JP3629393B2 - Drain plug device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a drain plug device that is used in a bathtub, a basin, or the like and opens and closes a drain port every time an operation unit is pushed.
[0002]
[Prior art]
Conventionally, there are technologies disclosed in JP-A-9-324451 and JP-A-11-107342 in drain plug devices.
In this prior art, as shown in FIG. 10, an internal hollow mechanical box 55 suspended from the plug lid 4 is detachably inserted into a bottomed cylindrical guide portion 3 disposed on the core of the drain port 11. Then, the support shaft 14 is inserted into the inside of the mechanical box 55 from the lower end of the mechanical box 55, the operation unit 6 is provided in the tank unit 1, and the release S having one end connected to the operation unit 6 is not disturbed. The inner tube s3 is wired along the inner surface of the tank portion 1 and the other end of the outer tube s3 is connected to the side portion of the plug lid 4, and the inner wire s4 is positioned in the mechanical box 55 through the plug lid 4. It has a configuration.
In this prior art, when the operation unit 6 is pushed, the inner wire s4 advances, the tip abuts on the upper end of the support shaft 14, and the inner wire s4 further advances to lift the plug lid 4 together with the mechanical box 55 to drain the water. The port 11 is opened (opened) to lock the thrust lock mechanism 7 installed in the mechanical box 55, and the thrust lock mechanism 7 is unlocked by the pushing operation of the next operation unit 6. The mouth 11 is closed (capped).
[0003]
Since this prior art can open and close the drain port 11 by pushing the release S wired in the tank portion 1, it is wired like a remote-operated drain plug device wired outside the bathtub or basin. It is possible to prevent an increase in cost due to an increase in the number of parts taking into account troublesome work, prevention of leakage associated with the outer wiring, and the like.
However, in the release S, the outer tube s3 is connected to the side portion of the plug lid 4 and the inner wire s4 alone is elastically bent in the introduction hole 44 having the bent portion 44a opened in the plug lid 4. Therefore, the contact frictional resistance at the introduction hole 44 of the synthetic resin plug lid 4 and the inner wire s4, particularly at the bent portion 44a is reduced. There is a problem in that it becomes very large, and a large force is required for the pushing operation of the operation unit 6 and the usability is deteriorated.
[0004]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described conventional circumstances, and an object of the present invention is to provide a remote-operated drainage plug device capable of smoothly and stably performing opening and closing operations of a plug lid over a long period of time. That is.
[0005]
[Means for Solving the Problems]
The technical means taken to solve the above-mentioned object is to support a hollow elevating body that is suspended from a stopper lid so that it can be moved up and down on a guide portion disposed on the core of the drainage port, and to lower the lower end of the elevating body. The support shaft is inserted into the elevator body, one end of the release is connected to the operation part provided in the tank part, the other end is connected to the stopper lid, and the inner wire is advanced by pushing operation of the operation part. In the drainage plug device in which the tip of the inner wire is abutted against the support shaft and the plug lid is lifted together with the lifting body to open the drainage port, the release introduces the outer tube into the plug lid from the side. The gist is to guide the inner wire into the lifting body by bending the tube in a downwardly curved manner in the lid and connecting the other end of the tube to the bottom portion of the stopper lid.
The inner wire described above is preferably a coil made of a metal material such as stainless steel, and the outer tube is preferably made of a tetrafluoroethylene resin.
The locking means has a locking strength such that the supporting shaft is locked with a force capable of artificially inserting and removing, or the locking is released only when a load of several tens of kilometers is applied. It is possible to design freely with the configuration adopted.
[0006]
According to this configuration, the sliding operation relationship between the inner wire and the stopper lid is completely eliminated, and the pushing operation force due to the frictional resistance is suppressed to a small value.
In addition, the coiled inner wire made of a metal material has sufficient durability against the pushing operation of the operation unit as compared with a single core wire or a core made of a stranded wire (inner wire), and has a predetermined Since it has elasticity, it has the flexibility which can respond also to bending. Outer tube made of tetrafluoroethylene resin (fluororesin) has excellent resistance to tensile force and heat resistance, almost no elongation due to sliding of inner wire, and variation in sliding stroke of inner wire There is no fear of the occurrence. In addition, since the frictional resistance is low, the slidability of the inner wire is not hindered even if it is bent with a small curvature, and the fluororesin particles serve as a lubricant even if the inner peripheral surface is scraped off at the sliding part. The smooth sliding of the inner wire is maintained for a long time. Therefore, the outer tube maintains a constant and smooth sliding performance of the inner wire for a long time even if it is bent downwardly in the stopper lid.
[0007]
Furthermore, it is preferable that the release is introduced and held with an upward inclined shape toward the center side of the stopper lid, and the introduction port facing the outside is slightly larger than the release diameter.
[0008]
In this configuration, the direction changing portion (reference S ′) of the release that is wired along the tank portion is positioned lower than the inlet at the outer end as shown in FIG. The elastic force generated in the direction changing portion (symbol S ′) is effectively used as a downward pressing force that pushes the stopper lid in the direction in which the stopper lid is in close contact with the drain outlet, and the clearance of the inlet is handled and used. The contact resistance generated between the release and the inlet opening is weakened to prevent cutting.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 7 show the first embodiment of the drain plug device of the present invention, FIG. 8 shows the second embodiment, and FIG. 9 shows the third embodiment. Yes. First, the first embodiment will be described. Reference symbol A is a drain plug device.
[0010]
The drain plug device A includes a drain port mounting member (drain port bracket) 2 that is attached to the bottom opening of the tank unit 1 and constitutes the drain port 11, and a guide unit 3 that is disposed on the core in the drain port 11. And a lid lid 4, an internal hollow elevating body 5 suspended from the cap lid 4, a support shaft 14 inserted from the lower end of the elevating body 5, and an operation portion detachably provided on the inner surface of the tank portion 1. 6, a release S provided over the operation unit 6 and the plug lid 4 described above, and a thrust lock mechanism 7 provided in the lift 5 described above.
[0011]
The lifting / lowering body 5 is a hollow cylindrical body in which the stopper lid 4 is integrally fixed to the upper end, and a support shaft 14 is inserted from a guide port 5 ′ at the lower end so as to be movable up and down.
[0012]
The guide portion 3 is a bottomed cylindrical body that is integrally formed with the drainage port mounting member (drainage bracket) 2 via a support bracket 21 having a cross-like shape in plan view or a bifurcated shape in plan view. The lift body 5 is slightly larger in diameter than the lift body 5 so that the lift body 5 can be vertically guided.
In addition, the drain port attachment member (drain port bracket) 2 has a drain space Z between the support brackets 21.
[0013]
As shown in FIGS. 2 and 4 to 7, the thrust lock mechanism 7 includes a rotary ring 17 rotatably provided at the upper end portion of the support shaft 14, and a locking tooth 151 provided on the side wall 15 of the elevating body 5. And a fixed tooth 152 provided at the bottom of the elevating body 5 and a spring 27 that urges the support shaft 14 in a pushing-up direction.
As shown in FIG. 4, the rotating ring 17 is fitted between the upper and lower flange portions 141 and 142 provided on the support shaft 14 so as not to be able to be removed, and is engaged with the locking teeth 151 and the fixed teeth 152 on both the upper and lower sides. .. Are formed at intervals of 90 degrees.
The engaging tooth portions 171 are formed in a substantially horizontal trapezoidal shape having an upper end portion and a lower end portion as inclined surfaces, and the upper end portion engages with a sawtooth portion 151a of a locking tooth 151 to be described later, and the lower end portion is It engages with a sawtooth portion 152a of a fixed tooth 152 to be described later.
The fixed teeth 152 and the locking teeth 151 are arranged to face each other so that the aforementioned sawtooth portions 152a and 151a face each other.
The fixed tooth 152 is configured by forming the above-described sawtooth portion 152a on the cap 25 that closes the bottom portion of the lifting body 5, specifically, the lower opening of the lifting body.
Four locking teeth 151 are formed on the side wall 15 of the elevating body 5 at intervals of 90 degrees, and the above-described sawtooth portions 151a are formed at the lower ends of the four locking teeth 151. Is formed.
Between the four locking teeth 151... In the elevating body 5, a groove portion 35 for guiding the upper engaging tooth portion 171 in the rotating ring 17 is formed.
The spring 25 is interposed between the bottom and the lower flange (not shown) that prevents the rotary ring 17 from being pulled out.
[0014]
The release S is a coil made of a flexible outer tube s1 formed of a tetrafluoroethylene resin material (fluororesin) and a metal material (for example, stainless steel) slidably inserted into the outer tube s1. Inner wire s2.
[0015]
The operation unit 6 connects the upper end of the outer tube s1 in the release S to the lower end of the release release guide main body 16 in which both the surface portion and the upper surface portion facing the inner surface of the tank portion 1 are opened, and connects the inner wire s2 to the release guide main body 16. The inside of the release guide main body 16 is inserted into the inside, and the opening portion of the upper surface of the release guide body 16 is closed by a push button 26 that moves up and down along the release guide main body 16. s2 is connected, and the back cover 46 is engaged with the surface portion of the release guide body 16 facing the tank portion 1, and the inner surface of the tank portion 1 is placed at a desired position on the inner surface of the tank portion 1 by a fixing means 56 such as a double-sided tape or suction cup on the back surface of the back cover 46 Installed.
[0016]
The plug lid 4 has an internal hollow shape composed of a disc portion 24 and a convex curved lid portion 34 engaged with the disc portion 24, and the center of the plug lid 4 from the side of the lid portion 34. The other end side (lower end side) of the release S is introduced and held in an upwardly inclined shape (for example, 15 degrees) toward the side, and the introduction port 341 is slightly larger in diameter than the release S diameter.
[0017]
The holding portion of the release S in the stopper lid 4 is a guide recessed in the top bottom of the rising portion 241 formed from the disc portion 24 and the inner surface of the lid portion 34 facing the rising portion 241. A holding space P for holding the release S in an upwardly inclined manner is formed with the bottom of the groove 342, and the introduction port 341 portion, which is the outer end portion of the holding space P, has a slightly larger diameter than the release S diameter. Thus, a clearance is secured between the release S and the edge of the inlet 341.
Reference numeral 343 denotes a pair of front and rear positioning pieces that hang from the edge of the guide groove 342 and abut against the both side surfaces of the rising portion 241 to sandwich the rising portion 241.
[0018]
Further, the holding space P is secured to a length slightly before the center of the stopper lid 4, the holding space P is used as a guide, the release S is bent downward from the tip, and the tip is The disc portion 24 is connected to the portion directly above the elevating body 5 in a watertight manner.
[0019]
The watertight connecting portion has a large-diameter concave portion 242 and a small-diameter concave portion 243 arranged in two upper and lower stages at the central portion of the disc portion 24 and is concentrically recessed, and only the inner wire s2 is provided at the bottom of the lower-diameter concave portion 243. Through the elevating body 5, the distal end of the outer tube s 1 in the release S is positioned at the bottom of the small-diameter recess 243, and a washer W fixed to the outer tube s 1 at the bottom of the large-diameter recess 242. A pair of rails 244 provided on the disk portion 24 are fitted into the large-diameter concave portion 242 with a part of the arranged O-ring O protruding upward, and the large-diameter concave portion 242 and the small-diameter concave portion 243 are sandwiched therebetween. A locking body 245 having a bifurcated locking piece 245a is detachably locked and the O-ring O is crushed, whereby the tip of the outer tube s1 is watertight to the disc portion 24. It has been linked.
[0020]
Reference numeral 246 is a drain hole, which is opened toward the portion excluding the clamping allowance of the packing 248 that is clamped by the packing receiver 247 projecting between the lower surface of the disk portion 24 and the lifting body 5, The hot water entering through clearance etc. is drained.
[0021]
The other end (lower end) of the inner wire s2 passes through a guide tube 248 that is suspended from the through hole 45 so as to contact the bottom of a recess 143 that is recessed on the upper end side of the support shaft 14 as shown in the figure. It is positioned to approach.
[0022]
Further, between the lower end portion of the support shaft 14 and the bottom portion of the guide portion 3, locking means M is configured to lock the lower end portion of the support shaft 14.
[0023]
The locking means M includes a locking hole 13 formed in the bottom of the guide portion 3 and a locking recess 144 provided in the vicinity of the lower end of the support shaft 14. The locking recess 144 is locked to the support shaft 14 so that the support shaft 14 cannot move up and down.
In the present embodiment, at least the lower end portion of the support shaft 14 is cut so as to be divided in half in the axial direction so as to have some elasticity.
This is for the purpose of removing the apparatus main body including the plug lid 4, the lifting body 5, and the support shaft 14 during maintenance.
[0024]
The operation of the drain plug device thus configured will be described.
The state shown in FIGS. 1 and 2 is a closed state. In this closed state, the upper and lower locking teeth 171, 171 of the rotating ring 17 are located in the upper end region of the groove 35.
1 and FIG. 2, that is, when the push button 26 is pushed from FIG. 5, the inner wire s2 advances and pushes the support shaft 14, but the lower end portion of the support shaft 14 is locked. The inner wire s <b> 2 that has lost its place because it is locked by the means M so as not to move up and down raises the elevating body 5. More specifically, the lower engaging tooth portion 171 of the rotating ring 17 is guided by the groove portion 35 while the spring 27 is compressed, and the lower engaging tooth portion 171 is fixed to the serrated tooth portion 152 a of the fixed tooth 152. And the lifting body 5 rises until it moves along the slope of the sawtooth portion 152a as shown in FIG. 6 (a) (the direction indicated by the arrow indicates the vertical movement of the lifting body 5 and The rotation direction of the rotating ring 17 is shown, and the same applies to the following (b), (c) and (d). Then, when the pushing operation of the push button 26 is stopped, the sawtooth portion 151a of the locking tooth 151 that descends by receiving the urging force of the spring 27 as shown in FIG. The stopper is engaged with the engaging tooth portion 171 and the stopper lid 4 is opened (plugged) while being spaced upward from the drain port 11 (FIG. 7).
When switching from the open state to the closed state again, the push button 26 is pushed to lift the elevating body 5 against the urging force of the spring 27 and rotate to the sawtooth portion 152a of the fixed tooth 152. The lower engaging tooth portion 171 is brought into contact with the ring 17 and the lower engaging tooth portion 171 is moved along the slope of the serrated tooth portion 152a (FIG. 6C). When the pushing operation of 26 is stopped, the upper engaging tooth portion 171 of the rotating ring 17 is guided by the inclined surface of the serrated tooth portion 151a of the locking tooth 151 that descends by the urging force of the spring 27. The tooth portion 171 is guided to the groove portion 35 to lower the elevating body 5 to the above-described FIGS. 1 and 2 and close (close) (FIG. 6D).
In addition, the release S which connects the operation part 5 and the stopper lid 4 is wired along the inner surface of the tank part 1 so as not to get in the way.
[0025]
Further, the release S is an upwardly inclined introduction holding, and the direction changing portion S ′ of the release S wired along the tank portion 1 is positioned lower than the introduction port 341 as shown in FIG. The elastic force can be utilized as the pressing force that pushes the plug lid 4 in the direction in which the stopper lid 4 is in close contact with the drain port 11 by the direction changing portion S ′.
[0026]
Next, the second embodiment shown in FIG. 8 will be described. In this embodiment, the thrust lock mechanism 7 is not provided in the elevating body 5 but the thrust lock mechanism 7 is provided in the operation portion 6. Since the other configuration is the same as that of the first embodiment, detailed description on the other configuration is omitted.
[0027]
The operation unit 6 includes a release guide main body 16, an operation shaft 36 that is inserted into the release guide main body 16 so as to be movable up and down and connects one end of the release S to a lower end, and a thrust provided between the operation shaft 36 and the release guide main body 16. This is a well-known structure comprising the lock mechanism 7 (see Japanese Patent Laid-Open Nos. 9-324451 and 11-107342).
The release guide body 16 is the same as the above-described embodiment in that the release guide body 16 is detachably fixed at a desired position in the tank 1 by a fixing means 56 such as a double-sided tape or a suction cup.
[0028]
The thrust lock mechanism 7 includes a fixed ring 37 provided at an upper end portion of the operation shaft 36 in the release guide main body 16, and a rotary ring 47 loosely fitted coaxially to the operation shaft 36 at a lower position thereof. A guide spring 57 provided on the inner surface of the release guide body 16, and a positioning spring 67 is interposed between the upper surface of the protrusion 161 provided around the middle of the operation shaft 36 and the rotary ring 47, and A spring 77 is interposed between the lower surface of the protrusion 161 and the bottom of the release guide main body 16.
The thrust lock mechanism 7 is configured to perform locking and unlocking on the lower end side of the vertical movement path each time the operating shaft 36 is pushed against the urging force of the spring 77.
[0029]
The fixing ring 37 has a sawtooth portion (not shown) at the lower portion thereof, and has several protrusions (not shown) on the side portion thereof. The rotating ring 47 has a serrated tooth (not shown) on the upper part that matches a serrated tooth (not shown) and has several protrusions (not shown) on its side. The guide portion 57 has a configuration in which guide grooves (not shown) in which the protrusions of the fixed ring 37 and the rotating ring 47 enter and saw-tooth portions (not shown) are alternately arranged. ing.
[0030]
Although not shown, the other end (lower end) of the release S is introduced and held in the stopper lid 4 from the side of the stopper lid 4 and the outer tube s1 is plugged as in the first and second embodiments described above. The outer tube s1 is bent downwardly in the lid 4 so that the tip (the other end) of the outer tube s1 is connected to the bottom of the stopper lid 4 in a watertight manner, and the inner wire s2 is brought into contact with the bottom of the recess 143 at the upper end of the support shaft 14. Or it is close.
[0031]
The operation of the drain plug device of the second embodiment having such a configuration will be described. FIG. 8A shows that the thrust lock mechanism 7 is in the unlocked state, that is, the plug lid 4 is in the open (closed) state. is there. When the operating shaft 36 is pushed from this state, the inner wire s2 moves forward and pushes the support shaft 14, but the lower end of the support shaft 14 is locked by the locking means M so that it cannot move. The inner wire s2 having lost the same as in the first and second embodiments described above raises the lifting body 5 having the stopper lid 4 at the upper end. As a result, the rotating ring 47 is pushed down below the guide portion 57 by the fixed ring 37, and when the sawtooth portion of the rotating ring 47 contacts the sawtooth portion of the fixed ring 37 and slightly rotates, the pushing is stopped. In response to the urging force of the spring 77, the protrusion of the rotating ring 47 engages with the sawtooth portion of the guide portion 57 and locks at the descending end side, so that the drain port 11 is opened (opened) ( FIG. 8B).
When the operating shaft 36 is pushed, the sawtooth portion of the rotating ring 47 is slightly rotated by the sawtooth portion of the fixed ring 37. When the pushing is stopped, the sawtooth portion of the rotating ring 47 is guided by the sawtooth portion. After rotating slightly in contact with the serrated tooth portion of the portion 57, the projection enters the guide groove and the lock is released, and the stopper lid 4 naturally falls together with the lifting body 5 to close the drain port (plugging). FIG. 8 (a).
[0032]
Next, a third embodiment shown in FIG. 9 will be described. In this embodiment, without using the thrust lock mechanism 7, the plug lid 4 is raised together with the elevating body 5 to open the drain port 11 (open plug). And a drain plug device A for closing (closing) the drain port 11.
The release S is introduced into the stopper lid 4 from the side of the stopper lid 4 and held, and the outer tube s1 is bent downwardly in the stopper lid 4 so that the tip (the other end) of the outer tube s1 is plugged. It is connected to the bottom portion of the lid 4 and the inner wire s2 is positioned so as to contact or approach the bottom of the recess 143 provided in the upper end side of the support shaft 14 of the support shaft 14. This is the same as in the second embodiment.
[0033]
In this embodiment, a guide tube 76 protrudes from the bottom of the release guide main body 16 of the operation unit 6, the operation shaft 36 is pressed against the guide tube 76 so as to move up and down, and an inner wire is connected to the operation shaft 36. The upper end which is one end of s2 is attached and pushed to raise the plug lid 4 together with the lifting body 5 to open (open) the drain port 11 as in the first and second embodiments described above. The lowering position of the operating shaft 36 at that time is held by the pressure contact force with the guide cylinder 76, and the operating shaft 36 is lifted when the inner wire s2 moving forward by the pulling operation of the operating shaft 36 is returned to the original state. The position is held by a pressure contact force with the guide cylinder 76, and the elevating body 5 and the plug lid 4 are naturally dropped to close the drainage port 11 (plugging).
In this embodiment, since a pulling operation is required, it is preferable to use an inner wire made of a single core wire or a stranded wire rather than a coiled inner wire s2 made of a metal material.
[0034]
【The invention's effect】
As described above, according to the present invention, the release is introduced into the plug lid from the side, bent downward in the same shape, and the tip of the outer tube is connected to the bottom portion of the plug lid to raise and lower the inner wire. Since the inner wire is guided by the outer tube even in the stopper lid, the inner wire is elastically bent downward at the bent portion of the introduction hole in the stopper lid. Compared with the case where the plug lid is bent and penetrated, the frictional resistance during the pushing operation can be greatly reduced, and the operability is very good.
In addition, it has sufficient durability against the pressing force and flexibility that can cope with the bent part, and further, it is a coil-like shape that slides smoothly without requiring a large force to push the operation part. The inner wire has the same degree of flexibility as the inner wire, has a predetermined durability against tensile force, high heat resistance, good dimensional retention, and smooth sliding of the inner wire over a long period of time The outer tube is made of a fluororesin outer tube that is maintained and the properties of the release are utilized, so that the outer tube is inserted into the stopper lid from its side as described above and curved downward. Even when it is bent and connected to the bottom part of the stopper lid, the inner wire can be stably and smoothly slid and the operation part can be pushed with a very light force. Operability is improved.
Moreover, if the release is introduced with an upward inclined shape toward the center side of the stopper lid, and the introduction port facing the outside is slightly larger than the release diameter, the release that is wired along the tank portion Direction in which the direction changing portion (reference S ′) is positioned lower than the introduction port (see FIG. 2), and the elastic restoring force generated in the direction changing portion (reference S ′) is in close contact with the drain outlet. It can be effectively used as a pressing force to be pushed, and the clearance at the inlet can be effectively used as a play allowance to prevent the release from being cut.
[Brief description of the drawings]
FIG. 1 is a front cross-sectional view showing a closed state of a first embodiment.
FIG. 2 is an enlarged sectional view of a main part showing a closed state.
FIG. 3 is an exploded perspective view of the plug lid, partially cut away.
FIG. 4 is an exploded perspective view showing a lifting body and a thrust lock mechanism inside thereof.
FIG. 5 is a development view showing the relationship between the engaging tooth portion, the locking tooth, and the fixed tooth of the rotating ring.
FIG. 6 is a development view showing the relationship between the engaging tooth portion, the locking tooth, and the fixed tooth of the rotating ring. FIG. (B) shows a state in the middle of opening of the plug that is moving along the slope of the serrated tooth portion of the fixed tooth, and (b) shows that the pushing operation is stopped and the engaging tooth portion on the upper side of the rotating ring is engaged with the locking tooth. (C) shows a state in which it is locked to the serrated tooth portion of the rotating ring, and (c) is a further pushing operation, and the lower engaging tooth portion of the rotating ring is the serrated tooth portion of the engaging tooth (D) shows a state in which the pushing operation is stopped, and the upper engaging tooth portion of the rotating ring is guided by the inclined surface of the serrated tooth portion of the locking tooth, and further into the groove portion. The state which is moved and tries to close a drain outlet is shown.
FIG. 7 is an enlarged cross-sectional view of the main part showing the open state.
FIGS. 8A and 8B are enlarged cross-sectional views showing an operation unit according to the second embodiment, in which FIG. 8A shows a closed state and FIG. 8B shows an opened state.
FIG. 9 is an enlarged cross-sectional view illustrating an operation unit according to a third embodiment.
FIG. 10 is a front sectional view of a conventional drain plug device.
[Explanation of symbols]
A: Drainage device 11: Drainage port 2: Drainage port attachment member 3: Guide part 4: Cap lid 5: Lifting body 14: Support shaft S: Release s2: Inner wire s1: Outer tube 1: Tank part 341: Inlet

Claims (3)

An internal hollow elevating body suspended from the stopper lid is supported on the guide portion arranged in the core of the drain outlet so that it can move up and down, and a support shaft is inserted into the elevating body from the lower end of the elevating body, One end of the release is connected to the operation part provided in the part, the other end is connected to the stopper lid, and the inner wire is advanced by pushing the operation part, and the tip of the inner wire is abutted against the support shaft and moved up and down. In the drain plug device that raises the plug lid together with the body to open the drain port, the release introduces the outer tube into the plug lid from the side and bends the curved tube downward in the plug lid. A drain plug device characterized in that the other end is connected to the bottom portion of the plug lid and the inner wire is guided into the elevating body. The said release is comprised with the coil-shaped inner wire which consists of metal materials, and the outer tube which consists of tetrafluoroethylene resin which guides the inner wire so that sliding is possible. Drain plug device. 3. The drain plug according to claim 2, wherein the release is introduced and held with an upwardly inclined shape toward the center side of the plug lid, and the introduction port facing the outside is slightly larger in diameter than the release diameter. apparatus.

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