ES2401612A2 - Use of elevation and turning of parabolic cylinder collector modules and fixing procedure thereof (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Uplifting and lifting tool of parabolic trough collector modules and its fixing procedure consisting of three parts: lifting and tipping means of the parabolic trough collector module (with mooring (4) for the chain that connects the module to the system elevation and the axis of rotation (7) of the tool), means for fixing the tool to the parabolic cylinder collector module (fixing parts (1) that connect the module and the tool and a bolt that joins the module with the reaction profile ) and securing means (two safety pins (2, 3) and the anchors (6) of the pins). The use of the tool allows the lifting and tilting operation of the solar collector module with only one overhead crane and a single tool, improving production and safety. (Machine-translation by Google Translate, not legally binding)

Description

USEFUL LIFTING AND FLASHING OF PARABOLIC CYLINDER COLLECTOR MODULES AND SAME SETTING PROCEDURE

Technical sector of the invention The invention corresponds to the sector of tools, tools or mounting instruments for parabolic trough collectors. Specifically, it is a tool for lifting and turning each of the modules that make up these collectors, during their assembly process. Background of the invention The assembly process of the structures of the modules of the parabolic trough collectors is carried out within an assembly hall. In the ship, a series of operations are carried out to obtain a completely assembled module (structure and mirrors) from the different parts that make up the structure. The proposed invention is included within the necessary tools to be able to carry out these works in the most optimal way possible. To properly understand the tool referred to in this report, it is necessary to understand what the module parts of a parabolic trough ("CCP") module are and how the modules are assembled to form a collector. The modules of the CCP are designed to support the absorber tubes through which the heat transfer fluid passes (whose mission is to transport the energy of solar radiation in the form of heat) and maintain the parabolic surface formed by the mirrors that concentrate the radiation solar in the absorber tube during the movement of the collector following the sun. The rotation movement that allows the sun to be tracked is transmitted from a central pylon ("drive pylon") to the ends of the collector. The rotation torque generated by the movement system is transmitted through the torsion beam of the modules ("torque box") and between modules through the simple and composite reaction profiles of the adjacent modules. The modules are supported by structures called simple pylons or "simple pylons" through dry bearings. The bearing cradle is placed in the "simple pylon" while the cylinder (also called "torque transfer tu be", hereinafter TTT) is located on the axis of rotation of the module and is located within the reaction profile composed of the modules The union between modules of the same collector and therefore the continuity in the transmission of the movement generated by the central pylon or "drive pylon" is achieved

by screwing the simple reaction profile of the module adjacent to the composite reaction profile of the previous module. During the manufacturing of the previous modules used in the solar fields of the first commercial Abengoa Solar plants, the lifting and turning processes were independent. Using a tool, the module was lifted with a crane bridge to the appropriate height where the module was hooked with another crane bridge with the help of another tool. The use of the proposed tool makes it possible to carry out the lifting and turning operation with only one crane bridge (two were previously necessary) and a single tool (one was previously necessary for lifting and another for turning). The use of a single tool reduces the time of operations, improving production and safety, as it is not necessary to change the height of tools, and risks of falling objects and people at different levels appear. Similar tools are not known in the state of the art. Therefore, the present invention aims to provide an instrument capable of performing this operation with a single crane bridge and a single tool with the purpose of improving the existing process of building CCP modules. Description of the invention The tool of the invention consists of three main parts differentiated according to the purpose for which they have been designed: means for lifting and turning the module, means for fixing the tool to the module and means for securing the fastener.

The lifting and turning means consist of two parts: the mooring for the chain that joins the module to the lifting means (crane or similar) and the axis of rotation of the tool. · Both parts are mounted so that they can rotate one respect to the other functioning as a friction bearing. The joint between the two is lubricated to minimize friction. The fixing means of the tool to the module is a redundant system and is formed by the fixing parts of the modules to the compound reaction profile and by the positioner of the compound reaction profile. The fixing parts are connected to the CCP module that you want to lift and turn through a bolt with a nut, the module and the tool being joined together in solidarity. The positioner of the compound reaction profile is attached to the CCP module through a bolt inserted in a hole in the positioner and in another hole in the reaction profile. This redundancy in the module-useful union, makes the fixing parts can be expendable as long as a good fixation of the positioner of the compound reaction profile is guaranteed.

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The fastening security means are constituted by two safety pins and the anchors of said pins. The positioner has guide cylinders on the inside of which the pins slide. The anchoring of the pins is welded to the positioner and has a groove. The pins have appendages that are inserted into the groove of the anchors to eliminate their sliding once the module has been attached to the tool. Both the pins and the anchors can be arranged in different ways in the tool to facilitate the construction process.

Once the tool has been manufactured, all the pieces form a set in which the single ca piece that has freedom of movement is the mooring since it can rotate on the axis of rotation of the tool. The pins are independent parts that once inserted into the positioner guide cylinders are fixed. The lifting and turning system can be implemented in all the tools whose object tive be the lifting and turning of the modules, regardless of the shape of the manifold. However, the fixing means of the tool to the module and the tracking means The strength of the clamp takes shape depending on the type of module that you want to manufacture since they depend on the design and geometry of the module in question. This tool is specially conceived for its application in the manufacture and assembly of CCP modules, but its extension to other fields of industry is not ruled out that require similar characteristics.

Brief description of the drawings

To complete the description that is being made and in order to help a better understanding of the invention, a set of drawings is attached where, with an illustrative and non-limiting nature, the following has been represented: Figure 1: General view of the module and the Structure of a CCP Figure 2: Composite reaction profile and simple reaction profile Figure 3: Reaction profile with the tool installed Figure 4: Lifting and turning tool Figure 5: Views of the lifting and turning tool Figure 6: Part 1, Fixing part to the compound reaction profile Figure 7: Part 2, Safety pin Figure 8: Part 3, Safety pin Figure 9: Part 4, Mooring piece Figure 10: Part 5, Positioner Figure 11: Part 6, Anchoring pin safety Figure 12: Part 7, Tool rotation axis The references in the drawings correspond to: 1 Fixing part to the compound reaction profile 2 Safety pin

21 solid cylinder 22 bumper 23 appendix 24 second solid cylinder

3 Safety pin 31 solid cylinder 32 butt 33 appendix 34 second solid cylinder

4 Mooring piece 41 hollow cylinder 420 card

5 Positioner 51 main plate 52 side plates 53 base plates 54 guide cylinder

6 Pin safety anchorage 61 slit

7 Tool rotation axis 71 main axis 72 circular stop with central hole 73 circular stop without central hole 74 brackets 75 solid cylinder

100 Central pylon or "drive pylon" 200 Single or "simple pylon" pylon 300 Cylinder or «Torque Transfer Tube» 400 Torsion beam or «Torque Box» 500 Absorber tube

600 Mirrors 700 Composite reaction profile 800 Simple reaction profile Preferred embodiment of the invention In order to achieve a better understanding of the invention, the tool according to a preferred embodiment will be described below. Figures 1 and 2 correspond to an overview of the CCP module, as explained in the background section of the invention. The CCP modules are designed to support absorbing tubes

(500) and maintain the parabolic surface formed by the mirrors (600) that concentrate tran solar radiation in the absorber tube (500) during collector movement following the sun. The rotation movement that allows you to track the sun is trans Measure from a central pylon (100) to the ends of the manifold. Rotation torque generated by the motion system is transmitted through the torsion beam

(400) and between modules through simple reaction profiles (800) and composites cough (700) of the adjacent modules. The modules are supported by structures called simple pylons

(200) through a dry bearing. The bearing cradle is placed on the pylon simple (200) while the cylinder, also called "torque transfer tube", in forward TTT (300) is located on the axis of rotation of the module and the qualified within the composite reaction profile (700) of the modules. The union between modules of the same collector and therefore the continuity in the Transmission of the movement generated by the central pylon (100) is achieved by screwing the simple reaction profile (800) of the module adjacent to the composite reaction profile

(700) of the previous module, the TTT being thus housed in the cradle of the bearing. During the manufacturing of the previous modules, the lifting and turning processes were independent. Using a tool, the module was raised with a door you crane up to the right height where with another crane bridge the mó hooked I say it with the help of another useful flip. The use of the proposed tool allows the lifting and turning operation with only one crane bridge (two were previously required) and only one useful (before it was necessary one for the elevation and another one for the turning).

The parts of the tool are manufactured in structural steel (although they could be manufactured in other materials) since the load requirements that must be supported are acceptable for this steel.

The construction of this tool and its attachment to the module are explained below. As previously stated, the tool (figure 4) is made up of three main parts differentiated according to the purpose for which they were designed: means for lifting and turning the module, means for fixing the tool to the module and safety means for the clamping:

one.

The lifting and turning means consist of two parts: the mooring (4, figure 9) for the chain that joins the module to the lifting system (crane or similar) and the axis of rotation of the tool (7, figure 12 ). Both parts are mounted so that they can rotate with respect to each other. The mooring piece (4), which is detailed in Figure 9, is constructed from a hollow cylinder (41) of greater internal diameter than the outer diameter of the one to be used for the tool axis (7). Next, the lug (42) is welded where the hook of the lifting element (normally crane bridge) is attached. Next, the rotation axis (7) of the tool, detailed in Figure 12, is manufactured. A series of strips (74) are welded in the longitudinal direction on the side of the end of the main shaft (71) (four strips can be placed leaving an angle of 90 ° between them). At the other end of the main shaft (71) a circular stop (72, circular piece with central hole) is introduced up to almost half the length of this shaft (71) and welded. The hollow cylinder (41) of the mooring piece (4) is introduced. A second circular stop (73, without central hole) is welded at the opposite end of the cartels (74) of the main shaft (71) and aligned with the center of the cylinders. On the other side of the circular stop (73) a solid cylinder (75) of smaller diameter is welded than the outer diameter of the main shaft (71). In an alternative manufacturing of the rotation axis (7) the main axis (71) is divided into two so that the first cylinder includes the cartels (74) and ends in a circular stop (72) and the second cylinder that delimits between two circular stops (72, 73) And the hollow cylinder (41) of the mooring piece (4) rotates on it. In this case, both circular stops are equal and without a central hole.

2.

The fixing means of the tool to the module are redundant and are formed by the fixing parts (1, figure 6) of the modules to the compound reaction profile (700) and by the positioner (5, figure 10) of the compound reaction profile . The fixing parts (1) to the compound reaction profile (700) are made of sheet metal with a drill and are

weld to the stop (72) closest to the cartels (74), forming a 90 ° angle between them, as indicated in the assembly plan (figures 4 and 5). Then they connect to the CCP module that you want to lift and turn through a bolt with a nut, the module and the tool being joined together in solidarity. The positioner (5) of the compound reaction profile (700) is attached to the CCP module through a bolt inserted in a hole made in the positioner (5) and in another hole existing in the reaction profile (700). This redundancy in the module-useful union, makes the fixing parts can be expendable as long as a good fixation of the positioner (5) to the compound reaction profile (700) is guaranteed. The axis of rotation of the tool (7) is welded to the positioner (5) by the main axis

(71) and its posters (74). Figure 10 shows the positioner (5). The positioner (5) has a recessed shape and is constructed from several pieces of sheet of the appropriate thickness: a square or rectangular main flat plate (51) (taking into account the geometry of the compound reaction profile (700)) and in two of its opposite sides are welded at 90 ° rectangular side plates (52) of the same length as the side of the main plate (51), to each of those side plates (52) a base plate is welded at 90 ° rectangular (53) of the same length as the sides (52) and out of the recess, so that the positioner (5) thus designed fits or "hugs" the profile (700) in question. On the rear face of each base plate (53), guide cylinders (54) are welded to serve as guides for pins (2, 3). Anchors (6) for said pins (2 and 3) are fixed by welding on the front face of the base plate (53).

3. The fastening security means are constituted by two pins (2, 3) and their anchors (6, figure 11). As shown in Figures 7 and 8, each of the pins (2 and 3) is constructed with two solid cylinders (21 and 24, 31 and 34). One of the two cylinders (24, 34) that constitutes each pin has a stop (22, 32) in the form of a flat ring welded at one of its ends. The other cylinder (21, 31) that constitutes each pin has an appendix (23, 33) welded at one of its ends. Said appendix (23, 33) consists of a small solid cylinder perpendicular to the main cylinder (21, 31) with a flat ring (22, 32) welded at its midpoint. To configure the pin, both cylinders (21 and 24, 31 and 34) are welded, forming an "L". The cylinder (24, 34) that has the stop (22, 32) is welded by the end closest to the stop (22,32) and the cylinder (21, 31) that has the appendix (23, 33) is welded by a point near the end of the appendix (23, 33).

The positioner (5) has guide cylinders (54) inside which the pins (2, 3) slide. Figure 11 shows the anchor (6) of the pins (2, 3), which is welded to the positioner (5). The anchor is a rectangular sheet and has a "U" shaped slot (61). The appendices (23,33) of the raisins

5 doors (2, 3) are introduced into the slit (61) of the anchors (6) to eliminate their sliding once the module has been attached to the tool. The procedure for fixing the lifting and turning tool to the parabolic trough collector module comprises the steps:

• Join the positioner (5) of the compound reaction profile (700) to the module

10 of the parabolic trough collector through a bolt inserted in a hole in the positioner (5) and in another hole in the reaction profile (700);

• Weld the fixing parts (1) to the stop (72) closest to the brackets (74), forming an angle between them of 900 and connect with the CCP module that

15 it is desired to raise and turn through a bolt with a nut, the module and the tool being joined together in solidarity;

• Slide the pins (2, 3) inside the guide cylinders (54) and insert the appendages (23, 33) of the pins (2, 3) into the slit (61) of the anchors (6) to remove sliding them once the mó

20 dulo has joined the tool.

Claims (7)

one.

Tool for lifting and turning of parabolic trough collector modules (CCP) that serves to facilitate the assembly process of the structures of the parabolic trough collector modules characterized in that the tool comprises lifting and tipping means of the cylinder collector module parabolic, means for fixing the tool to the parabolic trough collector module and means for securing the fastener; where the lifting and turning means of the module are formed by a mooring piece (4), comprising a hollow cylinder (41) welded to a lug (42) where the hook of the lifting element (crane bridge or similar) is attached and an axis of rotation of the tool (7), which comprises a main axis (71) that is inserted into the hollow cylinder (41), the mooring piece (4) being able to rotate with respect to the axis of rotation of the tool (7).

2.

Lifting and turning tool according to claim 1 characterized in that the axis of rotation of the tool (7) comprises a main axis (71), which at one end has a series of brackets (74) welded in the longitudinal direction, in the middle area it has welded a circular stop (72, circular piece with central hole) and at the other end aligned with the center of the main shaft (71), a second circular stop (73, without central hole) is welded; a solid cylinder (75) of smaller diameter than the outer diameter of the main shaft (71) is welded on the other side of the circular stop (73).

3.

Lifting and turning tool according to claim 1 characterized in that the main shaft (71) is divided into two so that the first cylinder includes at one end some welded (74) in longitudinal direction and ends in a circular stop

(72) at the other end and the second cylinder is delimited between two circular stops (72, 73) And on the other side of the circular stop (73) a solid cylinder (75) of smaller diameter is welded than the outer diameter of the main shaft (71). 4. Lifting and turning tool according to claim 1 characterized in that the fixing means of the tool to the CCP module comprise a positioner (5) of the compound reaction profile (700), where the positioner (5) is in the form of a recess and is constructed from several pieces of sheet of the appropriate thickness: a square or rectangular main flat plate (51) (taking into account the geometry of the composite reaction profile (700 »and on two of its sides welded at 90 °) rectangular side plates ( 52) of the same length as the side of the main plate (51), each of these side plates (52) is welded at 90 ° and out of the recess, a rectangular base plate (53) of the same length as the lateral (52), on the back of each base plate (53), guide cylinders (54) are welded, on the front face of the base plate (53), anchors (6) of sheet metal with a slit (61) are fixed by welding.

5.

Lifting and turning tool according to claim 1 characterized in that the fixing means of the tool to the CCP module comprises fixing pieces (1) of sheet metal with a hole welded to the axis of rotation of the tool (7).

6.

Lifting and turning tool according to claim 1, characterized in that the fastening safety means are constituted by two pins (2, 3) and their anchors (6, figure 11), each of the pins (2 and 3) being constructed with two solid cylinders (21 and 24, 31 and 34) counting, one of the two cylinders (24, 34) that constitutes each pin, with a stop (22, 32) in the form of a flat ring welded at one of its ends and the another cylinder (21, 31) that constitutes each pin has an appendix (23, 33) welded at one of its ends, said appendix (23, 33) consisting of a small solid cylinder perpendicular to the main cylinder (21,31) with a flat ring (22 or 32) welded at its midpoint; the pin is configured with both cylinders (21 and 24, 31 and 34) welded forming an "L", with the cylinder (24, 34) that has the stop (22, 32) welded by the end closest to the stop (22 , 32) And the cylinder (21, 31) that has the appendix (23.33) welded by a point near the end of the appendix (23.33).

7.

Method of fixing the lifting and turning tool described in the preceding claims to the parabolic trough collector module characterized in that it comprises the steps:

•

Join the positioner (5) of the compound reaction profile (700) to the module of the parabolic trough collector through a pin inserted in a hole made in the positioner (5) and in another hole existing in the reaction profile (700);

•

Weld the fixing parts (1) to the stop (72) closest to the brackets (74) and connect with the CCP module that you want to raise and turn through a bolt with a nut, the module and the tool being joined together in solidarity ;

•

Slide the pins (2, 3) inside the guide cylinders (54) and insert the appendages (23, 33) of the pins (2, 3) into the groove (61) of the anchors (6) to remove the sliding them once the module has been attached to the tool.

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