• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
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  • 优先权
    • 专利摘要:
    Channeling thermally isolated and with heat extraction, with interior at very low temperature. Device that uses cryogenic sources to circulate a coolant fluid through well-adjacent pipes, or immersed in longitudinal vessels that make up the walls of the pipeline, having inside the containers, which are hermetic, a fluid that either freezes, or it cools below its triple point, with the consequent decrease in effective thermal conductivity through said device, which is configured in its straight section as a superposition of circular crowns, structured as selected beams between circular containers, or containers vaulted (Machine-translation by Google Translate, not legally binding)
    公开号:ES2598171A1
    申请号:ES201630522
    申请日:2016-04-25
    公开日:2017-01-25
    发明作者:José María Martínez-Val Peñalosa;Javier Muñoz Antón;Juan Manuel González García
    申请人:Universidad Politecnica de Madrid;
    IPC主号:
    专利说明:

    THERMALLY ISOLATED CHANNELING AND WITH HEAT EXTRACTION, WITH INTERIOR TO VERY LOW TEMPERATURE

    DESCRIPTION
    Technical sector 5
    The invention falls within the field of thermal engineering, particularly in applications that require conduction or channeling through which a fluid circulates or a cable is deployed that is to be maintained at a very low temperature, for example, for superconductivity applications.
     10
    Technical problem to solve and background of the invention
    The problem is to configure a structural system with adequate mechanical resistance, which offers great resistance to the passage of heat through it, to preserve the interior of the pipeline at temperatures well below that of the exterior. fifteen

    There is a high number of catalogs of thermal insulators as well as documents, both scientific and industrial property, that disclose assemblies with successive layers, including vacuum panels (or more properly, of very low density of the interior gas filling the panel), as There are also sheets 20 of expanded material, such as polyurethane and polystyrene.

    The problem is to combine the thermal insulation with the mechanical resistance, because when a very solid structure is available, thermal bridges are created and the insulation suffers, since there is a good conduction through said 25 bridges.

    The utility model with publication number 1142732 "Rigid thermal insulation panel with internal vacuum" discloses a mechanical way of making the vacuum, by suction, totally different from that presented in this invention, both in the arrangement of elements and in the physical mechanism used in each case.
    Explanation of the invention.
    The invention takes advantage of the changes of state produced by the extraction of heat to constitute an insulating wall, either by the thermal properties of the solidified or frozen mass, or by the sharp decrease in density that is caused in a sealed tube or prism, initially filling of a gas at a specified pressure, and by another fluid passing through an adjacent conduit at a temperature below that of the triple point of the said fluid in the first place.

    The invention uses sources of cold, or cryogenic, that are not the subject of this invention, and that can be constituted by a ladder or succession of 10 sources with different working fluids in its thermodynamic cycle, such that the hot branch of a Cycle is at a temperature a few degrees Celsius above the cold branch of the cycle that works at the immediate higher temperature level, until it reaches room temperature.
     fifteen
    The invention consists in using cryogenic sources where a cooling fluid is cooled that cools another fluid, called cooled fluid, contained in airtight containers that constitute a layer of cylindrical or prismatic geometry, generally of length much greater than its transverse size, in whose containers the cooled fluid undergoes a thermodynamic transformation 20 selected from
    - freezing of the cooled fluid, initially contained in one or more containers that form a geometric figure with continuity, said fluid having the property of freezing forming a continuous solid and with pieces that fuse, as is the case of water, when forming ice; 25 said freezing being produced by the action of the cooling fluid flowing through adjacent or internal pipes to the referenced containers, the cooling fluid being cooled by at least one cryogenic source;
    - partial solidification within the containers because the fluid contained therein is cooled below its triple point, by the cooling action of another fluid, cooler, at the temperature of its triple point below that of the cooled fluid, being in turn the cooling fluid cooled by at least one cryogenic source.
    The relative arrangement between the spaces occupied by the fluid that cools below its triple point, and the cooling fluid, is selected from
    - a beam or plurality of cylindrical containers that are arranged in the form of a circular crown, adjacent each container with its two neighboring containers, those containers being the ones that hermetically contain the fluid that cools below its critical point, and said paths being traveled containers, along, also cylindrical conduits through which the cooling fluid circulates, which goes from a cryogenic source to another located at a certain distance, or goes to the end of a section through some pipes and returns to the same cryogenic source by other conductions parallel to the outbound ones; 10
    - a beam or plurality of domed-shaped containers that are also arranged in the form of a circular crown, the circular crown being closed on the outside by a cylindrical surface that is tangent to the apex of the vaults, and the circular crown being closed on the inside by another cylindrical surface on which both stirrups of each vaulted container 15 rest, the vaults being tightly closed at their ends, and originally filled with the fluid that cools below its critical point, and the cooling fluid circulating through the extrados of the vaults, from one cryogenic source to another, or round trip, through different extradós conduits, from a cryogenic source to itself. twenty

    The aforementioned circular crowns can be stacked radially, using gases to be cooled and cooling fluids, of respectively lower triple point temperatures for each crown, the more interior it is.
     25
    Each circular crown consists of two semi-crowns, one lower and one upper, which are adjusted by geometry, but which are independent in airtight containers and pipes.

    In what corresponds to the freezing layers, one of these is constituted by a lower half in a U-shape and a top horizontal cover with a slab shape.


    Explanation of the figures
    The figures, in general, are not to scale, since the relative sizes of the elements are very different; but they are representative of the invention and its operating principles. 5

    Figure 1 shows a diagram, in straight section, of the layer generated by freezing.

    Figure 2 shows the longitudinal scheme of the assembly, between two cryogenic sources 10 that are at its ends.

    Figure 3 shows the straight section of two insulating layers generated by partial vacuum induced by cooling a gas below its triple point, in cylindrical containers. fifteen

    Figure 4 corresponds to one of the cylindrical containers of the previous figure.

    Figure 5 corresponds to the straight section of a triple layer of insulating circular crowns, with gas cooled inside the vaults, and cooling gas on the outside of them.

    Figure 6 is similar to 5, with a vault arrangement that allows the three circular crowns to be split into two halves of the same type at the same time.
     25
    In order to facilitate the understanding of the figures of the invention, and of their embodiments, the relevant elements thereof are listed below:
    1. Central duct where it stays low or very low temperature.
    2. U-container for freezing ice or similar substance, such as a eutectic or saline water. 30
    3. Containment walls of the liquid that freezes and merges with the arms of the U.
    4. Slab type lid, also produced by freezing
    5. Gas cooler ducts.
    6. Cryogenic sources. 5
    7. Containers containing the gas to be cooled below its triple point.
    8. Cylindrical surface that is the inner boundary of the insulating layer.
    9. Cylindrical surface that is the outer border of the insulating layer.
    10. Helical springs for holding cooling liquid pipes.
    11. Vaults of the outermost circular crown. 10
    12. Conductions of the extradós of the vaults 11.
    13. Intermediate circular crown vaults.
    14. Conductions of the extradós of the vaults 13.
    15. Vaults of the innermost circular crown.
    16. Conductions of the extradós of the vaults 15. 15
    17. Outer shell of the outer crown.
    18. Wrap between the intermediate and outer crown.
    19. Wrap between inner and intermediate crown.
    20. Inner wrap of the inner crown.
    21. Coupling surface between the upper and lower circular semi-crowns. twenty

    Embodiment of the invention
    The invention has two complementary parts:
    - The mechanical structure that provides the stability and functionality of containers and pipes, and that can be manufactured with various materials, depending on the design pressure to confine the fluids used, and the mounting and operating temperatures;
    - Working fluids, which must meet very clear requirements in their thermodynamic properties, and which are very specific to this invention.
    Regarding the latter, in the case of freezing the most immediate is ice, which gives a perfect temperature reference, and also forms a true barrier not only against heat but against other aggressive substances, such as groundwater itself. To do this, around the volume (1) that is the true useful or channeling area, a U-container (2) is placed under it, which is filled with the liquid to be frozen, and which incorporates the pipes (5) of the fluid cooler, which are also placed in parietal vessels (3) and in the lid (4). The cooling fluid pipes are connected to cryogenic sources (6).
     10
    The partial vacuum vessels can be configured as cylinders (7) neatly packed inside an inner (8) and outer (9) cylindrical surfaces that delimit a crown, and within the vessels the supported cooling fluid pipes (5) are housed by helical springs (10). In each crown, the vaults (11, 13, 15) make up the space where the cooled fluid 15 is, while outside the extradures are the conduits of the cooling fluid, confined on the outside by the outer envelopes of each crown (17,18 , 19). In turn, the volume (1) is confined by the envelope (20); and in order that the volume (1) is accessible, the crowns, either one by one, or all together, are separable into two halves, lower and upper, leaving a coupling surface between them (21).

    To be used in the partial vacuum vessels by cooling a gas below its triple point, there are several possible substances, which used two to two, as a cooled gas and as a cooling fluid, would provide the result provided for in the invention.

    One of the tightest cases is that of nitrogen and argon. The latter has a triple point of 83.81 K; while the N2 at atmospheric pressure has a liquid-vapor equilibrium temperature of 77 K. 30

    If the argon vessels are originally filled at atmospheric pressure, and with temperature a few degrees above 0 ° C, their density will be about 2 kg / m3; and when it cools a little below its triple point, part of the argon will solidify, and will be useless for the purpose of heat transmission, lowering the gas density markedly.

    If instead of using nitrogen at 77 K hydrogen is used at 21 K, which is the temperature of liquid-vapor saturation at atmospheric pressure, the cooling intensity would be higher, and more argon would solidify.

    Moreover, if hydrogen is used as a cooling fluid, nitrogen can be used as a cooled gas below its triple point. This combination 10 can be used in the innermost crown, leaving the nitrogen-argon crown for the next outermost crown.

    For a third circular crown with its corresponding bundle of vessels and conduits, the cooling fluid can remain liquid nitrogen at 77 K, 15 and the gas to be cooled below its triple point is carbon dioxide, whose triple point is at 217 K.

    In this way, the fundamental mechanism that remains is that of conduction through the thermal bridge that is formed radially by the walls of the 20 vessels, whether they are circular in their straight section or vaulted.

    The thermal power transferred per unit of crown length, Q ’, through a solid cylindrical crown of conductivity material k, and with inner and outer radii re, is 25
    Q ’= 2πk (Te - Ti) / ln (re / ri)
    where ln (re / ri) is the geometric resistance factor corresponding to integrating the fraction (dr / r) between the inner and outer radius, dr being its differential. This is modified when, for each radius r there is no complete circumference of length 2πr, but a length 2nf (r) where f is the width of each leg of the vault and n is the number of vaults there are. For this case the geometric resistance factor becomes
    (dr / r) · (2πr / 2nf (r))
    If we consider that f (r) is constant with r, integration leads to
    Q ’= 2nfk (Te - Ti) / (π (re-ri))
    If for example re = 10 cm and ri = 5 cm, the original value of Q ’would be
    9k (Te - Ti) 5
    While if said crown were composed of 12 vaults of 0.1 cm thick legs (n = 12 and f = 0.1), the value of Q ’would be
    0.153k (Te - Ti)
    That is, 58 times lower.
     10
    Once the invention is clearly described, it is noted that the particular embodiments described above are subject to modifications in detail as long as they do not alter the fundamental principle and essence of the invention.
    权利要求:
    Claims (1)
    [1]
    1 - Thermally insulated and heat-drawn pipe, with interior at very low temperature, characterized in that it has cryogenic sources where a cooling fluid is cooled that cools another fluid, called cooled fluid, contained in airtight containers that constitute a cylindrical, or prismatic, or U-shaped geometry layer, in whose vessels the cooled fluid undergoes a thermodynamic transformation selected from
    - freezing of the cooled fluid, initially contained in one or more containers that form a geometric figure with continuity, said fluid having the property of freezing forming a continuous solid and with pieces that join together, as is the case with water, form ice; said freezing being produced by the action of the cooling fluid flowing through adjacent or internal pipes to the referenced containers, the cooling fluid being cooled 15 by at least one cryogenic source;
    - partial solidification within the containers because the fluid contained therein is cooled below its triple point, by the cooling action of another fluid, cooler, at the temperature of its triple point below that of the cooled fluid, being at in turn the cooling fluid 20 cooled by at least one cryogenic source.
    2 - Thermally insulated and heat drawn ducting, with interior at very low temperature, according to claim one, characterized in that the relative arrangement between the spaces occupied by the fluid that cools down below its triple point, and the cooling fluid , is selected from
    - a beam or plurality of cylindrical containers that are arranged in the form of a circular crown, adjacent each container with its two neighboring containers, those containers being the ones that hermetically contain the fluid that cools below its critical point, 30 and said paths being traveled containers, along, also cylindrical conduits through which the cooling fluid circulates, which goes from a cryogenic source to another located at a certain distance, or goes to the end of a section through some pipes and returns to the same cryogenic source by other conductions parallel to the outbound ones;
    - a beam or plurality of domed-shaped containers that are also arranged in the form of a circular crown, the circular crown being closed on the outside by a cylindrical surface that is tangent to the apex of the vaults, and the circular crown being closed by its inside by another cylindrical surface on which both stirrups of each vaulted container rest, the vaults being tightly closed at their ends, and originally filled with the fluid that cools below its critical point, and the cooling fluid circulating through the extrados of the vaults, from one cryogenic source to another, or round trip, through different extradós conduits, from a cryogenic source to itself.
    3 - Thermally insulated and heat drawn pipe, with a very low temperature inside, according to claim one or two, characterized in that said circular crowns can be stacked radially, using cooling gases and cooling fluids, of point temperatures triple respectively lower for each crown, the innermost it is.
     twenty
    4 - Thermally insulated and heat drawn pipe, with interior at very low temperature, according to claim one to third, characterized in that each circular crown is composed of two semi-crowns, one lower and one upper, which are independent in airtight containers and pipes.
     25
    5 - Thermally insulated and heat drawn ducting, with interior at very low temperature, according to claim one, characterized in that each freezing layer is constituted by a lower half in a U-shape and a top horizontal cover with a slab shape.
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4241233A|1978-07-26|1980-12-23|Electric Power Research Institute, Inc.|Method of forming dielectric material for electrical cable and resulting structure|
    US4315098A|1979-07-25|1982-02-09|Electric Power Research Institute, Inc.|Insulative spacer for a low temperature coaxial cable and coaxial cable including the same|
    EP1808868A1|2004-11-02|2007-07-18|Sumitomo Electric Industries, Ltd.|Superconducting cable|
    EP2615614A1|2010-09-07|2013-07-17|Chubu University Educational Foundation|Superconducting power transmission system|
    US20140221213A1|2011-12-06|2014-08-07|Sumitomo Electric Industries, Ltd.|Superconducting cable, superconducting cable line, method of installing superconducting cable, and method of operating superconducting cable line|
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