JP2018180298A - Self-running type endoscope - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a self-running type endoscope in which a quick movement is possible with a simple configuration.SOLUTION: A self-running type endoscope 3 comprises: a tip end part 11; a self-running mechanism unit 20; and an insertion part 12. The self-running mechanism unit 20 comprises a holding unit 30A that has: a front pipe 33A that has a foam fluorine tube body 33, which has a gap enabling ventilation of an interior surface side and an exterior surface side, is freely deformable and is set to a predetermined length,; an expansion unit 31A that is slidably arranged on an outer peripheral surface of the foam fluorine tube body 33, and is formed to be freely expandable with a plurality of slits 31s provided along a center axis; a bellows 32A that is arranged on the exterior surface of the foam fluorine tube body 33, foldable in a center axis direction and has an air leakage prevented; and a holding space S1 to which air is supplied via a connection tube 61b. The self-running type endoscope has the holding part 30A on a tip end part 11 side and on an insertion part 12 side, respectively.SELECTED DRAWING: Figure 2

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a self-propelled endoscope that self-propelled toward a deep portion of a pipe.

  Conventionally, various moving devices for moving in a narrow space have been proposed and put to practical use for the purpose of inspecting the inside of a building, inspecting and maintaining the inside of a machine, or searching in the event of a disaster.

  For example, Patent Document 1 discloses an in-pipe self-propelled device which is self-propelled in a pipe such as an industrial pipe line or a living body pipe line. The self-propelled device in the tube is elastically deformed in the radial direction by receiving supply of pressurized fluid and generates an elastic force in the axial direction, an elastic actuator, a mounting member provided at both end portions of the elastic actuator, and the mounting member An elastic member that applies an urging force between the mounting members in a direction opposite to the direction in which the elastic actuator contracts and is attached to both of the mounting members, and expands by receiving supply of pressurized fluid and locks onto the inner surface of the conduit And a locking unit.

  The in-pipe self-propelled device inserts the inserted object into the insertion path of the moving unit, and performs locking and releasing of the endoscope by the holding means in accordance with the expansion and contraction operation of the moving unit, thereby obtaining the endoscope It can be made to move forward.

  Specifically, the transfer unit is initially inserted into the duct to be examined with the balloons contracted. At the time of advancing, first, pressurized fluid is supplied to the front balloon to be expanded and pressed against the inner wall of the conduit and fixed. Next, holding this state, the pressurizing fluid is supplied to the elastic actuator to radially expand the actuator.

By this, the actuator is axially contracted against the biasing force of the elastic member. Then, the rear attachment member is moved forward by the contraction force. After the forward movement of the rear attachment member is completed, the rear balloon is inflated and pressed against the inner wall of the conduit and fixed. Then, keeping this state, the pressurized fluid is removed from the front balloon and the elastic actuators in order. Then, the front attachment member is moved forward by the biasing force of the elastic member.

After this movement, the front balloon is again inflated and pressed against the inner wall of the duct and fixed, and the pressurized fluid of the rear balloon is removed, and the pressurized fluid is supplied to the elastic actuator to radially expand it. The mounting member is moved forward. By repeating these operations, the mobile unit advances in the pipeline.
The moving unit moves backward if pressure is applied to the elastic actuator and the front and rear balloons in the reverse order.

Japanese Patent Application Laid-Open No. 04-002565

  However, in Patent Document 1 described above, the moving unit supplies pressurized fluid to the elastic actuator to expand the actuator while contracting in the axial direction against the biasing force of the elastic member, and the mounting member by the contraction force thereof Is moving. As described above, since the actuator is expanded and contracted, the amount of one movement is reduced. For this reason, it was difficult to obtain a desired moving speed. In addition, the pressure applied to the elastic actuator is increased in order to expand the elastic actuator against the biasing force of the elastic member.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a self-propelled endoscope which can move rapidly in a pipe and can pass an elbow with a simple configuration.

  A self-propelled endoscope according to one aspect of the present invention includes a distal end portion, a self-propelled mechanism portion, and an insertion portion, and the self-propelled mechanism portion has a gap that allows air to flow from the inner side to the outer side. An expandable tubular body provided with a plurality of slits along a central axis which is disposed on an outer peripheral surface of the tubular body having a deformable and predetermined length, and slidably provided on the outer circumferential surface of the tubular body. Holding portion having a portion, a bellows foldable in the central axis direction disposed on the outer peripheral surface of the tube and preventing air leakage, and a holding space to which air is supplied via a connection tube And the holding portions are respectively provided on the tip end side and the insertion portion side.

  According to the present invention, it is possible to realize a self-propelled endoscope which can move rapidly in a pipe and can pass an elbow with a simple configuration.

A diagram for explaining a self-propelled endoscope apparatus The figure explaining the self-propelled mechanism part provided in the self-propelled endoscope A diagram for explaining the first connecting member A diagram for explaining the second connecting member A diagram for explaining the third connecting member Diagram for explaining the front holding unit Diagram for explaining the relationship between the controller and the self-propelled mechanism The figure which compares and demonstrates the state at the time of pressure reduction of the front expansion part with which the front holding | maintenance part was equipped, and the state at the time of pressurization. The figure which compares and demonstrates the state at the time of pressure reduction of the back expansion part with which the back holding | maintenance part was equipped, and the state at the time of pressurization. The figure which compares and demonstrates the state at the time of pressure reduction of the expansion-contraction expansion-contraction bellows provided in the expansion-contraction part, and the state at the time of pressurization The figure explaining the front pipe comprised with the spiral pipe and the sealing member The figure explaining the self-propelled mechanism part which has a holding | maintenance part containing the front pipe | tube comprised by the helical pipe and the sealing member The figure which shows the state which inserted and arranged the insertion part which has a self-propelled mechanism part in piping. A diagram showing a state in which the forward self-propelled movement is started and the rear expansion portion is held and fixed to the pipe A diagram for explaining a state in which a telescopic bellows is pressurized and stretched forward A diagram showing a state in which the distal end surface is moved forward by a distance L2 with respect to the original state with the telescopic bellows in a predetermined extended state. The figure which demonstrates the state which hold | maintained and fixed the front expansion part with respect to piping, and hold | maintained the tip surface which moved in the moved position. The figure which shows the state which made the diameter of a back expansion part shrink, and made the expansion-contraction bellows shrink to original length, and the back expansion part was moved to the front by distance L2 A diagram showing a state in which air is supplied again into the rear holding space S3 and the rear expansion portion is held and fixed to the pipe again. The figure which shows the state by which the extension part of the original state, the front holding | maintenance part of the original state, and the front-end | tip part are arrange | positioned on the front side of the back expansion part hold-fixed by piping. The figure which shows the state in which the insertion part which has a self-propelled mechanism part was inserted in the deep part in piping. A diagram showing a state in which the backward self-propelled movement is started and the forward extension is held and fixed to the pipe A diagram for explaining a state in which a telescopic bellows is pressurized and stretched backward. The figure which shows the state which the expansion-contraction bellows became a predetermined expansion | extension state, and the largest expansion part of the back expansion part moved back distance L2 with respect to the original state The figure which demonstrates the state which hold | maintained and fixed the rear expansion part with respect to piping, and hold | maintained and moved the largest expansion part of the rear expansion part which moved. The figure which shows the state which made the diameter of the front expansion part shrink, and made the expansion-contraction bellows shrink | contract to original length, and the tip surface was moved to back L2 distance. A diagram showing a state in which air is again supplied into the front holding space S1 and the front extension is again held and fixed to the pipe. The figure which shows the state by which the extension part of the original state, the back holding part of the original state, and the insertion part are arrange | positioned at the back side of the front expansion part hold-fixed by piping. Diagram for explaining another configuration example of the self-propelled mechanism unit It is a Y11B-Y11B line sectional view of Drawing 11A, and a figure explaining composition of a holding part It is a Y11C-Y11C line sectional view of Drawing 11B, and a figure explaining an enlarged diameter part which constitutes attaching part. Diagram for explaining the operation of the holding unit Diagram for explaining another configuration example of the self-propelled mechanism unit The figure explaining the composition of the attaching part with which the self-propelled mechanism part of Drawing 12A is provided The figure explaining the effect | action of the holding | maintenance part with which the self-propelled mechanism part of FIG. 12A is provided The figure explaining the other example of composition of a self-propelled mechanism part The figure explaining the structure and effect | action of a holding part with which the self-propelled mechanism part of FIG. 13A is provided A diagram for explaining another configuration of the extension unit provided in the self-propelled mechanism unit A diagram for explaining another configuration of the extension unit provided in the self-propelled mechanism unit A diagram for explaining an expanded portion provided with a spherical surface portion Diagram for explaining the action of the expanded portion provided with the spherical surface portion The figure explaining the front attaching part which assists passage of the elbow tube of a tip part Diagram for explaining the action of the front holding unit The figure explaining the self-propelled mechanism part which provided the expansion-contraction part for elbows in the tip side The figure explaining the self-propelled mechanism part which provided the coil part in the tip side The figure explaining the self-propelled mechanism part which has an elastic projection in the tip side

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In each of the drawings used in the following description, in order to make each component have a size that can be recognized in the drawings, there is a case where the scale is different for each component. That is, the present invention is not limited only to the number of components described in these figures, the shapes of the components, the ratio of the sizes of the components, and the relative positional relationship between the components.

As shown in FIG. 1, a self-propelled endoscope apparatus 1 of the present invention includes an apparatus main body 2 and a self-propelled endoscope 3. The device body 2 includes a frame 4, a drum 5, a display device 6, and an operation unit 7. Reference numeral 8m is a connection port, to which an air supply tube 8c extended from the compressor 8 which is an external device is connected. The code | symbol 9 is a controller attachment or detachment part.
The self-propelled endoscope 3 mainly includes a distal end portion 11, a self-propelled mechanism portion 20, an insertion portion 12, and a controller 13 in order from the distal end side. The code | symbol 14 is an air connector, the code | symbol 15 is an electrical connector, the code | symbol 11a is an observation part, and the code | symbol 11b is a light emitting element.

  The controller 13 is attachable to and detachable from the controller attachment unit 9. The light emitting elements 11 b are, for example, LEDs, and a plurality of light emitting elements 11 b are arrayed around the observation unit 11 a. The distal end portion 11 is a hard member and incorporates an imaging device. Although not shown, signal lines extend from the imaging device. Electric wires for supplying power are connected to the light emitting elements.

  As shown in FIG. 2, the self-propelled mechanism unit 20 includes a front holding unit 30A, an expansion and contraction unit 40, and a rear holding unit 30B in order from the front side. The front holding portion 30A mainly includes an expansion member 31A and a holding bellows 32A. The telescopic portion 40 mainly includes a telescopic bellows 41. The rear holding portion 30B mainly includes a rear extension 31B and a rear bellows 32B.

Reference numeral 51 denotes a first connecting member, which connects the front holding portion 30A and the stretchable portion 40. The code | symbol 52 is a 2nd connection member, and connects the expansion-contraction part 40 and the back holding part 30B. The code | symbol 53 is a 3rd connection member, Comprising: The back holding part 30B and the insertion part 12 are connected.
The code | symbol S1 is front holding space, Comprising: It is space provided in the front holding part 30A. The code | symbol S2 is expansion-contraction space, Comprising: It is the space provided in the expansion-contraction part 40. FIG. The code | symbol S3 is back holding space, Comprising: It is space provided in the back holding part 30B.

The connection members 51, 52, 53 will be described with reference to FIGS. 3A to 3C.
As shown in FIGS. 3A to 3C, in the first connecting member 51, the second connecting member 52, and the third connecting member 53, wire penetrating through holes (hereinafter abbreviated as wire holes) 54, for example, 3 Two female screw through holes 55a, 55b, 55c are provided at predetermined positions. The above-described electric wires and signal wires are inserted into the wire holes 54.

  As shown in FIG. 3A, an external thread 56m of the joint 56 is screwed into the rear opening of the first through hole 55a with the internal thread of the first connection member 51 (this joint will be referred to as 56r1). On the other hand, a closing screw 57 for closing the through hole is screwed on one side of the front opening side or the rear opening side of the second through hole 55b with the second internal thread and the through hole 55 with the third internal thread. . In the present embodiment, the closing screw 57 is screwed to the front opening side. The code | symbol 51f is a 1st connection member front attachment part, and the code | symbol 51r is a 1st connection member back attachment part.

  As shown in FIG. 3B, a joint 56 is screwed into the front opening of the first female threaded through hole 55a of the second connection member 52 (this joint is described as 56f 2), and the first female threaded through hole A joint 56 is screwed into the rear opening of the hole 55a (this joint is described as 56r2). Further, a joint 56 is screwed into the rear opening of the second female threaded through hole 55b (this joint is described as 56r3). On the other hand, the closing screw 57 is screwed into the front opening of the third through hole 55c. Reference numeral 52f denotes a second connection member front attachment portion, and reference numeral 52r denotes a second connection member rear attachment portion.

  As shown in FIG. 3C, a joint 56 is screwed into the front opening of the first female threaded through hole 55a of the third connecting member 53 (this joint is described as 56f4), and the first female threaded through hole A joint 56 is screwed into the rear opening of the hole 55a (this joint is described as 56r4). Also, a joint 56 is screwed into the front opening of the second through hole 55b with the female screw (this joint is described as 56f5), and the joint 56 is through the rear opening of the through hole 55b with the second female screw. Screwed (this joint is described as 56r5). Further, a joint 56 is screwed into the rear opening of the third through hole 55c with a female screw (this joint is described as 56r6). In addition, the code | symbol 53f is a 3rd connection member front attachment part.

Each of the above-described joints is provided with an axial fluid hole 56h in addition to the male screw portion 56m.
Further, in the embodiment described above, the through hole of the connecting member which is the same member in which the wire hole 54 and the three female screw portion through holes 55a, 55b, 55c are provided at a predetermined position in advance is closed And the connecting members 51, 52, 53 are obtained.

  However, the first connecting member 51 is configured to have the wire hole 54 and the first female threaded through hole 55a, and the second connecting member 52 is the wire hole 54, the first female threaded through hole 55a, and the first female threaded hole. The third connecting member 53 includes the wire hole 54, the first female threaded through hole 55a, the second female threaded through hole 55b, and the third female threaded portion. The configuration may have an attached through hole 55c. This eliminates the need for the operation of providing the closing screw 57.

  In FIG. 2, reference numeral 61 denotes a front holding tube, reference numeral 61a denotes a front holding first connecting tube, and reference numeral 61b denotes a front holding second connecting tube. The code | symbol 62 is a tube for expansion-contraction, The code | symbol 62a is an expansion-contraction 1st connection tube. Reference numeral 63 is a rear holding tube.

  One end of the front holding tube 61 is connected to a joint 56 r 4 screwed to the third connecting member 53. The front end of the front holding first connecting tube 61a is connected to the joint 56r2 screwed to the second connecting member 52, and the end arranged at the rear of the front holding first connecting tube 61a is It is connected to the joint 56 f 4 screwed to the third connecting member 53. Further, an end portion of the front holding second connection tube 61b disposed on the front is connected to a joint 56r1 screwed to the first connection member 51, and an end disposed behind the front holding second connection tube 61b. The portion is connected to a joint 56 f 2 screwed to the second connection member 52.

  One end of the expansion and contraction space tube 62 is connected to a joint 56 r 5 screwed to the third connection member 53. Further, an end portion of the expandable first connection tube 62a disposed in front is connected to a joint 56r3 screwed to the second connection member 52, and an end portion disposed in the rear of the first connection tube 62a is a first end. It is connected to a joint 56 f 5 screwed to the third connecting member 53.

Then, one end of the rear holding space tube 63 is connected to a joint 56 r 6 screwed to the rear opening of the third female screw through hole 55 c of the third connecting member 53.
The front holding second connection tube 61b is attached with an extra length portion (not shown) of a predetermined length so as to achieve a desired slack state in the expansion space S2.

  That is, the extension length of the stretchable portion 40 is set to be approximately the same as that of the stretchable portion 40, and at the time of contraction, it is in a slack state inside the extension space 82. Further, electric wires are disposed in the wire holes 54 of the first connection member 51, the second connection member 52, and the third connection member 53, and are fixed by an adhesive or the like so as to have no gap. And the electric wire of the part of the expansion-contraction part 40 is set to the same extent as the length at the time of expansion | extension.

Each part which comprises the self-propelled mechanism part 20 is demonstrated.
First, the front holding portion 30A will be described with reference to FIGS. 2 and 4.
As shown in FIG. 4, the front holding portion 30A includes a front extension portion 31A, a front bellows 32A, a front pipe 33A, and a flange pipe 34. The flanged tube 34 has a tube portion 34a and a flange portion 34b and is set to a predetermined size. The flanged tube 34 is disposed between the front extension 31A and the front bellows 32A and integrally fixed.

The forward extension portion 31A is a tube made of an elastic resin such as polyurethane, acryl, nylon, etc., and provided with a plurality of slits 31s along the central axis Ca, in a direction orthogonal to the central axis Ca It is configured to be extensible. The reference numeral 31 c is a maximum expansion portion (abutment portion), and is formed to be located approximately at the center in the axial direction.
Reference numeral 31f is a first mounting surface, and reference 31r is a second mounting surface.

  The front bellows 32A is made of resin, for example, and can be folded in the direction of the central axis Ca to prevent air leakage. The front bellows 32A is set to a predetermined length, and the end surfaces thereof are configured as a bellows first fixed surface portion 32f and a bellows second fixed surface portion 32r.

  The front tube 33A is a tubular body and includes a foamed fluorine tube body 33, a tube first fixing portion 33f, and a tube second fixing portion 33r. The foamed fluorine tube body 33 has a predetermined slipperiness and is set to a predetermined length. A tube first fixing portion 33f is fixed at the front end of the foamed fluorine tube body 33, and a tube second fixing portion 33r is fixed at the rear end.

The foamed fluorine tube body 33 has a plurality of fine holes over the entire length. The fine holes are expanded by, for example, air being supplied to the tube inner hole to increase the internal pressure. Then, the air supplied to the inner hole of the tube is leaked outward by the minute holes being expanded.
That is, when the internal pressure increases, the foamed fluorine tube body 33 is provided with a gap which communicates the tube inner hole on the inner surface side with the outer surface outer side.

  A front extension 31A and a front bellows 32A are disposed on the outer peripheral surface of the front pipe 33A. The inner peripheral surface of the first attachment surface portion 31f of the front expanded portion 31A is closely fixed to the outer peripheral surface of the pipe first fixing portion 33f provided at the front end of the front pipe 33A by, for example, an adhesive. On the other hand, the inner peripheral surface of the second attachment surface 31r of the front expanded portion 31A is disposed slidably with respect to the outer peripheral surface of the front tube 33A.

  The inner peripheral surface of the pipe portion 34a of the flanged pipe 34 is integrally fixed in advance to the outer peripheral surface of the second attachment surface portion 31r of the front expanded portion 31A.

  The front side bellows fixing portion 32f of the front bellows 32A is integrally fixed to the rear end surface of the flange portion 34b of the flange pipe 34 integrally fixed to the front extension 31A disposed on the outer peripheral surface of the front pipe 33A. ing.

Therefore, the front side of the front bellows 32A is slidable relative to the outer peripheral surface integrally with the second attachment surface 31r side of the front extension 31A.
On the other hand, the rear side bellows fixing portion 32r of the front bellows 32A is integrally fixed to the outer peripheral surface on the rear side pipe fixing portion 33r side of the front tube 33A.

  As described above, the distal end hard member 11H constituting the distal end portion 11 is integrally fixed to the inner peripheral surface of the front side tube fixing portion 33f of the front tube 33A in which the front expanded portion 31A and the front bellows 32A are disposed. Be done. On the other hand, the first connecting member front mounting portion 51f of the first connecting member 51 is integrally fixed to the inner peripheral surface of the rear side pipe fixing portion 33r of the front pipe 33A.

  As a result, the front holding space S1 configured of the distal end hard portion 11H, the first connection member 51, the front pipe 33A sealing member 36, and the bellows 32A disposed on the outer peripheral side of the front pipe 33 is provided. The front holding portion 30A is configured.

Next, the stretchable portion 40 will be described with reference to FIG.
As shown in FIG. 2, the stretchable part 40 includes a stretchable bellows 41 and a coil 42. The telescopic bellows 41 is made of resin, for example, and can be folded in the direction of the central axis Ca substantially in the same manner as the front bellows 32A to prevent air leakage. Fixed surface portions 43f and 43r are provided at both ends of the telescopic bellows 41, respectively.

  The coil 42 is an elastic member and a coil spring having a predetermined elasticity. In the present embodiment, the stretchable bellows 41 and the coil 42 are integrally fixed. That is, the respective end outer peripheral surfaces of the coil 42 are integrally fixed to the respective end inner peripheral surfaces of the telescopic bellows 41. Therefore, while the expansion-contraction bellows 41 and the coil 42 extend integrally, they contract integrally.

  The end of the coil 42 on the side of the extension portion first fixing surface portion 43f of the coil 42 in which the expansion / contraction bellows 41 is integrated is integrally fixed to the outer peripheral surface of the first connecting member rear attachment portion 51r. Further, the extension portion first fixing surface portion 43f of the expansion / contraction bellows 41 is integrally fixed to the upright surface 51rs on the side of the first connecting member rear attachment portion 51r. On the other hand, the end on the extension portion second fixing surface portion 43r side of the coil 42 in which the expansion / contraction bellows 41 is integrated is integrally fixed to the outer peripheral surface of the second connecting member front mounting portion 52f. Further, the extension second fixing surface 43r of the expansion / contraction bellows 41 is integrally fixed to the rising surface 52fs on the side of the second connecting member front attachment 52f. By this, the expansion-contraction part 40 which has expansion-contraction space S2 is comprised.

Finally, the rear holding portion 30B will be described with reference to FIG.
As shown in FIG. 2, the rear holding portion 30B includes a rear extension 31B, a rear bellows 32B, a rear pipe 33B, and a flange pipe 34.
In the present embodiment, the rear expanded portion 31B and the front expanded portion 31A are the same member, the rear bellows 32B and the front flexible tube portion 32A are the same members, and the rear tube 33B and the front tube 33A are the same members.
Therefore, the components of the rear extension 31B, the rear bellows 32B, and the rear tube 33B are denoted by the same reference numerals as the components of the front extension 31A, the front bellows 32A, and the front tube 33A described above, and the description thereof is omitted.

  A rear extension 31B and a rear bellows 32B are disposed on the outer peripheral surface of the rear tube 33B. The inner peripheral surface of the first attachment surface portion 31f of the rear expanded portion 31B is closely fixed to the outer peripheral surface of the pipe first fixing portion 33f provided at the front end of the rear pipe 33B by, for example, an adhesive. On the other hand, the inner peripheral surface of the second attachment surface 31r of the rear expanded portion 31B is disposed slidably with respect to the rear outer peripheral surface of the rear tube 33B.

  The front side bellows fixing portion 32f of the rear bellows 32B is integrally fixed to the rear side end face of the flange portion 34b of the flange pipe 34 integrally fixed to the rear extension portion 31B disposed on the outer peripheral surface of the rear pipe 33B. .

As a result, the front side of the rear pipe 33B is slidable with respect to the outer peripheral surface on the rear side of the sealing member 36 in the same manner as the second attachment surface portion 31r of the rear expanded portion 31B. On the other hand, the rear side bellows fixing portion 32r of the rear bellows 32B is integrally fixed to the outer peripheral surface on the rear side tube fixing portion 33r side of the rear tube 33B.

  Then, as described above, the second connecting member rear mounting portion 52r of the second connecting member 52 is integrally formed on the inner peripheral surface of the front side pipe fixing portion 33f of the rear tube 33B provided with the rear expanding portion 31B and the rear bellows 32B. It will be fixed.

  On the other hand, the third connecting member front mounting portion 53f of the third connecting member 53 is integrally fixed to the inner peripheral surface of the rear side pipe fixing portion 33r of the rear pipe 33B. By this, the back holding part 30B which provided back holding space S3 is comprised.

  The front portion of the insertion portion 12 is fixed to the outer peripheral surface 53 o of the third connecting member 53. The front holding tube 61, the extension tube 62, the rear holding tube 63, the signal line (not shown), and the electric wire (not shown) are inserted into the inside of the insertion portion 12.

  As shown in FIG. 5, the controller 13 includes, for example, three valve units 17A, 17B, and 17C, a valve control board 18, an image control board 19 and the like in a housing 16. The code | symbol 17P is a coupling | joint, and the tube 14a extended from the air connector 14 and the connection tube 17a each extended from each valve unit 17A, 17B, 17C are connected. A supply tube (not shown) extending from the connection port 8 is connected to the air connector 14 to supply the gas supplied through the air supply tube 8c connected to the connection port 8m.

  The other end of the front holding tube 61 which has passed through the insertion portion 12 is connected to the first valve unit 17A, and the other end of the expansion tube 62 is connected to the second valve unit 17B. The other end of the rear holding tube 63 is connected to the unit 17C.

  According to this configuration, for example, when the first valve unit 17A is opened according to the control of the control device configured on the valve control board 18, for example, air in the compressor 8 is the forward holding tube 61, the forward first connection tube 61a, it is supplied into the front holding space S1 via the front second connecting tube 61b.

  As a result, the inside of the foamed fluorine tube body 33 is pressurized to expand the fine holes and a gap for enabling manual ventilation appears. As a result, the air leaking from the vicinity of the front expansion portion 31A is discharged outward. On the other hand, the air leaking from the vicinity of the front bellows 32A fills the inside of the front bellows 32A. As a result, the front bellows 32A is pressurized and stretched.

Then, as shown in the lower part of FIG. 6A, along with the expansion of the front bellows 32A, the front side bellows fixing portion 32f of the bellows 32A and the flange pipe 34 integrally fixed to the front extension portion 31A move L1 sliding forward Be done. By this sliding movement, the expansion amount of the front expansion portion 31A is expanded from the width (also referred to as a diameter) a in a pressure-reduced state and expanded to the width (diameter) b in a pressurized state.
The pressure inside the front holding space S1 is reduced, so that the front bellows 32A is contracted to return to the original state shown in the upper view of FIG. 6A.

  On the other hand, when, for example, the third valve unit 17C is opened according to the control of the control device, the air in the compressor 8 is supplied into the rear holding space S3 via the rear holding tube 63. As a result, as described above, the inside of the foamed fluorine tube body 33 is pressurized to expand the micropores, and the air leaking out from the vicinity of the rear bellows 32B presses the rear bellows 32B to be stretched.

As a result, as shown in the lower part of FIG. 6B, with the extension of the rear bellows 32B, the front bellows fixing portion 32f of the bellows 32B and the flange tube 34 integrally fixed to the rear extension 31B slide L1 forward. By moving, the expansion amount of the rear expansion portion 31B is expanded from the width a to the width b.
In addition, by decompressing the inside of the rear holding space S3, the rear bellows 32B is contracted and returns to the original state shown in the upper view of FIG. 6B.

  On the other hand, when, for example, the second valve unit 17B is opened according to the control of the control device, the air in the compressor 8 is supplied into the expansion space S2 via the expansion tube 62 and the expansion first connecting tube 62a. Ru. By this, the expansion-contraction bellows 41 is pressurized and starts expansion.

Here, the expansion-contraction bellows 41 expands the expansion-contraction bellows 41 and the coil 42 against the biasing force of the coil 42 as shown in the lower part of FIG. 6C by being expanded. Then, the tip surface of the first connecting member 51 moves by a distance L2 relative to the original state shown in the upper view of FIG. 6C.
The expansion bellows 32A is contracted by reducing the pressure in the expansion space S2 to return to the original state shown in the upper view of FIG. 6C.

  In the embodiment described above, the front holding portion 30A is provided with the front pipe 33A provided with the foamed fluorine tube body 33, and the rear holding portion 30B is provided with the rear pipe 33B provided with the foamed fluorine tube body 33. However, instead of the foamed fluorine tube body 33, the holding portions 30A and 30B may be configured using a spiral tube and a sealing member.

  The front holding portion 30A of the present embodiment shown in FIG. 7 includes a front expanded portion 31A, a front bellows 32A, a flanged pipe 34, and a spiral pipe 35 and a sealing member 36 that constitute the front pipe 35A. The sealing member 36 is a resin-made tubular member having a predetermined slip property, and is set to a predetermined size.

  The spiral tube 35 is, for example, a flexible pipe which can be deformed substantially in the same manner as a stand for lighting, and is set to a predetermined length. The spiral tube 35 has a gap that allows air to flow between the inner surface side space and the outer surface outer side, and at each end of the spiral tube 35, a spiral first fixing portion 35f and a spiral second fixing portion 35r are provided. It is provided.

  As shown in FIG. 8, a sealing member 36 serving as a sliding surface is provided on the outer peripheral surface of the helical tube 35 serving as the front tube 35A on the spiral first fixed portion 35f side while preventing gas such as air from leaking out. It is provided.

  A front extension 31A and a front bellows 32A are disposed on the outer peripheral surface of the front pipe 35A. Then, the front expanded portion 31A and the bellows first fixed surface 32f side of the front bellows 32A are disposed on the outer peripheral surface of the sealing member 36.

  The inner peripheral surface of the first attachment surface 31f of the front expanded portion 31A is closely fixed to the front outer peripheral surface of the sealing member 36 provided at the front end of the helical tube 35 by, for example, an adhesive.

On the other hand, the inner peripheral surface of the second attachment surface 31r of the front expanded portion 31A is disposed slidably with respect to the outer peripheral surface of the sealing member 36 provided on the helical tube 35.
The inner peripheral surface of the pipe portion 34a of the flanged pipe 34 is integrally fixed in advance to the outer peripheral surface of the second attachment surface portion 31r of the front expanded portion 31A.

The front side bellows fixing portion 32f of the front bellows 32A is integrally fixed to the rear end face of the flange portion 34b of the flange pipe 34 integrally fixed to the front extension 31A disposed on the outer peripheral surface of the helical pipe 35 ing.
Therefore, the front side of the front bellows 32A can slide on the outer peripheral surface of the sealing member 36 integrally with the second attachment surface 31r side of the front extension 31A.

  On the other hand, the rear side bellows fixing portion 32 r of the front bellows 32 A is integrally fixed to the outer peripheral surface on the rear side spiral fixing portion 35 r side of the helical tube 35.

  Then, as described above, the distal end hard member 11H constituting the distal end portion 11 is integrally fixed to the inner peripheral surface of the front spiral fixing portion 35f of the helical tube 35 in which the front expanded portion 31A and the front bellows 32A are disposed. Be done. On the other hand, the first connecting member front mounting portion 51f of the first connecting member 51 is integrally fixed to the inner peripheral surface of the rear side spiral fixing portion 35r of the spiral tube 35.

  As a result, a front holding space configured by the distal end hard portion 11H, the first connection member 51, the sealing member 36 provided in the helical tube 35, and the bellows 32A disposed on the outer peripheral side of the helical tube 35 A front holding portion 30A provided with S1 is configured.

The rear holding portion 30B is provided with a rear expanded portion 31B, a rear bellows 32B, a flanged pipe 34, and a spiral pipe 35 and a sealing member 36 which constitute the rear pipe 35B.
The rear expansion portion 31B is the same member as the front expansion portion 31A, the rear bellows 32B is the same member as the front bellows portion 32A, and the rear pipe 35B is the same member as the front pipe 35A.
Therefore, the description of the rear expanded portion 31B, the rear bellows 32B, and the rear pipe 35B is omitted.

  The rear expanded portion 31B and the rear bellows 32B are disposed on the outer peripheral surface of the helical tube 35, and the rear expanded portion 31B and the bellows first fixed surface portion 32f side of the rear bellows 32B are positioned on the outer peripheral surface of the sealing member 36. doing.

  The inner peripheral surface of the first attachment surface portion 31f of the rear expanded portion 31B is closely fixed to the front outer peripheral surface of the sealing member 36 provided at the front end of the helical tube 35 by, for example, an adhesive. On the other hand, the inner peripheral surface of the second attachment surface portion 31 r of the rear expanded portion 31 B is disposed slidably with respect to the rear outer peripheral surface of the sealing member 36 provided on the helical tube 35.

The front side bellows fixing portion 32f of the rear bellows 32B is integrally fixed to the rear end surface of the flange portion 34b of the flange tube 34 integrally fixed to the rear extension portion 31B disposed on the outer peripheral surface of the helical tube 35. . As a result, the front side of the helical tube 35 is slidable with respect to the rear outer peripheral surface of the sealing member 36 in the same manner as the second attachment surface 31r of the rear extension 31B.
On the other hand, the rear side bellows fixing portion 32 r of the rear bellows 32 B is integrally fixed to the outer peripheral surface on the rear side spiral fixing portion 35 r side of the helical tube 35.

  Then, as described above, the second connecting member rear attachment portion 52r of the second connecting member 52 is integrally formed on the inner peripheral surface of the front spiral fixing portion 35f of the helical tube 35 provided with the rear expanded portion 31B and the rear bellows 32B. It will be fixed. On the other hand, the third connecting member front mounting portion 53f of the third connecting member 53 is integrally fixed to the inner peripheral surface of the rear side spiral fixing portion 35r of the spiral tube 35. By this, the back holding part 30B which provided back holding space S3 is comprised.

According to this configuration, the air in the compressor 8 is supplied into the holding spaces S1 and S3 so that the air passes through the gap of the helical tube 35 and is directly supplied to the bellows 32A and 32B, thereby the bellows 32A. , 32B is pressurized and extends.
The other configuration is the same as the configuration shown in FIG. 2, and the same reference numerals are given to the same members and the description will be omitted.

Here, the operation of the self-propelled endoscope 3 having the self-propelled mechanism portion 20 configured as described above will be described with reference to FIGS. 9A to 9H.
The operator grips the insertion portion 12 of the self-propelled endoscope 3 and inserts the distal end portion 11 toward the deep portion of the pipe 100 which is the inspection site as shown in FIG. 9A. Then, the operator appropriately operates the operation unit (see reference numeral 7 in FIG. 1) to switch the self-running mechanism unit 20 to the forward self-running state.

  In the initial state, no air is supplied to the front holding space S1, the expansion space S2, and the rear holding space S3 of the self-running mechanism 20 of the self-propelled endoscope 3. Therefore, the front bellows 32A, the rear bellows 32B, and the telescopic bellows 41 are in a contracted state. For this reason, the front extension 31A and the rear extension 31B are before the extension of the width a.

The forward movement is started, and the third valve unit 17C is opened by the control signal output from the control device as described above, and the air of the compressor 8 is supplied into the rear holding space S3 to start the free movement operation. Ru. That is, first, when the rear bellows 32B is pressurized and reaches a predetermined pressurized state, as shown in FIG. 9B, the rear bellows 32B is expanded in a predetermined state, and the diameter of the rear expanded portion 31B is expanded. .
Then, the largest expanded portion 31 c separated from the inner surface 101 of the pipe 100 is tightly fixed to the inner surface 101, and the rear expanded portion 31 B is held and fixed to the pipe 100.

  Next, the control device outputs a control signal for maintaining the holding and fixing state of the rear extension portion 31B and a control signal for opening the second valve unit 17B. Then, air is supplied into the expansion space S2, the expansion bellows 41 is pressurized, and the expansion bellows 41 extends forward against the urging force of the coil 42 as shown by the arrow in FIG. 9C.

Then, when the telescopic bellows 41 reaches a predetermined pressurized state, as shown in FIG. 9D, the telescopic bellows 41 is further extended forward, and the distal end surface 11 f of the distal end portion 11 is shown in a broken line (FIG. The position L2 is moved forward by a distance L2 with respect to the position 9B).
Next, the control device outputs a control signal for maintaining the holding and fixing state of the rear expansion portion 31B and a control signal for maintaining the expansion state of the telescopic bellows 41, and outputs a control signal for opening the first valve unit 17A. Then, air is supplied into the front holding space S1 and the front expanded portion 31A is pressurized.

  Then, when the front expanded portion 31A reaches a predetermined pressurized state, as shown in FIG. 9E, the front bellows 32A is expanded in a predetermined state, and the front expanded portion 31A is expanded. Then, the largest expanded portion 31 c separated from the inner surface 101 of the pipe 100 is tightly fixed to the inner surface 101, and the front expanded portion 31 A is held and fixed to the pipe 100. In this state, the distal end surface 11f of the distal end portion 11 is held at the position moved forward by the distance L2.

  Next, the control device outputs a control signal for maintaining the holding and fixing state of the front extension 31A, while performing a control signal for releasing the holding and fixing state of the rear extension 31B and a control for contracting the telescopic bellows 41. Output a signal. Then, the third valve unit 17C and the second valve unit 17B are sequentially exhausted, and the pressure in the rear holding space S3 and the pressure in the expansion space S2 are sequentially reduced.

  In addition, the diameter of the rear expansion portion 31B is gradually reduced with the contraction of the rear bellows 32B, and then the expansion-contraction expansion-contraction bellows 41 is expanded by the biasing force of the coil 42, and the expansion-contraction portion 40 is gradually reduced. Go back to length. As a result, as shown in FIG. 9F, the rear expanded portion 31B is moved forward by the distance L2.

  Next, the control device outputs a control signal for maintaining the holding and fixing state of the front extension 31A, and outputs a control signal for opening the third valve unit 17C again. Then, air is supplied again into the rear holding space S3, and the rear expansion portion 31B is held and fixed again to the inner surface 101 as shown in FIG. 9G by the rear bellows 32B reaching a predetermined pressurized state. It will be in the state.

  Here, the control device outputs a control signal for maintaining the holding and fixing state of the rear expansion portion 31B, and outputs a control signal for releasing the holding and fixing state of the front expansion portion 31A to the first valve unit 17A. Then, the first valve unit 17A is in an exhaust state, and the pressure in the front holding space S1 is reduced.

  Then, with the contraction of the front bellows 32A, the diameter of the front expansion portion 31A is gradually reduced, whereby the position of the largest expansion portion 31c of the front bellows 32A is retracted, as shown in FIG. 9H (substantially the same as FIG. 9B). As shown in the figure, in a state in which the stretchable portion 40 in the original state, the front holding portion 30A in the original state, and the tip 11 are disposed on the front side of the rear expanded portion 31 held and fixed to the inner surface 101 of the pipe 100 Become.

  After that, the control shown in FIGS. 9C to 9H described above, that is, control to pressurize the spaces S1, S2, and S3 by control signals output from the control device or control to depressurize the self-running mechanism unit 20 is performed. To operate. As a result, the distal end portion 11 of the endoscope 3 can be quickly advanced toward the deep portion of the pipe 100 to reach the target portion while obtaining the propulsive force from the self-propelled mechanism portion 20.

  In the embodiment described above, the case where the insertion portion 12 is automatically advanced while obtaining the propulsive force has been described, but in the case where the insertion portion 12 is automatically retracted while obtaining the propulsive force, FIGS. As shown, according to the control of the control device, control to pressurize the spaces S1, S2 and S3 or control to depressurize is performed to operate the self-running mechanism unit 20.

First, after the end of the endoscopic examination, the operator operates the operation unit (see reference numeral 7 in FIG. 1) to switch the self-propelled mechanism 20 to the backward self-propelled state.
In addition, when the endoscopic examination is completed, for example, the air is not supplied to the inside of the front holding space S1, the inside of the expansion and contraction space S2, and the inside of the rear holding space S3 of the self-running mechanism 20 of the self-running endoscope 3. Accordingly, as shown in FIG. 10A, the front bellows 32A, the rear bellows 32B, and the telescopic bellows 41 are in a contracted state, and the front extension 31A and the rear extension 31B are before the width a.

  When the backward self-propelled movement is started, the valve unit 17A is opened by the control device and air is supplied into the front holding space S1. As a result, the front bellows 32A is pressurized to be in a predetermined extension state, and the front extension 31A is expanded. Then, as shown in FIG. 10B, the largest expanded portion 31c of the front expanded portion 31A separated from the inner surface 101 of the pipe 100 is closely fixed to the inner surface 101, and the front expanded portion 31A is held against the pipe 100 It becomes fixed state.

  Next, the controller opens the second valve unit 17B to supply air into the expansion space S2 while maintaining the holding and fixing state of the front extension 31A. As a result, as the expansion-contraction bellows 41 is pressurized, the expansion-contraction bellows 41 extends rearward against the urging force of the coil 42 as shown by the arrows in FIG. 10C.

  Then, when the telescopic bellows 41 reaches a predetermined pressurized state, as shown in FIG. 10D, the telescopic bellows 41 is further extended rearward, and the position of the largest extension 31c of the rear extension 31B is indicated by a broken line. The position L2 is moved rearward with respect to the position at the time of the end of the endoscopic inspection (the same position as the position in FIG. 10B).

  Next, the control device controls the supply of the air into the rear holding space S3 by opening the third valve unit 17C while maintaining the holding and fixing state of the front expansion portion 31A and the extension state of the telescopic bellows 41. As a result, the rear bellows 32B is pressurized to be in a predetermined extension state, and the rear expansion portion 31B is expanded.

Then, as shown in FIG. 10E, the largest expansion portion 31c of the rear expansion portion 31B separated from the inner surface 101 of the pipe 100 is closely fixed to the inner surface 101, and the rear expansion portion 31B is held against the pipe 100. It becomes fixed state.
In this state, the position of the largest expanding portion 31c of the rear expanding portion 31B is held in a state of being substantially backward L2 which is moved slightly ahead of the position shown in FIG. 10D.

  Next, the control device outputs a control signal for maintaining the holding and fixing state of the rear expansion portion 31A, and controls the control signal for releasing the holding and fixing state of the front expansion portion 31A and control for contracting the telescopic bellows 41. Output a signal. Then, the first valve unit 17B and the second valve unit 17B are in an exhaust state, and the pressure in the front holding space S1 and the expansion space S2 is reduced.

  Then, along with the contraction of the front bellows 32A, the diameter of the front extension 31A is gradually reduced, and the expansion bellows 41 are contracted by the biasing force of the coil 42, and the expansion portion 40 is gradually reduced to the original. Go back to length. By this, as shown to FIG. 10F, it will be in the state by which 31c of front expansion part 31A was moved behind distance L2.

  Next, the control device outputs a control signal for maintaining the holding and fixing state of the rear extension portion 31B, and outputs a control signal for opening the first valve unit 17A again. Then, air is supplied again into the front holding space S1, and the front expansion portion 31A is held and fixed again to the inner surface 101 as shown in FIG. 10G by the front bellows 32A reaching a predetermined pressurized state. It will be in the state.

  Here, the control device outputs a control signal for maintaining the holding and fixing state of the front expansion portion 31A, and outputs a control signal for releasing the holding and fixing state of the rear expansion portion 31B to the third valve unit 17C. Then, the third valve unit 17C is in an exhaust state, and the pressure in the rear holding space S3 is reduced.

  Then, with the contraction of the rear bellows 32A, the diameter of the rear expansion portion 31B is gradually reduced, whereby the position of the largest expansion portion 31c of the rear bellows 32B is retracted and expanded as shown in FIG. 10B. The telescopic portion 40 in the original state, the rear holding portion 30B in the original state, and the insertion portion 12 are disposed on the rear side of the front expanded portion 31A held and fixed to the inner surface 101 of the pipe 100.

  After that, the control of the space S1, S2 and S3 is performed according to the control signal output from the control device as described above and the control of depressurizing the space S1 is performed to operate the self-running mechanism unit 20. Let As a result, it is possible to quickly retract the insertion portion 12 of the endoscope 3 and extract it from the pipe 100 while obtaining the propulsive force from the self-propelled mechanism portion 20.

  As described above, according to the control of the control device, control of sending air of the compressor 8 to pressurize the spaces S1, S2 and S3 or control of depressurizing the insides of the spaces S1, S2 and S3 is performed and the forward expansion portion 31A. The rear extension portion 31B and the expansion / contraction bellows 41 can be extended and retracted to operate the self-propelled mechanism portion 20 to move the insertion portion 12 of the endoscope 3 forward or backward.

  In the embodiment described above, when the front pipe 35A and the rear pipe 35B using the spiral pipe 35 and the sealing member 36 are provided in the holding portions 30A and 30B, the amount of air leakage is reduced, and thus instead of the compressor 8 You may use a cylinder for the

  In addition, even in the configuration in which the front pipe 35A and the rear pipe 35B are provided in the holding portions 30A and 30B, the control shown in FIGS. 9A to 9H or 10A to 10H, that is, the control output from the control device The distal end portion 11 of the endoscope 3 is moved to the deep portion of the pipe 100 while obtaining propulsive force from the self-propelled mechanism unit 200 by performing control to pressurize the inside of the spaces S1, S2 and S3 or control to depressurize by the signal. You can move forward and backward.

  In the embodiment described above, the expansion portions 31A and 31B are expanded by filling the insides of the bellows 32A and 32B with air to pressurize and extend the insides of the bellows 32A and 32B, and the insides of the bellows 32A and 32B are added. The pressure is reduced from the pressure state to cause the expansion portions 31A and 31B to contract and return to the original state.

However, the self-propelled mechanism may be configured as follows.
11A to 11D show other configuration examples of the self-propelled mechanism portion, and the self-propelled mechanism portion 20A is configured to include a front holding portion 110A, an expansion and contraction portion 40, and a rear holding portion 110B in order from the front side. .

  In addition, back holding part 110B shown to FIG. 11A is the structure substantially the same as front holding part 110A, and the expansion-contraction part 40 is the same as that of the structure demonstrated by embodiment mentioned above. Therefore, the configuration of the front holding portion 110A will be described, and the description of the configuration of the rear holding portion 110B will be omitted. Moreover, the description is abbreviate | omitted also about the expansion-contraction part 40. FIG.

  As shown in FIG. 11B, the front holding portion 110A mainly includes three enlarged diameter portions 111 and an elastic core member 112. As shown to FIG. 11B and FIG. 11C, the enlarged diameter part 111 is comprised by the bellows 113 and the foaming fluorine tube body 114. As shown in FIG. The bellows 113 is made of resin and foldable in the central axial direction, similarly to the above-described bellows 32A and 32B, so that air leakage is prevented.

  As shown in FIG. 11B, the enlarged diameter portions 111 are disposed at equal intervals around the elastic core member 112. The foamed fluorine tube body 122 is provided inside the bellows 121. Air is supplied into the foamed fluorine tube body 114 through a connecting tube (not shown). According to this configuration, air is supplied into each foamed fluorine tube body 114 and pressurized, whereby each bellows 113 is expanded without being stretched and each enlarged diameter portion 111 is changed from a substantially linear shape to a substantially elliptical shape. It will gradually deform.

  Then, as shown in FIG. 11D, the outer side of the elastic core member 112 provided on each enlarged diameter portion 111 is expanded and deformed more than the center side of the bellows 113, and the outer surface 113f of a part of the bellows 113 is an inner surface. It is closely arranged to 101. As a result, the front holding portion 110 </ b> A is closely fixed to the inner surface 101 of the pipe 100 and fixed to the pipe 100.

  The above-described self-propelled mechanism unit 20A performs the control described with reference to FIG. 9A to FIG. 9H or FIG. 10A to FIG. 10H, that is, the foam forming the front holding unit 110A by the control signal output from the control device. It operates by control which pressurizes the inside of each foaming fluorine tube body 114 which constitutes the inside of fluorine tube body 114, space S2, and back attaching part 110B, or control which carries out pressure reduction. As a result, as described above, the distal end portion 11 of the endoscope 3 can be quickly advanced and retracted within the pipe 100 while obtaining the propulsive force from the self-propelled mechanism portion 20A.

Another configuration example of the self-propelled mechanism unit will be described with reference to FIGS. 12A to 12C.
In addition, since the front holding portion and the rear holding portion have substantially the same configuration, the configuration of the front holding portion will be described, and the description of the rear holding portion will be omitted.
As shown in FIG. 12A, the self-propelled mechanism unit 20B includes a front holding unit 120A, an expansion and contraction unit 40, and a rear holding unit 120B. The front holding portion 120 is an enlarged diameter portion, and includes a bellows 121, a foamed fluorine tube body 122, and a wire 123.

  The bellows 121 is made of resin and foldable in the central axis direction, similarly to the above-described bellows 32A and 32B, to prevent air leakage. The wire 123 is spirally wound around the outer peripheral surface of the bellows 121. As shown in FIG. 12B, the foamed fluorine tube body 122 is provided inside the bellows 121. In the present embodiment, air is supplied into the foamed fluorine tube body 122 via the front holding second connection tube 61b shown in FIG.

  According to this configuration, air is supplied into the foamed fluorine tube body 122 and pressurized, whereby the bellows 121 expands and expands. At this time, since the wire 123 is spirally wound around the outer peripheral surface of the bellows 121, the bellows 121 is deformed from a substantially linear state into a desired shape. As a result, as shown in FIG. 12C, the predetermined portion of the bellows 121 is deformed into a predetermined shape, whereby the bellows 121 of the front holding portion 120A is closely fixed to the inner surface 101 of the pipe 100 It becomes fixed state vis-a-vis.

  The above-described self-propelled mechanism unit 20B performs the control described with reference to FIGS. 9A to 9H or 10A to 10H, that is, the foam fluorine constituting the front holding unit 120A according to the control signal output from the control device. It operates by control which pressurizes the inside of the foaming fluorine tube body 122 which comprises the inside of tube body 122, space S2, and back holding | maintenance part 120B, or control which pressure-reduces. As a result, as described above, the distal end portion 11 of the endoscope 3 can be rapidly advanced and retracted in the pipe 100 while obtaining the propulsive force from the self-propelled mechanism portion 20B.

Another configuration example of the self-propelled mechanism unit will be described with reference to FIGS. 13A and 13B.
In addition, since the front holding portion and the rear holding portion have substantially the same configuration, the configuration of the front holding portion will be described, and the description of the rear holding portion will be omitted.
As shown in FIG. 13A, the front holding portion 20C includes a front holding portion 130A, an expansion and contraction portion 40, and a rear holding portion 130B. The front holding portion 130 is an enlarged diameter portion, and includes a bellows 131, a foamed fluorine tube body 132, and a plate member 133.

The bellows 131 is made of resin and foldable in the central axis direction, similarly to the above-described bellows 32A and 32B, so that air leakage is prevented. The plate member 133 is an elongated plate spring having a spring property, and is provided on the outer peripheral surface of the bellows 131 along the longitudinal direction.
The inside of the bellows 131 is provided with a foamed fluorine tube body 132. And air is supplied to the foaming fluorine tube body 132 via the front holding | maintenance 2nd connection tube 61b shown in FIG.

  According to this configuration, air is supplied into the foamed fluorine tube body 132 and pressurized, whereby the bellows 131 expand and expand. At this time, the bellows 131 is greatly expanded and deformed as it is separated from the plate member 132 provided on the outer peripheral surface in the circumferential direction. As a result, as shown in FIG. 13B, the plate member 133 is slightly curved by the bellows 131, while the bellows 131 on the opposite side to the plate member 133 is expanded to a predetermined shape, whereby the inner surface 101 of the pipe 100 is formed. On the other hand, the bellows 131 of the front holding portion 130A is tightly fixed to the pipe 100 and fixed.

  The self-propelled mechanism portion 20C described above performs the control described with reference to FIG. 9A to FIG. 9H or FIG. 10A to FIG. 10H, that is, the foamed fluorine tube body of the front holding portion 130A by The operation is performed by controlling to pressurize the inside of the foamed fluorine tube body 132 in the space 132, the space S2, and the rear holding portion 130B, or control to reduce the pressure. As a result, as described above, the distal end portion 11 of the endoscope 3 can be quickly advanced and retracted within the pipe 100 while obtaining the propulsive force from the self-propelled mechanism portion 20C.

The self-propelled mechanism parts 20, 20A, 20B, and 20C of embodiment mentioned above were comprised having the expansion-contraction part 40. FIG. However, the self-propelled mechanism portion 20D may be configured by providing the telescopic portion 140A shown in FIG. 14 or the telescopic portion 140B may be configured as shown in FIG.
As shown in FIG. 14, the self-propelled mechanism 20D includes a front holding portion 30A, an expansion and contraction portion 140A, and a rear holding portion 30B in order from the front side. The expandable portion 140A mainly includes a tube body 141, a piston mechanism portion 142, and the like.

  The piston mechanism portion 142 is provided in the vicinity of the rear bellows 32B in the insertion portion 12. The piston mechanism portion 142 mainly includes a cylinder tube (not shown), a piston 143, a piston rod 144, and a return spring 145. The cylinder tube is provided in the insertion portion 12 in a predetermined state. Air from the pump 146 is supplied into the cylinder tube. The code | symbol 147 is a valve unit for pumps.

  The return spring 145 is provided in a predetermined state in the cylinder tube. A return spring 145 is fixed to the piston 143. The return spring 145 is expanded as air from the pump 146 is supplied to pressurize the inside of the cylinder tube and the piston 143 is moved forward. On the other hand, the return spring 145 contracts as the pressure in the cylinder tube is reduced to move the piston 143 rearward.

The rear portion of the tube body 141 is integrally fixed to the front portion of the piston rod 144. A piston 143 is fixed to the rear of the piston rod 144.
Although illustration is omitted, in the tube body 141, a pipe line for supplying air into the front holding space S1 of the front holding portion 30A, a pipe line through which a wiring and a signal line are inserted are provided. Further, the front part of the tube body 141 and the rear part of the front bellows 32A are fixed by the connecting member 148 so that air does not leak out.

  According to this configuration, when the valve unit 147 for pump is opened according to the control of the control device, the piston 143 is advanced by pressurizing the inside of the cylinder tube by the air supplied from the pump 146, and the piston rod 144 and tube body 141 are advanced. Conversely, as the pressure in the cylinder tube is reduced by the pump 146, the piston 143 is retracted by the biasing force of the return spring 145, and the piston rod 144 and the tube body 141 are also retracted.

  Therefore, in the self-propelled mechanism portion 20D provided with the extendable portion 140A, the control device controls the pump valve unit 147 instead of controlling the second valve unit 17B to provide the self-propelled mechanism provided with the extendable portion 40 described above. Similar to the endoscope 3 having the traveling mechanism 20, the insertion portion 12 can be automatically inserted toward the deep portion of the pipe 100, or the insertion portion 12 can be automatically removed from the deep portion.

  The self-propelled mechanism portion 20E shown in FIG. 15 includes a front holding portion 30A, an expansion and contraction portion 140B, and a rear holding portion 30B in order from the front side. The expansion and contraction unit 140B mainly includes a helical tube 151 and a motor unit 152. The motor unit 152 is provided in the rear extension portion 31B. The motor unit 152 includes a motor 153 and a motor case 154. In the present embodiment, the motor 153 accommodated in the motor case body 154 is capable of sliding movement within the motor case body 154 by a predetermined distance.

The helical tube 151 is previously set to a length dimension, and one end thereof is integrally fixed to the motor 153. Reference numeral 155 denotes a female screw through hole, which is provided for advancing and retracting the helical tube 151 to be rotated. The other end of the helical tube 151 is provided with a rear portion of the front bellows 32A via a connecting member 156. The front bellows 32A is attached to the connection member 156 so as to advance and retract without rotating as the helical tube 151 rotates.
The helical pipe 151 is provided with a pipe line for supplying air into the front holding space S1 of the front holding portion 30A, and a pipe line through which the wiring and the signal line are inserted.

  According to this configuration, the helical tube 151 is rotated by driving the motor 153 according to the control of the control device, and the helical tube 151 together with the helical tube 151 advances or retracts in the direction corresponding to the rotation direction. The front holding portion 30A moves forward or backward.

  Therefore, in the self-propelled mechanism portion 20E provided with the extendable portion 140B, the control device controls the drive of the motor 153 instead of controlling the second valve unit 17B, thereby providing the self-propelled mechanism provided with the extendable portion 40 Similar to the endoscope 3 having the mechanism unit 20, the insertion portion 12 can be automatically inserted toward the deep portion of the pipe 100, or the insertion portion 12 can be automatically removed from the deep portion.

  In the embodiment described above, the first attachment surface side shape and the second attachment surface portion side shape of the extension portion are provided after the maximum extension portion 31c of the front extension portion 31A and the rear extension portion 31B is provided substantially at the center in the axial direction. Are substantially symmetrical with respect to the maximum expansion portion 31c. However, as shown to FIG. 16A, you may make it provide the spherical surface part 31g of a predetermined radius on the advancing direction side.

  According to this configuration, when traveling in the pipe by the self-propelled mechanism unit, the camera portion is centered as much as possible. Therefore, the expansion portion is expanded in diameter to such an extent that the pipe is not gripped to secure a level at which the traveling can be performed. Then, while maintaining the diameter expansion state, the inside of the pipe 160 configured as shown in FIG. 16B is allowed to pass through the distal end portion 11 of the endoscope 3 from the first straight pipe 161 side.

  At that time, the spherical surface portion 31g is located on the side of the first attachment surface portion 31f which is the side in the advancing direction of the front expanded portion 31A. By this, in the state where the spherical surface portion 31g abuts on the elbow pipe 162, it is possible to prevent the front end portion 11 from being caught by the connecting portion 74 and becoming impossible to advance, thereby realizing smooth passage. In addition, in order to make it easy to pull out the self-propelled mechanism portion manually, the maximum expansion portion 31c is interposed between the hand side and the shape with a small expansion.

The pipe 160 is configured of a first straight pipe 161, an elbow pipe 162, and a second straight pipe 163. Further, in the embodiment described above, the first attachment surface side of the front extension 31A is the spherical surface 31g. However, in the rear expanded portion 31B, the second mounting surface portion side is a spherical surface portion 31g.
Also, when moving the tip 11 from the first straight pipe 161 toward the second straight pipe 163, as shown in FIG. 17A, the tip 11 is caught by the step 164 near the second straight pipe 163 and can not be advanced. May be At this time, passage is possible by performing the following operation.

  Here, the worker supplies air into the front holding space S1. Then, the front bellows 32A is extended and the front extension 31A is gradually extended. At this time, the operator observes the screen of the display device 6 to confirm the change in the position of the tip 11.

  When the position of the tip 11 is moved in the direction of the central axis of the second straight tube 163 as shown in FIG. 17B with the extension of the front bellows 32A and the extension of the front extension 31A, The front image of the straight tube 163 is changed to a side wall image and displayed. This enables the step portion 164 of the tip 11 to pass.

  As described above, the function is also used as a functional portion that assists passage of the elbow tube of the tip end portion 11 by performing an operation to supply air into the front holding space S1 and expand the front extension portion 31A appropriately while passing the elbow tube. It can be done.

In the case where the main purpose is to pass the elbow pipe, as shown in FIG. 18, an elbow expandable portion 40E is further provided in front of the self-propelled mechanism 20. That is, the self-propelled mechanism portion 20 is configured by providing the elastic portion 40E, the front holding portion 30A, the elastic portion 40, and the rear holding portion 30B on the base end side of the distal end portion 11.
The elbow stretchable portion 40E has the same configuration as the stretchable portion 40, and includes a stretchable bellows 41 and a coil 42.

  According to this configuration, the position of the distal end portion 11 is changed by appropriately supplying air into the internal space of the elbow expandable portion 40E to extend the elbow expandable portion 40E while passing the elbow. It can assist elbow pipe passage.

  As shown in FIG. 19, a coil portion 170 may be further provided in front of the elbow elastic portion 40E. That is, the coil portion 170, the elastic portion 40E, the front holding portion 30A, the elastic portion 40, and the rear holding portion 30B are provided on the base end side of the distal end portion 11 to configure the self-running mechanism 20F. The coil section 170 is configured of a closely wound coil 171 and a loosely wound coil 172.

  According to this configuration, since the loosely wound coil 172 has low bending rigidity and is easily bent as compared with the closely wound coil 171, the distal end portion 11 side can be smoothly bent and passed while passing through the elbow.

  Further, instead of providing the coil portion 170 in front of the elbow expandable portion 40E as shown in FIG. 20, three or four elastic protrusions 175 may be provided at equal intervals in the circumferential direction. The protrusion ends 175a of the plurality of elastic protrusions 175 always abut against the inner surface 101 of the pipe 100, and elastically deform so that the protrusion ends 175a are positioned on the proximal side in the contact state.

  According to this configuration, the protruding end 175 a of the plurality of elastic protrusions 175 abuts on the inner surface 101 of the pipe 100, whereby the tip end portion 11 is disposed on the pipe center side. Therefore, while passing through the elbow, the tip end portion 11 can be smoothly passed.

  The present invention is not limited to the embodiment described above, and various modifications can be made without departing from the scope of the invention.

DESCRIPTION OF SYMBOLS 1 ... Self-propelled endoscope apparatus 2 ... Device main body 3 ... Endoscope 4 ... Frame 5 ... Drum
DESCRIPTION OF SYMBOLS 6 ... Display apparatus 7 ... Operation part 8 ... Compressor 11 ... Tip part 11H ... Tip hard part 11a ... Observation part 11b ... Light emitting element 11f ... Tip surface 12 ... Insertion part
13 Controller 14 Air connector 14a Tube 20 Self-propelled mechanism portion 30A Forward holding portion 30B Back holding portion 31 Rear extension portion 31A Forward extension portion 31B Rear extension portion 31c Maximum extension portion 32A Forward bellows 32B ... back bellows 33 ... foamed fluorine tube body 33 A ... front pipe 33 B ... back pipe 34 ... flange pipe 35 ... spiral pipe 36 ... sealing member 40 ... expansion and contraction part 41 ... bellows 42 ... coil
51 first connecting member 52 second connecting member 53 third connecting member
61 ... forward holding tube 62 ... expanding / contracting tube 63 ... backward holding tube 100 ... piping 101 ... inner surface

Claims (8)

A distal end portion, a self-propelled mechanism portion, and an insertion portion;
The self-propelled mechanism unit
A deformable tube having a gap that allows air flow between the inner surface side and the outer surface side, and a tube having a predetermined length,
An expandable portion formed by providing a plurality of slits along a central axis slidably disposed on the outer peripheral surface of the tube;
A bellows foldable in the direction of the central axis disposed on the outer peripheral surface of the tube, and in which an air leak is prevented;
A holding portion having a holding space to which air is supplied via a connection tube;
A self-propelled endoscope comprising the holding portion on the tip end side and the insertion portion side. The self-propelled mechanism unit
A telescopic part is provided between a front holding part which is a holding part provided on the tip end side and a rear holding part which is a holding part provided on the insertion part side. Self-propelled endoscope.   The tubular body has a predetermined sliding property and is ventilated between the tube inner hole and the outer surface by increasing the internal pressure in the holding space, which is set to a predetermined length. The self-propelled endoscope according to claim 2, which is a foamed fluorine tube body in which a gap is formed.   The tubular body is provided at a predetermined portion of the outer peripheral surface of the helical tube having a deformable and predetermined length with a gap that allows air flow, and closes the gap in advance. The self-propelled endoscope according to claim 2, further comprising: a sealing member in which the extended portion having a predetermined sliding property is slidably disposed.   The self-propelled endoscope according to claim 1, wherein the expansion portion is expanded by expanding air supplied into the holding space in the direction of the central axis. The telescopic portion is
A bellows which can be folded in the central axial direction to prevent air leakage;
An elastic member integrally fixed so as to extend or contract integrally with the bellows with predetermined elasticity;
The self-propelled endoscope according to claim 3, characterized in that The telescopic portion is
A piston mechanism provided with a piston provided in the insertion portion on the side of the rear holding portion, a piston rod on which the piston is fixed on the rear portion, and a return spring fixed on the piston;
A tube body integrally fixed to a front portion of the piston rod, which advances and retracts as the piston rod advances and retracts;
A pump for pressurizing or depressurizing the inside of a cylinder tube of the piston mechanism portion;
The self-propelled endoscope according to claim 3, characterized in that The telescopic portion is
A helical tube to which the front support is attached;
A motor for rotating the helical tube;
A motor case body in which the motor is slidably accommodated;
An internally threaded through hole for advancing and retracting the helical tube rotated by the motor;
The self-propelled endoscope according to claim 3, characterized in that

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