JP6764282B2 - Drainage lid - Google Patents

Description

The present invention relates to a lid for a drainage facility provided in the drainage facility.

Conventionally, drainage facilities buried underground for treating wastewater such as rainwater and sewage, such as manholes and manholes, have been known. Further, it is known that such a drainage facility is provided with a lid having a pressure release function.

For example, Patent Document 1 describes such a lid. The lid described in Patent Document 1 is a manhole cover composed of a lid body having ventilation holes penetrating vertically and a valve body (hereinafter, referred to as an exhaust valve) covered on the lid body. The exhaust valve is provided with an operating shaft (hereinafter referred to as a shaft portion) extending downward, and the lid body is formed with a support portion that slidably supports the shaft portion up and down. When the internal pressure of the manhole becomes high, the exhaust valve is lifted by the internal pressure and the ventilation hole is opened. Then, a part of the air in the manhole is discharged to the outside from the ventilation hole, and the internal pressure of the manhole is released.

By the way, the manhole cover may be stepped on by pedestrians. When a pedestrian steps on the exhaust valve, the exhaust valve may rotate with respect to the lid body. Patent Document 1 describes that the cross-sectional shape of the shaft portion of the exhaust valve is a non-round shape so that the exhaust valve does not rotate when a pedestrian steps on the exhaust valve.

Japanese Unexamined Patent Publication No. 2011-11185

However, the shaft portion is a portion provided near the rotation center of the exhaust valve. Therefore, when a rotational force is applied to the exhaust valve from the outside, a large force acts on the shaft portion. In addition, the shaft portion is a small diameter portion. Therefore, depending on the cross-sectional shape of the shaft portion, when a large rotational force is applied to the exhaust valve, the exhaust valve may rotate even though the cross-sectional shape of the shaft portion is non-round. Further, depending on the cross-sectional shape of the shaft portion, if a large rotational force is applied to the exhaust valve, the shaft portion may be damaged. It should be noted that such a problem may occur not only in the drainage facility buried in the ground but also in the lid provided in the drainage facility installed on the ground.

The present invention has been made in view of this point, and an object of the present invention is to provide a lid for a drainage facility in which the exhaust valve does not rotate and is not easily damaged even when a large rotational force is applied to the exhaust valve.

The lid for drainage equipment according to the present invention includes a lid main body having an exhaust hole formed therein and an exhaust valve. The exhaust valve has a valve body portion that is placed on the lid body and covers the exhaust hole, and an extension portion that extends downward from the valve body portion. The extension portion is provided at a position deviated from the center of the exhaust valve. The lid body has a rotation prevention portion that extends from the peripheral edge of the exhaust hole toward the center and prevents rotation of the exhaust valve by abutting with the extension portion of the exhaust valve.

According to the lid for drainage equipment, when a rotational force is applied to the exhaust valve, the extension portion of the exhaust valve and the rotation prevention portion of the lid body come into contact with each other to prevent the exhaust valve from rotating. Since the extension portion is provided at a position deviated from the center of the exhaust valve, the force acting on the extension portion when a rotational force is applied to the exhaust valve is smaller than when the extension portion is provided at the center of the exhaust valve. .. Therefore, even if a large rotational force is applied to the exhaust valve, the stretched portion is not easily damaged.

According to a preferred aspect of the present invention, the lid body is arranged in the central portion where the shaft hole is formed, the outer peripheral portion which is arranged radially outside the central portion and is separated from the central portion, and the radial direction. It has a plurality of bridging portions extending from the inside to the outside and connecting the central portion and the outer peripheral portion. The exhaust hole is partitioned by the central portion, the outer peripheral portion, and the bridging portion. The shaft hole is provided in the central portion of the lid body. The exhaust valve has a shaft portion that extends downward from the central portion of the valve body portion and is slidably inserted into the shaft hole. The rotation prevention portion is composed of the bridging portion.

According to the above aspect, when a rotational force is applied to the exhaust valve, the extension portion of the exhaust valve and the bridging portion of the lid body come into contact with each other to prevent the exhaust valve from rotating. Since the bridging portion is a member provided so as to span from the central portion to the outer peripheral portion of the lid body, there is little possibility that the extending portion will get over the bridging portion even if a large rotational force is applied to the exhaust valve. Further, since all or most of the rotational force applied to the exhaust valve is received by the contact between the extending portion and the bridging portion, a large force is not applied to the shaft portion. Therefore, even if a large rotational force is applied to the exhaust valve, the exhaust valve does not rotate and the shaft portion is not easily damaged.

According to another preferred embodiment of the present invention, the stretched portion comprises ribs extending in the circumferential direction.

The ribs extending in the circumferential direction have high rigidity against the force in the circumferential direction. Therefore, according to the above aspect, even if a large rotational force is applied to the exhaust valve, the rotation of the exhaust valve can be prevented more reliably.

According to another preferred aspect of the present invention, at least a part of the rib is arranged on the outer end side of the intermediate position between the radial center and the outer end of the valve body portion.

When the exhaust valve is not rotating, the torque (rotational force) applied to the exhaust valve from the outside is T, the distance from the radial center of the valve body to the rib is L, and the rib and the bridging part come into contact with each other. Assuming that the force applied to the rib from the bridging portion is F, T = L × F. Assuming that T is constant, the larger L is, the smaller F is. That is, the larger the distance from the radial center of the valve body portion to the rib, the smaller the force generated between the bridging portion and the rib. According to the above aspect, the ribs are arranged on the outer end side of the radial intermediate position of the valve body portion, and the distance from the center is relatively large. Therefore, the force generated between the bridging portion and the rib can be suppressed to be small. Therefore, even if a large force is applied to the exhaust valve, the rib and the bridging portion are not easily damaged, and the rotation of the exhaust valve can be prevented more reliably.

According to another preferred aspect of the present invention, the lid frame is fixed to the inspection port of the rainwater facility, and the lid body is detachably attached by mounting the lid body. The lid body has a lid stopper that prevents the lid body from scattering by engaging with the lid frame when it rises from the lid frame.

In rainwater facilities, a large amount of rainwater may temporarily flow during torrential rain, and part of the rainwater may have to be forcibly discharged to the outside. According to the above aspect, when a part of the rainwater rises to the inspection port during torrential rain, the lid body placed on the lid frame is lifted upward by the rainwater. As a result, the inspection port (strictly speaking, the opening of the lid frame) is opened, and rainwater can be discharged from the inspection port. Therefore, it is possible to discharge a large amount of rainwater that cannot be completely discharged from the exhaust hole alone. The inspection port is opened when the lid body floats, but the lid stopper engages with the lid frame to prevent the lid body from scattering. When the rainwater has been discharged, the lid body is lowered by its own weight and the inspection port is closed.

According to the present invention, it is possible to provide a lid for a drainage facility in which the exhaust valve does not rotate even when a large rotational force is applied to the exhaust valve and is not easily damaged.

It is a side view of a rainwater facility. It is a top view of the rainwater equipment. It is a top view of the lid. It is a side view of a lid. It is a back view of the lid. FIG. 3 is a cross-sectional view taken along the line AA of FIG. FIG. 3 is a cross-sectional view taken along the line BB of FIG. It is a top view of the lid body. It is a top view of the exhaust valve. It is a side view of an exhaust valve. 9 is a cross-sectional view taken along the line AA of FIG. 9 is a cross-sectional view taken along the line BB of FIG. FIG. 7 is a cross-sectional view corresponding to FIG. 7 of a lid when the exhaust valve is opened. FIG. 7 is a cross-sectional view corresponding to FIG. 7 of a lid when the exhaust valve and the lid body are opened. It is a partially enlarged back view of a lid. It is a partially enlarged back view of the lid which concerns on another embodiment. It is a partially enlarged back view of the lid which concerns on another embodiment.

Hereinafter, an embodiment of the present invention will be described. FIG. 1 is a side view of the rainwater facility 1 as an example of the drainage facility. FIG. 2 is a plan view of the rainwater facility 1. The rainwater facility 1 according to the present embodiment is buried underground. However, the drainage facility according to the present invention is not limited to the one buried in the ground, and a part or all of the drainage facility may be placed on the ground.

The rainwater equipment 1 includes a first pipe 21, a 20 connected to the first pipe 21, a second pipe 4 connected to the 20th pipe, a rainwater storage tank 3 connected to the second pipe 4, and rainwater. It is provided with a third pipe 6 connected to the storage tank 3. The third pipe 6 is connected to the side groove 60. The rainwater storage tank 3 has a tank body 2 and an inspection cylinder 5. The first pipe 21 is a pipe that guides rainwater toward 20 more. The second pipe 4 is a pipe that guides the rainwater discharged from the 20 to the rainwater storage tank 3. The third pipe 6 is a pipe that guides rainwater from the rainwater storage tank 3 toward the gutter 60.

An inspection port 11 is formed at the upper part of the 20. An inspection port 11 is also formed above the inspection cylinder 5 of the rainwater storage tank 3. The inspection port 11 is open upward. The inspection port 11 of the 20th inspection port and the inspection port 11 of the inspection tube 5 of the rainwater storage tank 3 are provided with a drainage lid (hereinafter, simply referred to as a lid) 10 according to the present embodiment. The lid 10 is provided only on one of the inspection port 11 of the 20th and the inspection port 11 of the inspection cylinder 5 of the rainwater storage tank 3, and the other is provided with a lid having no pressure release function. May be good.

Next, the details of the lid 10 will be described. Here, the lid 10 provided at the inspection port 11 of the inspection cylinder 5 of the rainwater storage tank 3 will be described. 3 is a plan view of the lid 10, FIG. 4 is a side view of the lid 10, and FIG. 5 is a back view of the lid 10. 6 is a cross-sectional view taken along the line AA of FIG. 3, and FIG. 7 is a cross-sectional view taken along the line BB of FIG. As shown in FIG. 6, the lid 10 includes a lid frame 12 fixed to the inspection port 11, a lid body 15 that is detachably attached to the lid frame 12 by being placed on the lid frame 12, and a lid body. The exhaust valve 14 mounted on the 15 is provided.

The lid main body 15 has a main body portion 13 and a lid stopper 16. Here, the main body 13 and the lid stopper 16 are separate bodies, and the lid stopper 16 is attached to the main body 13. However, the main body 13 and the lid stopper 16 are not limited to separate bodies, and may be integrated. Although the lid body 15 is fitted to the lid frame 12 via the sealing material 17, it is only placed on the lid frame 12 and is not fixed by adhesion or the like.

FIG. 8 is a plan view of the main body 13. The main body portion 13 includes a tubular portion 13B in which a shaft hole 13c is formed, an annular portion 13A arranged radially outside the tubular portion 13B and formed in an annular shape in a plan view, and a tubular portion 13B. It has a bridging portion 13C that connects the annular portion 13A.

The annular portion 13A is separated from the tubular portion 13B. The annular portion 13A and the tubular portion 13B are examples of the “central portion” and the “outer peripheral portion”, respectively. However, the outer peripheral portion of the lid body 15 is not necessarily limited to the annular member, and the central portion is not limited to the tubular member. The shaft hole 13c is provided in the central portion of the lid main body 15. The shaft hole 13c is formed in a substantially cross shape in a plan view. However, the plan view shape of the shaft hole 13c is not particularly limited. For example, the plan view shape of the shaft hole 13c may be circular (including a perfect circle and an oval).

The bridging portion 13C is formed in a rod shape extending from the inside to the outside in the radial direction. Here, the bridging portion 13C extends linearly along the radial direction. However, the bridging portion 13C may extend in a direction oblique to the radial direction. The bridging portion 13C is not limited to a straight line, but may be a curved line. The bridging portion 13C may have a bent shape. The number of the bridging portions 13C is not particularly limited, but is preferably a plurality. Here, four bridging portions 13C are provided. However, the number of the bridging portions 13C may be 2, may be 3, or may be 5 or more.

The annular portion 13A is formed with a hole 13a into which the lid stopper 16 is fitted. Here, two holes 13a are formed in the annular portion 13A. The two holes 13a are arranged at point-symmetrical positions with respect to the center C of the main body 13 (the center of the main body 13 is also the center of the exhaust valve 14 and the center of the lid 10). There is. However, the arrangement of the holes 13a is not particularly limited. Further, the number of holes 13a may be the same as the number of lid stoppers 16, and is not limited to two. The number of holes 13a may be one or three or more.

An exhaust hole 13b is formed inside the annular portion 13A. Here, four exhaust holes 13b are formed. However, the number of exhaust holes 13b is not limited to 4. The number of exhaust holes 13b may be 1 to 3 or 5 or more. The exhaust hole 13b is partitioned by an annular portion 13A, a tubular portion 13B, and a bridging portion 13C. A shaft hole 13c is formed in the tubular portion 13B.

As shown in FIG. 6, a recess 13d into which the exhaust valve 14 is fitted is formed in the central portion of the annular portion 13A. That is, the portion of the main body 13 on the inner side in the radial direction of the annular portion 13A has a recess 13d. By fitting the exhaust valve 14 into the recess 13d, the upper surface of the exhaust valve 14 and the upper surface of the lid body 15 and the ground are substantially flush with each other. An inclined surface 13e that is inclined downward toward the center is formed on the peripheral edge of the recess 13d. A sealing material 17 is attached to the outer peripheral surface of the annular portion 13A.

The lid stopper 16 has a head portion 16A fitted in the hole 13a of the annular portion 13A, and a shaft portion 16B located below the head portion 16A. A sealing material 18 is attached to the outer peripheral surface of the head portion 16A. The shaft portion 16B has a vertical portion 16a extending downward from the head portion 16A and an engaging portion 16b extending radially outward from the vertical portion 16a.

The lid frame 12 is fixed to the inspection cylinder 5. The lid frame 12 may be adhered to, for example, the inspection cylinder 5. The lid frame 12 may have an adhesive portion adhered to the inspection cylinder 5. The configuration for fixing the lid frame 12 to the inspection cylinder 5 is not limited at all. The lid frame 12 has a support portion 12a that supports the lid body 15. Here, the support portion 12a is composed of a flat surface that supports the lower surface of the outer peripheral portion of the lid main body 15.

The lid frame 12 has a tubular portion 12b and an engaged portion 12c protruding inward in the radial direction from the tubular portion 12b. Here, the engaged portion 12c is formed in a ring shape. The radial outer end of the engaging portion 16b of the lid stopper 16 is located radially outside the radial inner end of the engaged portion 12c of the lid frame 12. In a plan view, the engaged portion 12c and the engaging portion 16b partially overlap each other. As shown in FIG. 5, when viewed from below, the engaged portion 12c and the engaging portion 16b partially overlap each other. Therefore, when the lid main body 15 moves upward, the engaging portion 16b of the lid stopper 16 and the engaged portion 12c of the lid frame 12 come into contact with each other, and the upward movement of the lid main body 15 is restricted.

FIG. 9 is a plan view of the exhaust valve 14. FIG. 10 is a side view of the exhaust valve 14. 11 is a sectional view taken along line AA of FIG. 9, and FIG. 12 is a sectional view taken along line BB of FIG. However, in FIGS. 10 to 12, the valve stopper 14C, which will be described later, is not shown. As shown in FIGS. 11 and 12, the exhaust valve 14 includes a valve body portion 14A that is placed in the recess 13d of the lid body 15 and covers the exhaust hole 13b, and a shaft portion 14B that extends downward from the valve body portion 14A. It has a rib 14D extending downward from the valve body portion 14A and a valve stopper 14C (see FIG. 6) fixed to the lower end portion of the shaft portion 14B. The rib 14D is an example of an extension portion extending downward from the valve body portion 14A.

As shown in FIG. 9, the valve body portion 14A is formed in a circular shape in a plan view. As shown in FIG. 3, in a plan view, the valve body portion 14A is surrounded by the annular portion 13A of the lid body 15. As shown in FIG. 6, the side surface of the valve body portion 14A is inclined toward the center side toward the lower side. A sealing material 19 is provided on the side surface of the valve body portion 14A.

The shaft portion 14B extends downward from the central portion of the valve body portion 14A. The shaft portion 14B is slidably inserted into the shaft hole 13c of the tubular portion 13B of the lid main body 15. The cross-sectional shape of the shaft portion 14B is the same as the cross-sectional shape of the shaft hole 13c. In the present embodiment, since the cross-sectional shape of the shaft hole 13c is formed in a substantially cross shape, the cross-sectional shape of the shaft portion 14B is formed in a substantially cross shape.

The valve stopper 14C is fixed to a portion of the shaft portion 14B below the tubular portion 13B. The radial outer end of the valve stopper 14C is located radially outside the inner peripheral surface of the shaft hole 13c of the tubular portion 13B. In a plan view, the tubular portion 13B and the valve stopper 14C partially overlap each other. Therefore, when the exhaust valve 14 moves upward with respect to the lid main body 15, the valve stopper 14C and the tubular portion 13B come into contact with each other, and the upward movement of the exhaust valve 14 is restricted. As shown in FIG. 7, when the exhaust valve 14 is placed on the lid body 15 (when the exhaust hole 13b is closed by the exhaust valve 14), the lower end of the tubular portion 13B and the upper end of the valve stopper 14C. Let S be the distance between them. Then, when the exhaust valve 14 floats by the distance S, the valve stopper 14C and the tubular portion 13B come into contact with each other. The distance S is the maximum levitation amount of the exhaust valve 14.

The rib 14D is arranged outside the shaft portion 14B in the radial direction. The number of ribs 14D is not particularly limited, but as shown in FIG. 5, four ribs 14D are provided in the present embodiment. Each rib 14D extends in the circumferential direction and is curved.

The ribs 14D are arranged between the bridging portions 13C adjacent to each other in the circumferential direction. The rib 14D is preferably provided so that a part of the rib 14D is located in the vicinity of the bridging portion 13C. The length of the rib 14D is not particularly limited. FIG. 15 is an enlarged back view showing a portion of the lid 10 near the center. As shown in FIG. 15, let α be the angle formed by the line segment 14i connecting the center C and one end of the rib 14D and the line segment 14j connecting the center C and the other end of the rib 14D. The angle formed by the line segment 13i extending from the center C along the center of one bridging portion 13C and the line segment 13j extending from the center C along the center of the other bridging portion 13C (in other words, the bridging portion 13C). Let θ be the pitch angle in the circumferential direction of. In that case, α is preferably 0.5 × θ or more, more preferably 0.6 × θ or more, and further preferably 0.7 × θ or more. In this embodiment, θ = 90 ° and α = 70 °.

The radial position of the rib 14D is not particularly limited, but here, as shown in FIG. 12, at least a part of the rib 14D is located at an intermediate position M between the radial center C and the outer end P of the valve body portion 14A. Is also arranged on the outer end P side.

As shown in FIG. 7, the vertical dimension H of the rib 14D is larger than S. That is, H> S. The vertical dimension of the rib 14D is larger than the maximum levitation amount S of the exhaust valve 14. The rib 14D is arranged at a position where the rib 14D continues to overlap with the bridging portion 14C in the lateral direction even when the exhaust valve 14 floats. The rib 14D is configured so that the lower end of the rib 14D is located below the upper end of the bridging portion 14C even when the exhaust valve 14 is raised to the maximum. The size of the vertical dimension H of the rib 14D and the vertical dimension of the bridging portion 14C are not particularly limited. The vertical dimension H of the rib 14D may be smaller, equal, or larger than the vertical dimension of the bridging portion 14C. When the exhaust valve 14 rests on the lid body 15, the lower end of the rib 14D may be located below the lower end of the bridging portion 14C.

The materials of the lid frame 12, the main body 13 and the stopper 16 of the lid main body 15, and the exhaust valve 14 are not limited in any way. For example, it may be a synthetic resin such as vinyl chloride.

The weight of the exhaust valve 14 is smaller than the weight of the lid body 15. As shown in FIG. 3, the plan view area of the lid body 15 is larger than the plan view area of the exhaust valve 14.

The above is the configuration of the lid 10. Although the description is omitted, the configuration of the lid 10 provided at the inspection port 11 of 20 is the same. The lid 10 has a function of releasing the internal pressure of the rainwater facility 1 when the internal pressure becomes high, and a function of discharging a part of the rainwater when a large amount of rainwater flows into the rainwater facility 1 during a torrential rain. And have. Next, the pressure release operation and the rainwater discharge operation of the lid 10 will be described by taking the lid 10 provided on the inspection cylinder 5 of the rainwater storage tank 3 as an example.

When the internal pressure (air pressure) of the rainwater storage tank 3 becomes high, pressure is applied to the lid 10 from the lower side to the upper side. When the pressure becomes equal to or higher than a predetermined pressure (hereinafter referred to as the first pressure), the exhaust valve 14 floats due to the pressure, as shown in FIG. Then, the exhaust hole 13b (see also FIG. 8) blocked by the exhaust valve 14 is opened. As a result, a part of the internal air of the rainwater storage tank 3 is released to the outside through the exhaust hole 13b, and the internal pressure of the rainwater storage tank 3 decreases. Therefore, it is possible to prevent the internal pressure of the rainwater storage tank 3 from becoming excessively high. When the exhaust valve 14 floats by a predetermined distance S, the valve stopper 14C and the tubular portion 13B come into contact with each other, and the floating of the exhaust valve 14 is restricted. Since the exhaust valve 14 includes the valve stopper 14C, it is prevented from coming off from the lid main body 15. When the internal pressure of the rainwater storage tank 3 becomes less than the first pressure, the exhaust valve 14 is lowered by its own weight and placed on the lid main body 15. Then, the exhaust hole 13b is closed by the exhaust valve 14, and the rainwater storage tank 3 is sealed. When the internal pressure of the rainwater storage tank 3 increases again, the same operation is repeated. As a result, the internal pressure of the rainwater storage tank 3 is adjusted to less than the first pressure.

During a torrential rain, a large amount of rainwater may flow into the rainwater facility 1 and the rainwater storage tank 3 may overflow. In such a case, rainwater rises in the inspection cylinder 5, and the rainwater exerts an upward pressure on the lid 10. When the pressure applied to the lid 10 becomes equal to or higher than the first pressure, the exhaust valve 14 rises from the lid main body 15 and the exhaust hole 13b is opened (see FIG. 13). Rainwater is discharged to the outside of the rainwater storage tank 3 through the exhaust hole 13b.

When the amount of rainwater overflowing from the rainwater storage tank 3 is large, a sufficient amount of rainwater cannot be discharged only by the exhaust holes 13b, and further pressure is applied to the lid 10. When a pressure larger than the first pressure (hereinafter referred to as the second pressure) is applied to the lid 10, the lid main body 15 rises from the lid frame 12 and the inspection port 11 is opened, as shown in FIG. Since the lid frame 12 is fixed to the inspection port 11, when the lid main body 15 rises from the lid frame 12, strictly speaking, the inside of the lid frame 12 is opened. However, in the present specification, opening the inside of the lid frame 12 in this way is referred to as "opening the inspection port 11." Since the second pressure is larger than the first pressure, the lid main body 15 floats from the lid frame 12 with the exhaust valve 14 floating from the lid main body 15. When the lid body 15 floats from the lid frame 12, rainwater is discharged to the outside of the rainwater storage tank 3 through the exhaust hole 13b and the gap between the lid body 15 and the lid frame 12. Therefore, the amount of rainwater discharged increases. After the lid body 15 floats, the engaging portion 16b of the lid stopper 16 and the engaged portion 12c of the lid frame 12 engage with each other to prevent the lid body 15 from further rising. Therefore, the lid body 15 does not scatter from the lid frame 12. Further, the lid body 15 is maintained at a position above the lid frame 12. When the rainwater is sufficiently discharged and the pressure applied to the lid 10 becomes smaller than the second pressure, the lid body 15 is placed on the lid frame 12 by its own weight, and the inspection port 11 is closed. Further, when the pressure applied to the lid 10 becomes smaller than the first pressure, the exhaust valve 14 is placed on the lid main body 15 and the exhaust hole 13b is closed.

As described above, in the lid 10 according to the present embodiment, as shown in FIG. 15, the rib 14D of the exhaust valve 14 is arranged between the pair of bridging portions 13C adjacent to each other in the circumferential direction of the lid main body 15. There is. Therefore, when a large rotational force K is applied to the exhaust valve 14 from the outside, one end 14k of the rib 14D comes into contact with the bridging portion 13C, and the rotation of the exhaust valve 14 is prevented. Since the bridging portion 13C is provided so as to span from the inner side to the outer side in the radial direction from the tubular portion 13B of the lid body 15 to the annular portion 13A, the rib 14D can be hung even if a large rotational force is applied to the exhaust valve 14. There is no risk of getting over the passing section 13C. Further, a large force is not applied to the shaft portion 14B of the exhaust valve 14. Therefore, even if a large rotational force is applied to the exhaust valve 14 from the outside, the exhaust valve 14 does not rotate and the shaft portion 14B is not easily damaged.

By the way, after releasing the internal pressure of the rainwater equipment 1, the exhaust valve 14 descends by its own weight and is placed on the lid main body 15 to close the exhaust hole 13b. However, if the exhaust valve 14 rotates when it floats, the position of the rib 14D may shift from the position between the two adjacent bridging portions 13C in the circumferential direction to the position directly above the bridging portion 13C. .. If the exhaust valve 14 is lowered while being displaced, the rib 14D may ride on the bridge portion 13C, and the exhaust hole 13b may not be satisfactorily blocked by the exhaust valve 14. However, according to the lid 10 according to the present embodiment, the vertical dimension H of the rib 14D is larger than the maximum levitation amount S of the exhaust valve 14 (see FIG. 7). Even when the exhaust valve 14 is raised to the maximum, a part of the rib 14D does not come off from between the bridging portions 13C adjacent to each other in the circumferential direction. Therefore, the exhaust valve 14 does not rotate even when it rises. When the exhaust valve 14 descends due to its own weight, the rib 14D does not ride on the bridge portion 13C. Therefore, according to the lid 10 according to the present embodiment, the exhaust hole 13b can be satisfactorily closed after the internal pressure of the rainwater equipment 1 is released.

However, it is not essential that H> S. Although the above-mentioned effect cannot be obtained, H = S or H <S may be obtained.

The specific configuration of the regulating portion that regulates the exhaust valve 14 so as not to rise above the predetermined distance S is not limited in any way, but in the present embodiment, the regulating portion includes the valve stopper 14C extending radially outward of the shaft portion 14B. ing. In the present embodiment, when the exhaust valve 14 floats by a predetermined distance S, the valve stopper 14C comes into contact with the lower end of the tubular portion 13B, and the floating of the exhaust valve 14 is restricted.

The structure of the stretched portion is not particularly limited, but in the present embodiment, it is composed of a rib 14D extending in the circumferential direction. The rib 14D extending in the circumferential direction has high rigidity against a force in the circumferential direction. Therefore, even if a large rotational force is applied to the exhaust valve 14, the rotation of the exhaust valve 14 can be prevented more reliably.

The torque (rotational force) applied to the exhaust valve 14 from the outside is T, the distance from the radial center C of the exhaust valve 14 to the rib 14D is L, and the bridging portion is contacted by the rib 14D and the bridging portion 13C. Assuming that the force applied from 13C to the rib 14D is F, T = L × F. Assuming that T is constant, the larger L is, the smaller F is. That is, the larger the distance L from the center C to the rib 14D, the smaller the force generated between the bridging portion 13C and the rib 14D. In the present embodiment, as shown in FIG. 12, at least a part of the rib 14D is arranged on the outer end P side of the intermediate position M between the radial center C and the outer end P of the valve body portion 14A. .. The rib 14D is formed at a position relatively distant from the center C. Therefore, the force generated between the bridging portion 13C and the rib 14D can be suppressed to a small value. Therefore, even if a large rotational force is applied to the exhaust valve 14, the rib 14D and the bridging portion 13C are not easily damaged, and the rotation of the exhaust valve 14 can be prevented more reliably.

According to the lid 10 according to the present embodiment, when the internal pressure of the rainwater equipment 1 increases, the exhaust valve 14 is lifted upward by the internal pressure. As a result, the exhaust hole 13b is opened, and it is possible to prevent the internal pressure of the rainwater facility 1 from becoming excessively high. According to the lid 10 according to the present embodiment, it is not necessary to raise the lid main body 15 when releasing the internal pressure of the rainwater equipment 1. By floating the exhaust valve 14, which is lighter than the lid body 15, the air in the rainwater equipment 1 can be released to the outside. Therefore, it is possible to finely adjust the pressure of the rainwater facility 1. On the other hand, when rainwater rises to the inspection port 11 during torrential rain, a part of the rainwater can be discharged to the outside of the rainwater facility 1 through the exhaust hole 13b by floating the exhaust valve 14. Further, when the rainwater cannot be completely discharged only from the exhaust hole 13b, the lid main body 15 rises from the lid frame 12 and the inspection port 11 is opened. Therefore, in addition to the exhaust hole 13b, a part of rainwater can be discharged from the gap between the lid main body 15 and the lid frame 12. Therefore, the amount of rainwater discharged can be increased. According to the lid 10 according to the present embodiment, it is possible to discharge a large amount of rainwater that cannot be completely discharged only by the exhaust holes 13b during a torrential rain. According to the lid 10 according to the present embodiment, it is possible to finely adjust the pressure of the rainwater facility 1 and to discharge a large amount of rainwater during a torrential rain.

The inspection port 11 is opened when the lid body 15 floats from the lid frame 12, but when the lid body 15 rises by a predetermined amount or more, the lid stopper 16 engages with the lid frame 12. Therefore, the lid body 15 does not come off from the position above the lid frame 12. Therefore, after the rainwater is discharged from the inspection port 11, the lid body 15 is placed on the lid frame 12 by its own weight, and the inspection port 11 is closed.

Although one embodiment of the present invention has been described above, it goes without saying that the embodiment of the present invention is not limited to the above-described embodiment. The present invention can be implemented in various other forms. Next, other embodiments will be briefly described.

The lid 10 according to the embodiment is provided on the inspection cylinder 5 or the stile 10 of the rainwater storage tank 3. However, the application target of the lid according to the present invention is not limited to the rainwater storage tank 3 and the masu 10. The lid according to the present invention can be applied to any drainage facility.

The lid 10 according to the embodiment is configured such that the exhaust valve 14 can be levitated with respect to the lid main body 15 and the lid main body 15 can be levitated with respect to the lid frame 12. However, the lid body 15 does not necessarily have to be levitable. The lid stopper 16 of the lid body 15 may not be provided.

The number of ribs 14D arranged between the bridging portions 13C adjacent to each other in the circumferential direction is not limited to one. For example, as shown in FIG. 16, two ribs 14D may be arranged between the bridging portions 13C adjacent to each other in the circumferential direction. When a plurality of ribs 14D are arranged between the bridging portions 13C adjacent to each other in the circumferential direction, the distances of the ribs 14D from the center C may be equal (see FIG. 16) or may be different.

The extension portion arranged between the bridging portions 13C adjacent to each other in the circumferential direction is not limited to the rib 14D. For example, as shown in FIG. 17, the extending portion may be a pin 14E extending downward from the valve body portion 14A. As the extending portion, any member that engages with the bridging portion 13C in the circumferential direction can be used. The plurality of stretched portions may have the same shape and the same dimensions as each other, but at least one of the shapes and dimensions may be different.

The plurality of bridging portions 13C do not necessarily have to be arranged at a constant pitch in the circumferential direction. The circumferential intervals of the bridging portions 13C do not have to be equal, and may be unequal. The shapes and dimensions of the plurality of bridging portions 13C do not necessarily have to be the same.

The shape of the bridging portion 13C of the lid body 15 is not limited to the rod shape. As the shape of the bridging portion 13C, an arbitrary shape capable of connecting the annular portion 13A and the tubular portion 13B can be adopted.

The lid body 15 does not have to include the tubular portion 13B and the bridging portion 13C in which the shaft hole 13c is formed. The exhaust valve 14 does not have to have the shaft portion 14B. For example, the lid body 15 may be provided with a single exhaust hole in the center. In that case, the exhaust valve 14 extends downward from the valve body portion that covers the single exhaust hole and slidably engages with the peripheral edge of the exhaust hole of the lid body 15 in the vertical direction. It may have a plurality of stretched portions. A valve stopper that can be locked to the peripheral edge of the exhaust hole of the lid body 15 may be provided at the lower end of the extension portion. As the rotation prevention portion, a convex portion or a rod-shaped portion extending from the peripheral edge of the exhaust hole toward the center may be provided. Even in such a form, the rotation of the exhaust valve is prevented by the contact between the extension portion of the exhaust valve and the rotation prevention portion of the lid body.

In the above embodiment, the drainage facility is the rainwater facility 1 provided with 20 and the rainwater storage tank 3, but the drainage facility is not limited to the rainwater facility 1. The drainage facility may be a sewage facility that discharges sewage.

1 Rainwater equipment (drainage equipment)
10 Lid 12 Lid frame 13 Lid body 13A Circular part (outer circumference)
13B Cylindrical part (center part)
13C bridging part (rotation prevention part)
13b Exhaust hole 13c Shaft hole 14 Exhaust valve 14A Valve body part 14B Shaft part 14C Valve stopper (regulatory part)
14D rib (extended part)

Claims (5)

The lid body with the exhaust holes and
An exhaust valve having a valve body portion mounted on the lid body and covering the exhaust hole, and an extension portion extending downward from the valve body portion.
With
The extension portion is provided at a position deviated from the center of the exhaust valve, and is arranged on the outer end side of the intermediate position between the radial center and the outer end of the valve body portion.
The lid body is a lid for drainage facilities, which extends from the peripheral edge of the exhaust hole toward the center and has a rotation prevention portion that prevents rotation of the exhaust valve by abutting with the extension portion of the exhaust valve. The lid for a drainage facility according to claim 1, wherein the extension portion is not arranged on the center side of the intermediate position between the radial center and the outer end of the valve body portion. The lid body is arranged at the central portion where the shaft hole is formed, the outer peripheral portion in the radial direction from the central portion, the outer peripheral portion separated from the central portion, and extends from the inner side to the outer side in the radial direction. It has a plurality of bridging portions that connect the central portion and the outer peripheral portion.
The exhaust hole is partitioned by the central portion, the outer peripheral portion, and the bridging portion.
The shaft hole is provided in the center of the lid body and is provided.
The exhaust valve has a shaft portion that extends downward from the central portion of the valve body portion and is slidably inserted into the shaft hole.
The lid for drainage equipment according to claim 1 or 2 , wherein the rotation prevention portion is composed of the bridging portion. The lid for drainage equipment according to any one of claims 1 to 3, wherein the extending portion is composed of ribs extending in the circumferential direction. It is provided with a lid frame that is fixed to the inspection port of rainwater equipment and the lid body is detachably attached by mounting the lid body.
The method according to any one of claims 1 to 4, wherein the lid body has a lid stopper that prevents the lid body from scattering by engaging with the lid frame when it floats from the lid frame. Lid for drainage equipment.

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