• 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:
    The present invention relates to a method and a system (10) for depositing materials in a substrate (12). The method is particular in that an energy beam (16) is directed to a first material to form a downward melt pool (26) and a particle stream is directed to the pool (20). ) a second material that can migrate upwards in the melt of the first material. Such a method can be used in the manufacture of gas turbine blades, for example.
    公开号:CH704293B9
    申请号:CH02054/11
    申请日:2011-12-28
    公开日:2017-04-28
    发明作者:Yee Shuck Quinlan
    申请人:Rolls-Royce Corp;
    IPC主号:
    专利说明:

    Description Cross-references with parent applications [0001] The present application claims the priority of US Provisional Patent Application No. 61 427729, filed December 28, 2010, entitled "System and method for deposition of materials in a substrate" , incorporated herein by reference.
    Field of the Invention [0002] The present invention relates to the deposition of material and more particularly the deposition of material in a substrate. State of the art [0003] Methods and systems for the efficient deposition of a material, such as particles, in a substrate, remain an area of interest. Some systems have a number of shortcomings, disadvantages and disadvantages with respect to certain applications. In accordance, there remains a need for new contributions in this area of technology. SUMMARY [0004] The invention relates to a unique method of depositing materials in a substrate. Another aspect of the invention relates to a single system for depositing materials in a substrate. Special forms of performance will flow from the claims, description and figures provided in this document.
    Brief description of the drawings [0005] The description in this document refers to the accompanying drawings in which like reference numerals refer to like parts in the different views, and: FIG. 1 schematically illustrates certain aspects of a non-limiting example of a system for adding particles to a substrate to form a matrix material in accordance with an embodiment of the present invention; fig. 2 schematically illustrates certain aspects of a non-limiting example of particles deposited in a substrate, forming a matrix material, according to an embodiment of the present invention.
    Detailed Description [0006] In order to promote an understanding of the principles of the invention, reference will be made to the embodiments illustrated in the drawings and a specific language will be used to describe them. It will be admitted, however, that no limitation of the scope of the invention is contemplated by the illustration and description of certain embodiments of the invention. In addition, any changes and / or modifications of the illustrated embodiment (s) and / or described are considered within the scope of the present invention while remaining within the scope of the present invention. claims. In addition, any other applications of the principles of the invention, as illustrated and / or described herein, as coming to the mind of those skilled in the art to which the invention is applicable, are conceivable.
    Referring to the drawings and in particular to FIG. 1, certain aspects of a non-limiting example of a system 10 for adding particles to a substrate 12 to form a matrix material in accordance with an embodiment of the present invention are shown schematically. For example, in the case of a metal substrate 12 and particles in the form of oxides or other composite material, the system 10 forms a matrix material in the form of a metal matrix composite. In other embodiments, other matrix materials may be formed by a system 10, including metal / metal matrix materials and metal / metal / composite matrix materials, for example one of the metals being the substrate. and the other of the metals and the composite being formed of particles added to the substrate 12. In one embodiment, the system 10 is configured to achieve a desired level of porosity on the surface of the substrate 12.
    In one embodiment, the substrate 12 is an abradable stator for a gas turbine blade. In other embodiments, the substrate 12 may be any component, including, for example, a gas turbine blade; a dawn or a series of blades; an abrasive stator for a compressor blade, a fan or a turbine; another flow path component of a gas turbine or any other gas turbine component; or another mechanical component for any machine, device, system or structure. In one embodiment, the substrate 12 is a metal component. In other embodiments, the substrate 12 may be formed from one or more metallic and / or non-metallic materials.
    The system 10 comprises an energy emitter means 14 for directing an energy beam 16 on a substrate 12. The system 10 also includes a particle spraying means 18 for directing one or more particle streams 20 onto a substrate 12 for example, at and near the impact site 22 of the energy beam 16 on the substrate 12. In one embodiment, the particles 20 are not of the same material as the substrate 12. In other forms of All or some of the particles may be of the same material as the substrate 12. In one embodiment, the emitter means 14 and the spraying means 18 are housed in a single unit in the form of a nozzle. 24 which emits both an energy beam 16 and a particle stream 20. In other embodiments, the emitter means 14 and the spraying means 18 may other shapes, including separate emitting devices, and may also include a plurality of transmission devices for transmitting the energy beam 16 and / or the flow of particles 20.
    In one embodiment, the transmitter means 14 is configured and operated to form and direct a direct energy beam 16 in the form of a laser beam. In other embodiments, the transmitter means 14 may be configured to form other types of energy beams, including for example, but not limited to, one or more electron beams and / or one or more electric arcs. The transmitter means 14 is configured and positioned to direct the energy beam 16 from below a substrate portion 12 upward to your substrate portion 12. The energy beam 16 is configured to form a mass puddle. melted 26 in the substrate portion 12 of the underside of the substrate 12. The energy beam 16 forms a melt puddle 26 by melting the substrate 12 locally, the melt puddle 26 being rotated in a vertically downward direction that is, it is upside down.
    The spraying means 18 is configured and operated to direct the flow of particles 20 from below the substrate portion 12 upwardly to the portion such that at least some of the particles In one embodiment, some of the particles have a property different from that of the other particles. For example, in one embodiment, the particles are an aggregation of different types of particles, some particles may have a lower density than others and / or some particles may exhibit higher buoyancy in a pool of melt. 26 compared to other particles. The particles having a different property are configured to rise in the melt puddle 26 to the substrate 12 (unmelted portions of the substrate 12). The particles 20 may be formed of the same or different material and may be of the same or different size and shape, depending on the needs of the particular embodiment. In one embodiment, the particles are composite particles, for example a ceramic composite. In other embodiments, the particles may be formed of metal particles in addition to or instead of non-metallic particles. Some particles may be hollow, for example spheres or other hollow metal and / or nonmetallic forms, while other particles may be solid, depending on the particular embodiment. In yet other embodiments, the particles may include reactive pore-forming agents, in addition to or instead of other types of particles. In still other embodiments, all of the particles may be the same or substantially the same, for example in composition, size and shape, and they may all be configured to rise in the melt pool 26 to the substrate 12 (unmelted portions of substrate 12).
    The system 10 is configured to allow the particles, having the desired property, to rise in the melt puddle 26 up to the proximity of the unmelted portions of the substrate 12. The system 10 provides sufficient of energy to maintain the charged melt puddle 20 for a period of time sufficient to allow the particles having a different property to rise upward in the melt puddle 26. By forming the mass puddle in a downward direction, the particles having the different property can rise upward towards the substrate 12, for example by forming a desired degree of porosity in the substrate 12 next to unmelted portions of the substrate 12 This is contrary to other systems which form a melt puddle on an upper or lateral surface of the substrate, in which the desired particles es can not migrate to non-fused portions of the substrates.
    In a special embodiment, the system 10 also includes a first positioning system 28 and a second positioning system 30. In one embodiment, the system 10 also includes an enclosure 32 for enclosing the substrate 12 , the emitter means 14, the spraying means 18, the first positioning system 28 and the second positioning system 30. The first positioning system 28 is coupled to the combined emission nozzle 24 and used to move and / or turn the combined emission nozzle 24 for forming the melt puddle 26 using the energy beam 16. In one embodiment, the first positioning system 28 is also configured to progressively or intermittently move the melt puddle 26 to other parts of the substrate 12, for example parts adjacent to the initial or consecutive locations of the puddle melt 26 which are also arranged in a direction turned vertically downwards. In embodiments, wherein the energy emitter means 14 and the particle spraying means 18 are not combined in a single head or in which emitter means 14 and multiple spraying means 18 are used, systems Additional positioning devices may be coupled to each of the emitter means 14 and spray means 18. In one embodiment, the first positioning system 28 is a multi-axis positioning system. In other embodiments, the first positioning system 28 may be a single axis positioning system.
    The second positioning system 30 is coupled to and supports the substrate 12 and is used to move and / or rotate the substrate 12 to form the melt puddle 26 at desired sites on the substrate 12. Using the energy beam 16. In one embodiment, the second positioning system 30 is also configured to gradually or intermittently subject second portions and consecutive portions of the substrate 12 to the energy beam 16 and the particle stream 20, for example adjacent portions to the initial or consecutive locations of the melt puddle 26 which are also disposed in a vertically downwardly directed direction. In one embodiment, the second positioning system 30 is configured to rotate the substrate 12 in such a manner that the desired melt puddle 26 is facing downwards. In one embodiment, the second positioning system 30 is a multi-axis positioning system. In other embodiments, the second positioning system 30 may be a single-axis positioning system.
    In various embodiments, a first or second positioning system 28, 30 or both may be used to position the substrate 12 at the desired site to form the melt puddle 26 in a downwardly facing direction. Other embodiments can not use a positioning system to position the substrate 12, for example depending on the geometry of the substrate 12. For example, if the substrate 12 has a relatively flat surface that can be fixed in place, the positioning system 30 may be replaced by a simple support system to hold the substrate 12 in the desired orientation. Still other embodiments can not use a positioning system (s) to position the transmitter means 14 and / or the spraying means 18, but may instead use a simple support system to support the transmitter means 14 and / or the spraying means 18, based on the positioning system 30 for orienting the substrate 12 in the desired position.
    The enclosure 32 is configured to allow the control of the atmosphere inside the system 10 during the formation of the melt puddle 26 and the spraying of the particles 20. In one embodiment, the atmosphere maintained in the chamber 32 is the ambient air. In other embodiments, an inert gas or vacuum may be contained in enclosure 32.
    During the operation of the system 10, a desired portion of the substrate 12 is disposed in a direction turned vertically downward, for example by the positioning system 30. The energy beam 16 is directed from below the part of the substrate 12 where the melt puddle 26 is desired and is directed upwards towards the part. In one embodiment, the energy beam 16 is directed on the portion of the substrate 12 at an angle ο less than 45 degrees with respect to a vertical line 34. In a particular form, the energy beam 16 is directed on the portion of the substrate 12 at an angle θ less than about 15 degrees from a vertical line 34. In other embodiments, upper or lower angles may be used. The melt puddle 26 is then formed by the energy beam 16, turned vertically downward from the substrate portion 12. When the melt puddle 26 is formed, a particle stream 20 is directed from below the portion on the substrate 12 upwards to the portion in which the melt puddle 26 is formed. At least some of the particles are configured to rise in the melt puddle 26 to the substrate 12. The melt puddle 26 is maintained in the liquid state, for example by the energy beam 16, while the particles raise in the melt puddle to the substrate.
    Referring to FIG. 2, in embodiments in which the particles are not homogeneous, the particles 20A having the property of a higher buoyancy in the melt puddle and / or a density lower than that of the other particles 20B are the particles which rise in the melt puddle 26 to the substrate 12. In the embodiments in which the particles are homogeneous, for example having a density and / or buoyancy at the desired levels to promote flotation up the puddle In the upside-down melt, similar results near the substrate 12 at the top of the upside-down melt puddle would be obtained. Various embodiments may include moving and / or rotating the substrate 12 to provide another portion of the substrate 12 in a vertically downward direction to form a new melt pool 26 or to move the melt pool 26 to a new location on the substrate 12. This can be achieved by keeping the melt puddle 26 in the vertically downward direction, the melt puddle 26 being progressively moved into the next portion or another portion of the substrate. Similarly, the emitter means 14 and the spraying means 18 may be repositioned continuously or intermittently in order to move the melt puddle 26 of a portion of the substrate 12 to another portion of the substrate 12.
    When the desired quantity of particles 20 has been dispersed in the melt puddle 26 and the desired particles have risen in the melt puddle towards the substrate 12, the melt puddle 26 is solidified, for example into Such a coating may for example be a metal matrix composite coating having a desired level of porosity next to the unmelted portions of the substrate 12. The amount of porosity is based on the selection of the particles. In one embodiment, the amount of porosity is configured for abradability of the substrate 12, for example in a gas turbine blade stator component. In other embodiments, the amount of porosity is configured to retain lubrication, for example forming a self-lubricating material on the substrate 12. In still other embodiments, the amount of porosity is configured to achieve thermal conductivity desired, for example in a component of a turbine section of a gas turbine. In yet other embodiments, the amount of porosity can be configured to obtain other desired properties.
    Embodiments of the present invention include a method of depositing materials in a substrate, comprising disposing a first portion of a substrate in a vertically downwardly directed direction; the direction of an energy beam from below the first part upwards to the first part; forming a melt puddle in the substrate using the directed energy beam, the melt puddle being formed facing in a vertically downward direction in the first portion; and directing a flow of particles from below the first portion upward to the first portion, at least some of the particles being configured to rise in the melt puddle to the substrate.
    In an improvement, at least some of the particles have a property different from that of other particles; and the particles having the different property are said at least some particles that rise in the melt puddle towards the substrate.
    In another improvement, the property is a density lower than that of other particles.
    In yet another improvement, the property is a higher buoyancy in the pool of melt than that of other particles.
    In a special embodiment, the substrate is metallic and the particles in the melt puddle together with the melt substrate form a metal matrix composite.
    In yet another improvement, the particles include non-metallic particles. In yet another improvement, all the particles are non-metallic particles.
    In yet another improvement, the particles include hollow particles.
    In yet another improvement, the particles include reactive pore forming agents.
    In yet another improvement, the method further comprises the displacement and / or the rotation of the substrate to have a second portion of the substrate in a direction turned vertically downward while maintaining the melt puddle in the direction turned vertically downwards, the melt puddle being progressively displaced in the second part of the substrate.
    In another improvement, the energy beam is a laser.
    In yet another improvement, the method further comprises solidifying the melt puddle to form a coating on the substrate.
    In yet another improvement, the energy beam is directed at the first portion at an angle of less than approximately 15 degrees from the vertical.
    In yet another improvement, the substrate is formed of a material and the melt puddle being formed of the substrate material.
    Embodiments of the present invention include a system, comprising: an energy beam emitter positioned to direct the energy beam from below a first portion of a substrate upwardly to the first partly, the energy beam being configured to form a melt puddle in a vertically downward direction in the first portion; and a particle sprayer operated to direct a flow of particles from beneath the melt puddle upward to the melt puddle, the system being configured to allow at least some of the particles of raise in the pool of melt to the substrate.
    In an improvement, the system further comprises a positioning system coupled to the substrate and operated to move and / or rotate the substrate to have a second portion of the substrate in a direction turned vertically downward while maintaining the pool of melt in the direction turned vertically downward.
    In another improvement, the positioning system is configured for a progressive displacement of the melt puddle of the first part in the second part of the substrate.
    In yet another improvement, the system further comprises a positioning system coupled to the energy beam transmitter and operated to move and / or rotate the energy beam transmitter to form the melt pool in a second part of the substrate arranged in a direction turned vertically downwards.
    In yet another improvement, the energy beam emitter is configured for a progressive displacement of the melt puddle of the first part in the second part of the substrate.
    Embodiments of the present invention include a system, comprising: means for disposing a portion of a substrate in a direction vertically downwardly; means for forming a melt puddle in the portion of the substrate using a directed energy beam, the melt puddle being formed facing in a vertically downward direction in the substrate portion; and means to direct a flow
    权利要求:
    Claims (10)
    [1]
    A method for depositing materials in a substrate (12), comprising: disposing a surface of a substrate (12) having a first portion facing downwardly; the direction of an energy beam (16) from below the first portion to the first portion; forming a melt puddle (26) in the substrate (12) using the directed energy beam (16), the melt puddle (26) being formed in the first portion, and the direction of a flow of particles (20) from below the first portion to the first portion, at least some of the particles (20) being floating in the melt puddle (26) to move upwardly in the puddle. melt (26) to unmelted portions of the substrate (12); the particles (20) are not of the same material as the substrate (12); and solidifying the melt puddle (26) to form a coating on the substrate (12); the solidification comprising the formation of pores defined by the particles (30) in the coating of the substrate (12).
    [2]
    The process according to claim 1, wherein at least some of the particles have a property different from that of the other particles and rising in the melt puddle (26) to unmelted portions of the substrate (12), the property being for example, a lower density than the other particles or a higher buoyancy in the melt puddle (26) than that of the other particles.
    [3]
    The method of claim 1, wherein the substrate (12) is metallic and the particles (20) in the melt puddle (26) together with a melt substrate (12) forming a metal matrix composite.
    [4]
    4. The method of claim 1 or 3, the particles (20) including non-metallic particles, all the particles (20) being for example non-metallic particles, the particles may include hollow particles, the particles may include reactive pore formation.
    [5]
    The method of claim 1, further comprising, prior to the step of solidifying the melt puddle (26), displacing and / or rotating the substrate (12) to provide a second portion of the substrate (12) to the bottom while keeping the melt puddle (26) facing downwards, the melt puddle (26) being progressively displaced in the second part of the substrate (12).
    [6]
    6. The method of claim 1, the energy beam (16) being a laser.
    [7]
    The method of claim 1, the energy beam (16) being directed at the first portion at an angle of less than approximately 15 degrees from the vertical.
    [8]
    A system (10) configured to perform the method according to one of claims 1 to 7, comprising: an energy beam transmitter (14) positioned to direct the energy beam (16) from below a first portion of a substrate (12) to the first portion, the energy beam (16) being configured to form a melt puddle (26) in the first portion; and a particle sprayer (18) operated to direct a stream of particles (20) from below the melt puddle (26) to the melt puddle (26), the system (10) being configured to maintain the melt puddle (26) in a liquid state while at least some of the particles rise into the melt puddle (26) to unmelted portions of the substrate (12).
    [9]
    The system (10) of claim 8, further comprising a first positioning system (28) coupled to the substrate (12) and operated to move and / or rotate the substrate (12) to provide a second portion of the substrate ( 12) downwardly while keeping the melt puddle (26) facing downwards, said first positioning system (28) being configurable for a progressive movement of the melt puddle (26) of the first part in the second portion of the substrate (12), and a second positioning system (30) coupled to the energy beam emitter (16) and operated to move and / or rotate the energy beam emitter (16) to form the melt puddle (26) in the second portion of the substrate (12) disposed downwardly.
    [10]
    The system (10) of claim 9, wherein the energy beam transmitter (16) is configured for progressive movement of the melt puddle (26) from the first portion into the second portion of the substrate (12).
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    法律状态:
    2017-04-28| PK| Correction|Free format text: REVENDICATIONS 2 ET 8 CORRIGEE |
    2020-09-15| PFUS| Merger|Owner name: ROLLS-ROYCE CORPORATION, US Free format text: FORMER OWNER: ROLLS-ROYCE CORPORATION, US |
    2021-07-30| PL| Patent ceased|
    优先权:
    申请号 | 申请日 | 专利标题
    US201061427729P| true| 2010-12-28|2010-12-28|
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