JP2013122233A

JP2013122233A - Fluid motor and displacement fluid motor

Info

Publication number: JP2013122233A
Application number: JP2011290760A
Authority: JP
Inventors: Yoshio Abe; 芳男阿部
Original assignee: Individual
Current assignee: Individual
Priority date: 2011-12-10
Filing date: 2011-12-10
Publication date: 2013-06-20

Abstract

PROBLEM TO BE SOLVED: To solve a problem that understanding becomes impossible when there are three or more places that receive fluid pressure.SOLUTION: If a pressure receiving part is formed by forming a single piece from a recessed part of a rotor to a rotor protrusion in contact with a rotor frame, when there are three or more protruding parts of the rotor, forces of the pressure receiving parts are canceled with respect to each other and remain when the pressure receiving part is either an odd piece or an even piece and the pressure receiving part of one rotor is an odd piece, there is rotation in only pressure reception at one place, the pressure receiving part assists the rotation of the other rotor without a rotation force of the even piece via respective gears to a rotary shaft directly connected to the respective rotors, the rotation force is gradually generated in the other rotor as the rotor rotates, and mutual rotation forces assist each other since the rotation force gradually disappears in the one rotor as the rotation force is gradually generated in the other rotor, and the fluid motor or the displacement fluid motor rotates.

Description

圧のある流体を３葉のロータに押し込むと回転する自然科学及び自然現象を発見したWe discovered natural science and natural phenomena that rotate when a fluid with pressure is pushed into a three-leaf rotor.

特願平１０−２９７４８９等がある。Japanese Patent Application No. 10-297489.

使用方法を発見Discover how to use

特許法の中に自然現象を利用したという項目があるのそれの証明に元ずいたものでないと権利としてむずかしいのではないのかなThere is an item that uses a natural phenomenon in the patent law, but it may be difficult as a right unless it is based on proof of it.

２葉のロータより漏れは少ない。Less leakage than the two-leaf rotor.

自然現象ですので自然科学的な計算で出力計算ができる。Since it is a natural phenomenon, output can be calculated by natural scientific calculation.

押込口１よりよ圧力のある流体を押込むとロータの中点２８、２７、２６、３０、２８Ａ、２７Ａ２６Ａ、３０Ａからロータの先端点２、２１、２２、２４２５、２３、２Ａ、２１Ａ、２２Ａ、２４Ａ、２５Ａ、２３Ａまで間を１片とすれば図１で５と６打消されて力は０になるが７があるので回転力がありその時係り合うロータが８と９で打ち消されれて力が０になるので各各のロータに直結して軸を介してロータ側枠外の同じ側に同等のギアを設けて噛み合せる事で１方の回転力で他方のロータの回転を助けてやり次にしだいに図２にロータの凸部の位置になると流体圧が９Ａ、８Ａで打ち消されるが１７Ａに流体圧がかかるので回転力が生まれるが１８Ａと７Ａで打ち消されて回転力がないので上記各各のロータに直結した回転軸を介したギアにより左のロータの力で右のロータを回転を助けてやり互のロータは回転力を助け合いながら回転する。When a fluid having a higher pressure is pushed in from the pushing port 1, the rotor center points 28, 27, 26, 30, 28A, 27A 26A, 30A to the rotor tip points 2, 21, 22, 24 25, 23, 2A, 21A , 22A, 24A, 25A, 23A, if 1 piece, 5 and 6 are canceled out in FIG. 1 and the force becomes 0, but there is 7, so there is rotational force, and the rotors involved at that time are canceled by 8 and 9 Since the force becomes 0, it is directly connected to each rotor, and the same gear is provided on the same side outside the rotor side frame via the shaft to engage with each other, thereby helping the rotation of the other rotor with one rotational force. When the position of the convex portion of the rotor is gradually reached as shown in FIG. 2, the fluid pressure is canceled by 9A and 8A, but the fluid pressure is applied to 17A. A rotating shaft directly connected to each of the above rotors The right rotor is rotated by the power of the left rotor by the intervening gear, and the rotors rotate while helping each other.

各各のロータの凸部がロータ枠と接する数が違う場合はロータの凸部がロータ枠と接する数に比例して各各のロータに直結した回転軸を介した各各のギアの大きさとする。When the number of protrusions of each rotor is different from the number of contact with the rotor frame, the size of each gear via the rotation shaft directly connected to each rotor is proportional to the number of protrusions of the rotor in contact with the rotor frame. To do.

火力発電所に利用Used for thermal power plants

右側のロータに回転力がある図The right rotor has rotational force 左側のロータに回転力がある図Diagram with rotational force on left rotor

（加圧流体）押込口１
ロータ先端点２、２１、２２、２４、２５、２３
図１から回転後のロータ先端点２Ａ、２１Ａ、２２Ａ、２４Ａ、２５Ａ、２３Ａ
ロータ中点２８、２７、２６、３０
図１から回転後のロータ中点２８Ａ、２７Ａ、２６Ａ、３０Ａ
ロータの回転力に影響のある片７、５。６、９、８
図１から回転後ロータの回転力に７Ａ、５Ａ、６Ａ、９Ａ、８Ａ
影響のある片
ロータ枠４、３、４Ａ、３Ａ
排出口１１、１１Ａ
回転軸２０、１９、２０Ａ、１９Ａ
ギヤ１２、１３、１２Ａ、１３Ａ(Pressurized fluid) inlet 1
Rotor tip point 2, 21, 22, 24, 25, 23
Rotor tip point 2A, 21A, 22A, 24A, 25A, 23A after rotation from FIG.
Rotor midpoint 28, 27, 26, 30
Rotor midpoints 28A, 27A, 26A, 30A after rotation from FIG.
Pieces affecting the rotational force of the rotor 7, 5, 6, 9, 8
From Fig. 1, the rotational force of the rotor after rotation is 7A, 5A, 6A, 9A, 8A
Influenced single rotor frame 4, 3, 4A, 3A
Outlet 11, 11A
Rotating shaft 20, 19, 20A, 19A
Gear 12, 13, 12A, 13A

Claims

When the pressure receiving part of one rotor of the fluid motor is rare due to the fluid pressurized from the push-in port (1), since there is a large number of pressure receiving parts in one place, there is an even number of pressure receiving parts of the other rotor at that time. Since the rotating shafts (19), (20), (19A) and (20A) provided on the respective rotors are stable and do not rotate, they are proportional to the number of contact between the rotor frames and the rotors. When the fluid passes through the fluid motor, the pressurized fluid turns into a low-pressure fluid and exits from the discharge port of the rotor frame. A fluid motor and a positive displacement fluid motor characterized in that the other rotor does not have a rotational force but the rotational force gradually increases, so that the rotational force gradually increases, so that they rotate while supporting each other.