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JPH08233121A - Faucet valve - Google Patents

Faucet valve

Info

Publication number
JPH08233121A
JPH08233121A JP4102595A JP4102595A JPH08233121A JP H08233121 A JPH08233121 A JP H08233121A JP 4102595 A JP4102595 A JP 4102595A JP 4102595 A JP4102595 A JP 4102595A JP H08233121 A JPH08233121 A JP H08233121A
Authority
JP
Japan
Prior art keywords
valve body
sliding
hard carbon
surface roughness
sliding contact
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP4102595A
Other languages
Japanese (ja)
Inventor
Michihiko Koshida
充彦 越田
Jun Mihara
順 三原
Koichi Nagasaki
浩一 長崎
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Kyocera Corp
Original Assignee
Kyocera Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Kyocera Corp filed Critical Kyocera Corp
Priority to JP4102595A priority Critical patent/JPH08233121A/en
Publication of JPH08233121A publication Critical patent/JPH08233121A/en
Pending legal-status Critical Current

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  • Sliding Valves (AREA)
  • Multiple-Way Valves (AREA)

Abstract

PURPOSE: To improve the sealing property, to suppress a rise of the sliding torque, and to obtain a smooth sliding property with no linking, by forming the sliding surface of at least one side of a fixed valve body and a movable valve body to compose a faucet valve with an amorphorous hard carbon membrane, and making the surface roughness of the sliding surfaces of both valve bodies within a specific value. CONSTITUTION: While one side sliding surface 31 (21) or both side sliding surfaces 31 and 21 of a fixed valve body 30 and a movable valve body 20 to compose a faucet valve 10 are formed of amorphorous hard carbon membranes 33 and 23, the surface roughness (Ra) of the sliding surfaces 31 and 21 is made 0.08 to 0.4μm. When both sliding surfaces 31 and 21 of the fixed valve body 30 and the movable valve body 20 are formed of amorphorous hard carbon membranes 33 and 23, the membrane thickness T1 of the amorphorous hard carbon membrane 23 at the movable valve body 20 side, and the membrane thickness T2 of the amorphorous hard carbon membrane 33 at the fixed valve body 30 side are made T1 >=T2 , and the surface roughness (the mean roughness on the center line) R1 of the sliding surface 21 at the mavable valve body 20 side, and the surface roughness R2 of the sliding surface 31 at the fixed valve body 30 side are made R1 >=R2 .

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、水栓、湯水混合栓、医
療用サンプリングバルブ、薬液用バルブ等に用いる可動
弁体と固定弁体からなるフォーセットバルブに関するも
のである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a faucet valve composed of a movable valve body and a fixed valve body used for faucets, hot and cold water mixing taps, medical sampling valves, chemical liquid valves and the like.

【0002】[0002]

【従来の技術】水栓や湯水混合栓あるいは医療用サンプ
リングバルブや薬液用バルブに用いられるフォーセット
バルブは、2枚の円盤状弁体を互いに摺接した状態で相
対摺動させることによって、各弁体に形成した流体通路
の開閉を行うようになっている。例えば、水栓や湯水混
合栓として使用されているフォーセットバルブは、図4
(A)に示されるように、可動弁体20と固体弁体30
を互いの摺接面21、31で接した状態としておいて、
図4(B)に示すようにレバー40の操作で可動弁体2
0を動かすことによって、互いの弁体20、30に形成
した流体通路22、32の開閉を行い、供給流体の流量
調整をするようになっていた。
2. Description of the Related Art A faucet valve used for a faucet, a hot and cold water mixing valve, a medical sampling valve, and a chemical liquid valve has two disc-shaped valve bodies slidably contacting each other to be slid relative to each other. The fluid passage formed in the valve body is opened and closed. For example, a faucet valve used as a faucet or a hot and cold water mixing tap is shown in FIG.
As shown in (A), the movable valve body 20 and the solid valve body 30
With the sliding contact surfaces 21 and 31 in contact with each other,
As shown in FIG. 4B, the movable valve body 2 is operated by operating the lever 40.
By moving 0, the fluid passages 22 and 32 formed in the valve bodies 20 and 30 are opened and closed to adjust the flow rate of the supply fluid.

【0003】そして、上記可動弁体20及び固定弁体3
0は、摺動性やシール性を保つために高い寸法精度が要
求されるうえ、互いに絶えず摺り合わされるために摩耗
が激しく、また、常に流体にさらされるために腐食も激
しいことから、近年、高精度に加工することが可能であ
り、耐摩耗性や耐食性に優れたセラミックスにより形成
されている。
The movable valve body 20 and the fixed valve body 3 are provided.
In the case of 0, high dimensional accuracy is required to maintain slidability and sealability, wear is severe due to continuous sliding, and corrosion is severe due to constant exposure to fluid. It can be processed with high precision and is made of ceramics with excellent wear resistance and corrosion resistance.

【0004】ところで、摺動性とシール性は相反するも
のであり、シール性を高めるために摺接面を極めて平滑
な面とし、これらの摺接面を持った一対の弁体同士を摺
り合わせると、引っかかりや異音が発生し、さらには互
いの弁体が張り付いて動かなくなるというリンキング
(凝着)が生じていた。また、リンキングまで至らなく
ても、摺動回数を重ねるにつれ次第に摺動トルクが上昇
していくことも知られていた。
By the way, the slidability and the sealability are contradictory. In order to improve the sealability, the sliding contact surface is made extremely smooth, and a pair of valve bodies having these sliding contact surfaces are slid together. Then, there was a catch and an abnormal noise, and further, linking (adhesion) of the valve bodies sticking to each other and not moving. It has also been known that the sliding torque gradually increases as the number of sliding times increases even if linking is not achieved.

【0005】そこで、リンキングを防ぐため、さまざま
な解決策が提案されている。
Therefore, various solutions have been proposed to prevent linking.

【0006】例えば、摺接面に微小な凹凸を形成した
り、あるいは弁体を三次元網目構造の多孔質セラミック
スとし、この開気孔中に潤滑材として樹脂やオイルなど
を含浸させたものがある(特開昭61−206875
号、61−244980号、62−4949号、62−
37517号、特公平5−50475号各公報等参
照)。
For example, there is one in which minute unevenness is formed on the sliding contact surface, or the valve body is made of porous ceramics having a three-dimensional mesh structure, and the open pores are impregnated with resin or oil as a lubricant. (JP-A-61-206875
No., 61-244980, 62-4949, 62-
37517, Japanese Patent Publication No. 5-50475, etc.).

【0007】[0007]

【発明が解決しようとする課題】ところが、摺接面に微
小な凹凸を形成したフォーセットバルブでは、摺動性を
保つために潤滑剤が不可欠であるが、長期使用中に潤滑
剤が流出すると凹凸を有する摺動面同士の摺動となって
摺動トルクが大きくなってしまうといった問題やシール
性が損なわれる恐れがあった。
However, in a facet valve in which minute unevenness is formed on the sliding contact surface, a lubricant is indispensable to maintain slidability, but if the lubricant flows out during long-term use, There is a possibility that the sliding surface having irregularities may slide and the sliding torque may increase, and the sealing performance may be impaired.

【0008】また、潤滑剤の種類によっては、長期使用
中に劣化したり、ゴミ等の付着が発生して摺動特性の悪
化を避けることが難しかった。しかも、摺動摩耗によっ
て摺動面が滑らかになってしまい、結局リンキングの発
生が避けられなかった。
Further, depending on the type of lubricant, it is difficult to avoid deterioration of sliding characteristics due to deterioration during long-term use or adhesion of dust or the like. Moreover, sliding wear makes the sliding surface smooth, which inevitably causes linking.

【0009】一方、多孔質体中の開気孔中に樹脂を充填
したものでは、硬度の低い樹脂部分が先に削られてしま
い潤滑作用をなす樹脂が常に相手剤と接しないため、操
作力にばらつきがあった。しかも、緻密な相手材に比べ
多孔質体であるために硬度が低く、その結果、短期間で
摩耗してしまうという問題があった。
On the other hand, in the case where the open pores in the porous body are filled with a resin, the resin portion having a low hardness is shaved first, and the resin having a lubricating action is not always in contact with the mating agent. There was variation. Moreover, since it is a porous material as compared with a dense mating material, it has a low hardness, and as a result, there is a problem that it is worn in a short period of time.

【0010】これらに対し、近年、耐摩耗性に優れ、摩
擦係数の小さい非晶質硬質炭素(ダイヤモンド状炭素、
Diamond Like Carbon(DLC)、
アモルファスダイヤモンド、アモルファス水素化炭素、
i−カーボン等とも呼ばれる)が注目されており、この
非晶質硬質炭素から成る膜をセラミックス部材に形成し
た摺動部材が提案されている(特開平3−223190
号公報参照)。
On the other hand, in recent years, amorphous hard carbon (diamond-like carbon, which has excellent wear resistance and a small friction coefficient,
Diamond Like Carbon (DLC),
Amorphous diamond, amorphous hydrogenated carbon,
(Also referred to as i-carbon) has attracted attention, and a sliding member in which a film made of this amorphous hard carbon is formed on a ceramic member has been proposed (JP-A-3-223190).
(See the official gazette).

【0011】しかし、上記特開平3−223190号公
報に示された摺動部材は、非晶質硬質炭素膜を形成する
母材の表面粗さは示されているものの、非晶質硬質炭素
膜を形成した後の摺接面の表面粗さは全く示されておら
ず、摺接面の好ましい表面状態について何ら示唆されて
いないものであった。
However, in the sliding member disclosed in Japanese Patent Laid-Open No. 3-223190, although the surface roughness of the base material forming the amorphous hard carbon film is shown, the amorphous hard carbon film is formed. The surface roughness of the sliding contact surface after forming was not shown at all, and the preferable surface condition of the sliding contact surface was not suggested at all.

【0012】一方、フォーセットバルブの摺動回数は、
従来10万回の摺動全般に渡って摺動トルクが安定して
いることが要求されていたが、最近では20万回まで摺
動トルクが低く安定していることが要求され始めてい
る。これに対し、単に非晶質硬質炭素膜を用いただけで
は、20万回の摺動にわたって良好に使用可能なフォー
セットバルブは得られていないのが現状であった。
On the other hand, the number of sliding times of the facet valve is
Conventionally, it was required that the sliding torque be stable over the entire sliding of 100,000 times, but recently, it is beginning to be required that the sliding torque is low and stable up to 200,000 times. On the other hand, the present situation is that a simple use of an amorphous hard carbon film has not yielded a Faucet valve that can be favorably used over 200,000 times of sliding.

【0013】本発明の目的は、シール性が良好で、摺動
回数を重ねても摺動トルクが上昇せず、しかも母材の露
出を防止することが可能であり、且つ長期間にわたりリ
ンキングを生じることなく滑らかな摺動性を有するフォ
ーセットバルブを提供することにある。
The object of the present invention is that the sealing property is good, the sliding torque does not increase even after repeated sliding, the base material can be prevented from being exposed, and the linking is performed for a long period of time. An object of the present invention is to provide a facet valve having a smooth sliding property without causing any trouble.

【0014】[0014]

【課題を解決するための手段】そこで本発明は、フォー
セットバルブを構成する固定弁体と可動弁体の少なくと
も一方の摺接面を非晶質硬質炭素膜で形成し、かつ両弁
体の摺接面の表面粗さ(Ra)を0.08〜0.4μm
としたことを特徴とするものである。
Therefore, according to the present invention, the sliding contact surface of at least one of the fixed valve body and the movable valve body forming the facet valve is formed of an amorphous hard carbon film, and Surface roughness (Ra) of sliding contact surface is 0.08-0.4 μm
It is characterized by that.

【0015】即ち、摺動性を良好にするためには、非晶
質硬質炭素膜を被着した後の摺接面の表面粗さが重要で
あることを見出したのである。そして、摺接面の表面粗
さ(Ra)が0.08μm未満であると前述したように
各弁体が吸着して摺動トルクが大きくなってしまい、一
方0.4μmを超えるとシール性が悪くなってしまうこ
とから、上記範囲内に限定した。なお、非晶質硬質炭素
膜を一方の弁体のみにしか形成しない場合は、非晶質硬
質炭素膜を形成しない側の弁体の摺接面も表面粗さ(R
a)を0.08〜0.4μmとすることが必要である。
That is, it was found that the surface roughness of the sliding contact surface after depositing the amorphous hard carbon film is important for improving the slidability. When the surface roughness (Ra) of the sliding contact surface is less than 0.08 μm, each valve element adsorbs and the sliding torque becomes large as described above, while when it exceeds 0.4 μm, the sealing property becomes poor. Since it will worsen, it was limited to the above range. When the amorphous hard carbon film is formed only on one valve body, the sliding contact surface of the valve body on which the amorphous hard carbon film is not formed also has a surface roughness (R
It is necessary to set a) to 0.08 to 0.4 μm.

【0016】また、本発明は、フォーセットバルブを構
成する固定弁体と可動弁体の両方の摺接面を非晶質硬質
炭素膜で形成し、可動弁体側の非晶質硬質炭素膜の膜厚
1と固定弁体側の非晶質硬質炭素膜の膜厚T2 を T1 ≧T2 とし、かつ可動弁体側の摺接面の表面粗さ(中心線平均
粗さ)R1 と固定弁体側の摺接面の表面粗さR2 を R1 ≧R2 としたことを特徴とするものである。
Further, according to the present invention, the sliding contact surfaces of both the fixed valve body and the movable valve body forming the facet valve are formed of an amorphous hard carbon film, and the amorphous hard carbon film on the movable valve body side is formed. The film thickness T 1 and the film thickness T 2 of the amorphous hard carbon film on the fixed valve body side are set to T 1 ≧ T 2 , and the surface roughness (center line average roughness) R 1 of the sliding contact surface on the movable valve body side is set. The surface roughness R 2 of the sliding contact surface on the fixed valve body side is set to R 1 ≧ R 2 .

【0017】即ち、20万回以上の摺動回数に渡って優
れた摺動性を維持するためには、固定弁体と可動弁体の
両方の摺接面に非晶質硬質炭素膜を被着しなければなら
ず、この際に可動弁体側の非晶質硬質炭素膜の膜厚T1
を厚くし、表面粗さR1 を大きくすれば良いことを見出
したのである。
That is, in order to maintain excellent slidability over the number of sliding times of 200,000 times or more, an amorphous hard carbon film is coated on the sliding contact surfaces of both the fixed valve body and the movable valve body. The amorphous hard carbon film on the movable valve side T 1
It has been found that it is sufficient to increase the thickness and increase the surface roughness R 1 .

【0018】これは、固定弁体側の摺動面は部分的に摺
動するのに対し、可動弁体側は常に全面が摺動するため
摺動条件が厳しいことによるものである。つまり、可動
弁体側の非晶質硬質炭素膜を厚くすることによって摺動
摩耗により膜が完全に磨滅することを防止し、また可動
弁体側の非晶質硬質炭素膜の表面粗さを大きくすること
によって摺動摩耗により滑らかな面となることを防止で
きるのである。
This is because the sliding surface on the fixed valve body side partially slides, whereas the entire surface on the movable valve body side always slides, so the sliding conditions are severe. That is, by thickening the amorphous hard carbon film on the movable valve body side, it is possible to prevent the film from being completely worn away by sliding wear, and to increase the surface roughness of the amorphous hard carbon film on the movable valve body side. As a result, it is possible to prevent a smooth surface due to sliding wear.

【0019】[0019]

【実施例】以下、本発明実施例を説明する。なお、従来
部分と同一部分については同一符号で示す。
EXAMPLES Examples of the present invention will be described below. The same parts as the conventional parts are indicated by the same reference numerals.

【0020】図1は、本発明に係るフォーセットバルブ
の弁体のみを示す図であり、図2は可動弁体20のみ
を、図3は固定弁体30のみをそれぞれ示す図である。
FIG. 1 is a view showing only a valve body of a faucet valve according to the present invention, FIG. 2 is a view showing only a movable valve body 20, and FIG. 3 is a view showing only a fixed valve body 30.

【0021】図1に示すように、円盤状をした固定弁体
30と可動弁体20を互いの摺接面21、31で接した
状態としておいて、可動弁体20を動かすことによっ
て、互いの弁体20、30に備えた流体通路22、32
の開閉を行い、流体の流量調整を行うようにしてある。
As shown in FIG. 1, the fixed valve body 30 and the movable valve body 20, which are disc-shaped, are kept in contact with each other at their sliding contact surfaces 21 and 31, and the movable valve body 20 is moved to move the movable valve body 20 to each other. Fluid passages 22, 32 provided in the valve bodies 20, 30 of
Is opened and closed to adjust the flow rate of the fluid.

【0022】又、これらの可動弁体20、固定弁体30
には耐摩耗性に優れ変形し難い材質が要求されることか
ら、それぞれの基体24、34は真鍮やステンレス、あ
るいは超硬合金などの硬質金属、又はセラミックスによ
り形成し、その表面に非晶質硬質炭素膜23、33を被
着して摺接面21、31を形成してある。
The movable valve body 20 and the fixed valve body 30 are also provided.
Since a material having excellent wear resistance and resistant to deformation is required for each of the bases 24 and 34, each of the bases 24 and 34 is formed of a hard metal such as brass, stainless steel, or a cemented carbide, or ceramics, and the surface thereof is amorphous. Hard carbon films 23 and 33 are adhered to form sliding contact surfaces 21 and 31.

【0023】ここで、上記基体24、34を成すセラミ
ックスは、アルミナ、ジルコニア、炭化珪素、窒化珪素
等を主体とする焼結体であって、所定の焼結助剤等を所
定量配合することで得られる。例えば、アルミナに対し
てはCaO,SiO2 ,MgOのうち少なくとも一種
を、炭化珪素に対してはC,B,B4 C,Al2 3
2 3 等を、さらに窒化珪素に対しては周期律表2
a、3a族元素の酸化物や窒化物をそれぞれ焼結助剤と
して添加し、ジルコニアに対してはY2 3 ,CaO,
MgOなどの安定化剤を添加する。
Here, the ceramics forming the bases 24 and 34 are sintered bodies mainly containing alumina, zirconia, silicon carbide, silicon nitride and the like, and a predetermined amount of a predetermined sintering aid or the like is mixed therein. Can be obtained at. For example, for alumina, at least one of CaO, SiO 2 , and MgO is used, and for silicon carbide, C, B, B 4 C, Al 2 O 3 ,
For Y 2 O 3 and the like, and for silicon nitride, the periodic table 2
Oxides and nitrides of a and 3a group elements are respectively added as sintering aids, and for zirconia, Y 2 O 3 , CaO,
Stabilizers such as MgO are added.

【0024】また、各弁体の摺接面21、31を成す非
晶質硬質炭素膜23、33上の表面粗さ(中心線平均粗
さ:Ra)はそれぞれ0.08〜0.4μmの範囲内と
してある。これは、表面粗さ(Ra)が0.08μm未
満であると、摺接面21、31が滑らかすぎて吸着しや
すくなるためであり、逆に0.4μmを超えるとシール
性が悪くなるためである。
The surface roughness (center line average roughness: Ra) on the amorphous hard carbon films 23 and 33 forming the sliding contact surfaces 21 and 31 of each valve body is 0.08 to 0.4 μm, respectively. Within the range. This is because when the surface roughness (Ra) is less than 0.08 μm, the sliding contact surfaces 21 and 31 are too smooth to be easily adsorbed, and when the surface roughness (Ra) exceeds 0.4 μm, the sealing property deteriorates. Is.

【0025】また、上記非晶質硬質炭素膜23、33の
厚みはそれぞれ0.3〜1.5μmの範囲内としてあ
る。これは厚みが0.3μm未満であると摩耗により磨
滅しやすく、逆に1.5μmを超えると製膜時の歪み等
により剥離しやすいためである。
The thickness of each of the amorphous hard carbon films 23 and 33 is within the range of 0.3 to 1.5 μm. This is because when the thickness is less than 0.3 μm, it is easily worn away due to abrasion, and conversely, when the thickness is more than 1.5 μm, it is easily peeled off due to distortion during film formation.

【0026】なお、この実施例では両弁体の摺接面2
1、31を非晶質硬質炭素膜23、33で形成したが、
一方のみを非晶質硬質炭素膜で形成したものでも良い。
この場合は、他方の摺接面はセラミックスで形成し、そ
の表面粗さ(Ra)を0.08〜0.4μmとする。た
だし、好適な摺動性をより長期間維持するためには、両
方の弁体の摺接面21、31を非晶質硬質炭素膜23、
33で形成することが好ましい。
In this embodiment, the sliding contact surface 2 of both valve bodies is
1 and 31 are formed of amorphous hard carbon films 23 and 33,
It is also possible that only one of them is formed of an amorphous hard carbon film.
In this case, the other sliding contact surface is made of ceramics and has a surface roughness (Ra) of 0.08 to 0.4 μm. However, in order to maintain preferable slidability for a longer period of time, the sliding contact surfaces 21 and 31 of both valve bodies are made of the amorphous hard carbon film 23,
It is preferable to form 33.

【0027】さらに、本発明では、図1〜3の実施例の
ように両弁体に非晶質硬質炭素膜23、33を備えた場
合において、それぞれの非晶質硬質炭素膜23、33の
膜厚みの関係、及びそれぞれの摺接面21、31の表面
粗さの関係が重要であることを見出した。
Further, according to the present invention, when both valve bodies are provided with the amorphous hard carbon films 23 and 33 as in the embodiment of FIGS. It has been found that the relationship between the film thickness and the surface roughness of the sliding contact surfaces 21 and 31 is important.

【0028】即ち、可動弁体20側の非晶質硬質炭素膜
23の厚みT1 と、固定弁体30側の非晶質硬質炭素膜
33の厚みT2 を比較したときに、 T1 ≧T2 を満たし、かつ可動弁体20側の摺接面21の表面粗さ
1 と、固定弁体30側の摺接面31の表面粗さR2
比較したときに、 R1 ≧R2 を満たしている点が重要である。
That is, when comparing the thickness T 1 of the amorphous hard carbon film 23 on the movable valve body 20 side with the thickness T 2 of the amorphous hard carbon film 33 on the fixed valve body 30 side, T 1 ≧ When T 2 is satisfied and the surface roughness R 1 of the sliding contact surface 21 on the movable valve body 20 side and the surface roughness R 2 of the sliding contact surface 31 on the fixed valve body 30 side are compared, R 1 ≧ R The point that 2 is satisfied is important.

【0029】つまり、可動弁体20側の摺接面21は常
に全面摺動であり、固定弁体30側に比べて摩耗しやす
いため、摺動を繰り返すと可動弁体20の摺接面21側
の摩耗量が大きくなるが、予め非晶質硬質炭素膜23の
厚みT1 を大きくし、可動弁体20側の表面粗さR1
大きくしておけば、長期間にわたって良好な厚みと表面
粗さの範囲を維持できるのである。
That is, the sliding contact surface 21 on the movable valve body 20 side is always entirely slid, and is more easily worn than on the fixed valve body 30 side. Therefore, when sliding is repeated, the sliding contact surface 21 of the movable valve body 20 is repeated. Although the amount of wear on the side becomes large, if the thickness T 1 of the amorphous hard carbon film 23 is made large in advance and the surface roughness R 1 at the movable valve body 20 side is made large, a good thickness will be obtained for a long period of time. The range of surface roughness can be maintained.

【0030】また、上記摺接面21、31の表面粗さR
1 、R2 については、 R1 >R2 を満たすことが好ましい。
Further, the surface roughness R of the sliding contact surfaces 21 and 31.
1, for R 2 preferably satisfy the R 1> R 2.

【0031】なお、非晶質硬質炭素膜23、33の被着
にはCVD法、PVD法等のさまざまな方法を用いる
が、製膜時のガス圧、温度、時間等の条件を変化させる
ことによって自由に厚みT1 、T2 を調整することがで
きる。また、非晶質硬質炭素膜23、33上の表面粗さ
1 、R2 については、基体24、34の表面粗さや製
膜条件等を変化させることによって、自由に調整するこ
とができる。
Although various methods such as the CVD method and the PVD method are used for depositing the amorphous hard carbon films 23 and 33, the conditions such as gas pressure, temperature and time during film formation may be changed. The thicknesses T 1 and T 2 can be freely adjusted by. The surface roughness R 1 and R 2 on the amorphous hard carbon films 23 and 33 can be freely adjusted by changing the surface roughness of the substrates 24 and 34 and the film forming conditions.

【0032】また、以上の実施例ではディスク状の弁体
を用いた例を示したが、本発明はこの形状に限定される
ものではなく、例えばボールバルブなどさまざまな形状
のフォーセットバルブに適用できることは言うまでもな
い。
Further, although the above embodiment has shown the example using the disc-shaped valve body, the present invention is not limited to this shape, and is applied to various types of facet valves such as ball valves. It goes without saying that you can do it.

【0033】実験例1 まず、フォーセットバルブを成す可動弁体20と固定弁
体30の基体24、34をアルミナセラミックスで形成
し、可動弁体20は外径30mm、厚み10mmの円盤
状体で直径5mmの流体通路22を有し、固定弁体30
は外径40mm、厚み8mmの円盤状体に直径5mmの
流体通路32を有する形状とした。
Experimental Example 1 First, the bases 24 and 34 of the movable valve body 20 and the fixed valve body 30 forming the facet valve are made of alumina ceramics, and the movable valve body 20 is a disk-shaped body having an outer diameter of 30 mm and a thickness of 10 mm. A fixed valve body 30 having a fluid passage 22 with a diameter of 5 mm
Is a disk-shaped body having an outer diameter of 40 mm and a thickness of 8 mm and a fluid passage 32 having a diameter of 5 mm.

【0034】そして、一方の弁体の表面に非晶質硬質炭
素膜を被着した。非晶質硬質炭素膜の形成方法として
は、ベンゼン(C6 6 )ガスをフィラメントでイオン
化した炭素イオンをイオン加速器により基体の表面に蒸
着させるイオンプレーティング法を採用し、厚みは0.
8μmとした。
Then, an amorphous hard carbon film was deposited on the surface of one valve body. As a method for forming the amorphous hard carbon film, an ion plating method in which carbon ions obtained by ionizing benzene (C 6 H 6 ) gas with a filament is vapor-deposited on the surface of the substrate by an ion accelerator, and the thickness is 0.
It was 8 μm.

【0035】また、可動弁体20と固定弁体30の摺接
面21、31の表面粗さが異なるものを数種類試作し、
摺動実験を行った。
Several prototypes of the sliding valve surfaces 21 and 31 of the movable valve body 20 and the fixed valve body 30 having different surface roughness are manufactured.
A sliding experiment was conducted.

【0036】実験は、上記可動弁体20と固定弁体30
をケーシングによって30kgfの軸力で押さえつけな
がら、流体通路22、32に80℃の温水を1kg/c
2の圧力で注入し、可動弁体20を操作レバー40に
より摺動させるのに必要な操作力を測定した。
In the experiment, the movable valve body 20 and the fixed valve body 30 were
While pressing the casing with an axial force of 30 kgf, 1 kg / c of hot water at 80 ° C is placed in the fluid passages 22 and 32.
It was injected at a pressure of m 2 and the operating force required to slide the movable valve body 20 by the operating lever 40 was measured.

【0037】この試験による評価基準は、10万回摺動
させた時の操作レバー40の最大操作力が0.8kg以
下のものを摺動性が良好であると判断した。結果は表
1、及び図5に示通りである。
As the evaluation criteria in this test, it was judged that the slidability was good when the maximum operating force of the operating lever 40 after sliding 100,000 times was 0.8 kg or less. The results are shown in Table 1 and FIG.

【0038】表1より明らかに、両方の弁体に非晶質硬
質炭素膜を形成していないもの(No.1)では摺動中
の操作レバー40の操作力の上昇が速く、10万回後の
操作力は3.0kgfと大きかった。
As is clear from Table 1, in the case where the amorphous hard carbon film is not formed on both valve bodies (No. 1), the operating force of the operating lever 40 increases rapidly during sliding 100,000 times. The subsequent operation force was as large as 3.0 kgf.

【0039】また、No.2のように固定弁体30側に
非晶質硬質炭素膜33を形成しても、その表面粗さ(R
a)が0.08μm未満のものでは摺動の初期段階で吸
着が発生し、一時的に操作力が高くなっていた。
No. Even if the amorphous hard carbon film 33 is formed on the fixed valve body 30 side as in 2, the surface roughness (R
When a) was less than 0.08 μm, adsorption occurred at the initial stage of sliding and the operating force was temporarily increased.

【0040】これらに対し、No.3〜5に示すよう
に、可動弁体20と固定弁体30のいずれか一方に非晶
質硬質炭素膜を形成し、しかもその摺接面の表面粗さ
(Ra)を0.08〜0.4μmの範囲内としたもの
は、最大操作力が0.8kgf以下となり良好な摺動性
を示した。
In contrast to these, 3 to 5, an amorphous hard carbon film is formed on one of the movable valve body 20 and the fixed valve body 30, and the surface roughness (Ra) of the sliding contact surface is 0.08 to 0. In the case of the range of 0.4 μm, the maximum operating force was 0.8 kgf or less, and good slidability was exhibited.

【0041】[0041]

【表1】 [Table 1]

【0042】実験例2 次に上記と同様にして、摺接面の表面粗さの異なるもの
を数種類試作し、フォーセットバルブのリーク試験を行
った。
Experimental Example 2 Next, in the same manner as described above, several kinds of sliding contact surfaces having different surface roughness were made as prototypes, and a leak test of the facet valve was conducted.

【0043】まず、可動弁体20と固定弁体30を一部
切り欠きを有するケーシングによって30kgfの軸力
で流体通路22、32が完全に遮断されるように押さえ
つけたフォーセットバルブを水中に浸漬させた。その
後、流体通路22側より圧力4kg/cm2 で空気を流
し込み、ケーシングの切り欠きより泡が発生するかどう
かでシール性の良否を判断した。
First, the movable valve body 20 and the fixed valve body 30 are soaked in water by a casing having a notch so that the fluid passages 22 and 32 are completely blocked by the axial force of 30 kgf. Let After that, air was flown in from the fluid passage 22 side at a pressure of 4 kg / cm 2 , and the quality of the sealing property was judged by whether or not bubbles were generated from the notch of the casing.

【0044】結果は表2に示す通りである。この結果よ
り明らかに、可動弁体20と固定弁体30の両方の摺接
面を表面粗さ(Ra)0.4μm以下とすれば泡が発生
せず、シール性が良好であることがわかる。
The results are shown in Table 2. From this result, it is clear that when the sliding contact surfaces of both the movable valve body 20 and the fixed valve body 30 have a surface roughness (Ra) of 0.4 μm or less, bubbles do not occur and the sealing property is good. .

【0045】したがって、摺接面の少なくとも一方に非
晶質硬質炭素膜を形成し、かつ両方の摺接面の表面粗さ
(Ra)を0.08〜0.4μmの範囲内とすれば、低
い操作力と高いシール性を長期間維持できることがわか
る。
Therefore, if an amorphous hard carbon film is formed on at least one of the sliding contact surfaces and the surface roughness (Ra) of both sliding contact surfaces is within the range of 0.08 to 0.4 μm, It can be seen that low operating force and high sealing performance can be maintained for a long time.

【0046】[0046]

【表2】 [Table 2]

【0047】実験例3 次に、図1に示すフォーセットバルブを成す可動弁体2
0と固定弁体30の基体24、34をアルミナセラミッ
クスで形成し、可動弁体20は外径30mm、厚み10
mmの円盤状体で直径5mmの流体通路22を有し、固
定弁体30は外径40mm、厚み8mmの円盤状体に直
径5mmの流体通路32を有する形状とした。
Experimental Example 3 Next, the movable valve body 2 forming the facet valve shown in FIG.
0 and the bases 24 and 34 of the fixed valve body 30 are made of alumina ceramics, and the movable valve body 20 has an outer diameter of 30 mm and a thickness of 10
The fixed valve body 30 has a shape of a disc-shaped body having an outer diameter of 40 mm and a thickness of 8 mm, and a fluid passage 32 having a diameter of 5 mm.

【0048】そして、両方の弁体の表面に非晶質硬質炭
素膜23、33を被着して摺接面21、31を形成し
た。非晶質硬質炭素膜の形成方法としては、ベンゼン
(C6 6 )ガスをフィラメントでイオン化した炭素イ
オンをイオン加速器により基体の表面に蒸着させるイオ
ンプレーティング法を採用した。
Amorphous hard carbon films 23 and 33 were adhered to the surfaces of both valve bodies to form sliding contact surfaces 21 and 31. As a method for forming the amorphous hard carbon film, an ion plating method was adopted in which carbon ions obtained by ionizing benzene (C 6 H 6 ) gas with a filament were deposited on the surface of the substrate by an ion accelerator.

【0049】また、上記摺接面21、31の表面粗さR
1 ,R2 、及び非晶質硬質炭素膜23、33の厚み
1 ,T2 が異なるものを数種類試作し、摺動実験を行
った。
Further, the surface roughness R of the sliding contact surfaces 21 and 31.
Several kinds of 1 , R 2 and amorphous hard carbon films 23, 33 having different thicknesses T 1 , T 2 were made as prototypes and a sliding test was conducted.

【0050】実験は、上記可動弁体20と固定弁体30
をケーシングによって30kgfの軸力で押さえつけな
がら、流体通路22、32に80℃の温水を1kg/c
2の圧力で注入し、可動弁体20を操作レバー40に
より摺動させるのに必要な操作力を測定した。なお、操
作レバー40の支点から作用点までの長さは65mmと
した。この試験による評価基準は、20万回摺動させた
時の操作レバー40の最大操作力が0.8kg以下のも
のを摺動性が良好であると判断した。
In the experiment, the movable valve body 20 and the fixed valve body 30 are
While pressing the casing with an axial force of 30 kgf, 1 kg / c of hot water at 80 ° C is placed in the fluid passages 22 and 32.
It was injected at a pressure of m 2 and the operating force required to slide the movable valve body 20 by the operating lever 40 was measured. The length from the fulcrum of the operating lever 40 to the point of action was 65 mm. As an evaluation criterion by this test, it was judged that the slidability was good when the maximum operating force of the operating lever 40 when sliding 200,000 times was 0.8 kg or less.

【0051】また、20万回摺動後の可動弁体20側の
摺接面21を観察し、非晶質硬質炭素膜23が磨滅して
基体24が露出しているかどうかを調べた。結果は表3
及び図6〜8に示通りである。
Further, the sliding contact surface 21 on the movable valve body 20 side after sliding 200,000 times was observed to examine whether or not the amorphous hard carbon film 23 was abraded and the substrate 24 was exposed. The results are shown in Table 3.
And as shown in FIGS.

【0052】これらの結果より明らかに、可動弁体20
側の非晶質硬質炭素膜23の厚みT1 が固定弁体30側
より小さいもの(No.1,2,3)、又は可動弁体2
0側の摺接面21の表面粗さR1 が固定弁体30側より
小さいもの(No.1,4,7)では、可動弁体20側
の非晶質硬質炭素膜23が磨滅して基体24が露出した
り、操作力が0.8kgfを超えてしまった。
Clearly from these results, the movable valve body 20
The thickness T 1 of the amorphous hard carbon film 23 on the side is smaller than the fixed valve body 30 side (No. 1, 2, 3), or the movable valve body 2
When the surface roughness R 1 of the sliding contact surface 21 on the 0 side is smaller than the fixed valve body 30 side (No. 1, 4, 7), the amorphous hard carbon film 23 on the movable valve body 20 side is worn away. The substrate 24 was exposed, and the operating force exceeded 0.8 kgf.

【0053】これらに対し、可動弁体20側の非晶質硬
質炭素膜23の厚みT1 が固定弁体30側の厚みT2
上で、可動弁体20側の摺接面21の表面粗さR1 が固
定弁体30側の表面粗さR2 以上であるもの(No.
5,6,8,9)は、基体の露出がなく、操作力も0.
7kgf以下と優れた結果であった。
On the other hand, the thickness T 1 of the amorphous hard carbon film 23 on the movable valve body 20 side is equal to or larger than the thickness T 2 on the fixed valve body 30 side, and the surface roughness of the sliding contact surface 21 on the movable valve body 20 side is large. The surface roughness R 1 is not less than the surface roughness R 2 on the fixed valve body 30 side (No.
No. 5,6,8,9) does not expose the substrate and the operating force is 0.
It was an excellent result of 7 kgf or less.

【0054】[0054]

【表3】 [Table 3]

【0055】[0055]

【発明の効果】以上のように本発明によれば、フォーセ
ットバルブを構成する固定弁体と可動弁体の少なくとも
一方の摺接面を非晶質硬質炭素膜で形成し、かつ両方の
摺接面の表面粗さ(Ra)を0.08〜0.4μmとし
たことによって、低い操作力と高いシール性を長期間維
持することのできる高性能のフォーセットバルブを提供
できる。
As described above, according to the present invention, the sliding contact surface of at least one of the fixed valve body and the movable valve body forming the facet valve is formed of an amorphous hard carbon film, and both sliding surfaces are formed. By setting the surface roughness (Ra) of the contact surface to be 0.08 to 0.4 μm, it is possible to provide a high-performance facet valve capable of maintaining a low operating force and a high sealing property for a long period of time.

【0056】また、本発明によれば、フォーセットバル
ブを構成する固定弁体と可動弁体の両方の摺接面を非晶
質硬質炭素膜で形成し、可動弁体側の非晶質硬質炭素膜
の膜厚T1 と固定弁体側の非晶質硬質炭素膜の膜厚T2
を T1 ≧T2 とし、かつ可動弁体側の摺接面の表面粗さ(中心線平均
粗さ)R1 と固定弁体側の摺接面の表面粗さR2 を R1 ≧R2 としたことによって、20万回の摺動を行っても0.8
kgf以下の低い操作力を維持し、しかも基体の露出も
ないことから、長期間にわたって良好な摺動性を維持で
きる極めて高性能のフォーセットバルブを提供できる。
Further, according to the present invention, the sliding contact surfaces of both the fixed valve body and the movable valve body forming the facet valve are formed of the amorphous hard carbon film, and the amorphous hard carbon on the movable valve body side is formed. Film thickness T 1 and amorphous hard carbon film thickness T 2 on the fixed valve body side
Is T 1 ≧ T 2 , and the surface roughness (center line average roughness) R 1 of the sliding contact surface on the movable valve body side and the surface roughness R 2 of the sliding contact surface on the fixed valve body side are R 1 ≧ R 2 . As a result, even after sliding 200,000 times 0.8
Since a low operating force of not more than kgf is maintained and the substrate is not exposed, it is possible to provide an extremely high-performance facet valve capable of maintaining good slidability for a long period of time.

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

【図1】本発明のフォーセットバルブの弁体のみを示す
斜視図である。
FIG. 1 is a perspective view showing only a valve body of a faucet valve of the present invention.

【図2】図1の可動弁体を示す斜視図である。FIG. 2 is a perspective view showing the movable valve body of FIG.

【図3】図1の固定弁体を示す斜視図である。3 is a perspective view showing the fixed valve body of FIG. 1. FIG.

【図4】一般的なフォーセットバルブの作動状態を示す
斜視図で(A)は流体通路を開通させた図であり、
(B)は流体通路を遮断した図である。
FIG. 4 is a perspective view showing an operating state of a general faucet valve, in which (A) is a view in which a fluid passage is opened,
(B) is a view in which the fluid passage is cut off.

【図5】本発明及び比較例のフォーセットバルブにおけ
る摺動回数と操作力の関係を示すグラフである。
FIG. 5 is a graph showing the relationship between the number of sliding times and the operating force in the facet valve of the present invention and the comparative example.

【図6】本発明及び比較例のフォーセットバルブにおけ
る摺動回数と操作力の関係を示すグラフである。
FIG. 6 is a graph showing the relationship between the number of times of sliding and the operating force in the facet valve of the present invention and the comparative example.

【図7】本発明及び比較例のフォーセットバルブにおけ
る摺動回数と操作力の関係を示すグラフである。
FIG. 7 is a graph showing the relationship between the number of times of sliding and the operating force in the facet valve of the present invention and the comparative example.

【図8】本発明及び比較例のフォーセットバルブにおけ
る摺動回数と操作力の関係を示すグラフである。
FIG. 8 is a graph showing the relationship between the number of sliding times and the operating force in the facet valve of the present invention and the comparative example.

【符号の説明】[Explanation of symbols]

10 :フォーセットバルブ 20 :可動弁体 21 :摺接面 22 :流体通路 23 :非晶質硬質炭素膜 24 :基体 30 :固定弁体 31 :摺接面 32 :流体通路 33 :非晶質硬質炭素膜 34 :基体 40 :操作レバー 10: Faucet valve 20: Movable valve body 21: Sliding contact surface 22: Fluid passage 23: Amorphous hard carbon film 24: Base body 30: Fixed valve body 31: Sliding contact surface 32: Fluid passage 33: Amorphous hard Carbon film 34: Substrate 40: Operating lever

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】バルブを構成する固定弁体と可動弁体の少
なくとも一方の摺接面を非晶質硬質炭素膜で形成し、か
つ両弁体の摺接面の表面粗さ(Ra)を0.08〜0.
4μmとしたことを特徴とするフォーセットバルブ。
1. A sliding valve contact surface of at least one of a fixed valve element and a movable valve element constituting a valve is formed of an amorphous hard carbon film, and the surface roughness (Ra) of the sliding contact element of both valve elements is determined. 0.08-0.
Faucet valve characterized by having a thickness of 4 μm.
【請求項2】バルブを構成する固定弁体と可動弁体の両
方の摺接面を非晶質硬質炭素膜で形成し、可動弁体側の
非晶質硬質炭素膜の膜厚T1 と固定弁体側の非晶質硬質
炭素膜の膜厚T2 を T1 ≧T2 とし、かつ可動弁体側の摺接面の表面粗さ(中心線平均
粗さ)R1 と固定弁体側の摺接面の表面粗さR2 を R1 ≧R2 としたことを特徴とするフォーセットバルブ。
2. A sliding contact surface of both a fixed valve body and a movable valve body which form a valve is formed of an amorphous hard carbon film, and is fixed to a film thickness T 1 of the amorphous hard carbon film on the movable valve body side. The film thickness T 2 of the amorphous hard carbon film on the valve body side is T 1 ≧ T 2 , and the surface roughness (center line average roughness) R 1 of the sliding contact surface on the movable valve body side and the sliding contact on the fixed valve body side. A facet valve having a surface roughness R 2 of R 1 ≧ R 2 .
JP4102595A 1995-02-28 1995-02-28 Faucet valve Pending JPH08233121A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP4102595A JPH08233121A (en) 1995-02-28 1995-02-28 Faucet valve

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP4102595A JPH08233121A (en) 1995-02-28 1995-02-28 Faucet valve

Publications (1)

Publication Number Publication Date
JPH08233121A true JPH08233121A (en) 1996-09-10

Family

ID=12596862

Family Applications (1)

Application Number Title Priority Date Filing Date
JP4102595A Pending JPH08233121A (en) 1995-02-28 1995-02-28 Faucet valve

Country Status (1)

Country Link
JP (1) JPH08233121A (en)

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US7498083B2 (en) 2004-11-12 2009-03-03 Kabushiki Kaisha Kobe Seiko Sho Sliding member with excellent wear resistance in water-based environments
JP2010271029A (en) * 2009-04-23 2010-12-02 Sumitomo Heavy Ind Ltd Cooling storage type refrigerating machine, method of manufacturing rotary valve for the cooling storage type refrigerating machine and method of manufacturing the cooling storage type refrigerating machine
WO2023145270A1 (en) * 2022-01-28 2023-08-03 株式会社日立ハイテク Flow switching valve and manufacturing method therefor

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
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