JP6682071B2 - Water stop structure - Google Patents

Description

  The present invention relates to a water blocking structure in drainage piping.

  BACKGROUND ART Conventionally, as a water stop structure in a drainage pipe, a structure using a packing made of an elastic member such as rubber attached to a drainage tool is known. In the waterproof structure using the packing, the packing is stopped by bringing the packing into close contact with a drain plug or another pipe.

The water stop structure shown in FIG. 15 is a water stop structure including a valve body as a drainage tool and a packing attached to the valve body.
The valve body is a lid body around which packing is fitted, and is provided with a lock mechanism called a thrust lock mechanism in the lower part.
The thrust lock mechanism includes a lock shaft, a rotary gear, a fixed gear, and a spring. When the rotary gear and the fixed gear mesh with each other, the valve body can be switched between a raised state and a lowered state for each pushing operation. The lock shaft is fitted on the back surface of the valve body and moves up and down based on the pushing operation applied to the valve body. The rotary gear is arranged in the middle of the lock shaft and is driven by vertical movement of the lock shaft, but is rotatable with respect to the lock shaft. The fixed gear is composed of an upper gear and a lower gear, the upper gear and the lower gear have inclined teeth for rotating the rotary gear by a predetermined angle, and the upper gear has locking teeth that mesh with the rotary gear.

  The operation of the above conventional water blocking structure will be described below.

First, when a pushing operation is directly applied to the valve body from a state where the valve body is raised, the lock shaft and the rotary gear are pushed down in accordance with the pushing operation. At this time, the rotating gear is brought into sliding contact with the inclined teeth of the lower gear by the pushing down and rotates by a predetermined angle. When the pushing operation is completed, the lock shaft and the rotary gear are slightly raised due to the repulsion of the spring, but the raised rotary gear is pressed against the slanted teeth of the upper gear and comes into sliding contact therewith, and further rotated by a predetermined angle and the locking teeth are engaged. Mesh with. At this time, the engagement keeps the valve body in a lowered state lower than the initial state, and the packing attached to the valve body comes into close contact with the drainage port, so that the drainage port is in a water stop state.
When the valve body is pushed again from the lowered state of the valve body, the lock shaft and the rotary gear are pushed down to bring the rotary gear into sliding contact with the inclined teeth of the lower gear, thereby rotating the rotary gear again by a predetermined angle. The meshing with the upper gear is released. At this time, the valve body rises due to the repulsion of the spring, the packing is separated from the drain port, and the water stop state is released.
That is, in the water stop structure, the thrust lock mechanism opens and closes the drain port by switching the valve body between the raised state and the lowered state for each pushing operation.

Here, as shown in FIG. 16, in the water blocking structure, as described above, the lowered state is not maintained unless the valve body is pushed down to the maximum and then slightly raised to the height at which the rotary gear and the upper gear mesh with each other. (In FIG. 16, the state in which the valve body is lowered to the maximum is shown by a two-dot chain line.)
Therefore, the packing cannot stop the water unless it absorbs the height H from the state where the valve body is lowered to the maximum to the height position where the rotary gear and the upper gear mesh with each other. Therefore, the packing having the conventional water-stop structure has a flexible fin portion, and the fin portion is deformed so as to warp at the periphery of the drainage port to absorb the height H.

  In addition to the above, as a water blocking structure using a packing, a water blocking lid as a drainage tool and a water blocking structure using a packing attached to the water blocking lid are known as shown in FIG. The water blocking lid is a lid member around which packing is fitted, and when placed on the drain port, the packing comes into close contact with the peripheral edge of the drain port to stop water.

Japanese Patent Laid-Open No. 10-165322 Japanese Patent Laid-Open No. 8-68091

In the above-mentioned conventional water-stopping structure, in the water-stopping structure by the valve body, when the fin part of the packing is largely deformed when the valve body is descended, the fin part may contact the valve body or the packing itself. . At this time, as shown in FIG. 18, the fin portion and the contact surface are in close contact with each other with no gap over the entire circumference, whereby a vacuum state is created between the fin portion and the contact surface, and the deformed fin portion contacts the contact surface. There was a problem that it stuck to and could not return to the original. In this state, even if the valve body is in the lowered state, the packing remains separated from the peripheral edge of the drain port, and it becomes impossible to stop the drain port.
The above problem is likely to occur particularly when the valve body is pushed in while the hot water is stored in the tank body because the surface tension of the water acts between the fin portion and the contact surface.

  Further, the above problem is not limited to the case where the lock mechanism is the thrust lock mechanism, and the same problem occurs when the lock mechanism using another cam structure such as the one-way cam described in Patent Document 1 is used. It happens.

  Further, as shown in FIG. 19, the above problem also occurs in a water-stop structure having a water-stop lid. In particular, in a water-stop lid that can stop water in tanks of different materials, shapes, etc., the fins are configured to be greatly deformed to absorb the difference in the shape of the drainage port, so the above The problem arises.

  The present invention has been made in view of the above problems, and in a water blocking structure using a packing having a flexible fin portion, a water blocking defect due to the fin portion sticking to the contact surface. The purpose is to provide a waterproof structure that prevents

The present invention according to claim 1 is a drainage tool,
In a waterproof structure equipped with a packing that is attached to a drainage tool and is watertight with other members,
The packing is equipped with elastic fins,
The drainage tool or packing includes a contact surface that contacts the deformed fin portion,
Equipped with a sticking prevention mechanism that prevents the fins from sticking to the drainage tool or packing itself ,
The sticking prevention mechanism is a water-stopping structure characterized in that a gap is formed on the contact surface so as to connect to the outside of the contact surface .

  In addition, the above "the fin part sticks to the drainage tool or the packing itself" means that the fin part comes into contact with the drainage tool or the packing itself and cannot be returned to the original state in the contact state. It does not mean merely abutting without a gap.

The present invention according to claim 2 is the water blocking structure according to claim 1, wherein the sticking prevention mechanism is a groove portion.

  The “groove portion” includes a groove, a recess, a groove formed by a step, and the like, and when it is recessed from other portions, it is included in the “groove portion”.

The present invention of claim 3 is a waterproofing structure according to claim 1, wherein said sticking prevention mechanism is protrusion.

The above-mentioned "projection portion" includes a protrusion, a convex portion, a protrusion due to a step, and the like, and when it is projected from other portions, it is included in the "projection portion".
Further, the sticking prevention mechanism may be formed by both the "groove portion" and the "projection portion".

In the present invention according to claim 4 , the sticking prevention mechanism comprises:
The water stop structure according to any one of claims 1 to 3 , which is provided in the drainage tool.

According to the present invention of claim 5 , the sticking prevention mechanism comprises:
It is water stopping structure according to any one of claims 1 to 4, characterized in that provided in the packing.

According to a sixth aspect of the present invention, in which the drainage tool is a valve body that opens and closes a drainage port of a tank body,
The valve body is in each press operation is applied to the valve body, according to any one of claims 1 to 5, characterized in that it comprises a locking mechanism for switching the lowered position and raised position of the valve body It has a waterproof structure.

According to the present invention described in claim 1, since the water blocking structure is provided with the sticking prevention mechanism, it is possible to prevent water blocking failure due to the fin portion sticking to the drainage tool or the packing itself. Further , since the sticking prevention mechanism is formed on the contact surface, sticking of the fin portion can be more effectively prevented.
According to the present invention described in claims 2 to 5 , it is possible to indicate the specific shape and position of the sticking prevention mechanism.
The present invention described in claims 1 to 5 is particularly useful for a valve body having a lock mechanism, as shown in claim 6 .

It is sectional drawing and the principal part enlarged view which show the construction state of 1st embodiment. (A) sectional view showing a valve body (b) It is an A-A 'sectional view of (a). It is sectional drawing which shows the raising state of a valve body. It is a sectional view showing the state where the valve body is pushed down and the packing is largely deformed. It is a reference drawing which shows operation | movement of a thrust lock mechanism. It is sectional drawing which shows the lowered state of a valve body. It is sectional drawing and the principal part enlarged view which show the construction state of 2nd embodiment. (A) sectional view showing a valve body (b) It is an A-A 'sectional view of (a). It is sectional drawing which shows the raising state of a valve body. It is a sectional view showing the state where the valve body is pushed down and the packing is largely deformed. It is a reference drawing which shows operation | movement of a thrust lock mechanism. It is sectional drawing which shows the lowered state of a valve body. It is an A-A 'sectional view of (a) sectional view (b) (a) showing the valve body concerning a third embodiment. It is an exploded sectional view showing a fourth embodiment. It is sectional drawing which shows the conventional water stop structure. It is sectional drawing which shows the descending state of the valve body in the conventional water stop structure. It is an exploded sectional view showing other waterproof structures. It is sectional drawing which shows the state which the packing stuck to the contact surface. It is sectional drawing which shows the state which the packing stuck to the contact surface in other water stop structures.

  The water blocking structure of the present invention will be described below with reference to the drawings. The following description is for facilitating the understanding of the embodiments, and the present invention is not limited to the understanding. In addition, in the following embodiments, unless otherwise specified, the positional relationship between the upper, lower, left, and right members will be described based on the construction state shown in FIG. 1.

  As shown in FIGS. 1 to 6, the present embodiment has a water blocking structure in which a valve body 5 as a drainage tool stops water at a drainage port 1 formed in a tank body B.

The tank body B is a box-like wash-basin with an open top, and the drain plug 2 is attached to the opening formed in the bottom surface.
The drain plug 2 is a tubular member having a flange at the upper end, and a drain port 1 for draining drainage from the tank B is formed inside the drain plug 2, and a male screw is screwed on the outer periphery of the tubular portion. It is carved. The cylindrical portion of the drain plug 2 is inserted into the opening formed on the bottom surface of the tank body B and is screwed with the connection pipe 3 arranged on the back surface of the tank body B. The connection pipe 3 is screwed to the lower end of the drain plug 2 by a female screw threaded on the upstream side, and its downstream side is connected to a drain trap (not shown) using a nut and packing.
The drain trap is a pipe member that is bent in a substantially S shape when viewed from the side, and is capable of storing a part of the drain water that has flowed into the bent portion. The drainage trap can form a sealed water by filling a part of the drainage flow path with the drainage, and can prevent odor and backflow of harmful insects from the downstream side.

  The valve body 5 is a lid member in which a packing 7 is fitted around the valve body 5 and the upper end of a thrust lock mechanism 10 as a lock mechanism is attached to the back surface. The drain port 1 is closed in a watertight manner.

  As shown in FIG. 2, the valve body 5 is provided with an abutting surface 9 that abuts when the packing 7 is elastically deformed on the back surface, and a plurality of groove portions 6 are formed on the abutting surface 9 as a sticking prevention mechanism. There is. The groove 6 is a groove formed at three positions on the contact surface 9 every 120 degrees, and extends radially from the center of the valve body 5 toward the outer periphery. The outer end of the groove portion 6 is arranged outside the outer diameter of the packing 7.

  The packing 7 is made of an elastic member such as rubber or silicon, has a substantially circular shape in plan view, and has a fin portion 8 on the outer peripheral side. The fin portion 8 is a thin annular portion extending in the outer peripheral portion of the packing 7, and has flexibility enough to elastically deform when it comes into contact with the drain plug 2. Note that, as shown in FIG. 3, the upper surface side of the fin portion 8 does not contact the contact surface 9 in a normal state. On the other hand, as shown in FIG. 4, the upper surface side of the fin portion 8 is bent back when the fin portion 8 is largely deformed, and abuts on the projection portion 25 formed on the abutting surface 9.

The thrust lock mechanism 10 is a lock mechanism arranged or formed inside the casing 11, and includes a lock shaft 12, a rotating cam 13, a fixed cam 15, a cam groove 18, and a spring 19, and a perforated plate 21 is formed on the outer periphery thereof. ing. 5 is a reference diagram for facilitating the understanding of the present invention, in which the rotary cam 13, the fixed cam 15 and the like of the thrust lock mechanism 10 are shown in a developed state.
The lock shaft 12 is a shaft portion that penetrates through the center of the thrust lock mechanism 10. The upper end of the lock shaft 12 is fitted to the back surface of the valve body 5 and is biased upward by the repulsion of the spring 19. The rotation cam 13 is rotatably attached to the lock shaft 12 in the middle thereof.
The rotary cam 13 is a cam member that is attached to the axial movement of the lock shaft 12 and is rotatably attached to the lock shaft 12 as an axis. Are formed.
The fixed cam 15 includes an upper gear 16 and a lower gear 17. The upper gear 16 is formed on the inner circumference of the casing 11, and is provided with saw-toothed inclined teeth 16 a that rotate the rotating cam 13, and locking teeth 16 b that mesh with the rotating cam 13. The lower gear 17 is formed around the entire upper end of the lower member 20 inserted from the lower end of the casing 11, and has saw blade-shaped inclined teeth 17 a for rotating the rotating cam 13.
The cam grooves 18 are groove-shaped portions extending between the upper gears 16 at predetermined intervals in the axial direction of the casing 11.
The spring 19 is an elastic member made of metal, the lower end of which is in contact with the lower member 20 and biases the lock shaft 12 upward.
It has a mesh-shaped collecting part for collecting hair and the like mixed in the drainage flowing from the tank B of the plate 21 and its outer diameter is substantially the same as the inner diameter of the drain plug 2.

  The water blocking structure composed of the above members operates as follows.

First, as shown in FIG. 3, when the valve body 5 is in a raised state, the rotary teeth 14 of the rotary cam 13 are arranged in the cam groove 18. In this state, the rotary cam 13 and the fixed cam 15 are not meshed with each other, and the valve body 5 fitted to the upper end of the lock shaft 12 is held in the raised state by the repulsion of the spring 19. Further, when the valve body 5 is raised, the packing 7 is separated from the peripheral edge of the drainage port 1.
When a direct pushing operation is applied to the valve body 5 in the raised state, the valve body 5, the lock shaft 12, and the rotary cam 13 are pushed down in accordance with the pushing operation. Then, the rotating teeth 14 of the rotating cam 13 are brought into sliding contact with the inclined teeth 17a of the lower gear 17 by the pushing down and rotate by a predetermined angle. At this time, as shown in FIG. 4, the fin portion 8 of the packing 7 bends upward by contacting the upper surface of the drain plug 2, and the upper surface of the fin portion 8 contacts the contact surface 9 of the valve body 5. . However, since the groove portion 6 as the sticking prevention mechanism is formed on the contact surface 9, the vacuum state is not achieved.
When the pushing operation is completed, the lock shaft 12 and the rotating cam 13 are lifted by the repulsion of the spring 19. The rotary teeth 14 of the rotary cam 13 are pressed against the slanted teeth 16a of the upper gear 16 by the repulsion of the spring 19 and are brought into sliding contact with each other to rotate a predetermined angle and mesh with the locking teeth 16b. (FIG. 5 (a)) At this time, the valve body 5 shifts from the state shown in FIG. 4 to the state shown in FIG. 6, and the valve body 5 is kept in the lowered state by the engagement of the rotary cam 13 and the fixed cam 15 (upper gear 16). To be done. Further, at this time, the fin portion 8 is gradually deformed while being in contact with the drain plug 2, so that the packing 7 and the peripheral edge of the drain port 1 (the drain plug 2) are maintained in close contact with each other. That is, the packing 7 has a height H from the state where the valve body 5 is lowered to the maximum to the height position where the rotary cam 13 and the upper gear 16 are meshed with each other due to elastic deformation of the flexible fin portion 8. Absorb. In addition, in FIG. 6, the position of the valve body 5 when the valve body 5 is lowered to the maximum is shown by a two-dot chain line.

When the valve body 5 is pushed again from the lowered state of the valve body 5, the lock shaft 12 and the rotary cam 13 are pushed down so that the rotary teeth 14 of the rotary cam 13 slide with the inclined teeth 17a of the lower gear 17. When they come into contact with each other and rotate by a predetermined angle, the meshing with the locking teeth 16b of the upper gear 16 is released. At this time, the valve body 5 becomes the state shown in FIG. 4 again, and the fin portion 8 is largely deformed by being pressed against the drain plug 2, but since the groove portion 6 is formed in the contact surface 9, for example, the tank body. Even if a pushing operation is applied to the valve body 5 while hot water is stored in B, the fin portion 8 does not remain stuck to the contact surface 9 of the valve body 5.
When the pushing operation is completed, the lock shaft 12 and the rotary cam 13 are lifted by the repulsion of the spring 19, and the rotary teeth 14 of the rotary cam 13 are pressed against the slanted teeth 16a of the upper gear 16 to slide, so that the cam groove. Since the valve body 5 is housed in the housing 18 (FIG. 5B), the valve body 5 is kept in the raised state by the urging of the spring 19. Further, the packing 7 is separated from the drain plug 2 and the drain port 1 is opened, but since the packing 7 is prevented from sticking to the contact surface 9 by the protrusion 25, the packing 7 sticks to the contact surface 9. It is possible to return to the original state without.

As described above, the first embodiment of the present invention has a structure in which the thrust lock mechanism 10 switches between the raised state and the lowered state of the valve body 5. Therefore, as shown in FIGS. 5 and 6, when the valve body 5 is switched to the lowered state, the rotation tooth 14 of the rotary cam 13 and the locking tooth 16b of the upper gear 16 are pushed after the valve body 5 is pushed down to the maximum. It rises by the height H up to the meshing height position. However, in the present invention, the packing 7 includes the flexible fin portion 8, and the fin portion 8 is elastically deformed to absorb the height H, and the valve body 5 maintains the closed state of the drainage port 1. can do.
Even when the upper surface of the fin 8 and the contact surface 9 of the valve body 5 may come into contact with each other during the elastic deformation, the contact surface 9 is provided with the groove portion 6 as a sticking prevention mechanism. Therefore, it is possible to prevent the fin portion 8 from being stuck to the contact surface 9. Even if a pressing operation is applied to the valve body 5 while hot water is stored in the tank body B, a slight gap is formed by the groove portion 6, so that the upper surface of the fin portion 8 and the contact surface are formed. The hot water and the like that have entered between 9 and 9 are discharged from the gap, and a vacuum state due to surface tension does not occur. Further, since the outer end of the groove portion 6 is arranged outside the outer diameter of the packing 7, when the fin portion 8 is elastically deformed, it is possible to always form a gap with the contact surface 9. .

  The second embodiment of the present invention will be described below.

  As shown in FIGS. 7 to 12, the present embodiment has a water blocking structure in which the drainage port 1 formed in the tank B is stopped by the valve body 5 as a drainage tool.

The tank body B is a box-like wash-basin with an open top, and the drain plug 2 is attached to the opening formed in the bottom surface.
The drain plug 2 is a tubular member having a flange at the upper end, and a drain port 1 for draining drainage from the tank B is formed inside the drain plug 2, and a male screw is screwed on the outer periphery of the tubular portion. It is carved. The cylindrical portion of the drain plug 2 is inserted into the opening formed on the bottom surface of the tank body B and is screwed with the connection pipe 3 arranged on the back surface of the tank body B. The connection pipe 3 is screwed to the lower end of the drain plug 2 by a female screw threaded on the upstream side, and its downstream side is connected to a drain trap (not shown) using a nut and packing.
The drain trap is a pipe member that is bent in a substantially S shape when viewed from the side, and is capable of storing a part of the drain water that has flowed into the bent portion. The drainage trap can form a sealed water by filling a part of the drainage flow path with the drainage, and can prevent odor and backflow of harmful insects from the downstream side.

  The valve body 5 is a lid member in which a packing 7 is fitted around the valve body 5 and the upper end of a thrust lock mechanism 10 as a lock mechanism is attached to the back surface. The drain port 1 is closed in a watertight manner.

  As shown in FIG. 7, the valve body 5 has a contact surface 9 on the back surface that abuts when the packing 7 is elastically deformed, and a plurality of protrusions 25 are formed on the contact surface 9 as sticking prevention mechanisms. ing. The protrusions 25 are protrusions formed at three positions on the contact surface 9 at 120 ° intervals, and extend radially from the center of the valve body 5 toward the outer periphery. The outer end of the protrusion 25 is arranged outside the outer diameter of the packing 7.

  The packing 7 is made of an elastic member such as rubber or silicon, has a substantially circular shape in plan view, and has a fin portion 8 on the outer peripheral side. The fin portion 8 is a thin annular portion extending in the outer peripheral portion of the packing 7, and has flexibility enough to elastically deform when it comes into contact with the drain plug 2. Note that, as shown in FIG. 9, the upper surface side of the fin portion 8 does not contact the contact surface 9 in a normal state. On the other hand, as shown in FIG. 10, the upper surface side of the fin portion 8 is bent back when the fin portion 8 is largely deformed, and abuts on the projection portion 25 formed on the abutting surface 9.

The thrust lock mechanism 10 is a lock mechanism arranged or formed inside the casing 11, and includes a lock shaft 12, a rotating cam 13, a fixed cam 15, a cam groove 18, and a spring 19, and a perforated plate 21 is formed on the outer periphery thereof. ing. Note that FIG. 11 is a reference diagram for facilitating the understanding of the invention, in which the rotary cam 13, the fixed cam 15 and the like of the thrust lock mechanism 10 are shown in a developed state.
The lock shaft 12 is a shaft portion that penetrates through the center of the thrust lock mechanism 10. The upper end of the lock shaft 12 is fitted to the back surface of the valve body 5 and is biased upward by the repulsion of the spring 19. The rotation cam 13 is rotatably attached to the lock shaft 12 in the middle thereof.
The rotary cam 13 is a cam member that is attached to the axial movement of the lock shaft 12 and is rotatably attached to the lock shaft 12 as an axis. Are formed.
The fixed cam 15 includes an upper gear 16 and a lower gear 17. The upper gear 16 is formed on the inner circumference of the casing 11, and is provided with saw-toothed inclined teeth 16 a that rotate the rotating cam 13, and locking teeth 16 b that mesh with the rotating cam 13. The lower gear 17 is formed around the entire upper end of the lower member 20 inserted from the lower end of the casing 11, and has saw blade-shaped inclined teeth 17 a for rotating the rotating cam 13.
The cam grooves 18 are groove-shaped portions extending between the upper gears 16 at predetermined intervals in the axial direction of the casing 11.
The spring 19 is an elastic member made of metal, the lower end of which is in contact with the lower member 20 and biases the lock shaft 12 upward.
It has a mesh-shaped collecting part for collecting hair and the like mixed in the drainage flowing from the tank B of the plate 21 and its outer diameter is substantially the same as the inner diameter of the drain plug 2.

  The water blocking structure composed of the above members operates as follows.

First, as shown in FIG. 9, the rotary teeth 14 of the rotary cam 13 are arranged in the cam groove 18 when the valve body 5 is raised. In this state, the rotary cam 13 and the fixed cam 15 are not meshed with each other, and the valve body 5 fitted to the upper end of the lock shaft 12 is held in the raised state by the repulsion of the spring 19. Further, when the valve body 5 is raised, the packing 7 is separated from the peripheral edge of the drainage port 1.
When a direct pushing operation is applied to the valve body 5 in the raised state, the valve body 5, the lock shaft 12, and the rotary cam 13 are pushed down in accordance with the pushing operation. Then, the rotating teeth 14 of the rotating cam 13 are brought into sliding contact with the inclined teeth 17a of the lower gear 17 by the pushing down and rotate by a predetermined angle. At this time, as shown in FIG. 10, the fin portion 8 of the packing 7 bends upward by contacting the upper surface of the drain plug 2, and the upper surface of the fin portion 8 contacts the contact surface 9 of the valve body 5. . However, since the protrusion 25 as a sticking prevention mechanism is formed on the contact surface 9, a slight gap is formed between the upper surface of the fin 8 and the contact surface 9 of the valve body 5, and the vacuum is generated. It does not go into a state.
When the pushing operation is completed, the lock shaft 12 and the rotating cam 13 are lifted by the repulsion of the spring 19. The rotary teeth 14 of the rotary cam 13 are pressed against the slanted teeth 16a of the upper gear 16 by the repulsion of the spring 19 and are brought into sliding contact with each other to rotate a predetermined angle and mesh with the locking teeth 16b. (FIG. 11 (a)) At this time, the valve body 5 shifts from the state shown in FIG. 10 to the state shown in FIG. 12, and the valve body 5 is kept in the lowered state by the engagement of the rotary cam 13 and the fixed cam 15 (upper gear 16). To be done. Further, at this time, the fin portion 8 is gradually deformed while being in contact with the drain plug 2, so that the packing 7 and the peripheral edge of the drain port 1 (the drain plug 2) are maintained in close contact with each other. That is, the packing 7 has a height H from the state where the valve body 5 is lowered to the maximum to the height position where the rotary cam 13 and the upper gear 16 are meshed with each other due to elastic deformation of the flexible fin portion 8. Absorb. Note that, in FIG. 12, the state where the valve body 5 is lowered to the maximum is shown by a two-dot chain line.

When the valve body 5 is pushed again from the lowered state of the valve body 5, the lock shaft 12 and the rotary cam 13 are pushed down so that the rotary teeth 14 of the rotary cam 13 slide with the inclined teeth 17a of the lower gear 17. When they come into contact with each other and rotate by a predetermined angle, the meshing with the locking teeth 16b of the upper gear 16 is released. At this time, the valve body 5 is again in the state shown in FIG. 10, and the fin portion 8 is largely deformed by being pressed against the drain plug 2, but since the contact surface 9 is formed with the protrusion 25, for example, the tank Even if the valve body 5 is pushed while the hot water is stored in the body B, the fin portion 8 does not remain stuck to the contact surface 9 of the valve body 5.
When the pushing operation is completed, the lock shaft 12 and the rotary cam 13 are lifted by the repulsion of the spring 19, and the rotary teeth 14 of the rotary cam 13 are pressed against the slanted teeth 16a of the upper gear 16 to slide, so that the cam groove. Since the valve body 5 is housed in the valve 18 (FIG. 11B), the valve body 5 is kept in the raised state by the urging of the spring 19. Further, the packing 7 is separated from the drain plug 2 and the drain port 1 is opened, but since the packing 7 is prevented from sticking to the contact surface 9 by the protrusion 25, the packing 7 sticks to the contact surface 9. It is possible to return to the original state without.

As described above, the first embodiment of the present invention has a structure in which the thrust lock mechanism 10 switches between the raised state and the lowered state of the valve body 5. Therefore, as shown in FIGS. 11 and 12, when the valve body 5 is switched to the lowered state, the rotation tooth 14 of the rotary cam 13 and the locking tooth 16b of the upper gear 16 are pushed after the valve body 5 is pushed down to the maximum. It rises by the height H up to the meshing height position. However, in the present invention, the packing 7 includes the flexible fin portion 8, and the fin portion 8 is elastically deformed to absorb the height H, and the valve body 5 maintains the closed state of the drainage port 1. can do.
Even when the upper surface of the fin 8 and the contact surface 9 of the valve body 5 may come into contact with each other during the elastic deformation, the contact surface 9 is provided with the protrusion 25 as a sticking prevention mechanism. Therefore, it is possible to prevent the fin portion 8 from being stuck to the contact surface 9. Even if a pushing operation is applied to the valve body 5 while hot water is stored in the tank body B, a slight gap is formed between the upper surface of the fin portion 8 and the contact surface 9 by the protrusion 25. Since it is formed, hot water or the like that has entered between the upper surface of the fin portion 8 and the contact surface 9 is discharged from the gap, or air flows in from the gap, and a vacuum state due to surface tension does not occur. . Further, since the outer end of the projection 25 is arranged outside the outer diameter of the packing 7, it is possible to form a gap between the fin 8 and the contact surface 9 when the fin 8 elastically deforms. In addition, it becomes possible to prevent the elastically deformed fin portion 8 and the end portion of the protrusion 25 from being caught.

  The third embodiment of the present invention will be described below. In the third embodiment described below, only the valve element 5 and the packing 7 are different from the first embodiment, and other members are given the same numbers as in the first embodiment. The description is omitted.

  As shown in FIG. 13, the valve body 5 is a lid member in which packing 7 is fitted around, and the upper end of the thrust lock mechanism 10 as a lock mechanism is attached to the back surface. The close contact of the packing 7 closes the drain port 1 in a watertight manner.

  The packing 7 is substantially L-shaped in cross section, and includes a tubular portion 30 fitted to the outer periphery of the valve body 5 and a thin fin portion 8 extending outward from the lower end of the tubular portion 30. The fin portion 8 is configured to be flexible enough to be deformed when it comes into contact with the drain plug 2. In the present embodiment, the outer peripheral surface of the tubular portion 30 is the contact surface 9 that comes into contact when the fin 8 is elastically deformed, and the contact surface 9 is provided with the protrusion 25 as a sticking prevention mechanism. ing. The protrusion 25 is a ridge formed at three positions on the contact surface 9 every 120 degrees, and extends in the axial direction (vertical direction) of the contact surface 9.

  When the packing 7 of the third embodiment comes into contact with the drain plug 2 due to a reason such as a pressing operation being applied to the valve body 5, the fin portion 8 warps upward and the upper surface of the fin portion 8 is packed. It comes into contact with the contact surface 9 of 7. However, since the contact surface 9 is formed with the protrusion 25 as a sticking prevention mechanism, a slight gap is formed between the upper surface of the fin 8 and the contact surface 9 of the packing 7, and the vacuum state is maintained. do not become.

Although the third embodiment has been described above, the invention of the present application is not limited to the shape of each of the above-described embodiments, and design changes and the like can be appropriately made without departing from the scope of the invention.
For example, in each of the above-described embodiments, the sticking prevention mechanism is the protrusion or groove formed on the ridge, but the sticking prevention mechanism may be composed of one or more convex portions, or one or more. It may be composed of a concave portion. Further, it may be constituted by unevenness, steps, graining, corrugation of the contact surface, or the like.
Further, the sticking prevention mechanism is formed on the contact surface 9 with which the fin portion 8 abuts, but it may be formed on the fin portion 8 side, or formed on both the contact surface 9 and the fin portion 8. It may be.
Further, the sticking prevention mechanism does not necessarily have to be formed on the valve body 5 or the packing 7, and another member having a sticking prevention mechanism may be arranged between the valve body 5 and the packing 7.

  Further, in each of the above-described embodiments, the lock mechanism is the thrust lock mechanism 10, but instead of the thrust lock mechanism 10, a one-way cam described in Patent Document 1 or other known lock mechanism may be used. . Further, the water blocking structure of the present invention does not necessarily have to have the lock mechanism, and may be adopted for a rubber plug or the like which does not have the lock mechanism.

  Further, in each of the above-described embodiments, the drainage tool is the valve body 5, but as shown in FIG. 14, the drainage port of the tank body such as the kitchen sink is closed to stop the hot water in the tank body. The lid 35 may be a drainage tool, or other members may be drainage tools.

1 Drain Port 2 Drain Plug 3 Connection Piping 5 Valve Body 6 Groove 7 Packing 8 Fin 9 Abutting Surface 10 Thrust Lock Mechanism 11 Casing 12 Lock Shaft 13 Rotating Cam 14 Rotating Teeth 15 Fixed Cam 16 Upper Gear 16a Tilting Teeth 16b Locking Teeth 17 Lower gear 17a Inclined tooth 18 Cam groove 19 Spring 20 Lower member 21 Eye plate 25 Projection portion 30 Cylindrical portion 35 Water stop lid B Tank body

Claims (6)

Drainage equipment,
In a waterproof structure equipped with a packing that is attached to a drainage tool and is watertight with other members,
The packing is equipped with elastic fins,
The drainage tool or packing includes a contact surface that contacts the deformed fin portion,
Equipped with a sticking prevention mechanism that prevents the fins from sticking to the drainage tool or packing itself ,
The watertight structure, wherein the sticking prevention mechanism forms a gap with the contact surface, the gap being connected to the outside of the contact surface . The water blocking structure according to claim 1, wherein the sticking prevention mechanism is a groove. The water blocking structure according to claim 1, wherein the sticking prevention mechanism is a protrusion. The sticking prevention mechanism
It is provided in the drainage tool, The water stop structure of any one of Claim 1 thru | or 3 characterized by the above-mentioned. The sticking prevention mechanism
The waterproof structure according to any one of claims 1 to 4 , wherein the waterproof structure is provided on the packing. The drainage device is a valve body for opening and closing the drainage port of the tank body,
The valve body is in each press operation is applied to the valve body, according to any one of claims 1 to 5, characterized in that it comprises a locking mechanism for switching the lowered position and raised position of the valve body Water-stop structure.

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