangement for mounting the tubular array to supports or housings which in turn are mounted on a solar tower, the mounting arrangement being configured to allow lateral and upward/downward movement of the tubules in the array due to thermal contraction and expansion, the mounting arrangement comprising spacers for preventing adjacent tubules from contacting but maintaining them in a nearly contacting position.

8. The concentrated solar thermal receiver of claim 7 wherein the mounting arrangement includes at least one support beam carrying a movable mount mounting the lateral tubule assembly to at least one of the support beams to allow lateral and up/down movement thereof.

9. The centralized solar thermal receiver of claim 8, wherein the at least one support beam comprises at least two longitudinally or vertically aligned support beams and the movable mount comprises a linkage.

10. The concentrated solar thermal receiver of claim 9 wherein the tie rods are rotatably and slidably mounted to the support beams, the tie rods in turn rotatably mounted to lugs on the lateral tubule assembly, the tie rods being spaced apart by spacers comprising slidable shims.

11. The concentrated solar thermal receiver of any one of claims 2 to 10 wherein the array of fine tubes comprises a plurality of multi-channel fine tubes extending side-by-side with each other in a parallel and serpentine array from an inlet manifold of the inlet header to an outlet manifold of an outlet header.

12. The concentrated solar thermal receiver of any one of claims 7 to 11 wherein at least one of the inlet or outlet headers has a floating mount that allows it to move in concert with the thermal expansion and contraction of the array of thin tubes.

13. The concentrated solar thermal receiver of claim 12 wherein the lower inlet header is provided with a floating mount and the upper outlet header is provided with a fixed mount for mounting the upper header to an upper portion of a support frame or enclosure.

14. The concentrated solar thermal receiver of claim 11 wherein the number of parallel tubules and the number of channels per tubule are inversely related to each other such that the total number of transverse tube channels remains substantially the same whether from the same or different tubules.

15. The centralized solar thermal receiver of any one of claims 11 or 14 wherein the length of each tubule in the array is substantially similar and the flow resistance of each tubule is substantially similar to provide similar residence time of the thermally conductive fluid.

16. The concentrated solar thermal receiver of any one of claims 2 to 15 wherein the array of tubules are substantially coplanar to provide a continuous coplanar energy receiving surface and some of the tubules are bent out of plane when the in-plane bend radius is too small to bring adjacent coplanar tubules into near contact while allowing for inter-tubule play.

17. A concentrated solar thermal receiver according to any one of the preceding claims wherein said receiver includes an insulating cover movable between an open position and a closed position, wherein said open position is said solar thermal energy receiving surface exposed to receive solar flux; wherein the closed position is the solar thermal energy receiving surface covered to block or reduce incidence of solar flux on the tubules.

18. A concentrated solar thermal receiver for receiving concentrated solar thermal energy from a concentrated array of solar reflectors, the receiver comprising a single layer tubule array configured to carry a heat transfer fluid and defining a concentrated solar thermal energy receiving surface, the tubule array having a fluid inlet in communication with at least one inlet duct and a fluid outlet in communication with at least one outlet duct, wherein the tubule array is arranged in a serpentine pattern combining to define an exposed concentrated solar thermal energy receiving surface, the receiver comprising a thermal insulating cover movable between an open position to receive solar flux and a closed position to expose the solar receiving surface; wherein the closed position is the solar thermal energy receiving surface covered to block or reduce incidence of solar flux on or in the absence of significant reduction or absence of heat loss from the array of tubules.

19. The concentrated solar thermal receiver of claim 18 wherein the receiver includes a support frame extending around the solar thermal energy receiving surface, wherein the cover is movable between the closed position and an open position wherein it extends over the surface and at least a portion of the frame, and wherein the open position allows the surface to be fully exposed to solar thermal radiation, the receiver including an actuator for moving the cover between the open and closed positions.

20. The centralized solar thermal receiver of claim 19, wherein the receiver comprises at least one sensor for actuating the actuator in response to a sensed condition.

21. The concentrated solar thermal receiver of claim 19 or 20 wherein the actuator is selected from a pneumatic, hydraulic or electric linear actuator or drive, a rack and pinion arrangement or a prime mover and a pulley arrangement actuated by the prime mover to move the cover between the open and closed positions.

22. The concentrated solar thermal receiver of any one of claims 18-21 wherein the cover is pivotable about an axis parallel to the upper end of the receiver and the cover includes a counterbalance to facilitate opening and closing of the cover.

23. The concentrated solar thermal receiver of any one of claims 18 to 21 wherein the cover comprises a side adapted to resist high incident radiation and a mounting arrangement for holding the side facing the source or high incident radiation in open and closed positions and moving therebetween.

24. The concentrated solar thermal receiver of claim 23 wherein the cover is located directly below the receiver when the cover is in an open position to provide protection against high incident radiation to portions of the receiver support structure directly below the receiver and behind the cover.

25. The concentrated solar thermal receiver of any one of claims 23 or 24 wherein the mounting arrangement comprises a four bar linkage type mount for movably mounting the cover to the support structure or tower.

26. The concentrated solar thermal receiver of any one of claims 23 or 24 wherein the mounting arrangement comprises a set of tracks carried on the support structure or tower, the cover being fitted with rollers or the like to ride along the set of tracks.

27. The centralized solar thermal receiver of claim 20, wherein the at least one sensor is selected from the group consisting of at least any two of temperature sensors including infrared sensors or cameras, flow sensors, and power sensors for detecting power interruptions.

28. The concentrated solar thermal receiver of any one of the preceding claims 18 to 27 wherein in systems where the heat transfer fluid is not exhausted from the tubes when there is no solar flux on the tubes, the thermal insulated doors are configured to reduce convective and radiative heat losses from the array of tubes.

29. The concentrated solar thermal receiver of any one of the preceding claims wherein the heat transfer fluid is sodium and the tube is comprised of a stainless steel alloy such as 230 or 625 or a nickel based alloy such as inconel.

30. The concentrated solar thermal receiver of any one of the preceding claims wherein the array of tubes defines a curved or multi-faceted surface.

31. The concentrated solar thermal receiver of any one of the preceding claims wherein the array of tubes defines a cylindrical or semi-cylindrical surface.

32. The concentrated solar thermal receiver of any one of claims 1 to 29 wherein the array of tubes defines an inverted truncated cone, or a portion thereof, at an optimal angle in the vertical direction to receive the optimal solar flux concentration.

33. A concentrated solar thermal tower assembly comprising a solar thermal tower and a concentrated solar thermal receiver according to any one of the preceding claims mounted in the upper part of the tower.

34. A concentrated solar thermal energy tower assembly as described in claim 33 wherein said tower is pivotable between an upright position and a prone position to enable maintenance thereof.

35. A concentrated solar thermal energy tower assembly as claimed in claim 34 wherein the tower includes at least two legs at its bottom configured to disconnect from the mount or base plate and at least two opposing legs configured to pivot to a prone position relative to the mount or base plate.

36. A concentrated solar thermal energy tower assembly as claimed in claim 29 and claim 21, wherein the prime mover includes at least one limiting and speed control means for limiting and/or controlling the speed of the insulated door.

Technical Field

The present invention relates to a Concentrated Solar Power (CSP) receiver, and to a CSP tower assembly including such a receiver.

Background

In one type of CSP system, a concentrated array of heliostats reflects sunlight toward one or more solar receiver modules mounted on a central solar tower. Typically, the heliostats take the form of sun-tracking mirrors that reflect and focus sunlight or solar thermal energy onto a central receiver module mounted on a solar tower.

The receiver module may comprise an array of pipes or ducts carrying a circulating heat transfer fluid, such as sodium or molten salt. This transfers heat to a heat storage device such as a salt container (reservoir), which in turn may be used to heat water to drive one or more batteriesA plurality of steam turbines. The peak value of the heat received by the receiver is usually at most 1500KW/m²This will result in metal temperatures in excess of 600 or 700 deg.c. The extreme thermal stresses and changes to which the receiver is subjected place demands on the type of material used and affect the life of the receiver, and it is not uncommon for the receiver to fail prematurely under such thermal stresses.

Under these extreme operating conditions, it is desirable to avoid so-called "hot spots" and to efficiently receive and transfer heat through the transfer pipe over the entire receiver, with a relatively uniform heat distribution.

The reference to any prior art in this specification is not, and should not be taken as, an acknowledgment or any form of suggestion that this prior art forms part of the common general knowledge of any claim or that this prior art could reasonably be expected by a person skilled in the art to be a combination of related and/or other prior art.

Disclosure of Invention

A first aspect of the present disclosure provides a concentrated solar thermal receiver for receiving concentrated solar thermal energy from a concentrated array of solar reflectors, the receiver comprising a single layer array of tubules configured to carry a heat transfer fluid and defining in combination an exposed concentrated solar thermal energy receiving surface, the tubule array having a fluid inlet in communication with at least one inlet duct and a fluid outlet in communication with at least one outlet duct, wherein the tubule array is arranged in a serpentine configuration and the array has a predominantly transverse channel or assembly.

A second aspect of the present disclosure provides the concentrated solar thermal receiver of any one of the preceding claims, the array comprising a mounting arrangement for mounting the tubular array to a support or housing which in turn is mounted on a solar tower, the mounting arrangement being configured to allow lateral and upward/downward movement of the tubules in the array due to thermal contraction and expansion, the mounting arrangement comprising spacers for preventing adjacent tubules from contacting but maintaining them in a nearly contacting position.

A third aspect of the present disclosure provides a concentrated solar thermal receiver for receiving concentrated solar thermal energy from a concentrated array of solar reflectors, the receiver comprising a single layer tubule array configured to carry a heat transfer fluid and defining a concentrated solar thermal energy receiving surface, the tubule array having a fluid inlet in communication with at least one inlet duct and a fluid outlet in communication with at least one outlet duct, wherein the tubule array is arranged in a serpentine pattern, in combination defining an exposed concentrated solar thermal energy receiving surface, the receiver comprising a thermal insulating cover movable between an open position and a closed position. The open position being the exposed solar energy receiving surface to receive solar energy flux; wherein the closed position is the solar heat receiving surface covered to block or reduce incidence of solar flux on or in the tubules, substantially reducing or not reducing heat loss from the array of tubules.

The fluid inlet may comprise an operatively lower inlet header and the fluid outlet comprises an operatively upper outlet header, and the combination of the array of tubules defines a boundary of the concentrated thermal energy receiving surface and extends between the inlet header and the outlet header.

The array of tubules may define a predominantly lateral and upward, or single, fluid flow path.

The transverse components may be substantially horizontal and the vertical components or the longitudinal components may be vertical in at least one plane. The array may comprise a mounting arrangement for mounting the tubular array to a support or housing which in turn is mounted on a solar tower, the mounting arrangement being configured to allow lateral and upward/downward movement of the tubules due to thermal contraction and expansion, the mounting arrangement comprising spacers for preventing adjacent tubules from contacting but maintaining them in a nearly contacting position.

The mounting arrangement may comprise at least two elongate support beams which are longitudinally or vertically aligned with respect to the array of tubes and which carry movable links which mount the cross tube members to the support members to allow lateral and up/down movement thereof.

The support beam may be in the form of a duct, the links being rotatably and slidably mounted to the support beam, the links in turn being rotatably mounted to lugs on the transversely extending duct assemblies, the links being spaced apart by slidable spacers.

The length of each tube in the array may be substantially similar, and the flow resistance of each tubule may be substantially similar to provide similar residence time of the thermally conductive fluid.

The receiver may comprise said receiver including a movable between an open position to expose said solar energy receiving surface to receive solar energy and a closed position; wherein the closed position is the solar energy receiving surface covered to block or reduce incidence of solar flux by the tubules or to reduce heat loss by the array of tubules when incidence of solar flux is reduced

The tubule array may include a plurality of multi-pass tubules extending side-by-side with each other in a parallel and serpentine array from an inlet manifold of the inlet header to an outlet manifold of the outlet header.

The number of parallel tubules and the number of channels per tubule are inversely related to each other so that the total number of transverse tube channels, whether from the same or different tubules, remains substantially the same.

The array of tubules may be substantially coplanar to provide a coplanar energy receiving surface. While adjacent tubes in a coplanar array are arranged in near contact while allowing for inter-tubule play, some tubules may bend out of plane when the in-plane bend radius is too small to allow bending without excessive deformation or tapering.

The overall structure of the array may be a square or rectangular billboard structure.

The array of tubes may define a curved or multi-faceted surface.

The array of thin tubes defines a cylindrical or semi-cylindrical surface, in which case the solar tower is completely or partially surrounded by heliostats, respectively.

The array of tubules defines an inverted truncated cone, or a portion thereof, at an optimal angle in the vertical direction to receive an optimal solar flux concentration.

At least one of the inlet or outlet headers has a floating mount that allows it to move in concert with the thermal expansion and contraction of the array of tubules.

The lower inlet header may be provided with a floating mounting, the upper outlet header may be provided with a fixed base for mounting said upper header to a frame or a housing, and the support beam is movably anchored to the support frame or housing.

The cover may comprise a side adapted to resist high incidence radiation and a mounting arrangement for holding the side facing the source or high incidence radiation in open and closed positions and moving therebetween.

Preferably, when the cover is in the open position, the cover is located directly below the receiver to provide protection against high incident radiation to portions of the receiver support structure directly below the receiver and behind the cover.

The mounting arrangement may comprise a four-bar linkage type mounting for movably mounting the cover to the support structure or tower.

In a system where the heat transfer fluid is not exhausted from the tubes when there is no solar flux on the tubes, the thermal isolation doors are configured to reduce convective and radiative heat losses from the tube array.

The heat transfer fluid may be sodium and the tube may be composed of a stainless steel alloy such as 230 or 625 or a nickel-based alloy such as inconel.

The present disclosure extends to a concentrating solar heat concentration tower comprising a solar heat concentration tower and a concentrating solar heat receiver of the type described above mounted to the upper part of the tower.

The tower is pivotable between an upright position and a prone position to enable maintenance thereof.

The present disclosure includes a concentrated solar tower comprising at least one solar thermal receiver of the above type.

The present disclosure may also include a concentrated solar thermal power plant comprising at least one concentrated solar thermal collector tower assembly of the type defined, the array of heliostats and control means for controlling operation of the receiver being arranged around the receiver and adjustable to focus solar radiation on the receiver. To prevent overheating of the receiver, the control means may be operable to open and close the lid.

Other aspects of the disclosure, as well as other embodiments of the aspects described in the preceding paragraphs, will become apparent from the following description, given by way of example with reference to the accompanying drawings.

Drawings

Other aspects of the disclosure and other embodiments of the aspects described in the preceding paragraphs will become apparent from the following description, which is given by way of example only with reference to the accompanying drawings.

Fig. 1 shows a schematic diagram of a CSP system including a solar thermal receiver in the present disclosure;

fig. 1A shows a perspective view of a solar thermal receiver mounted on a tower.

Fig. 1B shows a front view of the solar thermal receiver and tower of fig. 1A.

Fig. 1C shows a top view of the solar thermal receiver and tower of fig. 1A and 1B.

Fig. 1D shows a side view of a solar thermal receiver and tower.

FIG. 1E shows a cross-sectional side view of line 1E-1E of FIG. 1B.

FIG. 1F shows details of the upper outlet header connection.

FIG. 1G shows a detail of the lower outlet header connection; fig. 2A shows a detailed perspective view of the solar thermal receiver of fig. 1A.

Fig. 2B shows a rear view of the solar thermal receiver.

Fig. 2C shows a top view of the solar thermal receiver.

Fig. 2D shows a side view of a solar thermal receiver.

Figure 3A shows a detailed side view of a support beam of a solar thermal receiver,

FIG. 3B shows a detailed end view of the support beam of FIG. 3A.

Fig. 4A shows a perspective view of a second embodiment of a solar thermal receiver mounted on top of a tower in an open position;

fig. 4B shows a perspective view of the solar thermal receiver and tower of fig. 4A in a closed position.

Fig. 5A shows a cross-sectional side view of a solar thermal receiver cover or door.

FIG. 5B shows a cross-sectional elevation view of the solar receiver door of FIG. 5A;

fig. 6 shows a perspective view of a rotary actuator for opening and closing a door by means of a pulley arrangement.

Fig. 7 shows a typical solar thermal collector tower assembly with a solar thermal receiver mounted on the upper side and a rotary actuator attached to the tower base.

FIG. 7A shows a detail of the foundation of the tower of FIG. 7.

Fig. 8A shows a partial perspective view of another embodiment of a solar thermal receiver with an alternative door assembly in an open position.

Fig. 8B shows a partial schematic side view of the solar thermal receiver of fig. 8A with the door assembly in an intermediate position, an

Fig. 8C shows a partial schematic side view of the solar thermal receiver of fig. 8A with the door assembly in a closed position.

Detailed Description

As shown in FIG. 1, CSP system 100 includes an array of heliostats 102-1, 102-2, 102-N (collectively referred to as array 102) for reflecting sunlight towards a solar thermal receiver module 104 on a tower 105. In the simplest form, each heliostat 102-x includes a support member 106 and a reflective member 108 supported by the support member 106. The support member 106 is fixed to the ground 150 (and thus tends to be stationary) while the reflective member 108 is adjustably or controllably rotatable relative to the support member 106. In both cases idealized as relative rotation. The first case is to compensate for the sun's motion during the day to facilitate the direction of continuous solar energy to the solar receiver module 104. The second (case) is to calibrate the heliostat direction or heliostat orientation.

As shown with reference to fig. 1A-1D, a solar thermal receiver 10 (defining a receiver cavity) is shown mounted within a rectangular box-like frame or enclosure 12 that is tilted forward at an angle of approximately twenty degrees from vertical so as to be in an optimal orientation to receive concentrated solar energy from a heliostat array 102. The housing is in turn mounted to an upper side of the solar tower 14 by means of an upper strut 15A and a lower lug 15B. It will be appreciated that the frame may extend to one or more sides of the tower, depending on the location of the heliostat array. An inlet duct or pipe 16 leads from the base of the tower (tower) to a lower inlet header 18 of the solar thermal receiver 10. An upper outlet duct or pipe 20 extends from an upper outlet header 22 and similarly leads to the base of the tower. An array of tubules 24 extends in a serpentine configuration between the inlet manifold of the inlet header 18 and the outlet manifold of the outlet header 22. The array of tubules is similarly inclined forwardly at an angle of about 20 degrees from vertical and the inlet and outlet headers 18, 20 are vertically aligned.

As clearly depicted in fig. 2A-2D, the serpentine array of tubules 24 includes ten individual tubules 26.1, 26.2, 26.3, 26.4, 26.5, 26.6, 26.7, 26.8, 26.9, and 26.10 extending in parallel from the inlet manifold 18A and inlet header 18 to the outlet manifold 22A of outlet header 22. Each of which has a main horizontal component comprising six horizontal channels 26a, 26b, 26c, 26d, 26e and 26f, connected by a smaller upwardly inclined assembly comprising five partially vertical channels 26g, 26h, 26j, 26k and 26m, and which tubes transition from horizontal to partially vertical and back to a tight (aligned) radiused bend 27. As best shown in fig. 2A-2D, the surface of the receiver is single-sided, and the tubules are arranged so that they are in near contact with the subject to act between the tubules (to accommodate inter-tubular play), thereby minimizing radiant heat penetration into the cavity and back flow behind the tubules, and thereby maximizing radiant heat absorption by exposed solar thermal energy absorbing surfaces exposing the tubules. Typically, the distance between adjacent tubules is about 1.5mm, but it will be appreciated that the distance may vary, for example from about 1mm to 3-4mm, to have sufficient spacing to ensure that the adjacent tubules do not contact each other or allow excessive heat to penetrate to the back face.

As shown at 28, most of the bends in the tubule are coplanar with the surface of the receiver. However, there are certain tubules (26.9 and 26.10) that bend out of the illustrated planes 32, 34, and 36 at a bend radius of the desired turn that is less than the achievable bend radius at location 30. The outer planar tubules are in turn bent back into a coplanar configuration with the remaining tubules of the receiver, such as at location 40. The tubules are designed to ensure that the resistance across each tubule is substantially equal and therefore the flow rate through each tubule is similar. Since the lengths of most tubules are substantially similar, the residence time of fluid passing through each tubule is similar. Tubules 26.9 and 26.10 are slightly longer due to the additional bends out of plane, but are compensated for by the out-of-plane portions of the partial shield not absorbing as much heat.

It can be clearly seen how, in the inlet and outlet manifolds 18A and 22A, the spare tubes extend from opposite sides of the inlet and exhaust manifolds to allow sufficient space for the connections established by the inlet and exhaust manifolds, and the even-numbered tubules have re-entry portions so that they can be merged back into the single-sided receiver.

These tubules are mounted together on a pair of parallel tubular support beams 42 and 44, the details of which are more clearly shown in fig. 3A and 3B. It will be appreciated that one support beam or three or more may be provided, depending on the degree of support required. Each support beam comprises a central pipe or duct 46 surrounded by a series of annular support frames 48 separated by annular spacers 50. The support frame and the gasket can slide up and down on the conveying pipe. The support is constructed with apertured projections 52, the projections 52 being mounted in turn by shafts (pins)54 to lugs 56(tabs), the lugs 56 being welded to adjacent tubules 26.1, 26.2, 26.3 and 26.4. Although only one pair is shown in fig. 3A, it should be understood that all of the tubule lugs are coupled to their respective projections by their own dedicated shaft. A support bracket is rotatably disposed (carry) on the delivery tube 46 and a shaft 54 similarly rotatably mounts the projection 52 to the projection 56. This mounting arrangement allows for horizontal and vertical or up and down movement of the tubule (due to thermal expansion and contraction parallel and perpendicular to the horizontal axis) so that the tubule remains horizontal and aligned with the receiver surface and can expand or contract vertically. Spacers 50 between the annular shelves or connections ensure that the vertical spacing of the tubules is maintained with sufficient space to ensure that adjacent tubules do not come into contact.

Tubule support beams (tube supports)42 and 44 are mounted to the housing 12 using an array of connecting rods, including connecting rods 68 extending inwardly to the base of the housing 12, and connecting rods 69 extending upwardly to the upper horizontal frame of the housing. The connecting rod is fitted with a universal coupling 70 to allow freedom of movement during expansion and contraction of the thin tube array.

Referring now to fig. 1E, 1F and 1G, the upper outlet header 22 is shown securely bolted via mounting tabs 62 to an L-shaped mounting bracket 60 extending from the housing 12. The lower inlet header 18 is in turn mounted via mounting lugs 66 to a cross beam 64, which cross beam 64 is disposed at the base of the array of tubules 24 such that it can float relative to the housing 12. This allows the capillary array to expand and contract arbitrarily with thermal changes relative to the housing without placing excessive stress on the capillary array or the inlet and outlet manifolds. The tie rods 68 and 69 provide additional mounting security while allowing the required freedom of movement and the entire tubule assembly is suspended within the housing.

In a particular embodiment, the tubule has an outer diameter of 26.7mm and an inner diameter of 23.4mm, thus having a wall thickness of 1.65 mm. The total height of the tube array was 1.73m, the width of the array from each header was about 2.2m, and the spacing between the outer vertical assemblies was about 1.8 m. It will be appreciated that all of these dimensions can vary widely depending on the desired target dimensions, the type of heat transfer fluid carried, the materials used, and other variables. Typical size ranges are as follows, but are not limited to these ranges:

the outside diameter of the tubules typically ranges from 20mm to 40mm, 25 to 30mm or 26 to 28 mm.

The array height and width is typically 1.5m x 1.5.5 m for flat receivers and 9m x 20m for cylindrical receivers, although the diameter may be only 1m and the height only 1.5m (5 m)²)。

However, the overall size of the receiver is determined by the total field heat input by the surrounding heliostat array, the need to control the desired flux limit at any point in the receiver-1500 kW/m2, the need to minimize flux spillover. The height or width may range from 1.3 to 20.0m²To change between. The receiver need not be square, but the square size can cover 2-400 m of the receiver²The size of (c). The preferred size of the square receiver is 10-15m²Typically 13m²(width 3.7mx and height 3.7 m).

Without being bound by theory, in order to minimize thermal stress gradients, it is desirable to make the tubules as thin as possible while maintaining their structural integrity. Considering the material used and the diameter of the tubule, it is considered that the thickness of the tubule is from 1.8mm to 1 mm. In particular, for a tubule outer diameter of 25-27mm, a thickness of 1.1-1.3mm, or 1.2mm, may be considered.

Suitable materials are selected for the receiver to allow for high and variable temperature operating conditions, and to withstand creep and fatigue. Based on an evaluation of the 1000 hour service life under creep conditions (intermediate wall temperature around 650C), stainless steel alloys 230 and 625 were found to be potentially viable alloys, but other stainless steel alloys, such as 316H, 347H, and nickel-based alloys, such as inconel, may also be used.

It will be appreciated that the number of channels and the number of tubules may vary, and the supports may be arranged so that the face of the receiver is flat, curved or multi-faceted, depending on the application. For example, a tubule may be used with 60 channels, 2 tubules and 30 channels, 3 tubules and 20 channels, 4 tubules and 15 channels, 5 tubules and 12 channels, 6 tubules and 10 channels, 10 tubules and 6 channels, 20 tubules and 3 channels. In each case, the optimal heating time (heating to the desired temperature 600C) needs to be balanced with the optimal through-flow.

It will be appreciated that the array of thin tubes extend from the operatively lower inlet header 18 to the operatively upper outlet header 22, so defining a horizontal or upward (i.e. single) fluid flow path, not downward at any location, thereby facilitating the natural outflow or venting of gas through the outlet header, and avoiding or at least reducing the formation or accumulation of gas pockets, and ensuring a relatively uniform flow resistance and constant fluid flow. At low flow rates with a vertical up/down flow configuration, buoyancy effects can cause local stagnation in one or more tubes.

Referring now to fig. 4A-4B, a second embodiment of a solar thermal receiver 10A is shown mounted within a rectangular box-like frame or enclosure 12A defining a receiver cavity that is tilted forward at an angle of about 20 degrees from vertical so that it is in an optimal orientation to receive concentrated solar energy from the heliostat array 102. The heliostat array may comprise a wide variety of heliostats of the type described in published international patent application WO2015143494 (in the name of the applicant), but is not so limited. The housing is in turn mounted on one upper side of the solar tower 14 by means of an upper strut 15A and a lower projection (not shown). It will be appreciated that the frame may extend to one or more other sides of the tower, depending on the location of the heliostat array. An inlet duct or pipe 16 leads from the bottom of the tower to a lower inlet header (not shown) of the solar thermal receiver 10A. An upper outlet duct or pipe 18 extends from the upper outlet header and similarly leads to the base of the tower. The inlet and outlet ducts or pipes 16 and 18 may be insulated and protected by wrapping in a segmented pipe insulation layer (e.g., spun mineral wool) and covering it in a weatherproof outer surface layer (e.g., galvanized steel).

The array of tubules 19 extends in a serpentine configuration between an inlet manifold of the inlet header and an outlet manifold of the outlet header. The capillary array was similarly tilted forward at an angle of about twenty degrees from vertical. The array of tubules 19 is similar to the array of 24 of the first embodiment.

The insulated door assembly 20A includes a frame 22A, which frame 22A includes a front frame portion 24A carrying a door 26A and a rear frame portion 28A carrying a counterweight 30A. The frame is pivotally mounted on an axle 32A via a pair of vertical supports 34A. The shaft 32A is in turn carried on a pair of trunnions 36A, the trunnions 36A being mounted on top of the housing 12 of the receiver. Extending rearwardly from the upright support 34A are pairs of tubular extension arms 38A, 40A which form the rear frame 28A. The counterweight 30A is bolted between the rearmost ends of the extension arms 38A.

Extending forwardly from the upright support 34A are a pair of inner extension arms 40A mounted at the upper end of the door, and a pair of outer extension arms 42A mounted on apertured tabs 44A located midway along the outer surface of the door 26A. The cross member 47A extends between the vertical poles (vertical support bars) 34A. The exterior surface of the door 26A and the extension arms 40A, 42A are fitted with a refractory plate 48A formed of a high strength reinforced silica-based composite or other suitable temperature resistant rigid material to provide shielding from concentrated solar radiation. The front of the frame 12A is similarly fitted with a refractory plate or pan 48 AA.

The composition of the (ascertained) insulated door assembly is more clearly shown in fig. 5A and 5B. Below the fire resistant plate 48A is a weather shield 50A formed of galvanized steel. Which covers a ceramic fiber blanket 52A comprising a thicker outer layer 52AA in the 50mm thick area and an inner layer 52BB located inside the door frame 54A, the entire blanket assembly being bonded to (fastened to) the door frame 54A stainless steel mesh 56A in the area of half the thickness of the outer layer. In one example, ceramic fiber blanket 52A may be an alumina-silicate fiber blanket, but it will be appreciated that they may be formed from any other suitable temperature insulating and heat insulating material, as well as combinations of these materials.

The door assembly 20A pivots between an open position, shown in fig. 4A, and a closed position, shown in fig. 4B, in which the outer edge of the door forms a close fit of the array of tubules 20A within the receiver cavity, effectively shielding the tubules 19 from solar radiation. The door assembly is moved between the open and closed positions by an endless cable that extends over a pulley 58 that is splined to shaft 32A. The cable and pulley arrangement may be replaced with various other types of actuators, including rack and pinion arrangements, and electric, hydraulic or pneumatic linear actuators or drives acting between the door and the tower.

As shown in fig. 6 and 7, the looped cable 60A extends around a drive wheel 62A (the extended pulls the cable between the two posts), which drive wheel 62A in turn is driven by a rotary actuator 64A, which includes a gearbox and clutch mechanism (not shown). A first set of external limit switches 66A and 66B are adjustably positioned along the external slots 67A and 67B to limit movement of the door between the open and closed positions (corresponding to 110 deg. of rotation). The outer limit switches 66A and 66B represent the open and closed positions of the door, respectively. A second set of internal limit switches 66C and 66D may also be adjustable on corresponding internal slots 67C and 67D to adjust the speed of the rotary actuator 64A. To mitigate the effects of starting and stopping when the door assembly is operating, for example, the actuator is operated at a reduced speed until it passes the first internal limit switch 66C, at which time the rotary actuator 64A increases its speed. When the rotary actuator 64A passes the second internal limit switch 66D, its speed (of the rotary actuator 64A) is again reduced and maintained at that reduced speed until the second external limit switch 66B triggers the actuator to stop. The looped cable 60A is tensioned by a pair of auxiliary pulleys 68A. The length of cable 60B that moves downward when the door is opened may be further tensioned by one or more counterbalances (not shown).

The actuator 64A comprises any prime mover including a compressed air actuator, an electric or internal combustion engine, or the like. The actuator is in turn configured to receive a control signal from a remote controller. It will be appreciated that the door may be opened or closed in response to any number of such signals, including an operator direct control or automatic opening and closing in response to one or more sensors, such as infrared sensors or cameras or flow sensors, that detect a desired condition (e.g., a need to close the door). These may include overheating or cooling of the receiver, which may be measured by the temperature of the sodium exiting the receiver, the flow of sodium through the capillary array or other blockage or restriction of the heat transfer fluid, a power outage, or extreme weather conditions.

Fig. 7 shows a perspective view of a typical solar tower assembly 400 with the solar thermal receiver 10A mounted on top of the tower in the manner previously described, with the rotary actuator 64A attached to the base 140 of the tower, and the looped cable 60A tensioned between the drive wheel and the pulley 58. The tower assembly 400 may be fitted with one or more target areas in the form of rectangular plates 402 to enable individual heliostats to be aimed and calibrated to analyze the solar image on the target heliostat reflection using a camera.

Referring now to FIG. 7A, the base of the tower is formed from base plates 404A and 404B bolted to the concrete plinth. The base plate 404A is bolted to a respective leg 406A of the tower, and the base plate 404B is pivotally mounted to the respective leg 406B by a pivot pin 408. For ease of maintenance, the legs 406A are unscrewed from the respective base plate 404A and the tower is tilted down to a horizontal position by pivoting the pivot pin 408. In the illustrated embodiment, the inlet and outlet headers 16 and 18, which are covered with insulation, are moved to a position where they extend adjacent the rear surface of the tower (about 1-1.5 meters from the corner post 210 of the tower) so that they can be easily accessed in a low position. It will be appreciated that once the sodium has cooled and solidified to enable the tower to be winched, the pipes 16 and 18 may be disconnected at the foundation. A thermal tracer element (not shown) in the form of a mineral insulated cable extends along and in direct contact with the pipes 16 and 18 below the insulation layer, causing the solidified sodium to be reheated to a melting point above 98C (after the tower has been raised and the pipes reconnected).

Fig. 8A-8C illustrate an alternative embodiment of a door assembly 70 that includes a door 72, the door 72 being equipped with a four-bar linkage mechanism that includes upper bars (upper bars)74A and 74B and lower bars (lower bars)76A and 76B. The upper rods 74A and 74B are disposed at their upper ends and are mounted to the upper portion of the opposite side of the tower 105 at pivot points 78. The lower end of the upper rod is mounted to the upper side of the door 72 at pivot point 80. The lower bar is similarly directed to the underside of the door 72 at pivot point 82 and the opposite end of the bar is mounted to the tower 105 or an extension thereof (not shown) at pivot point 84.

As best seen in fig. 8A-8C, the door is shown pivoted on the lever from the open position of fig. 8A to the closed position of fig. 8C, wherein the door 72 completely covers the receiver 88. Various means may be used to move the door between the open and closed positions, including pulley arrangements acting on the upper and/or lower bars, or linear drives or actuators (electrically, hydraulically or pneumatically operated) acting on the upper or lower bars, and curved rack and pinion arrangements may also be used to pivot the upper and lower bars up or down. As an alternative to a four bar linkage, the door 72 may also be configured to travel on a pair of tracks that follow a similar path as the trajectory of the door on the four bar linkage.

An advantage of these arrangements for the door (pivoted from the upper frame of the receiver) is that in the open position the door can protect the portion of the tower closest to the receiver from excessive solar radiation from the heliostat array, thereby avoiding the need for additional refractory cladding. In addition, the additional load on the receiver device is avoided by the separate mounting arrangement of the door. However, in one embodiment, the (and) catches (not shown) make up the upper and lower portions of the doorframe, and the uppermost portion of the door 72 may be engaged by a complementary catch (not shown) to improve the stability of the door (in the open and closed positions). Another advantage is that it is the same side of the door that is always exposed to solar thermal radiation, with the result that said exposed side of the door can be specially configured to resist high thermal radiation.

As for the receiver, different configurations of the tubules may be used, including a predominantly transverse serpentine configuration as exemplified above, or other configurations in which fluid flow through the tubules is predominantly transverse and upward (i.e., unitary) from the lower inlet to the upper inlet.

It has been found that in general, the life of the receiver can be extended by distributing the heat flux evenly and arranging the receiver tubes in a serpentine pattern, as opposed to a single pass multi-tube array where the tubes are predominantly vertical or upward.

A variety of heat transfer fluids may also be used, including molten salts, liquid metals (e.g., sodium), and water/steam. In certain embodiments, sodium is a preferred heat transfer fluid because of its high thermal conductivity, enabling it to heat up relatively quickly and having a relatively high heat capacity at high temperatures. It maintains a wide temperature range (98C to 883C) in the liquid state, provides a sufficient upper limit in the case of overheating (operating temperature range higher than 500C to 600C), and has a lower freezing temperature than the salts that have been traditionally used.

It will be understood that the invention disclosed and defined in this specification extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the present invention.