KR101258779B1 - Endoscopy aids turning direction - Google Patents

Abstract

The endoscope is bent at an angle of 120 ° after inserting the endoscope into the inside of the bifurcation when the endoscope enters the endoscope into the bifurcation where the duodenum and the placement position are disposed at an angle of more than a right angle. The present invention relates to an endoscopic directional turning assist aid for guiding the insertion of an endoscope into a bile duct by guiding the endoscope's curvature at a larger angle, and more specifically, The rotary knob is coupled to a fixing pipe coupled to an upper end of the outer tube. The rotary knob is exposed to the outside through a space formed between the inner and outer tubes on the rotary knob, The wire fixed to the lower end of the coil is wound in accordance with the rotation of the rotary knob, And when the wire is loosened by the reverse rotation of the rotary knob, the endoscope inserted into the dual tube is restored to its original shape by the elastic restoring force and the restoring force of the inner and outer coil ends, Due to its characteristics, the endoscope which is not bent properly is inserted into the inside of a separate swing support so as to be inserted into organs of the human body, and the end is pulled according to the forward and reverse rotation of the rotary knob.

Description

Endoscopy aids turning direction < RTI ID = 0.0 >

In particular, the present invention relates to an endoscopic directional turning aid, and more particularly, to an endoscope turning aiding aid which, when the endoscope is inserted into an endoscope into an inside of a bile duct arranged at an angle of at least a right angle with the duodenum, To guide the endoscopic gyration at an angle larger than the inherent adjustment angle of the endoscope, so that the entry of the endoscope into the biliary can be easily and accurately grasped.

Endoscopes in the medical field are used to examine the inside of the human body (stomach, bronchus, esophagus, large intestine, small intestine, etc.) by using a small camera without having to open or incise the body such as surgery or autopsy Current endoscopes are being extended to various industrial fields such as not only in medical field but also in observing the inside without observing the dismantling of precision machinery or observing abnormality inside the pipe.

In a general endoscope device, a camera is mounted on the tip of a bending device. Inside the bending device, a wire for transmitting an image data, a wire for supplying power to the camera, And an adjustment wire for adjusting the bending of the bending device are incorporated.

When the camera is inserted into a specific region of the human body or an observation destination of a mechanical device, the endoscope apparatus having such a structure is used to change and adjust the photographing direction or angle of the camera by pulling the adjustment wire when the camera reaches a proper position .

Endoscopy is a medical device designed to allow the internal organs or body cavity to be seen directly. It is a device designed to inspect and insert a machine into organs that can not directly see lesions without surgery or autopsy. Such endoscopes generally include bronchoscopy, esophagus, stomach, duodenal, rectal, cystoscopy, laparoscopic, thoracoscopic, mediastinal, and cardiac.

In order to confirm the inner wall of the bile duct by inserting the endoscope through the stomach, the endoscope of the conventional endoscope as described above is formed at a right angle with respect to the stomach, so that the endoscope is not bent toward the bile duct, There is a problem that a lot of regions are generated and accurate perspective can not be obtained.

In addition, even when the endoscope is inserted into the bile duct, when the endoscope is pushed into the bile duct, the force of the endoscope is transmitted to the entrance of the bile duct without the support mechanism for dispersing or supporting the pushing force Therefore, there is a problem that it is difficult to perform the procedure because of the difficulty of the procedure for confirming that the sphincter is severely ruptured or the secondary damage or contamination occurs.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and it is an object of the present invention to provide an endoscopic endoscope, And an endoscopic directional turning auxiliary member in which an end is pulled and bent or loosened to be linearly restored.

Another object of the present invention is to provide a biliary device which can be bent at an angle of 120 DEG which is larger than a bending angle of the endoscope itself by being pulled according to forward and reverse rotation of the rotary knob, The area of the blind spot for confirming the biliary tract is reduced, and the lesion on the inner wall of the biliary canal can be easily confirmed through the stomach.

It is still another object of the present invention to provide an endoscopic apparatus capable of simply rotating the direction of the endoscope inserted into the inside of the dual tube by pulling the wire fixed to the end of the dual tube by the rotation of the rotary knob, So that a separate operating force is not required because the dual tube portion of the dual tube of the dual tube and the self-elastic force of the endoscope return to the straight line.

In order to achieve the above-mentioned object, the present invention provides a pivoting anchor for allowing a user to enter an inside of a biliary canal by swinging the end of an endoscope to check the wall surface of the biliary duct, The inner tube and the outer tube of the dual tube are formed by inserting an inner tube having an inner and outer coil ends extended into an outer tube having an exposing hole formed therein at a lower end thereof to form a spacing space, And an endoscope hole passing through the center of the syringe thread or the distal end is formed at an upper end of the fixation tube, and a fixation tube having a through hole is coupled and fixed to one side of the fixation tube, And a winding groove formed on an upper surface of a tip end of the rotary knob, the rotary knob having one end fixed to the winding groove of the rotary knob, And a wire fixed to a lower end of the outer coil is formed by exposing the wire through the wire hole formed at the time when the outer coil end of the outer tube starts after passing through the through hole of the fixing pipe and passing through the spacing space, When the rotary knob is rotated while being inserted into the endoscope hole of the rotary knob, the inside of the inner tube, and the exposed hole of the outer tube, the wire is wound around the winding groove, and the outer coil end is pulled while the inner coil end and the endoscope end are pulled together Wherein the endoscope is rotated so that the direction of sight of the endoscope is turned and the rotation knob is rotated in the opposite direction to restore the elastic force of the endoscope and the elastic force of the inner and outer coil ends.

As described above, according to the present invention, by inserting the endoscope which does not bend properly into the inside of a separate turning aid, the endoscope can be inserted into organs of the human body and the end of the endoscope can be bent or loosened according to forward and reverse rotation of the rotary knob, . ≪ / RTI >

The distal end is pulled by the forward and reverse rotation of the rotary knob to be bent at an angle of 120 °, which is larger than the bending angle of the endoscope itself. Thus, it is easy to enter the biliary duct, and at the same time, The area of the biliary duct can be reduced and the affected part of the inner wall of the biliary can be easily identified through the stomach.

In addition, since the wire fixed to the end of the dual tube is pulled by the rotation of the rotary knob, the direction of the endoscope inserted into the inside of the dual tube can be simply pivoted. By rotating the rotary knob in the opposite direction, The tube portion and the endoscope are returned to the straight line by the self-elastic force of the endoscope, so that no separate operating force is required.

1 is an exploded perspective view showing an endoscopic directional turning auxiliary member according to the present invention,
FIG. 2 is an exploded perspective view showing an endoscopic directional turning auxiliary member according to the present invention,
FIG. 3 is an engaging sectional view showing an endoscopic directional turning auxiliary member according to the present invention,
FIG. 4 is a sectional view of the endoscopic directional turning auxiliary member according to the present invention in an operating state,
5A is a partially enlarged view of a single type wire according to the present invention,
FIG. 5B is a partially enlarged view showing a twisted wire according to the present invention,
6 shows an example in which a plurality of loop wires are arranged at inner and outer coil ends according to the present invention,
7 shows an example in which the wire according to the present invention is directly connected to the end of the outer tube through the spacing space,
8 is a surgical state view of the endoscopic directional turning aid according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1 and 8, the endoscopic swinging aid according to the present invention is introduced through the gastrointestinal tract 200 and the duodenum of the human body to swing the end of the endoscope 300 in order to confirm the wall surface in the bile duct 201 The inner tube 11 is inserted into and bonded to the inside of the outer tube 12 to form an integral dual tube 10 and the inner tube 11 is inserted between the inner and outer coil ends 11a and 12a (30) and the rotating body (40) by the rotation of the rotating body (40) coupled with the holder (30) coupled to the upper part of the dual tube (10) The wire 20 is connected to the operation port 50 which moves up and down to form the endoscopic revolving dial 100. [

1 and 2, the dual tube 10 includes an inner tube 11 having an inner coil end 11a integrally formed at one end thereof for turning, an outer coil end 12a formed integrally with the inner tube 11a, And then fixed to the inner surface of the outer tube 12 by adhesion.

That is, the portion integrally connected with the inner and outer coil ends 11a and 12a of the dual tube 10 is formed of a rigid material, and the outer and inner coil ends 11a and 12a, And stages (11b) and (12b).

The inner tube 11 is in the shape of a pipe, and the photographing portion of the endoscope 300 is exposed at the lower end.

Between the inner tube 11 constituting the dual tube 10 and the inner and outer rigid ends 11b and 12b of the outer tube 12, blades B woven in the form of a mesh are inserted together, .

The inner and outer coil ends 11a and 12a of the inner and outer tubes 11 and 12 are wound in a coil shape having a flat cross section, And the other part is formed by impregnating the blade.

In addition, it is preferable that the material of the inner tube 11 is made of Teflon, which is known as PTFE (polytetrafluoroethylene) in the present invention.

Meanwhile, it is preferable that the material of the outer tube 12 is made of elastic material such as PEBAX (polyamide thermoplastic elastomer) in the present invention.

The wire 20 is passed through the inner and outer coil ends 11a and 12a and is passed through the outer tube 12 at a portion of the outer coil end 12a and exposed to the outside, As shown in FIG.

On the other hand, the upper and lower ends of the outer coil 12a of the outer tube 12 of the dual tube 10 to which the wire 20 is passed and which are exposed to the outside are fixed to the upper and lower ends of the hard band 13 ).

That is, the rigid band 13 surrounds and connects the portion where the outer coil 12a of the outer tube 12 and the outer rigid end 12b are connected. The rigid band 14 is connected to the outer tube 12, And the lower end of the outer coil 12a.

A wire hole 13a through which the wire 20 passing through the outer tube 12 is exposed is formed on the rigid band 13. An end of the outer ear 20 is formed on the outer circumferential surface of the rigid band 14, Knot holes 14a are formed by weaving and knotting.

That is, the outer tube 12 is prevented from being damaged by friction at the portion where the wire 20 is passed by the rigid band 13 and the outer tube 12 is fixed at the fixed portion of the wire 20 by the rigid band 14. [ ) Is prevented from being damaged.

As shown in FIGS. 5A and 5B, at this time, the wire 20 may be composed of one or more strands twisted and twisted.

That is, the surface of the wire 20 may be coated with a polyurethane coating layer 21 so as to minimize friction with the rigid band 13 or the blade B when the wire 20 is pulled or pulled.

6, the ring wires 60 are bundled at equal intervals along the length of the outer coil end 12a so as to be wired at both ends to form a loop 61 ).

The end of the wire 20 exposed to the outside of the outer coil 12a is passed through the plurality of the rings 61 and then is bundled with the hard band 14 coupled to the lower end of the outer coil 12a And fixed to the ring 61 by being tied.

7, in another embodiment, the wire 20 has one end fixed to the actuator 50 and the other end passed between the inner and outer tubes 11 and 12, The lower end of the outer coil end 12a of the tube 12 may be exposed through the lower end of the tube 12 to be connected and fixed to the rigid band 14. [

1 and 2, the holder 30 and the rotating body 40 are rotated by rotation of the rotating body 40 which is idly coupled with the holder 30 coupled to the upper portion of the dual tube 10, The wire 20 is connected to the operating member 50 which moves upward and downward in a state of being helically fastened.

At this time, the holder 30 is formed with a protrusion 31 protruding toward the center on the cylindrical inner circumferential surface.

In addition, the holder 30 has a female helical end 32 formed on the inner circumferential surface on the lower side of the projection 31.

In addition, the holder 30 includes a coupling end 33 to which the dual tube 10 is inserted and coupled to the inner peripheral surface of the lower side of the female helical end 32.

The rotating body 40 has a fastening end 45 formed at the center of the lower surface of the rotating end 41 and spaced apart from the fitting end 42 in the shape of a rectangular tube, do.

However, the rotating body 40 is formed with a through hole 46 through which the endoscope 300 passes at the center of the rotation end 41 and the fitting end 42.

Next, a wire 20 is connected and fixed to a lower end of the actuating member 50, and a male end 51 is formed on an outer circumferential surface of the female screw end 32 to be screwed.

The operating member 50 includes an insertion hole 52 through which the endoscope 300 passing through the insertion hole 42 is inserted and the insertion end 42 is inserted.

At this time, the fitting hole 52 is formed in the shape of a square hole so that the fitting end 42 of a rectangular tube shape is inserted, and the rotational force when the rotating body 40 rotates is transmitted through the fitting end 42 to the operating hole 50 So that the operating member 50 is rotated.

4, when the rotating body 40 is rotated after inserting the endoscope 300 through the dual tube 10, the rotating body 40, and the operating member 50, the operating member 50 The wire 20 is pulled when the holder 30 and the rotating body 40 are moved upward by the spiral fastening so that the ends of the outer coil ends 11a and 12a and the endoscope 300 are bent at 120 degrees, And is easily inserted into the inside of the bile duct 201 generated at an angle of 120 °.

On the other hand, when the rotating body 40 is rotated in the opposite direction, the pulling force of the wire 20 is released, and the outer coil ends 11a, 12a and the endoscope 300 are restored to a straight line state.

Hereinafter, the operation and operation of the present invention will be described.

1, 5, and 7, the endoscopic revolving tool 100 is used to determine the state of the endoscope 300 on the inner wall of the bile duct 201 connected to the stomach 200 of various organs of the human body. As an example, will be described.

In order to confirm the inner wall of the bile duct 201 by inserting the endoscope 300 through the gastrointestinal tract 200 and the duodenum, the gastrointestinal 200 and the bile duct 201 are positioned orthogonally to each other, The distal end is not bent toward the biliary duct 201, so that it is difficult to precisely look at it. Even if it is bent, a large area of a blind spot is generated, and precise viewing is impossible.

When the end of the endoscope 300 is inserted into the biliary duct 201, when the endoscope 300 is pushed in by an unreasonable force, the biliary duct 201 is ruptured or damaged, It is difficult to perform the procedure because of the high degree of difficulty of the procedure for confirmation.

In order to use the endoscopic revolving dial 100, the female thread 32 of the holder 30 and the distal end 51 of the actuating rod 50 are screwed together and the actuating rod 50 is inserted into the holder 30, As shown in FIG.

The clamping end 45 of the upper rotating body 40 is inserted into the holder 30 and the clamping end 42 is fitted into the through hole 46 of the actuating member 50, The rotary body 40 is pressed and assembled to the holder 30 so that the projections 31 are inserted into and engaged with the rotary bodies 43 and 43.

Then, the upper end of the wire 20 passing through the dual tube 10 is fixed to the lower end portion of the operating member 50 by using attachment or separate fastening means.

Next, the upper end of the dual tube 10 is inserted into the coupling end 33 of the holder 30 and is fixed by adhesion to complete the endoscope vortex 100.

In order to perform imaging using the endoscopic revolving dial 100, the end of the lens for photographing the endoscope 300 is inserted into the through hole 46 of the rotating body 40, (52) and the inner tube (11) so as to be exposed to the end.

When the rotatable end 41 of the rotator 40 is held by hand and rotated in one direction while the endoscope 300 is coupled with the rotator 40, And is idly inserted in the groove 43.

The rotation of the rotating body 40 is transmitted to the operating member 50 through the fitting end 42 so that the operating member 50 is moved upward or downward along the arm spiral 32 .

That is, when the operating member 50 is raised by the rotational force of the rotating body 40, the wires 20 are lifted together to pull the outer coil end 12a and the inner coil end 11a and the endoscope 300, So that the endoscope 300 is rotated in the direction of sight of the endoscope 300. In the present invention, the endoscope 300 is turned at an angle of 120 ° between the duodenum and the bile duct 201.

That is, when the rotating body 40 is rotated so that the operating member 50 is raised upward, the wire 20 is pulled so that the ends of the outer coil end 12a, the inner coil end 11a, and the endoscope 300 are pulled together The direction in which the lens 301 of the endoscope 300 faces is changed.

As the end of the endoscope 300 is bent together with the inner and outer coil ends 11a and 12a, the endoscope 300 can be easily inserted into the bile duct 201 while being inserted through the stomach 200 and the duodenum, There is a characteristic that a condition can be simply watched by a practitioner.

Conversely, when the rotary member 30 is rotated so that the operating member 50 is lowered downward, the male or female end 51 is screwed to the lower portion in a state of being screwed with the female screw end 32, 20 are pulled by the self-elastic force of the outer coil 12a, the inner coil 11a and the endoscope 300 so that the direction of the lens 301 of the endoscope 300 is naturally restored to a straight line .

Thereby, the end of the endoscope 300 is supplementarily bent by using the endoscope revolving tool 100, so that the endoscope can be easily seen at a desired position. Also, when the endoscope 300 is used, It is characteristic.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

10: Dual tube 11: Neve dual tube
11a: Inner coil end 11b: Inner hard end
12: outer tube 12a: outer coil section
12b: external rigid end 13: rigid band
13a: wire hole 14: hard band
14a: Knot hole 20: Wire
21: Coating layer
30: holder 31: projection
32: Female thread 33: Bonded end
40: rotating body 41: rotating stage
42: insertion end 43: projection groove
45: fastening end 46: through hole
50: Operation Sphere 51: Suunas or Fleet
52: insertion hole 60: loop wire
61: collar 100: endoscopic turning orifice
200: stomach 201: bile duct
300: endoscope 301: lens
B: blade

Claims (6)

A swinging aid for allowing the endoscope 300 to swing through the stomach 200 of the human body and the duodenum to confirm the wall surface of the bile duct 201,
An inner tube 11 having an inner coil end 11a formed integrally at one end thereof is inserted into an outer tube 12 having an outer coil end 12a formed integrally at an end thereof and then a dual tube 10 ),
The wire 20 is passed through the inner and outer coil ends 11a and 12a and is exposed to the outside through the outer tube 12 at the portion of the outer coil end 12a, And,
The holder 30 and the rotating body 40 are rotated by the rotation of the rotating body 40 coupled to the holder 30 coupled to the upper portion of the dual tube 10, The wire 20 is connected to the wire 50,
After the endoscope 300 is inserted through the dual tube 10, the rotating body 40 and the operating member 50 and the rotating body 40 is rotated, the operating member 50 is rotated by the holder 30 and the rotating body The wire 20 is pulled so that the outer coil ends 11a and 12a and the endoscope 300 are bent so as to be inserted into the biliary duct 201, And when the wire is rotated in the opposite direction, the pulling force of the wire (20) is released and the outer coil ends (11a) (12a) and the endoscope (300) are restored to a straight state. phrase. The holder (30) according to claim 1, wherein the holder (30) is provided with a projection (31) projecting toward the center on a cylindrical inner circumferential surface, an arm helical edge (32) is formed on an inner peripheral surface of a lower side of the projection The inner end surface of the female helical end 32 is formed with a coupling end 33 into which the dual tube 10 is inserted,
The rotating body 40 is formed with a fastening end 45 having a protruding groove 43 formed on the outer circumferential surface so as to be spaced apart from a fitting end 42 of a rectangular rod shape formed at the center of the lower surface of the rotating end 41, A through hole 46 through which the endoscope 300 passes is formed at the center of the rotation end 41 and the fitting end 42,
A wire 20 is connected and fixed to a lower end of the operating member 50 and a male or female end 51 is formed on an outer circumferential surface of the female screw end 32 to be engaged with the female screw end 32, And an insertion hole (52) through which the endoscope (300) passes through the through hole (46). [3] The apparatus according to claim 1, wherein the wire (20) is composed of a single or two or more strands twisted and twisted,
A polyurethane coating layer 41 is coated on the surface of the wire 20,
The upper and lower ends of the outer coil 12a of the outer tube 12 of the dual tube 10 to which the wire 20 is passed and exposed to the outside are fixed to the upper and lower ends of the outer tube 12, Respectively,
It is possible to prevent the outer tube 12 from being damaged by friction at the portion where the wire 20 is passed by the hard band 13 and to prevent the outer tube 12 from being damaged by the hard band 14, And an end portion of the endoscopic turning support member is configured to prevent breakage. The method as claimed in claim 3, wherein the loop wire (60) is folded in the form of an '8' so that the loop (61) is formed at both ends by winding around the outer circumferential surface of the rigid end (14) coupled to the lower end of the outer coil ,
Wherein an end of the wire (20) exposed to the outside of the outer coil end (12a) is fixed to the loop (61) of the loop wire (60) by binding it to the loop (61). [6] The method of claim 4, wherein the loop wires (60) are bundled at a plurality of equal intervals along the length of the outer coil end (12a) to form a loop (61)
The end of the wire 20 exposed to the outside of the outer coil end 12a is passed through a plurality of rings 61 and then is hooked to the rigid band 14 coupled to the lower end of the outer coil end 12a 61) of the endoscope body (1). 2. The endoscopic directional turning aid according to claim 1, wherein the inner and outer coil ends (11a) and (12a) are configured to be bent at 120 degrees without being pulled when the wire (20) is pulled.

Images