KR20230147448A - Endoscope tube - Google Patents

Abstract

The disclosed content relates to an endoscope tube that has the flexibility to bend smoothly in various directions, prevents twisting, and allows rotational torque to be efficiently transmitted by reducing the elasticity of the coating layer.
The disclosed content includes a linear metal band, a metal wire mesh layer surrounding the spiral metal band, a covering layer formed of a soft synthetic resin material surrounding the metal wire mesh layer, and a coating layer integrally provided with the coating layer and having self-elasticity of the coating layer. An endoscopic tube including an elasticity reducing band formed of a hard synthetic resin material to reduce elasticity is presented as an example.

Description

Endoscope tube{ENDOSCOPE TUBE}

The disclosed content relates to a tube used in an endoscope that allows an object to be observed to be imaged through a small camera provided at the tip in the medical field or various other industrial fields.

Unless otherwise indicated herein, the matters described in this identification are not prior art to the claims of this application, and are not admitted to be prior art by being described in this identification.

An endoscope, mainly used in the medical field, uses a small camera to check the presence of diseases or abnormalities by observing the inside of the human body, such as the stomach, esophagus, large intestine, small intestine, bronchial tubes, nasal cavity, or inner ear, etc., without laparotomy or incision of the body. refers to a device that allows In addition, endoscopes used in the medical field are also applied to minimally invasive procedures or surgeries such as laparoscopy and arthroscopy.

These endoscopes are applied not only to the medical field, but also to various industrial fields such as the defense field, automobile field, and internal exploration field in a form that allows the interior to be observed without dismantling the aircraft or to investigate abnormalities inside the pipe. It is becoming.

These endoscopes include an endoscope tube equipped with a small camera at the tip, a data transmission cable arranged inside the endoscope tube and transmitting images captured by the small camera, and a data transmission cable arranged inside the endoscope tube and supplying power to the small camera. Includes power cable. Additionally, a tube drive wire may be installed inside the endoscope tube to adjust the angle of the tip of the endoscope tube in order to adjust the shooting angle of the small camera. Additionally, forceps for collecting part of human tissue or other instruments necessary for surgery or procedures may be inserted into the endoscope tube.

Meanwhile, the endoscopic tube applied to the endoscope must have the flexibility to bend smoothly in various directions while preventing twisting. For this purpose, the endoscope tube includes a spiral metal band, a metal wire mesh layer surrounding the band, and a soft coating layer surrounding the band.

As an example of such an endoscopic tube, Korean Utility Model Publication No. 20-2017-0004276 (published on December 20, 2017) includes an inner spiral metal band that accommodates an optical cable for imaging the inside of the human body and forceps for collecting human body parts, An outer spiral metal band surrounding the inner spiral metal band, a wire mesh made of stainless steel surrounding the outer spiral metal band from the outside, a polyurethane coating layer surrounding the wire mesh, and a polyurethane coating layer on the outside. A disposable endoscope tube device is disclosed, including a polymer coating layer surrounding the wire mesh, wherein the wire mesh brings the metal band and the coating layer into close contact to prevent the coating layer and the metal band from slipping and twisting each other.

However, the conventional endoscopic tube as described above has a structure in which twisting is prevented by internal and external spiral metal bands while being flexible due to a coating layer made of polyurethane. However, due to the self-elasticity of the coating layer, rotational torque is efficiently reduced. There were limits to delivery.

Republic of Korea Utility Model Publication No. 20-2017-0004276 (published on December 20, 2017)

The aim is to provide an endoscope tube that has the flexibility to bend smoothly in various directions, prevents twisting, and allows rotational torque to be transmitted efficiently by reducing the elasticity of the coating layer.

Additionally, it is not limited to the technical challenges described above, and it is obvious that other technical challenges may be derived from the description below.

The disclosed content includes a spiral metal band, a metal wire mesh layer surrounding the spiral metal band, a coating layer formed of a soft synthetic resin material surrounding the metal wire mesh layer, and a coating layer provided integrally with the coating layer and having self-elasticity of the coating layer. An endoscopic tube including an elasticity reducing band formed of a hard synthetic resin material to reduce elasticity is presented as an example.

According to a preferred feature of the disclosed content, the spiral metal band includes an inner spiral metal band member extending along a spiral inclined in one direction, and a spiral surrounding the inner spiral metal band but inclined in the opposite direction to the inner spiral metal band. It includes an outer spiral metal band member extending along.

According to a preferred feature of the disclosed content, the covering layer is formed by extruding a soft synthetic resin material on the outer circumferential surface of the metal wire mesh layer in a state in which an elasticity reducing band is surrounded on the outer circumferential surface of the metal wire mesh layer, and the elastic The hard synthetic resin material forming the reduction band has a higher melting point than the soft synthetic resin material forming the coating layer.

According to a preferred feature of the disclosed content, a coating layer is laminated on the outer peripheral surface of the coating layer.

According to a preferred feature of the disclosed content, the elasticity reducing band is formed as a spiral spring.

According to a preferred feature of the disclosed content, the elasticity reduction band is formed as a grid tube body in which a plurality of bands made of the hard synthetic resin material cross each other at right angles or obliquely cross each other at a certain angle.

According to an endoscopic tube according to an embodiment of the disclosed content, the coating layer formed of a soft synthetic resin material and the metal wire mesh layer have flexibility to gently bend in various directions, while twisting is prevented by the spiral metal band, In particular, the coating layer formed of a soft synthetic resin material is provided with an elasticity reducing band formed of a hard synthetic resin material, for example in the form of a spiral spring or braided tube body, to reduce the elasticity of the coating layer, so that the endoscope tube It has the advantage that rotational torque can be transmitted efficiently.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a layered structure diagram of an endoscopic tube according to an embodiment of the disclosed content.
Figure 2 is a cross-sectional structural diagram of an endoscopic tube according to an embodiment of the disclosed content.
3 to 5 are perspective views of various types of elasticity reduction bands in an endoscopic tube according to an embodiment of the disclosed content.

Hereinafter, the configuration, operation, and effects of the preferred embodiment will be examined with reference to the attached drawings. For reference, in the drawings below, each component is omitted or schematically shown for convenience and clarity, and the size of each component does not reflect the actual size. In addition, the same reference numerals refer to the same components throughout the specification, and reference numerals for the same components in individual drawings will be omitted.

As shown in FIGS. 1 to 5, the endoscopic tube according to an embodiment of the disclosed content has a spiral metal band 10, a metal wire mesh layer 20, and a covering layer 30 sequentially forming concentric circles. It is formed by stacking, and has a structure in which the coating layer 30 is integrally provided with an elasticity reduction band 40 that reduces the elasticity of the coating layer 30.

Here, the spiral metal band 10 is formed on the core material forming the inner space of the endoscopic tube 1 according to an embodiment of the disclosed content, and has a certain width and thickness to prevent twisting and have appropriate tension. The branches have a kind of coiled spring shape with a square cross-section extending along a spiral at regular pitch intervals.

When the endoscopic tube according to an embodiment of the disclosure is applied to, for example, an ENT endoscope, it can be manufactured to have an outer diameter of, for example, 4.0 mm or 6.0 mm. In the former case, a spiral metal band (10) can be formed by a helical spring with a rectangular cross-section having a width of 2.0 mm and a thickness of 0.2 mm extending along the helix with a pitch spacing of 0.3 mm, in the latter case having a width of 2.5 mm and a thickness of 0.3 mm. The branches can be formed as helical springs whose rectangular cross-section extends along the helix with a pitch spacing of 0.8 mm.

In addition, the spiral metal band 10 may be formed of only a single spiral metal band member, but it is preferable that two spiral metal band members extending along spirals inclined in different directions are formed overlapping each other.

In the latter case, the spiral metal band 10 includes an inner spiral metal band member 11 that extends along a spiral inclined in one direction, and surrounds the inner spiral metal band 11, but is formed in an opposite direction to the inner spiral metal band 11. It includes an outer spiral metal band member 13 extending along an inclined spiral. At this time, the inner spiral metal band member 11 and the outer spiral metal band member 12 are preferably made of the same material, for example, stainless steel, but depending on the embodiment, they may be made of different metal materials. It may be possible.

The above-described spiral metal band 10 is surrounded by a metal wire mesh layer 20. The metal wire mesh layer 20 surrounds the spiral metal band 10 so that tension can be maintained in the spiral metal band 10, and at the same time, when the covering layer 130, which will be described later, is laminated, the covering layer 130 The soft synthetic resin material forming the infiltrated and tightly bonded to the outer peripheral surface of the spiral metal band 10, especially the outer spiral metal band member 13, thereby forming the spiral metal band 10, especially the outer spiral metal band member 13, and the coating layer. (130) serves to prevent the phenomenon of slipping and twisting against each other.

The metal wire mesh layer 20 may be formed, for example, by forming a layer of a certain width by a plurality of wires made of stainless steel, and then braiding the layers of the certain width together. For example, the wire included in the metal wire mesh layer 20 may have a diameter of 0.05 mm, and the metal wire mesh layer 20 is formed into a spiral shape by layers of a certain width formed of a plurality of wires. The metal band 10, particularly the outer peripheral surface of the outer spiral metal band member 13, may be braided to overlap about four times.

The metal wire mesh layer 20 described above is surrounded by the covering layer 30. The covering layer 30 corresponds to a cover layer surrounding the wire mesh 130 and can be formed of, for example, a soft synthetic resin material such as a polyurethane-based soft synthetic resin material or a silicon-based soft synthetic resin material.

Additionally, the coating layer 31 may be laminated on the coating layer 30 using a non-toxic polymer such as silicone-based synthetic resin material, which is widely used in medical applications.

The above-described coating layer 40 is integrally provided with elasticity reduction bands 40, 40', 40". The elasticity reduction bands 40, 40', 40" are used to prevent excessive elasticity of the coating layer 30 formed of a soft synthetic resin material. By reducing its own elasticity, the rotational torque applied by, for example, a tube drive wire or the resistance of body tissue can be transmitted efficiently, for example, polyurethane-based hard synthetic resin material or silicone-based hard synthetic resin. It can be formed from a hard synthetic resin material such as ash.

The term "soft" used in the coating layer 30 and the term "hard" used in the elasticity reduction bands 40, 40', 40", which will be described later, are not divided into two based on a specific hardness value, but are relative to each other. Please make it clear in advance that it is used with a certain meaning.

These elasticity reducing bands (40, 40', 40") may be formed as spiral springs (corresponding to reference numeral 40) as shown in FIG. 3, or as shown in FIG. 4, for example, may be made of polyurethane-based hard synthetic resin. Bands made of hard synthetic resin material, such as ash or silicone-based hard synthetic resin material, may be formed into a lattice tube body crossing each other at right angles (corresponding to reference numeral 40'), as shown in FIG. 5, for example, polyurethane-based hard synthetic resin material. Bands made of hard synthetic resin material, such as synthetic resin material or silicone-based hard synthetic resin material, are formed into a lattice tube body that is inclined to each other at a certain angle (corresponding to reference numeral 40").

In order to integrate the coating layer 30 and the elasticity reduction bands (40, 40', 40"), the coating layer (30) has elasticity reduction bands (40, 40', 40") on the outer peripheral surface of the metal wire mesh layer (20). It is preferable that a soft synthetic resin material is laminated on the outer peripheral surface of the metal wire mesh layer 20 in the surrounded state by, for example, extrusion. In this case, the hard synthetic resin material forming the elasticity reducing bands 40, 40', and 40" is preferably selected to have a higher melting point than the soft synthetic resin material forming the covering layer 30.

As described above, the endoscopic tube according to an embodiment of the disclosed content has the flexibility to be gently bent in various directions by the coating layer 30 and the metal wire mesh layer 20 formed of a soft synthetic resin material. Torsion is prevented by the spiral metal band 10, and in particular, elasticity reduction bands 40 and 40 are formed of a hard synthetic resin material to reduce the self-elasticity of the covering layer 30, which is formed of a soft synthetic resin material. '. 40") is provided integrally in the form of, for example, a spiral spring or a braided tube body, so that the rotational torque for inserting the endoscope tube can be efficiently transmitted.

Although preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the embodiments described in this specification and the configuration shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention. Since this is not the case, it should be understood that there may be various equivalents and modifications that can replace them at the time of filing this application. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later rather than the detailed description, and the meaning and scope of the claims and their All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

10: Spiral metal band
11: Inner spiral metal band
12: Outer spiral metal band
20: Metal wire mesh layer
30: coating layer
31: coating layer
40, 40', 40": Reduced elasticity band

Claims (6)

Spiral metal band;
a metal wire mesh layer surrounding the spiral metal band;
a covering layer formed of a soft synthetic resin material surrounding the metal wire mesh layer; and
An endoscope tube including an elasticity reduction band integrally provided with the coating layer and made of a hard synthetic resin material to reduce the elasticity of the coating layer. In claim 1,
The spiral metal band includes an inner spiral metal band member extending along a spiral inclined in one direction, and an outer spiral metal band member surrounding the inner spiral metal band and extending along a spiral inclined in the opposite direction to the inner spiral metal band. An endoscope tube comprising: In claim 1,
The covering layer is formed by laminating a soft synthetic resin material by extrusion on the outer peripheral surface of the metal wire mesh layer in a state in which an elasticity-reducing band is surrounded on the outer peripheral surface of the metal wire mesh layer, and the hard synthetic resin material forming the elasticity-reducing band is An endoscope tube, characterized in that it has a higher melting point than the soft synthetic resin material forming the coating layer. In claim 1,
An endoscope tube, characterized in that a coating layer is laminated on the outer peripheral surface of the coating layer. The method of any one of claims 1 to 4,
An endoscope tube, characterized in that the elasticity reduction band is formed of a spiral spring. The method of any one of claims 1 to 4,
An endoscope tube, characterized in that the elasticity reduction band is formed as a grid tube body in which a plurality of bands made of the hard synthetic resin material cross each other at right angles or cross each other obliquely.

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