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JP5592282B2 - Valve device - Google Patents
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JP5592282B2 - Valve device - Google Patents

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JP5592282B2
JP5592282B2 JP2011010845A JP2011010845A JP5592282B2 JP 5592282 B2 JP5592282 B2 JP 5592282B2 JP 2011010845 A JP2011010845 A JP 2011010845A JP 2011010845 A JP2011010845 A JP 2011010845A JP 5592282 B2 JP5592282 B2 JP 5592282B2
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inner cylinder
cylinder side
flow path
valve
opening
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JP2012149751A (en
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良泰 伊藤
朋弘 穐田
範行 北地
尚紀 柴田
仁史 北村
康成 前田
恭子 堤
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Panasonic Corp
Panasonic Holdings Corp
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Panasonic Corp
Matsushita Electric Industrial Co Ltd
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  • Taps Or Cocks (AREA)
  • Electrically Driven Valve-Operating Means (AREA)
  • Indication Of The Valve Opening Or Closing Status (AREA)

Description

本発明は、流量を制御する弁装置に関する。   The present invention relates to a valve device for controlling a flow rate.

従来より、円筒状の外筒とこれに内装される円筒状の内筒を備え、外筒と内筒とが相対回転することにより流量を調整する回転式の流量調整弁が知られている(例えば、特許文献1参照)。この流量調整弁は、外筒および内筒のうち、一方の外周部には多数の小孔を有する流量調節部と面積の大きい開口部を有する開放部とが周方向に設けられ、他方の外周部には流量調節部および開放部と重なる大きさの開口部が設けられている。そして、流量調節部および開放部と開口部との重なり度合いによって流量が調整される。   2. Description of the Related Art Conventionally, there is known a rotary flow rate adjustment valve that includes a cylindrical outer cylinder and a cylindrical inner cylinder that is housed therein, and that adjusts the flow rate by rotating the outer cylinder and the inner cylinder relative to each other ( For example, see Patent Document 1). This flow control valve is provided with a flow rate adjusting portion having a large number of small holes in an outer peripheral portion of one of an outer cylinder and an inner cylinder and an open portion having an opening having a large area in the circumferential direction, and the other outer peripheral portion. The part is provided with an opening having a size overlapping the flow rate adjusting part and the opening part. Then, the flow rate is adjusted according to the flow rate adjusting unit and the degree of overlap between the opening and the opening.

特開2003−42312号公報JP 2003-42312 A

しかしながら、この流量調整弁は、それが配置される管路を流れる流体の圧力変化を考慮したものではなかった。一般的に地域による水道の水圧には大きなバラツキがあり、水道の供給弁において同一の弁構造で対応しようとした場合、例えば低水圧側に合わせて設計すると弁の開口度が大きくなり、高水圧地域での使用時に流量変化が大きくなる。このため流量、温度の混合調整がしにくくなるなどの問題があった。一方、高水圧側に合わせて設計すると弁の開口度は小さくなり、低水圧地域での使用時に流量が小さくなりすぎるなどの問題があった。水圧に応じて弁を個別に準備して対応することが考えられるが、品種増による製造および管理コストがアップするなどの問題がある。したがって、中水圧側に合わせて弁の開口度を設計することが一般的であるが、低水圧地域および高水圧地域での使用時の問題は完全に解消されない。   However, this flow regulating valve does not take into account the pressure change of the fluid flowing through the pipe line in which it is disposed. Generally, there is a large variation in the water pressure of the water supply in each region, and when trying to cope with the same valve structure in the water supply valve, for example, if designed according to the low water pressure side, the opening degree of the valve becomes large, and the high water pressure The flow rate changes greatly when used in the area. For this reason, there existed problems, such as it becoming difficult to perform mixing adjustment of flow volume and temperature. On the other hand, when designed according to the high water pressure side, the degree of opening of the valve is small, and there is a problem that the flow rate becomes too small when used in a low water pressure region. Although it is conceivable to prepare and respond to the valves individually according to the water pressure, there are problems such as an increase in production and management costs due to an increase in the variety. Therefore, it is common to design the opening degree of the valve in accordance with the middle water pressure side, but the problem during use in the low water pressure region and the high water pressure region is not completely solved.

本発明は、以上のとおりの事情に鑑みてなされたものであり、地域による一次側の水圧のバラツキが大きい場合でも一つの弁で対応可能な弁装置を提供することを課題とする。 This invention is made | formed in view of the above situations, and makes it a subject to provide the valve apparatus which can respond with one valve, even when the variation of the water pressure of the primary side by area is large.

上記の課題を解決するために、本発明の弁装置は、円筒状の外筒およびこの外筒に内装される円筒状の内筒を有し、前記外筒の側面部には内外に貫通する外筒側開口が形成され、この外筒側開口は外部流路と接続可能であり、前記内筒の内側には流体が流通する内部流路が形成され側面部には内外に貫通する内筒側開口が周方向に複数形成され、これら内筒側開口はそれぞれ開口面積が異なり、前記内筒の周方向の回転により複数ある前記内筒側開口の一つが前記外筒側開口に重なり前記内部流路と前記外部流路が連通して流体が流通可能な流体流路が形成され、前記内筒側開口各々において前記流体流路の形成が可能であり、それら流体流路の切り替えが可能とされている弁と、前記内筒を回転させる回転制御部とを備え、前記回転制御部は、前記弁の一次側の流体圧力に関する情報に基づいて、複数ある前記内筒側開口において形成される前記流体流路のいずれかに切り替えて前記流体の流通を可能にしていることを特徴とする。   In order to solve the above-described problems, the valve device of the present invention has a cylindrical outer cylinder and a cylindrical inner cylinder installed in the outer cylinder, and penetrates inward and outward in a side surface portion of the outer cylinder. An outer cylinder side opening is formed, the outer cylinder side opening is connectable to an external flow path, an inner flow path through which fluid flows is formed inside the inner cylinder, and an inner cylinder that penetrates inward and outward in a side surface portion A plurality of side openings are formed in the circumferential direction, and the inner cylinder side openings have different opening areas, and one of the plurality of inner cylinder side openings overlaps the outer cylinder side opening due to the rotation of the inner cylinder in the circumferential direction. A fluid channel is formed in which the fluid channel can communicate with the external channel, and the fluid channel can be formed in each of the inner cylinder side openings, and the fluid channels can be switched. A rotation control unit that rotates the inner cylinder, and the rotation control unit. The flow of the fluid is enabled by switching to one of the plurality of fluid flow paths formed in the inner cylinder side opening based on information on the fluid pressure on the primary side of the valve. .

この弁装置においては、さらに、前記回転制御部に電気的に接続される、前記弁の一次側の流体圧力に関する情報に基づいて前記内筒の回転の指示を入力するコントローラを備えており、前記回転制御部は、前記コントローラに入力された指示により前記内筒を回転させて複数ある前記内筒側開口において形成される前記流体流路のいずれかに切り替えることが好ましい。   The valve device further includes a controller that is electrically connected to the rotation control unit and that inputs an instruction to rotate the inner cylinder based on information on the fluid pressure on the primary side of the valve. Preferably, the rotation control unit rotates the inner cylinder according to an instruction input to the controller and switches to one of the plurality of fluid flow paths formed in the inner cylinder side opening.

また、この弁装置においては、さらに、前記弁の一次側の流路に設けられる、圧力センサおよび流量センサのうち少なくともいずれか一方を備えており、前記弁の一次側の流体圧力に関する情報が、前記圧力センサ、前記流量センサまたはこれら両者によって検知され、前記回転制御部は、前記検知結果に基づいて前記内筒を回転させて複数ある前記内筒側開口において形成される前記流体流路のいずれかに切り替えることが好ましい。   The valve device further includes at least one of a pressure sensor and a flow rate sensor provided in a flow path on the primary side of the valve, and information on fluid pressure on the primary side of the valve is Detected by the pressure sensor, the flow sensor or both of them, the rotation control unit rotates any one of the fluid flow paths formed in the plurality of inner cylinder side openings by rotating the inner cylinder based on the detection result. It is preferable to switch to

本発明の弁装置によれば、地域による一次側の水圧のバラツキが大きい場合でも一つの弁で対応可能である。 According to the valve device of the present invention, even when there is a large variation in water pressure on the primary side depending on the region, a single valve can be used.

、本発明の弁装置の一実施形態を概略的に示した構成図である。1 is a configuration diagram schematically showing an embodiment of a valve device of the present invention. 図1の弁装置において内筒を周方向に180°回転させた弁の断面図である。It is sectional drawing of the valve which rotated the inner cylinder 180 degrees to the circumferential direction in the valve apparatus of FIG. 図1の弁装置における弁の斜視図である。It is a perspective view of the valve in the valve apparatus of FIG. 本発明の弁装置の別の一実施形態を概略的に示した構成図である。It is the block diagram which showed schematically another one Embodiment of the valve apparatus of this invention.

本発明の弁装置を図面に沿って説明する。図1は、本発明の弁装置の一実施形態を概略的に示した構成図であり、図2は、図1の弁装置において内筒を周方向に180°回転させた弁の断面図であり、図3は、図1の弁装置における弁の斜視図である。   The valve device of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram schematically showing an embodiment of the valve device of the present invention, and FIG. 2 is a cross-sectional view of a valve obtained by rotating an inner cylinder 180 ° in the circumferential direction in the valve device of FIG. FIG. 3 is a perspective view of a valve in the valve device of FIG.

弁装置1は、外筒3および内筒10を有する弁2と回転制御部20とで構成されており、例えば、上水道の配管30の管路などに配設され、管路内を流れる水道などの流体の流量を増減制御するのに用いることができる。   The valve device 1 includes a valve 2 having an outer cylinder 3 and an inner cylinder 10 and a rotation control unit 20. For example, a water pipe that is disposed in a pipeline of a water supply pipe 30 and flows in the pipeline. It can be used to increase or decrease the flow rate of the fluid.

弁2の外筒3は、円筒状に形成されており、側面部には内外に貫通する外筒側開口4が形成され、この外筒側開口4は外部流路31と接続可能とされている。外筒側開口4の個数は特に制限されるものではなく、例えば、一つでもよいし、二つ以上であってもよい。外筒側開口4が複数ある場合、各々の位置は周方向に形成されていれば特に制限されない。外筒側開口4の開口面積は外部流路31を形成する配管30の管路の大きさに応じたものとすることができる。本実施形態では、二つの外筒側開口4a、4bがそれぞれ外筒3の側面部に周方向に形成されており、これら外筒側開口4a、4bは対向しており、また、それぞれ開口面積が異なっている。   The outer cylinder 3 of the valve 2 is formed in a cylindrical shape, and an outer cylinder side opening 4 penetrating inward and outward is formed in the side surface portion, and the outer cylinder side opening 4 can be connected to an external flow path 31. Yes. The number of outer cylinder side openings 4 is not particularly limited, and may be one or two or more, for example. In the case where there are a plurality of outer cylinder side openings 4, each position is not particularly limited as long as each position is formed in the circumferential direction. The opening area of the outer cylinder side opening 4 can be determined according to the size of the pipe line of the pipe 30 forming the external flow path 31. In the present embodiment, two outer cylinder side openings 4a and 4b are respectively formed in the circumferential direction on the side surface portion of the outer cylinder 3, and these outer cylinder side openings 4a and 4b are opposed to each other, and each has an opening area. Is different.

外筒3の筒軸方向の一端部には、外筒3の内径と同径である、内筒10を挿入する挿入孔5が形成されている。他端部には、外筒3の内径よりも小さい径である貫通孔6が形成されており、この貫通孔6は、後述する内筒10の回転軸部14が挿通可能にこの回転軸部14の外径よりも若干大きい径とされている。   An insertion hole 5 for inserting the inner cylinder 10 having the same diameter as the inner diameter of the outer cylinder 3 is formed at one end of the outer cylinder 3 in the cylinder axis direction. A through-hole 6 having a diameter smaller than the inner diameter of the outer cylinder 3 is formed at the other end, and the through-hole 6 can be inserted into a rotary shaft 14 of the inner cylinder 10 to be described later. The outer diameter of 14 is slightly larger.

弁2の内筒10は、円筒状に形成されており、外径が外筒3の内径よりも若干小さい径とされ、回転可能に外筒3に内装されている。内筒10の内側には流体が流通する内部流路11が形成されており、筒軸方向の一端部には開口12が形成され、この開口12は外部流路32と接続可能とされ、内部流路11と外部流路32が連通可能とされている。   The inner cylinder 10 of the valve 2 is formed in a cylindrical shape, has an outer diameter that is slightly smaller than the inner diameter of the outer cylinder 3, and is rotatably mounted in the outer cylinder 3. An internal flow path 11 through which a fluid flows is formed inside the inner cylinder 10, and an opening 12 is formed at one end in the cylinder axis direction. The opening 12 can be connected to an external flow path 32, The flow path 11 and the external flow path 32 can communicate with each other.

内筒10の側面部には内外に貫通する内筒側開口13が周方向に複数形成されている。複数ある内筒側開口13はそれぞれ開口面積が異なっており、これら内筒側開口13の開口面積は外部流路31に接続される外筒側開口4の開口面積以下とすることができる。内筒側開口13は三つ以上形成されていてもよい。これら内筒側開口13の位置は、各々が周方向に形成され、隣接する複数の内筒側開口13が一つの外筒側開口4と重ならないように離間されていることが考慮される。   A plurality of inner cylinder side openings 13 penetrating inward and outward are formed in the side surface of the inner cylinder 10 in the circumferential direction. The plurality of inner cylinder side openings 13 have different opening areas, and the opening area of these inner cylinder side openings 13 can be made equal to or smaller than the opening area of the outer cylinder side opening 4 connected to the external flow path 31. Three or more inner cylinder side openings 13 may be formed. It is considered that the positions of the inner cylinder side openings 13 are each formed in the circumferential direction, and the plurality of adjacent inner cylinder side openings 13 are separated so as not to overlap one outer cylinder side opening 4.

本実施形態では、二つの内筒側開口13a、13bが形成されており、これら内筒側開口13a、13bは対向している。内筒側開口13a、13bはそれぞれ開口面積が異なっており、内筒側開口13aの開口面積は外筒側開口4aの開口面積と略同面積とされており、内筒側開口13bの開口面積は外筒側開口4aの開口面積よりも小さい面積とされている。   In this embodiment, two inner cylinder side openings 13a and 13b are formed, and these inner cylinder side openings 13a and 13b are opposed to each other. The inner cylinder side openings 13a and 13b have different opening areas. The opening area of the inner cylinder side opening 13a is substantially the same as the opening area of the outer cylinder side opening 4a, and the opening area of the inner cylinder side opening 13b. Is smaller than the opening area of the outer cylinder side opening 4a.

内筒10の筒軸方向の他端部には回転軸部14が形成されている。内筒10の回転軸部14を外筒3の挿入孔5および貫通孔6に順次挿通させることにより内筒10が外筒3に内装される。   A rotation shaft portion 14 is formed at the other end portion of the inner tube 10 in the tube axis direction. The inner cylinder 10 is housed in the outer cylinder 3 by sequentially inserting the rotation shaft portion 14 of the inner cylinder 10 into the insertion hole 5 and the through hole 6 of the outer cylinder 3.

内筒10が周方向に回転すると、内筒側開口13の一つが外筒側開口4と重なり内部流路11と外部流路31が連通して流体が流通可能な流体流路33が形成される。図1では開口面積が大きい内筒側開口13aと、外部流路31に接続されている外筒側開口4aとが重なって流体流路33が形成されている。また、開口12と外部流路32とが接続されており、流体は、外部流路32、内部流路11、外部流路31の順に経由して流通するようになっている。もちろん、外部流路31、内部流路11、外部流路32の順に流体を流通させることもできる。   When the inner cylinder 10 rotates in the circumferential direction, one of the inner cylinder side openings 13 overlaps with the outer cylinder side opening 4 to form a fluid channel 33 through which the internal channel 11 and the outer channel 31 communicate to allow fluid to flow. The In FIG. 1, a fluid flow path 33 is formed by overlapping an inner cylinder side opening 13 a having a large opening area and an outer cylinder side opening 4 a connected to the external flow path 31. Moreover, the opening 12 and the external flow path 32 are connected, and the fluid flows through the external flow path 32, the internal flow path 11, and the external flow path 31 in this order. Of course, the fluid can be circulated in the order of the external flow path 31, the internal flow path 11, and the external flow path 32.

図1において内筒10を周方向に180°回転させると、図2−3に示すように、開口面積が小さい内筒側開口13bと、外部流路31に接続されている外筒側開口4aとが重なって流体流路33が形成されている。この例においても、開口12と外部流路32とが接続されており、流体は、外部流路32、内部流路11、外部流路31の順に経由して流通可能になっている。   1, when the inner cylinder 10 is rotated 180 ° in the circumferential direction, as shown in FIG. 2-3, the inner cylinder side opening 13b having a small opening area and the outer cylinder side opening 4a connected to the external flow path 31 are obtained. And a fluid flow path 33 is formed. Also in this example, the opening 12 and the external flow path 32 are connected, and the fluid can flow through the external flow path 32, the internal flow path 11, and the external flow path 31 in this order.

このように、弁2は、内筒側開口13a、13b各々において流体流路33の形成が可能である。また、内筒側開口13aを介する流体流路33に流体を流通させるか、内筒側開口13bを介する流体流路33に流体を流通させるか、流体流路33の切り替えが可能とされている。   Thus, the valve 2 can form the fluid flow path 33 in each of the inner cylinder side openings 13a and 13b. In addition, the fluid flow path 33 through the inner cylinder side opening 13a is allowed to flow, the fluid is passed through the fluid flow path 33 via the inner cylinder side opening 13b, or the fluid flow path 33 can be switched. .

回転制御部20は、弁2の内筒10を回転させており、弁2の一次側の流体圧力に関する情報に基づいて、複数ある内筒側開口13において形成される流体流路33のいずれかに切り替えて、その流体流路33への流体の流通を可能にしている。   The rotation control unit 20 rotates the inner cylinder 10 of the valve 2, and based on information on the fluid pressure on the primary side of the valve 2, any one of the fluid flow paths 33 formed in the plurality of inner cylinder side openings 13. The fluid is allowed to flow to the fluid flow path 33.

回転制御部20は、例えば、図1に示すようにモータ21と制御部22で構成することができる。モータ21は、弁2の内筒10の回転軸部14に連結され、モータ21の回転駆動により内筒10を周方向に回転可能にしている。制御部22は、例えば、マイクロコンピュータなどを内蔵する電気回路などを収納した制御ボックスなどで構成されており、モータ21と電気的に接続されている。この制御部22は、複数ある内筒側開口13において形成されるいずれの流体流路33に流体を流通させるか、その流体流路33の切り替えのためのモータ21の回転駆動を制御するものであり、内筒側開口13が所定の位置に配置されるように制御するものである。   The rotation control unit 20 can be composed of, for example, a motor 21 and a control unit 22 as shown in FIG. The motor 21 is connected to the rotating shaft portion 14 of the inner cylinder 10 of the valve 2, and the inner cylinder 10 can be rotated in the circumferential direction by the rotation drive of the motor 21. The control unit 22 includes, for example, a control box that houses an electric circuit that incorporates a microcomputer or the like, and is electrically connected to the motor 21. The control unit 22 controls the rotational drive of the motor 21 for switching the fluid flow path 33 to flow through any of the fluid flow paths 33 formed in the plurality of inner cylinder side openings 13. Yes, and controls the inner cylinder side opening 13 to be arranged at a predetermined position.

低水圧地域など弁2の一次側の流体圧力が低い地域での使用時には、図1に示すように、開口面積が大きい内筒側開口13aが外部流路31に接続されている外筒側開口4aに重なる位置に配置されるようにモータ21を回転駆動させ、流体流路33を切り替える。内筒側開口13aが配置される位置は、外筒側開口4aに完全に重なるような位置でなくてもよく、その一部が重なるような位置に配置することもできる。また、内筒側開口13aを介する流体流路33に切り替えた後、内筒10の回転によりその流体流路33に流体を流通させることができれば、流体流路33切り替え時に内筒側開口13aが外筒側開口4aに重ならない位置に配置することもできる。   When used in an area where the fluid pressure on the primary side of the valve 2 is low, such as in a low water pressure area, as shown in FIG. 1, the outer cylinder side opening in which the inner cylinder side opening 13 a having a large opening area is connected to the external flow path 31. The motor 21 is rotationally driven so as to be disposed at a position overlapping with 4a, and the fluid flow path 33 is switched. The position at which the inner cylinder side opening 13a is disposed may not be a position that completely overlaps the outer cylinder side opening 4a, but may be disposed at a position at which a part thereof overlaps. Further, after switching to the fluid flow path 33 via the inner cylinder side opening 13 a, if the fluid can be circulated through the fluid flow path 33 by rotation of the inner cylinder 10, the inner cylinder side opening 13 a is changed when the fluid flow path 33 is switched. It can also be arranged at a position that does not overlap the outer cylinder side opening 4a.

例えば、内筒側開口13aを介する流体流路33に切り替えた後も内筒側開口13aと外筒側開口4aとの重なり度合いを変化させて流体の流量を変化させたり止水したりするなど内筒10を周方向に一定の範囲内で回転させる場合がある。この場合には、内筒側開口13aを介する流体流路33切り替え時に内筒側開口13aが、外筒側開口4aの付近(内外に貫通していない箇所)に重なるように配置されるなど外筒側開口4aおよびその付近を含めて一定の範囲内で配置されることも許容される。   For example, even after switching to the fluid flow path 33 via the inner cylinder side opening 13a, the degree of overlap between the inner cylinder side opening 13a and the outer cylinder side opening 4a is changed to change the flow rate of the fluid or stop the water. The inner cylinder 10 may be rotated within a certain range in the circumferential direction. In this case, when the fluid flow path 33 is switched via the inner cylinder side opening 13a, the inner cylinder side opening 13a is arranged so as to overlap with the vicinity of the outer cylinder side opening 4a (a portion not penetrating inside and outside). Arrangement within a certain range including the cylinder side opening 4a and its vicinity is also allowed.

一方、高水圧地域など弁2の一次側の流体圧力が高い地域での使用時には、図2に示すように、開口面積が小さい内筒側開口13bが外部流路31に接続されている外筒側開口4aに重なる位置に配置されるようにモータを回転駆動させ、流体流路33を切り替える。この場合においても、内筒側開口13bが配置される位置は、外筒側開口4aに完全に重なるような位置でなくてもよく、その一部が重なるような位置に配置することもできる。また、内筒側開口13bを介する流体流路33に切り替えた後、内筒10の回転によりその流体流路33に流体を流通させることができれば、流体流路33切り替え時に内筒側開口13bが外筒側開口4aと重ならない位置に内筒側開口13bを配置することもできる。   On the other hand, when used in an area where the fluid pressure on the primary side of the valve 2 is high, such as a high water pressure area, the outer cylinder in which the inner cylinder side opening 13b having a small opening area is connected to the external flow path 31, as shown in FIG. The motor is driven to rotate so as to be disposed at a position overlapping the side opening 4a, and the fluid flow path 33 is switched. Also in this case, the position at which the inner cylinder side opening 13b is disposed does not have to be completely overlapped with the outer cylinder side opening 4a, and can be disposed at a position where a part thereof overlaps. Further, after switching to the fluid flow path 33 through the inner cylinder side opening 13b, if the fluid can be circulated through the fluid flow path 33 by rotation of the inner cylinder 10, the inner cylinder side opening 13b is opened when the fluid flow path 33 is switched. The inner cylinder side opening 13b can also be arranged at a position that does not overlap the outer cylinder side opening 4a.

以上の弁装置1は、弁2の一次側の流体圧力が低い地域での使用時には開口度が大きな流体流路33に流体を流通させることができる。この場合、圧力損失が低減するため、流体の流量が小さくなりすぎるなどの問題を低減することができる。また、弁2の一次側の流体圧力が高い地域での使用時には開口度が小さな流体流路33に流体を流通させることができる。この場合、流量変化を緩やかにすることができ、流量、温度の混合調整がしにくくなるなどの問題を低減することができる。このように弁2の一次側の流体圧力の変動が大きい場合でも、一つの弁装置1で一定以上の流量を確保することが可能である。しかも、流量変化を緩やかにすることができるので温度、流量の微調整が容易であり、ユーザの利便性を大きく向上できる。よって、弁2の一次側の流体圧力の変動が大きい場合でも一つの弁装置1で対応可能である。   The valve device 1 described above can circulate a fluid through the fluid flow path 33 having a large opening degree when used in an area where the fluid pressure on the primary side of the valve 2 is low. In this case, since the pressure loss is reduced, it is possible to reduce problems such as the fluid flow rate becoming too small. Further, when used in an area where the fluid pressure on the primary side of the valve 2 is high, the fluid can be circulated through the fluid flow path 33 having a small opening degree. In this case, the change in flow rate can be moderated, and problems such as difficulty in adjusting the mixing of the flow rate and temperature can be reduced. Thus, even when the fluctuation of the fluid pressure on the primary side of the valve 2 is large, it is possible to ensure a flow rate of a certain level or more with one valve device 1. In addition, since the change in flow rate can be moderated, fine adjustment of the temperature and flow rate is easy, and the convenience for the user can be greatly improved. Therefore, even when the fluctuation of the fluid pressure on the primary side of the valve 2 is large, the single valve device 1 can cope with it.

弁装置1は、図1に示すように、さらに、内筒10の回転の指示を入力するコントローラ23を設けることもできる。このコントローラ23は、例えば、流体流路33切り替えのためのボタンを有する。図1の例では、低水圧地域用に流体流路33を切り替えるための低水圧ボタン24と、高水圧地域用に流体流路33を切り替えるための高水圧ボタン25を有する。   As shown in FIG. 1, the valve device 1 may further include a controller 23 that inputs an instruction to rotate the inner cylinder 10. The controller 23 has a button for switching the fluid flow path 33, for example. In the example of FIG. 1, a low water pressure button 24 for switching the fluid flow path 33 for a low water pressure area and a high water pressure button 25 for switching the fluid flow path 33 for a high water pressure area are provided.

このコントローラ23において低水圧ボタン24または高水圧ボタン25を押すなどの操作を行うと、内筒10の回転の指示が入力される。コントローラ23は、回転制御部20の制御部22と電気的に接続されており、その入力情報は入力信号として制御部22に伝えられるようになっている。   When an operation such as pressing the low water pressure button 24 or the high water pressure button 25 is performed on the controller 23, an instruction to rotate the inner cylinder 10 is input. The controller 23 is electrically connected to the control unit 22 of the rotation control unit 20, and the input information is transmitted to the control unit 22 as an input signal.

低水圧ボタン24を押した場合、図1に示すように、開口面積が大きい内筒側開口13aが外筒側開口4aに重なる位置に配置されるようにモータ21が回転駆動し、内筒側開口13aを介する流体流路33に流体が流通可能に流体流路33が切り替えられる。高水圧ボタン25を押した場合、図2−3に示すように、開口面積が小さい内筒側開口13bが外筒側開口4aに重なる位置に配置されるようにモータが回転駆動し、内筒側開口13bを介する流体流路33に流体が流通可能に流体流路33が切り替えられる。   When the low water pressure button 24 is pressed, as shown in FIG. 1, the motor 21 is driven to rotate so that the inner cylinder side opening 13a having a large opening area is disposed at a position overlapping the outer cylinder side opening 4a. The fluid flow path 33 is switched so that fluid can flow through the fluid flow path 33 via the opening 13a. When the high water pressure button 25 is pressed, as shown in FIG. 2-3, the motor is driven to rotate so that the inner cylinder side opening 13b having a small opening area is disposed at a position overlapping the outer cylinder side opening 4a. The fluid channel 33 is switched so that fluid can flow through the fluid channel 33 via the side opening 13b.

低水圧ボタン24および高水圧ボタン25のうちいずれのボタンを選択して押すかは、あらかじめ計測した、弁2の一次側の流体圧力(水圧)に基づいて決定される。例えば、水圧が0.4MPa未満の場合には低水圧ボタン24を押し、水圧が0.4MPa以上の場合には高水圧ボタン25を押す。   Which one of the low water pressure button 24 and the high water pressure button 25 is selected and pressed is determined based on the fluid pressure (water pressure) on the primary side of the valve 2 measured in advance. For example, when the water pressure is less than 0.4 MPa, the low water pressure button 24 is pushed, and when the water pressure is 0.4 MPa or more, the high water pressure button 25 is pushed.

このような弁装置1は、弁2の一次側の流体圧力の変動が大きい場合でも、弁2の一次側の流体圧力に関する情報に基づいて、ボタン一つで流体流路33を切り替えて対応させることができるため、ユーザの利便性をより大きく向上できる。   In such a valve device 1, even when the fluctuation of the fluid pressure on the primary side of the valve 2 is large, the fluid flow path 33 is switched with a single button based on the information on the fluid pressure on the primary side of the valve 2. Therefore, user convenience can be greatly improved.

図4は、本発明の弁装置の別の一実施形態を概略的に示した構成図である。図1−図3に示した弁装置および弁と同じ部分には同一の符号を付し、その説明を省略する。   FIG. 4 is a configuration diagram schematically showing another embodiment of the valve device of the present invention. The same parts as those of the valve device and the valve shown in FIGS. 1 to 3 are denoted by the same reference numerals, and description thereof is omitted.

弁装置1は、図4に示すように、流体圧力を検知する圧力センサ26および流体流量を検知する流量センサ27のうち少なくともいずれか一方を設けることができる。これら圧力センサ26および流量センサ27は弁2の一次側の流路に設けられ、弁2の一次側の流体圧力に関する情報は、圧力センサ26、流量センサ27またはこれら両者によって検知され取得される。   As shown in FIG. 4, the valve device 1 can include at least one of a pressure sensor 26 that detects a fluid pressure and a flow sensor 27 that detects a fluid flow rate. The pressure sensor 26 and the flow rate sensor 27 are provided in the flow path on the primary side of the valve 2, and information on the fluid pressure on the primary side of the valve 2 is detected and acquired by the pressure sensor 26, the flow rate sensor 27, or both.

回転制御部20では、取得された情報に基づいてモータ21を回転駆動させ、複数ある内筒側開口13において形成される流体流路33のいずれかに切り替える。モータ21の回転駆動の制御は、制御部22のマイクロコンピュータなどに格納されたプログラムに沿って行われる。例えば、弁2の一次側の流体圧力に関する情報としての水圧が0.4MPa未満の場合には、開口面積が大きい内筒側開口13aが外筒側開口4aに重なる位置に配置されるようにモータ21が回転駆動し、内筒側開口13aを介する流体流路33に切り替えられる。水圧が0.4MPa以上の場合には、開口面積が小さい内筒側開口13bが外筒側開口4aに重なる位置に配置されるようにモータ21が回転駆動し、内筒側開口13bを介する流体流路33に切り替えられる。   In the rotation control unit 20, the motor 21 is driven to rotate based on the acquired information, and is switched to one of the fluid flow paths 33 formed in the plurality of inner cylinder side openings 13. The rotation drive of the motor 21 is controlled according to a program stored in a microcomputer of the control unit 22 or the like. For example, when the water pressure as information on the fluid pressure on the primary side of the valve 2 is less than 0.4 MPa, the motor is arranged such that the inner cylinder side opening 13a having a large opening area is overlapped with the outer cylinder side opening 4a. 21 is rotationally driven and switched to the fluid flow path 33 through the inner cylinder side opening 13a. When the water pressure is 0.4 MPa or more, the motor 21 is rotationally driven so that the inner cylinder side opening 13b having a small opening area is disposed at a position overlapping the outer cylinder side opening 4a, and the fluid passing through the inner cylinder side opening 13b. The flow path 33 is switched.

このような弁装置1は、弁2の一次側の流体圧力の変動が大きい場合でも、圧力センサ26や流量センサ27の検知結果に基づいて自動で最適な流体流路33に切り替えて対応させることができる。このため、ユーザの操作が不要となり、利便性をさらに一層向上させることができる。   Such a valve device 1 can automatically switch to the optimum fluid flow path 33 based on the detection results of the pressure sensor 26 and the flow sensor 27 even when the fluctuation of the fluid pressure on the primary side of the valve 2 is large. Can do. For this reason, a user's operation becomes unnecessary and the convenience can be further improved.

以上、実施形態に基づき本発明を説明したが、本発明は上記の実施形態に何ら限定されるものではなく、その要旨を逸脱しない範囲内において各種の変更が可能である。例えば、図1の例ではコントローラ23が設けられ、図4の例では圧力センサ26および流量センサ27が設けられているが、コントローラとともに、圧力センサおよび流量センサのうち少なくともいずれか一方が設けられていてもよい。このような弁装置では、ユーザの選択により、コントローラによって流体流路を切り替えたり、自動で流体流路を切り替えたりすることができるなどユーザの利便性を向上できる。   While the present invention has been described based on the embodiments, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention. For example, the controller 23 is provided in the example of FIG. 1 and the pressure sensor 26 and the flow sensor 27 are provided in the example of FIG. 4, but at least one of the pressure sensor and the flow sensor is provided together with the controller. May be. In such a valve device, the user's convenience can be improved, for example, the fluid channel can be switched by the controller or the fluid channel can be automatically switched by the user's selection.

1 弁装置
2 弁
3 外筒
4、4a、4b 外筒側開口
10 内筒
11 内部流路
13、13a、13b 内筒側開口
20 回転制御部
23 コントローラ
26 圧力センサ
27 流量センサ
31 外部流路
33 流体流路
DESCRIPTION OF SYMBOLS 1 Valve apparatus 2 Valve 3 Outer cylinder 4, 4a, 4b Outer cylinder side opening 10 Inner cylinder 11 Internal flow path 13, 13a, 13b Inner cylinder side opening 20 Rotation control part 23 Controller 26 Pressure sensor 27 Flow sensor 31 External flow path 33 Fluid flow path

Claims (4)

管路内を流れる水道水の流量を調整する弁装置であって、円筒状の外筒およびこの外筒に内装される円筒状の内筒を有し、前記外筒の側面部には内外に貫通する外筒側開口が形成され、この外筒側開口は外部流路と接続可能であり、前記内筒の内側には水道水が流通する内部流路が形成され側面部には内外に貫通する内筒側開口が周方向に複数形成され、これら内筒側開口はそれぞれ開口面積が異なり、前記内筒の周方向の回転により複数ある前記内筒側開口の一つが前記外筒側開口に重なり前記内部流路と前記外部流路が連通して水道水が流通可能な流体流路が形成され、前記内筒側開口各々において前記流体流路の形成が可能であり、それら流体流路の切り替えが可能とされている弁と、前記内筒を回転させる回転制御部とを備え、
前記回転制御部は、前記弁の一次側の水圧に関する情報に基づいて、一次側の水圧が基準値以上である場合には開口面積の狭い方の内筒側開口において形成される流体流路になるように、前記外筒側開口に重なる前記内筒側開口を切り替え、一次側の水圧が基準値未満である場合には開口面積の広い方の内筒側開口において形成される流体流路になるように、前記外筒側開口に重なる前記内筒側開口を切り替えることにより前記流体流路を切り替えて前記水道水の流通を可能にしていることを特徴とする弁装置。
A valve device for adjusting the flow rate of tap water flowing in a pipe line, which has a cylindrical outer cylinder and a cylindrical inner cylinder installed in the outer cylinder. A penetrating outer cylinder side opening is formed, the outer cylinder side opening can be connected to an external flow path, an internal flow path through which tap water circulates is formed inside the inner cylinder, and a side portion penetrates inside and outside A plurality of inner cylinder side openings are formed in the circumferential direction, the inner cylinder side openings have different opening areas, and one of the plurality of inner cylinder side openings is formed as the outer cylinder side opening by rotation of the inner cylinder in the circumferential direction. Overlapping the internal flow channel and the external flow channel to form a fluid flow channel through which tap water can flow, and the fluid flow channel can be formed in each of the inner cylinder side openings. A valve that can be switched, and a rotation control unit that rotates the inner cylinder,
Based on the information on the primary side water pressure of the valve, the rotation control unit is configured to adjust the fluid flow path formed in the inner cylinder side opening having the smaller opening area when the primary side water pressure is equal to or higher than a reference value. The inner cylinder side opening overlapping the outer cylinder side opening is switched so that when the primary water pressure is less than a reference value, the fluid flow path formed in the inner cylinder side opening with the larger opening area As described above, the valve device is characterized in that the tap water is allowed to flow by switching the fluid flow path by switching the inner cylinder side opening overlapping the outer cylinder side opening .
さらに、前記回転制御部に電気的に接続される、前記弁の一次側の水圧に関する情報に基づいて前記内筒の回転の指示を入力するコントローラを備えており、前記回転制御部は、前記コントローラに入力された指示により前記内筒を回転させて前記流体流路を切り替えることを特徴とする請求項1に記載の弁装置。 The controller further includes a controller that is electrically connected to the rotation control unit and that inputs an instruction to rotate the inner cylinder based on information relating to a water pressure on the primary side of the valve. The rotation control unit includes the controller the valve device according to claim 1, characterized in that switching the pre Symbol fluid flow path by rotating the inner cylinder by the input instruction to. さらに、前記弁の一次側の流路に設けられる、圧力センサおよび流量センサのうち少なくともいずれか一方を備えており、前記弁の一次側の水圧に関する情報が、前記圧力センサ、前記流量センサまたはこれら両者によって検知され、前記回転制御部は、前記検知結果に基づいて前記内筒を回転させて前記流体流路を切り替えることを特徴とする請求項1または2に記載の弁装置。 Further, at least one of a pressure sensor and a flow rate sensor provided in a flow path on the primary side of the valve is provided, and information regarding the water pressure on the primary side of the valve is the pressure sensor, the flow rate sensor, or these It is detected by both the rotary control unit, the detection result valve arrangement according to claim 1 or 2, characterized in that switching the pre Symbol fluid flow path by rotating the inner cylinder on the basis of. 管路内を流れる水道水の流量を調整する弁装置であって、円筒状の外筒およびこの外筒に内装される円筒状の内筒を有し、前記外筒の側面部には内外に貫通する外筒側開口が形成され、この外筒側開口は外部流路と接続可能であり、前記内筒の内側には水道水が流通する内部流路が形成され側面部には内外に貫通する内筒側開口が周方向に複数形成され、これら内筒側開口はそれぞれ開口面積が異なり、前記内筒の周方向の回転により複数ある前記内筒側開口の一つが前記外筒側開口に重なり前記内部流路と前記外部流路が連通して水道水が流通可能な流体流路が形成され、前記内筒側開口各々において前記流体流路の形成が可能であり、それら流体流路の切り替えが可能とされている弁と、前記内筒を回転させる回転制御部と、所定の流体流路に切り替えるために複数ある前記内筒側開口の一つが前記外筒側開口に重なるように前記内筒の回転の指示を入力する複数のボタンとを備え、A valve device for adjusting the flow rate of tap water flowing in a pipe line, which has a cylindrical outer cylinder and a cylindrical inner cylinder installed in the outer cylinder. A penetrating outer cylinder side opening is formed, the outer cylinder side opening can be connected to an external flow path, an internal flow path through which tap water circulates is formed inside the inner cylinder, and a side portion penetrates inside and outside A plurality of inner cylinder side openings are formed in the circumferential direction, the inner cylinder side openings have different opening areas, and one of the plurality of inner cylinder side openings is formed as the outer cylinder side opening by rotation of the inner cylinder in the circumferential direction. Overlapping the internal flow channel and the external flow channel to form a fluid flow channel through which tap water can flow, and the fluid flow channel can be formed in each of the inner cylinder side openings. A valve that can be switched, a rotation control unit that rotates the inner cylinder, and a predetermined fluid And a plurality of buttons one of a plurality of the inner cylinder side opening to input instructions of rotation of the inner tube so as to overlap the outer tube side opening to switch to road,
前記複数のボタンは、開口面積の狭い方の内筒側開口が前記外筒側開口に重なるように前記内筒の回転を指示する第1のボタンと、開口面積の広い方の内筒側開口が前記外筒側開口に重なるように前記内筒の回転を指示する第2のボタンとを有し、前記弁の一次側の水圧が基準値以上である場合には第1のボタンが選択されて前記内筒の回転の指示が入力され、一次側の水圧が基準値未満である場合には第2のボタンが選択されて前記内筒の回転の指示が入力され、The plurality of buttons include a first button for instructing rotation of the inner cylinder so that an inner cylinder side opening having a smaller opening area overlaps the outer cylinder side opening, and an inner cylinder side opening having a larger opening area. And a second button for instructing rotation of the inner cylinder so as to overlap the opening on the outer cylinder side, and the first button is selected when the water pressure on the primary side of the valve is equal to or higher than a reference value. An instruction to rotate the inner cylinder is input, and when the water pressure on the primary side is less than a reference value, the second button is selected and an instruction to rotate the inner cylinder is input,
前記回転制御部は、前記弁の一次側の水圧に関する情報に基づいて前記複数のボタンから選択されたボタンの前記内筒の回転の指示によって、前記指示に対応する流体流路に切り替えて前記水道水の流通を可能にしていることを特徴とする弁装置。The rotation control unit switches to the fluid flow path corresponding to the instruction in accordance with an instruction to rotate the inner cylinder of the button selected from the plurality of buttons based on information on the water pressure on the primary side of the valve. A valve device characterized by enabling water flow.
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JP2001065725A (en) * 1999-08-25 2001-03-16 Saginomiya Seisakusho Inc Valve opening maintenance control method and valve opening control device for electric control valve
JP2002099330A (en) * 2000-09-22 2002-04-05 Aera Japan Ltd Flow controller
JP2003042312A (en) * 2001-08-01 2003-02-13 Kurimoto Ltd Rotary flow control valve
JP4460820B2 (en) * 2002-10-29 2010-05-12 アドバンス電気工業株式会社 Fluid flow control method using constant pressure flow control valve
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JP4792496B2 (en) * 2008-12-25 2011-10-12 株式会社ティクスホールディングス Flow control valve
JP2011226554A (en) * 2010-04-20 2011-11-10 Panasonic Corp Electric valve device and water heater using the same
JP5104897B2 (en) * 2010-04-22 2012-12-19 パナソニック株式会社 Flow rate adjusting valve and water heater provided with the same

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