• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Furnace for heat treatment of filaments, comprising a furnace body (1) higher than wide with a first (1.1) and a second end (1.2), means for conducting (2) the filaments comprising first ( 2.1) and second rotary supports (2.2) between which the filaments are threaded, a platform (3) on which the conduit means (2) of the filaments are arranged and which is arranged swingably at the first end ( 1.1) of the furnace body (1), and joining means (4) connecting the platform (3) with the second end (1.2) of the furnace body (1) transferring the movements of the second end (1.2) of the body from furnace (1) to the platform (3), so as to ensure the parallelism between the filaments, preventing them from becoming deformed, or they may come into contact with each other. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2638003A1
    申请号:ES201630306
    申请日:2016-03-15
    公开日:2017-10-18
    发明作者:Manuel Torres Martinez
    申请人:Manuel Torres Martinez;
    IPC主号:
    专利说明:

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    DESCRIPTION
    OVEN FOR THERMAL TREATMENT OF FILAMENTS Technical sector
    The present invention is related to the processing and treatment of filaments for the manufacture of carbon fiber, proposing a furnace with improved structural features that ensures the parallelism between the filaments that travel through the interior of the furnace during its entire treatment process, avoiding that deformed, or can come into contact with each other. The furnace is configured for the manufacture of carbon fiber from filaments of a precursor such as polyacrylonitrile (PAN), although its application to this type of polymer is in no case limited, and the invention can be applied for the manufacture of filaments of other types of alternative precursors, such as lignin, polyolefins or others of similar characteristics.
    State of the art
    The process of manufacturing carbon fiber from a precursor such as polyacrylonitrile (PAN) essentially comprises a stabilization / oxidation stage, a carbonization stage and a surface treatment stage. Additionally, when it comes to obtaining a high performance fiber, a graffiti stage can be added before the surface treatments stage, whereby graphite fiber is obtained.
    During the stabilization / oxidation stage, the PAN precursor undergoes a first transformation to an oxidized state, known as OPAN or oxidized polyacrylonitrile, by means of a double reaction of cyclization and dehydrogenation. On the other hand, in the carbonization stage, a continuous structure in hexagonal carbon ring loops is achieved from OPAN. This stage is subdivided into two phases, one at a lower temperature, in which a pyridmic structure is formed, and another at a higher temperature, in which the structure collapses into a turbostratic structure.
    Both stabilization / oxidation and carbonization are carried out at elevated temperatures, which in the stabilization / oxidation process are below 300 ° C, and in the carbonization process can reach up to 1800 ° C, or more. These processes are
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    they develop in specific furnaces, such as the furnace for manufacturing carbon fiber described in the Spanish patent ES 2,528,068 B1 of the same applicant as the present invention.
    Said furnace comprises in its interior modules in which the filaments are treated for their transformation into carbon fiber, and means of conduction of the filaments formed by a set of rotating supports movable between them, between which the filaments are passed, which define a variable storage system in height of the filaments inside the oven. With this configuration of rollers, the filaments acquire a vertical arrangement inside the modules, maintaining an adequate parallelism between the successive round trips of the filaments.
    The vertical arrangement allows to increase the storage capacity of the filaments inside the oven, thereby reducing the surface area occupied by it, and therefore, the cost of the installation of carbon fiber manufacturing. In addition, the variable height storage allows to regulate the residence time of the filaments inside the different modules of the furnace according to the needs required by the precursor for the manufacture of carbon fiber.
    However, to maximize the storage capacity of the filaments and occupy the minimum surface, this type of furnaces has a structure that is much higher than its width, so that the higher the oven height, the more storage capacity is obtained . This structure can present stability problems, since mainly due to adverse weather conditions where the oven is arranged, such as the wind, and due to the height and weight of the oven itself, the upper part of the oven can oscillate. This oscillation causes a lateral displacement of the upper part of the oven that can affect the parallelism between the filaments, so that they can deform, or even come into contact with each other.
    Therefore, an alternative oven configuration is necessary to guarantee the parallelism of the filaments during their entire treatment process.
    Object of the invention
    According to the invention, a filament manufacturing furnace is proposed which is
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    configured to guarantee the parallelism of the filaments in their journey through the interior of the oven when unwanted movements of the upper part of the oven occur, preventing the filaments from deforming, or coming into contact with each other.
    The filament kiln comprises:
    - a furnace body that is considerably taller than it is wide, and that has a first end and a second end,
    - means for conducting the filaments comprising first and second rotating supports between which the filaments are threaded, where in first use position for the treatment of the filaments, the first rotating supports are arranged at the first end of the body of oven and the second rotating supports are arranged at the second end of the oven body, such that the filaments are in a vertical arrangement between the first and the second end of the oven body,
    - a platform on which the conduction means of the filaments are arranged, which is tiltedly arranged at the first end of the furnace body, and
    - joining means that join the platform with the second end of the furnace body, transferring the movements of the second end of the furnace body to the platform.
    With this oven configuration, it is guaranteed that any movement of the second end of the furnace body is transmitted identically to the platform of the first end of the furnace body, so that the filaments are always held tensioned in a vertical arrangement between the first and the second end of the furnace body, maintaining the parallelism between the filaments at all times, and preventing them from deforming, or coming into contact with each other.
    The joining means comprise at one of its ends a few first anchor points for fixing to the platform of the first end of the furnace body, and at the opposite end they comprise a second anchor points for fixing to the second end of the body of oven.
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    The anchor points are distributed in at least two rows parallel to each other, where the anchor points of each row are aligned with each other, and where the anchor points of the first row are interspersed with respect to the anchor points of the second row . This distribution in at least two rows, with the anchor points of each row interspersed with each other, allows to improve the transmission of efforts from the second end of the kiln body to the platform, thus ensuring that the platform faithfully reproduces the movements of the second end of the oven body. Thus, the conduction means carried by the filaments move as a single assembly, avoiding deformation of the filaments.
    According to a preferred embodiment, each first anchor point comprises a conical trunk body that is inserted in a reciprocal housing of the platform, while each second anchor point comprises an elastic body that is fixed to the second end of the furnace body and that is configured to allow a radial play and a tilting game with respect to the longitudinal axis of the joining means to which it is attached. In addition, the second end of the oven body comprises housings for the passage of the joining means, where the housings have a diameter greater than the diameter of the joining means that is passed through the housing. In this way, overvoltages are avoided in the fixing of the second anchor points, which could affect the structural integrity of the joining means, and can even cause them to fracture, since it is precisely this area of the furnace structure the one that supports more efforts when there is a movement of the second end of the kiln body.
    The platform of the first end of the furnace body comprises an arm that is connected to a base support by means of an articulation provided with a rotating shaft. The joint has a spherical shape that fits into one reciprocal hollows of the base support, so that the platform is capable of rotating and tilting with respect to the axis of rotation of the joint, being able to reproduce any movement that originates at the second end of the body of oven.
    The filament conduction means are arranged inside modules that divide the interior of the furnace into different stages of the filament treatment. The modules comprise a structure through which the joining means pass, where the modules are supported on the platform of the first end of the furnace body, and are attached to the second end of the furnace body through the joining means. From
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    in this way, the joining means also transmit the movements of the second end of the furnace body to the modules that incorporate the conduction means of the filaments, also ensuring that the modules are maintained at all times in a vertical arrangement between the first and the second end of the oven body.
    The modules are arranged on the platform in module columns, each of said module columns comprising a front access door that is operable by means of actuation means, which consist of cylinders that at their free end are connected to the Front access door and at its other end are fixed to the cross beam. These doors are designed to facilitate access to the interior of the modules and allow cleaning or maintenance work.
    The furnace additionally comprises sensing means that are configured for the measurement of the movements of the second end of the furnace body and displacement means that are configured to move the platform according to the movements measured by the sensor means. With this solution it is possible to partially release the joining means in the transmission of the movement to the platform, thereby increasing their useful life and improving the response speed of the entire assembly.
    In this way, an oven is produced to manufacture carbon fiber filaments, which, due to its constructive and functional characteristics, allows for adequate travel of the filaments through the interior of the oven, regardless of the movements that may originate in the structure of the oven, maintaining the filaments parallel to each other at all times, preventing them from deforming or coming into contact with each other.
    Description of the figures
    Figure 1 is a front view partially showing the interior of the oven of the invention.
    Figure 2A is a front view of the oven in use position, with the filaments tensioned in a vertical arrangement between the first and second ends of the oven body.
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    Figure 2B shows the second end of the oven body displaced laterally, but with the filaments equally tensioned in a vertical arrangement between the first and second ends of the oven body.
    Figure 3 shows a detail of the first end of the furnace body during threading of the filaments between the rotating supports.
    Figure 4 shows a detail of the first end of the furnace body when the second end of the furnace body is displaced laterally.
    Figure 5 shows a perspective view of the first end of the furnace body where the modules for the treatment of the filaments are partially observed.
    Figure 6 shows a perspective view of the second end of the furnace body where the second anchor points that fix the joining means to the transverse beam are observed.
    Figure 7 shows a perspective view of the first end of the furnace body where the first anchor points that fix the attachment means to the platform are observed.
    Figure 8 shows an enlarged longitudinal sectional view of the detail indicated with reference VIII in Figure 6.
    Figure 9 shows an enlarged longitudinal sectional view of the detail indicated with reference IX in Figure 7.
    Figure 10A shows a front view of the platform.
    Figure 10B shows a side view of the platform.
    Figures 11 and 12 show front views representing the opening of the module doors.
    Detailed description of the invention
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    The invention relates to a furnace for the manufacture of filaments, which is particularly configured for application in the manufacture of carbon fiber filaments from the treatment of polyacrylonitrile (PAN) filaments, without being this limiting application.
    The furnace comprises a furnace body (1) of rectangular longitudinal section having a height considerably greater than its width, similar to a wind turbine tower, as shown in the partial sectional view of Figure 1. Also the section The cross section of the furnace body (1) is provided in a circular manner, although this configuration is not limited, and can be of oval or polygonal cross-section.
    The oven body (1) has an elongated shape with a first end (1.1) and a second end (1.2) opposite the first end (1.1). As shown in the figures, the first end (1.1) corresponds to the bottom of the oven, and the second end (1.2) to the top of the oven, although the second end (1.2) of the oven body (1 ) could be any intermediate point located between the lower part and the upper part of the oven body (1).
    At the first end (1.1) of the furnace body (1) there is an inlet (1.3) of the untreated filaments, and on the opposite side of the first end (1.1) there is an outlet (1.4) of the filaments already treated after they have circulated inside the furnace in successive round trips, and after being subjected to stabilization, oxidation, and carbonization stages for their transformation into carbon fiber. At the second end (1.2) of the upper part of the furnace body (1) there is an outlet of the circulated gases (1.5) used in the filament treatment stages.
    Inside the furnace body (1) there is a filament storage system comprising conduction means (2) through which the filaments are passed to conduct them through the interior of the furnace in successive round trips and turn between the inlet (1.3) and the outlet (1.4) of the oven body (1).
    The driving means (2) comprise first rotating supports (2.1) formed by rollers in vertical arrangement and second rotating supports (2.2) also formed by other rollers in vertical arrangement. The first rotating supports (2.1) are connected to the first end (1.1) of the furnace body (1), while the second rotating supports (2.2) are connected to the second end (1.2) of the body of
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    oven (1).
    The rotating supports (2.1,2.2) are movable in each other in the vertical direction, so that at least one of the rotating supports (2.1, 2.2) is movable vertically with respect to the other rotating support (2.1, 2.2). As can be seen in the examples of figures 2A, 2B and 4, the second rotating supports (2.2) are movable vertically with respect to the first rotating supports (2.1), between the first (1.1) and the second end (1.2) of the oven body (1), while the first rotating supports (2.1) are fixedly arranged at the first end (1.1) of the oven body (1).
    The second rotating supports (2.2) can vary in height between them, so that the variable displacement in the vertical direction the rotating supports (2.2) allows for any speed of supply of the filaments, the treatment time in each of the Stages inside the oven remain constant, a feature that offers benefits in the processes of starting and stopping, avoiding the loss of large amounts of material due to incomplete treatment of the filaments.
    With this arrangement, to proceed to the threading of the filaments between the conduction means (2), first the second rotating supports (2.2) are moved towards the first end (1.1) of the furnace body (1) to be inserted between the first rotating supports (2.1), then the filaments are introduced through the entrance (1.3) by passing them between the rotating supports (2.1, 2.2) and extracting them through the exit (1.4), as shown in Figure 3. A Once the filaments are threaded between the rotating supports (2.1, 2.2), the second rotating supports (2.2) move towards the second end (1.2) of the furnace body (1), so that the filaments are tensioned between the supports swivels (2.1,2.2) in a vertical arrangement between the first end (1.1) and the second end (1.2) of the furnace body (1), as shown in Figure 2A, maintaining a proper parallelism between the filaments in succession tours back and forth inside the oven.
    As shown in Figure 2B, the furnace body (1) can oscillate, mainly by the action of the force of the wind to which the furnace can be subjected in its place of location, this oscillation being aggravated by the weight of the oven body (1) and because of its elongated shape with a height considerably greater than its width. Thus, the second end (1.2) of the furnace body (1) can move laterally at any
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    direction, which negatively affects the vertical arrangement of the filaments that are arranged between the rotating supports (2.1,2.2) of the conduction means (2), which can deform or come into contact with each other depending on the degree of oscillation of the oven body (1).
    To ensure that the filaments are maintained in a vertical arrangement between the first end (1.1) and the second end (1.2) of the furnace body (1) and with an adequate parallel between them, the furnace of the invention additionally comprises a platform ( 3) and means of union (4). The platform (3) is arranged tiltingly at the first end (1.1) of the furnace body (1), and on it the conduction means (2) of the filaments are arranged, while the joining means (4) they join the platform (3) with the second end (1.2) of the furnace body (1), transferring the movements of the second end (1.2) of the furnace body (1) to the platform (3).
    In this way, the oscillation of the second end (1.2) of the furnace body (1) is transmitted to the platform (3) that supports the conduction means (2) of the filaments, through the joining means (4) , thus ensuring at all times that the filaments are maintained in a vertical arrangement between the first end (1.1) and the second end
    (1.2) of the furnace body (1), with an adequate parallelism between them, preventing them from deforming or coming into contact with each other, as shown in Figure 2B, that is, the round trips of the filaments are kept perpendicular to the horizontal planes defined by the first (1.1) and the second end
    (1.2) of the oven body (1).
    It is envisaged that the joining means (4) are mechanical cables, which are not completely rigid, but have a certain degree of flexibility to be able to absorb the stresses to which the furnace body is subjected ( 1) during the oscillation, such as cables with interwoven steel cables.
    The furnace body (1) comprises in its interior some modules (5) in which the stabilization, oxidation, and carbonization steps for the treatment of the filaments and their transformation into carbon fiber are carried out. The modules (5) comprise inside the conduction means (2) of the filaments, and have hot gas inlets (not shown in the figures) to create the necessary conditions for the treatment of the filaments at each stage . Figure 5 shows a view in
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    perspective of the interior of the oven, where for reasons of clarity the modules (5) are only partially represented and without the conduction means (2). As seen in said figure 5, on the left side of the platform there is a first set of modules (5) where the stages of stabilization and oxidation of the filaments are carried out, and on the right side of the platform It has a second set of modules (5), independent of the first set, where the stage of carbonization of the filaments is carried out.
    The modules (5) comprise a structure that incorporates refractory material to reduce energy losses by thermal escape between the modules (5) and the outside, and between the modules themselves (5). The structure of the modules is used to pass through it the joining means (4), so that the transmission of the forces of the second end (1.2) of the furnace body (1), are transmitted to the modules ( 5) through the means of union (4).
    The modules (5) comprising the conduction means (2) are arranged between the first
    (1.1) and the second end (1.2) of the oven body (1). The modules (5) are supported on the platform (3) of the first end (1.1) of the furnace body (1), while in relation to the second end (1.2) of the furnace body (1), the union of the modules (5) to the second end of the furnace body (1) is carried out by means of the joining means (4), as can be seen in detail in Figures 11 and 12. In this way, both the modules (5) and the conduction means (2) and the filaments form an assembly that is arranged on the tilting platform (3) and connected to the second end (1.2) of the furnace body (1) by means of the joining means (4).
    It is envisaged that the modules (5) through which the joining means (4) are guided are small blocks, preferably less than 1 meter high. The modules (5) are arranged parallel to each other and stacked on each other, favoring their arrangement and alignment for the introduction of the joining means (4). Among the blocks that make up the modules (5) there is an elastically deformable material that makes it possible to compensate for the differences in thermal expansion between the material with which the joining means (4) and the material that form the modules (5) are made. .
    The second end (1.2) of the furnace body (1) comprises a transverse beam (6)
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    preferably of section in "H" which is jointly joined by both ends to the furnace body (1), so that the stresses to which the furnace body (1) is subjected are transmitted directly to the transverse beam (6) .
    The joining means (4) have at one of their ends first anchor points (7) for fixing to the platform (3) of the first end (1.1) of the furnace body (1), and at the opposite ends the joining means (4) have second anchor points (8) for fixing to the transverse beam (6) of the second end (1.2) of the furnace body (1). The anchor points (7, 8) have a particular distribution that improves the transmission of movements from the cross beam (6) to the platform (3).
    As can be seen in detail in Figure 7, the first anchor points (7) are distributed in at least two rows (f1, f2) that extend in the longitudinal direction (x) of the platform (3), the direction being longitudinal (x) parallel to the major sides of the platform (3). It is envisioned that the anchor points (7) of each row (f1, f2) are aligned with each other in the longitudinal direction (x), and the two rows (f1, f2) of anchor points (7) are parallel between yes. This distribution of anchor points (7) favors the transmission of stresses to the platform (3), both in the longitudinal direction (x) and in the transverse direction (y), which is parallel to the smaller sides of the platform ( 3) and perpendicular to the longitudinal direction (x).
    It is evident that this distribution of at least two rows (f1, f2) presents a better transmission of the forces than in the case of using a single row of anchor points aligned in the longitudinal direction (x), where the transmission of movements only it would be effective in the longitudinal direction (x), and it would not be as effective in the transverse direction (y). However, since the transverse beam (6) can oscillate in any direction, the platform (3) must also swing in any direction in order to reproduce the movements of the transverse beam (6), therefore, it is provided that in addition to the distribution of at least two rows (f1, f2), the first anchor points (7) have a three-way distribution, where the anchor points (7) of the first row (f1) are interspersed with respect to the points of anchor (7) of the second row (f2). This interleaved distribution between the anchor points (7) of each row (f1, f2) improves the transmission of stresses in all directions, while minimizing the number of necessary anchor points.
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    The distribution of the second anchor points (8) on the transverse beam (6) of the second end (1.2) of the furnace body (1) is identical to the distribution of the first anchor points (7) described above. In figure 6 only the first row (f1) of anchor points (8) is shown, which are arranged on a wing of the cross beam (6), while the anchor points of the second row (f2) are they have on the other wing of the transverse beam (6) that is hidden in figure 6.
    Figures 6 and 7 show that the distribution in at least two rows (f1, f2) only applies to the first set of modules (5) of the stabilization or oxidation stage, although it could also be applied to the second set of modules (5) of the carbonization stage.
    A longitudinal sectional view of one of the second anchor points (8) fixed in the transverse beam (6) of the second end (1.2) of the furnace body (1) is shown in Figure 8. The second anchor points (8) have an elastic body as a label that allows the joining means (4) in its connection zone with the second end (1.2) of the furnace body (1) to have a slight radial play and a slight tilting with respect to the longitudinal axis (z) of the joining means (4), so as to avoid overvoltages that may affect the structural integrity of the joining means (4), and which may cause it to fracture.
    Figure 8 also shows that the transverse beam (6) of the second end (1.2) of the furnace body (1) has housings (6.1) for the passage of the joining means (4). The housings (6.1) have a diameter greater than the diameter of the joining means (4) that is passed through it, in this way the joining means (4) is allowed to have a slight radial play in the housing ( 6.1), and also avoid overvoltages that may affect the structural integrity of the joining means (4).
    A longitudinal sectional view of one of the first anchor points (7) fixed on the platform (3) of the second end (1.2) of the furnace body (1) is shown in Figure 9. The anchor point (7) comprises a truncated conical body that is inserted in a reciprocal housing of the platform (3).
    Thus, for the installation of the joining means (4) they are first introduced through the platform housings (3) and subsequently introduced into the
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    housings (6.1) of the transverse beam (6) of the second end (1.2) of the furnace body (1), after which the second anchor points (8) are tightened to tension the joining means (4), thus remaining these axially held in tension between the platform (3) and the second end (1.2) of the furnace body (1).
    An example of embodiment of the platform (3) of the first end (1.1) of the furnace body (1) is shown in Figures 10A and 10B, which is supported by a single pivot point centered with respect to the platform (3). In any case, this embodiment is not limiting, and the platform (3) can be supported with other means that allow its tilting in any direction, such as four pneumatic cylinders arranged at its ends, or other similar arrangement.
    The platform (3) comprises a triangular-shaped arm (3.1) which in its lower vertex is connected, by means of an articulation (3.3), to a base support (3.2) provided with two lugs arranged on the floor of the oven. The articulation (3.3) has an axis of rotation (w) that allows the tilting of the platform (3) with respect to the base support (3.2), and has a spherical shape that fits into reciprocal holes of the base support (3.2), of so that the articulation (3.3) allows the platform (3) to pivot with respect to the base support
    (3.3). Specifically, as shown in Figure 10B, the platform (3) can rotate and tilt with respect to the axis of rotation (w) of the joint (3.3).
    The modules (5) are arranged in modules columns (5), a module (5) being arranged on top of another, where each of said modules columns (5) comprises a front access door (9) that allows access to the inside of the modules (5) to carry out cleaning tasks thereof, or maintenance work. Each of said doors (9) is operable in opening by means of actuation (10), which according to the example shown in Figures 11 and 12 consist of cylinders that at their free end are connected to the front access door (9) and at its other end they are fixed to the transverse beam (6). In this way, to carry out the opening of a module (5), the cylinder of the drive means (10) is compressed and causes the door of the module (5) to be opened to be superimposed on the door (9 ) of the module (5) located immediately next to it, as illustrated in figure 12. For reasons of clarity in figures 11 and 12 only two of the doors (9) of the modules (5) are shown.
    Figures 11 and 12 show pulleys (11) that are directly attached to a wing
    of the transverse beam (6) of the second end (1.2) of the furnace body (1). These pulleys (11) are responsible for driving in vertical displacement to the second rotating supports
    (2.2) to tension the filaments that are threaded between the rotating supports (2.1, 2.2). The pulleys (11) are arranged fixed to the cross beam (6) as well as the joining means
    5 (4), however, they do not participate in any case in the transmission of movements to the
    platform (3). The pulleys (11) could be fixed to the top of the modules (5), although it is planned to fix them to the transverse beam (6) since they are motorized pulleys, and the heat of the modules (5) can affect its operation
    10 Additionally, it is provided that at the second end (1.2) of the furnace body (1) sensor means are provided for measuring the movements of the second end
    (1.2) of the furnace body (1), and displacement means that move the platform (3) as a function of the movements measured by the sensor means. The sensor means can be any type of medium that allows to detect the movements of the second
    15 end (1.2) of the furnace body (1), such as accelerometers arranged in the transverse beam (6), or meters of the distance between the furnace body (1) and the modules (5). The displacement means can be formed by a motor that acts directly on the articulation (3.3) of the platform (3). In this way, you can act on the platform (3) immediately as soon as a movement of the
    20 second end (1.2) of the furnace body (1), whereby the joining means (4) and mainly the second anchor points (8) have to withstand less effort in the transmission of the movements to the platform (3).
    权利要求:
    Claims (13)
    [1]
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    1Horno for the thermal treatment of filaments, comprising:
    - an oven body (1) that is taller than it is wide and has a first end
    (1.1) and a second end (1.2), and
    - conduction means (2) of the filaments comprising first rotating supports (2.1) and second rotating supports (2.2) between which the filaments are threaded, and where in use position the first rotating supports
    (2.1) are arranged at the first end (1.1) of the furnace body (1) and the second rotating supports (2.1) are arranged at the second end (1.1) of the furnace body (1), such that the filaments remain in a vertical arrangement between the first end (1.1) and the second end (1.2) of the oven body (1), characterized in that the oven additionally comprises:
    - a platform (3) on which the conduction means (2) of the filaments are arranged and which is tiltedly arranged at the first end (1.1) of the furnace body (1), and
    - joining means (4) connecting the platform (3) with the second end (1.2) of the furnace body (1) transferring the movements of the second end (1.2) of the furnace body (1) to the platform (3 ).
    [2]
    2. - Furnace for the thermal treatment of filaments, according to claim 1, characterized in that the joining means (4) comprise at one end first anchor points (7) for fixing to the platform (3) of the first end (1.1) of the oven body (1), and at the opposite end a few second anchor points (7) for fixing to the second end (1.2) of the oven body (1).
    [3]
    3. - Furnace for the thermal treatment of filaments, according to the previous claim, characterized in that the anchor points (7, 8) are distributed in at least two rows (f1, f2) parallel to each other, where the anchor points ( 7, 8) of each row are aligned with each other, and where the anchor points (7, 8) of the first row (f1) are interspersed with respect to the anchor points (7, 8) of the second row (f2) .
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    [4]
    4. - Furnace for the thermal treatment of filaments, according to any one of the
    previous claims, characterized in that the joining means (4) consist of mechanical cables that have a certain degree of flexibility.
    [5]
    5. - Furnace for the thermal treatment of filaments, according to any one of the
    claims 2 to 4, characterized in that each first anchor point (7) comprises a conical trunk body that is inserted into a reciprocal housing of the platform (3).
    [6]
    6. - Furnace for the thermal treatment of filaments, according to any one of the
    claims 2 to 5, characterized in that each second anchor point (8) comprises an elastic body that is fixed to the second end (1.2) of the furnace body (1) and that is configured to allow a radial play and a tilting set with respect to the longitudinal axis (z) of the joining means (4) to which it is attached.
    [7]
    7. - Furnace for the thermal treatment of filaments, according to any one of the
    previous claims, characterized in that the second end (1.2) of the furnace body (1) comprises housings (6.1) for the passage of the joining means (4), where the housings (6.1) have a diameter larger than the diameter of the joining means (4) that is passed through housing (6.1).
    [8]
    8. - Furnace for the thermal treatment of filaments, according to any one of the
    previous claims, characterized in that the second end (1.2) of the furnace body (1) comprises a transverse beam (6) preferably of section in "H"
    jointly joined by its ends to the furnace body (1), the joining means (4) being fixed by one of its ends to said transverse beam (6).
    [9]
    9. - Furnace for the thermal treatment of filaments, according to any one of the
    previous claims, characterized in that the platform (3) comprises an arm
    (3.1) which is connected to a base support (3.2) by means of an articulation (3.3) provided with a turning axis (w), where the articulation (3.3) has a spherical shape that fits into reciprocal holes of the base support (3.2) , such that the platform (3) rotates and tilts with respect to the axis of rotation (w) of the joint (3.3).
    [10]
    10. - Furnace for the thermal treatment of filaments, according to any one of the preceding claims, characterized in that the conduction means (2) of the
    filaments are arranged inside modules (5) comprising a structure through which the joining means (4) pass, where the modules (5) are supported on the platform (3) of the first end (1.1) of the furnace body (1), and are connected to the second end (1.2) of the furnace body (1) through the joining means (4).
    5
    11 Environment for the thermal treatment of filaments, according to the preceding claim, characterized in that the modules (5) are arranged in modules columns (5), each of said modules columns (5) comprising a front access door (9) ) which is operable by means of drive (10).
    10
    [12]
    12. - Furnace for the thermal treatment of filaments, according to the previous claim, characterized in that the actuation means (10) consist of cylinders that at their free end are connected to the front access door (9) and at the other end are fixed to the cross beam (6).
    fifteen
    [13]
    13. - Furnace for the thermal treatment of filaments, according to any one of the preceding claims, characterized in that the furnace additionally comprises sensor means configured for measuring the movements of the second end.
    (1.2) of the furnace body (1) and travel means configured to move the
    20 platform (3) depending on the movements measured by the sensor means.
    [14]
    14. - Furnace for the thermal treatment of filaments, according to any one of claims 10 to 13, characterized in that the modules (5) are blocks that are arranged parallel to each other and stacked on each other, and that between the modules
    25 (5) an elastically deformable material is arranged.
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    同族专利:
    公开号 | 公开日
    US20190078234A1|2019-03-14|
    US10895021B2|2021-01-19|
    JP6855500B2|2021-04-07|
    WO2017158214A1|2017-09-21|
    DE112017001343T5|2018-11-22|
    JP2019512613A|2019-05-16|
    ES2638003B1|2018-05-08|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4188731A|1976-08-25|1980-02-19|Rauskolb Fred W|Method and apparatus for eliminating wet streaks in fibrous sheets or webs by infra-red radiation|
    US4559010A|1984-05-01|1985-12-17|Toray Industries, Inc.|Apparatus for producing oxidized filaments|
    WO2014091642A1|2012-12-12|2014-06-19|Jfeスチール株式会社|Device for preventing steel plate meandering in vertical looper and method for preventing meandering of steel plate|
    CN104968622B|2012-12-28|2018-08-14|普睿司曼股份公司|Method of the manufacture for the prefabricated component of the optical fiber with low water peak|
    ES2528068B1|2014-07-22|2015-08-13|Manuel Torres Martínez|Furnace for continuous carbon fiber manufacturing and installation for manufacturing carbon fiber with said furnace|
    WO2016128209A1|2015-02-09|2016-08-18|Clariant International Ltd|Modular furnace, in particular for the oxidative stabilization of a carbon fiber starting material|
    ES2547755B1|2015-06-25|2016-06-16|Manuel Torres Martínez|Extrusion head for filament generation, installation and extrusion procedure using said extrusion head|
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    ES201630306A|ES2638003B1|2016-03-15|2016-03-15|OVEN FOR THERMAL TREATMENT OF FILAMENTS|ES201630306A| ES2638003B1|2016-03-15|2016-03-15|OVEN FOR THERMAL TREATMENT OF FILAMENTS|
    PCT/ES2017/070048| WO2017158214A1|2016-03-15|2017-01-27|Oven for the thermal treatment of filaments|
    JP2018548353A| JP6855500B2|2016-03-15|2017-01-27|Oven for heat treatment of filaments|
    DE112017001343.7T| DE112017001343T5|2016-03-15|2017-01-27|OVEN FOR THE THERMAL TREATMENT OF FILAMENTS|
    US16/084,409| US10895021B2|2016-03-15|2017-01-27|Oven for the thermal treatment of filaments|
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