JPH0361443B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improvement in a tube for an insertion channel of an endoscope.

Generally, the tube that constitutes the forceps channel of an endoscope is made of a flexible cylindrical member, but recently, in order to reinforce this cylindrical member, a braid made of cotton material is fitted or the tube is thickened. It has been proposed that the structure be buried in the
(Japanese Utility Model Publication No. 57-7503). Then, to prevent the blades from separating, the stitches are kept somewhat "loose" to create gaps, and a resin layer is embedded in the gaps to integrate the blades.

However, when the tube is inserted into the flexible tube of the endoscope insertion section, the tube cannot be bent so sharply, so even though there are few problems, when the tube is inserted into the flexible tube of the endoscope insertion section, the tube can be bent sharply. , the tip of the forceps being inserted strongly hits the inner surface of the curved part, and the mesh breaks down from the part that hits the "loose" gap of the blade. The blade moved as the tip of the forceps repeatedly hit the tube, which weakened the tube and eventually caused the tip of the forceps to become stuck.

In addition, since the blades in the above tube have many "sparse" parts, sometimes the part corresponding to the curved pipe has a small radius of curvature (for example, about 5 ^R ).
If you do so, it will easily collapse and become flat. As a result, the inside of the forceps channel became extremely narrow, making it difficult to pass the forceps therein, and the forceps also had a heavy protruding force, resulting in poor operability. Moreover,
When passing the forceps through the narrow portion of the forceps channel, the forceps are pushed in more, which makes the tube more likely to be damaged due to the same reasons as mentioned above, and the braided mesh is more likely to break.

The present invention has been made focusing on the above circumstances,
The purpose is to create a tube for the insertion channel of an endoscope that is reinforced so that even if the curved tube of the insertion section is greatly curved, the blade will not shift when a treatment instrument such as forceps hits it, and the tube will not become flat. Our goal is to provide the following.

Hereinafter, each embodiment of the present invention will be described based on the drawings.

1 to 4 show a first embodiment thereof. Reference numeral 1 in FIG. 1 is a medical endoscope 1, and this endoscope 1 is composed of an operating section 2, an insertion section 3 to be inserted into a body cavity, and a light guide cord 4. The insertion section 3 is formed by connecting a tip component 7 to the tip of a flexible tube 5, which will be described later, via a curved tube 6. The bending tube 6 is bent by operating the operating knob 8 of the operating section 2 so that the direction of the tip component 7 can be changed. Further, the operation section 2 is provided with an eyepiece section 9, an air/water supply switching button 11, a suction operation button 12, and an insertion port section 13 for a treatment tool. Further, as shown in FIG. 2, an insertion channel tube 14, which will be described later, is inserted into the insertion portion 3. The tip of this tube 14 is inserted into a hole 15 formed in the tip component 7 and fixed with adhesive. Note that the other end of the hole 15 is open to the outside. Further, the proximal end side of the tube 14 is guided into the operating section 2 and connected to the insertion opening section 13. The hollow space within the tube 14 forms a channel through which a treatment tool such as forceps is inserted.

The insertion channel tube 14 is made of a porous material made of polytetrafluoroethylene (PTFE). A first elastic coating film 16 is formed on this outer surface to make it watertight, and a tubular blade 17 as a reinforcing tubular member is fitted on the outer side of the first elastic coating film 16 to make it watertight. A second elastic body 18 is formed on the surface. And these are integrally combined. Further, the blade 17 is embedded between the first and second elastic coatings 16 and 18.

As shown in FIGS. 3 and 4, the blade 17 is formed by knitting metal wire rods 19 as long materials into a tubular shape. In other words, each metal wire 1
Each metal wire 19... is made into a bundle of three wires and each bundle is plain-woven as a wire and woven into a tubular shape, and each metal wire material 19... has an equal inclination angle θ ₁ , θ from both sides with respect to the longitudinal direction of the tube 14. ₂ and each is tilted. Further, the mesh density of the braid 17 is different between the range corresponding to the flexible tube 5 and the range corresponding to the curved tube 6. In other words, the flexible tube 5 and the curved tube 6
The density of the stitches differs from the vicinity corresponding to the connecting portion 20 that connects the two. Specifically, the flexible tube 5
The stitches on the side are "loose" and the stitches on the curved tube 6 side are "dense".

FIG. 4a shows a "dense" state, and FIG. 4b shows a "sparse" state. Therefore, the relationship between the inclination angle θ 1 _{and θ 2 of} each metal wire 19 in the distal end portion 17a and the proximal end portion 17b of the blade 17 is θ ₁ >
θ ₂ . Therefore, the gap 21 in the distal end portion 17a of the blade 17 with dense stitches is small, and the gap 21 in the proximal end portion 17b of the blade 17 with sparse stitches is small.
The void 22 in is larger than the void 21 described above.
The difference in the density of the stitches mentioned above is due to the blade 17.
When knitting, it can be easily adjusted by changing the winding speed.

Next, the operation of the insertion channel tube 14 will be explained. When the insertion section 3 of the endoscope 1 is used by being inserted into a body cavity, the bending tube 6 is remotely operated to bend by the operation knob 8 of the operation section 2, so that it is bent considerably. On the other hand, the flexible tube 5 portion of the insertion section 3 does not curve that much, but only gently. Therefore, the portion of the insertion channel tube 14 corresponding to the flexible tube 5 is also only slightly curved. Therefore, a treatment tool such as a biopsy forceps inserted into the tube 14 is guided gently along the inner wall of the tube 14 and does not press strongly locally on the inner wall. However, the portion of the insertion channel tube 14 corresponding to the curved tube 6 is sharply bent as described above, and the tip of the treatment instrument inserted therein is pushed out while strongly locally pressing the inner wall. However, the blade 17 in this insertion channel tube 14 has a portion 17a corresponding to the curved portion 6.
By making the stitches particularly dense, the voids 21 of the stitches become smaller. Therefore, as soon as the blade 17 is pressed in the axial direction, the gaps 21 in the mesh almost disappear, and the inner diameter of the blade 17 is regulated. Therefore, even if the inner wall of the tube 14 is locally pushed by the treatment instrument, the metal wires 19 of the blade 17 hardly move.
Therefore, buckling of the tube 14 is prevented,
And the treatment tool will not get caught. Furthermore, if the metal wires 19 of the blade 17 are closely spaced together, it will not become flat even if it is sharply bent, and a wide insertion path for the treatment instrument can be ensured. On the other hand, in the flexible tube 5, by making the mesh of the blade 17 sparse, the first and second elastic coating films 16 and 18, which are sandwiched and embedded in the blade 17, are firmly bonded through the large gaps 22 of the mesh. be done. In addition, since the blade 17 is not locally pressed by the treatment instrument,
Even if the tube 14 located inside the curved tube 6 and the blade 17 were to separate from each other due to no movement of the metal wire 19..., the separation would be stopped at a portion corresponding to the flexible tube 5, and the tube for the insertion channel would be removed. 14 strength can be maintained.

FIG. 5 shows a second embodiment. In this embodiment, the tip end portion 17a of the blade 17 has dense stitches.
A transition portion 23 is provided between the base end portion 17b and the transition portion 23, and the stitch density of the transition portion 23 is made “more dense” than that of the distal end portion 17a. By providing the transition portion 23 with denser stitches in this manner, change in the inner diameter of the blade 17 is suppressed, so that separation between the blade 17 and the tube 14 is not transmitted to the proximal portion 17b. In addition,
The density of this transition section 23 can also be easily adjusted by changing the winding speed when knitting the braid 17.

By the way, in the first and second embodiments described above, the blade 17 is placed in the tube 14 when the braid 17 is knitted densely (the warp threads stand up) and when it is knitted sparsely (the warp threads bend). There is a difference in the outer diameter when covered, with the former having a larger outer diameter. Therefore, by reinforcing only the portions of the insertion channel tube 14 that require strength against the pressure of the forceps, and reducing the outer diameter of the portions that do not require strength against the pressure, other built-in items can be protected. In addition, the curved pipe 6
Comparing the length of the flexible tube 5 with that of the flexible tube 5, the latter is much longer, and the sparse portion of the blade 17 is used for this portion. Therefore, the blade 14 with sparse stitches
The inner diameter of the portion tends to be large, so it is easy to cover the tube 14. Since the part that requires strength against the pressure of the treatment tool, that is, the part with dense stitches, is short, assembly work is also facilitated.

FIG. 6 shows a third embodiment. This is because the sparse and dense state of the blade 17 is the same as in the first embodiment, but the inner circumferential surface of the blade 17 is
An elastic coating film 24 exposed on the inner circumferential surface of the tube 14 and formed on the outer circumferential surface of the tube 14 ensures watertightness of the tube 14.
This can be easily made, for example, by covering a stretchable tube material with the braid 17, coating the surface of the blade 17 with the elastic coating 24, and then stretching the tube material to reduce its outer diameter. In this embodiment, since there are no members inside the blade 17, the inner diameter of the tube 14 can be increased. Moreover, the tube materials used in the above manufacturing process can be reused many times and are inexpensive.

By the way, in the first, second and third embodiments described above, the braid 17 may be knitted into a tubular shape and then placed over each tube, or the braid 17 may be placed directly on each tube. It may be formed into a tubular shape while knitting.

Furthermore, when the core material is inserted into the tube with the blade covering each tube and the blade 17 is squeezed from the outside so as to come into close contact with the tube, the blade 17 bites into the tube. Therefore, in the first and second embodiments, the outer diameter is small, and in the third embodiment, the amount of exposure to the inner surface of the blade 17 can be adjusted.

In addition, in the above explanation, the blade 17 with dense stitches
Although the explanation has been made regarding the inside of the curved tube 6, it may extend inside the connecting portion 20 or the flexible tube 5 on the side of the connecting portion 20.

Furthermore, in the above embodiment, the blade 17
Continuously “dense” and “sparse” wires without cutting them
However, the braid 17 with dense stitches and the braid 17 with sparse stitches may be connected. Furthermore, the state in which the stitches become dense to sparse may be gradually changed. Further, in the first and second embodiments, the elastic coating film 16 was formed on the outer surface of the porous PTFE tube 14 to make it watertight and airtight. The tube may be made of polymer resin such as a tube, a polyurethane tube, or a heat-irradiated polyethylene tube. In addition, the elastic coating film 1 used in the first, second, and third embodiments
6 and 18 may be any material having rubber elasticity, such as fluorine rubber, chloroprene rubber, butadiene rubber, butadiene/styrene rubber, polyurethane rubber, or natural rubber.

As explained above, according to the present invention, even if the curved tube of the insertion section is greatly curved, the reinforcing tubular members of the insertion channel tube in the corresponding region are closely arranged, so that they will not shift. It does not buckle or become flat. Therefore, the treatment instrument can be smoothly inserted into the curved tube without getting caught. Furthermore, the arrangement of the reinforcing tubular members is not disrupted, and their durability can be improved. In addition, since the reinforcing tubular members in the parts corresponding to the flexible tubes are sparsely arranged, they ensure bonding with the tube material, etc., and prevent peeling on the curved tube side. Strength can be improved accordingly.

[Brief explanation of drawings]

FIG. 1 is a plan view of an endoscope to which the first embodiment of the present invention is applied, FIG. 2 is a sectional side view of a tube for the insertion channel, and FIG. 3 is a side view of a blade used in the tube. Fig. 4a, b
are an enlarged surface view of the main part of the blade, and the fifth
The figure is a side view of a blade according to a second embodiment of the present invention.
FIG. 6 is a side sectional view of a tube for an insertion channel according to a third embodiment of the present invention. 1... Endoscope, 3... Insertion section, 5... Flexible tube,
6... Curved tube, 14... Tube for insertion channel, 17... Blade, 19... Metal wire.

Claims (1)

[Claims] 1. A tube for an endoscope insertion channel that is inserted into an insertion section having a curved part and a flexible part and is attached with a reinforcing tubular member made of a knitted elongated material, wherein the reinforcing tubular member is A tube for an insertion channel of an endoscope, characterized in that the elongated material is arranged more densely in at least a part of the curved part of the insertion part than in other parts.