KR102112982B1 - Tube absence - Google Patents

Abstract

(Task) A tube member is provided so that the tube window member can be removed without removing the tube member from the fluid piping member.
(Solution means) The pipe member 100 is sandwiched between the fluid pipe members to form part of the fluid pipe. The tube member 100 includes a tube member body 102, a tubular window member 104, and a holding member 106. The tubular window member 104 is made of a transparent material, and the flow path 112 and the wing member 108 inside thereof can be viewed from the outside. In addition, the tubular window member 104 is held in a position sandwiched by the holding member 106 into the tube member main body 102. By holding the retaining member 106 backward from the retaining position to the release position, the retaining member 106 is released from the coronary window member 104 and the retaining of the retaining member 104 is released. As a result, the tubular window member 104 can be removed from the tube member body 102 through the lateral opening 130.

Description

Tube absence

The present invention relates to a pipe member sandwiched between the fluid pipe members and constituting a part of the fluid pipe, and more particularly, to a pipe member capable of confirming the flow of fluid in the fluid pipe.

In order to visually check the flow of fluid in a fluid piping, a pipe member is known that allows the inside of the flow path to be visually recognized from a portion made of a transparent material. For example, the flow sensor disclosed in Patent Document 1 includes a transparent tube, a fitting screwed to both ends thereof, and a turbine unit mounted in the tube, and when the fluid flows through the tube, the turbine unit rotates according to the flow rate. And displacement in the axial direction, and by reading the displacement amount of the turbine, it is possible to measure the flow of the fluid and its flow rate.

Japanese Patent Application Publication No. 58-9025

In the flow sensor as described above, while continuing to use, the inner peripheral surface of the tube may be gradually contaminated by fluid passing through the transparent tube or solids contained therein, thereby deteriorating visibility in the flow path. In such a case, the transparent tube is taken out and the inside is cleaned or replaced with a new tube. However, in the conventional pipe member such as the above-described flow sensor, in order to remove the transparent tube serving as the tubular window member, the pipe member itself had to be removed from the fluid piping member and the pipe member had to be disassembled. This is a very cumbersome and time-consuming task.

Therefore, it is an object of the present invention to provide a tube member capable of removing a tubular window member without removing the tube member from the fluid piping member.

That is, the present invention,

A pipe member sandwiched between the fluid pipe members to form a part of the fluid pipe,

A tube member body defining a first passage, the tube member body having a lateral opening opened to communicate with the first passage from a side with respect to the length axis of the first passage,

A tubular window member that is inserted into the tube member main body through the lateral opening, and has a second passage which, when fitted into the tube member main body, communicates with the first passage and constitutes a flow path of the tube member, A tubular window member that is made of at least a part of a transparent material so that the passage can be visually recognized through at least a part,

As a holding member mounted on the tube member main body, a holding position engaged with the tubular window member and holding the tubular window member in a position sandwiched by the tube member body, and away from the tubular window member to the tubular window member Disclosed is a tubular member having a retaining member that is displaceable between a release position that releases the retaining and the tubular window member is detachable from the tubular member body through its lateral opening.

In the tubular member, since the tubular window member can be removed through the lateral opening of the tubular member body, it is necessary to detach the tubular member itself from the fluid piping member in the conventional manner when removing the tubular window member. none.

Preferably,

The holding member is slidably mounted in the tube member body between the holding position and the releasing position in the direction of its longitudinal axis,

In the state where the tubular window member is in its release position, the first passage is displaced in the direction of the length axis from the fitting position sandwiched in the tube member main body and the fitting position. And a communication release position in which communication of the second passage is released.

The tubular window member can be removed from the tube member main body through its lateral opening in the communication release position.

Also preferably,

The tube member main body has a normal front portion and a rear portion, and an intermediate portion between the front portion and the rear portion, and a side opening thereof is formed in the intermediate portion,

The tubular window member is mated in the direction of its longitudinal axis with the tubular member main body at its fitting position, and is sealed with the front portion thereof.

The retaining member becomes a normal member having a third passage, and in its retaining position, is engaged with the tubular window member and its rear portion, so that the third passage together with the first passage and the second passage The flow path of the tube member can be configured.

Furthermore, the holding member can be detached from the tube member main body through the side opening in the state where the tubular window member is removed from the tube member main body.

With this configuration, cleaning and replacement of the holding member is facilitated.

Preferably,

The retaining member has a protruding portion that protrudes outward in the radial direction from the outer circumferential surface of the retaining member, and the tubular member body has a receiving concave portion that receives the protruding portion,

The retaining member, when in its retaining position, is rotatable about its length axis relative to the tube member body, and is in a mating rotational position whose protruding features are aligned in the direction of the length axis relative to the receiving recess. At this time, the protruding portion can be displaced to its releasing position while being accommodated in the receiving concave portion, and when not in the mating rotational position, the protruding portion can interfere with the tube member body so that it cannot be displaced to its releasing position. .

With such a configuration, it is possible to prevent the holding member from being incorrectly displaced from the holding position to the released position by shifting the holding member from the mating rotation position.

Preferably,

The protruding shape portion has a locking outer edge portion extending along the outer circumferential surface of the tube member body, and a locking protrusion is formed on one of the inner circumferential surfaces of the pipe member body and the inner circumferential portion facing the outer circumferential surface, and is caught on the other side A concave portion is formed, and when the holding member is rotated from its mating rotational position in its holding position to become a locking rotational position, the locking projections and the locking recesses are engaged so that rotation of the holding member can be suppressed.

Or instead of the above configuration,

The protruding portion has a locking projection on a sliding engagement surface that is slidingly engaged with the tubular window member,

The tubular window member has a locking recess for receiving the locking projection,

When the retaining member is rotated from its mating rotational position in the retaining position to become the engaging rotational position, the engaging projection and the engaging concave portion are engaged so that rotation of the retaining member can be suppressed.

In this case, a flexible portion having flexibility in the direction of the length axis is formed on the sliding engagement surface of the holding member, and the engaging projection can be formed on the flexible portion.

With such a configuration, since the holding member can be prevented from being rotated from the jammed rotational position to the mating rotational position, it is possible to more reliably prevent the holding member from being erroneously displaced to the release position.

Preferably,

The tube member main body is formed at a side edge of the lateral opening and has a guide surface extending in the direction of its longitudinal axis, and the tube window member has a guide portion protruding radially outward from the outer circumferential surface of the tube window member,

When the tubular window member is inserted into the first passage from its lateral opening to the communication release position, the guide portion abuts on the guide surface so that the tubular window member is aligned with the tubular body in the direction of its length axis. When the position becomes, and the tubular window member is displaced from its communication release position to its fitting position, the guide portion can be made to slide on the guide surface.

With such a configuration, positioning is easy when the tubular member is attached to the tubular member body.

Preferably, it is possible to further include a flow display member disposed in the second passage of the tubular window member and displaced by a fluid flowing in the flow path.

Specifically, the flow display member becomes a wing member rotatably mounted to the tubular window member in a circumferential direction with respect to its length axis, and can be detached from the tube member body together with the tubular window member. .

By having such a flow display member, it is possible to easily recognize the presence or absence of a flow of fluid in the flow path of the tube member. In addition, since the wing members are also removed, cleaning and replacement of the wing members is also facilitated.

Preferably, the tubular window member has a window outer circumferential surface exposed to the outside when it is fitted into the tube member body, and a window inner circumferential surface located in the radial direction inside of the window outer circumferential surface, and the interior of the second passage is It is possible to see through the outer peripheral surface of the window and the inner peripheral surface of the window, and the outer peripheral surface of the window can be shaped such that the center of curvature of the outer peripheral surface of the window is a position between the center of curvature of the inner peripheral surface of the window and the outer peripheral surface of the window. Specifically, the cross-sections of the outer circumferential surface of the window and the inner circumferential surface of the window can be made to be arcuate, respectively.

When the outer circumferential surface of the window and the inner circumferential surface of the window have a shape as described above, the wing member disposed in the tubular window member is enlarged to be seen, so that the rotation of the wing member can be more easily confirmed.

Preferably, the lateral opening has first and second lateral openings formed at positions opposing in the radial direction of the first passageway, and the tubular window member is provided through either of the first and second lateral openings. It can be attached to the tube member body.

If there is only one lateral opening, there may be a case where the mounting and dismounting of the tubular window member becomes difficult when the lateral opening faces the wall or the like when the pipe member is mounted between the fluid piping members. By forming two lateral openings at positions facing in the radial direction, it becomes possible to reduce the possibility of becoming such a state.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the pipe member which concerns on this invention is demonstrated based on attached drawing.

1 is a perspective view showing an assembled state of a tube member according to a first embodiment of the present invention.
FIG. 2 is an exploded perspective view of a component of the tube member of FIG. 1.
3 is a plan view of the tube member of FIG. 1.
4 is a side view of the tube member of FIG. 1.
5 is a cross-sectional view taken along line VV of FIG. 3.
6 is a cross-sectional view taken along line VI-VI in FIG. 4.
FIG. 7 is a first view showing an operation of attaching and detaching a tubular window member in the tube member of FIG. 1, and is a view showing a state where the holding member is in a mating rotational position.
Fig. 8 is a second view showing the operation of attaching and detaching the tubular window member in the tube member of Fig. 1, and is a view showing a state where the holding member is in the released position.
Fig. 9 is a third view showing the installation and removal operation of the tubular window member in the tubular member of Fig. 1, and is a view showing a state where the tubular window member is in a communication release position.
Fig. 10 is a fourth view showing the operation of attaching and detaching the tubular window member in the tubular member of Fig. 1, and is a view showing a state in which the tubular window member is removed from the tubular member body.
FIG. 11 is a fifth view showing an operation of attaching and detaching a tubular window member in the tube member of FIG. 1, and is a view showing a state in which the holding member is pulled out from the tube member main body.
Fig. 12 is a sixth view showing the operation of attaching and detaching the tubular window member in the tube member of Fig. 1, and is a view showing a state in which the holding member is removed from the tube member main body.
13 is a cross-sectional view of a member for visual recognition of flow, and is a view showing a state where the wing member is in the second position after being removed from the tube member main body.
FIG. 14 is a flow view member of FIG. 13, and is a view showing a state in which the wing member is detached from the tubular window member.
15 is a cross-sectional view along the line XV-XV in FIG. 10.
16 is a side sectional view of a tube member according to a second embodiment of the present invention.
17 is a perspective view of a tube member according to a third embodiment of the present invention.
18 is a perspective view of a tube member according to a fourth embodiment of the present invention.
19 is an exploded perspective view of the tubular window member, the wing member, and the holding member in the tube member of FIG. 18.
20 is an exploded perspective view of the tubular window member, the wing member, and the retaining member of FIG. 19 seen from different directions.
21 is a side sectional view of the tube member of FIG. 18.
22 is a cross-sectional view of the tube member body in the tube member of FIG. 18.
23 is a side view of the wing member in the tube member of FIG. 18.
24 is a front view of the wing member of FIG. 23.
25 is a side sectional view of a tube member according to a fifth embodiment of the present invention.
26 is a perspective view of a tube member according to a sixth embodiment of the present invention.
27 is an exploded perspective view of the tubular window member, the wing member, and the holding member in the tube member of FIG. 26.
FIG. 28 is an exploded perspective view of the tubular window member and the wing member and the retaining member of FIG. 27 seen from different directions.
29 is a side sectional view of the tube member of FIG. 26.
30 is a cross-sectional view of the tube member body in the tube member of FIG. 26.

The pipe member 100 according to the first embodiment of the present invention includes, as shown in FIGS. 1 to 4, a pipe member body 102 to which fluid piping members (not shown) are connected to both ends, and a pipe member body. It is provided with the tubular window member 104 and the holding member 106 mounted on the 102, and the wing member 108 mounted on the tubular window member 104. The pipe member 100 is sandwiched between the fluid pipe members to constitute a part of the fluid pipe. The entire tubular window member 104 is made of a transparent material, and constitutes a flow viewing member 110 of the tubular window member 104 and the wing member 108. The wing member 108 disposed inside the tubular window member 104 is made visible from the outside through the transparent tubular window member 104. The wing member 108 is intended to rotate by the flow of fluid in the passage 112 of the tube member 100, and by viewing the rotation of the wing member 108 through the transparent tubular window member 104, the passage ( It is possible to check the presence or absence of the flow of the fluid in 112).

The tube member body 102 is composed of a normal front portion 114, a normal rear portion 116, and an intermediate portion 118 therebetween. As shown in FIG. 5, the tube member main body 102 defines the first passage 124 extending from the front opening 120 of the front portion 114 to the rear opening 122 of the rear portion 116. . Female threads 126 for fixing the fluid piping members are formed in the front portion 114 and the rear portion 116, respectively. In addition, as shown in FIG. 2, the middle portion 118 has two strut portions 128 connecting the front portion 114 and the rear portion 116, and the first portion between the strut portions 128 is provided. First lateral openings 130 and second lateral openings 132 facing in the radial direction of the passage 124 are formed. These lateral openings 130 and 132 are opened to communicate with the first passage 124 from the side with respect to the longitudinal axis L of the first passage 124. The rear portion 116 and the middle portion 118 are configured as an integral member, and the front portion 114 becomes a separate member from the rear portion 116 and the middle portion 118, thereby being provided to the middle portion 118. It is rotatably mounted about the longitudinal axis L. With this configuration, the fluid piping member is fixed to the other female screw portion 126 while the fluid piping member is already fixed to the female screw portion 126 of one of the front portion 114 and the rear portion 116. At this time, since it is possible to rotate the other with respect to the fluid piping member to be mounted next, it is possible to fix the other female screw portion 126 to the fluid piping member without rotating the fluid piping member. In addition, when the user views the wing member 108 through the tubular window member 104, it is also possible to change the rotational direction position of the intermediate portion 118 so that the support portion 128 becomes a position that does not interfere with the viewing. .

The tubular window member 104 has a normal circumferential wall portion 134 and defines a second passage 136 therein as shown in FIG. 5. Moreover, as shown in FIG. 6, the shaft support portion 140 is formed in the front end portion 138 of the circumferential wall portion 134 so as to cross the second passage 136 in the radial direction, and the shaft support portion 140 From the vicinity of the center, a rotation shaft 142 is formed which extends from the direction of the length axis L toward the rear (left when viewed in the drawing). The tubular window member 104 is fitted into the tube member body 102 in an assembled state, and the front end portion 138 of the circumferential wall portion 134 of the front portion 114 of the tube member body 102 It is inserted into the inside, and is in a position matched in the direction of the tube member main body 102 and the longitudinal axis L. In addition, the front end portion 138 is sealingly engaged with the inner circumferential surface 114a of the front portion 114 so that the second passage 136 of the tubular window member 104 is attached to the front portion 114 of the tube member body 102. Therefore, it is in a state in communication with the first passage 124.

The wing member 108 has a main body portion 144 extending in the direction of the longitudinal axis L, and two blades 146 formed in a spiral shape on the outer circumferential surface 144a of the main body portion 144. The main body portion 144 in the wing member 108 constitutes a normal shaft holding portion 144 that holds the rotating shaft 142 of the tubular window member 104. The shaft holding portion (body portion) 144 holds the rotating shaft 142 of the tubular window member 104 relatively rotatable. Thereby, the wing member 108 is rotatable about the rotation axis 142 about the rotation center axis C. As shown in FIG. In the assembled state, as shown in FIGS. 5 and 6, the wing member 108 is in a state in which the entirety thereof is located in the second passage 136 of the tubular window member 104.

The holding member 106 has a normal circumferential wall portion 148 and defines a third passage 150 therein as shown in FIG. 5. In addition, on the front end surface 148a of the circumferential wall portion 148, a wing support portion 152 extending so as to traverse the third passage 150 in the radial direction is formed, and the wing member (152) The rear end 154 of 108) is supported from the rear. In the assembled state, the retaining member 106 has its rear end 156 inserted into the rear portion 116 of the tube member body 102 to mate with the tube member body 102 in the direction of the length axis L. It becomes the position. The rear end portion 156 is sealingly engaged with the inner circumferential surface 116a of the rear portion 116 of the tube member body 102, and the front end portion 158 is sealed with the rear end portion 160 of the tubular window member 104. It is aligned. Thus, the third passage 150 of the holding member 106 communicates with the first passage 124 and the second passage 136, together with these first passage 124 and the second passage 136, the tube The flow path 112 of the member 100 is configured. 1 and 2, the holding member 106 also has two protruding portions 162 protruding radially outward from the outer circumferential surface 148b of the circumferential wall portion 148, and this protruding portion 162 has a locking outer edge portion 164 extending along the outer peripheral surface 102a of the tube member body 102. A through-hole (hanging recess) 166 penetrating to the inner surface thereof is formed in the engaging outer edge portion 164, and the outer circumferential surface 102a of the tube member body 102 is formed when the through-hole 166 is assembled. A part of the ball (hanging projection) 168 pressed into the image is received so that the position in the rotational direction of the holding member 106 relative to the tube member main body 102 is maintained. The holding member 106 is slidable in the direction of the longitudinal axis L and the rotational direction around the longitudinal axis L with respect to the tube member body 102, as will be described later. And as shown in Fig. 4, when the through hole 166 of the engaging outer edge portion 164 is in the engaging rotation position where the ball 168 is hooked and fixed, to the engagement of the through hole 166 and the ball 168. Retention in the circumferential direction is suppressed, and the holding position for holding the tubular window member 104 in the tubular member body 102 by the projecting portion 162 interfering with the tubular member body 102 It cannot be displaced from the direction of the longitudinal axis L toward the rear. Further, the through holes 166 as the locking recesses and the balls 168 as the locking projections may be arranged in opposite directions, or may be configured to engage with each other by structures other than the through holes 166 and the balls 168. do.

The pipe member 100 is capable of mounting and removing the tubular window member 104 in a state where the fluid pipe member is connected and fixed to the pipe member body 102 and is inserted into the fluid pipe. The procedure for removing the tubular window member 104 is as follows.

First, in the rotational direction sufficient to disengage the through hole 166 of the holding member 106 and the ball 168 of the tube member body 102 engaged with each other in the assembled state of FIG. 4. The engagement is released by applying a force to the holding member 106, and the holding member 106 is rotated from the locked rotational position in Fig. 4 to the mating rotational position in Fig. 7. In this mating rotational position, the protruding portion 162 of the holding member 106 is mated in the direction of the length axis L and the receiving concave portion 170 formed in the rear portion 116 of the tube member body 102. It is. Next, the holding member 106 is displaced backward from the holding position in Fig. 7 in the direction of the longitudinal axis L to be the released position in Fig. 8. The holding member 106 becomes a position away from the tubular window member 104 in the released position, so that the holding member 106 is retained relative to the tubular window member 104. Further, in the mating rotational position, in the process of displacing the holding member 106 from the holding position to the released position, the protruding portion 162 of the holding member 106 receives the concave portion 170 of the tube member body 102. By being accommodated inside, the holding member 106 can be displaced to a release position. On the other hand, even if the holding member 106 is displaced rearward from the holding position toward the release position in the state not in the mating rotational position, the protruding portion 162 of the holding member 106 retains the pipe member body 102. Since it interferes with the rear portion 116, the retaining member 106 cannot be displaced to the release position. Next, the tubular window member 104 is pulled outward from the fitting position of FIG. 8 inserted in the tube member body 102 from the front portion 114 of the tube member body 102, and the communication in FIG. Let it be released. In this communication release position, the sealing engagement between the tubular window member 104 and the front portion 114 of the tube member body 102 is released, and the communication between the first passage 124 and the second passage 136 is also released. do. The coronary window member 104 is mounted therein by taking out the coronary window member 104 in the communication release position through the first lateral opening 130 (FIGS. 1 to 3) of the tube member body 102. It is removed from the tube member body 102 together with the wing member 108 (FIG. 10). Thus, in the said pipe member 100, when removing the tubular window member 104, it is not necessary to remove the pipe member main body 102 from the fluid piping member.

When attaching the removed tubular window member 104, the above-described separation procedure is reversed. The tubular window member 104 can be inserted into and inserted into the tube member body 102 through either the first lateral opening 130 or the second lateral opening 132. As can be seen from FIG. 2, the support portion 128 which becomes the side edge of the first and second lateral openings 130 and 132 of the tube member body 102 extends in the direction of the length axis L A guide surface 172 is formed, and a guide portion 174 protruding from the outer circumferential surface 104b is formed in the tubular window member 104. When the tubular window member 104 is inserted into the tubular member body 102 through any of the first and second lateral openings 130 and 132, the guide portion 174 of the tubular window member 104 is attached to the tubular member body ( Abutting on the guide surface 172 of 102, the tubular window member 104 is in a position mated in the direction of the longitudinal axis L with respect to the tubular member body 102 to be coaxial with each other. From these guide surfaces 172 and the guide portion 174, the tubular window member 104 does not fall out from the side openings 130 and 132 on the opposite side to the side openings 130 and 132 that have passed through when inserted. Also, the alignment of the tubular window member 104 and the tubular member body 102 also becomes easy. In addition, when the tubular window member 104 is displaced from the communication release position of FIG. 9 to the fitting position of FIG. 8, the guide portion 174 slides on the guide surface 172 to position the tubular window member 104 at an appropriate position. You may be guided to.

In the tube member 100, in a state where the tubular window member 104 is detached from the tube member main body 102 (FIG. 10), the holding member 106 is forward (as shown in FIG. It can be displaced to the right side when viewed) and pulled out from the rear portion 116 of the tube member body 102, and can also be removed from the tube member body 102 through the lateral openings 130 and 132 (FIG. 12).

The wing member 108 is attached to the inside of the tubular window member 104 when it is removed from the tube member body 102. As shown in FIG. 13, the first locking portion 178 protruding outward in the radial direction is formed in the rear end portion 176 of the rotating shaft 142 of the tubular window member 104. In addition, the rear end portion 176 on which the first locking portion 178 of the rotating shaft 142 is formed is divided into two by the slit 180, so as to have flexibility in the radial direction. A second locking portion 182 protruding radially inward from its inner circumferential surface 144b is formed in the shaft holding portion 144 of the wing member 108. As described above, the wing member 108 is rotatable about the rotation center axis C with respect to the tubular window member 104 by holding the rotation shaft 142 by the shaft holding portion 144, At the same time, it is also possible to displace along the rotational center axis C with respect to the rotational axis 142. As shown in FIG. 6, the wing member 108 has a first locking portion (as shown in FIG. 13) from a first position where the front end portion 184 abuts the shaft support portion 140 of the tubular window member 104. 178) and the second locking portion 182 are freely displaceable without receiving little resistance until the second position is engaged. That is, the wing member 108 is displaced even without applying a force to the second position, but more than that, since the force is not displaced by the force of the weight of the wing member 108, the tubular window member 104 It is prevented from falling out and falling by itself. The wing member 108 is in a state where the rear end portion 154 protrudes from the rear end surface 104a of the tubular window member 104 in the second position. When the protruding rear end portion 154 of the wing member 108 in the second position is grasped and pulled further rearward, the first locking portion 178 of the rotating shaft 142 is the second locking portion of the shaft holding portion 144 It is pressed inward in the radial direction by 182, whereby the rear end portion 176 divided into two of the rotating shaft 142 is bent inward in the radial direction to engage the first locking portion 178 and the second locking portion 182. Is released. That is, the snap fit is constituted by the first engaging portion 178 and the second engaging portion 182, and the snap fitting is pulled out by pulling the wing member 108 with a force of a certain level or more to pull out the wing member 108. It becomes possible to further displace from the second position. The wing member 108 is thus displaced rearward beyond the second position simply by pulling, and can be easily removed from the tubular window member 104 as shown in FIG. 14. By removing the wing member 108 in this way, it becomes possible to easily clean the inner circumferential surface 104c of the tubular window member 104. When attaching the wing member 108 to the tubular window member 104, the rotational shaft 142 is inserted into the shaft retaining portion 144, the wing member 108 is pushed into the tubular window member 104, and the wing member The first locking portion 178 of the rotation shaft 142 is bent in the radial direction in the second locking portion 182 of the 108 so that the second locking portion 182 rides over the first locking portion 178 do. In this way, the wing member 108 can be easily mounted.

When attaching and detaching the tubular window member 104 with respect to the tubular member body 102, the holding member 106 is in the released position as shown in Figs. In this release position, the wing support portion 152 of the holding member 106 is directed to the first lateral opening 130 and the second lateral opening 132 (left and right as viewed in the drawing), as shown in FIG. 15. Direction). As described above, in the assembled state, the wing member 108 is supported by the wing support 152 and held in the first position, but without support by the wing support 152, it is freely displaced to the second position. . When the wing member 108 is displaced from the first position to the second position in the process of mounting or detaching the tubular window member 104, the rear end 154 of the wing member 108 is attached to the holding member 106. There is a danger of getting caught. In the tube member 100, the direction in which the wing support portion 152 is directed to the first and second lateral openings 130 and 132, that is, the tubular window member 104 is first and second lateral openings 130 and 132 ) Extends in a direction along the direction of movement of the tubular window member 104 when mounting and detaching, so that the wing member 108 continues to support the wing support portion 152 in the process of mounting and dismounting. Will be. This prevents the wing member 108 from being displaced toward the second position and being caught inside the holding member 106.

As shown in FIG. 16, the tube member 200 according to the second embodiment of the present invention is mainly different from the wing member 208 and the structure that holds the tube member 100 according to the first embodiment. In the member 210 for visual recognition of the flow of the tube member 200, an axial holding portion 244 fixed to the peripheral wall portion 234 is formed in the tubular window member 204, and the wing member 208 The main body portion 242 constitutes the rotating shaft 242. The shaft holding portion 244 of the tubular window member 204 has a first locking portion 278 that protrudes radially inward on its inner circumferential surface 244b. Moreover, the rotation shaft (body part) 242 of the wing member 208 has a second locking portion 282 protruding outward in the radial direction to the front end portion 284. In the illustrated assembled state, the stepped portion 288 of the front end portion 284 of the rotating shaft 242 abuts or approaches the rear end face 290 of the shaft holding portion 244, and after the rotating shaft 242 The cross section 292 is supported by the wing support portion 252 of the holding member 206. Thereby, the position of the wing member 208 in the direction of the rotation center axis C is maintained. The rear end surface 292 of the rotating shaft 242 becomes conical, and the wing support 252 is formed with a conical recess 294 fitted to the conical rear end 292 of the rotating shaft 242, and thus concave. The position in the radial direction of the rear end face 292 of the rotating shaft 242 is fixed at the portion 294, so that the rotational central axis C is not shaken. In the state where the tubular window member 204 is removed from the tube member main body 202, the wing member 208 has its second locking portion 282 from the first position in FIG. The second position contacting the first locking portion 278 can be freely displaced. Snapping by the first locking portion 278 and the second locking portion 282 by pulling the portion protruding from the rear end face 204a of the tubular window member 204 of the wing member 208 in the second position The pit is released, and the wing member 208 can be removed from the tubular window member 204. In this embodiment, since the tubular window member 204 does not have a rotating shaft, the interior of the tubular window member 204 after removing the wing member 208 is empty and the inner peripheral surface of the tubular window member 204 It becomes easier to wash (204c).

17, the C-shaped lock member 396 detachably mounted on the outer circumferential surface 302a of the tube member main body 302, as shown in FIG. It is equipped with. By attaching this lock member 396 to the tube member main body 302 with the holding member 306 in the holding position, the projecting portion 362 of the holding member 306 interferes with the lock member 396 The holding member 306 cannot be displaced rearward from the holding position. That is, in the state in which the lock member 396 is attached, the holding member 306 cannot be displaced to the release position, and therefore, it is prevented that the passage of the flow path is accidentally released. In addition, when using such a lock member 396, it is not necessary for the holding member 306 to be able to rotate in the circumferential direction.

The tube member 400 according to the fourth embodiment of the present invention has a configuration close to that of the tube member 200 according to the second embodiment, however, as shown in FIGS. 18 to 24, the shape of each member is different from each other. Do.

19 and 20, a flat holding surface 404d is formed on the outer circumferential surface 404b of the tubular window member 404, and when it is inserted into the tube member body 402, this holding surface 404d The support member 428 (FIG. 18) of the tube member main body 402 is brought into surface contact and held. Further, the guide portion 474 protruding from the outer circumferential surface 404b of the circumferential wall portion 434 becomes a plate shape extending on the outer circumferential surface 404b in the direction of the length axis L, and the guide surface of the tube member body 402 It is intended to make contact with the 472 from a wider surface. By setting it as such a structure, it becomes possible to mount the tubular window member 404 with respect to the tube member main body 402 in a more stable state.

The tubular window member 404 has an axial holding portion 444 that extends from the peripheral wall portion 434 to the center of the second passage 436, as can be seen from FIGS. 20 and 21. Unlike the shaft holding portion 244 of the second embodiment shown in Fig. 16, this shaft holding portion 444 has a cantilever structure. By setting it as such a cantilever structure, cleaning of the inner peripheral surface 404c of the tubular window member 404 becomes easier, and resistance of the fluid flowing through the flow path 412 becomes smaller.

Moreover, as shown in FIG. 22, the tubular window member 404 is located inside the window outer circumferential surface 405a and the window outer circumferential surface 405a, which are exposed to the outside when sandwiched in the tube member main body 402, The window member 408b defining the second passage 436 has a window inner circumferential surface 405b, and the wing member 408 disposed in the second passage 436 is visible through these window outer circumferential surfaces 405a and window inner circumferential surfaces 405b. Becomes Moreover, as shown in FIG. 22, the window inner circumferential surface 405b is a part of a circular inner circumferential surface 404c. In the tubular window member 404 in the present embodiment, the window outer circumferential surface 405a having a circular arc cross-section, the center of curvature P1 thereof is the center of curvature P2 and the window outer circumferential surface 405a of the window inner circumferential surface 405b. It is shaped to be the position between. Therefore, the wall thickness in the radial direction of the circumferential wall portion 434 is the thickest in the central portion of the window outer circumferential surface 405a and gradually becomes thinner as it goes toward the end. In Fig. 22, the virtual circle V passing through the arc of the outer circumferential surface of the window 405a is indicated by a broken line. A lens is formed by such a window outer circumferential surface 405a and a window inner circumferential surface 405b, and the wing member 408 in the second passage 436 is seen to be enlarged as compared to that of the above embodiment when viewed from the outside. Thereby, the visibility of the wing member 408 is improved. In addition, the window outer circumferential surface 405a and the window inner circumferential surface 405b are not necessarily circular or circular in cross section, and may be a non-circular surface.

The wing member 408 comprises a main body part 442 constituting a rotation axis that is rotatably held by the shaft holding part 444 of the tubular window member 404, and an outer peripheral surface 442a of the main body part 442 A first fluid resistance portion 447a disposed on the outer circumferential surface 442a between the first and second wings 446a and 446b, and between the first and second wings 446a and 446b And a second fluid resistance portion 447b. The rotating shaft (body part) 442 of the wing member 408 has a stepped portion 488 facing the rear side of the front end portion 484. In the assembled state of FIG. 21, the stepped portion 488 of the rotating shaft 442 abuts or approaches the locking portion 478 of the shaft holding portion 444, and the rear end face 492 of the rotating shaft 442 is By being supported by the wing support portion 452 of the holding member 406, the position in the direction of the rotation center axis C is maintained. In a state where the tubular window member 404 is removed from the tubular member body 402, the wing member 408 is detached from the tubular window member 404 by grasping and pulling the rear end face 492 side of the rotation shaft 442. You can pay. Alternatively, the blade member 408 is tubular by pressing the front end 484 of the rotating shaft 442 protruding forward from the shaft retaining portion 444 of the tubular window member 404 with a hand or a thin rod-like member or the like. It can also be removed from the window member 404.

The first and second fluid resistance portions 447a and 447b of the wing member 408 are, as shown in FIG. 24, a body portion 442 along one plane F including the rotational center axis C. The direction of the rotational center axis C along the one plane F, as shown in Fig. 23, protrudes from the outer circumferential surface 442a in opposite directions (up and down, respectively as seen in Fig. 24). 23, it has a flat plate shape extending in the left and right directions). The first and second wings 446a, 446b are located on opposite sides to the one plane F, and are approximately perpendicular to the one plane F from the outer peripheral surface 442a of the body portion 442 It is formed so as to protrude in the direction (left and right direction when viewed in FIG. 24). The first blade 446a has a flat plate shape that extends obliquely and linearly with respect to the rotational center axis C when the one plane F is viewed in the vertical direction (i.e., viewed in the direction of FIG. 23). As a result, a surface inclined with respect to the rotation center axis C is formed on the first wing 446a, and when the fluid flows in the direction of the length axis L (ie, the direction of the rotation center axis C), the wing A force in the rotational direction is generated by the fluid in the member 408. The second wing 446b also has the same shape as the first wing 446a. The wing member 408 rotates around the rotational center axis C by the force in the rotational direction that the first and second wings 446a, 446b receive from the fluid when fluid flows through the flow path 412. . On the other hand, the first and second fluid resistance portions 447a and 447b extend in the direction of the rotational center axis C, as described above, so as not to form a surface inclined with respect to the rotational center axis C. Therefore, the force in the rotational direction by the fluid does not act on the first and second fluid resistance portions 447a and 447b while the wing member 408 is stationary. However, when the wing member 408 is rotating, the first and second fluid resistance units 447a and 447b receive resistance from the fluid in a direction opposite to the rotational direction. Accordingly, the first and second fluid resistance portions 447a, 447b cancel a portion of the force in the rotational direction that the first and second wings 446a, 446b receive from the fluid, and the wing member 408 Overall, the sum of the force in the rotational direction received from the fluid is reduced, and it functions to suppress an increase in the rotational speed of the blade member 408. In addition, because the fluid resistance is proportional to the square of the relative speed between the object and the fluid, the faster the flow rate of the flowing fluid and the faster the rotational speed of the wing member 408, the first and second fluid resistance parts 447a, 447b The resistance force received from the fluid increases. That is, the effect of suppressing the rotational speed by the first and second fluid resistance units 447a and 447b increases as the rotational speed of the wing member 408 increases. In addition, the shapes of the first and second fluid resistance portions 447a and 447b are not necessarily planar, and may be in the form of a cylinder or a prism extending outward in the radial direction, and rotating such a columnar one. It is good also as what was arranged in multiple numbers in the direction of the central axis C. Further, the fluid resistance portion may be provided only on one side of the rotation shaft 442.

The wing member 408 is a two-color molding member resin-molded with a red first resin material and a yellow second resin material. The mold (not shown) for molding the wing member 408 is constituted by two molds as divided into one plane F shown in FIG. 24. That is, the molded wing member 408 is pulled out of the mold in a direction perpendicular to the one plane F. Here, the wing member 408, in particular, the first and second blades (446a, 446b) and the first and second fluid resistance portion (447a, 447b) in the direction of ejection of the mold (see FIG. 24 in the left and right direction) ), It is possible to easily release the mold from the mold. Further, the wing member 408 injects a first resin material from a mold corresponding to the first blade 446a, and injects a second resin material from a mold corresponding to the second blade 446b. Is formed. Therefore, the molded wing member 408 is formed with a red first resin material on the left side and a yellow second resin material on the right side when viewed in FIG. 24, with its one plane F as a boundary. It is composed by. That is, the wing member 408 is a two-color member, half of which is red and the other half is yellow. Thus, when the wing member 408 has two different colors, rotation of the wing member 408 can be easily recognized by a change in color. In addition, in this embodiment, although there are two colors of red and yellow, it is naturally possible to use a combination of different colors. In addition, as described above, the mold for performing such two-color molding can be a mold divided into one plane (F), and since the mold division of the mold can be simplified, mold production is relatively easy. Becomes

The first and second fluid resistance portions 447a and 447b of the wing member 408 are mainly formed to suppress an increase in the rotational speed of the wing member 408, as described above, but the wing member 408 It also plays a role of maintaining the posture of the wing member 408 when the tubular window member 404 mounted with) is fitted into the tube member main body 402. That is, in the state in which the tubular window member 404 is removed, the rotating shaft 442 of the wing member 408 is in the state of a cantilever by the shaft holding portion 444 of the tubular window member 404, The wing member 408 is easily inclined with respect to the tubular window member 404, wherein the first and second fluid resistance parts 447a, 447b are disposed between the first and second wings 446a, 446b. By this, these parts engage with the inner circumferential surface 404c of the tubular window member 404, so that the inclination of the wing member 408 is suppressed. In particular, the wing members 408 in this embodiment have only the first and second wings 446a and 446b extending from side to side as seen in FIG. 24 so as to be a two-color molded member as described above, and upward. And the shape that does not extend downward, so that the first and second fluid resistance portions 447a and 447b are not provided, the wing member 408 is greatly inclined upward and downward. When the wing member 408 is largely inclined as described above, the rear end face 492 of the rotation shaft 442 is concave in the wing support portion 452 when the tubular window member 404 is inserted into the tube member body 402. It will not fit into part 494 (FIG. 21). On the other hand, as described above, the inclination of the wing member 408 with respect to the tubular window member 404 by the first and second fluid resistance parts 447a, 447b is set to fall within a predetermined range. The rear end face 492 of the rotating shaft 442 of 408 is properly fitted and held in the conical recess 494 of the holding member 406. That is, by suppressing the inclination of the wing member 408 by the first and second fluid resistance parts 447a, 447b, the mounting operation of the tubular window member 404 in the state where the wing member 408 is mounted is facilitated. It becomes possible to perform.

In the retaining member 406 in the present embodiment, the side of the protruding portion 462 facing the tubular window member 404 is a sliding sliding surface with the rear end surface 404a of the tubular window member 404. It is an engagement surface 462a, and a flexible portion 463 having flexibility in the direction of the length axis L is formed on the sliding engagement surface 462a. A locking protrusion 466 is formed in the flexible portion 463. The engaging projection 466 is received in the engaging recess 498 formed in the rear end face 404a of the tubular window member 404 in the assembled state, and the retaining member 406 relative to the tubular window member 404 The position in the direction of rotation is maintained. As shown in Fig. 18, the retaining member 406 engages the engaging projection 466 and the engaging recess 498 when the engaging projection 466 is in the engaging rotation position engaged with the engaging recess 498. By this, rotation in the circumferential direction is suppressed. When the retaining member 406 is rotated from the engaging rotation position relative to the tubular member main body 402 and the tubular window member 404, the engaging projection 466 is pulled out of the engaging recess 498, and the tubular window member 404 ) Is moved in the surrounding concave portion 499 formed around the rear end surface 404a. The engaging projection 466 does not contact the tubular window member 404 when located within the surrounding recess 499. In addition, an inclined surface 462b is formed on the rear surface of the protruding portion 462, and when the retaining member 406 is rotated from the mating rotation position to the engaging rotation position, the protruding portion 462 is attached to the tube member body ( It is prevented from being easily caught in the corner of the receiving concave portion 470 of 402).

As shown in FIG. 25, the tube member 500 according to the fifth embodiment of the present invention has a different holding form of the wing member 508 with respect to the tube member 400 according to the fourth embodiment. Specifically, the front end 591 and the rear end 592 of the rotary shaft 542 of the wing member 508 each have a tapered shape, and the shaft holding portion 544 of the tubular window member 504 is capped. It becomes an image, and the concave recess 594 is formed in the wing support part 552 of the holding member 506. The taper angle of the front end surface 591 of the wing member 508 is more acute than the taper angle of the shaft holding portion 544 of the tubular window member 504, and the taper angle of the rear end surface 592 of the wing member 508 The taper angle is more acute than the taper angle of the conical recess 594 of the holding member 506. Therefore, the front end surface 591 and the rear end surface 592 of the wing member 508 are basically brought into contact with the shaft holding portion 544 and the conical recess portion 594 at their tip portions, respectively. Thereby, the contact area of the rotating shaft 542 of the blade member 508, the shaft holding part 544, and the wing support part 552 becomes small, and frictional resistance at the time of rotation is reduced.

The tube member 600 according to the sixth embodiment of the present invention has a configuration similar to that of the tube members 400 and 500 in particular according to the fourth and fifth embodiments, as shown in Figs. The members 400 and 500 differ in the following points.

In the tubular window member 604 in the tube member 600, a gripping portion 675 is formed between the window outer peripheral surface 605a and the guide portion 674. In the fourth embodiment, when the tubular window member 404 is taken out from the tubular member body 402, the tubular window member 404 is pushed out from the rear side. The finger may not reach the rear side of the tubular window member 404. On the other hand, since the gripping part 675 as mentioned above is formed in the tubular window member 604 in the said pipe member 600, even in such a situation, the gripping part 675 is gripped and the tubular window member ( By pulling 604), it becomes possible to easily take out the tubular window member 604 from the tube member body 602.

28, the locking projection 666 of the holding member 606 is triangular. Further, the protruding portion 662 of the holding member 606 extends further outward in the radial direction, so that the holding member 606 can be easily operated.

As shown in FIG. 29, the 1st and 2nd fluid resistance part 647a, 647b of the wing member 608 becomes longer in the direction of the longitudinal axis L, and has a shape closer to a rectangle. Thereby, the area of the 1st and 2nd fluid resistance part 647a, 647b becomes large. The first and second wings 646a and 646b also have large areas. Thereby, the visibility of the wing member 608, especially when viewed from the outside of the tubular window member 604, can be improved. Moreover, the resistance received from the fluid flowing through the flow path 612 increases, and it becomes possible to rotate the wing member 608 even at a smaller flow rate. Further, a groove 693 is formed near the rear end face 692 of the wing member 608. When the wing member 608 is detached from the tubular window member 604, the finger is removed from the groove 693, so that the wing member 608 can be separated more easily. The structure of the shaft holding portion 644 of the tubular window member 604 for holding the rotational shaft 642 of the wing member 608 is similar to that of the pipe member 500 according to the fifth embodiment shown in FIG. , Differs in that the support end face 645 of the shaft holding portion 644 is a plane that is approximately perpendicular to the longitudinal axis L. Thereby, the tapered-shaped front end 691 of the wing member 608 is always in point contact with the support end surface 645, so that the front end surface 691 and the support end surface when the wing member 608 rotates The frictional resistance between 645 is not increased.

As shown in FIG. 30, when viewed from the view of the tubular window member 604, the left window outer circumferential surface 605a has a circular arc portion 605a-1 and a straight portion extending straight therefrom to the holding surface 604d ( 605a-2), from the outer peripheral surface 605a of the window to the holding surface 604d, and has a shape without a recess. Thus, when attaching the tubular window member 604 to the tubular member body 602, the tubular window member 604 does not get caught in the holding portion 628 of the tubular member body 602 and is smoothly in the tubular member body 602. Will be inserted.

The embodiments of the present invention have been described above, but the present invention is not limited to these embodiments. For example, the tubular window member does not need to be entirely composed of a transparent material, and if the wing member in the flow path can be visually recognized while being inserted into the tube member body, only a part of the tubular window member is configured by a transparent material. The transparent material may be colored as long as the wing member is visible, or may not be completely transparent on a frosted glass. In addition, as a flow display member for displaying the flow of the fluid in the flow path, a non-wing member may be used, for example, another member such as a fluid resistance member pushed by the fluid and displaced in the flow direction. In addition, when the target fluid contains visible solids or bubbles, the presence or absence of the flow of the fluid can be confirmed by observing them, so it is not necessary to provide a flow display member such as a wing member. In the above-described embodiment, the presence or absence of a flow of fluid is confirmed by rotation of the wing member, but it is also possible to use a flow sensor that measures the flow rate of the fluid from the rotational speed of the wing member. Furthermore, as a structure for preventing the holding member from being inadvertently displaced from the holding position to the released position, a screw may be passed through the engaging outer edge of the holding member, and the screw may be screwed to the tube member body. At this time, the holding member may be fixed with a screw after setting it to the locked rotation position, or may be fixed with a screw at the mating rotation position.

The structures in each embodiment can be freely combined with each other. For example, the wings of the wing members in the first to third embodiments may have the same shape as the first and second wings of the wing members in the fourth to sixth embodiments. Further, in the first to third embodiments, the wing member may be a two-color molding member or may have first and second fluid resistance parts. Alternatively, the structure for suppressing rotation of the holding member in the first and second embodiments may be a structure such as the locking protrusion of the holding member and the locking recess of the tubular window member as in the fourth to sixth embodiments, Conversely, the structures of the first and second embodiments may be employed in the fourth to sixth embodiments. Other constituent parts in each embodiment can also be freely combined with each other.

Tube member 100; Tube member body 102; Outer peripheral surface 102a; Tubular window member 104; Rear section 104a; Outer peripheral surface 104b; Inner peripheral surface 104c; Holding member 106; Wing member 108; Flow viewing member 110; Flow path 112; Anterior portion 114; Inner circumferential surface 114a; Rear portion 116; Inner peripheral surface 116a; Middle portion 118; Front opening 120; Rear opening 122; First passage 124; Female thread portion 126; Holding section 128; A first lateral opening 130; A second lateral opening 132; The peripheral wall portion 134 (of the tubular window member 104); Second passage 136; Front end portion 138; Shaft support 140; Rotating shaft 142; Shaft holding part (body part) 144; Outer peripheral surface 144a; Inner peripheral surface 144b; Wing 146; The peripheral wall portion 148 (of the holding member 106); Shear surface 148a; Outer peripheral surface 148b; Third passage 150; Wing support 152; Rear end portion 154 (of the wing member 108); Rear end portion 156 (of holding member 106); The front end 158 (of the holding member 106); The rear end portion 160 (of the tubular window member 104); Protruding features 162; Jam outer edge portion 164; Through hole 166; Ball 168; Accommodation recess 170; Guide surface 172; Guide portion 174; Rear end portion 176 (of the rotating shaft 142); A first locking portion 178; Slit 180; A second locking portion 182; The front end portion 184 (of the wing member 108);
Tube member 200; Tube member main body 202; Tubular window member 204; Rear section 204a; Inner peripheral surface 204c; Holding member 206; Wing member 208; Flow viewing member 210; Peripheral wall portion 234; Rotating shaft (body part) 242; Shaft holding portion 244; Inner peripheral surface 244b; Wing support 252; First locking portion 278; A second locking portion 282; The front end portion 284; Stepped portion 288; The rear end face 290 (of the shaft holding portion 244); The rear end face 292 (of the rotating shaft 242); Conical recess 294;
Tube member 300; Tube member main body 302; Outer peripheral surface 302a; Holding member 306; Protruding portion 362; Lock member 396;
Tube member 400; Tube member main body 402; Tubular window member 404; Rear section 404a; Outer peripheral surface 404b; Inner peripheral surface 404c; Holding surface 404d; The outer peripheral surface of the window (405a); The inner peripheral surface of the window (405b); Holding member 406; Wing member 408; Flow path 412; Holding section 428; Peripheral wall portion 434; Second passage 436; Front end portion 438; Rotating shaft (body part) 442; Outer peripheral surface 442a; Shaft holding portion 444; First wing 446a; Second wing 446b; A first fluid resistance part 447a; A second fluid resistance portion 447b; Wing support 452; Rear end 460; Projecting portion 462; Sliding engagement surface 462a; Inclined surface 462b; Flexible part 463; Jam protrusion 466; Accommodation recess 470; Guide surface 472; Guide portion 474; Engaging portion 478; Front end 484; Stepped portion 488; Rear section 492; Concave portion 494; Engaging recess 498; Peripheral recess 499;
Tube member 500; Tubular window member 504; Holding member 506; Wing member 508; Rotating shaft 542; Shaft holding portion 544; Wing support 552; Shear surface 591; Rear section 592; Conical recess 594;
Tube member 600; Tube member main body 602; Tubular window member 604; Holding surface 604d; Window outer peripheral surface 605a; Arc-shaped portion 605a-1; Straight upper part 605a-2; Holding member 606; Wing member 608; Euro 612; Landing portion 628; Rotating shaft 642; Shaft holding part 644; Support section 645; First wing 646a; Second wing 646b; First fluid resistance portion 647a; Second fluid resistance portion 647b; Projecting portion 662; Jam protrusion 666; Guide portion 674; Gripping portion 675; Shear surface 691; Rear section 692; Home (693);
Length axis (L); Rotation center axis (C); Center of curvature (P1); Center of curvature (P2); Virtual circle (V); 1 plane (F);

Claims (14)

A pipe member sandwiched between the fluid pipe members to form a part of the fluid pipe,
Has a normal front portion and a rear portion, a first passage extending from the front portion to the rear portion, and a lateral opening opened to communicate with the first passage from a side with respect to the length axis of the first passage, the front A pipe member body adapted to be fixed to the fluid piping member in the portion and the rear portion,
A tubular window member inserted into the tube member main body through the lateral opening, and having a second passage communicating with the first passage and constituting a flow path of the tube member when inserted into the tube member body, A tubular window member configured such that at least a part is made of a transparent material, so that the passage is visible through the at least part;
As a holding member mounted on the tube member body, the tube member body fixed between the fluid piping members is engaged with the tube window member to hold the tube window member in a position sandwiched by the tube member body A retaining member displaceable between the position and a release position that releases retention for the tubular window member away from the tubular window member and allows the tubular window member to be removed from the tubular member body through the lateral opening. Equipped, tube member. According to claim 1,
The holding member is slidably mounted in the tube member body between the holding position and the release position in the direction of the length axis,
In the state where the tubular window member is in the release position, the retaining member is displaced in the direction of the length axis from the fitting position sandwiched between the tube member body and the fitting position, and the first passage And a communication release position in which communication of the second passage is released.
The tubular member is capable of being removed from the tubular member body through the lateral opening in the communication release position. According to claim 2,
The tube member main body has an intermediate portion between the front portion and the rear portion, and the lateral opening is formed in the intermediate portion,
The tubular window member is aligned in the direction of the longitudinal axis with the tubular member body in the fitting position, and is sealingly engaged with the front portion,
The retaining member becomes a normal member having a third passage, and in the retaining position, is engaged with the tubular window member and the rear portion so that the third passage is together with the first passage and the second passage The tube member constituting the flow path of the tube member. According to claim 2,
The holding member, in the state where the tubular window member is detached from the tube member body, is capable of being removed from the tube member body fixed between fluid piping members through the lateral opening. According to claim 2,
The holding member has a protruding portion that protrudes outward in the radial direction from the outer circumferential surface of the holding member, and the tubular member body has a receiving concave portion that receives the protruding portion,
The retaining member, when in the retaining position, is rotatable about the longitudinal axis relative to the tube member body, and is in a mating rotational position where the protruding features are aligned in the direction of the longitudinal axis relative to the receiving recess. At this time, the protruding portion is displaced to the release position while being accommodated in the receiving recess, and when not in the mating rotational position, the protruding feature interferes with the tube member body and cannot be displaced to the released position. absence. The method of claim 5,
The protruding shape portion has a locking outer edge portion extending along the outer circumferential surface of the tube member body, and a locking protrusion is formed on one of the inner circumferential surface of the pipe member body and the inner circumferential portion facing the outer circumferential surface, and is hung on the other side A concave portion is formed, and when the holding member is rotated from the mating rotational position in the holding position to become a locking rotational position, the locking projection and the locking recess are engaged so that rotation of the holding member is suppressed. . The method of claim 5,
The protruding shape portion has a locking projection on a sliding engagement surface that is slidingly engaged with the tubular window member,
The tubular window member has a locking recess for receiving the locking projection,
When the holding member is rotated from the mating rotational position in the holding position to become the engaging rotational position, the engaging protrusion and the engaging recess are engaged so that rotation of the holding member is suppressed. The method of claim 7,
A flexible member having a flexible portion in the direction of the longitudinal axis is formed on the sliding engagement surface of the holding member, and the engaging projection is formed on the flexible portion. The method according to any one of claims 2 to 8,
The tubular member body is formed at a side edge of the lateral opening and has a guide surface extending in the direction of the longitudinal axis, and the tubular window member has a guide portion protruding radially outward from the outer peripheral surface of the tubular window member,
When the tubular window member is inserted into the first passage from the lateral opening to the communication release position, the guide portion abuts on the guide surface so that the tubular window member is mated in the direction of the length axis with respect to the tubular member body. When the position becomes a position, and when the tubular window member is displaced from the communication release position to the fitting position, the guide portion slides on the guide surface. The method according to any one of claims 1 to 8,
And a flow indicator member disposed in the second passage of the tubular window member and displaced by a fluid flowing in the flow path. The method of claim 10,
The flow-indicating member becomes a wing member rotatably mounted in the circumferential direction with respect to the longitudinal axis to the tubular window member, and is detached from the tube member body together with the tubular window member. The method according to any one of claims 1 to 8,
When the tubular window member is fitted into the tube member main body, the window has an outer peripheral surface exposed to the outside, and an inner peripheral surface of the window positioned radially inside the outer peripheral surface of the window, and the inside of the second passage is the window outer peripheral surface and the The pipe member is made visible through the inner circumferential surface of the window, and the outer circumferential surface of the window is shaped such that the center of curvature of the outer circumferential surface of the window is between the center of curvature of the inner circumferential surface of the window and the outer circumferential surface of the window. The method of claim 12,
The cross-section of the outer peripheral surface of the window and the inner peripheral surface of the window is a circular arc member, respectively. The method according to any one of claims 1 to 8,
The lateral opening has first and second lateral openings formed at positions opposite in the radial direction of the first passageway, and the tubular window member is connected to the tube member body through either of the first and second lateral openings. The tube member which became available for installation.

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