JP2005264652A - Drain structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent large noise from a drain port from being generated when waste water is drained based on the principle of siphon. <P>SOLUTION: This drain structure draining the waste water based on the principle of syphon comprises a water storage part 1, the drain port 2, a drain tube 3, and a float 4. The float 4 closes the drain port 2 when a water level in the water storage part 1 is low and separates from the drain port 2 against a suction force to the drain tube 3 by buoyancy applied to the float when the water level in the water storage part 1 is high. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a drainage structure, and more particularly to a drainage structure when draining according to the principle of siphon.

  A drainage structure using the principle of siphon has been proposed (for example, Patent Document 1). In patent document 1, it is set as the structure which increases the flow volume of waste_water | drain by providing a drop mouth in a trough and siphoning.

  The principle of siphon refers to a principle that causes a suction action on the upstream side of the liquid when the liquid falls in a substantially full state in the pipe. For this reason, in the drainage structure using the siphon principle, the liquid can be smoothly discharged by the action of sucking the upstream liquid, and the diameter of the drain pipe can be reduced and the number of drain pipes can be reduced. Can be realized.

  On the other hand, there exists a drainage structure which arrange | positions a floating obstruction | occlusion member to a drain outlet like patent document 2. FIG. The levitation blocking member closes the drainage port during normal times when there is no water, and floats by the buoyancy of the member to open the drainage port when water accumulates around the levitation blocking member. Thereby, a foreign substance does not penetrate | invade into a drain outlet at normal time, and clogging of a drain outlet can be prevented.

Japanese Patent Laid-Open No. 9-111972 JP 55-55758

  In the drainage structure as in Patent Document 1, when the drainage pipe that communicates from the drainage port is drained to the extent that it is almost full, drainage is performed according to the siphon principle. Then, a strong suction force downstream acts on the drain port, and the water around the drain port is sucked and smooth drainage is performed. At this time, when there is sufficient water around the drain outlet, only water is sucked from the drain outlet, so that the water in the drain pipe flows and no loud noise is generated from the drain outlet.

  However, when there is not enough water around the drain outlet, the surrounding air is also sucked from the drain outlet together with water with a strong suction force. If water is strongly sucked into the drain pipe in a state of air mixing from the drain port, the water greatly disturbs the flow in the drain pipe, and a loud sound is generated from the drain port.

  By the way, when the structure which arrange | positions a floating obstruction | occlusion member in a drain outlet like patent document 2 is applied to the drainage structure by the principle of siphon, if there is no sufficient water around the drain outlet, Descent and plug the drain. For this reason, air is not sucked together with the drainage, and no loud noise is generated from the drainage port. However, once the floating blocking member is strongly attracted to the drainage port by the above-described suction force, there is a possibility that even if water accumulates again around the drainage port, it cannot float and open the drainage port.

  Therefore, an object of the present invention is to prevent generation of a loud sound from a drain outlet without impairing the drainage function even when draining according to the principle of siphon.

  The first configuration of the present invention for achieving the above object is a drainage structure for draining according to the principle of siphon. In a drainage structure for collecting drainage, a drainage port disposed in the water reservoir, and a drainage port. A drainage pipe for draining the communicating water, and a float arranged in the water reservoir, the float closing the drain outlet when the water level in the water reservoir is low, and the water level in the water reservoir is high. Then, the buoyancy received by the float is separated from the drain outlet against the suction force to the drain pipe.

  A second configuration of the present invention is the drainage structure according to the first configuration, wherein a float receiver formed of an elastic member that does not allow water to pass is disposed around the drain outlet. And

  A third configuration of the present invention is the drainage structure according to the first or second configuration, wherein the float has a vent pipe for communicating the water reservoir and the drain pipe, and the vent pipe The upper end of is located in a position higher than the upper part of the water reservoir.

  A fourth configuration of the present invention is the drainage structure according to any one of the first to third configurations, wherein the float is configured to be movable only in the vertical direction.

  A fifth configuration of the present invention is the drainage structure according to the third or fourth configuration, wherein an upper end of the vent pipe is opened when the float closes the drain, and the float is opened from the drain. When it leaves | separates, it is characterized by closing.

  According to the first configuration of the present invention, when the water level of the water reservoir is low, the float is sucked by a strong suction force generated in the direction of the drain pipe by the siphon principle, and the float blocks the drain port. Water and air do not enter the drain. On the other hand, when the water level becomes high, the buoyancy is greater than the suction force on the float, and the float is separated from the drain port. At this time, only water flows into the drain port. For this reason, water does not flow into the drain outlet in a state of air mixing. As a result, it is possible to prevent a loud sound from being generated from the drain port.

  According to the 2nd structure of this invention, the said float receptacle of the said drain outlet peripheral part is comprised with an elastic member. The float is sucked by a strong suction force generated in the direction of the drain pipe due to the siphon principle, but according to this configuration, the float comes into contact with an elastic member around the drain port when the drain port is closed. For this reason, it is possible to prevent a large collision sound from being generated when the float blocks the drain port. Further, since the float receiver is configured by a member that does not allow water to pass, when the float blocks the drain outlet, water does not enter the drain outlet, and water flows into the drain outlet in a state of air mixing. Absent.

  According to the third configuration of the present invention, the upper end of the vent pipe is positioned higher than the upper part of the water reservoir, so that the water in the water reservoir is also retained when the float blocks the drain. It does not enter the ventilation pipe. For this reason, the said ventilation pipe exhibits the function to ventilate reliably. Note that the upper part of the water reservoir here is the highest water level determined by the balance of the inflow and outflow of drainage, and does not necessarily indicate a specific shape part.

  Therefore, when the water level around the drainage port is lowered, when the float is sucked to block the drainage port and the drainage is temporarily interrupted, only the atmosphere is supplied from the vent pipe into the drainage pipe. Thereby, the attraction | suction force to the said float by siphon effect | action can be eliminated reliably. In the first or second configuration, the suction force depends on design matters such as the height of the drainage pipe and the diameter of the drainage port blocked by the float. However, by eliminating the suction force by the third configuration, if the buoyancy acts on the float, it can be easily separated from the drain port, and the design items can be set freely.

  According to the fourth configuration of the present invention, since the float can be translated only in the vertical direction, the float surely blocks the drainage port in a state where the vent pipe is erected, and the The lower end of the ventilation pipe installed upright on the float is in reliable communication with the drain pipe. For this reason, the float exerts a function of reliably closing the drain when the water level of the water reservoir is lowered, and the vent pipe reliably introducing air into the drain pipe.

  According to the fifth configuration of the present invention, the upper end of the vent pipe is closed when the float is separated from the drain port. Therefore, even when the water level of the drainage drops and the suction force by the siphon reaches the lower part of the float, there is no inflow of air that weakens the suction force into the vent pipe. For this reason, even if the pipe diameter of the vent pipe is large, there is no problem that a large amount of air is supplied to the lower part of the float via the vent pipe, and the float is surely connected to the drain outlet. The drainage port can be closed by being drawn.

  Further, according to this configuration, when the float is separated from the drainage port, water flows into the drainage pipe, but air does not flow in because the upper end of the vent pipe is closed. On the other hand, when the float blocks the drain outlet, water does not flow into the drain pipe, but air flows in because the upper end of the vent pipe is open. In this way, only one of water and air can be selectively allowed to flow into the drain port, and water can be reliably prevented from flowing into the drain port in a state of being mixed with air. For this reason, it is possible to prevent a loud sound from being generated from the drain port.

  As described above, according to the present invention, it is possible to prevent the generation of a loud sound from the drain outlet when draining according to the siphon principle.

[Example 1]
The drainage structure of Example 1 is demonstrated using figures. FIG. 1 is an explanatory diagram of a drainage structure according to the first embodiment.

  As shown in FIG. 1, the drainage structure of the present embodiment is a drainage structure configured to drain according to the siphon principle, and a drainage reservoir 1 in which drainage accumulates and a drainage outlet 2 disposed in the reservoir 1. And a drain pipe 3 for discharging water through the drain port 2 and a float 4 disposed in the water reservoir 1.

  The water reservoir 1 is disposed at the bottom of a drainage facility such as a bathtub or rain gutter. The height of the water reservoir 1 is higher than at least the sum of the reverse gradients of the drainage pipe 3 in order to push the drainage accumulated in the reverse slope of the attached drainage pipe 3 in the downstream direction and cause drainage by the siphon principle. Have

  A drain port 2 is disposed in the water reservoir 1 so as to communicate with the drain pipe 3. It is preferable that the drain pipe 3 is in a state where it is likely to become full in order to drain water based on the siphon principle. For this reason, it is preferable to use a continuous pipe having a small diameter (φ50 or less, preferably φ10 to φ25) as the drain pipe 3.

  The float 4 is made of a hollow resin or the like, is arranged inside the water reservoir 1, and floats and sinks according to the water level accumulated in the water reservoir 1. In this embodiment, the float 4 has a spherical shape as shown in FIG. However, the present invention is not limited to this. For example, a configuration may be adopted in which the drainage port is closed so as to be substantially sealed by forming a flat bottom surface such as a columnar shape and contacting the periphery of the drainage port.

  When the water level in the water reservoir 1 is low, a sufficient buoyancy does not work on the float 4, and a suction force generated on the drainage pipe 3 works by its own weight and siphon principle. For this reason, as shown in FIG. 1, the float 4 contacts the drainage port 2 to close the drainage port 2. Then, neither water nor air flows into the drain port 2. Therefore, when the float 4 is blocking the drain port 2, water does not flow into the drain port 2 in a state of air mixing, and no sound is generated from the drain port 2.

  When the water level in the water reservoir 1 increases and the water pressure on the float 4 increases, the buoyancy also increases. Here, when the buoyancy is larger than the sum of the weight of the float 4 and the suction force generated in the drainage pipe 3 by the siphon principle, the float 4 floats in the water in the water reservoir 1 by the buoyancy, and the drain port 2 apart. At this time, since there is an amount of water enough to float the float 4 in the water reservoir 1, only water flows into the drain port 2. That is, water does not flow into the drain port 2 in a state where air is mixed, and the sound generated from the drain port 2 can be reduced.

  The design of the float 4 will be specifically described. As described above, in order for the float 4 to lift up by the buoyancy against the suction force to the drain pipe 3, the buoyancy of the float 4 is Fb (N), the suction force by the drain pipe 3 is Fs (N), If the working gravity is Fg (N), the relationship of Fb> Fs + Fg (N) needs to be satisfied. Here, each force can be expressed as follows.

The buoyancy Fb of the float 4 is expressed as follows: D (m) is the depth of the portion that receives the water pressure in the horizontal plane coordinates (x, y) of the float 4 and C (kg / m ³ ) is the density of drainage.
Fb = 9.8C∬Ddxdy (N) (1)
It can be expressed as.

The suction force Fs by the drainage pipe 3 is such that the vertical height of drainage below the drainage port 2 is H (m), the density of drainage is C (kg / m ³ ), and the horizontal area of the drainage port 2 is S (m ² )
Fs = 9.8 CHS (N) (2)
It can be expressed as. That, Fs is a function of is below the discharge port 2 drainage vertical height H (m) and the horizontal area of the discharge port 2 S (m ^2).

Gravity Fg acting on the float 4 is W (kg) when the mass of the float 4 is W (kg).
Fg = 9.8 W (N) (3)
It can be expressed as.

Therefore, the size of the float 4, the vertical height H (m) of the drain port 2, the horizontal area S (m ² ) of the drain port 2, and the material of the float 4 are set so as to satisfy the relationship of Fb> Fs + Fg (N). If determined, the float 4 is separated from the drain port 2 against the suction force to the drain pipe 3.

  With the above configuration, when the water level of the water reservoir 1 is low, the float 4 is sucked by the strong suction force generated in the direction of the drain pipe 3 by the siphon principle, and the float 4 closes the drain port 2. Water and air do not enter the drain. On the other hand, when the water level rises, the buoyancy acting on the float works against the suction force, and the float 4 moves away from the drain port 2, but at this time, air flows into the drain port 2 due to the high water level of the water reservoir 1. Since there is no room for flow, only water flows into the drain port 2. For this reason, water does not flow into the drain port 2 in a state of being mixed with air, and it is possible to prevent a loud sound from being generated from the drain port 2.

[Example 2]
The drainage structure of Example 2 is demonstrated using figures. FIG. 2 is an explanatory diagram of a drainage structure according to the second embodiment. Here, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

  In FIG. 2, the float 4 is sucked by a strong suction force generated in the direction of the drain pipe 3 by the siphon principle. For this reason, when the drainage port 2 and the float 4 are made of a hard material, a large collision sound may be generated when the float 4 blocks the drainage port 2.

  Therefore, in the drainage structure of the present embodiment, as shown in FIG. 2, in addition to the configuration of the first embodiment, a float receiver 5 is disposed at a portion where the lower portion of the float 4 abuts in the peripheral portion of the drain port 2. The float receiver 5 is formed of an elastic member that does not allow water to pass through.

  Then, when the float 4 closes the drain port 2, the float 4 comes into contact with the float receiver 5 around the drain port 2. For this reason, the impact sound of the float 4 and the drain port 2 is remarkably relieved by the elasticity of the float support 5. Further, since the float receiver 5 is constituted by a member that does not allow water to pass, when the float 4 closes the drain port 2, water does not enter the drain port 2, and water flows into the drain port 2 in a state of air mixing. There is no. The material of the float receiver 5 may be any material as long as it does not pass water and has an impact absorbing function. For example, foamed rubber such as foamed EPDM or foamed silicon rubber can be used.

Example 3
The drainage structure of Example 3 will be described with reference to the drawings. FIG. 3 is an explanatory diagram of a drainage structure according to the third embodiment. Here, the same reference numerals are given to the same components as those in the above-described embodiment, and the description thereof is omitted.

  As shown in FIG. 3, in the drainage structure of the present embodiment, the float 4 has a ventilation pipe 6 for communicating the water reservoir 1 and the drainage pipe 3. Further, the upper end of the vent pipe 6 is located higher than the upper part of the water reservoir 1. In addition, the upper part of the water reservoir part 1 said here is the highest level of the water level decided by the balance of the inflow / outflow of drainage, Comprising: It does not necessarily indicate a shape specific part. Therefore, the water in the water reservoir 1 does not enter the ventilation pipe 6.

Here, an advantageous effect when the ventilation pipe 6 is attached will be described. As shown in Example 1, the suction force Fs depends is below the discharge port 2 drainage vertical height H (m) and the horizontal area of the discharge port 2 S (m ^2). For this reason, in the above-described embodiment, it is necessary to design the size and weight of the float 4 according to the suction force Fs that depends on these design matters.

  However, when the float 4 has the vent pipe 6 as in the present embodiment, the atmosphere is supplied from the vent pipe 6 into the drain pipe 3 when the float 4 closes the drain port 2. Then, since the negative pressure near the lower portion of the drain port 2 can be set to atmospheric pressure, the suction force to the float 4 due to siphon action can be eliminated. As a result, if the buoyancy is exerted on the float 4, the float 4 can be easily separated from the drain outlet 2. It is not necessary to design the weight.

  The diameter of the vent pipe 6 needs to be at least smaller than that of the drain pipe 3. If the pipe diameter of the vent pipe 6 is larger than the diameter of the drain pipe 3, the surface area for the suction force Fs into the drain pipe 3 cannot be secured. This is because it cannot actually be sucked.

  As shown in FIG. 3, a top plate 7 for preventing foreign matter mixing is installed on the upper portion of the water reservoir 1, and the upper end of the vent pipe 6 disposed on the float 4 is a part of the top plate 7 (guide portion). ) Is configured to be movable in parallel up and down. That is, the movement in the left-right direction is restricted by the guide portion. With such a configuration, when the float 4 is lowered, the drain port 2 can be reliably closed, and the lower end of the vent pipe 6 standing on the float 4 is reliably communicated with the drain pipe 3. Therefore, the vent pipe 6 functions to introduce air into the drain pipe 3 while stopping the inflow of drain water into the drain port 2, and the suction force due to the siphon action near the drain port 2 can be reliably eliminated. it can.

  In this embodiment, a part of the eye plate 7 is used as the guide portion, but the present invention is not limited to this. For example, as shown in FIG. 4, a plurality of guide plates 8 are provided as guide portions around the cylindrical float 4 on the side surface or bottom surface of the water reservoir 1, and the float 4 is not moved in the horizontal direction. You may comprise so that it may move only to a direction.

Example 4
The drainage structure of Example 4 will be described with reference to the drawings. FIG. 5 is an explanatory diagram of a drainage structure according to the fourth embodiment. Here, the same reference numerals are given to the same components as those in the above-described embodiment, and the description thereof is omitted.

  As shown in FIG. 5, in the drainage structure of the present embodiment, a lid 9 is provided on the upper end of the vent pipe 6 disposed in the float 4. Further, a rod-like member 10 supported by a rod-like member support portion 11 is disposed in the vicinity of the drainage port 2 of the drainage pipe 3 and penetrates through the ventilation pipe 6 and comes into contact with the lid 9 from below. Here, the rod-shaped member 10 also serves as a guide portion for guiding the float 4 so as to be movable only in the vertical direction. The length of the rod-shaped member 10 has such a length that it abuts against the lid 9 and pushes up the lid 9 only when the float 4 closes the drain port 2. For this reason, when the float 4 closes the drain port 2, the rod-shaped member 10 pushes up the lid 9 and the upper end of the vent pipe 6 is opened. Further, when the float 4 is separated from the drain port 2, the rod-like member 10 is separated from the lid 9, so that the lid 9 is lowered by its own weight and the upper end of the vent pipe 6 is closed. Next, the operation during drainage will be specifically described.

  As shown in FIG. 5A, in the initial state where water does not flow into the water reservoir 1, the float 4 closes the drain port 2 by its own weight. In this state, the rod-shaped member 10 attached to the drainage pipe 3 passes through the ventilation pipe 6 and the upper end thereof contacts the lid 9, thereby opening the lid 9.

  As shown in FIG. 5 (b), when water flows into the water reservoir 1, buoyancy gradually acts on the float 4 according to the water level of the water reservoir 1, and force acts in a direction away from the drain port 2. In a state where the float 4 is not separated from the drain port 2, water does not flow into the drain pipe 3 yet.

  As shown in FIG. 5 (c), when the water level of the water reservoir 1 further rises and the buoyancy is exerted on the float 4 to overcome the dead weight of the float 4, the float 4 is separated from the drain port 2. At this time, the lid 9 simultaneously closes the upper end opening of the vent pipe 6 by its own weight, so that air does not enter from the vent pipe 6. For this reason, water flows into the drainage pipe 3 from the portion where the float 4 is separated from the drainage port 2, while air does not flow from the vent pipe 6. Therefore, it is possible to create a state in which only water flows into the drain port 2.

  As shown in FIGS. 5 (d) and 5 (e), when the water level in the water reservoir 1 drops due to drainage, the float 4 also falls, and when the float 4 approaches the drain outlet 2, the suction force to the drain pipe 3 by siphon action As a result, the float 4 is attracted to the drain port 2 and closes the drain port 2. At this time, the rod-shaped member 10 comes into contact with the lid 9 to push up the lid 9 and the upper end of the vent pipe 6 is opened. In this state, since the float 4 closes the drain port 2, water does not flow into the drain port 2, while air flows into the drain port 2 because the vent pipe 6 is open. In this way, it is possible to create a state in which only air flows into the drain port 2.

  As shown in FIG. 5 (f), when the air sufficiently enters from the vent pipe 6, the negative pressure near the lower portion of the drain port 2 can be set to atmospheric pressure, so the suction force to the drain pipe 3 is eliminated. The Then, when the water level of the water reservoir 1 is low, the state returns to the state of FIG. 5B again, and when the water level of the water reservoir 1 is high, the state returns to the state of FIG. 5C again, and these operations are repeated.

  Thus, when the float 4 closes the drain port 2, only air flows into the drain pipe 3 through the vent pipe 6, and when the float 4 moves away from the drain port 2, only water from the lower part of the float 4 enters the drain pipe 3. Flows in. In this way, only one of water and air can be selectively allowed to flow into the drain port 2, and water can be reliably prevented from flowing into the drain port 2 in a state of being mixed with air. For this reason, it is possible to prevent a loud sound from being generated from the drain port 2.

  Further, when the float 4 is separated from the drain port 2, the upper end of the vent pipe 6 is closed. Therefore, even if the diameter of the vent pipe 6 is large, air does not flow into the vent pipe 6. In Example 3, if the vent pipe 6 is made too large, a large amount of air flows from the vent pipe 6 and the float 4 may not be sufficiently sucked in the direction of the drain pipe 3. It was necessary to adjust the diameter. However, in this embodiment, as long as the float 4 does not block the drain port 2, air does not flow into the drain port 2 from the vent pipe 6. For this reason, that is, since the float 4 can reliably block the drain port 2 by the suction force to the drain pipe 3, the diameter of the vent pipe 6 can be designed freely.

  In this embodiment, the vent pipe 6 is opened and closed by disposing the lid 9 and the rod-shaped member 10, but the present invention is not limited to this. For example, as shown in FIG. 6, when the float 4 is separated from the drain port 2 (see FIG. 6B), the inner diameter of the vent pipe 6 configured to fit into the vent pipe 6 from above is A vent pipe closing member 12 for closing the vent pipe having substantially the same diameter is disposed, and the fitting with the vent pipe 6 is released only when the float 4 reaches the lower end (see FIG. 6A). It is good also as a structure.

  INDUSTRIAL APPLICABILITY The present invention can be used for a general drainage structure in which drainage is performed according to the principle of siphon.

1 is an explanatory diagram of a drainage structure according to Embodiment 1. FIG. Explanatory drawing of the drainage structure which concerns on Example 2. FIG. Explanatory drawing of the drainage structure which concerns on Example 3. FIG. Explanatory drawing of the drainage structure using the guide plate 8 which concerns on Example 3. FIG. Explanatory drawing of the drainage structure which concerns on Example 4. FIG. Explanatory drawing of the drainage structure which concerns on another Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Water reservoir part, 2 ... Drain outlet, 3 ... Drain pipe, 4 ... Float,
5 ... Floating receptacle, 6 ... Vent pipe, 7 ... Eye plate, 8 ... Guide plate, 9 ... Lid,
10 ... Bar-shaped member, 11 ... Bar-shaped member support,
12… Vent pipe closing member, 13… Cylinder

Claims (5)

In the drainage structure that drains by the principle of siphon,
A water reservoir where drainage accumulates;
A drain outlet disposed in the water reservoir,
A drain pipe for draining water communicating with the drain port;
A float arranged in the water reservoir,
The float blocks the drain port when the water level in the water reservoir is low, and separates from the drain port against the suction force to the drain pipe by the buoyancy received by the float when the water level in the water reservoir increases. Drainage structure characterized by that. The drainage structure according to claim 1,
A drainage structure formed by an elastic member that is impermeable to water is disposed around the drainage port. The drainage structure according to claim 1 or 2,
The float has a ventilation pipe for communicating the water reservoir and the drain pipe,
The drainage structure according to claim 1, wherein an upper end of the vent pipe is located higher than an upper part of the water reservoir. A drainage structure according to any one of claims 1 to 3,
The drainage structure characterized in that the float is configured to be movable only in the vertical direction. The drainage structure according to claim 3 or 4,
The upper end of the vent pipe is
When the float closes the drain, it opens,
A drainage structure characterized by closing when the float is separated from the drainage port.

Images