JP6040015B2 - Fitting device and intubation support device - Google Patents

Description

  The present invention relates to a joint device and an intubation support device.

  2. Description of the Related Art Conventionally, for example, a joint device disclosed in Patent Document 1 is known as a joint device to which a member to be connected is detachably connected. The joint device preferably improves the strength of the component parts in order to improve durability. The component strength can be improved by making the component thick.

JP 2009-58032 A

  However, when the thickness of the component parts is increased, the component parts are increased in size and the joint device is likely to be increased in size. Then, this invention makes it a subject to provide the coupling apparatus and intubation support apparatus which can suppress the enlargement of a coupling apparatus, aiming at thickness increase of a component.

  In order to solve the above-described problem, in a joint device in which a member to be connected is detachably connected, an insertion portion that is inserted into and removed from a cylindrical portion that is a connection portion between the member to be connected and the joint device, and the insertion portion is a cylindrical portion The fitting body is provided at a position deviated from the portion inserted into the insertion portion and protrudes outward from the insertion portion, and is attached to the fitting body so as not to move in the insertion / removal direction to the insertion portion of the tube portion. A locking member having a locking portion for locking to a locked portion formed on the outer surface of the cylindrical portion, and the insertion portion and the locking portion are arranged inside the ring in a state where the portion is inserted into the cylindrical portion And an operating ring that is movable along the insertion / removal direction and is movable to the first position and the second position, provided on the inner surface of the operating ring, and locked when the operating ring is disposed at the first position. Restriction position that restricts the movement of the locking part so that the part does not move away from the insertion part When the operation ring is arranged at the second position, the abutment portion arranged at a position deviating from the restriction position, and the in-ring protrusion which is a protrusion formed on the inner surface of the operation ring and protruding inward It has a guide member which is arrange | positioned between a part and the protrusion part of a coupling main body, and guides an operation ring in the insertion / extraction direction.

  In the above invention, the locking portion is preferably provided at the tip of the leaf spring.

  In the above-described invention, it is preferable that a protrusion on the contact portion side surface of the leaf spring is provided on the surface on the contact portion side.

  In the said invention, it is preferable that the urging | biasing means which urges | biases an operation ring in the insertion / extraction direction is arrange | positioned between the protrusion part in a ring, and the protrusion part of a coupling main body.

  In the above invention, the insertion portion is inserted into the ring and disposed between the protruding portion of the joint body and the operation ring, and is rotatable around the insertion portion. An operation ring movement restriction having a restriction abutting portion for restricting movement of the operation ring from the first position to the second position by contacting the operation ring when rotating to the first rotation position. The operation ring has a ring, and when the operation ring is moved from the first position to the second position in a state where the operation ring movement restriction ring is rotated to the second rotation position, the operation ring moves against the restriction contact portion. It is preferable that a contact avoiding portion that does not contact is formed.

  In the above invention, the locking member has an insertion portion insertion ring portion through which the insertion portion is inserted, and the insertion portion insertion ring portion acts on a restriction ring side click mechanism provided in the operation ring movement restriction ring, It is preferable that a joint body side click mechanism is provided that gives a click feeling to the operation ring movement restriction ring when the operation ring movement restriction ring is rotated between the first rotation position and the second rotation position.

  In the above invention, the operation ring movement restriction ring is a hole through which the guide shaft is inserted, and has the same central angle as the rotation angle between the first rotation position and the second rotation position of the operation ring movement restriction ring. It is preferable that an arc-shaped long hole having the following is formed.

  In order to solve the above-described problem, the intubation support device includes the above-described joint device.

  ADVANTAGE OF THE INVENTION According to this invention, the joint apparatus and intubation support apparatus which can aim at reduction of a number of parts can be provided.

It is a figure which shows the structure of the external appearance of the intubation assistance apparatus which concerns on embodiment of this invention. It is the elements on larger scale which expanded the A section shown in FIG. It is the exploded perspective view of the joint device concerning an embodiment of the invention, and is the figure seen from back. It is the exploded perspective view of the joint device concerning an embodiment of the invention, and is the figure seen from the front. It is the perspective view which looked at the chassis from back. It is the perspective view which looked at the chassis from the front. It is the perspective view which looked at the locking member from the front. It is the perspective view which looked at the operation ring from back. It is a perspective view which shows the structure of a guide shaft, a sleeve, and a coil spring. It is sectional drawing which shows the structure of the outline of the cross section in the part to which the guide shaft of a coupling apparatus, a sleeve, and a coil spring are attached. It is the front view which looked at the control ring from the front. It is a figure which shows the operation state of the coupling apparatus which made the intubation assistance tool removable, and shows the schematic structure in the cross section containing a central axis. It is a figure which shows the operation state of the coupling apparatus by which mounting | wearing of the intubation assistance tool was completed, and shows the schematic structure in the cross section containing a central axis. It is a figure which expands and shows the schematic structure of the part in which the projection part 80 of a leaf | plate spring is provided, and the part of a contact part.

  Hereinafter, embodiments of the joint device 1 and the intubation support device 2 according to the embodiment of the present invention will be described with reference to the drawings.

(Intubation support device 2)
As shown in FIG. 1, an intubation support device 2 includes an intubation support tool (intlock) 3 as a connected member, a device main body 4, and a joint device 1 that removably connects the intubation support tool 3 to the device main body 4. And have. The intubation support tool 3 is used as a guide for inserting an intubation tube T used when air is sent from a ventilator (not shown) into a patient's trachea. Further, the apparatus main body 4 includes a tubular scope portion (not shown) that can be inserted into the intubation support tool 3, and an image captured by the scope portion can be displayed on the display 5.

  Therefore, by inserting the intubation tube T into the trachea using the intubation support tool 3 with the scope portion inserted in the intubation support tool 3, an image of the vicinity of the distal end portion of the intubation tube T inserted into the body. Can be displayed on the display 5. Thus, since the state of the portion where the intubation tube T is inserted can be visually recognized by projecting an image in the vicinity of the distal end portion of the intubation tube T on the display 5, the intubation tube T can be safely and quickly placed at a desired site in the body. Can be inserted.

  In the following description, the direction of the arrow X1 that is the direction from the device body 4 toward the intubation support tool 3 is the front (the direction of the arrow X2 that is the opposite direction is the rear), and the joint device as shown in FIGS. The direction away from the central axis X of 1 is the outer direction (outer side), the direction approaching the central axis X is the inner direction (inner side), and the direction orthogonal to the central axis X is the radial direction. Is described as the right direction (right side) and counterclockwise as the left direction (left side).

(Intubation support tool 3)
The intubation support tool 3 is inserted from the patient's mouth toward the trachea. The intubation support tool 3 is formed of a transparent member such as a transparent synthetic resin and has light transmittance. The intubation support tool 3 is formed in a curved longitudinal shape. The intubation support tool 3 is formed in a substantially linear shape up to the vicinity of the intermediate portion 8 between the connecting tube portion 6 (see FIGS. 12 and 13) serving as a connecting portion with the joint device 1 and the distal end 7. In the vicinity 8 of the part, it is bent in a substantially 90 ° direction and has a shape reaching the tip 7 side. As shown in FIG. 2, which is an enlarged view of portion A shown in FIG. 1, the intubation support tool 3 is formed with a guide groove 9, a scope guide hole 10, and an operation instrument hole 11.

  The guide groove 9 is a groove part in which an opening is formed on the outer surface of the intubation support tool 3 and is set to have a width dimension and a depth dimension into which the intubation tube T can be inserted. The guide groove 9 is formed in a shape that naturally guides (guides) the distal end of the intubation tube T to the patient's glottic fissure while the intubation support tool 3 is inserted into the patient's mouth. Therefore, by inserting the intubation tube T along the guide groove 9 toward the distal end 7 with the intubation support tool 3 inserted into the patient's mouth, the intubation tube T can be inserted into the trachea from outside the mouth. it can.

  The scope guide hole 10 is a hole part into which a scope part (not shown) can be inserted, and is formed in the intubation support tool 3. The scope guide hole 10 is set to a hole diameter into which the scope portion can be inserted. The scope guide hole 10 has a rear end side communicating with the connection cylinder portion 6, and the scope portion is inserted from the opening 12 (see FIGS. 12 and 13) on the rear end side of the connection cylinder portion 6 toward the distal end 7. be able to. The vicinity of the distal end 7 of the scope guide hole 10 is blocked by the closing portion 13 so that the distal end of the scope portion inserted into the scope guide hole 10 is not exposed to the outside. The blocking part 13 is transparent, and the outside can be observed from the inside.

  Here, the scope unit (not shown) has a flexible tube (not shown) and a camera unit (not shown) provided at the tip of the tube, and the rear end of the scope unit is connected to the apparatus body 4. Has been. As a scope part, the thing of the structure disclosed by Unexamined-Japanese-Patent No. 2005-319028, 2006-109938, 2006-204569 etc. can be used, for example. The camera unit includes a photographing lens, an imaging element such as a CCD on which subject light captured from the photographing lens is imaged, and an LED that illuminates the subject. A communication line for connecting the apparatus main body 4 and the camera unit is passed through the tube. An image signal picked up by the image pickup device is transmitted to a processing unit provided in the apparatus main body 4 via the communication line, and an image picked up on the display 5 is displayed. In addition, a control signal is transmitted from the apparatus body 4 to an image sensor, an LED, and the like.

  With the scope portion inserted into the scope guide hole 10 so that the distal end (camera portion) of the scope portion reaches the closed portion 13, the intubation support tool 3 enters the body through the mouth and is captured by the camera portion. The inside of the body can be observed on the display 5 of the apparatus body 4. The scope unit is provided with an objective lens instead of the camera unit provided in the scope unit, an image guide or a light guide is used instead of a communication line passing through the tube, and an object captured by the objective lens is passed through the image guide. It is good also as a structure to observe.

  The operation instrument hole 11 is a hole part through which a therapeutic instrument such as a suction tube for sucking fluid foreign substances such as saliva and sputum and forceps for removing solid foreign substances is inserted. It is formed in the support tool 3. The operation instrument hole 11 has a rear end side that opens to the outside of the connecting cylinder portion 6 and a distal end side that opens in the vicinity of the blocking portion 13 so that a treatment instrument or the like can be inserted.

  As shown in FIGS. 12 and 13, the intubation support tool 3 is connected to the apparatus main body 4 shown in FIG. 1 by connecting the connecting cylinder portion 6 to the joint apparatus 1. In the connecting cylinder portion 6, a locked groove 14 as a locked portion that is locked to a locking portion 17 (described later) provided in the joint device 1 is formed on the outer peripheral surface in an annular shape over the entire circumference. Yes.

(Device body 4)
As shown in FIG. 1, the apparatus main body 4 includes, for example, a longitudinal case 15 such as a waterproof structure. The joint device 1 is provided on the front end side of the case 15 and an image is provided on the rear end side. A display 5 for display is provided. The intubation support tool 3 can be attached to the apparatus main body 4 via the joint apparatus 1. The case 15 is provided with a power switch, an operation switch, etc. (not shown) for driving the display 5 and the like.

  The display 5 displays an image observed by the scope portion inserted into the scope guide hole 10, and various information of the intubation support device 2 is received by a processing circuit which is a processing device (not shown) housed in the case 15. It is the part that is processed and displayed.

(Fitting device 1)
Next, the overall configuration of the joint device 1 will be described with reference to FIGS. 3 and 4 are exploded perspective views of the joint device 1, FIG. 3 is a view seen from diagonally rear, and FIG. 4 is a view seen from diagonally forward. The joint device 1 is attached to the device main body 4 and has a chassis 16 as a joint main body, and a locking portion 17 that locks in a locked groove 14 (see FIGS. 12 and 13) of the intubation support tool 3. A member 18, an operation ring 19 that allows the joint device 1 to be attached to or detached from the intubation support tool 3, a guide shaft 20 as a guide member that guides the movement of the operation ring 19 in the front-rear direction, A sleeve 21 through which the guide shaft 20 is inserted, a coil spring 22 as a biasing means for biasing the operation ring 19 forward, a state where the operation ring 19 can be moved, and a state where the movement of the operation ring 19 is prohibited. The control ring 23 as a control ring movement restricting ring to be controlled, the C ring 24 that keeps the restricting ring 23 from moving in the front-rear direction with respect to the chassis 16, and the connecting cylinder 6 and the chassis 16 are sealed in a liquid-tight manner. Having that O-ring 25 and the like.

(Configuration of chassis 16)
A specific configuration of the chassis 16 will be described with reference to FIGS. 5 and 6 are perspective views of the chassis 16, FIG. 5 is a view seen from diagonally rear, and FIG. 6 is a view seen from diagonally forward.

  The chassis 16 has an insertion tube portion 26, a projecting portion 27, and an attachment portion 28, and has a substantially cylindrical shape as a whole. The insertion cylinder part 26 is an insertion part that can be inserted inside the connection cylinder part 6 provided at the rear end of the intubation support tool 3 and is a cylindrical part having a hollow part 29 inside. The protruding portion 27 is a flange-shaped portion that is disposed at the rear end portion of the insertion tube portion 26 and protrudes outward. The attachment portion 28 is provided on the rear side of the protruding portion 27 of the chassis 16 and constitutes a part of the attachment structure with the apparatus main body 4. The attachment portion 28 has a cylindrical shape having a hollow portion 30 inside. The chassis 16 having the insertion cylinder part 26, the protrusion part 27, and the attachment part 28 can be formed as a single piece by molding with a resin material, for example.

  The hollow portion 29 and the hollow portion 30 communicate with each other. Therefore, a scope portion (not shown) provided in the apparatus body 4 can be passed through the hollow portion 30 and the hollow portion 29 and guided from the connecting cylinder portion 6 to the scope guide hole 10 of the intubation support tool 3.

  A male screw portion 31 is formed on the outer periphery of the attachment portion 28. On the apparatus main body 4 side, a female screw portion (not shown) that can be screwed to the male screw portion 31 is provided. The chassis 16 is attached and fixed to the apparatus main body 4 using the screw connection between the male screw portion 31 and the female screw portion.

  On the outer periphery of the insertion tube portion 26, a C-ring groove portion 32 into which the C-ring 24 is fitted and an O-ring groove portion 33 into which the O-ring 25 is fitted are formed. The C-ring groove portion 32 and the O-ring groove portion 33 are formed on the outer periphery of the insertion tube portion 26 over the entire circumference.

  In addition, a groove 34 that is parallel to the central axis X is formed on the outer peripheral surface of the insertion tube portion 26 from the front edge toward the rear. The groove 34 is configured as a key groove that is fitted to a not-shown convex strip formed on the inner periphery of the connecting tube portion 6 of the intubation support tool 3 from the rear edge toward the front. That is, the intubation support tool 3 can be attached to the joint device 1 in a predetermined fixed direction by connecting the intubation support tool 3 to the joint device 1 so that the groove portion 34 and the projection are fitted.

  The protrusion 27 is formed with a guide shaft insertion hole 35 through which the guide shaft 20 is inserted. The guide shaft insertion holes 35 are arranged at four locations around the central axis X of the joint device 1 at intervals of 90 degrees. A protruding portion 37 (see FIG. 10) that protrudes inward is formed on the inner periphery of the front end portion of the guide shaft insertion hole 35. When the guide shaft 20 is inserted into the guide shaft insertion hole 35, the protruding portion 37 engages with a screw head 65 of the guide shaft 20 described later, and prevents the guide shaft 20 from being pulled forward.

(Locking member 18)
Next, the structure of the locking member 18 will be described with reference to FIGS. FIG. 7 is a perspective view of the locking member 18 as viewed obliquely from the front. The locking member 18 extends (protrudes) forward from a ring portion 38 as an insertion portion insertion ring portion into which the insertion tube portion 26 is inserted, and an outer peripheral edge of the ring portion 38, and serves as a leaf spring. And a functioning leaf spring portion 39. The locking member 18 is formed of, for example, a stainless steel plate, and is formed by punching a plate-shaped member having a ring portion 38 and a plate spring portion 39 from the stainless steel plate. On the other hand, it can be manufactured by performing press working to form a leaf spring portion 39 and projections 40 and 40 described later.

  The inner diameter R1 of the ring portion 38 is set to a size that can be loosely inserted into the insertion tube portion 26 without play. The ring portion 38 has a flat plate shape that is thin in the front-rear direction and thick in the radial direction, and on the back surface, protrusions 40 and 40 that protrude rearward are formed at two locations across the central axis X. As shown in FIG. 6, holes 41, 41 are formed on the front surface of the projecting portion 27 at two locations across the central axis X. The locking member 18 is attached to the chassis 16 in a state where the insertion tube portion 26 is inserted into the ring portion 38 and the ring portion 38 is in contact with the protruding portion 27. The protrusions 40 and 40 and the holes 41 and 41 are arranged at positions where the locking members 18 are fitted to each other in a state where the locking member 18 is attached to the chassis 16. By fitting the protrusions 40 and 40 into the holes 41 and 41, the locking member 18 is positioned in the left and right direction (the circumferential direction of the central axis X) with respect to the chassis 16.

  The leaf spring portions 39 are provided at four locations around the central axis X at intervals of 90 degrees. In addition, the leaf | plate spring part 39 and the latching | locking part 17 are arrange | positioned with respect to the central axis X symmetrically. The leaf spring portion 39 has a flat plate shape that is wide in the left-right direction and thin in the radial direction. Further, the leaf spring portion 39 is a portion bent forward from the ring portion 38 at a substantially right angle, and is arranged substantially parallel to the central axis X. Accordingly, the leaf spring portion 39 has flexibility and elasticity in the radial direction.

  The front end of the leaf spring portion 39 is provided with a locking portion 17 that protrudes inward. The locking part 17 can be locked in a locked groove 14 (see FIGS. 12 and 13) formed in the connecting cylinder part 6. The locking portion 17 can be formed, for example, by rounding the front end portion of the leaf spring portion 39 inward toward the rear. An inner front end portion of the engaging portion 17 is formed with an inclined surface 42 that extends outward from the rear to the front, and an inclined surface 43 that is disposed on the rear side of the inclined surface 42 and that extends outward from the front to the rear. Has been.

  The distance D1 between the locking portions 17 of the leaf spring portions 39 arranged in the radial direction is smaller than the outer diameter of the connecting cylinder portion 6 and slightly smaller than or substantially the same as the outer diameter at the bottom of the locked groove 14. Is set. Therefore, when the connecting cylinder portion 6 is inserted between the four leaf spring portions 39 against the urging force of the leaf spring portion 39, the locking portion 17 can be locked in the locked groove 14.

  A long hole 44 that is longer in the front-rear direction than in the left-right direction is formed at the center of the leaf spring portion 39. Of the four leaf spring portions 39, a protrusion 45 is provided in the long hole 44 of one leaf spring portion 39. The protruding portion 45 is bent so that a plate-like portion formed by bending forward from the ring portion 38 protrudes inward, and the curved portion is formed as the protruding portion 45. The protrusion 45 is formed in a plate-like part formed by bending forward from the ring part 38. A curved portion is formed by projecting inward such that a circular arc portion is formed in a plane orthogonal to the central axis X, and the curved portion is used as a protrusion 45.

  The leaf spring portion 39 is formed with a bent portion 46 that is bent outward at a substantially central portion in the front-rear direction, and thereby has a recessed portion 47 that is recessed outward. As shown in FIGS. 12 and 13, the concave portion 47 is formed at the rear end portion of the connecting cylinder portion 6 when the engaging portion 17 is locked in the locked groove 14 formed in the connecting cylinder portion 6. 48 can fit. Thus, by providing the recessed part 47 in which the rear-end part 48 fits in the leaf | plate spring part 39, the locked state of the latching | locking part 17 and the to-be-latched groove 14 can be made reliable.

(Operation ring 19)
Next, the configuration of the operation ring 19 will be described with reference to FIGS. The operation ring 19 has a hollow portion 49 inside and has a substantially cylindrical shape as a whole. The operation ring 19 is provided on the outer peripheral surface at the conical portion 50 whose diameter gradually increases from the front toward the rear, and at the rear end portion of the operation ring 19, and has a step portion 51 with respect to the conical portion 50. And a large-diameter portion 52 having a larger outer diameter.

  On the inner periphery of the operation ring 19, an in-ring protruding portion 53 that is a protruding portion protruding inward is provided. The in-ring protruding portion 53 has a rib shape, and the operation ring 19 is thick at a portion where the in-ring protruding portion 53 is formed. Further, the in-ring protruding portion 53 is formed over substantially the entire inner periphery of the operation ring 19 except for groove portions 56A and 56B and a contact portion 57 described later. By forming the in-ring protrusion 53 on the operation ring 19, the strength (rigidity) of the operation ring 19 can be improved.

  The front and rear portions of the inner ring protrusion 53 of the operation ring 19 are formed in a large inner diameter portion 54 and a large inner diameter portion 55 having an inner diameter larger than the inner diameter R 2 of the inner ring protrusion 53. The width W1 in the front-rear direction of the large inner diameter portion 55 is wider than the width W2 in the front-rear direction of the locking portion 17 of the locking member 18 (see FIG. 7).

  Groove portions 56 </ b> A and 56 </ b> B that penetrate the large inner diameter portion 54 and the large inner diameter portion 55 are formed in the annular protrusion 53. Four sets of the groove portions 56A and 56B are formed around the central axis X at intervals of 90 degrees, and a portion between the groove portions 56A and 56B is formed as a contact portion 57. The size and shape of the groove portions 56 </ b> A and 56 </ b> B are such that they can pass through the long hole 44 formed in the leaf spring portion 39 of the locking member 18. Is set to the size that can enter.

  In addition, a guide member attaching portion 58 to which the guide shaft 20 is attached at intervals of 90 degrees around the central axis X is formed in the in-ring protruding portion 53. The guide member mounting portion 58 is formed in a recess that is recessed forward from the rear surface of the in-ring protruding portion 53. A screw hole 59 is formed in the bottom surface of the guide member mounting portion 58. A screw part 64 provided at the tip of the guide shaft 20 described later can be screwed into the screw hole 59.

  Grooves 60 are formed in the annular projecting portion 53 at two locations across the central axis X. The groove part 60 is formed in the recessed part dented ahead from the rear surface of the protrusion part 53 in a ring. The groove portion 60 is formed in the range of about 30 degrees around the central axis X, and has a position and shape into which a locking projection 61 provided on a restriction ring 23 described later can enter. When the rotation position of the restriction ring 23 around the central axis X is a position where the locking projection 61 is opposed to the groove portion 60 in the front-rear direction, the locking projection 61 enters the groove portion 60 when the operation ring 19 is moved rearward. Therefore, the operation ring 19 can be moved forward. On the other hand, when the rotation position around the central axis X of the restriction ring 23 is a position where the locking protrusion 61 does not oppose the groove portion 60 in the front-rear direction, the locking protrusion 61 even if the operation ring 19 is moved backward. 61 abuts on the rear side surface of the in-ring projecting portion 53, and the rearward movement of the operation ring 19 is restricted.

  The connecting tube portion 6 of the intubation support tool 3 can be inserted into the operation ring 19 from the front. The inner diameter R2 of the in-ring protrusion 53 is larger than the outer diameter R3 (see FIG. 12) of the connecting cylinder 6, and the connecting cylinder 6 can be inserted inside the in-ring protrusion 53. Further, the inner diameter R2 of the in-ring protruding portion 53 is set to be substantially the same as the interval D2 outside the locking portion 17 of the leaf spring portion 39 disposed in the radial direction. Further, the inner diameter of the large inner diameter portion 54 is set to a dimension that allows a small diameter portion 70 of the regulation ring 23 described later to be inserted without backlash and to be smoothly moved back and forth.

  Further, an in-ring protruding portion 62 that is a protruding portion protruding inward is provided in front of the large inner diameter portion 55. The in-ring projecting portion 62 also has a rib shape, and is formed over substantially the entire inner circumference of the operation ring 19. The operation ring 19 includes the in-ring protrusion 62 in addition to the in-ring protrusion 53, so that the rigidity in the radial direction is further improved.

(Guide shaft 20, sleeve 21, coil spring 22)
Next, the configuration of the guide shaft 20, the sleeve 21, and the coil spring 22 will be described with reference to FIGS. FIG. 9 is a perspective view showing configurations of the guide shaft 20, the sleeve 21, and the coil spring 22. FIG. 10 is a cross-sectional view illustrating a schematic configuration of a cross section in a portion to which the guide shaft 20, the sleeve 21, and the coil spring 22 of the coupling device 1 are attached. Four guide shafts 20, sleeves 21, and coil springs 22 are provided so as to correspond to the four guide shaft insertion holes 35, respectively.

  The guide shaft 20 includes a guide portion 63 and a screw portion 64 provided at the front end of the guide portion 63, and a screw head 65 is provided at the rear end of the guide portion 63. As shown in FIG. 9, the guide shaft 20 has the largest outer diameter R4 of the screw head 65, the outer diameter R5 of the guide portion 63 is smaller than the outer diameter R4 of the screw head 65, and the screw portion 64. The outer diameter R6 is set to be the same as or slightly smaller than the outer diameter R5 of the guide portion 63. The outer diameter R4 of the screw head 65 is set to a dimension that does not play in the guide shaft insertion hole 35 and can move smoothly back and forth. As shown in FIG. 10, the screw portion 64 can be screwed into a screw hole 59 formed in the guide member mounting portion 58 of the operation ring 19.

  A protrusion 37 is formed on the inner periphery of the front end portion of the guide shaft insertion hole 35 formed in the protrusion 27 of the chassis 16, and the inner diameter of the opening 36 formed inside the protrusion 37 is the screw head 65. Is smaller than the outer diameter R4. Therefore, as shown in FIG. 10, when the guide shaft 20 is inserted into the guide shaft insertion hole 35 with the screw portion 64 facing forward, the screw head 65 of the guide shaft 20 is engaged with the protruding portion 37, and the guide It is possible to prevent the shaft 20 from slipping forward of the guide shaft insertion hole 35.

  The sleeve 21 has a large-diameter portion 66 substantially at the center in the front-rear direction, and has a front sleeve portion 67 that is a front portion of the large-diameter portion 66 and a rear sleeve portion 68 that is a rear portion. . The outer diameter R7 of the front sleeve portion 67 and the outer diameter R8 of the rear sleeve portion 68 are smaller than the outer diameter of the large diameter portion 66, and the outer diameter R7 of the front sleeve portion 67 is smaller than the outer diameter R8 of the rear sleeve portion 68. Smaller than. A guide portion 63 of the guide shaft 20 is inserted through the sleeve 21. The inner diameter of the sleeve 21 is set to such a dimension that the guide portion 63 inserted through the sleeve 21 is free from backlash and can move smoothly back and forth. The outer diameter R8 of the rear sleeve portion 68 is larger than the inner diameter of the opening portion 36 of the guide shaft insertion hole 35 formed in the protruding portion 27 of the chassis 16.

  The coil spring 22 is passed through the front sleeve portion 67 of the sleeve 21. The outer diameter of the large diameter portion 66 is larger than the inner diameter of the coil spring 22. Therefore, the rearward movement of the coil spring 22 passed through the front sleeve portion 67 can be restricted by the large diameter portion 66.

(Regulation ring 23)
Next, the configuration of the restriction ring 23 will be described with reference to FIGS. FIG. 11 is a front view of the restriction ring 23 as viewed from the front. The restriction ring 23 is provided with a large diameter portion 69 and a small diameter portion 70. The outer diameter of the small diameter portion 70 is set to a dimension that can be inserted inside the large inner diameter portion 54 of the operation ring 19. The inner diameter of the large-diameter portion 69 is set to a dimension that allows the protruding portion 27 of the chassis 16 to be inserted inside.

  On the inner periphery of the restriction ring 23, an in-ring protrusion 72 having a hole 71, which is a protrusion protruding in a flange shape on the inside, is provided. The in-ring protrusion 72 is formed over the entire inner periphery of the restriction ring 23. The inner diameter R9 of the hole 71 is set to a dimension that allows the insertion cylinder portion 26 of the chassis 16 to be inserted without play and to smoothly rotate the restriction ring 23 around the central axis X.

  A guide shaft through hole 73 through which the rear sleeve portion 68 of the sleeve 21 in a state of being passed through the guide shaft 20 is passed, and a leaf spring portion 39 of the locking member 18 are passed through the in-ring projecting portion 72. A leaf spring through-hole 74 is formed. The guide shaft through-hole 73 and the leaf spring through-hole 74 have an arc shape centered on the central axis X, and are formed as elongated holes that are longer in the left-right direction (circumferential direction of the central axis X) than the radial direction. Yes. The guide shaft through-holes 73 and the leaf spring through-holes 74 are formed at four locations around the central axis X at intervals of 90 degrees.

  The radial width of the guide shaft through hole 73 is smaller than the outer diameter of the large diameter portion 66 of the sleeve 21. Therefore, the sleeve 21 in which the rear sleeve portion 68 is passed through the guide shaft through hole 73 can bring the large diameter portion 66 into contact with the in-ring protruding portion 72. That is, the sleeve 21 is restricted from moving backward by the large-diameter portion 66 serving as the in-ring protrusion 72.

  The right end portion of the leaf spring through-hole 74 is a widened portion 75 in which a radial hole is widened outward. In addition, click recesses 76A and 76B serving as restriction ring side click mechanisms are formed on the inner peripheral surface of one of the four plate spring through holes 74. The click recess 76A and the click recess 76B are spaced apart in the left-right direction, and the protrusion 45 provided in the elongated hole 44 of the leaf spring portion 39 of the locking member 18 can be fitted. That is, the protrusion 45 can be fitted into the click recesses 76A and 76B by passing the leaf spring portion 39 provided with the protrusion 45 through the plate spring through hole 74 formed with the click recesses 76A and 76B. be able to.

  The front end edge of the small diameter portion 70 is provided with a locking projection 61 that is a protruding portion protruding forward. The locking protrusions 61 are formed at two locations with the central axis X in between, and are positioned and shaped so as to be able to enter the groove 60 (see FIG. 8).

  The operation ring 19 is arranged in a state where the restricting ring 23 is disposed at a position where the locking protrusion 61 does not oppose the groove 60 in the front-rear direction, that is, at a position where the locking protrusion 61 faces the rear side surface of the in-ring protrusion 53. Is moved rearward, the rearward movement of the operation ring 19 is restricted by the contact between the in-ring protrusion 53 and the locking projection 61. On the other hand, when the operating ring 19 is moved rearward with the restricting ring 23 disposed at a position where the locking protrusion 61 faces the groove 60 in the front-rear direction, the locking protrusion 61 is moved to the groove 60. Therefore, the operation ring 19 can be moved further rearward than when the locking projection 61 abuts against the in-ring protrusion 53.

(Assembly process of joint device 1)
The assembly of the coupling device 1 having the above-described configuration will be described with reference to FIGS.

(Incorporation of the locking member 18 into the chassis 16)
First, the locking member 18 is directed from the ring portion 38 side (that is, the leaf spring portion 39 is directed forward) so that the insertion tube portion 26 of the chassis 16 is inserted inside the ring portion 38 of the locking member 18. ) Into the chassis 16. The engaging member 18 rotates with respect to the circumferential direction of the central axis X by fitting the protrusion 40 formed on the rear surface of the ring portion 38 into the hole 41 formed on the front surface of the protruding portion 27 of the chassis 16. It can be positioned and fixed so that it does not.

  A groove portion 77 is formed on the side surface of the protruding portion 27. The groove 77 is a mark indicating the front direction of the intubation support device 2 and is the display direction of the display 5 when the intubation support device 2 is used. The groove part 77 and the groove part 34 formed in the insertion cylinder part 26 are arranged in the same direction in the circumferential direction of the central axis X.

  Since the protrusion 40 and the hole 41 are arranged with the central axis X in between, the locking member 18 can fit the protrusion 40 into the hole 41 even if the locking member 18 is rotated 180 degrees around the central axis X. Can do. In the present embodiment, the protrusions 45 provided on the locking member 18 are arranged closer to the groove 77 side so that the rotation positions around the central axis X of the locking member 18 are aligned and protruded into the hole 41. The part 45 is fitted.

(Incorporation of restriction ring 23 into chassis 16)
Next, in order to insert the insertion tube portion 26 of the chassis 16 into the hole 71 of the restriction ring 23, the restriction ring 23 is moved from the large-diameter portion 69 side (that is, with the locking projection 61 facing forward). ) Install in the chassis 16. At this time, the four leaf spring portions 39 are respectively passed through the four leaf spring through holes 74. By passing the plate spring portion 39 through the widened portion 75 (see FIG. 11) of the plate spring through hole 74, the plate spring portion 39 can be easily passed through the plate spring through hole 74.

  Click recesses 76A and 76B (see FIG. 11) are formed in one of the four leaf spring through holes 74 provided in the restriction ring 23. The restriction ring 23 is inserted in a state in which the position in the left-right direction is aligned so that the leaf spring portion 39 in which the protrusion 45 is formed is disposed in the leaf spring through hole 74 in which the click recesses 76A and 76B are formed. It is passed through the cylindrical portion 26.

  The protrusion 45 can be fitted into the click recesses 76A and 76B. Therefore, by arranging the leaf spring portion 39 in which the protrusion 45 is formed in the leaf spring through hole 74 in which the click recesses 76 </ b> A and 76 </ b> B are formed, the restriction ring 23 is rotated left and right around the central axis X. When the projection 45 is fitted into the click recesses 76A and 76B, a click feeling can be obtained.

(Incorporation of C-ring 24 and O-ring 25)
The rear surface of the in-ring protrusion 72 of the restriction ring 23 abuts on the front surface of the ring portion 38 of the locking member 18, and the ring portion between the front surface of the protrusion 27 of the chassis 16 and the in-ring protrusion 72 of the restriction ring 23. The restriction ring 23 is incorporated in the chassis 16 so that 38 is sandwiched. In this state where the restriction ring 23 is incorporated in the chassis 16, the front end 78 of the inner peripheral edge of the in-ring protrusion 72 of the restriction ring 23 is disposed immediately after the C-ring groove 32. Therefore, by engaging the C ring 24 with the C ring groove 32, the locking member 18 and the restriction ring 23 are sandwiched between the C ring 24 and the front surface of the protruding portion 27 of the chassis 16. The movement of the locking member 18 and the restriction ring 23 in the front-rear direction is restricted. The restriction ring 23 can be rotated in the circumferential direction of the central axis X. Subsequently, the O-ring 25 is passed from the front end of the insertion tube portion 26 of the chassis 16 and fitted into the O-ring groove portion 33.

(Incorporation of the operation ring 19 into the chassis 16)
Next, the operation ring 19 is assembled into the chassis 16 from the large diameter portion 52 side so that the insertion tube portion 26 of the chassis 16 is inserted into the hollow portion 49 of the operation ring 19. At this time, the groove portion 60 is opposed to the locking projection 61 in the front-rear direction, and the guide member mounting portion 58 is opposed to the guide shaft insertion hole 35 formed in the protruding portion 27 of the chassis 16 in the front-rear direction. It is assumed that the contact portion 57 and the elongated hole 44 of the leaf spring portion 39 are aligned in the left-right direction. Further, the operation ring 19 is assembled in the chassis 16 in a state where the sleeve 21 through which the coil spring 22 is passed through the front sleeve portion 67 is disposed between the four guide shaft insertion holes 35 and the guide member mounting portion 58. At this time, the rear sleeve portion 68 of the sleeve 21 passes through the guide shaft through hole 73 of the restriction ring 23 and is disposed in the guide shaft through hole 73.

  A mark portion 19A (see FIG. 8) is provided on the outer peripheral surface of the large-diameter portion 52 of the operation ring 19 by engraving or the like. By aligning the mark portion 19A with the groove portion 77, the alignment of the locking projection 61 and the groove portion 60 in the front-rear direction, the alignment of the guide shaft insertion hole 35 and the guide member mounting portion 58, the contact portion 57, Marking portion 19A, locking protrusion 61, groove portion 60, guide shaft insertion hole 35, guide member mounting portion 58, abutting portion 57, and plate so as to facilitate alignment with the long hole 44 of the leaf spring portion 39 A long hole 44 and the like of the spring portion 39 are arranged.

  As described above, with the operation ring 19 incorporated in the chassis 16, the guide shaft 20 is inserted from the rear end of the guide shaft insertion hole 35, and passes through the guide shaft through hole 73 of the restriction ring 23. The screw part 64 is screwed into the screw hole 59 of the guide member attaching part 58. The screw head 65 engages with a protrusion 37 formed at the front end of the guide shaft insertion hole 35. Therefore, the operation ring 19 in a state in which the screw portion 64 of the guide shaft 20 is screwed into the screw hole 59 of the guide member mounting portion 58 is restricted from moving forward by the engagement with the protruding portion 37 of the screw head 65. Is done. That is, by engaging the screw head 65 with the protrusion 37, it is possible to prevent the operation ring 19 from dropping forward from the chassis 16. Further, the screw head 65 can move back and forth in response to the guide of the guide shaft insertion hole 35 in the range behind the protrusion 37 with respect to the guide shaft insertion hole 35.

  The outer diameter R4 of the screw head 65 is set to a dimension that does not play in the guide shaft insertion hole 35 and can move smoothly back and forth. Therefore, the screw head 65 can move back and forth in response to the guide of the guide shaft insertion hole 35 in a range behind the protrusion 37 with respect to the guide shaft insertion hole 35. Further, the inner diameter of the large inner diameter portion 54 of the operation ring 19 is set to a size that allows the small diameter portion 70 of the restriction ring 23 to be inserted smoothly and back and forth without being loose. Therefore, the operation ring 19 that moves back and forth also receives the guide of the small diameter portion 70 of the restriction ring 23.

  In a state in which the screw portion 64 of the guide shaft 20 is screwed into the screw hole 59 of the guide member mounting portion 58 of the operation ring 19 and the operation ring 19 is mounted to the chassis 16, the guide member mounting portion 58, the in-ring protrusion 72, A coil spring 22 is disposed between the two. The natural length of the coil spring 22 is longer than the distance between the guide member mounting portion 58 and the large diameter portion 66 of the sleeve 21 in a state where the guide shaft 20 is screwed into the screw hole 59. Further, the rear sleeve 68 of the sleeve 21 into which the front sleeve portion 67 is inserted into the coil spring 22 is passed through the guide shaft through hole 73, and the large diameter portion 66 of the sleeve 21 is in contact with the front surface of the in-ring protruding portion 72. It touches. Therefore, the operation ring 19 is attached to the chassis 16 in a state of being biased forward by the coil spring 22, and the operation ring 19 can be elastically moved backward against the biasing force of the coil spring 22.

  The rear sleeve portion 68 is passed through the guide shaft through-hole 73 of the restriction ring 23 so that the amount of rotation of the restriction ring 23 in the left-right direction is restricted. The angle that the length of the guide shaft through-hole 73 in the left-right direction forms the center axis X and the angle that the interval between the click recess 76A and the click recess 76B forms the center axis X are substantially the same. The protrusion 45 is fitted into the click recesses 76A and 76B just before the rotation of the restriction ring 23 is restricted by the contact between the rear sleeve portion 68 and the guide shaft through hole 73.

  A stamp (mark) 79 is formed on the side surface of the large diameter portion 69 of the restriction ring 23. The stamp 79 is formed in the projecting portion 27 at the center of the rotatable range when the regulating ring 23 is rotated in a range in which the rotation is regulated by the contact between the rear sleeve portion 68 and the guide shaft through hole 73. It arrange | positions so that the groove part 77 may be located.

(Operation of the coupling device 1)
Next, the operation of the joint device 1 when the intubation support tool 3 is attached to and detached from the joint device 1 having the above-described configuration will be described with reference to FIGS. FIG. 12 is a diagram illustrating an operational state of the joint device 1 in which the intubation support tool 3 is detachable, and a schematic configuration in a cross section including the central axis X. FIG. 13 is a diagram illustrating an operation state of the joint device 1 in which the intubation support tool 3 is completely mounted, and a schematic configuration in a cross section including the central axis X.

  As shown in FIGS. 12 and 13, the operation ring 19 can move back and forth. As shown in FIG. 12, the joint device 1 is in a state in which the intubation support tool 3 can be attached and detached while the operation ring 19 is displaced rearward. On the other hand, as shown in FIG. 13, in a state where the operation ring 19 is displaced forward, the joint device 1 is locked so that the intubation support tool 3 cannot be removed. In the following description, the position of the operation ring 19 shown in FIG. 12 will be described as the release position P, and the position of the operation ring 19 shown in FIG.

  The operation ring 19 is always disposed at the lock position Q by the urging force of the coil spring 22 that exerts a reaction force on the front surface of the in-ring protrusion 72 of the restriction ring 23 via the large-diameter portion 66 of the sleeve 21. In the lock position Q, the contact portion 57 is disposed outside the locking portion 17, and the contact portion 57 is in contact with the outside of the locking portion 17. Therefore, the locking portion 17 cannot be displaced outward. Further, when the operation ring 19 is disposed at the lock position Q, the locking protrusion 61 (see FIG. 3 and the like) is opposed to the rear surface portion that is disengaged from the groove portion 60 of the in-ring protrusion 53. The operation ring 19 cannot be moved to the release position P.

  When attaching the intubation support tool 3 to the joint device 1, first, the restriction ring 23 is rotated so that the groove 60 formed in the in-ring protruding portion 53 and the locking projection 61 face each other in the front-rear direction. In the coupling device 1 according to the present embodiment, the restriction ring 23 is rotated leftward, and the right end of the guide shaft through-hole 73 (see FIG. 11 and the like) of the restriction ring 23 abuts on the rear sleeve portion 68 to rotate. In a restricted state, the locking projection 61 faces the groove portion 60 in the front-rear direction. The guide shaft through hole 73 is formed in the range of about 45 degrees around the central axis X, and the rear sleeve portion 68 is disposed in the range of about 22.5 degrees from the right end of the guide shaft through hole 73. In this case, the groove portion 60, the guide shaft through hole 73, and the like are arranged so that the locking projection 61 faces the groove portion 60 in the front-rear direction. It should be noted that the protrusion 45 provided on the locking member 18 is fitted into the click recess 76A just before the right end of the guide shaft through hole 73 of the restriction ring 23 comes into contact with the rear sleeve portion 68, and the click feeling Can be obtained.

  The locking projection 61 can be inserted into the groove portion 60 in a state where the restricting ring 23 is rotated leftward and the locking projection 61 faces the groove portion 60 in the front-rear direction. Therefore, when the operation ring 19 is pushed backward in this state, the operation ring 19 can be moved backward and the operation ring 19 can be displaced to the release position P. The outer diameter of the conical portion 50 of the operation ring 19 increases toward the rear, and a step portion 51 is provided. Therefore, when the operation ring 19 is picked up with fingers and the operation ring 19 is moved backward, the fingers are not easily slid with respect to the operation ring 19, and the operation for moving the operation ring 19 backward is easy to perform.

  When the operation ring 19 is disposed at the release position P, the contact portion 57 provided on the in-ring protruding portion 53 of the operation ring 19 is disposed outside the long hole 44 of the leaf spring portion 39 of the locking member 18. The Therefore, when the leaf spring portion 39 is bent outward, the left and right portions of the long hole 44 of the leaf spring portion 39 can enter the groove portions 56A and 56B, and the locking portion 17 also enters the large inner diameter portion 55. it can. For this reason, if the outward force is applied to the locking portion 17, the locking portion 17 can be displaced outward.

  The operation ring 19 is disposed at the release position P, that is, the locking portion 17 is displaceable outward, and the connecting tube portion 6 of the intubation support tool 3 is placed between the operation ring 19 and the insertion tube portion 26. Insert into. When the connecting cylinder part 6 is inserted between the operating ring 19 and the insertion cylinder part 26, the rear end part 48 of the connecting cylinder part 6 comes into contact with the inclined surface 42 of the locking part 17, and the locking part 17 is moved outside. Displace to. Since the locking portion 17 is displaced outward, the connecting cylinder portion 6 can be moved rearward. While the locking portion 17 is placed along the outer peripheral surface of the connecting cylinder portion 6, the connecting cylinder portion 6 can move rearward, and the locking portion 17 is locked in the locked groove 14 as shown in FIG. 12. Can be made. In addition, the intubation assistance tool 3 is connected to the joint apparatus 1 so that the groove part 34 may fit in the convex strip which abbreviate | omits illustration formed in the inner periphery of the cylinder part 6 for a connection.

  If the force that pushes the operating ring 19 backward is eliminated while the locking portion 17 is locked in the locked groove 14, the operating ring 19 moves forward by the urging force of the coil spring 22. As shown, it is displaced to the lock position Q. As shown in FIG. 13, when the operation ring 19 is disposed at the lock position Q, the contact portion 57 is disposed in contact with the outside of the locking portion 17. Therefore, the locking portion 17 cannot be displaced outward. In other words, even if the connecting cylinder portion 6 is moved forward, the connecting cylinder portion 6 does not move due to the engagement between the locking portion 17 and the locked groove 14. That is, the connecting cylinder portion 6 (intubation support tool 3) cannot be removed from the joint device 1.

  In this state, the restriction ring 23 is rotated rightward so that the left end of the guide shaft through hole 73 of the restriction ring 23 is brought into contact with the rear sleeve portion 68. It should be noted that the protrusion 45 provided on the locking member 18 is fitted into the click recess 76B just before the left end of the guide shaft through hole 73 of the restriction ring 23 comes into contact with the rear sleeve portion 68, and the click feeling Can be obtained.

  In a state where the left end of the guide shaft through-hole 73 is in contact with the rear sleeve portion 68, the locking protrusion 61 faces the rear surface of the in-ring protrusion 53. For this reason, even if the operation ring 19 is moved rearward, the locking projection 61 abuts on the rear side surface of the in-ring protrusion 53, and the rearward movement of the operation ring 19 is restricted. As described above, the movement of the operation ring 19 to the rear is restricted, so that the operation ring 19 is moved backward when the intubation support tool 3 is inserted into the patient's mouth carelessly, for example. Therefore, it is possible to prevent an accident in which the connecting cylinder portion 6 is detached from the joint device 1. When the rear sleeve portion 68 is disposed within a range of about 22.5 degrees from the left end of the guide shaft through hole 73, the locking projection 61 does not enter the groove portion 60, and is formed on the rear surface of the in-ring protruding portion 53. The groove 60, the guide shaft through hole 73, and the like are arranged so as to face each other.

  When removing the intubation support tool 3 connected to the joint device 1, the restriction ring 23 is rotated counterclockwise so that the locking projection 61 faces the groove portion 60, and the operation ring 19 can be moved to the release position P. To do. Then, in the state where the operation ring 19 is displaced to the release position P, the intubation support tool 3 is pulled forward. In a state where the operation ring 19 is disposed at the release position P, the locking portion 17 can move outward. Therefore, when the intubation support tool 3 is pulled forward, the locking part 17 is disengaged to the rear side of the locked groove 14 of the connecting cylinder part 6, and the intubation support tool 3 can be extracted forward.

(Main effects of this embodiment)
The joint device 1 of the present embodiment includes an insertion tube portion 26 as an insertion portion that is inserted into and removed from a connection tube portion 6 that is a connection portion to which the intubation support tool 3 is connected to the joint device 1, and the insertion tube portion 26. A chassis 16 is provided as a joint body having a protruding portion 27 provided at a position deviated from a portion inserted into the connecting cylinder portion 6 and protruding outward from the insertion cylinder portion 26. Further, the coupling device 1 is attached to the chassis 16 so as not to move in the insertion / removal direction of the connecting cylinder portion 6 with respect to the insertion cylinder portion 26, that is, the front-rear direction, and the insertion cylinder portion 26 is inserted into the connecting cylinder portion 6. In this state, a locking member 18 having a locking portion 17 that locks in a locked groove 14 as a locked portion formed on the outer surface of the connecting cylinder portion 6 is provided. With the C-ring 24 fitted in the C-ring groove 32, the locking member 18 is sandwiched between the restriction ring 23 and the projecting portion 27 and attached to the chassis 16 so as not to move in the front-rear direction. Furthermore, the coupling device 1 includes an operation ring 19 that can move to a lock position Q as a first position and a release position P as a second position that are arranged along the front-rear direction. The insertion cylinder part 26 and the latching | locking part 17 are arrange | positioned. The operation ring 19 is provided on the inner surface of the operation ring 19, and when the operation ring 19 is disposed at the lock position Q, the locking portion 17 does not move in a direction away from the insertion tube portion 26. When the operating ring 19 is disposed at the release position P, a contact portion 57 disposed at a position deviating from the restriction position is provided. Further, the operation ring 19 is provided with an in-ring protrusion 53 which is a protrusion formed on the inner surface of the operation ring 19 and protruding inward. The coupling device 1 includes a guide shaft 20 as a guide member that is disposed between the in-ring protrusion 53 and the protrusion 27 of the chassis 16 and guides the operation ring 19 in the front-rear direction.

  In the coupling device 1 configured as described above, the guide shaft 20 that guides the operation ring 19 in the front-rear direction is provided between the in-ring protruding portion 53 and the protruding portion 27. Therefore, the operating ring 19 can be made thicker inward as compared with a case where a guide cylinder that guides the operating ring 19 in the front-rear direction is provided around the insertion cylinder portion 26. That is, by providing the inner protrusion 53 formed in the thick portion toward the inner side on the inner peripheral side of the operation ring, the strength of the operation ring 19 is improved without increasing the outer diameter of the operation ring 19. be able to. That is, the strength of the operation ring 19 can be improved while suppressing an increase in size of the joint device 1.

  The operation ring 19 can be formed of a resin by providing the operation ring 19 with an in-ring protrusion 53 to improve the strength. Thereby, weight reduction of the operation ring 19 and the coupling apparatus 1 can be achieved. In the present embodiment, the locked groove 14 as the locked portion is a concave portion, and the locking portion 17 as the locking portion is a convex portion, but the locked portion side is convex. And the locking portion side may be configured as a concave portion.

  The in-ring projecting portion 53 shown in the present embodiment is formed over the entire inner circumference of the operation ring 19 except for the contact portion 57 and the groove portions 56A and 56B. However, it is not necessary to form it over the entire circumference, and the thickness may be partially reduced in consideration of the strength required for the operation ring 19. The width of the grooves 56A and 56B is sufficient if the right and left portions of the elongated hole 44 of the leaf spring portion 39 can enter, but the width of the grooves 56A and 56B is widened in the left and right direction of the projecting portion 53 in the ring. The width may be shortened.

  The locking portion 17 is provided at the tip of a leaf spring portion 39 as a leaf spring and is elastically supported by the leaf spring portion 39. Therefore, engagement / disengagement of the locking portion 17 with respect to the locked groove 14 can be performed smoothly.

  On the outer side of the leaf spring 39, that is, on the surface on the contact portion 57 side, a protrusion 80 (see FIG. 7) protruding in an arc shape on the contact portion 57 side is provided. The protruding portion 80 is disposed at a position that is outside the locking portion 17. FIG. 14 shows an enlarged schematic configuration of a portion where the protrusion 80 of the leaf spring 39 is provided and a portion of the contact portion 57. The contact portion 57 is an arc surface having the center axis X as the center of curvature. Therefore, when the portion of the leaf spring 39 that contacts the contact portion 57 is a flat surface, there is a possibility that the contact is left and right on both sides. In the case of the one-piece contact, there is a possibility that the state in which the locking portion 17 is not displaced outwardly becomes unstable in the state where the operation ring 19 is disposed at the lock position Q.

  In the coupling device 1, a protruding portion 80 that protrudes outward is provided on the outer side (the contact portion 57 side) of the locking portion 17 of the leaf spring 39. The protrusion 80 protrudes in the shape of an arc having a larger curvature than the curvature of the contact portion 57. Therefore, when the leaf spring 38 abuts against the abutment portion 57, the protrusion 80 can make a line contact with the abutment portion 57 at the top 81. For this reason, it is possible to prevent the contact of the leaf spring 39 with the contact portion 57 from being left and right, and when the operation ring 19 is disposed at the lock position Q, the locking portion 17 is not displaced outward. The state to be made can be stabilized. Further, by forming the protrusion 80 in the shape of an arc, the rigidity of the portion of the leaf spring 39 that contacts the contact portion 57 can be increased. Therefore, when the protrusion 80 is in contact with the contact portion 57, the state in which the locking portion 17 is not displaced outward can be made more stable.

  In the coupling device 1, a coil spring 22 as an urging means for urging the operation ring 19 forward is disposed between the in-ring protrusion 53 and the protrusion 27.

  By arranging the coil spring 22 in this way, for example, compared to the case of using a spring ring that takes a biasing force in the radial direction as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2009-58032), It is possible to increase the range of movement of the operation ring 19 in the front-rear direction in which an urging force can be applied to the operation ring 19 while suppressing an increase in the radial direction.

  When the spring ring described above is used, if the range in which the urging force acts in the front-rear direction is increased, the spring ring needs to be increased in the radial direction, so that the spring ring has a larger diameter and the joint device may be increased in size. There is. On the other hand, according to the configuration of the present embodiment, when it is necessary to increase the range of movement of the operation ring 19 in the front and rear direction and to increase the range in which the urging force of the coil spring 22 acts accordingly, the coil spring Even if 22 is lengthened, the enlargement of the joint device 1 in the radial direction can be suppressed. In this embodiment, the coil spring 22 is configured to urge the operation ring 19 forward, but the coil spring 22 is urged toward the spring, that is, the operation ring 19 is urged backward (biased in the pulling direction). ).

  The joint device 1 has a restriction ring 23 as an operation ring movement restriction ring. The restriction ring 23 is disposed between the protruding portion 27 of the chassis 16 and the operation ring 19 while the insertion tube portion 26 is inserted through the restriction ring 23. Further, the restriction ring 23 is rotatable around the insertion tube portion 26, and is rotated to a first rotation position where the restriction ring 23 has been rotated to the right and a second rotation position which has been rotated to the left. Can do. When the restricting ring 23 is rotated to the first rotation position, it comes into contact with the operation ring 19 to thereby prevent the operation ring 19 from moving from the lock position Q to the release position P. 61. The operation ring includes a contact avoiding portion that does not contact the lock protrusion 61 when the operation ring 19 is moved from the lock position Q to the release position P in a state where the restriction ring 23 is rotated to the second rotation position. The groove part 60 is formed.

  By configuring the joint device 1 in this way, the restriction ring 23 can be rotated to the left and right to enable or prohibit movement of the operation ring 19 in the front-rear direction.

  The locking member 18 has a ring portion 38 as an insertion portion insertion ring portion through which the insertion cylinder portion 26 is inserted, and the ring portion 38 has a click for a restriction ring side click mechanism provided in the restriction ring 23. A protrusion 45 is provided as a joint body side click mechanism that acts on the recesses 76A and 76B to give a click feeling to the restriction ring 23 when the restriction ring 23 is rotated between the first rotation position and the second rotation position. ing. The protruding portion 45 only needs to be fixed with respect to the circumferential direction of the chassis 16. For example, the protruding portion 27 may be formed with a protruding portion that engages with the clicking recesses 76 </ b> A and 76 </ b> B.

  By configuring the joint device 1 in this manner, a click feeling can be obtained when the regulating ring 23 is rotated to the first rotation position and the second rotation position.

  The restriction ring 23 is a hole through which the guide shaft 20 is inserted, and has an arc-shaped long hole having the same central angle as the rotation angle between the first rotation position and the second rotation position of the restriction ring 23. A guide shaft through-hole 73 is formed.

  By configuring the joint device 1 in this manner, the rotational position of the restriction ring 23 can be restricted while suppressing an increase in the number of parts. A sleeve 21 is inserted through the guide shaft 20. Therefore, when the restriction ring 23 is rotated between the first rotation position and the second rotation position, the guide shaft through-hole 73 does not directly contact the guide shaft 20. Therefore, distortion and damage of the guide shaft 20 can be prevented.

DESCRIPTION OF SYMBOLS 1 ... Joint apparatus 2 ... Intubation assistance apparatus 3 ... Intubation assistance tool (member to be connected)
6 ・ ・ ・ Connection cylinder (cylinder)
14 ... Locked groove (locked part)
16 ... Chassis (joint body)
17... Locking portion 18... Locking member 19... Operation ring 20... Guide shaft (guide member)
22 ... Coil spring (biasing means)
23 ... Restriction ring (operation ring movement restriction ring)
26 ... Insertion cylinder part (insertion part)
27 ... Projection part 39 ... Leaf spring part 45 ... Projection part (joint body side click mechanism)
53 ... Projection in the ring 57 ... Contact part 60 ... Groove part (contact avoidance part)
61 ・ ・ ・ Locking protrusion (regulating contact part)
73 Guide shaft through hole (long hole)
76A, 76B ... Click recess (regulation ring side click mechanism)
80 ... Projection part P ... Release position (second position)
Q ... Lock position (first position)

Claims (7)

In the joint device in which the connected member is detachably connected,
An insertion portion that is inserted into and removed from a cylindrical portion that is a connection portion between the connected member and the joint device, and is provided at a position that is away from a portion where the insertion portion is inserted into the cylindrical portion. A joint body having a protruding portion protruding outward;
The locked portion formed on the outer surface of the cylindrical portion, attached to the joint main body so as not to move in the insertion / extraction direction of the cylindrical portion with respect to the insertion portion, with the insertion portion being inserted into the cylindrical portion. A locking member having a locking portion for locking to the portion;
An operation ring that is movable between a first position and a second position, wherein the insertion part and the locking part are arranged inside the ring and are arranged along the insertion / extraction direction;
When the operation ring is provided on the inner surface of the operation ring and the operation ring is arranged at the first position, the movement of the engagement portion is restricted so that the engagement portion does not move away from the insertion portion. A contact portion disposed at a position deviating from the restriction position when the operation ring is disposed at the second position.
A guide member that is arranged between an in-ring protruding portion that is formed on an inner surface of the operating ring and protrudes inward, and the protruding portion of the joint body, and guides the operating ring in the insertion / extraction direction; ,
A joint device comprising: The joint device according to claim 1,
The locking portion is provided on a leaf spring;
A coupling device characterized by the above. The joint device according to claim 2,
The joint device according to claim 1, wherein a protrusion projecting toward the contact portion is provided on a surface of the leaf spring on the contact portion side. In the joint device according to any one of claims 1 to 3,
Between the said protrusion part in a ring, and the said protrusion part, the biasing means which urges | biases the said operation ring in the said insertion / extraction direction is arrange | positioned. In the joint device according to any one of claims 1 to 4,
The insertion portion is inserted into the ring and is disposed between the projecting portion of the joint body and the operation ring, and is rotatable around the insertion portion, and includes a first rotation position and a second rotation position. A regulating contact portion that regulates movement of the operation ring from the first position to the second position by contacting the operation ring when the operation ring is rotated to the first rotation position. Having an operation ring movement restriction ring having
When the operation ring is moved from the first position to the second position in a state where the operation ring movement restriction ring is rotated to the second rotation position, the restriction contact portion is included in the operation ring. A contact avoiding portion that does not contact with is formed,
A joint device characterized by that. The joint device according to claim 5,
The locking member has an insertion portion insertion ring portion through which the insertion portion is inserted,
The insertion portion insertion ring portion acts on a restriction ring side click mechanism provided in the operation ring movement restriction ring, and the operation ring movement restriction ring is rotated between the first rotation position and the second rotation position. Sometimes, a joint body side click mechanism that provides a click feeling to the operation ring movement restriction ring is provided,
A joint device characterized by that. In the coupling device according to claim 5 or 6,
The operation ring movement restriction ring is a hole through which the guide shaft is inserted, and has the same center as the rotation angle between the first rotation position and the second rotation position of the operation ring movement restriction ring. Arc-shaped long holes having corners are formed,
A joint device characterized by that.

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