JPH0390720A - Cleaning water supply device - Google Patents

Abstract

PURPOSE:To enable reliable washing of a toilet bowl by providing a control device which controls a valve mechanism based on a pressure detected by a pressure detecting means during the feed of washing water to a water feed port. CONSTITUTION:In an MPU 16b, a valve 18 for a rim is opened by means of a starting input to a control part 17, and a timer 16d is started. A feed water pressure detected by a pressure sensor 20 is stored in a memory 16c, an instantaneous flow rate of washing water is calculated, and a time required for an amount of feed water for prewashing a bowl part is calculated. When a timer 16d comes to a water feed time for creation of a siphon action, a valve 19 for jet is opened, and a timer 16e is started. When the timer comes to a bowl part water feed time, the valve 18 is closed. Further, based on data stored in the memory 16c, a time in which a given amount of water is fed to a jet part is calculated, and when a timer 16e comes to a time, the valve 19 is closed.

Description

Translated fromJapanese

【発明の詳細な説明】（ａ業上の利用分野）本発明は便器へ洗浄水を供給する装置に関する。[Detailed description of the invention](Field of use in business a)The present invention relates to an apparatus for supplying flush water to a toilet bowl.

（従来の技術）トラップ排水路へ洗浄水を供給してトラップ排水路にサ
イホン作用を発生させボウル部の汚物・汚水を排出させ
た後、ボウル部へ給水してボウル部の洗浄ならびに封水
を行なうようにした洗浄給水装置は特公昭５５−３００
９２号公報で知られている。この装置は、ボウル部用お
よびトラップ用の二つの電磁弁を備え各電磁弁を予め設
定した時間だけ開弁するよう構成されている。(Prior art) Cleaning water is supplied to the trap drainage channel to generate a siphon effect in the trap drainage channel to discharge dirt and waste water from the bowl, and then water is supplied to the bowl to clean and seal the bowl. The cleaning water supply system designed to carry out this process was developed in
It is known from Publication No. 92. This device includes two solenoid valves, one for the bowl and one for the trap, and is configured to open each solenoid valve for a preset time.

（発明が解決しようとする課題〉このように従来の洗浄給水装置は、予め設定された時間
だけ電磁弁を開弁させる構成であるから、給水管の給水
圧が異なれば便器の各部へ供給される洗浄水量が変動す
る。給水圧が高いと過剰な給水となり節水の観点から好
ましくなく、給水圧が低いと給水量が不足して汚物の排
出やボウル部の洗浄が不十分となる場合がある。(Problems to be Solved by the Invention) As described above, the conventional flushing water supply device is configured to open the solenoid valve only for a preset time, so if the water supply pressure of the water supply pipe differs, the water supply to each part of the toilet bowl will be affected. The amount of water used for washing fluctuates. If the water supply pressure is high, excessive water will be supplied, which is undesirable from a water conservation perspective. If the water supply pressure is low, the amount of water supplied may be insufficient, resulting in insufficient drainage of waste and insufficient cleaning of the bowl. .

まｋ、給水圧が低い場合は、大気圧の変動により給水量
が異なる。例えば、給水圧が絶対圧で１．４ｋｇ／ａｍ
２ａｂｓ、　（ゲージ圧で０．４ｋｇ／ｃｍ２Ｇ）とし
て、気象の変化で大気圧が１．０±０．０５ｋｇ／ｃｍ
２ａｂｓ。Also, if the water supply pressure is low, the amount of water supplied will vary due to fluctuations in atmospheric pressure. For example, the water supply pressure is 1.4 kg/am in absolute pressure.
2abs, (0.4kg/cm2G in gauge pressure), atmospheric pressure becomes 1.0±0.05kg/cm due to weather changes.
2 abs.

程度変化する場合を想定すると、流量は給水圧と大気圧
の差の平方根に比例するから、低気圧の時と高気圧の時
では大気圧１．０ｋｇの時の流量に対して約±６％変動
する。Assuming a case where the degree changes, the flow rate is proportional to the square root of the difference between the water supply pressure and atmospheric pressure, so between low pressure and high pressure, the flow rate will fluctuate by about ±6% compared to the flow rate when atmospheric pressure is 1.0 kg. do.

本発明はこのような課題を解決するためなされたもので
、その目的は給水圧力にかかわらず所定の水量が供給で
きる洗浄給水装置を提供するにある。さらに、大気圧の
変動に対しても給水量の影響を受けない装置を提供する
ものである。The present invention has been made to solve these problems, and its purpose is to provide a cleaning water supply device that can supply a predetermined amount of water regardless of the water supply pressure. Furthermore, the present invention provides an apparatus in which the amount of water supplied is not affected by changes in atmospheric pressure.

（課題を解決するための手段）前記課題を解決するため請求項１に係る洗浄給水装置は
、大気開放端へ給水する管路へ給水を制御する弁機構の
下流側に圧力センサを設け、制御装置はこの圧力検出手
段により検出した給水圧力に基づいて弁機構を制御する
よう構成したことを特徴とする請求項２に係る装置は、弁機構が閉状態のときに前記圧
力検出手段により大気圧を検出してこれを記憶し、開弁
時の給水圧との差圧を求めて、所定の給水量が供給され
るよう各弁機構の弁機構を制御する構成としたことを特
徴とする。(Means for Solving the Problems) In order to solve the above problems, the cleaning water supply device according to claim 1 is provided with a pressure sensor provided on the downstream side of a valve mechanism that controls water supply to a pipe line that supplies water to an end open to the atmosphere. The apparatus according to claim 2 is characterized in that the apparatus is configured to control the valve mechanism based on the water supply pressure detected by the pressure detection means, when the valve mechanism is in a closed state, the pressure detection means detects atmospheric pressure. The valve mechanism is characterized in that the valve mechanism of each valve mechanism is controlled so that a predetermined amount of water is supplied by detecting and storing the detected value, and determining the differential pressure between the water supply pressure and the water supply pressure when the valve is opened.

（作　用）請求項１に係る発明において、制御装置は弁機構を開状
態に駆動して洗浄水を供給した後、弁機構の吐水側に設
けた圧力検出手段により給水圧を検出する。制御装置は
、検出した給水圧に対応して弁機構の開弁時間・開度等
を制御し、便器の各々の給水口へ所定量の洗浄水を特徴
する請求項２に係る発明にあっては、制御装置は閉弁時
に検出した大気圧値を記憶し、開弁時の給水圧との差圧
を求めて、所定の給水量が供給させるよう弁機構を制御
する。(Function) In the invention according to claim 1, after the control device drives the valve mechanism into an open state to supply cleaning water, the water supply pressure is detected by the pressure detection means provided on the water discharge side of the valve mechanism. In the invention according to claim 2, the control device controls the opening time, opening degree, etc. of the valve mechanism in response to the detected water supply pressure, and supplies a predetermined amount of flushing water to each water supply port of the toilet bowl. In this case, the control device stores the atmospheric pressure value detected when the valve is closed, determines the pressure difference between the atmospheric pressure value and the water supply pressure when the valve is open, and controls the valve mechanism so that a predetermined amount of water is supplied.

（実施例）以下、本発明の実施例を添付図面に基づいて説明する。(Example)Embodiments of the present invention will be described below with reference to the accompanying drawings.

第１図は請求項１に係る洗浄給水装置を備えた便器の縦
断面である。FIG. 1 is a longitudinal section of a toilet bowl equipped with a cleaning water supply device according to a first aspect of the present invention.

図において便器１は隔壁２で区画されたボウル部３とト
ラップ排水路４を有する。トラップ排水路４は、ボウル
部３の後壁下部に開設した流入口５と、便器１の略中央
部底面に開設した流出口６とを略逆Ｕ字状に屈曲して連
結しており、トラップ排水路４の項部４ａより下流側の
排出路４ｂを略直管形状に形成している。そして、その
下端部である流出口６近傍に管壁を内方へ縮径した絞り
部４ｃを設けるとともに、排出路４ｂの管壁に複数の突
起４ｄを第２図に示すように所定間隔で螺旋状に配設し
ている。In the figure, a toilet bowl 1 has a bowl portion 3 separated by a partition wall 2 and a trap drainage channel 4. The trap drainage channel 4 connects an inlet 5 opened at the lower part of the rear wall of the bowl part 3 and an outlet 6 opened at the bottom of the approximately central part of the toilet bowl 1 by bending it into an approximately inverted U shape. A discharge passage 4b on the downstream side of the neck portion 4a of the trap drainage passage 4 is formed into a substantially straight pipe shape. A constricted part 4c is provided near the outlet 6 at the lower end of the pipe wall, and a plurality of protrusions 4d are provided on the pipe wall of the discharge passage 4b at predetermined intervals as shown in FIG. They are arranged in a spiral.

ボウル部３の上端周縁のリム部７には、リム通水路８を
ボウル部３の内方へ突出するように環状に形成し、この
リム通水路８の底面にリム射水孔９を適宜間隔毎にボウ
ル部３に対して斜めに開設する。また、リム通水路８は
後部においてリム給水室１０に連通しており、このリム
給水室１ｏの上面にはリム給水口１１を穿設している。A rim water passageway 8 is formed in the rim part 7 at the upper edge of the bowl part 3 in an annular shape so as to protrude inward of the bowl part 3, and rim water injection holes 9 are formed at appropriate intervals on the bottom surface of the rim water passageway 8. It is opened diagonally with respect to the bowl part 3. Further, the rim water passage 8 communicates with a rim water supply chamber 10 at the rear, and a rim water supply port 11 is bored in the upper surface of the rim water supply chamber 1o.

ボウル部３の底部にジェット用ノズル１２をジェット噴
射孔１３がトラップ排水路４の流入口５を指向するよう
取着している。A jet nozzle 12 is attached to the bottom of the bowl part 3 so that the jet injection hole 13 is directed toward the inlet 5 of the trap drainage channel 4.

便器１の後部上方にボックス１４を設け、このボックス
１４内社洗浄給水装置１５を収納している。洗浄給水装
置１５は、制御装置１６と、この制御装置１６に洗浄起
動入力を与える操作部１７と、リム用およびジェット用
の弁機構１８．１９と、リム用弁機構１８の下流側の管
路に取着された圧力検出手段である圧力センサ２０およ
び大気開放弁２１とから構成される。リム用弁機構１８
の一端は給水管２２へ接続され、他端はリム給水室１０
のリム給水口１１へ接続しており、この接続管路に圧力
センサ２０を備えている。ジェット用弁機構１９の一端
は給水管２２へ接続され、他端は大気開放弁２１および
ジェット用給水管２３を介してジェット用ノズル１２の
ジェット給水口２４へ接続している。ジェット用給水管
２３は金属・合成樹脂あるいは合成ゴム製の管路で形成
され、給水管路長が短くなるようボウル部３の底部に沿
って配設している。A box 14 is provided above the rear part of the toilet bowl 1, and this box 14 houses an in-house cleaning water supply device 15. The cleaning water supply device 15 includes a control device 16, an operation unit 17 that provides a cleaning start input to the control device 16, valve mechanisms 18 and 19 for rims and jets, and a conduit downstream of the valve mechanism 18 for rims. It consists of a pressure sensor 20, which is a pressure detection means attached to the air pressure sensor 20, and an atmosphere release valve 21. Rim valve mechanism 18
One end is connected to the water supply pipe 22, and the other end is connected to the rim water supply chamber 10.
The rim water supply port 11 is connected to the rim water supply port 11, and a pressure sensor 20 is provided in this connecting conduit. One end of the jet valve mechanism 19 is connected to a water supply pipe 22, and the other end is connected to a jet water supply port 24 of the jet nozzle 12 via an atmosphere release valve 21 and a jet water supply pipe 23. The jet water supply pipe 23 is formed of a pipe made of metal, synthetic resin, or synthetic rubber, and is arranged along the bottom of the bowl portion 3 so that the length of the water supply pipe is short.

次に第３図のブロック構成図を参照に洗浄給水装置の構
成を説明する。Next, the configuration of the cleaning water supply device will be explained with reference to the block diagram shown in FIG.

制御装置１６は、入力インタフェース回路１６８１マイ
クロプロセツサ（以下ＭＰＵと記す）１６ｂ、メモリ１
６Ｃ１第１および第２のタイマｌｅｄ、ｆｅｅ、出力イ
ンタフェース回路１６ｆから構成される。入力インタフ
ェース回路ｔｅａには操作部１７および圧力センサ２０
が接続され、出力インタフェース回路１５ｆにはリム・
ジェット用の各弁機構１８．１９が接続される。The control device 16 includes an input interface circuit 1681, a microprocessor (hereinafter referred to as MPU) 16b, and a memory 1.
6C1 consists of first and second timer LEDs, fees, and an output interface circuit 16f. The input interface circuit tea includes an operating section 17 and a pressure sensor 20.
is connected to the output interface circuit 15f.
Each valve mechanism 18,19 for the jet is connected.

操作部１７は、便器１の洗浄を開始させるためのスイッ
チを備えており、このスイッチの開閉は起動信号線１７
ａにより制御装置１６に入力される。The operation unit 17 includes a switch for starting flushing of the toilet bowl 1, and opening/closing of this switch is controlled by a start signal line 17.
a is input to the control device 16.

なお、操作部１７には、洗浄水の供給量を選択できるよ
う複数の操作ボタンを設けてもよい。また、着座を検出
するスイッチあるいはセンサ等を設け、これらの信号を
制御装置に入力して、着座状態のみ操作部１７の操作を
有効としたり、あるいは、着座状態から未着座状態とな
ったのち所定時間後に自動的に洗浄を開始させる構成で
あってもよい。Note that the operation unit 17 may be provided with a plurality of operation buttons so that the supply amount of cleaning water can be selected. In addition, a switch or a sensor for detecting seating may be provided, and these signals may be input to the control device to enable the operation of the operating section 17 only when the user is seated, or to enable a predetermined operation after the seat is changed from the seated state to the non-seated state. It may be configured to automatically start cleaning after a certain period of time.

圧力センサ２０は、半導体または圧電セラミックス形の
圧力センせを用いる。圧力センサ２０の出力信号を圧力
信号Ｍｉ２０　ａを介して入力インタフェース２２ａ内
のＡ−Ｄ変換器に入力して、給水圧力に対応したディジ
タル信号に変換する。The pressure sensor 20 uses a semiconductor or piezoelectric ceramic type pressure sensor. The output signal of the pressure sensor 20 is input to the A-D converter in the input interface 22a via the pressure signal Mi20a and converted into a digital signal corresponding to the water supply pressure.

リム用、ジェット用の各弁機構１８．１９は電磁弁で構
成し、この電磁弁は所定の電圧を印加した時に開弁状態
となるものを用いる。１８ａ。Each of the valve mechanisms 18 and 19 for the rim and the jet is constituted by a solenoid valve, which opens when a predetermined voltage is applied. 18a.

１９ａは各弁機構１８．１９を夫々駆動するための信号
線である。19a is a signal line for driving each valve mechanism 18, 19, respectively.

メモリ１６ｃには、洗浄水の給水順序および給水量に関
するデータが予め記憶されている。The memory 16c stores in advance data regarding the order in which cleaning water is supplied and the amount of water supplied.

次に第４図のタイムチャートおよび第５図のフローチャ
ートを参照に本実施例の動作を説明する。なお、第５図
で３１〜３２０はフローチャートの各ステップを示す。Next, the operation of this embodiment will be explained with reference to the time chart of FIG. 4 and the flow chart of FIG. 5. In addition, in FIG. 5, 31 to 320 indicate each step of the flowchart.

また、説明の都合上、各弁機構１８．１９をリム用弁、
ジェット用弁と記す。Also, for convenience of explanation, each valve mechanism 18.19 is a rim valve,
It is called a jet valve.

第４図はリム射水孔９からボウル部３への給水とジェッ
ト噴射孔１３からトラップ排水路４への給水タイよング
の一例を示したもので、この実施例では前洗浄給水が終
了する前に、サイホン作用を発生させるための給水を行
うようにしている。FIG. 4 shows an example of the timing of water supply from the rim water injection hole 9 to the bowl part 3 and from the jet injection hole 13 to the trap drainage channel 4. In this embodiment, before the pre-cleaning water supply ends, In addition, water is supplied to generate a siphon effect.

操作部１７より洗浄起動人力が与えられると、ＭＰＵ１
６ｂはまずリム用弁１８を開状態に駆動するとともに（
ｓ　ｉ　）　、第１のタイマ１６ｄを起動する（Ｓ２）
。次にＭＰＵ１６ｂは入力インタフェース回路１６ａ内
のＡ−Ｄ変換器を起動させて、圧力センサ２０が検出し
ている給水圧に対応するディジタル量を読み込み、この
値をメモリ１６ｃに記憶させるとともに、この値から洗
浄水の瞬間流量を算出または換算する（Ｓ３）。そして
ＭＰＵ１６ｂは、メモリ１６ｃ内に記憶されているボウ
ル部前洗浄給水量データを読み出し、この給水量を供給
するのに必要な時間（ｔｌ）を算出する（Ｓ４）。When human power to start cleaning is given from the operation unit 17, the MPU 1
6b first drives the rim valve 18 to the open state (
s i ), start the first timer 16d (S2)
. Next, the MPU 16b activates the A-D converter in the input interface circuit 16a, reads the digital amount corresponding to the water supply pressure detected by the pressure sensor 20, stores this value in the memory 16c, and also stores this value in the memory 16c. The instantaneous flow rate of cleaning water is calculated or converted from (S3). Then, the MPU 16b reads the bowl pre-cleaning water supply amount data stored in the memory 16c, and calculates the time (tl) required to supply this water supply amount (S4).

まに１メモリ２２ｃ内にはボウル部３への給水量が何℃
になった時点でサイホン作用を発生させるための給水を
開始するかのデータが記憶されており、ＭＰＵ１６ｂは
この給水量が供給されるのに必要な時間（ｔ２）を算出
する（Ｓ５）。The amount of water supplied to the bowl part 3 is stored in the memory 22c.
Data on whether to start water supply to generate a siphon effect at the point in time is stored, and the MPU 16b calculates the time (t2) required for this water supply amount to be supplied (S5).

そして、ＭＰＵ１８ｂはタイマ１６ｄの経過時間を監視
して、時間ｔ２に達した時点で（Ｓ６）、ジェット用弁
１９を開状態に駆動するとともに（Ｓ７）、第２のタイ
マ１６ｅを起動しくＳａ）、次にボウル部給水時間（ｔ
ｌ）に達した時点で（Ｓ　９）　、リム用弁を閉状態に
駆動する（ＳＩＯ）。次に、ＭＰＵ１６ｂはメモリ１６
ｃに記憶された給水圧のデータを基にジェット部へ所定
の給水量を供給するのに必要な時間（ｔ３）を算出する
（Ｓｌｌ）。そして、第２のタイマｊ６ｅが時間ｔ３に
達した時点で（Ｓ　１２）、ＭＰＵ１６ｂはジェット用
弁１９を閉状態に駆動する（３１３）。Then, the MPU 18b monitors the elapsed time of the timer 16d, and when it reaches time t2 (S6), drives the jet valve 19 to an open state (S7), and starts the second timer 16e (Sa). , then the bowl water supply time (t
At the time point l) is reached (S9), the rim valve is driven to the closed state (SIO). Next, the MPU 16b
The time (t3) required to supply a predetermined amount of water to the jet section is calculated based on the water supply pressure data stored in c (Sll). Then, when the second timer j6e reaches time t3 (S12), the MPU 16b drives the jet valve 19 to the closed state (313).

ここまでのステップで、便器１のボウル部３の壁面の前
洗浄およびサイホン作用を発生させるための給水が完了
する。なお、ジェット用ノズル１２のジェット用噴射孔
１３からトラップ排水路４内に噴射された洗浄水は、項
部４ａを越えて排出路４ｂへ流入し、排出路４ｂに形成
した突起４ｄに衝突し、流れの向きを変えながら排出路
４ｂの管内全体に亘って時的−に流れ落ちる。この洗浄
水により流出口６の近傍に設けた絞り部４Ｃに水シール
が発生するとともに、トラップ排水路４内の空気は洗浄
水とともに流出口６から図示しない排水管へ排出される
。このため、トラップ排水路４内に負圧が発生し、ボウ
ル部３内の溜水２５がトラップ排水路４内に呼び込まれ
て、トラップ排水路４内は洗浄水で充満された完全なサ
イホン状態となる。このサイホン状態はジェット用弁１
９を閉状態にした後も、ボウル部３内の溜水２６の水位
が低下して隔壁２の下端２ａからトラップ排水路４内へ
空気が流入するまで継続され、この間にボウル部３内の
汚物・汚水等の排出がなされる。With the steps up to this point, the pre-cleaning of the wall surface of the bowl portion 3 of the toilet bowl 1 and the water supply for generating the siphon action are completed. Note that the cleaning water injected into the trap drainage channel 4 from the jet injection hole 13 of the jet nozzle 12 flows into the discharge channel 4b over the neck portion 4a, and collides with the protrusion 4d formed in the discharge channel 4b. , while changing the direction of the flow, it flows down throughout the pipe of the discharge path 4b. This cleaning water causes a water seal to occur in the constriction portion 4C provided near the outlet 6, and the air in the trap drainage channel 4 is discharged together with the cleaning water from the outlet 6 to a drain pipe (not shown). Therefore, a negative pressure is generated in the trap drain 4, and the accumulated water 25 in the bowl part 3 is drawn into the trap drain 4, and the trap drain 4 becomes a complete siphon filled with washing water. state. This siphon state is the jet valve 1
9 is closed, this continues until the water level of the pooled water 26 in the bowl part 3 decreases and air flows into the trap drainage channel 4 from the lower end 2a of the partition wall 2. During this period, the water level in the bowl part 3 Filth, sewage, etc. are discharged.

メモリ１６ｃ内には、このサイホン作用継続時間のデー
タが予め記憶されている。ＭＰＵ１６ｂは、ステップＳ
１３でジェット用弁を閉にした後、直ちに第１または第
２タイマ１６ｄ、１６ｅを起動しく３１４）、サイホン
作用継続時間が経過した時点で（Ｓ１５）、再度リム用
弁１８を開状態に駆動しく５１６）、再度第１または第
２タイマｌａｄ、１６ｅを起動する（Ｓ１７）、そして
、メモリ１６ｃに記憶した給水圧に係るデータを基に、
メモリ１６ｃ内に予め記憶されているボウル部への封水
給水量を供給するの定要する時間を算出しく３１８）、
この封水給水時間が経過した時点で（Ｓ１９）、リム用
弁１８を閉状態に駆動する（３２０）。Data regarding the duration of this siphon action is stored in advance in the memory 16c. The MPU 16b performs step S
After closing the jet valve in step 13, the first or second timer 16d or 16e is started immediately (314), and when the siphon action duration time has elapsed (S15), the rim valve 18 is driven to the open state again. 516), starts the first or second timer lad, 16e again (S17), and based on the data related to the water supply pressure stored in the memory 16c,
Calculate the time required to supply the sealed water supply amount to the bowl portion that is stored in advance in the memory 16c (318);
When this water seal water supply time has elapsed (S19), the rim valve 18 is driven to the closed state (320).

以上で、第４図に示す一連の洗浄動作が終了する。With this, the series of cleaning operations shown in FIG. 4 is completed.

なお、本実施例では、サイホン作用を発生させるための
洗浄水供給を、ボウル部３の底部に設けたジェット用ノ
ズル１２から行っているが、第６図に示すようにトラッ
プ排水路４の略頂部に散水部２６を設け、トラップ排水
路４の項部４ａより下流側へ洗浄水をシャワー状に供給
する構造でもよい。In this embodiment, the cleaning water for generating the siphon effect is supplied from the jet nozzle 12 provided at the bottom of the bowl portion 3, but as shown in FIG. A water sprinkling section 26 may be provided at the top to supply washing water in a shower form to the downstream side of the trap drainage channel 4 from the neck section 4a.

また、洗浄給水装置１５を便器１に内蔵させずにトイレ
の壁等に取り付ける構造でもよい。Alternatively, the cleaning water supply device 15 may not be built into the toilet bowl 1, but may be attached to a wall of the toilet or the like.

次に請求項２に係る洗浄給水装置の動作を第７図のフロ
ーチャートを参照に説明する。Next, the operation of the cleaning water supply device according to the second aspect will be explained with reference to the flowchart shown in FIG.

操作部より洗浄起動入力が与えられると、ＭＰＵ１６ｂ
は入力インタフェース回路１６ａ内のＡ−Ｄ変換器を起
動して、圧力センサ２ｏの検出圧力値を読み込み、ＭＰ
Ｕ１６ｂ内のレジスタあるいはメモリ１６ｃに記憶させ
る（ＳＯ）。この状態では各弁機構１８．１９は閉弁状
態である。リム用弁機構１８の下流側はリム射水孔９を
介して大気と連通されている。したがって、圧力センサ
２０は大気圧を検出しており、ＭＰＵ１６ｂは大気圧に
対応するディジタル量を読み込み記憶したことになる。When a cleaning start input is given from the operation unit, the MPU 16b
starts the A-D converter in the input interface circuit 16a, reads the pressure value detected by the pressure sensor 2o, and reads the pressure value detected by the pressure sensor 2o.
It is stored in a register in U16b or in memory 16c (SO). In this state, each valve mechanism 18, 19 is in a closed state. The downstream side of the rim valve mechanism 18 is communicated with the atmosphere via the rim water injection hole 9. Therefore, the pressure sensor 20 has detected the atmospheric pressure, and the MPU 16b has read and stored the digital quantity corresponding to the atmospheric pressure.

以下、ステップ３１〜Ｓ２０までの流れは基本的に第５
図と同じであるが、ステップｓ３における瞬間流量の算
出は大気圧の変動を補正して正確な瞬間流量を求めるよ
うにしている。すなわち、第５図に示したフローチャー
トでは、大気圧が例えば１．０ｋｇ／ｃｍ２ａｂｓ、と
一定であるとの条件のもとに、各圧力センサ２０．２１
で検出した給水圧にのみ基づいて瞬間流量を求めている
が、本実施例では止水状態で大気圧を検出し、給水圧と
大気圧との差圧（真のゲージ圧）に基づいて瞬間流量を
求めるようにしている。Below, the flow from step 31 to S20 is basically the fifth step.
Although it is the same as the figure, the calculation of the instantaneous flow rate in step s3 corrects fluctuations in atmospheric pressure to obtain an accurate instantaneous flow rate. That is, in the flowchart shown in FIG. 5, each pressure sensor 20.21 is
The instantaneous flow rate is calculated based only on the water supply pressure detected by the system, but in this example, the atmospheric pressure is detected when the water is stopped, and the instantaneous flow rate is calculated based on the differential pressure (true gauge pressure) between the water supply pressure and the atmospheric pressure. I am trying to find the flow rate.

したがって、給水管２２の給水圧力が低い場合は、低気
圧、高気圧等による大気圧の変動により流量が影響され
るが、補正を行うことで正確な流量を求めることができ
る。よって、給水圧力の変動のみならず、大気圧の変動
に対しても便器１へ供給される流量が変動することはな
く、所定の流量で確実な洗浄が行える。Therefore, when the water supply pressure of the water supply pipe 22 is low, the flow rate is affected by atmospheric pressure fluctuations due to low pressure, high pressure, etc., but an accurate flow rate can be obtained by performing correction. Therefore, the flow rate supplied to the toilet bowl 1 does not fluctuate not only due to fluctuations in water supply pressure but also to fluctuations in atmospheric pressure, and reliable flushing can be performed at a predetermined flow rate.

なお、本実施例は最初に給水する側の管路に圧力センサ
２０が設けられているが、大気開放端に連なる管路への
給水が最初ではない給水順序の場合は、前回の給水時に
検出した給水圧の記憶データに基づいて給水時間を仮に
算出して給水量の制御を行い、圧力センサ２０が設けら
れている管路に給水した時に、真の給水圧力を検出して
、これ以降の給水時間を再算出するようにすればよい。In this embodiment, the pressure sensor 20 is installed in the pipe that supplies water first, but if the water supply order is not first to supply water to the pipe connected to the end open to the atmosphere, the pressure sensor 20 will be detected at the time of the previous water supply. The water supply amount is controlled by temporarily calculating the water supply time based on the stored water supply pressure data, and when water is supplied to the pipe where the pressure sensor 20 is installed, the true water supply pressure is detected and the subsequent All you have to do is recalculate the water supply time.

また、洗浄給水装置１５を、便器１に内蔵せずに、トイ
レの壁面等に取り付ける構成としてもよい。Furthermore, the cleaning water supply device 15 may be configured to be attached to the wall of the toilet, etc., instead of being built into the toilet bowl 1.

また、本実施例では二つの開閉弁を並設する構成とした
が、一つの開閉弁の下流側に方向切替弁を配置する構成
としてもよい。また、開閉弁でなく、流量調節弁を用い
、開度を調節するようにしてもよい。Further, in this embodiment, two on-off valves are arranged in parallel, but a direction switching valve may be arranged downstream of one on-off valve. Further, instead of an on-off valve, a flow rate control valve may be used to adjust the opening degree.

（発明の効果）以上説明したように本発明に係る洗浄給水装置は、大気
開放端への給水を制御する弁機構の下流側に圧力センサ
を備え、開弁時の給水圧に基づいて開弁時間を制御する
ので、給水圧力の高低にかかわらず所定量の洗浄水が供
給でき、便器の洗浄を確実に行わせることができる。(Effects of the Invention) As explained above, the cleaning water supply device according to the present invention includes a pressure sensor on the downstream side of the valve mechanism that controls water supply to the end open to the atmosphere, and opens the valve based on the water supply pressure when the valve is opened. Since the time is controlled, a predetermined amount of flushing water can be supplied regardless of the level of water supply pressure, and the toilet bowl can be flushed reliably.

さらに、閉弁時にはこの圧力センサにより大気圧を検出
し、給水時の圧力との差圧に基づいて開弁時間の制御を
行なう構成とすることにより、大気圧の影響を除去し低
気圧・高気圧の条件でも所定量の給水が可能となる。Furthermore, when the valve is closed, this pressure sensor detects the atmospheric pressure, and the valve opening time is controlled based on the pressure difference between the water supply pressure and the water supply pressure, thereby eliminating the influence of atmospheric pressure. A predetermined amount of water can be supplied even under these conditions.

【図面の簡単な説明】[Brief explanation of drawings]

第１図は本発明に係る洗浄給水装置を備えたサイホン式
の便器の縦断面図、第２図は第１図のＴＩ　−ＩＩ線断
面図、第３図は洗浄給水装置のブロック構成図、第４図
は洗浄給水パターンの一例を示すタイムチャート、第５
図は洗浄給水装置の動作を示すフローチャート、第６図
はトラップ排水路へサイホン作用を発生させるための給
水部の他の実施例を示す要部断面図、第７図は請求項２
に係る洗浄給水装置の動作を示すフローチャートである
。なお、図面中、１は便器、３はボウル部、４はトラップ
排水路、９はリム射水孔、１１はリム給水口、１３はジ
ェット用噴射孔、１５は洗浄給水装置、１６は制御装置
、１８はリム用弁機構、１９はジェット用弁機構、２０
は圧力検出手段である圧力センサ、２２は給水管、２４
はジェット給水口、２６はサイホン作用を発生させるた
めの散水部である。特許FIG. 1 is a longitudinal sectional view of a siphon-type toilet equipped with a cleaning water supply device according to the present invention, FIG. 2 is a sectional view taken along the line TI-II in FIG. 1, and FIG. 3 is a block diagram of the cleaning water supply device. Figure 4 is a time chart showing an example of the cleaning water supply pattern;
Figure 6 is a flowchart showing the operation of the cleaning water supply device, Figure 6 is a sectional view of main parts showing another embodiment of the water supply unit for generating siphon action to the trap drainage channel, and Figure 7 is claim 2.
3 is a flowchart showing the operation of the cleaning water supply device according to the present invention. In addition, in the drawing, 1 is a toilet bowl, 3 is a bowl part, 4 is a trap drainage channel, 9 is a rim water injection hole, 11 is a rim water supply port, 13 is a jet injection hole, 15 is a cleaning water supply device, 16 is a control device, 18 is a rim valve mechanism, 19 is a jet valve mechanism, 20
2 is a pressure sensor which is a pressure detection means; 22 is a water supply pipe; 24 is a pressure sensor;
26 is a jet water supply port, and 26 is a water sprinkling unit for generating a siphon effect. patent

Claims (2)

Translated fromJapanese

【特許請求の範囲】[Claims]（１）便器の複数の給水口に洗浄水を供給する装置にお
いて、この装置は電気的に作動する複数の弁機構と、こ
れらの弁機構の吐水側に接続された管路の中でその吐出
端が大気開放である管路に設けられた圧力検出手段と、
給水時にこの圧力検出手段により検出された圧力に基づ
いて各弁機構を制御する制御装置を備えたことを特徴と
する洗浄給水装置。(1) In a device that supplies flush water to multiple water inlets of a toilet bowl, this device consists of multiple electrically operated valve mechanisms and a pipe connected to the water outlet side of these valve mechanisms. pressure detection means provided in a conduit whose end is open to the atmosphere;
A cleaning water supply device characterized by comprising a control device that controls each valve mechanism based on the pressure detected by the pressure detection means during water supply.（２）前記制御装置は圧力検出手段が設けられた管路の
弁機構が閉状態のときに検出した圧力を記憶するととも
に、給水状態に検出した圧力と記憶した圧力の差に基づ
いて予め設定された所定水量が供給されるよう弁機構を
制御することを特徴とする請求項１記載の洗浄給水装置
。(2) The control device stores the pressure detected when the valve mechanism of the pipeline provided with the pressure detection means is in the closed state, and also sets the pressure in advance based on the difference between the pressure detected in the water supply state and the stored pressure. 2. The cleaning water supply device according to claim 1, wherein the valve mechanism is controlled so that a predetermined amount of water is supplied.