JPS58210378A - Fluid machinery driven by heat engine - Google Patents

Abstract

PURPOSE:To improve the effect of insulating working fluid in a fluid machinery from that in a heat engine by dividing a closed container with two flexible partition plates to dispose the fluid machinery in a central chamber and the heat engine in one of outside chambers and affording communication between one outside chamber and the other to interconnect the fluid machinery and heat engine with a transmission shaft extending through the partition plate. CONSTITUTION:A heat engine 23 and a fluid machinery (like a pump) 24 are interconnected through a transmission shaft 25 to drive a piston 26 vertically. A partition chamber 37 is provided between the engine 23 and the machinery 24 and a first flexible partition plate 38 is provided in the chamber 37 to seal said shaft 25. A partition chamber 44 and a cushion chamber 45 are provided at the opposite side to said chamber 37, and in the partition chamber 44 is provided a second flexible partition plate 46. Also, the chamber 43 and the chamber 50 are interconnected through an equalizing pipe 51, and the chambers 42, 49 by an equalizing pipe 52. Each working fluid for the heat engine 23 and the fluid machinery 24 is divided by the first and second partition plates 38, 46 and large differential pressure is not produced between both side chambers of the partition plates so that satisfactory sealing property is ensured.

Description

【発明の詳細な説明】 本発明は、熱機関で駆動する流体機械に関し。[Detailed description of the invention] The present invention relates to a fluid machine driven by a heat engine.

籍に熱機関の作動流体と流体機械によって圧縮等の作用
を受ける流体（以下流体機械の作動流体と略称する）と
が互いに混じり会わない＊に隔てたものに関する。It relates to a system in which the working fluid of a heat engine and the fluid subjected to compression or other action by a fluid machine (hereinafter referred to as the working fluid of a fluid machine) are separated so that they do not mix with each other.

従来の熱１？Ｍ闇で駆動する流体機械において熱機関の
作＃流体と流体機械の作−流体を隔てる様にしたものは
、第１図の様な構造であったＯ第１図において、熱機関
（υによって駆動さｎる伝動軸１２）にはえ体愼械（３
）のピストン（４）が取付けらｎ、熱機関（υから受け
る力によって伝動軸（２）が軸方向に往復運動し、そｎ
によって往復運動するピストン（４）によってその軸方
向両側の室（５）及び（６）の体積が増減する。そｎに
よって、流体機械（３）の作動流体は。Conventional heat 1? M In a fluid machine driven in the dark, the structure that separates the working fluid of the heat engine and the working fluid of the fluid machine is as shown in Figure 1. The fly body machine (3) is attached to the driven transmission shaft 12).
) is installed, and the transmission shaft (2) reciprocates in the axial direction due to the force received from the heat engine (υ).
The volume of the chambers (5) and (6) on both sides in the axial direction increases and decreases due to the reciprocating piston (4). According to this, the working fluid of the fluid machine (3) is:

吸入通路（７）、吸入！（８）、吸入弁（９）又はμＱ
を通って厘（５）又は（６）に人〃、前記ピストン（４
）の往復運動によって加圧され、吐出弁（６）又はｕ２
９．吐出室−，吐出通路四を通って出て行く。こうして
、熱機関（υは、伝動軸（２）、流体機械（３）を介し
て流体機械の作動媒体に仕事をする。Inhalation passage (7), inhalation! (8), suction valve (9) or μQ
Pass through the piston (4) to the piston (5) or (6).
) is pressurized by the reciprocating movement of the discharge valve (6) or u2
9. The discharge chamber exits through the discharge passage 4. In this way, the heat engine (υ) performs work on the working medium of the fluid machine via the transmission shaft (2) and the fluid machine (3).

一万、熱機関（υの作動流体と流体機械（３）の作動流
体とが互いに混じ９酋わない様にするため、熱機関（υ
と）流体機械（３）との間の仕切嵐（ロ）内に可読性隔
板α〜が設けられている０この可焼性隔板α句の一方の
縁Ｑηは、前記熱機関（ｌへ流体慎械（３〕及び厘−ｒ
外部に対して田閉する街閉谷器（至）に封止さｎ。10,000, in order to prevent the working fluid of the heat engine (υ) and the working fluid of the fluid machine (3) from mixing with each other, the heat engine (υ
A readable diaphragm α is provided in the partition storm (b) between the heat engine (3) and the heat engine (3). One edge Qη of this flammable diaphragm α Fluid Shinki (3) and Rin-r
It is sealed in a street closure device (to) that is closed to the outside.

他方の縁σ９１は伝動１１１１　Ｉ２）に封止さｎてお
９．熱機関（１）の作製流体と流体機械（３）Ｏｆ「−
流体とは互いに混じり甘うことはなく、かつ伝動＠（２
）の往復運動は町胸性隔板α〜の変形によって許さｎる
。The other edge σ91 is sealed to the transmission 1111 I2). Preparation of heat engine (1) Fluid and fluid machine (3) Of "-
Fluids do not mix with each other, and transmission @ (2
) is allowed by the deformation of the thoracic septum α~.

ところで、この様な構成の揚台１次の嫌な入点があった
。すなわち、仕切室（至）内のり焼注隔板α〜で隔てら
ｎ７′ｃｍ−とＩ４−１！内の圧力は１時間平均的ＶＣ
は等しくなる様になっているが、伝動軸（２）が往復運
動している各瞬間には咎しくない。今、第１図において
ｔｊＪ撓性陽性隔板α６Ｊする蚕■内の圧力と呈呵）内
の圧力が等しいとして、このとき伝動軸（２）が上方Ｖ
ｃｆ位すると、可撓性隔板α〜の縁四も伝動軸（２）と
共に上方に変位するので、呈−）の体積は減少して内圧
が増加し、他万屋四の体積は増加して内圧が試少し、そ
の結果可読性隔板（１句にこの差圧による力が下方に鋤
く。これによってａＪ撓性噛板圓には、縁四の上方への
移動による菱形と上記差圧による力によって生じる菱形
とが生じ、差圧が０になる筐で菱形が続くことになる。By the way, there was an unpleasant entry point in the first stage of the lift platform with such a configuration. That is, n7'cm- and I4-1! The pressure inside is 1 hour average VC
are designed to be equal, but this is not a problem at each moment when the transmission shaft (2) is reciprocating. Now, in Fig. 1, assuming that the pressure inside the silkworm tjJ and the pressure inside the flexible positive diaphragm α6J are equal, then the transmission shaft (2) is
cf, the edge 4 of the flexible diaphragm α~ is also displaced upward along with the transmission shaft (2), so the volume of the diaphragm 4 decreases and the internal pressure increases, and the volume of the other yoroya 4 increases. The internal pressure is tested, and as a result, the force due to this differential pressure is applied downward to the readable diaphragm (one line).As a result, the aJ flexible diaphragm has a rhombus shape due to the upward movement of the edge 4, and the above differential pressure. A diamond shape is formed due to the force caused by the force, and the diamond shape continues in the case where the differential pressure becomes zero.

ところが。However.

町涜性隔板ＯＢ＋としてこの様な菱形が十分にＬＩＪ能
なものを作ることは碌しく、菱形が不十分であると。It is difficult to make such a diamond shape as a town sacrificial partition board OB+, but a diamond shape is insufficient.

呈９１１０１　Ｉ２１１間に差圧がｆ４す、そｆ′Ｌに
よって可撓性隔板（至）に大きな応力が生じる。そのた
め、可焼性隔板ａ〜の信頼性が低下し、そｔ″ＬＫ−よ
って装置全体の信頼性が低下すること［なる。A large stress is generated in the flexible diaphragm due to the differential pressure between the 91101 and 1211 f4 and f'L. As a result, the reliability of the combustible partition plates a decreases, and the reliability of the entire device decreases.

本発明は、従来のかかる問題点に鑑み、熱機関の作動流
体と流体機械の作動流体と１１４てる機能の１ｄ頼性會
高めた熱機関で駆動する流体機械を提供することを目的
とする。SUMMARY OF THE INVENTION In view of these conventional problems, it is an object of the present invention to provide a fluid machine driven by a heat engine that has improved reliability in the function of connecting the working fluid of the heat engine and the working fluid of the fluid machine.

本発明は１．このため密閉容器内を、その内壁九封止さ
ｎたｍｌおよび第２の町涜性隔板によって。The present invention consists of 1. For this purpose, the inside of the airtight container is sealed by its inner wall and a second diaphragm.

これら可撓性Ｖｈ板間の第１の閉空間とその両側の第２
と第３の閉空間と九区画し、８１）記第１の閉空間内に
流体機械ｔｌ−配設し、　ＩＩＪ記第２の閉空閣内心熱
機関を配設し１ｇａ記熱慎開と流体機械を連結する伝ｍ
＠を前記ホ１及び＃！Ｌ２のｑ例性隔板を貫通きせて設
けると共にその員ｉ１１部を鈎止し、かっ礒２の閉空間
と第３の閉空間ｔ一連通させ、伝動軸の往復運動にか力
為わらず第１及びｆＡ２の町涜性隔板の谷々の両側の産
肉の圧力が変わらない嫌にした熱機関で駆動さ几る流体
機憧ｔ−提供する。A first closed space between these flexible Vh plates and a second closed space on both sides thereof.
and a third closed space, and 81) A fluid machine tl- is arranged in the first closed space, a heat engine is arranged in the second closed space described in IIJ, and a 1ga heat pump and a fluid are arranged in the second closed space. A transmission linking machines
@ to the above ho1 and #! The diaphragm of L2 is provided by penetrating it, and its member I11 is hooked, so that the closed space of the partition 2 and the third closed space T are communicated with each other, so that no force is applied to the reciprocating movement of the transmission shaft. A fluid machine driven by a heat engine is provided in which the pressure of the meat on both sides of the valleys of the first and fA2 diaphragms does not change.

以下１本発明の一実施例を第２図に基づいて説明すると
、ｔ２Ｂ１Ｆ′ｉ熱嶺関、吻は圧縮遺、ポンプ等の流体
＋ｌｉ械であり、熱機関■）と流体機械−にまたがって
伝動軸＠）が設けら几ている。この伝動細岡は黒磯１Ｊ
Ａ−ノから受ける力によって軸方向に往復通勤、シ、こ
九に匠体慎械例のピストン＃ｊが取付けらｎ。Below, one embodiment of the present invention will be described based on FIG. A transmission shaft (@) is provided. This transmission Hosooka is Kuroiso 1J
Due to the force received from A-no, the piston #j of the craftsmanship model is installed in the axially reciprocating direction.

ている。またＪ流体機械例には、吸入通路−，吸入室μ
ｓｊ、吸入弁に）＋９１Ｑ１．前記ピストンに）両側へ
Ｉ１）ｆ８２１−吐出弁曽四、吐出室９３５１．吐出通
路□ｊが設けらｎてｈる。さらに、熱機関（２８）と流
体機械例との間に仕切厘刷が設けられ、この室側に第１
００Ｊ′佛性隔板（碑が設けらｎている。この第１の町
撓性隔板声）の一方の縁−は、＃記熱機関＠ｊ、流体機
械四。ing. In addition, in the J fluid machine example, suction passage -, suction chamber μ
sj, to the suction valve) +91Q1. to the piston) to both sides I1) f821-discharge valve So4, discharge chamber 9351. A discharge passage □j is provided. Further, a partition plate is provided between the heat engine (28) and the fluid machine example, and a first partition plate is provided on this chamber side.
00J' One edge of the Buddhist diaphragm (a monument is provided.This first flexible diaphragm voice) is #heat-recording engine @j, fluid machine 4.

仕切蚕句及び後述の仕切室−とクッション室陶會一体的
に囲んで外部に対して蕾閉する密閉容＃閣の内壁に封止
されている。・第１の可読性隔板ｔａ８１の他方の縁間
は、伝＃＠轡に封止さｎている。こりして室−ノは第１
の町例性隔敬轡によって、流体機械−側の第１の閉空間
の一部となる蚕倒と熱１奴関■）側の第２の閉空間の一
部となる藁□□□とに連通しない状態で２分されている
。また流体機械−の熱愼闇朔とは反対側に仕切峯四とク
ッション量四がこの順で設けらｎており、仕切蚕四に第
２の可読注隔板（ハ）が設けら几ている。この第２のｈ
Ｊ碗注性隔板の−万の縁−η＃１ｖｆｉ閉容器閣の内壁
に封止さｎ。The partition wall, the partition chamber (described later), and the cushion chamber are integrally enclosed and sealed on the inner wall of the cabinet. - The other edge of the first readable partition plate ta81 is sealed. The room is the first
Due to the distance between the two, the silkworms become part of the first closed space on the fluid machine side, and the straw becomes part of the second closed space on the heat 1 side. It is divided into two parts without communicating with each other. Also, on the opposite side of the fluid machine from the heat sink, the partition ridge 4 and the cushion volume 4 are provided in this order, and the partition ridge 4 is provided with a second readable note partition (c). There is. This second h
The rim of the J-cup septum is sealed to the inner wall of the enclosure.

他方の鍬−は仕切室間を貫通する伝動軸−Ｊに封止さｎ
てｈる０こ？して仕切蚕閾は第２のｏｆ焼性隔板冑によ
って流体機械−側の第１の閉空間の一部となる室−・と
前６己クツシヨン室−と共［請３の閉空間を４１１成す
る嵐−の２つに互？に連通しない様に２分逝几ている。The other hoe is sealed to a transmission shaft J that passes between the partitions.
Tehr0ko? The partition wall is shared with the chamber which becomes part of the first closed space on the side of the fluid machine and the front 6-cushion chamber by means of the second incendiary partition plate. 411 The storm that forms - is it mutual? It has been dead for 2 minutes so that it doesn't communicate.

さらに、蚕□□□と室別とは流通抵抗の小さい均圧雪β
ＩＪで連通され、室−と厘−とｒＬ流通抵抗の小さ込均
圧′ａｖ々で：１！！ｍさｎている〇尚、第２図ＶＣお
いては、伝動軸−は往復運動の鍼１１１１！の中）ｏ征
直にあυ、この位置で呈閣醐−叡Ｊの内圧ははｙ寺しく
なるようになっている。また、欲動＠ゆＪが往Ｕｌ運動
したときには、属調と鋤の体イ貞がＷ反的に増減するが
七の、Ｖ減分かはｙ等しくて尾Ｉ駒と−の体積のＩはほ
とんど変化せずかつ増減分のびＬ体が均圧宮１ｌＪ２ｊ
ｔ−通って移動する球に構成され、呈郵）とｆＡＪｌ＆
’ｃつい王も同様に構成されている０こｆｌは、嶌叩；
鄭）−（鋤と纂１及び第２の口■涜性噛板轡薗を過当な
形状に設ぼｔＬ、＊ｊつ均圧管ｐ１須４の流通抵抗を小
さくすることによってｔｊＪ舵であり、こうすることに
よって伝動軸ゆ）が往虚運動しても第１及び第２の可撓
性隔板１８８１四に大きな応力が働かない様にしている
。また、伝ｍ　４Ｍ１　ｐｔの往復運動によって、クッ
ションＭ１６１内の体積が変化する棟になっており、こ
ｎによって伝動＠（ロ）ノが上方に移動して室四内に侵
入してくるとｎｔｉｔ内の圧力が上昇して臥動軸ｆＪＨ
ｃ償人を阻止する株な力がｍき、逆ＶＣ伝動＠に）が下
方に運動して厘閣内から出て何〈と呈四内の圧力が減少
しＳ伝動軸Ｖ！ｂ）［出て行くのを阻止する・泳な力が
鋤くようになっている。Furthermore, silkworm
Communicated through IJ, with small equalized pressure 'av' of chamber, chamber and rL flow resistance: 1! ! In addition, in Fig. 2 VC, the transmission shaft is the reciprocating needle 1111! (in the middle) As for Seinao, in this position, the internal pressure of Seikakugo-EiJ becomes extremely high. Also, when the drive @YuJ moves forward, the genus tone and the body of the plow increase and decrease in the opposite direction to W, but the V decrement of 7 is equal to y, and the I of the volume of the tail I piece and - is almost unchanged and increases and decreases L body is equal pressure sign 1lJ2j
It consists of a sphere that moves through the t-) and fAJl&
0kofl, which is composed of the same king, is a rock;
(Zheng) - (TjJ rudder by setting the plow and the second mouth part 1 and the 2nd mouth part in an excessive shape tL, *j and reducing the flow resistance of the pressure equalizing pipes p1 and 4, This prevents large stress from acting on the first and second flexible diaphragms 18814 even if the transmission shaft 1881 moves backwards and forwards. In addition, due to the reciprocating motion of the transmission m 4M1 pt, the volume inside the cushion M161 changes. The internal pressure increases and the recumbent axis fJH
The force that prevents the Atonement increases, and the reverse VC transmission (@) moves downward and exits the Rikaku, causing the pressure inside the S transmission shaft to decrease and the S transmission shaft V! b) [Preventing the child from leaving/The swimming force is acting as a plow.

さらに密閉容器閣内の熱＋！ｉ調−）及び呈−（第２の
閉空間）の方には水素、ヘリウム等の熱機関の作動流体
が、流体機械−及び厘−一（鞘１の閉空間）の方には流
体機械−の作動流体がそｎぞＩＬ充填さｎている。熱機
関μｓ）の作動流体は、また均出雷四ｊを弁して室数及
びクッション室四（第３の閉空間）内にも閉じ込められ
ている。便って、熱機関ゆンの作動流体と流体イ賎械例
の作動流体とは、第１の閉空間と第２・第３の閉空間を
分離する第１及びｍ２のｏｒ例性隔板轡Ｍによって互い
に混じり甘うことの無い僚に隔てら几ていることになる
０また。クッション差四と仕切室ｍｔの呈１ＬｊＱ１．
流体慎械朔の至−幻と仕切室間の厘ｆｉＱｌおよび流体
機械例の属菌と仕切嵐Ｃｒ）の室（閑とは、密閉答器曲
と伝動軸に）との間の狭い隙間をヅｒして連通しており
、流体峨偉例の曲記呈βりと鈎とは缶閉容語曲とピスト
ンに）との間の狭い隙間を介して連通している。これら
狭い隙間を介して連通している２つの虱は流体が目出に
出入りできるようになっているので、２つの凰間に差圧
があｎば流体は圧力の萬い嵐から圧力の低い呈の刀へ反
圧がなくなるまで流動し続けるが、この狭い１ゑ曲は流
通抵りＬが大きいので、２室間の時間平均圧力に差がな
くかつ谷厘円の圧力が高い周波式で＆鯛して瞬間す勺に
産圧が生じる様な、Ｉ＃甘にはこの狭い隙間を介してＪ
！！罵している２至間を移動する流体の流血は０と見な
ぜる泣少い様になっている。また、熱機関−ノ内の時間
平均圧力と成体機械例内の時間平均圧力とは１図外装置
で寺しくなる僚に構成さ几ている。Even more heat inside the airtight container! The working fluid of the heat engine, such as hydrogen or helium, is in the i-key and the sho- (second closed space), and the fluid machine is in the fluid machine- and rin-i (the closed space of the sheath 1). - working fluid is filled in each IL. The working fluid of the heat engine μs) is also confined within the chamber number and cushion chamber 4 (third closed space) by means of the equalizer 4j. For convenience, the working fluid of the heat engine and the working fluid of the fluid machine are the first and m2 or example partition plates that separate the first closed space and the second and third closed spaces.轡M also separates them from their colleagues who do not mix with each other. Cushion difference 4 and partition mt presentation 1LjQ1.
The narrow gap between the phantom and the partition chamber of the fluid machine sakuo and the chamber of the genus bacteria of the fluid machine example and the partition storm Cr). They communicate through a narrow gap between the can closure and the piston. The two lice communicate through these narrow gaps, allowing fluid to flow in and out of the gap, so if there is a pressure difference between the two lobes, the fluid will change from a high pressure storm to a low pressure one. The flow continues until there is no counter pressure to the sword, but since the flow resistance L is large in this narrow 1-degree bend, there is no difference in the time average pressure between the two chambers, and the pressure in the Tanirin circle is high. ＆The moment the sea bream catches the sea bream, production pressure is generated in the sea bream.
! ! The amount of blood flowing from the fluid that moves between the two cursing characters seems to be 0, making it seem like there is less crying. Moreover, the time-average pressure inside the heat engine and the time-average pressure inside the finished machine are constructed in a way that is difficult to achieve by a device not shown in the figure.

次に作用を説明すると、熱機関−ｊが及はす力によって
伝ｗＪＪ−８２５）は軸方向［往復運動し、そｎによっ
て伝動軸ゆ）に取付けられたピストン吻も往復運動する
。すると、差四）と箪−の体側ムこのピストン四の往復
運動に伴なって増減する。拘えばピストンに）が第２図
に示す位置から上方に移動して室伜幻内の体積が減少す
ると、室１８１）内の流体機械の作動流体は圧縮さｎて
屋ｖ３１）内の圧力は瑣〃口する〇そして、ＭｉＶ３Ｕ
内の圧力が吐出室−）の圧力より尚くなると吐出弁１８
８１が囲いてｍ　１８Ｉ＋　）りの流体は吐出弁内。Next, to explain the operation, the power exerted by the heat engine causes the transmission wJJ-825) to reciprocate in the axial direction, and thereby the piston nose attached to the transmission shaft also reciprocates. Then, the difference 4) and the side arm of the chest increase or decrease with the reciprocating movement of the piston 4. When the piston (in particular, the piston) moves upward from the position shown in FIG. 〃〃口〇And MiV3U
When the pressure inside becomes higher than the pressure in the discharge chamber -), the discharge valve 18
81 surrounds m 18I+ ) of fluid inside the discharge valve.

吐出産φ）を通って吐出通路茜の力へ込出さｆ’して行
＜Ｏｏｃに伝動軸（ロ）ノが破高照まで行って丁がり始
めると、至圓）内の圧力は下がり始め＊峯＠ＩＩ内の圧
力が肚出處■ＩＦ’Ｓの圧力より低くなると、吐出弁−
が閉じ、吐出室（イ）１か＆ｊｍｌｌｌへの流体の流入
が阻止さｎる。さらに伝動軸（ロ）−が下がって堅いυ
内の圧力が吸入量（至）ｊ内の圧力より上がると、吸入
弁に）ノが開き。When the power transmission shaft (B) reaches the high point and begins to tighten, the pressure inside the outlet begins to decrease. *When the pressure inside Mine@II becomes lower than the pressure in the IF'S, the discharge valve -
is closed, and the flow of fluid into the discharge chamber (A) 1 or 1 is blocked. Furthermore, the transmission shaft (b) is lowered and becomes stiff υ
When the pressure inside rises above the pressure inside the suction amount (to), the suction valve opens.

奴人通路Ｅ、吸入■□□□ｊ、吸入弁−１を追って流体
が室１８１）へ流入する。次に伝動軸例が攻低点へ行っ
て上がり始めると、室ｔ８１１内の圧力は上がり始め１
厘４８１ｊ内の圧力が吸入ｍｖ！８＋内の圧力より、Ｖ
ｉＩＩくなると。The fluid flows into the chamber 181) following the slave passage E, the suction ■□□□j, and the suction valve-1. Next, when the transmission shaft example goes to the attack and low point and starts to rise, the pressure in the chamber t811 starts to rise.
The pressure inside 481j is suction mv! From the pressure within 8+, V
When it comes to III.

吸入弁ｐ＋か閉じて家門から吸入量μｓ、への流出が阻
止さｎる。さらに伝動軸例が上がって透間１内の圧力が
吐出至鄭１内°の圧力より旨くなると吐出弁（８８）が
開き１以上の過程を伝動軸−の往ｉ＆連動に伴なって繰
り返し、その結果として吸入通路ｗ＋’ｔ−通じて流体
讃械−の作動流体を吸入加圧して吐出通路□□□を通じ
て送り出す。また良問についても呈−幻と同様に伝動軸
（ロ））の往復運動に伴なって吸入量μｓｊの流体を吸
入弁１ＢＱＩを通じて室ｔ、１２１内に流入させ、箆四
内の流体を加圧して吐出弁−１吐出室−ノ、吐出通路四
Ｓ）を通じて送り出す。泥って伝動軸例の往復＞ｍ動に
よって流体戟械開の作動流体が吸入通ｆ６割？通じて吸
入さｎ、カロ圧υＬ吐出造路−１，！して吐出さｎる。The suction valve p+ is closed to prevent the flow of the suction amount μs from the gate. When the transmission shaft is further increased and the pressure in the flume 1 becomes higher than the pressure in the discharge space 1, the discharge valve (88) opens and the above steps are repeated as the transmission shaft moves back and forth. As a result, the working fluid of the fluid pump is sucked and pressurized through the suction passage w+'t- and sent out through the discharge passage □□□. In addition, regarding the good question, as with the phantom, the suction amount μsj of fluid is caused to flow into the chambers t and 121 through the suction valve 1BQI, and the fluid in the 4th part is added. Pressurized and sent out through the discharge valve 1 and the discharge chamber 4 and the discharge passage 4S). Mud is the reciprocation of the transmission shaft example> m movement, and the working fluid of the fluid machine opening is suctioned through f60%? Inhalation through n, Calorie pressure υL discharge passage -1,! and discharge it.

この様にして、熱偵関轡は伝動軸吻及び流体儲４戒帥’
ｉｒ’ｒｒシて流体憬識例の作動流体に仕事をする。In this way, the heat detection system is connected to the power transmission shaft and the fluid control system.
ir'rr works on the working fluid of the fluid condition example.

一方１以上のｍ　ｔ’ｔ＝中、熱機関−ノの作動流体と
訊体叙減嘴の作動流体とは、仕切厘−ｊ及び−内に設け
ら几た第１の町浣性噛板轡及びＥＡ２のｏＪ涜注性隔板
で隔てらｎでいる。しかも上述の如く、第２図の鎌に伝
動軸−が往よ連動の県中の中心ａ直にあると＠、嵐明（
ト）１（４）凶の内圧がはソ寺しく、又伝動ｌｌ１ｌＩ
４臣）が往復運動しても室擲）と惧）の体積の沌及び室
（岡と西の体積の和がほとんど変化せずがっ蚕飼とｖＪ
Ｏｌ及び菫（祠と四がそｎぞれ流週ゴ肱抗の小さｈ均圧
！”１５１＋及び茜で連通さｎているため、伝ａ１轡が
往復運動しても第１及び＠２の６ＪＡ性隔板１ａ８１四
には大きな応力は１動かず、こ几によって可涛性噛、阪
の信頼性が同上する。On the other hand, the working fluid of the heat engine and the working fluid of the heat engine are connected to the first mesh plate provided in the partitions and the partitions. It is separated by the oJ injectable septum of 轡 and EA2. Moreover, as mentioned above, if the transmission shaft of the sickle in Figure 2 is located directly at the center a of the prefecture, @Arashimei (
g) 1(4) The internal pressure of evil is so strong that it also transmits
Even if the four ministers) make reciprocating movements, the sum of the volumes of the muro and the west and the sum of the volumes of the muro and the west hardly change.
Ol and Sumire (shrine and 4 are connected by 151+ and Akane, respectively, so even if the transmission a1 moves back and forth, the 1st and @2 6JA diaphragm 1a814 has a large stress that does not move, and the reliability of the flexible mesh and sag is the same as above.

本発明の熱機関で駆動する流体機械によると。According to the fluid machine driven by the heat engine of the present invention.

以上の説明から明らかな低に、熱機関と流体域械ｔ一連
結する伝動軸が往復連動しても、燕磯開の作ｗＪＪ流体
と流体沢械の作動流木とを隔てる第１及び第２の９屍１
：１．隔板に大きな応力が生じないので。It is clear from the above explanation that even if the transmission shaft connected to the heat engine and the fluid flow machine reciprocates, the first and second 9 corpses 1
:1. Because large stress does not occur on the partition plate.

これら可焼性ｐ＃仮の１ｉ！頼注が従来に比べて同上し
。These burnable p# provisional 1i! Raichu is the same as above compared to before.

そのため全体装置である熱機関で駆動される流体機械の
１ｄ粗性が同上する０Therefore, the 1d roughness of the fluid machine driven by the heat engine, which is the entire device, is 0, which is the same as above.

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

第１図は従来例の概１１１Ｉ！構成図、４２図は本発明
の一実施例の概略構成図である〇 閥は熱機関、ｔｌ！４１は流体機械、μｓＪは伝動軸、
に）はピストン、句綱は仕切厘、Ｍは第１０町虜性隔板
。 １４Ｑは缶閉谷器、閣−四国は虚、茜は講２の９脆性隔
板、　１５１ＪＩｌｌは均圧管。 特許出願人代理人 第７図 第２図Figure 1 shows an outline of the conventional example 111I! 42 is a schematic diagram of an embodiment of the present invention. 〇 indicates a heat engine, and tl! 41 is a fluid machine, μsJ is a transmission shaft,
ni) is the piston, haiku-zuna is the partition, and M is the 10th town prisoner partition. 14Q is a can closure, Kaku-Shikoku is empty, Akane is Ko 2's 9 brittle diaphragm, 151JIll is a pressure equalizing pipe. Patent applicant's agent Figure 7 Figure 2

Claims (1)

【特許請求の範囲】[Claims] （１）　苦閉答器内１−．その内壁に封止された第１お
よび第２の可読性隔板によって、これらａＪ涜注隔板間
の第１の閉空間とその両側の第２機械を連結する伝動軸
１Ｑ記第１及び第２の可撓性隔板を貫通させて設けると
共にその貫通部を耐止し、かつ！２の閉窒間と第３の閉
空間を連通させた熱唱鏡開で駆動する流体慎械〇(1) 1-. The first and second readable partitions sealed on the inner wall of the transmission shaft 1Q connect the first closed space between these partitions and the second machines on both sides thereof. A flexible diaphragm is provided through it, and the penetration part is protected, and! A fluid machine driven by a heat exchange mechanism that communicates the second closed space with the third closed space.