Method of manufacturing endoscope flexible tube

US 20050228222A1
Filed: 04/06/2005
Published: 10/13/2005
Est. Priority Date: 04/09/2004
Status: Abandoned Application

First Claim

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1. A method of manufacturing an endoscope flexible tube comprising:

irradiating a flexible tube member with a near infrared ray before covering the flexible tube member formed at least partly of metal with an outer coat to raise the surface temperature of the flexible tube member to a temperature higher than that the outer coat deforms; and

covering an outer periphery of the flexible tube member raised in temperature by the near infrared ray with the outer coat.

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Abstract

The present invention provides a method of manufacturing a flexible tube for an endoscope including heating a flexible tube member formed at least partly of metal and covering an outer coat thereon, wherein the flexible tube member is heated by irradiating a near infrared ray. The near infrared ray can heat metal satisfactorily and selectively in comparison with other materials such as synthetic resin or the like. Therefore, heating of the portion other than the surface of the flexible tube member can be restrained. Therefore, even when synthetic resin is used for a jig, deformation of the jig can be restrained. The preferred wavelength of the near infrared ray is from about 0.8 to about 2.0 μm.

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24 Claims

1. A method of manufacturing an endoscope flexible tube comprising:
- irradiating a flexible tube member with a near infrared ray before covering the flexible tube member formed at least partly of metal with an outer coat to raise the surface temperature of the flexible tube member to a temperature higher than that the outer coat deforms; and
  
  covering an outer periphery of the flexible tube member raised in temperature by the near infrared ray with the outer coat.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. A method of manufacturing an endoscope flexible tube according to claim 1, wherein the method of manufacturing the flexible tube member comprises:
    - winding a flex on a cylindrical or column-shaped core member formed of material containing at least synthetic resin; and
      
      disposing a mesh tube containing metal as at least part of the material on the outer periphery of the flex.
  - 3. A method of manufacturing an endoscope flexible tube according to claim 2, further comprising:
    - decreasing an outer diameter of the core member and pulling the core member from the flexible tube member after covering the outer periphery of the flexible tube member with the outer coat.
  - 4. A method of manufacturing an endoscope flexible tube according to claim 1, wherein a wavelength when a maximum value of emission spectrum of the near infrared ray is obtained resides within the range from about 0.8 μ
    - m to about 2.0 μ
      
      m.
  - 5. A method of manufacturing an endoscope flexible tube according to claim 1, wherein the covering of the outer periphery of the flexible tube member is performed by one of extrusion molding and dipping.
  - 6. A method of manufacturing an endoscope flexible tube according to claim 1, wherein the covering of the outer periphery of the flexible tubular member with the outer coat comprises molding the outer coat into a tubular shape in advance of the covering.
  - 7. A method of manufacturing an endoscope flexible tube according to claim 1, wherein the endoscope flexible tube is an insertion portion of an endoscope.
  - 8. A method of manufacturing an endoscope flexible tube according to claim 1, wherein the endoscope flexible tube is a universal cord of an endoscope.

9. A method of manufacturing an endoscope flexible tube by covering an outer periphery of a mesh tube whereof at least an element wire or a part of a bundle of element wires is formed of metallic material with an outer coat formed of a thermoplastic resilient member by extrusion molding or dipping, the method comprising:
- heating a surface of the mesh tube using a light emitting member for emitting a near infrared ray whereof the maximum value of emission spectrum resides within the range from about 0.8 μ
  
  m to about 2.0 μ
  
  m in advance before covering the outer periphery of the mesh tube with the outer coat; and
  
  bonding between the mesh tube and the outer coat by an energy generated when preheating the mesh tube.

10. A method of manufacturing an endoscope flexible tube by covering an outer periphery of a mesh tube whereof at least an element wire or a part of a bundle of element wires is formed of metallic material with an outer coat formed of a thermoplastic resilient member and formed into a tubular shape in advance, the method comprising:
- heating a surface of the mesh tube using a light emitting member of a near infrared ray whereof the maximum value of emission spectrum resides in the range from about 0.8 μ
  
  m to about 2.0 μ
  
  m before covering the outer periphery of the mesh tube with the thermoplastic resilient member; and
  
  bonding the mesh tube and the thermoplastic resilient member with an energy generated when preheating the mesh tube.

11. A method of manufacturing an endoscope flexible tube comprising:
- disposing a mesh tube comprising an element wire or a bundle of element wires formed at least partly of metallic material weaved therein outside a flex which is a metal band strip wound into a helical shape;
  
  irradiating a near infrared ray from outside the mesh tube to heat the mesh tube to a temperature at which an outer coat formed of thermoplastic resilient member for covering the outside of the mesh tube is at least softened; and
  
  after having heated the mesh tube to the temperature at which the outer coat is softened, covering the outer periphery of the mesh tube with the outer coat by one of extrusion molding and dipping to bond the mesh tube and the outer coat by preheating of the mesh tube.
- View Dependent Claims (12)
- - 12. A method of manufacturing an endoscope flexible tube according to claim 11, wherein the wavelength of the near infrared ray irradiated in the step of heating resides within the range from about 0.8 μ
    - m to about 2.0 μ
      
      m.

13. A method of manufacturing an endoscope flexible tube comprising:
- detachably disposing a flex formed by winding a band strip into a helical shape on an outside of a core member, the core member having a circumferential peripheral surface and being capable of expanding and contracting in a radial direction and a longitudinal direction;
  
  disposing a mesh tube on an outside of the flex, the mesh tube including an element wire or a bundle of element wires formed at least partly of metallic material weaved therein and having a higher heat absorption coefficient observed when a near infrared ray is irradiated than the core member;
  
  irradiating the near infrared ray from outside the mesh tube and heating the mesh tube to a temperature at which an outer coat formed of thermoplastic resilient member for covering the mesh tube is softened;
  
  covering an outer periphery of the mesh tube with the outer coat by one of extrusion molding and dipping immediately after having heated the mesh tube to the temperature at which the outer coat is softened and bonding the mesh tube and the outer coat by preheating the mesh tube; and
  
  removing the core member from inside the mesh tube in a state in which the core member is pulled in the longitudinal direction to reduce the diameter radially inwardly.
- View Dependent Claims (14)
- - 14. A method of manufacturing an endoscope flexible tube according to claim 13, wherein stainless steel is used for the mesh tube, silicone rubber is used for the core member, and light whereof the wavelength of which can obtain the maximum value of emission spectrum resides within the range from about 0.8 μ
    - m to about 2.0 μ
      
      m is irradiated as the near infrared ray.

15. A method of manufacturing an endoscope flexible tube comprising:
- detachably disposing a flex formed by winding a band strip into helical shape on an outside of a core member, the core member having a circumferential peripheral surface and being capable of expanding and contracting in a radial direction and a longitudinal direction;
  
  disposing a mesh tube on an outside of the flex, the mesh tube including an element wire or a bundle of element wires formed at least partly of metallic material weaved therein and having a higher heat absorption coefficient observed when a near infrared ray is irradiated than the core member;
  
  irradiating the near infrared ray from outside the mesh tube and heating the mesh tube to a temperature at which an outer coat formed of thermoplastic material of tubular shape for covering the mesh tube;
  
  covering an outer periphery of the mesh tube with the outer coat immediately after having heated the mesh tube to the temperature at which the outer coat is softened and bonding the mesh tube and the outer coat by preheating the mesh tube; and
  
  removing the core member from inside the mesh tube in a state in which the core member is pulled in the longitudinal direction to reduce the diameter radially inwardly.
- View Dependent Claims (16)
- - 16. A method of manufacturing an endoscope flexible tube according to claim 15, wherein stainless steel is used for the mesh tube;
    - silicone rubber is used for the core member; and
      
      light whereof the wavelength of which can obtain the maximum value of emission spectrum resides within the range from about 0.8 μ
      
      m to about 2.0 μ
      
      m is irradiated as the near infrared ray.

17. An endoscope flexible tube manufactured by a method comprising:
- detachably disposing a flex formed by winding a band strip into a helical shape on an outside of a core member, the core member having a circumferential peripheral surface and being capable of expanding and contracting in a radial direction and a longitudinal direction;
  
  disposing a mesh tube on an outside of the flex, the mesh tube including an element wire or a bundle of element wires formed at least partly of metallic material weaved therein and having a higher heat absorption coefficient with respect to a near infrared ray than the core member when a surface of the mesh tube is heated by the near infrared ray;
  
  heating an outer periphery of the mesh tube by the near infrared ray to a temperature at which an outer coat of thermoplastic resilient member for covering the outer periphery of the mesh tube is at least softened and bonded to the mesh tube;
  
  immediately after the heating, covering the outer peripheral surface of the mesh tube with the outer coat by one of extrusion molding and dipping and bonding the mesh tube and the outer coat by preheating the mesh tube; and
  
  pulling the core member out from the flex in a state in which the core member is pulled in the longitudinal direction to reduce the diameter radially inwardly.
- View Dependent Claims (18, 19, 20)
- - 18. An endoscope flexible tube according to claim 17, wherein the mesh tube is formed of metallic material containing at least one of stainless steel alloy, copper, brass, tungsten, and iron, and the core member is formed of a synthetic resin material containing silicone rubber.
  - 19. An endoscope flexible tube according to claim 17, wherein the mesh tube is formed of a compound of metallic material containing at least one of stainless steel alloy, copper, brass, tungsten and iron and non-metallic material containing at least one of synthetic resin, silk string, and kite string, and the core member is formed of a synthetic resin material containing silicone rubber material.
  - 20. An endoscope flexible tube according to claim 17, wherein the mesh tube is formed of stainless steel, the core member is formed of silicone rubber, and a wavelength whereby the maximum value of emission spectrum of the near infrared ray can be obtained resides in the range from about 0.8 μ
    - m to about 2.0 μ
      
      m.

21. An endoscope flexible tube manufactured by a method comprising:
- detachably disposing a flex formed by winding a band strip into a helical shape on an outside of a core member, the core member having a circumferential peripheral surface and being capable of expanding and contracting in a radial direction and a longitudinal direction;
  
  disposing a mesh tube on an outside of the flex, the mesh tube including an element wire or a bundle of element wires formed at least partly of metallic material weaved therein and having higher a heat absorption coefficient with respect to a near infrared ray than the core member when a surface of the mesh tube is heated by the near infrared ray;
  
  heating an outer periphery of the mesh tube by the near infrared ray to a temperature at which an outer coat formed of a thermoplastic resilient material for covering the outer periphery of the mesh tube into a tubular shape is at least softened and bonded to the mesh tube;
  
  immediately after the heating, covering an outer peripheral surface of the mesh tube and bonding the mesh tube and the outer coat by preheating the mesh tube; and
  
  pulling the core member out from the flex in a state in which the core member is pulled in the longitudinal direction to reduce the diameter radially inwardly.
- View Dependent Claims (22, 23, 24)
- - 22. An endoscope flexible tube according to claim 21, wherein the mesh tube is formed of metallic material containing at least one of stainless steel alloy, copper, brass, tungsten, and iron;
    - and the core member is formed of a synthetic resin material containing silicone rubber.
  - 23. An endoscope flexible tube according to claim 21 wherein the mesh tube is formed of a compound including metallic material containing at least one of stainless steel alloy, copper, brass, tungsten, and iron and non-metallic material containing at least one of a synthetic resin, silk string, and kite string;
    - and the core member is formed of a synthetic resin material containing silicone rubber.
  - 24. An endoscope flexible tube according to claim 21, wherein the mesh tube is formed of stainless steel, the core member is formed of silicone rubber, and a wavelength whereby the maximum value of emission spectrum of the near infrared ray can be obtained resides within the range from about 0.8 μ
    - m to about 2.0 μ
      
      m.

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Current Assignee
Olympus Corporation
Original Assignee
Olympus Corporation
Inventors
Furumi, Satoshi

Application Number

US11/100,242
Publication Number

US 20050228222A1
Time in Patent Office

Days
Field of Search
US Class Current

600/101
CPC Class Codes

A61B 1/0011   Manufacturing of endoscope ...

A61B 1/005   Flexible endoscopes

A61L 29/14   Materials characterised by ...

Method of manufacturing endoscope flexible tube

First Claim

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Abstract

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24 Claims

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Method of manufacturing endoscope flexible tube

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

Citations

24 Claims

Specification

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Solutions

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