WO2002041682A2 - Moteur a rotor et pompe a rotor - Google Patents

Moteur a rotor et pompe a rotor Download PDF

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Publication number
WO2002041682A2
WO2002041682A2 PCT/CN2001/001560 CN0101560W WO0241682A2 WO 2002041682 A2 WO2002041682 A2 WO 2002041682A2 CN 0101560 W CN0101560 W CN 0101560W WO 0241682 A2 WO0241682 A2 WO 0241682A2
Authority
WO
WIPO (PCT)
Prior art keywords
swivel
runner
wall surface
pump
engine
Prior art date
Application number
PCT/CN2001/001560
Other languages
English (en)
Chinese (zh)
Inventor
Chenglin Zhang
Original Assignee
Chenglin Zhang
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 Chenglin Zhang filed Critical Chenglin Zhang
Priority to AU2002221487A priority Critical patent/AU2002221487A1/en
Publication of WO2002041682A2 publication Critical patent/WO2002041682A2/fr

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01CROTARY-PISTON OR OSCILLATING-PISTON MACHINES OR ENGINES
    • F01C1/00Rotary-piston machines or engines
    • F01C1/30Rotary-piston machines or engines having the characteristics covered by two or more groups F01C1/02, F01C1/08, F01C1/22, F01C1/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
    • F01C1/34Rotary-piston machines or engines having the characteristics covered by two or more groups F01C1/02, F01C1/08, F01C1/22, F01C1/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F01C1/08 or F01C1/22 and relative reciprocation between the co-operating members
    • F01C1/344Rotary-piston machines or engines having the characteristics covered by two or more groups F01C1/02, F01C1/08, F01C1/22, F01C1/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F01C1/08 or F01C1/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the inner member

Definitions

  • the invention belongs to the field of machinery manufacturing, and particularly relates to a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), and an internal combustion type composed of a runner or a swivel.
  • the engine (or prime mover) is a commonly used power machine.
  • the prior art close to the runner (or swivel) engine (or prime mover) in the present invention is a "crankless piston-type rotary engine" ( The Chinese Patent Application Publication No. CN1105736A published on July 26, 1995).
  • there are two types of work principle of the engine One is that the working material enters the work cavity from the inlet, pushes the moving plug on the rotor, rotates the rotor, and the working material after work is discharged from the outlet;
  • the on-off valve installed at the inlet is opened to allow a certain amount of flammable working substance to enter the work chamber.
  • the on-off valve When the entered amount of flammable working substance reaches the specified amount, the on-off valve is closed and the ignition is instantaneous, so that the combustible working substance is burned to perform work and push the rotor
  • the moving plug rotates the rotor, and the exhaust gas after work is discharged from the outlet.
  • the moving plug is fixed on the rotor or / the fixed plug is fixed on the stator, or moves linearly, or performs a fan-shaped opening and closing movement around the shaft, or moves linearly, or
  • the moving plug or fixed stopper that makes a fan-shaped opening and closing movement around the shaft is pushed or pushed by the spring force or magnetic attraction or centrifugal force or the pressure of the working substance at the inlet or the two thrust plugs connected together.
  • the published application document also provides that the working cavity surrounded by the rotor and the stator can be divided into two parts: a working cavity and a power output cavity, where the power output cavity is compressed air or / flammable Donor from the outlet to the high pressure gas storage tank outside the machine, and then supplied to the inlet of the work chamber.
  • the necessary technical features for forming a sealed working cavity and the necessary mechanical power output are lacking. It requires technical features to make its purpose difficult to achieve; linear motion moving plugs or / fixing plugs which are pushed out by spring force or / magnetic attraction force. Because these forces have time characteristics, moving plugs // fixing plugs must also bear work material.
  • Embodiment 10 provides a two-plug structure integrally mounted on the rotor, which can perform linear reciprocating motion in the rotor. They rotate with the rotor and receive the inner wall of the stator by a moving plug. After extrusion, another moving plug is directly pushed out. The length of the two connected moving plugs is fixed. The rotor axis and the center of the inner wall of the stator are not at the same place.
  • the outer wall of the rotor is in contact with the fixed plug side on the inner wall of the stator.
  • the rotor is Rotating on its own axis, this embodiment 10 does not provide the shape of the inner wall of the stator, so that this embodiment cannot achieve the intended purpose. If the cross-sectional shape of the inner wall of the stator is circular, then when the rotor rotates, the moving plug cannot be pushed out.
  • the inner wall of the stator is in contact, so that there is a gap in the formed working cavity, especially when the moving plug is turned to the straight line where the stator shaft center and the inner wall of the rotor are connected. When the gap reaches the maximum, the work efficiency will be reduced.
  • a fluid pump (or heat pump or vacuum pump) is a commonly used machine.
  • the prior art that is close to the rotor (or swivel) pump (or heat pump or vacuum pump) of the present invention is a "crankless piston rotary engine” (Chinese Patent Application Publication No. N1105736A published on July 26, 1995), “An Eccentric Vane Pump” (Chinese Utility Model Patent Specification CN2204343Y published on August 2, 1995) "Plate piston type suction pump” (Chinese publication patent application publication No. CN1131728A published on September 25, 1996) “Self-priming pump suction and discharge device” (Announcement No. published on February 26, 1997 It is CN2248256Y's Chinese Utility Model Patent Specification).
  • the working principle of the pump is that the moving plug rotates with the rotor and pressurizes the fluid that enters the working chamber from the inlet to flow out from the outlet. It can move linearly or / fan-shaped around the shaft.
  • the plug or / plug is pushed or pushed away by the spring force or / magnetic attraction force or / moving plug to push each other, and forms a working cavity with the rotor and the stator;
  • the public document of "An Eccentric Vane Pump” It is disclosed that the rotor axis and the center of the pump body are not at the same place.
  • the rotor rotates on its own axis.
  • the rotor is equipped with at least two blades.
  • the blades can expand and contract.
  • the two symmetrically installed blades are connected by springs. When the rotor rotates, the two The symmetrical blades are pushed and extended by each other through the spring, which can reduce the friction of the inner wall of the vane pump body.
  • a cylindrical hole is opened at one end of the vane, and a roller can be rolled in the inner wall of the pump body.
  • the working mode is that the liquid enters from the inlet.
  • the pump body is pressed by the protruding blades on the rotating rotor and flows out from the outlet.
  • plate piston two-way sucking pump Disclosed is the rotor axis and the pump body The center of the wall is at the same place.
  • the shape of the inner wall of the pump body is circular, and the upper and lower symmetrical parts are cut.
  • the outer circle of the rotor is equidistantly equipped with four plate piston bodies, each with a spring top spring.
  • the plate piston body consists of When the two pieces are combined, the two pieces can slide with each other, and each piece is spring-loaded.
  • the piston body is always in contact with the inner wall of the pump body.
  • Lubricating oil injection hole for injecting lubricating oil to the friction part.
  • the working method is that the liquid flows from the inlet.
  • the plate piston body pushed out by the spring force on the rotating rotor is compressed and flows out of the outlet.
  • the rotor axis is not at the same center as the inner wall of the pump body
  • There is a blade groove on the rotor. The thickness of the groove is greater than the thickness of the blade. After the blade is inserted, a hole is formed. The blade is ejected by the spring in the groove to make the blade contact the inner wall of the pump.
  • the formula is that the liquid enters the pump body from the inlet and is pressed by the blades protruding from the rotating rotor.
  • extension speed can be increased will affect the time that the blade extends to the inner wall of the pump body. According to the relationship between time and the angular velocity of the rotor, the larger the rotor speed, the smaller the effective volume when the pump is operating, which affects the efficiency of the pump.
  • An object of the present invention is to provide a fluid runner composed of a runner or a rotating body with a complete structure.
  • Fuel is compressed to ignite or / is ignited and can be continuously fed into fuel. Fuel is also continuously burned.
  • the rotary wheel (or swivel) pump (or heat pump or vacuum pump) manufactured by it has small mechanical loss, small mechanical friction, flexible rotation, and high efficiency. It can quickly form or / synchronously form an effective compression cavity to ensure work efficiency.
  • a pump or / can pump or / compress a liquid or / gas or / powder or / thick fluid.
  • Fluid runner (or swivel) engines are divided into only one work unit and at least two work units.
  • a fluid runner (or swivel) engine (or prime mover) with only one work unit it includes a runner or swivel, casing or housing, end cover, power output shaft or power output sleeve, Plate or / rotating plate or / stopper or / rotating block or / at least two of the above, spring or / shrap or / permanent magnet or / synchronous mechanical transmission mechanism or / at least two of the above
  • the wheel is constituted or / consisting of a swivel
  • the housing or housing is constituted by a chassis or / consisting of a housing
  • the rotor or / rotation is installed in the housing or / out of the housing or / in the housing or Outside the casing
  • the runner or the rotor can rotate to form a work unit, which is installed on the casing or on the housing or on the runner or on the
  • Each component is provided with at least one baffle or / rotating plate or / stopper or / rotating block or / at least one of the above two components, each baffle or / rotating
  • the plate or / stop or / turn block is at least one spring force or / elastic core force or / synchronized ⁇ ⁇ transmission force or / synchronous electromagnetic transmission force or / synchronized pneumatic transmission force / Synchronous hydraulic transmission force or / Pushed or pushed away by the combined force of at least two of the above forces, by the thrust of the sliding wall surface on the casing or / housing or / The thrust of the sliding wall surface on the runner or / the swing body or / The thrust of the sliding wall surface on the end cover is / by at least one spring force or / spring force or / magnetic force // centrifugal force // synchronous mechanical transmission force // synchronous electromagnetic transmission force // synchronous pneumatic transmission force // synchronous hydraulic transmission force or / Pushed in or / closed by the combined force of at least two of the above forces, the two
  • a fluid runner (or swivel) engine (or prime mover) with at least two work units
  • the swivel is composed of one runner or / swivel or / is composed of at least two serially connected or / fixed serially connected or / fixedly connected swivel or / swivel or / is composed of at least two sets
  • the rotor or / turn body is formed or / is constituted by a rotor or / turn body combined with at least two of the above structural relationships, and the housing or / housing is constituted by one housing or / housing or
  • each baffle or / rotary plate or / stopper or / rotary block is at least one spring force or / shrap force or / magnetic force or / mutual thrust or / self thrust or / work fluid pressure Or / centrifugal force or / synchronous mechanical transmission
  • the combined force of at least two of the above forces is pushed or pushed
  • the outlet is discharged, and the power output shaft or the power output sleeve is connected with the runner or the swivel as a whole or is fixedly connected or fixedly installed, and extends out of the one end cover or the both end cover or the runner.
  • the energy-containing fluid enters the power cavity formed in each work unit from each inlet to perform work, so that the runner or / rotation body rotates, and the power is output to the outside through the power output shaft or / power output sleeve.
  • a wind runner (or runner) that works by wind can be made.
  • Body or prime mover
  • the outlet of the wind collecting device is directly connected with each inlet of the wind turbine (or swivel) engine (primary mover) or / through at least one peripheral channel, they are fixed Connected or / actively connected, they are hermetically connected or / Controllable leak tight communication.
  • a wind collecting device capable of aligning with the wind direction
  • an airflow with energy is formed, and the work is performed from the inlet of the wind turbine (or swivel) engine (or prime mover) into the power cavity in the machine to make the rotor or
  • the body rotates to output power through the power output shaft or / power output sleeve.
  • an internal combustion runner can be made (Or swivel) engine, the outlet of the gas supply device is directly connected with each inlet of the internal combustion runner (or swivel) engine or / via at least one peripheral channel, which are fixed or / movable They are hermetically connected or / controllable hermetically connected.
  • the pressured air or air-fuel mixture from the gas supply device directly enters the power chamber and burns with fuel or / is ignited to generate thermal gas to perform work in the power chamber or / After combusting or being ignited with fuel at the inlet of the power cavity or in the peripheral channel to generate heat gas, it enters the power cavity of the internal combustion runner (or swivel) engine to perform work.
  • At least one burner or / at least one fuel supply is fixedly installed on the isolation plate or / on the gas supply device or / at the inlet of the gas supply device // the inlet extension channel or / the outlet or / the outlet peripheral channel Or / at least one set of fuel feeder igniter or / at least one igniter or / at least one of each of at least two of the foregoing.
  • the air supply device is a device or machine that can compress and discharge or / can pump out air or air-fuel mixture.
  • the air or air-fuel mixture from the air supply device enters the internal combustion runner (or Body) in the engine and burns or is ignited in the engine to generate heat gas to do work in the power chamber or / € A power chamber to make the runner or the rotor rotate, through the power output shaft or the power output sleeve to External output power.
  • the pressured air or air-fuel mixture from the gas supply device enters the combustion chamber outside the machine and burns or / After being ignited to generate thermal gas, it enters the power chamber of the external combustion runner (or swivel) engine to perform work.
  • At least one burner or / at least one fuel is fixedly installed on the off-board combustion chamber or / on the gas supply device or / at the inlet of the gas supply device / or at the inlet extension channel or at the outlet or at the outlet outside channel
  • the air supply device is a device or machine that can compress or / pump out air or air-fuel mixture.
  • the air or air-fuel mixture from the air supply device enters the outer combustion chamber from the inlet of the outer combustion chamber.
  • Combustion or / ignition generates thermal gas, and then the thermal gas flows from the outlet of the external combustion chamber to the inlet of the external combustion runner (or swivel) engine, and enters the power chamber inside the machine to perform work, so that the runner or The body rotates to output power through a power output shaft or a power output sleeve.
  • an internal combustion runner (or swivel) can be made )
  • the engine in the same working unit of the internal combustion rotary (or swivel) engine, the runner or / swivel rotates once, and at least one compression chamber is formed, and the air or air-fuel mixture compressed by the compression chamber is The work unit is pushed directly into the power chamber or / by the runner or / by the swivel or / in the housing or / in the housing or / in the end cover or / in the isolation plate or / in the baffle or in the stop At least one channel in the middle or / rotary plate or / block or / is supplied to the power chamber via at least one peripheral channel and fuel is burned or / is ignited to generate thermal gas to perform work in the power chamber // in the above-mentioned channel // At the inlet of the power chamber,
  • This internal combustion runner (or swivel) engine can complete the four processes of intake, compression, work, and exhaust in the same work unit. Air and fuel are burned or / ignited in the power chamber to generate thermal gas to perform work. Or / combusted in the machine or / is ignited to generate thermal gas directly into the power chamber to do work, make the runner or / rotate the body, and output power through the power output shaft or / power output sleeve.
  • an external combustion type can be made.
  • a runner (or swivel) engine in the same working unit of the external combustion runner (or swivel) engine, the runner or / swivel rotates once, and at least one compression cavity is formed. Air or air-fuel mixture is supplied to the external combustion chamber through at least one peripheral channel and the fuel is burned or / ignited, and the generated thermal gas is supplied to the external combustion runner (or The power chamber of the engine does work.
  • At least one burner or / at least one fuel feeder or / at least one set of fuel feeder igniter or / at least one igniter is fixedly installed on the disk or / on the inlet extension channel of the compression cavity or / on the peripheral channel of the outlet. Or / at least one of each of at least two of the above.
  • This external combustion runner (or swivel) engine can complete the four processes of intake, compression, work, and exhaust in the same work unit, but the process of fuel and air combustion generating heat gas is burned outside the machine Performed indoors, the hot gas enters the power chamber from the combustion chamber outside the machine to perform work, which causes the runner or / rotation body to rotate and output power through the power output shaft or / power output sleeve.
  • a fluid runner (or swivel) pump composed of a runner or a swivel is also provided in the present invention (Or heat pump or vacuum pump), its structure is basically the same as the structure of the two fluid runner (or swivel) engines (or prime movers) described above, and works in the opposite way, but both perform energy conversion.
  • fluid runner (or swivel) pump (or heat pump or vacuum pump) is also divided into only one compression unit and at least two compression units ;
  • a fluid runner (or swivel) pump (or heat pump or vacuum pump) with only one compression unit it includes a runner or / rotation, pump casing, end cover, power input shaft or / power input / sleeve, baffle Or / turn plate or / stop or / turn block or / at least two of the above, spring or / shrap or / permanent magnet
  • the runner or / the swivel is constituted by a runner or / is constituted by a swivel
  • the pump housing or / the housing is constituted by a pump housing or / is constituted by a housing
  • the rotor or the rotor is installed in the pump housing or the pump housing or the housing or the housing.
  • the rotor or the rotor can rotate to form a compression unit on the rotor or the rotor or the pump.
  • At least one baffle or / rotary plate or / stopper or / rotary block or / upper is provided on the shell or / end cover or / on each of at least two of the above components which can be reciprocated or / reciprocated.
  • At least one of each of the at least two components, each baffle or / rotary plate or / stopper or / rotary block is at least one spring force or / shrap force or / magnetic force or / mutual thrust or / own thrust or /
  • the force of the compressed suction fluid or / centrifugal force or / synchronous mechanical transmission force or / synchronous electromagnetic transmission force or / synchronous pneumatic transmission force or / synchronous hydraulic transmission force or / the combined force of at least two of the above forces is pushed or pushed away by the pump Thrust on sliding wall surface on shell or / shell or on sliding wall surface on runner or / swing or sliding wall on end cover Or thrust / or by at least one spring force / forces or shrapnel / or magnetic
  • the power input shaft or the power input sleeve is connected to the rotor or the rotor. It is an integral or / fixed connection or / fixed installation, and extends out of the one end cover or / the two end covers or / on the runner or / on the swivel.
  • Fluid runner (or swivel) pumps (or heat pumps or vacuum pumps) with at least two compression units include runners or / rotations, pump housings // housings, end covers, isolation discs, power input shafts, or / Power input sleeve, baffle or / rotary plate or / stop block or / rotary block or / at least two kinds of springs or springs or springs or permanent magnets or step hydraulic transmission or at least two of the above, or / Swiveling consists of one runner or / consists of one turning or / consists of at least two serially connected or / fixed serially connected or / fixed serially installed runners or / swivels or / consists of at least Two sets of rotating wheels or / rotating bodies or / composed of at least two structural relationships of the above-mentioned combination of rotating wheels or / rotating bodies, the pump housing or / housing is composed of one pump housing or / consisting of one housing Or / consists of at least two pump casings or /
  • the resultant force of the force is pushed or pushed away, by the thrust of the sliding wall surface on the pump casing or / the housing, or by the thrust of the sliding wall surface on the runner or / rotating body, or / the thrust of the sliding wall surface on the end cover Or / by the thrust of the sliding wall surface on the isolation disc or / by at least one spring force or / shrap force or / magnetic force or /
  • All ports between the swivel and the pump housing or / housing are closed by end caps, the openings between two parallel adjacent compression units are closed by at least one isolation disc, and the end cap is connected with the runner or / swivel or /
  • the pump housing or / housing is connected as a whole or / fixed connection or / fixed installation, the isolation disc is connected with the rotor or / swivel or / pump housing or / housing is integrated or / fixed connection or / fixed installation, in
  • Each compression unit has at least one inlet on the pump housing or / on the housing or / on the rotor or / on the swivel or / on the end cover or / on the isolation disc or / at least one of each of the above two components Inlet, at least one outlet on the pump casing or / the casing or / the rotor or / the rotor or / the end cover or / the isolation disc of each compression unit There is at least one outlet, and the rot
  • Each compression unit forms at least one closed compression cavity that communicates only with the outlet.
  • the power input shaft or / power input sleeve is connected to the rotor or / rotation as a whole or / Fixed connection or / fixed installation, and extend out of one end cover or / extend both end cover or / On the runner or / on the swivel.
  • a combined runner (or swivel) pump (or heat pump or vacuum pump) can be made; It is formed by combining at least two of the one kind of rotor (or swivel) pumps or / by combining at least one of the two kinds of rotary (or swivel) pumps, and the spatial position relationship of the combination is serial or / Parallel or / Phase set or / A combination of at least two of the above structural relationships, each of their two pump housings or / housings or / mutually connected as one or / fixed connection or / fixed installation or / opposed Fixed installation, between every two wheels or / rotations or / to each other They are connected as a whole or / fixed connection or / fixed installation or / movably connected or not connected to each other via a linkage mechanism.
  • Their power input methods are separate input or / partial combination input or / all combination input
  • the casings or / pump casings or / the casings are / are connected to each other or / fixedly connected or / fixedly installed or / relatively fixedly installed, every two of their wheels or / rotated bodies or / mutually They are connected as a whole or / fixed connection or / fixed installation
  • the air or air-fuel mixture from the compression chamber passes through the casing or / the pump casing. Or / in the housing or / in the runner or / in the swivel or / in the isolation tray or / end cap At least one channel in the baffle or in the block or in the turn plate or in the turn block or / is supplied to the power chamber through at least one peripheral channel to burn with fuel or / is ignited to generate thermal gas in the power chamber Work is performed either in the above-mentioned passage or at the inlet of the power cavity, after being burned with fuel or / ignited to generate heat gas, and entering the power cavity of the internal combustion runner (or swivel) engine to perform work.
  • At least one burner or / at least one is fixedly installed on or on the runner or on the swivel or on the end cover or on the isolation disk or on the peripheral channel at the outlet of the compression cavity or at the extension channel at the inlet of the compression cavity.
  • each power chamber of the engine does work.
  • On the outside combustion chamber or / on the compression chamber or / on the pump casing or / the casing or / the runner or / the rotor or / the end cover or / isolated at the inlet or / the outlet of the compression chamber At least one burner or / at least one fuel feeder or / at least one set of fuel feeder igniter or / at least one igniter is fixedly installed on the disk or / on the inlet extension channel of the compression cavity or / on the peripheral channel of the outlet. Or / at least one of each of the at least two.
  • thermodynamic gas can directly enter or / through at least one peripheral channel into each power chamber of the internal combustion runner (or swivel) engine to perform work.
  • At least one non-return valve or / one-way pressure valve or / control valve is fixedly installed on the passage from the outside combustion chamber to the power chamber; at least one burner or / at least one fuel feeder is fixedly installed on the outside combustion chamber Or / at least one set of fuel supply igniter or / at least one igniter or / at least one of each of at least two of the above.
  • baffle or / rotary plate or / stopper or / rotary block on / on the pump housing or / on the housing or / on the end cover or / on the isolation disc can be axial or / oblique axial or / radial or / The oblique radial reciprocating linear movement or / reciprocating arc movement or / reciprocating fan rotation or / reciprocating bidirectional rotation.
  • the cross-sectional shape of the inner wall surface or the outer wall surface or the inner and outer wall surface of the housing and the baffle plate or the rotating plate or the stopper or the rotating block is circular or oval or semi-ellipsoidal or Partially oval or circular / non-circular ring // circle with outer wattle or / circle with inner wattle or / circle with tangent or / circle with outer corner or / with inner angle Body circular or / circle with concave portion or / circle with convex portion or / eccentric equal diameter ring or / eccentric equidistant ring or / hyperbolic ring or / at least three sides Contours.
  • the cross-sectional shape of the inner wall surface or outer wall surface of the runner or / turn body or / chassis or / pump housing or / housing and baffle or / turn plate or / stop or / slide is directly processed / Swivel or / chassis or / pump casing or / housing formed or / fixedly connected or / fixedly mounted on the runner or / rotation or / chassis or / pump casing On or / on the housing.
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • runner or swivel
  • rotator or a rotator cone
  • Body or / Rotary angle body or / Vortex body are integrally connected or fixedly installed or installed.
  • connection on the inside surface of the end cap or on the one end or both ends of the wheel or the swivel or on the one end or both ends of the isolation disc or the fixed connection or the fixed Rotary wheel (or swivel) engine or / rotary (or swivel) pump of the rotating wave body or / slope body or / spinning slope body or / swivel body, its runner or / rotor Can rotate in both directions.
  • the rotating wave body or / rotating slope body // rotating cone slope body // rotating angle body // rotating body on the runner or / rotating body or / end cover or / isolating disk is a direct processing runner or /
  • the swivel or / end cap or / isolated disc is formed or / is the component of the corresponding shape is fixedly connected or / fixedly installed on the runner or / rotation or / end cap or / isolated disc.
  • the baffle or / rotary plate or / stopper or / rotary block works
  • the radial or / axial shape of the force bearing surface is straight or / outer arc or / inner arc or / toothed or / slotted or / outer angled / inner angled or / mesh or / above A combination of at least two shapes.
  • the cut shape is straight or / outer arc or / inner arc or / toothed or / slotted or / slanted or / I-shaped or / cross-shaped or / cross-shaped or / both
  • Dovetail shape // outer angle or / inner angle or / a combination of at least two of the above.
  • thermometer sprayers or / at least one thermometer or / gas smoke meter or / gas pH meter or / at least one of each of at least two of the above There is at least one water channel in the temperature measuring sprinkler or / the water sprinkler.
  • the water channel is straight or / curved or / slanted.
  • the temperature measuring sprinkler or / water sprinkler can be controlled to continuously inject water or / Can be intermittently sprayed with water.
  • the shape of the water spray from the temperature measuring sprinkler or the outlet of the sprinkler is a strip shape or a spiral shape or a rotary shape or a circular shape or an oval shape or a circular shape or an oval shape or a fan shape.
  • the temperature measuring sprinkler or / the sprinkler sprays alkaline water or / acid water or / neutral water.
  • the temperature measuring element in the temperature measuring sprinkler or / the temperature measuring device is at least one liquid thermometer or / at least one metal thermometer or / at least one thermal resistance or / at least one thermocouple or / at least one temperature transmission Or at least one of each of the at least two of the above.
  • the heat sink or / radiating fin is connected with the rotor or the rotor as a whole or / fixed connection or / fixed installation, inside the rotor or / outside the rotor or / inside the rotor or / outside the rotor Rotate synchronously.
  • the inlet of the radiator tube communicates with the outside world or with the openings on the end cover or the isolation plate or with the return and return chamber in the end cover or the isolation plate.
  • the outlet of the radiator tube communicates with the outside or / and
  • the openings in the cover or / isolation plate communicate with each other or / with the exit and return chambers in the end cover or / isolation plate.
  • the heat sink connected to the runner or the swivel body or fixedly connected or fixed is a scroll or a straight piece.
  • the axial flow compression cylinder is connected with the rotating wheel or / rotating body as a whole or / fixed connection or / fixed installation, inside the rotating wheel or / outside the rotating wheel Or / synchronized rotation within the body or / out of the body.
  • the inlet of the axial-flow compression cylinder is in communication with the outside world or through the filter, or in the end cover or on the isolation plate, or in the end cover or the inlet and return chamber in the isolation plate.
  • the outlet of the compression cylinder is in communication with the inlet of the compression chamber, or in the end cover or in the isolation plate, or in the end cover or in the isolation chamber.
  • the inlet and outlet are in the runner.
  • At least one channel in / or in the swivel or / in the housing or / in the pump housing or / in the housing or / in the end cover or / in the isolation plate or / the peripheral device is connected.
  • There are some scrolls or / straight pieces connected in the axial compression cylinder as a whole or / fixed connection or / fixed installation.
  • runner (or swivel) engines or prime movers) or / rotor (or swivel) pumps (or heat pumps or vacuum pumps)
  • runner (or swivel) engines or prime movers
  • / rotor (or swivel) pump or heat pump or vacuum pump
  • There are at least one heat dissipation hole in the tray and one kind of fluid can flow through the heat dissipation holes or at least two kinds of fluid can flow respectively.
  • At least one set of balls or / at least one set of rollers, or at least one set of rollers is installed between one side or / two sides or / all sides of the force bearing surface of the baffle or / stopper and the installed moving groove.
  • the column is installed on the moving groove or / is installed on the baffle or / block or both.
  • At least one set of balls or / at least one set of rollers can be installed on the sliding end or / the sliding surface of the baffle or / rotary plate or / stopper or / rotary block.
  • various revolving (or swivel) engines or prime movers) or / revolver (or swivel) pumps (or heat pumps or vacuum pumps)
  • the block or / rotary block is sealed during sliding with the housing or / rotary body or / end cover or / isolating disc.
  • the baffle or / rotary plate or / stopper or / rotary block is mounted on the sliding end or / sliding surface.
  • At least one strip body or / strip plate capable of reciprocating and retracting is provided, and the strip body or / strip plate is ejected by at least one spring or / by at least one spring sheet or / by at least one of each of the two above.
  • baffle or / rotary plate or / stopper or / rotary block is installed or / rotational or / chassis or / pump casing or / case or end cover or / isolated
  • the housing or / end cover or / isolator plate is connected as a whole or / fixed connection or / fixed installation, the straight groove or / arc groove or / fan groove is opened on the cylinder or / arc On bars or / curved blocks.
  • At least one ball or at least one roller that can roll can be installed on each of the arc grooves.
  • the fixed or / movable rotating shafts on each turntable or / turn block are ejected by at least one spring or / by at least one shrapnel or / by at least one of each of the above two or / each turntable or /
  • the turning block is directly ejected by at least one spring or / by at least one shrapnel or / by at least one of each of the two above.
  • At least one bush is installed between each spring or spring sheet and the fixed or movable shaft on the rotating plate or the rotating block or between each spring or spring sheet and the rotating plate or / the rotating block At least one bearing bush.
  • lubricating oil storage chamber in the casing or / the pump casing or / the housing or / the runner or / the swivel or / the end cover or / the isolation plate, the lubricating oil in the storage chamber can be injected into the sliding Lubrication grooves or / lubrication holes on the wall.
  • lubricating oil groove on the casing or / pump housing or / casing or / rotating wheel or / rotating body or / end cover or / isolating disk which can inject lubricating oil to the sliding wall surface or / Lubrication hole or / injection hole capable of injecting lubricating oil into the storage chamber.
  • the seal is an annular groove or / non-annular groove filled with sealing oil or / an annular groove or / non-annular groove filled with sealing oil and an oil-absorbing sealing material or / is filled according to the shape of the installation location.
  • the groove of the sealing oil or / the groove filled with the sealing oil and equipped with the oil-absorbing sealing material or / is a ring or a sleeve or a sleeve or a strip or a piece or a sheet made of a wear-resistant and heat-resistant sealing material corresponding to the shape of the installation location. Shaped or unformed.
  • sealing oil storage chamber in the runner or / rotating body // machine housing or / pump housing // housing or / end cover or / isolating disk
  • the sealing oil in the storage chamber can be injected into the seal Oil tank.
  • There is at least one on the runner or / rotating body or / the casing or / the pump casing or / the housing or / the end cover or / the isolation disc can inject the sealing oil into the sealing oil groove or / can inject the sealing oil to Fill hole in storage compartment.
  • the sliding surface of the rotating shaft or / bearing pad or / rotary bearing pad has angled or / curved lines or / spiral lines.
  • the casing or / pump housing or / the housing or / the rotor or / the swivel or / the end cover or / the isolator disk that can inject lubricant to the ball or / the roller or / At the bearing or / can be injected into the injection hole of the storage chamber.
  • At least one pair of oil can be injected into the ball or / roller on the casing or / the pump casing or / the housing or / the rotor or / the swivel or / the end cover or / the isolation disk Or / injection and outflow holes at the bearing.
  • the synchronous mechanical transmission mechanism includes at least one transmission rod or / including at least one transmission body and at least one transmission rod or / at least one transmission member.
  • the transmission rod or / the transmission member is installed on the rotating wheel or / Swivel or / Cover or / Pump housing or / Cover or / End cover or / Isolation plate, can reciprocate or / reciprocate or / rotate, baffle or / rotary plate or / stop
  • the block or / turn block is driven by at least one transmission rod or transmission member, which is connected as a whole or / movably connected or / direct contact or / spring contact or / rotation contact, and the two transmission rods are movable.
  • connection or / direct contact or / spring contact the connection between the transmission rod and the transmission part is / moving Contacts.
  • various revolving (or swivel) engines or prime movers) or / revolver (or swivel) pumps (or heat pumps or vacuum pumps)
  • the frequency of reciprocating or / reciprocating rotation of the block is synchronized with the speed of the rotor or the rotor.
  • a synchronous electromagnetic transmission mechanism is installed therein.
  • the synchronous electromagnetic transmission mechanism includes at least one set of coil cores for generating electromagnetic force and at least one synchronously controlled power switch or / at least one directly driven by a transmission body or / transmitted by a transmission rod or / transmitted by a transmission member.
  • the power switch of the transmission, the coil core is fixedly mounted on the casing or / the pump casing or / the casing or the / rotor or the swivel or the end cover or the isolation disk.
  • the core directly drives or / Driven by a transmission rod or / Driven by a transmission member or / Turn plate or / Stop or / Turn block.
  • a pneumatic synchronous transmission mechanism can also be used to drive the baffle or / rotary plate Or / stop or / block
  • the pneumatic synchronous transmission mechanism includes at least one set of cylinder piston, air inlet and outlet pipe and at least one synchronous electromagnetic control valve or / is directly driven by at least one transmission body or / via a transmission rod or / via a transmission member Control valve
  • the cylinder is fixedly mounted on the casing or / pump casing or / the casing or / the runner or / the swivel or / the end cover or / the isolation disk
  • the piston is directly driven or / via the transmission rod Drive or / drive the baffle or / turn plate or / stop or / turn block via the drive.
  • hydraulic synchronous transmission mechanisms can also be used to drive the baffles or / rotary plates Or / block or / block
  • the hydraulic synchronous transmission mechanism includes at least one set of hydraulic cylinder pistons, liquid inlet and outlet pipes and at least one synchronous electromagnetic control valve or / is directly driven by at least one transmission body or / via a transmission rod or / via a transmission
  • the control valve of the component transmission, the hydraulic cylinder is fixedly installed on the casing or / the pump casing or / the casing or the / rotor or the swivel or the end cover or the isolation disk
  • the piston directly drives or / Driven by a transmission rod or / by a transmission member to drive the baffle or / rotary plate or / stopper or / rotary block.
  • the transmission body is a mechanical part that drives the above-mentioned transmission mechanism; the synchronous mechanical transmission mechanism or / synchronous electromagnetic transmission round body or / ring or or non-round body or / non-round ring or / Non-circular annular grooves // round bodies with external teeth or / round bodies with teeth // round bodies with partial teeth // round grooves with partial teeth // outer body or / outer body or / inner Wattle body // Inner rosette groove // Cam or / Round groove with convex body // Round groove with four wheels or / Concave body // Ellipse body // Ellipse groove or / Semi-ellipsoidal or / Semi-ellipsoidal Slot or / partially ellip
  • Every two sets of rotating wheels or / swivels or / are connected to each other or / fixed connection or / fixed installation or / movably connected or not connected to each other through the linkage mechanism, every two The two sets of casings or / pump casings or / housings or / are mutually connected together or / fixedly connected or / fixedly installed.
  • Two movably connected wheels or / turn bodies are connected as a whole or / fixedly connected or / fixedly installed power output shaft or / power output sleeve or / power input shaft or / power input sleeve or / to each other through a belt Or / gear or / unidirectional transmission gear or / unidirectional transmission flywheel or / chain or / rack or / toothed belt or / toothed disc or / drive rod or / drive shaft or / crankshaft or / by at least two of the above combinations .
  • the shape of the fuel injected from the burner or / fuel feeder outlet is bar or / spiral or / rotary or / circular or / elliptical or / circular or / elliptical or / fan-shaped or /
  • the burner or / fuel feeder also has at least one passage for air or water, or at least two passages for air and water, respectively.
  • the air passage is straight or / curved or / slanted, the water of the burner or / fuel feeder or the / air passage can be controlled to continuously supply air or / inject water or / can be controlled to intermittently supply air or / Spray water, the water channel of the burner or / fuel supply can spray neutral water or / acid water or / alkaline water.
  • the shape of the burner or / fuel feeder outlet for supplying air or / injecting water is stripe or / spiral or / rotary or / circular or oval / circular or / elliptical or / Fan-shaped or / solitary stripe or / scattered or / multi-point polygonal or / multi-line polygonal // polygonal with at least three sides or / at least trilateral with side or / at least two combination.
  • the ignition element in the burner or / igniter is to At least one thermal resistance element or / at least one AC discharge electrode or / at least one DC discharge electrode or / at least one spark plug or / at least one of each of the at least two of the above.
  • the compression chamber is compressed. Air can be stored for use when the power chamber is working.
  • the inlet of the chamber is communicated with the outlet of the compression chamber through a fixedly installed check valve or / one-way pressure valve or / control valve, and the outlet is fixedly installed with a check valve or / one-way pressure valve or / control valve and the power chamber
  • the entrance is connected.
  • the transmission body in the runner (or swivel) engine can Rotating, can control the position where the baffle or / rotating plate or / stopper or / rotating block is fully extended or / completely turned away; 3.
  • the axis line of the rotary wheel or / rotating body can move in parallel and radially; 4.
  • An arc-shaped plate that can control movement or / rotation is installed in the runner or / in the swivel / in the casing or / in the housing, and the movement or / rotation position of the solitary plate can change the volume when the power cavity is formed; Part of the sliding wall surface on the wheel or on the body or on the housing or on the housing or the inner or outer body or the inner body or the outer body or the tangent body can be moved or rotated To change the volume of the power cavity when it is formed or to seal the formed power cavity or incompletely seal it; 6. On the inner wall surface or outer wall surface of the runner or / rotational body // chassis or / housing.
  • An identical shape can be moved or / rotated on or on / inside the wall or / outside the wall or / inside the wall or / outside the wall Arc-shaped bars or / curved plates or / inner angles or / external angles or / straight bars, which can control the formed power chamber seal or / incomplete seal when moving or / rotating; 7. in the runner (Or swivel) on the runner or / swing where the engine power cavity is formed, or on the housing, or on the housing, or on the end cover, or on the isolation plate, there is control or
  • At least one of a straight piston cylinder or a sector piston cylinder that is adjusted, a piston that can be reciprocated or / reciprocated is installed in the straight piston cylinder or / the sector piston cylinder.
  • the cut shape of a straight piston cylinder is round or / elliptical or / semi-ellipsoidal semi-circular or / non-circular or / square or / rectangular or / polygon with at least three sides.
  • the shape of the piston corresponds to the above
  • the shape of the cut surface of the piston cylinder, the shape of the top surface of the piston is a curved top or a / flat top or a top with a concave portion or a top with a convex portion or a top with a combination of at least two of the above.
  • the cut shape of the sector piston cylinder is square or / rectangular or / the top of the fan is curved or / the top of the fan is angular or / one side of the fan is / or both sides of the fan are curved or / angled or / at least two of the above shapes combination.
  • the seal ring or / seal sleeve or / sealing strip or / corresponding seal on the piston is subject to at least one spring or / at least one spring ejector or / at least one ejector of each of the two, which can be installed in the piston's mounting groove.
  • Mobile. The piston is directly driven by the transmission body or / is driven by the transmission member or the transmission rod, and the transmission member or the transmission rod is driven by the transmission body.
  • the transmission body in the runner or in the rotor or in the housing or in the housing or on the end cover or on the isolation plate can be relatively rotated or changed, which can change the position of the piston to reciprocate or reciprocate.
  • the runner or / rotation body in order to make the compression cavity not work, can rotate inertia or / can be compressed by external force transmission Air or / fluid, on the casing or / the casing or / the rotor or / the rotor / or the end cover or / the isolation disc on the casing where the compression chamber of the runner (or swivel) engine is formed
  • At least one port, and at least one non-return valve or / control valve or / one-way pressure valve is fixedly installed inside or outside each port.
  • At least one port is communicated with the inlet of the external air storage container through at least one control valve or / one-way pressure valve or / one-way valve.
  • the outlet of the external air storage container is in communication with the runner (or swivel) engine via at least one control valve or / one-way pressure valve or / one-way valve.
  • At the inlet and outlet of the compression chamber There is between the casing or / pump casing or / the casing or / the runner or / the swivel or / the end cover or / the isolation plate / the epitaxial channel between the outlet and the epitaxial channel between the inlet At least one channel, and at least one control valve or / one-way pressure valve is fixedly installed inside or outside each channel; 2.
  • the transmission body in the runner (or swivel) engine or the runner pump can rotate and can control The position where the baffle plate or / turn plate or / stop or / turn block is fully extended or / turned completely; 3.
  • the axis of the rotation of the swivel can move in parallel and radially; 4.
  • An arc-shaped plate that can control movement or / rotation is installed in / chassis or / pump casing or / housing.
  • the movement or / rotation position of the arc-shaped plate can make the fluid entering the inlet directly flow to the corresponding position, change The volume of the compression cavity when it is formed; V.
  • the body or / external body or / tangent body can be moved or / rotated to change the volume when the compression cavity is formed or / to seal the formed compression cavity or / incompletely;
  • a straight piston cylinder or / sector piston cylinder a piston that can be reciprocated or / reciprocated is installed in the straight piston cylinder or / sector piston cylinder; on the cylinder wall of the straight piston cylinder or / sector piston cylinder or / on the
  • the reciprocating or / reciprocating piston has a lubricant injection port, which can inject lubricant to make the piston move or rotate flexibly and reduce wear;
  • the cut shape of the straight piston cylinder is circular or / elliptical or / semi-ellipsoidal Shaped or / non-circular ring or / square or / rectangular or / polygon with at least three sides, the shape of the piston is relative Based on the shape of the cut surface of
  • the piston is directly driven by the transmission body or / driven by the transmission member or / transmission rod, and the transmission member or / transmission rod is driven by the transmission body; inside the runner or / inside the body or / inside the casing or / pump
  • the transmission body in the shell or / in the shell or / on the end cover or / isolating disc can be relatively rotated or / changed, which can change the position of the piston to compress the fluid; enable the reciprocating movement of the piston and the compression chamber to compress the fluid at the same time or / and not at the same time Fluids cannot be compressed after / or mutual compensation.
  • other technical solutions can also be adopted to control or adjust the flow rate and pressure of the fluid extruded from the compression chamber.
  • the runner (or swivel) engine in order for the runner (or swivel) engine to start and work normally, the runner (or swivel) engine Equipped with fuel supply device or / starting device or / afterburner device // starting afterburner device // starting afterburner device // temperature measurement device or / water spray device or / temperature measurement water spray device or / temperature measurement water spray device Or / power supply unit or / external air storage device or / cooling device or / air filtering device or / lubricating oil supply device or / lubricating oil cooling device or / sealing oil supply device or / at least two devices mentioned above, Start, afterburner, fuel supply Materials, automatic water spray, forced cooling, storage of compressed air, lubrication, sealing and other purposes.
  • Fuel supply device includes fuel, fuel container, electric or / mechanical fuel pump, motor or / mechanical transmission mechanism, automatic or / controllable start-stop controller, control valve or / one-way valve or / one-way pressure
  • the fuel supply device further includes an automatic or / controllable fuel flow regulator, and the fuel supply device further includes a fuel filter.
  • the starting device includes a starting motor, a mechanical transmission mechanism, an automatic or / controllable start-stop controller, a connecting wire or / including an electric air pump, a motor, a start-stop controller, a control valve or / one-way valve or / one-way pressure A valve or / at least two kinds of valves, a connecting channel, and a connecting wire; the starting device constituted by the electric air pump further includes an air filter.
  • the boosting device includes an electric air pump, a motor, an automatic or / controllable start-stop controller, a control valve or / one-way valve or / one-way pressure valve or / at least two of the above-mentioned valves, a connecting channel, and a connecting wire.
  • the force device also includes an automatic or / controllable air flow controller, and the force device also includes an air filter. 4.
  • the starting device and the afterburner constituted by the electric air pump can be combined into a starting afterburner.
  • the device is combined into one, and is used as the starting or / afterburning of the rotary engine.
  • the temperature measuring device includes a temperature measuring device or a temperature measuring controller and connecting wires. 6.
  • Water spray device includes water, water container, water filter, electric or transmission pump, motor or / mechanical transmission mechanism, automatic or / controllable start-stop controller, control valve or / one-way valve or / one-way The pressure valve or / at least two kinds of valves, the connecting channel, and the connecting wire, the water spraying device further includes an automatic or / controllable water flow regulator, and the water spraying device further includes a water filter. 7.
  • the temperature measurement device and the water spray device are combined into a temperature measurement water spray device. The device is integrated into one, which can measure temperature and spray water, and realize automatic control of water spray. 8.
  • the power supply device includes a mechanical transmission mechanism, a generator, a rectifier regulator, a battery, a controller of each electrical equipment, a protector of each electrical equipment, and a connecting wire.
  • the external air storage device includes a control valve or a one-way pressure valve or both of the above-mentioned valves, an air storage container, and a connection channel.
  • the cooling device includes cooling fluid, cooling fluid container, electric or / mechanical transmission cooling fluid pump, motor or / mechanical transmission mechanism, automatic or / controllable start-stop controller, heat dissipation
  • the cooling fluid forcedly circulated by the cooling device, the connecting channel, the connecting wire, and the cooling device is supplied to the runner (or the swivel) engine to cool the runner or / the swivel or the / chassis or the housing or the end cover or the isolation disc or
  • the cooling fluid forcibly circulated by the cooling device is supplied to the lubricating oil cooler to cool the lubricating oil for forced circulation;
  • the cooling device further includes a cooling fluid filter; and the radiator of the cooling device includes a heat dissipation box, an electric or Driven fan, motor or / mechanical transmission.
  • Lubricating oil supply device includes lubricating oil, lubricating oil container, lubricating oil filter, electric or / mechanical transmission lubricating oil pump, motor or / mechanical transmission mechanism, automatic or / controllable start-stop controller, automatic or / Controllable lubricating oil flow regulator, control valve or / one-way valve or / one-way pressure valve or / at least two kinds of valves, connecting channels, connecting wires; for the rotor (or rotating The engine, the lubricating oil circulation supply system further includes a lubricating oil cooling device, the lubricating oil cooling device includes a lubricating oil cooler and a connection channel, and the lubricating oil is cooled in the lubricating oil cooler by a circulating cooling fluid or / electrically or mechanically The driven fan is forcedly cooled.
  • the lubricating oil cooler forcedly cooled by the fan also includes an electric or / mechanical driven fan and a motor or / mechanical driven mechanism.
  • the sealing oil supply device includes a sealing oil, a sealing oil container, an electric or / mechanical transmission sealing oil pump, a motor or / mechanical transmission mechanism, a sealing oil filter, a connecting channel, and a connecting wire.
  • Filter elements are included in the above-mentioned air filtration device or / air filter or / fuel filter or / water filter or / cooling fluid filter or / lubricating oil filter or / sealing oil filter Containers with filter elements and connection channels.
  • Various inlets or / various outlets // various inlet holes // various outlet holes // various ports or / various through holes or / various channels or / various injection holes or / various inflow holes or
  • the directions of the various outflow holes are axial or / oblique axial or / radial or / oblique radial or / at least two directions with respect to the axis of the rotor or / the rotating body.
  • the structure is simpler, with higher efficiency and reliability. It is preferable that the cross-sectional shape of the runner or / rotating body or / machine casing or / pump housing or / inner wall surface or / outer wall surface or / inner and outer wall surface is eccentric equal-diameter ring or / eccentric equidistant ring or Curved ring shape; every two symmetrically installed in the rotor (or swivel) engine (or prime mover) and runner (or swivel) pump (or heat pump or vacuum pump) of the eccentric equal-diameter ring shape structure
  • the baffle or / rotary plate or / stopper or / rotary block is directly pushed to each other by a transmission rod or /, so that the baffle or / rotary plate or / stopper or / rotary
  • the length of the tool mounting frame can be adjusted and the tool mounting frame can move back and forth linearly in the clamp.
  • the tool performs full-circle rotation or / half-circle reciprocating rotation // reciprocating rotation according to a specified arc on the inner wall surface or / outer wall surface // inner-outer wall surface of the part to be processed, so that the inner wall surface or / outer wall surface /
  • the wall surface is gradually cut into an eccentric annular inner wall surface or / outer wall surface or / inner and outer wall surface. 2.
  • the inner wall surface or outer wall surface or inner and outer wall surface of a machined part is processed into a circle with a predetermined diameter.
  • One end of a tool mounting frame The tool is installed, and the other end is also equipped with a tool or directly contact with the wall surface of the component or with ball or rollers or rollers in contact with the wall surface of the component.
  • the length of the tool holder is fixed, and the tool holder can reciprocate in the clamp.
  • the linear movement, the tool rotates the inner wall surface or the outer wall surface or the inner and outer wall surface of the machined part, or rotates halfway, or cuts and reciprocates according to the specified arc, and gradually moves the center axis of the machined part in parallel or
  • the axis of rotation of the / tool mounting bracket clamp enables the inner wall surface or / outer wall surface or / inner and outer wall surface of the machined part to be gradually cut into an eccentric annular inner wall surface or / outer wall surface or / inner and outer wall surface.
  • a method for processing an eccentric equidistant annular inner wall surface or / outer wall surface or / inner and outer wall surface processing the inner wall surface or / outer wall surface of a component to be processed into a circular shape, or / setting at least two stationary phase casings or /
  • Two adjacent inner and outer wall surfaces of the machined part of the pump casing or / housing are respectively machined or / only one of the wall surfaces is processed into a concentric circular circle with a specified diameter, and the center axis of the machined part or / tool holder clamp The axis of rotation of the part is moved in parallel to the specified eccentric axis position.
  • One end of the tool holder is equipped with a tool, and the other end is also equipped with a tool or / directly contacts the wall surface being processed or / installs a ball or / roller or / roller.
  • the length of the tool holder can be adjusted in contact with the wall surface being processed into a circular shape.
  • the tool holder can move back and forth linearly in the clamp, and the tool rotates the inner wall surface or the outer wall surface or the inner and outer wall surface of the workpiece.
  • a method for processing an eccentric equidistant annular inner wall surface or / outer wall surface or / inner and outer wall surface processing the inner wall surface or / outer wall surface of a component to be processed into a circular shape or / at least two stationary phase casings or / Two adjacent inner and outer wall surfaces of the machined part of the pump casing or / housing are respectively machined or / only one of the wall surfaces is processed into a concentric circular circle with a predetermined diameter.
  • a tool is mounted on one end of the tool mounting frame, and the other end is also mounted on the tool.
  • the length of the tool holder can be adjusted, the tool holder can be in the clamp
  • the tool moves linearly back and forth.
  • the tool performs full-circle rotation or / half-cycle reciprocating rotation or / reciprocating rotation according to the specified arc on the inner wall surface or / outer wall surface or / inner and outer wall surface of the part to be processed, and gradually moves the center axis of the processed part in parallel Or / the axis of rotation of the tool holder clamp, so that the distance between at least two stationary wall sets in the casing or in the pump casing or in the casing is gradually cut into an eccentrically equidistant ring Wall or / Outer wall surface or / inner and outer wall surface.
  • V A method for processing a curved ring-shaped inner wall surface or / outer wall surface or / inner and outer wall surface, in which the inner wall surface or / outer wall surface or / inner and outer wall surface of a machined component is processed into a circle with a predetermined diameter, and the center axis or / The rotation axis of the cutting tool holder clamp is moved in parallel to the specified eccentric axis position.
  • One end is mounted on the tool holder, and the other end is movably connected to one end of the transmission rod.
  • the other end of the transmission rod is sleeved on the center axis of the workpiece.
  • the length of the tool mounting bracket or / driving rod can be adjusted.
  • the driving rod can drive the tool mounting bracket to reciprocate and linearly move in the clamp, and the tool can complete the inner wall surface or outer wall surface or inner and outer wall surface of the machined part.
  • the circumferential rotation gradually cuts, so that the inner wall surface or / outer wall surface or / inner and outer wall surface of the workpiece is gradually cut into a hyperbolic ring-shaped inner wall surface or / outer wall surface or / inner and outer wall surface. 6.
  • the inner wall surface or the outer wall surface or the inner and outer wall surface of a part to be processed is processed into a circular circle with a predetermined diameter, and a tool is mounted on one end of the tool mounting frame.
  • the other end is movably connected to one end of the transmission rod, and the other end of the transmission rod is sleeved on the central axis of the workpiece
  • the driving rod can drive the tool mounting bracket to reciprocate and linearly move in the clamp, and the tool faces the inner or outer wall surface or the inner and outer wall surface of the machined part.
  • the inner or outer wall surface or the inner and outer wall surface In addition to the above six processing methods, other methods can also be used to process the parts to be processed into an eccentric equal-diameter ring or / eccentric equidistant ring or / hyperbolic ring inner wall surface or / outer wall surface or / inner and outer wall surface.
  • a kind of outer ring wall surface or inner ring wall surface or inner and outer The ring-shaped wall surface method of the wattle body is to process the inner wall surface / outer wall surface or inner and outer wall surface of the processed part into a circle with a predetermined diameter, and cut or / saw at least one groove in the axial or / oblical axis to be processed.
  • the center axis of the component or the rotation axis of the tool holder clamp is moved in parallel to the specified eccentric axis position.
  • the tool is mounted on one end of the tool holder. The length of the tool holder can be adjusted.
  • the outer wall surface is subjected to half-cycle reciprocating rotation or / reciprocating rotation of a predetermined arc to gradually cut, so that the inner wall surface or / outer wall surface or / inner and outer wall surface of the processed component is gradually cut to have at least one inner or outer body or inner / outer body.
  • Body shape 2.
  • the inner wall surface or outer wall surface or inner and outer wall surface of the machined part is subjected to half-cycle reciprocating rotation or reciprocating rotation of a predetermined arc step by step, and the center axis of the machined component or the rotation axis of the tool holder is gradually moved in parallel to make the machined component
  • the inner wall surface or / outer wall surface or / inner and outer wall surface is gradually cut into at least one annular wall surface with inner wattle body or / an annular wall surface with outer wattle body or / an annular wall surface with inner and outer wattle body.
  • other methods can also be used to process the processed component into an annular wall surface with an inner wattle body // an annular wall surface with an outer wattle body // an annular wall surface with an inner wattle
  • the inner wall surface or / The outer wall surface or / inner and outer wall surface is processed into a circle with a predetermined diameter.
  • the center axis of the machined part or the rotation axis of the tool holder clamp is moved in parallel to the specified eccentric axis position.
  • One end of the tool holder is equipped with a tool and the other end is connected with
  • One end of the transmission rod is movably connected, and the other end of the transmission rod is sleeved on a fixed shaft located at the center axis of the part to be processed.
  • the length of the tool mounting bracket or / the transmission rod can be adjusted, and the transmission rod can drive the tool.
  • the rack moves linearly back and forth in the clamp, and the tool rotates the inner wall surface or the outer wall surface or the inner and outer wall surface of the machined part and rotates gradually to make the inner wall surface or the outer wall surface or the inner and outer wall surface of the machined part gradually cut.
  • the other end of the cutter is movably connected to one end of the transmission pestle, and the other end of the transmission rod is sleeved on a fixed shaft located at the center axis of the part to be processed.
  • the length of the tool mounting bracket or / the transmission rod can be adjusted, and the transmission rod can transmit
  • the tool holder moves linearly back and forth in the clamp.
  • the tool rotates the inner wall surface or the outer wall surface or the inner and outer wall surface of the machined part and rotates it step by step, and moves the center axis of the machined part or the tool rack holder in parallel.
  • the axis of rotation of the part enables the inner wall surface or / outer wall surface or / inner and outer wall surface of the machined part to be gradually cut into non-circular inner wall surface or / outer wall surface or / inner and outer wall surface.
  • other methods can also be used to process the processed component into a non-circular inner wall surface or / outer wall surface or / inner and outer wall surface.
  • the tool or / machined part or the speed of the tool is not equal to the speed of the machined part.
  • each part, part, component that constitutes a runner (or swivel) engine (or prime mover) or / rotor (or swivel) pump (or heat pump or vacuum pump) can be composed of a whole.
  • a single wheel or a single swivel can be composed of a whole or fixedly connected or fixed at least two parts
  • a single casing or a single pump casing or / Single shell is formed by a whole or / is fixedly connected by at least two parts or / fixed installation
  • single end cover or / single isolation disk is formed by a whole or / fixedly connected by at least two parts or / fixed installation
  • a single baffle or / single turn plate or / single stop or / single turn block is formed as a whole or / is fixedly connected by at least two parts or / fixed installation.
  • a high-power or / extremely high-power fluid runner (or swivel) engine or prime mover or / internal combustion or / external combustion or / internal and external combustion runner (or swivel) engine or / internal combustion or / External combustion or internal and external combustion combined cycle (steam) runner (or swivel) engine.
  • one compression unit can be manufactured into multiple compression chambers, and one compression unit can be manufactured into a high-power Runner (or swivel) pump (or heat pump or vacuum pump); runner for a compression unit with at least two phases connected in series or / phase parallel or / phase series parallel or / phase set or / combined with at least two structural relationships (Or swivel) pump (or heat pump or vacuum pump), especially suitable for manufacturing high-power or / high-power fluid runner (or swivel) pump (or heat pump or vacuum pump) or / multi-stage compression high-pressure runner (or Swivel) pump (or heat pump or vacuum pump).
  • FIGS. 1 to 6 are an external view, a structural sectional view, and a working cross-sectional view of Embodiment 1 of the present invention
  • FIGS. 7 to 9 are an external view and a working cross-sectional view of Embodiment 2 of the present invention.
  • 10 to 11 are external views and sectional views of another structure of the runner 1 according to the first embodiment of the present invention.
  • 12 to 13 are an external view and a cross-sectional view of another structure of the runner 1 according to the second embodiment of the present invention
  • 14 is a working cross-sectional view of a third embodiment of the present invention
  • Embodiment 38 to 42 are an external view, a structural sectional view, and a working sectional view of Embodiment 8 of the present invention.
  • Embodiment 43 to 47 are an external view, a structural sectional view, and a working sectional view of Embodiment 9 of the present invention.
  • 53 to 57 are an external view, a structural sectional view, and a working sectional view of an eleventh embodiment of the present invention.
  • 58 to 60 are an external view, a structural cross-sectional view, and a cross-sectional view of each mark according to Embodiment 12 of the present invention.
  • 61 is an external view of a thirteenth embodiment of the present invention.
  • FIG. 62 is a working sectional view of the fourteenth embodiment of the present invention.
  • FIG. 63 is a working sectional view of the fifteenth embodiment of the present invention.
  • FIG. 64 is a working cross-sectional view of a sixteenth embodiment of the present invention.
  • FIG. 65 is a working sectional view of a seventeenth embodiment of the present invention.
  • FIG. 66 is a working sectional view of the eighteenth embodiment of the present invention.
  • FIG. 67 is a working cross-sectional view of a nineteenth embodiment of the present invention.
  • FIG. 68 is a working cross-sectional view of Embodiment 20 of the present invention
  • FIG. 69 is a working sectional view of the twenty-first embodiment of the present invention
  • FIG. 68 is a working cross-sectional view of Embodiment 20 of the present invention
  • FIG. 69 is a working sectional view of the twenty-first embodiment of the present invention.
  • FIG. 70 is a working sectional view of the twenty-second embodiment of the present invention.
  • FIG. 71 is a working sectional view of the twenty-third embodiment of the present invention.
  • FIG. 72 is a working sectional view of the twenty-fourth embodiment of the present invention.
  • FIG. 73 is a working sectional view of the twenty-fifth embodiment of the present invention.
  • FIG. 74 is a working sectional view of the twenty-sixth embodiment of the present invention.
  • FIG. 75 is a working sectional view of a twenty-seventh embodiment of the present invention.
  • FIG. 76 is a working sectional view of the twenty-eighth embodiment of the present invention.
  • 77 is a working cross-sectional view of a twenty-ninth embodiment of the present invention.
  • FIG. 78 is a working cross-sectional view of Embodiment 30 of the present invention.
  • FIG. 79 is a working sectional view of the thirty-first embodiment of the present invention.
  • FIG. 80 is a working cross-sectional view of the thirty-second embodiment of the present invention.
  • FIG. 81 is a working sectional view of the thirty-third embodiment of the present invention.
  • FIG. 82 is a working sectional view of the thirty-fourth embodiment of the present invention.
  • FIG. 83 is a sectional view of a cooling hole in the casing or / the pump casing or / the casing in the present invention
  • FIG. 84 is a working sectional view of the thirty-fifth embodiment of the present invention
  • FIG. 85 is a working sectional view of the thirty-sixth embodiment of the present invention.
  • FIG. 86 is a working sectional view of the thirty-seventh embodiment of the present invention.
  • FIG. 87 is a working sectional view of the thirty-eighth embodiment of the present invention.
  • FIG. 88 is a working cross-sectional view of the thirty-ninth embodiment of the present invention.
  • FIG. 89 is a working cross-sectional view of the forty embodiment of the present invention.
  • FIG. 90 is a transmission relationship diagram of a set of rotating wheels (or swivels) or / swivels in the present invention.
  • FIG. 91 is a working sectional view of the forty-first embodiment of the present invention.
  • FIG. 92 is a working sectional view of the forty-second embodiment of the present invention.
  • FIG. 93 is a work sectional view of the forty-third embodiment of the present invention
  • FIG. Fig. 94 is a working sectional view of the forty-fourth embodiment of the present invention
  • Fig. 95 is a working sectional view of the forty-fifth embodiment of the present invention
  • Fig. 96 is a working sectional view of the forty-sixth embodiment of the present invention
  • FIG. 98 is a working cross-sectional view of the forty-eighth embodiment of the present invention
  • FIG. 99 is a working cross-sectional view of the forty-ninth embodiment of the present invention.
  • Figure 101 is a working sectional view of the fifty-first embodiment of the present invention.
  • Figure 102 is a working sectional view of the fifty-second embodiment of the present invention;
  • Figure 103 is a working sectional view of the fifty-third embodiment of the present invention;
  • Figure 104 is A working cross-sectional view of the fifty-fourth embodiment of the present invention;
  • FIG. 105 is a working cross-sectional view of the fifty-fifth embodiment of the present invention;
  • FIG. 106 is a working cross-sectional view of the fifty-sixth embodiment of the present invention;
  • Fig. 108 is a working sectional view of the fifty-ninth embodiment of the present invention;
  • FIG. 109 is a working sectional view of the fifty-ninth embodiment of the present invention
  • Fig. 110 is a working sectional view of the sixtyth embodiment of the present invention.
  • Figure 111 is a sixty embodiment of the present invention
  • Figure 112 is a working sectional view of the sixty-second embodiment of the present invention
  • Figure 113 is a working sectional view of the sixty-third embodiment of the present invention
  • Figure 114 is a working sectional view of the sixty-fourth embodiment of the present invention
  • FIG. 115 is a working sectional view of the sixty-fifth embodiment of the present invention
  • FIG. 116 is a working sectional view of the sixty-sixth embodiment of the present invention.
  • FIG. 117 is a working sectional view of the sixty-seventh embodiment of the present invention.
  • Working sectional view of the sixty-eighth embodiment is a working sectional view of the sixty-ninth embodiment of the present invention.
  • FIG. 120 is a working sectional view of the seventy embodiment of the present invention.
  • FIG. 121 is a work sectional view of the seventy-first embodiment of the present invention.
  • FIG. 122 is a working sectional view of the seventy-second embodiment of the present invention.
  • FIG. 123 is a transmission diagram of the transfer plate 55 of FIG. 122;
  • FIG. 124 is a work sectional view of the seventy-third embodiment of the present invention.
  • FIG. 125 is a transmission diagram of the relay plates 63 and 64 of FIG. 124;
  • FIG. 126 is a working sectional view of the seventy-fourth embodiment of the present invention.
  • FIG. 127 is a working sectional view of the seventy-fifth embodiment of the present invention.
  • FIG. 128 is a working sectional view of the seventy-sixth embodiment of the present invention.
  • FIG. 129 is a working sectional view of the seventy-seventh embodiment of the present invention.
  • FIG. 130 is a working cross-sectional view of the seventy-eighth embodiment of the present invention.
  • FIG. 131 is a working sectional view of the seventy-ninth embodiment of the present invention.
  • FIG. 132 is a working cross-sectional view of the eighty embodiment of the present invention.
  • FIG. 133 is a transmission diagram of the transfer plates 61 and 62 of FIG. 132;
  • FIG. 134 is a partial cross-sectional view of a first embodiment of a baffle 51 installed on a runner (or a swivel) or a swivel 1 in the present invention
  • FIG. 135 is a partial cross-sectional view of a second embodiment of a baffle 51 installed on a runner (or a swivel) or a swivel 1 in the present invention
  • FIG. 136 is a partial cross-sectional view of a third embodiment of a baffle plate 51 on a runner (or a swivel) or a swivel 1 in the present invention
  • FIG. 137 is a partial cross-sectional view of a fourth embodiment of a baffle plate 51 on a runner (or a swivel) or a swivel 1 according to the present invention.
  • FIG. 138 is a partial cross-sectional view of a fifth embodiment of a baffle plate 51 on a runner (or a swivel) or a swivel 1 in the present invention.
  • 139 is a partial cross-sectional view of a sixth embodiment of a baffle 51 on a runner (or a swivel) or a swivel 1 in the present invention
  • 140 is a partial cross-sectional view of a first embodiment of a baffle plate 51 installed on the casing 2 or the pump casing 2 or the casing 2 in the present invention
  • FIG. 141 is a partial cross-sectional view of a second embodiment 51 provided with a baffle plate on the casing 2 or the pump casing 2 or the casing 2 in the present invention
  • 142 is a partial cross-sectional view of a third embodiment of a baffle plate 51 installed on the casing 2 or the pump casing 2 or the casing 2 in the present invention
  • FIG. 143 is a partial cross-sectional view of a first embodiment of an arc-shaped baffle 52 mounted on the runner (or swivel) 1 of the present invention
  • FIG. 144 is a partial cross-sectional view of the first embodiment of the invention in which 5 baffles 52 are installed on the casing 2 or the pump casing 2 or the casing 2;
  • FIG. 145 is a partial cross-sectional view of a first embodiment of a rotating plate 62 on a rotating wheel (or a rotating body) or a rotating body 1 in the present invention
  • FIG. 146 is a partial cross-sectional view of the first embodiment of the straight baffle 51 equipped with rollers 91 on the side of the present invention.
  • Fig. 147 is a partial cross-sectional view of the first embodiment of the arc-shaped baffle 52 provided with balls 92 on the side of the present invention
  • FIG. 148 is a partial cross-sectional view of Embodiment 1 of the arc-shaped rotating plate 62 provided with balls 92 on the side of the present invention
  • FIG. 149 is a partial cross-sectional view of the first embodiment of the first embodiment in which rollers 91 are provided on the side of the straight rotating plate 61 in the present invention.
  • FIG. 150 is a partial cross-sectional view of Embodiment 1 of the first embodiment in which rollers 91 and balls 92 are installed on both front and side surfaces of a straight baffle 51;
  • FIG. 151 is a partial cross-sectional view of the first embodiment of the synchronous mechanical transmission mechanism of the present invention
  • FIG. 152 is an arrow-marked cross-sectional view in FIG. 151;
  • FIG. 153 is a partial cross-sectional view of a second embodiment of the synchronous mechanical transmission mechanism of the present invention
  • FIG. 154 is a cross-sectional view labeled with an arrow in FIG. 153
  • 155 is a sectional view of the first embodiment of the fuel feeder 71 in the present invention
  • FIG. 156 is a sectional view of the second embodiment of the fuel feeder 72 in the present invention
  • FIG. 157 is a sectional view of the first embodiment of the lighter 73 in the present invention.
  • FIG. 158 is a sectional view of the first embodiment of the burner 7 in the present invention.
  • FIG. 159 is a sectional view of the second embodiment of the burner 7 in the present invention.
  • FIG. 161 is a sectional view of the fourth embodiment of the burner 7 in the present invention.
  • Fig. 162 is a sectional view of the fifth embodiment of the burner 7 in the present invention.
  • Figure 163 is a sectional view of the sixth embodiment of the burner 7 in the present invention.
  • Figure 164 is a cross-sectional view of the first embodiment of the temperature measuring water jet 8 of the present invention.
  • FIG. 165 is a cross-sectional view of the second embodiment of the temperature measuring water sprayer 8 according to the present invention.
  • FIG. 166 is a sectional view of a first embodiment of a water sprayer 81 in the present invention.
  • FIG. 167 is a cross-sectional view of the first embodiment of the thermometer 82 in the present invention.
  • FIG. 168 is a principle block diagram of the first embodiment of the internal combustion type runner (or swivel) engine connected to auxiliary equipment in the present invention
  • FIG. 169 is a principle block diagram of Embodiment 2 of the internal combustion type runner (or swivel) engine connected to auxiliary equipment in the present invention
  • 170 is a principle block diagram of a third embodiment of an internal combustion type runner (or swivel) engine connected to an auxiliary device according to the present invention
  • Figure 171 is a principle block diagram of the first embodiment of the connection between the external combustion type (or swivel) engine and auxiliary equipment in the present invention.
  • 1 to 6 are an external view, a structural cross-sectional view, and a working cross-sectional view of the first embodiment of the present invention
  • the first embodiment provides an internal combustion runner (or swivel) engine with air compression in the same working unit Cavity 01 and power cavity 02
  • the structure of this embodiment can be manufactured to have one working unit or / at least two working units connected in series or / parallel or / serial / parallel or /
  • the structure of this embodiment Can also be made into a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) engine, internal or external combustion rotor Wheel (or swivel) engines and runner (or
  • FIG. 1 is an external view of Embodiment 1 of the present invention.
  • the runner 1 is a cylinder and is installed in the casing 2, and their axis lines do not coincide.
  • the runner 1 is fixedly connected to the shaft.
  • the air-flow compression cylinder 12 and the axial-flow air compression cylinder 12 are fixedly connected to the power output shaft 11.
  • the runner 1 is provided with four movable baffles 51, and the runner 1 can rotate in the casing 2.
  • the casing 2 is An inner wall surface is a circular cylinder.
  • the lower part of the cylinder has four mounting bases 21 connected together.
  • the mounting base 21 has mounting holes 210 for mounting a runner (or swivel) engine.
  • the bottom of the casing 2 is also There are an air intake pipe 231 and an air outlet 240, which are used to provide air and exhaust gas for a runner (or swivel) engine.
  • a burner 7 and a temperature measuring sprinkler 8 are fixed on the casing 2 at the power chamber 02. The burner 7 is to feed fuel into the runner (or swivel) engine and ignite it.
  • the temperature measuring sprinkler 8 measures the temperature in the runner (or swivel) engine. Water is sprayed into the cavity 02 to increase power and control the operating temperature.
  • the casing 2 at the air compression cavity 01 is equipped with Control valve 973, which can control the function of the compressed air of the runner (or swivel) engine.
  • the air inlet 2330 When it is closed, it can compress the air to provide sufficient air for fuel combustion. When it is open, it cannot compress the air; There is an air inlet 2330 on the casing 2 at the cavity 02.
  • the air inlet 2330 is equipped with an automatic intake valve block 975 and a spring 916.
  • air When the power cavity 02 is not performing work, air is automatically introduced to form a power cavity.
  • the baffle 51 of 02 is not under force.
  • the pressure of the work gas in the power chamber 02 is higher than the external gas pressure.
  • the air inlet 2330 is automatically closed by the valve block 975 and the spring 916.
  • FIG. 1 When the power chamber 02 is not doing work, it can rotate inertially; the middle part of the casing 2 has an injection port 250, which can be filled with lubricating oil, so that the baffle 51 can slide flexibly. Both ends of the casing 2 have some end cap mounting ears, and the ears have mounting holes 220 for mounting the end caps 3 and 4.
  • Figure 1 also shows the appearance of the end caps 3 and 4.
  • the end cap 3 is a disc, which has a mounting hole 320, an eccentric shaft hole 310, and an air inlet 330.
  • the mounting hole 320 is on the mounting ear.
  • End cover 3 is mounted on the housing 2, the shaft hole 310 is used to penetrate the power output shaft 11, and the air inlet 330 is for introducing air to the runner engine and providing it to the axial air compression cylinder 12; There are also injection ports 350 and 360 through which lubricating oil and sealing oil can be injected.
  • the end cap 4 is also a circular disk, which has a mounting hole 420, an eccentric shaft groove 410, and an air outlet 440, and has an air outlet pipe 44.
  • the mounting hole 420 is on the mounting ear and is used to mount the end cap 4 to the casing.
  • the shaft groove 410 is used for the power output shaft 11, and the air outlet 440 is used to flow the air compressed by the axial-flow air compression cylinder 12 into the air outlet pipe 44 and is supplied to the runner (or the swivel) through the air inlet pipe 231 on the casing )engine.
  • FIG. 2 is an external view of the casing 2 in FIG. 1 after reversing. From the figure, the appearance of the other surface of the casing 2 can be seen.
  • the air flowing from the intake pipe 231 enters the casing 2 through the air inlet 230, and the air inlet There is an air outlet 240 next to 230, and a control valve 973 is installed in a through hole.
  • FIG. 3 is an external view of the turning wheel 1 in FIG. 1 after reversing.
  • the turning wheel 1 is a cylinder, and an axial-flow air compression cylinder 12 is connected to the power output shaft 11 in the cylinder.
  • FIG. 4 is an external view of the end cap 4 in FIG. 1 after being reversed. It can be seen from the figure that the air pipe 44 and the end cap 4 are integrated or / fixedly connected.
  • the end cap 4 also has an injection port 450 for injection. lubricating oil.
  • FIG. 5 is a sectional view of the combined structure of FIG. 1. From the figure, the combined structure of the runner 1, the casing 2, the end caps 3 and 4, the baffle 51, the transmission rod 921, and the like can be seen.
  • the runner 1 is installed in the casing 2. Inside, two ends of the casing 2 are provided with end covers 3 and 4.
  • the power output shaft 11 penetrates the end cover 3, and the shaft holes 310 and the shaft grooves 410 of the end covers 3 and 4 are provided with rollers 94.
  • the inlets 350 and 450 are filled with lubricating oil and come into contact with the rotating wall surface of the power output shaft 11 to make the entire runner 1 rotate flexibly.
  • the cover 3 is provided with an oil-absorbing material sealing ring 961, and the sealing oil is injected from the injection port 360, and it is in rotational contact with the runner 1, to ensure that the gas does not flow to the air inlet 330;
  • the two transmission levers 921 push each other.
  • the position where the pair of baffles 51 push each other can be seen from the figure.
  • the two transmission pestles 921 and the two transmission levers 921 of the other pair of baffles 51 are not at the same position.
  • the two pairs of baffle plates 51 do not affect each other when they are moved, and the spring 911 installed in the baffle plate 51 can finely adjust the moving position of the baffle plate 51.
  • FIG. 6 is a working cross-sectional view of Embodiment 1. This figure can most intuitively explain the working situation of Embodiment 1.
  • two pairs of baffles 51 and transmission rods 921 are drawn at overlapping positions for convenience of explanation.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be manufactured to turn the runner 1 in the opposite direction.
  • the inner wall surface of the casing 2 is a circular or / eccentric circular ring with an equal diameter
  • the outer wall surface of the runner 1 is a circular or / non-circular shape with a protrusion 13, and when the protrusion 13 is turned to the upper end, It is in contact with the inner wall of the casing 2; the pressured fuel supplied by the burner 7 enters the power chamber 02, is mixed with the air, and is ignited to generate a thermal gas.
  • the runner 1 When the baffle 51 is pushed, the runner 1 can be rotated and rotated to At the position indicated by the arrow at A1, the other baffle 51 is pushed again, so that the previous baffle 51 reaches the air outlet 240, so that the exhaust gas after work is discharged, and then transferred to the air inlet 230, due to the axial air compression
  • the air supplied from the cylinder 12 has a certain pressure, and the air flows in through this port.
  • the other baffle 51 After turning through the air inlet 230, the other baffle 51 is forced to continue to push the runner 1 to rotate, forcing the baffle 51 into the compressed air stage. It can be seen that as the runner 1 rotates, the runner 1, the machine 2. As the volume between the baffles 51 becomes smaller and smaller, the air compression chamber 01 is formed.
  • the casing 2 is equipped with a temperature measuring water sprayer 8, which has two functions of temperature measurement and water spraying.
  • the temperature measuring element transmits a signal that the temperature value becomes a certain value to the temperature control water spraying device. When the signal reaches the specified value At this time, the water spray system is started, and the pressure water is sprayed into the power chamber 02 through the temperature measuring sprayer 8 to keep the temperature of the power chamber 02 within a predetermined range. Water vapor and exhaust gas formed by water heating can also be used.
  • the harmful gases in the gas are reacted or / adsorbed or / sprayed into the acidic water or / alkaline water which can be neutralized according to the acidity and alkalinity of the combustion gas, so as to reduce pollution when the exhaust gas is discharged.
  • a control valve 973 and a spring 915 in the figure, which can control the work of the air compression chamber 01.
  • the control valve 973 When the control valve 973 is pressed in, the air compression chamber 01 cannot compress the air.
  • the control valve 973 is in the position shown in the figure, Due to the action of the spring 915, the passage is closed, and the air compression chamber 01 can compress air.
  • the air inlet 2330 is provided with a valve block 975 and a spring 916.
  • the air inlet 2330 It is closed when power chamber 02 is doing work, and it is opened when power chamber 02 is not doing work, and air can be automatically introduced into power chamber 02.
  • the arrow indicated by A3 is the beginning of work
  • the arrow indicated by A1 is the end of work
  • the arrows indicated by A1 to A2 are the exhaust and intake phases
  • the subsequent phases of A2 are the compressed air phases.
  • the outer wall of the runner 1 in FIG. 6 can also be made into a circular shape without the protruding body 13, and the working principle is the same as that in FIG. 6. It can be seen from FIG.
  • the transmission lever 921 keeps reciprocating, so that the distance between each pair of baffles 51 remains relatively constant, and each pair of baffles 51 can be kept at the same time.
  • the spring 911 installed in the baffle 51 can make the baffle 51 contact the inner wall of the casing 2 with a certain pressure, and can also finely adjust the distance between each pair of baffles 51 so that the baffle 51 can work during operation. Keep tight.
  • each baffle 51 it must go through four stages of inhalation, compression, work, and exhaust. After inhalation, it enters the compression stage. It forms an air compression chamber 01 with the runner 1, the casing 2, and the like.
  • a gasket 962 is installed on the burner 7, and a gasket 963 is installed on the temperature measuring sprinkler 8.
  • the fuel can also be supplied during the compression phase, so that the fuel and air are mixed during the compression process, and then ignited when entering the power chamber, which can also make the runner (or swivel) engine cycle work.
  • At least one set of various air inlets, air outlets, burners, and temperature-measuring sprayers may be further provided at corresponding positions on the casing 2 to implement the runner (or swivel). 1 Bidirectional rotation.
  • control valve 973 and its function, the air inlet 2330 and its function appearing in the first embodiment will not be drawn in the following embodiments in order to be simplified and not repeated. Regardless of whether the air compression chamber 01 and the power chamber 02 are in the same wheel or in each wheel in the following embodiments, the control valve 973 is installed at the position where the air compression chamber 01 is formed, and can be installed in the casing 2 or the runner. 1 or / end cap 3 or / end cap 4, the ability of the air compression chamber 01 to compress air can be controlled, and the air inlets 2330 are all provided at the formation of the power chamber 02, which can be performed when the power chamber 02 is not doing work. Unforced.
  • the inner wall surface of the casing 2 can be directly processed into a circular or / non-circular or / eccentric equal-diameter annular or hyperbolic annular sliding wall surface, and components of corresponding shapes can also be fixedly connected or fixed. It is installed in the casing 2 and formed.
  • Embodiment 2 provides an internal combustion rotor (or swivel) engine, which has an air compression chamber 01 and Power chamber 02, whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two working units connected in series or / parallel or / series / parallel or / phase set or / combined with at least two structural relationships ( Or swivel) engine, each working unit can be manufactured with at least one air compression cavity 01 and at least one power cavity 02; its structure can also be manufactured as an external combustion rotor (or swivel) engine, internal and external combustion Type runner (or swivel) engine, fluid runner (or swivel) engine (or prime mover), wind runner (or swivel) engine (or prime mover), runner (or swivel) pump (or Heat pump or vacuum pump).
  • an internal combustion rotor (or swivel) engine which has an air compression chamber 01 and Power chamber 02, whose structure can be manufactured as an internal combustion
  • FIG. 7 is an external view of the casing 2 in the second embodiment.
  • the casing 2 has an eccentric circular body 274 integrally connected or fixedly connected or fixedly installed.
  • the lower portion of the casing 2 has an air inlet 230 and an air outlet.
  • the lower part of the casing 2 has four bases 21 connected as a whole or / fixed connection or I fixed installation, the base 21 has a mounting hole 210, and the lower part of the casing 2 is connected as a whole or / fixed connection or / Fixedly installed air passage 231, the upper end of the casing 2 has two injection holes 250 and 260, injection holes 250 and 260 also have extension tubes.
  • the fuel supply device 71, control valve 973, and ventilation channel 99 are fixedly installed on the casing at the compression chamber 01.
  • the extension channel of the ventilation channel 99 must be installed.
  • the control valve has an air inlet passage 233 on the casing 2 at the power chamber 02.
  • FIG. 8 is an external view of the runner 1 in the second embodiment.
  • the runner 1 has an axial-flow air compression cylinder 12
  • the axial-flow air compression cylinder 12 has a power output shaft 11
  • the runner 1 Each end has a disc 17 connected as a whole or / fixedly connected or / fixedly installed.
  • Each disc 17 is provided with a sealing ring 961 and a set of rollers 94 on the circumference, and the inner side of each disc 17
  • FIG. 9 is a cross-sectional view of the working principle of the second embodiment, which can explain the working situation of the second embodiment.
  • two pairs of baffles 52 and respective transmission rods 923 are drawn at overlapping positions for convenience of description;
  • the dashed arrows and arrows indicate the flow of gas and fuel.
  • the arc arrows indicate the rotation direction of the runner 1. It can also be manufactured to turn the runner 1 in the opposite direction. It can be seen from the figure that the outer wall surface of the runner 1 is circular.
  • the inner wall surface of the casing 2 is a circular or / eccentric circular ring with an equal diameter.
  • the compression chamber 01 With the rotation of the runner 1, the volume of the compression chamber 01 gradually becomes smaller. When it reaches a minimum, the fuel and air mixture is compressed and burned, and then transferred to the power chamber 02 to perform work, pushing the baffle 52 to make the rotation Wheel 1 rotates, and the exhaust gas after work is exhausted from the air outlet 240.
  • the recessed portion 16 on the runner 1 has a small space for gas flow when the volume of the compression chamber 01 is minimized; the casing 2 at the compression chamber 01 Ventilation channel 99 is fixed on the top, the ventilation A control valve is connected to the outside of the road 99.
  • the runner engine When the runner engine is not performing work, it is driven by external force to become an air compression runner pump. Compressed air is supplied from the ventilation channel 99 to the external air storage device. When the engine needs compressed air, the compressed air is supplied into the runner engine from the ventilation channel 99.
  • the control valve can control the opening and closing of the ventilation channel 99.
  • each baffle 52 is pushed by at least one transmission rod 923, and each pair of transmission rods 923 is directly driven between them Equipped with a spring 911, the distance difference between each pair of baffles 52 during rotation can be compensated, so that the baffles 52 are always in contact with the sliding wall surface.
  • At least one set of various air inlets, air outlets, and fuel injectors may be further provided at corresponding positions on the casing 2 to realize bidirectional rotation of the runner (or swivel) 1.
  • the inner wall surface of the casing 2 can be directly processed into a circular or / non-circular ring // eccentric equal-diameter ring or / curved ring sliding wall surface, and a component of a corresponding shape can also be fixedly connected or / fixed. It is installed in the casing 2 and formed.
  • the structure of the runner 1 is suitable for an inner wall surface of the casing 2 which is an eccentric, equal-diameter annular sliding wall surface.
  • the structure of the runner 1 can also be made into an external combustion type or / internal and external combustion type runner (or swivel) engine, a fluid runner (or swivel) engine (or prime mover), and a wind runner (or swivel). Rotor (or swivel) of the engine (or prime mover), rotary pump (or heat pump or vacuum pump). It can be seen from FIG.
  • FIG. 11 is a cross-sectional view of FIG. 10.
  • the transmission rods 921 of the two pairs of baffle plates 51 are drawn on the same plane in FIG. 11.
  • a transmission rod 921 is used for transmission.
  • the outer wall of the runner 1 is provided with some recessed grooves 14.
  • the runner 1 has an axial-flow air compression cylinder 12 integrally connected or fixedly connected or fixedly installed.
  • the structure of the runner 1 is suitable for an inner wall surface of the casing 2 which is an eccentric, equal-diameter annular sliding wall surface.
  • the structure of the runner 1 can also be made into an external combustion type or / internal and external combustion type runner (or swivel) engine, a fluid runner engine (or prime mover), and a wind runner (or swivel).
  • FIG. 13 is a cross-sectional view of FIG. 12.
  • FIG. 14 is a working cross-sectional view of Embodiment 3 of the present invention.
  • an internal combustion runner (or swivel) engine is provided, and there is an air compression chamber 01 and a power chamber 02 in the same working unit.
  • the structure of the embodiment can be manufactured as an internal combustion rotor (or a swivel body) having one working unit or / at least two working units connected in series or / parallel or / serial / parallel or / phase set or / combined with at least two structural relationships. Engine), each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02.
  • the outer wall surface of the runner 1 is circular, and the inner wall surface of the casing 2 is circular or / eccentric.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover) , Wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or swivel) pump (or Heat pump or vacuum pump).
  • a fluid runner or swivel engine (or prime mover)
  • Wind runner (or swivel) engine or prime mover
  • external combustion runner or swivel
  • internal and external combustion runner (or swivel) engine and runner (or swivel) pump or Heat pump or vacuum pump
  • the dotted line and arrow in the figure indicate the flow of gas, fuel, and water, and the solitary arrow in runner 1 indicates that the runner 1 turns.
  • the direction of movement can also be made such that the runner 1 rotates in the opposite direction; the pressured fuel supplied by the burner 7 enters the combustion chamber 03 and is ignited to generate thermal gas, which directly enters the power chamber 02 to perform work and push the stopper.
  • the plate 51 can rotate the runner 1.
  • the valve disc 974i 3 ⁇ 4 is opened from the air outlet 2410 of the compression chamber 01.
  • the air storage chamber 201 in the casing 2 is pressurized air stored in the air storage chamber 201 through the air outlet. 2310 and control valve 977 enter combustion chamber 03, There is enough air to completely burn the fuel.
  • a water sprayer 82 is fixed on the casing 2 at the combustion chamber 03, which can inject pressured water into the combustion chamber 03 and the power chamber 02.
  • the casing 2 is also fixed with a temperature detector 83, which can measure the temperature of the work gas when it is out, and output a signal to the outside. When the signal reaches a specified value, the water spray device outside the starter passes the water spray device 82.
  • the outer wall of the runner 1 is circular, and the inner wall of the casing 2 is an eccentric smooth wall surface. It can be seen from FIG. 14 that with the rotation of the wheel 1, the transmission rod 921 keeps reciprocating, so that the distance between each pair of baffles 51 can be kept relatively constant, and each pair of baffles 51 can keep reciprocating at the same time. Move so that the extended end of the baffle 51 keeps close to the smooth sliding wall surface during work Seal. Each baffle 51 passes through four stages of inhalation, compression, work, and exhaust during one rotation, and enters the compression stage after inhalation. In this way, the reciprocating rotation becomes an internal combustion runner (or Swivel) engine.
  • the air inlet passage 231 forms a strip-shaped air inlet 230, and the runner 1 has an axial-flow air compression cylinder 12 integrally connected or fixedly connected or fixedly installed.
  • At least one set of various air inlets, air outlets, burners, water sprayers, and temperature detectors may be further provided at corresponding positions on the casing 2 to realize the turning wheel (or turning body). 1 Bidirectional rotation.
  • FIG. 15 is a working cross-sectional view of Embodiment 4 of the present invention.
  • Embodiment 4 provides an internal combustion runner (or swivel) engine, which has an air compression chamber 01 and a power chamber 02 in the same working unit.
  • the structure of the example can be manufactured as an internal combustion runner (or swivel) with one working unit or / at least two working units connected in series or / parallel or / serial / parallel or / phase set or / combined with at least two structural relationships.
  • Each working unit of the engine can be manufactured with at least one air compression chamber 01 and at least one power chamber 02.
  • the outer wall surface of the runner 1 is round, the inner wall surface of the casing 2 is round, and the outer wall of the runner 1 and There is at least one or / at least one contact surface between the inner walls of the casing 2;
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) Engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner or swivel engine (or prime mover)
  • a wind runner (or swivel) Engine or prime mover
  • external combustion runner or swivel
  • internal and external combustion runner (or swivel) engine and runner (or swivel) pump or heat pump or vacuum pump
  • baffles 51 and transmission rods 921 are drawn at overlapping positions for ease of explanation.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and the runner 1 can also be manufactured to rotate in the opposite direction; the fuel feeder 72
  • the supplied pressured fuel enters the combustion chamber 03 and is ignited by the igniter 73 to generate thermal gas. It directly enters the power chamber 02 to perform work.
  • the baffle 51 is pushed, the runner 1 can be rotated, and the arrow to C1 is rotated.
  • the other baffle 51 is pushed again, so that the previous baffle 51 reaches the air outlet 240, so that After the work is performed, the air is discharged, and at the same time, the rotating plate 54 on the runner 1 is opened to form an air inlet 230. Since the air supplied by the axial-flow air compression cylinder 12 has a certain pressure, the air flows in from this air inlet 230, and The exhaust gas is blown out. When it is turned to C2, the other baffle 51 is forced to continue to push the runner 1 to rotate, forcing the baffle 51 to enter the compressed air stage, and at the same time, the swivel plate 54 is closed due to the pulling force of the tension spring 916.
  • thermometer 83 fixed at 240, which can measure the exhaust gas Temperature, and output a signal.
  • the water spray device outside the starter sprays water with pressure into the combustion chamber 03 and the power chamber 02 through the water sprayer 81 to make the temperature of the rotary engine Keep it within the specified range, so that the power can be increased, the operating temperature can be controlled, and the water vapor formed by the heating of the water can be reacted with or harmful to the harmful gases in the exhaust gas or / adsorbed or / injected into the energy based on the acidity and alkalinity of the combustion gas.
  • the arrows indicated by C4 are the beginning of work
  • the arrows indicated by C1 are the end of work
  • the arrows indicated by C1 to C2 are the exhaust and intake phases
  • C2 to C3 are the compressed air phases.
  • the outer wall of the runner 1 is circular
  • the inner wall of the casing 2 is an eccentric smooth wall surface. It can be seen from FIG. 15 that as the runner 1 rotates, the transmission lever 921 keeps reciprocating, so that the distance between each pair of baffles 51 remains relatively constant, and each pair of baffles 51 can keep reciprocating at the same time.
  • baffle 51 moves so that the extended end of the baffle 51 is always kept sealed with the smooth sliding wall surface during operation.
  • Each baffle 51 passes through four stages of inhalation, compression, work, and exhaust during one rotation, and enters the compression stage after inhalation. In this way, the reciprocating rotation becomes an internal combustion runner (or Swivel) engine.
  • the runner 1 turns on the turn plate 54 After opening, a strip-shaped air inlet 230 is formed.
  • the runner 1 has an axial flow air compression cylinder 12 connected as a whole or / fixedly connected or / fixedly installed.
  • At least one set of various air inlets, air outlets, fuel injectors, igniters, water sprayers, and temperature detectors may be further provided at corresponding positions on the casing 2 to realize the runner. (Or swivel) 1 Bidirectional rotation.
  • Embodiment 16 to 22 are an external view, a structural cross-sectional view, and a working cross-sectional view of Embodiment 5 of the present invention;
  • Embodiment 5 provides an internal combustion runner (or swivel) engine with air compression in the same working unit.
  • the cavity 01 and the power cavity 02. The structure of this embodiment can be manufactured to have a working unit or / at least two working units connected in series or / parallel or / serial / parallel or / phase set or / combined with at least two structural relationships.
  • each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) ) Engine (or prime mover), wind turbine (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, and runner ( Or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner or swivel) Engine (or prime mover), wind turbine (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, and runner ( Or swivel) pump (or heat pump or vacuum pump).
  • FIG. 16 is an external view of Embodiment 5 of the present invention.
  • the runner (or swivel) engine is composed of runner 1, casing 2, end caps 3 and 4, burner 7, and temperature measurement spray.
  • the water wheel 8 is composed of a runner 1 installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected to the axial-flow air compression cylinder 12, the lower part of the casing 2 is fixedly connected to the mounting base 21, and the mounting base 21 has mounting holes.
  • the housing 2 has an air inlet 230, an air outlet 240, and mounting holes 220 for the end caps 3 and 4, the housing 2 is equipped with a burner 7 and a temperature measuring sprinkler 8, and the housing 2 also has an injection port.
  • the appearance of the end cap 3 is a disc, with a shaft hole 310 in the center, outside the shaft hole 310 is an air inlet 330, and there are some installations around the end cover 3 Hole 320; the end cover 4 is also a disc, and there are some mounting holes 420 and an air outlet 440 at the periphery.
  • the air outlet 440 is through and is connected with the air outlet 240 on the casing 2.
  • FIG. 17 is an external view of the casing 2 in FIG. 16 after reversing.
  • the casing 2 There is an inner body 271, and an inner air outlet 240 is provided on the inner body 271, which communicates with the air outlet 240 seen in FIG. 16 to form an air outlet channel together.
  • FIG. 18 is an external view of the runner 1 in FIG. 16 after reversing.
  • the runner 1 is fixedly connected to the axial flow air compression cylinder 12, and the axial flow air compression cylinder 12 and the power output shaft 11 are also fixedly connected.
  • FIG. 19 is an external view of the end cover 4 after reversing in FIG. 16.
  • the periphery of the end cover 4 has an air inlet 430, an air outlet 440, and some mounting holes 420.
  • the recessed circular groove has a vent in the circular groove which communicates with the air inlet 430, so that the air entering the circular groove can flow out from the air inlet 430.
  • FIG. 20 is an external view of the end cover 3 after reversing in FIG. 16. As can be seen from the figure, there are some mounting holes 320 at the periphery of the end 3 and a shaft hole 310 at the center for passing through the power output shaft 11. There is also an air inlet 330 to allow air to enter the runner engine.
  • FIG. 21 is a cross-sectional view of the combined structure of the fifth embodiment of the present invention. From the figure, the mutual structure of the runner 1, the casing 2, the end covers 3 and 4, the baffle 52, and the like can be seen; the axial air compression in the runner 1 The air compression cross section of the cylinder 12 gradually decreases from right to left, and the rotation of the vortex blades achieves the purpose of compressed air; the inner wall of the casing 2 has two inner bodies 271, and the baffle 52 rotates with the runner 1. The pressure of the inner body 271 is pressed into the runner 1. After the baffle 52 rotates through the wattle of the inner body 271, it is pushed out by the thrust of the spring 911.
  • the air inlet 2320 of the power chamber 02 is seen in the figure, and the high-temperature and high-pressure gas that pushes the baffle 52 to perform work enters the power chamber 02 through the air inlet 2320.
  • the installation position of the roller 94 and the sealing ring 961 can also be seen from the figure.
  • FIG. 22 is a working cross-sectional view of the fifth embodiment of the present invention. This figure can best explain the working situation of the fifth embodiment of the present invention.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the line arrows indicate the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction.
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the shell 2 is a circular shape with two inner wattles 271. At least one or / at least one contact surface is between the outer wall of the runner 1 and the two inner wattles.
  • the air enters through the air inlet 2310.
  • the baffle 52 After the baffle 52 passes through the inner body 271 inside the casing 2, it is pushed out by the spring 911 and compresses the incoming air to form the air compression chamber 01.
  • the air pushes the valve block 971 through the air outlet 2410 and enters the air storage chamber 201 in the casing 2.
  • the pressured air in the air storage chamber 201 pushes the valve block 972 into the power chamber 02 through the air inlet 2320.
  • the combustion in the chamber 02 generates thermal work and pushes the baffle 52 to rotate the entire runner 1.
  • the exhaust gas after the work is completed is pushed to the air outlet 2420 and discharged.
  • the baffle 52 reaches the position indicated by the arrow D1, it enters the air compression stage.
  • the compression ends.
  • the position indicated by the arrow D3 After reaching the position indicated by the arrow D3, it enters the work stage and reaches the position indicated by the D4 position.
  • the work is finished; the burner 7 and the temperature measuring sprayer 8 are installed on the casing 2 forming the power chamber 02, and the gaskets 962 and 963 are installed.
  • the spring 911 in the figure can push away the baffle 52, the spring 913 can control the valve block 971 to circulate pressured air in one direction, and the spring 914 can control the valve block 972 to circulate pressured air in one direction.
  • the ejection baffle 52 may also be ejected by using a transmission mechanism, which will be described in the following embodiments.
  • Embodiment 6 provides an internal combustion runner (or swivel) engine with air compression in the same working unit Cavity 01 and power cavity 02, the structure of this embodiment can be manufactured to have one working unit or / at least two working units connected in series or / parallel or / serial / parallel or / phase set or / at least two structural relationship combinations Internal combustion runner (or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the structure of this embodiment can also be manufactured as a fluid runner (or rotor Body) engine (or prime mover), wind turbine (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (Or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner or rotor Body
  • FIG. 23 is an external view of Embodiment 6 of the present invention. It can be seen from the figure that the axial flow air compression cylinder 12 is fixedly connected to the runner 1, the three external bodies 14 are fixedly connected to the runner 1, and the lower part of the casing 2 is fixed. Connected to the mounting base 21, there are mounting holes 210 on the mounting base 21, and mounting holes 220 on the periphery of both ends of the casing 2 can be installed end caps 3 and 4, the casing 2 also has an air outlet 240, which is connected to The inner wall of the casing 2 is provided with a protrusion and a cylinder on both sides of the casing 2. A baffle 52 is installed in the protrusion. The cylinder port is closed by a cover 931.
  • the casing 2 is also provided with a burner. 7 and temperature measuring sprinkler 8;
  • the end cap 3 is a circular disk, with a through-hole shaft hole 310 at the center for passing through the power output shaft 11, and some mounting holes 320 around the end cap 3 for
  • the end cover 3 is installed on the casing 2 and a hollow disk is fixed on the end cover 3.
  • the disk is equipped with rollers 94 and can be inserted into one end of the runner 1.
  • the disk also has two symmetrical straight grooves 370.
  • the injection port 350 can be filled with lubricating oil, so that the roller 94 can roll flexibly;
  • the end cap 4 is a hollow disk, and the hollow part extends out of the cylinder to form
  • the air inlet 430, the roller is also installed in the disc 94, can be inserted into the other end of the runner 1, the periphery of the end cover 4 has some mounting holes 420 and a straight air outlet 440, the air outlet 440 and the casing 2
  • the air outlet 240 is butted, and the end cover 4 also has an injection port 450, which can be filled with lubricating oil, so that the roller 94 can roll flexibly in the end cover 4.
  • FIG. 24 is an external view of the casing 2 in FIG. 23 after reversing. As can be seen from the figure, there is an air inlet 230 on the periphery of the casing 2 to supply air to the air compression chamber 01. There is also an air inlet 2320 of the power chamber 02 in the middle section, and the burner 7 is also installed there.
  • FIG. 25 is an external view of the runner 1 after being reversed in FIG. 23.
  • the runner 1 is composed of an axial-flow air compression cylinder 12 and a power output shaft 11.
  • the runner 1 is fixedly connected to three external parts. Wai Jing body 14.
  • FIG. 26 is an external view of the end cover 4 after reversing in FIG. 23. It can be seen from the figure that a hollow disk is fixedly connected to the end cover 4. Rollers 94 are installed in the disk, and the disk has two symmetrical straight The slot 470, the air outlet 440, the mounting hole 420 and the air inlet 430 all pass through the end cover 4.
  • FIG. 27 is an external view of the end cap 3 in FIG. 23 after being reversed. As can be seen from the figure, the center Both the shaft hole 310 and the mounting hole 320 pass through the end cover 3.
  • FIG. 28 is a cross-sectional view of the combined structure of Embodiment 6 of the present invention.
  • the structures of the runner 1, the casing 2, the end covers 3 and 4, the baffle 52, and the like can be seen from the figure.
  • the runner 1 is installed in the casing 2.
  • a baffle 52 and a spring 911 are installed in the protruding body of the casing 2 and the cylinder. Both ends of the runner 1 are inserted into the hollow disks of the end covers 3 and 4, and rollers 94 are installed at positions where they contact.
  • FIG. 29 is a working cross-sectional view of the sixth embodiment of the present invention. This figure can best explain the working situation of the sixth embodiment of the present invention.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the line arrows indicate the turning direction of the runner 1, and it can also be made that the runner 1 rotates in the opposite direction.
  • the outer wall of the runner 1 has three outer bodies 14, and the inner wall surface of the casing 2 is a circle. Shape, there is at least one or / at least one contact surface between each of the inner wall of the casing 2 and the three outer bodies 14 on the runner 1. When the whole runner 1 rotates, the outer bodies 14 push the baffle 52.
  • the wattage of the outer wattle body 14 turns to the position indicated by the arrow E1, and air enters from the air inlet 230.
  • the air compression chamber 01 disappears, and then the E3 arrow indicates In the position, the baffle 52 is extended to form two spaces in front and back. Its front space forms the power chamber 02, the rear space forms the air compression chamber 01, and the air compressed by the air compression chamber 01 pushes the valve block 971 through the air outlet 2410.
  • the function of the springs 913 and 914 is that the gas must have a certain pressure to open the valve blocks 971 and 972, and it can also stop the gas Backflow.
  • the casing 2 is fixedly provided with a burner 7 and a temperature measuring sprinkler 8, and is further provided with gaskets 962 and 963.
  • the port of the cylinder to which the spring 911 is installed is closed by a cover 931.
  • FIG. 7 shows an internal combustion runner (or swivel) engine. Its air compression unit and work unit are composed of separate swivel (rotor) 1.
  • the structure of this embodiment can be manufactured as An internal combustion runner (or swivel) engine composed of at least one air compression unit and at least one work unit, each air compression unit can be manufactured with at least one air compression chamber 01, and each work unit can be manufactured with at least one power Cavity 02, each working unit is connected in series or / parallel or / serial / parallel or / phase set or / at least two of the above structural relationships; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or original Motive), wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or swivel) pump (Or heat pump or vacuum pump).
  • a fluid runner (or swivel) engine or original Motive
  • wind runner (or swivel) engine or prime mover
  • external combustion runner or swivel
  • FIG. 30 is an external view of Embodiment 7 of the present invention. As can be seen from the figure, it is composed of a runner 1, a casing 2, end caps 3 and 4, two burners 7, and two temperature measuring sprayers 8.
  • the rotor 1 is installed in the housing 2 and can be rotated.
  • the lower part of the housing 2 has a mounting base 21, a mounting hole 210 on the top, and mounting ears on the periphery of both ends of the housing 2.
  • the casing 2 has air inlets 230, outlet gas 241, and inlet pipe 232.
  • the outlet gas 241 is hollow.
  • the storage cylinder 981 is in communication with the casing 2.
  • the intake pipe 232 is a power chamber 02 for supplying the pressured air in the air storage cylinder 981 into the casing 2, so that the fuel supplied by the burner 7 can be in the power chamber 02.
  • the casing 2 is equipped with two burners 7 and two temperature measuring sprinklers 8;
  • the end cover 3 is a disc with a circular groove, and there are some mounting ears on its periphery.
  • the end cap 4 is a disc, There are some mounting ears on the periphery.
  • a fixed straight shaft 481 protrudes from the inner side of the end cover 4.
  • FIG. 31 is an external view of the casing 2 after reversing in FIG. 30. It can be seen from the figure that the casing 2 has an air inlet 240, and the exhaust gas is discharged therefrom, and the casing 2 has an inner body 271 therein.
  • FIG. 32 is an external view of the turning wheel 1 in FIG. 30 after reversing. It can be seen from the figure that there is no axial flow air compression cylinder in the turning wheel 1, the turning wheel 1 is directly connected to the power output shaft 11, and there are three on the turning wheel 1.
  • Each disk is provided with a sealing ring 961 on the outer wall of the disk, and two baffles 52 are symmetrically arranged between the two disks. The baffle 52 can move in a straight groove of the disk.
  • FIG. 33 is an external view of the end cover 3 in FIG. 30 after the direction is reversed. As can be seen from the figure, the shaft hole 310 and the mounting hole 320 pass through the end cover 3.
  • FIG. 34 is an external view of the end cap 4 after reversing in FIG. 30.
  • the end cap 4 has a round bar groove that can be inserted into one end of the runner 1, and the center of the end cap 4 extends a fixed
  • the straight shaft 481 is also provided with two convex shafts 432.
  • Embodiment 7 is a sectional view of the combined structure of Embodiment 7 of the present invention. From the figure, the combined structure of the runner 1, the casing 2, the end covers 3 and 4, the baffle 52, and the like can be seen; the air compression chambers 01 and The power chamber 02 works on two wheels.
  • the air inlet 230 in the figure corresponds to the air compression wheel, and the two burners 7 correspond to the power wheels. They are connected as a whole; the inner and end covers of the runner 1.
  • a roller 94 is installed, and the injection port 450 at the shaft center of the end cap 4 passes through the straight shaft 481 to the roller 94 installed in the runner 1, and can provide lubricant for the roller 94.
  • the rollers 94 in the end caps 3 and 4 are supplied with lubricating oil through the injection ports on the end caps. It can be seen from the figure that two burners 7 are installed at the two air inlets 2320 of the power chamber 02, each The wheel is provided with two symmetrical baffles 52. The baffle 52 is extended by two convex shafts 482 fixed on the straight shaft 481. It can also be seen from the figure that the three disks of the wheel 1 are installed. At the positions of the three sealing masses 961, the power output shaft 11 extends outside the end cover 3.
  • FIG. 36 is a working cross-sectional view of the air compression unit in the seventh embodiment of the present invention, which can explain the operation of the air compression unit in the seventh embodiment of the present invention.
  • the dashed line and the arrow in the figure indicate the flow of air.
  • the inner arc arrow indicates the rotation direction of the runner 1, and it can also be manufactured to turn the runner 1 in the opposite direction.
  • the outer wall surface of the runner 1 is circular, and the inner wall surface of the casing 2 is a belt.
  • the inner wall radius of the casing 2 becomes smaller, forcing The baffle 52 is gradually pushed in, and when it is transferred to the wattle of the inner body 271, the baffle 52 is completely pushed in.
  • This repeated rotation can compress the air.
  • the compressed air pushes open the valve block 971 and enters the air storage cylinder 981 through the air outlet 2410 in the gas outlet 241.
  • the spring 913 can make the valve block 971 flow under pressure in one-way gas. Open.
  • FIG. 37 is a working cross-sectional view of a work unit in Embodiment 7 of the present invention, which can explain the work situation of the work unit in Embodiment 7 of the present invention.
  • the dotted line and the arrow in the figure indicate the flow of gas, fuel, and water.
  • the arc arrow inside the wheel 1 indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction.
  • the outer wall surface of the wheel 1 is circular, and the inner wall surface of the casing 2 It has a circular shape with an inner body 271. There is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner body 271 on the inner wall of the cabinet 2.
  • the baffle 52 After turning to the position indicated by the arrow F6, as the radius of the inner wall of the casing 2 gradually becomes smaller, the baffle 52 will be gradually pushed in. When transferred to the wattle of the inner body 271, the baffle 52 is fully pushed in; Exhaust gas after combustion in the power chamber 02 is discharged from the air outlet 240 with the rotation of the baffle 52.
  • the casing 2 is also equipped with a temperature measuring sprinkler 8, seals 962 and 963, and a spring 914 can control the pressure of the valve block 972. Gas flows in one direction.
  • Embodiment 8 provides an internal combustion runner (or swivel) engine, and its air
  • the compression unit and the work unit are composed of separate swivel (rotor) 1.
  • the structure of this embodiment can be manufactured as an internal combustion rotor (or swivel) engine with at least one air compression unit and at least one work unit.
  • Each air compression unit can be manufactured to have at least one air compression chamber 01, and each work unit can be manufactured to have at least one power chamber 02.
  • Each working unit is connected in series or / parallel or / series and parallel or / phase set or / at least two of the above Combination of structural relationships; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), and an external combustion runner ( (Or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or swivel) pump (or heat pump or vacuum pump).
  • FIG. 38 is an external view of Embodiment 8 of the present invention. As can be seen from the figure, it is composed of a runner 1, a casing 2, end caps 3 and 4, a burner 7, a temperature measuring sprinkler 8, and an air storage cylinder. 981 and other components.
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected to the axial flow air compression cylinder 12, the axial flow air compression cylinder 12 is fixedly connected to the power output shaft 11, and the power output shaft 11 has One external body 111, the runner 1 is connected to two external bodies 14; the lower part of the casing 2 has a mounting seat 21, the mounting seat has a mounting hole 210, and the two ends of the casing 2 have some mounting holes 220 for Install end caps 3 and 4.
  • the upper part of the casing 2 has two upper protrusions. They are equipped with a baffle and a transmission mechanism.
  • the casing 2 has an extension tube 241, which is used to pass the air compressed by the air compression chamber 01.
  • the casing 2 is provided with a burner 7 and a temperature measuring water sprayer 8, the burner 7 has a fuel supply inlet and an intake pipe 232, and the intake pipe 232 Pressurized air flows into the burner 7;
  • the end cap 3 is a hollow disk with some mounting ears on the periphery, mounting holes 320 on the ears, and the center There is a shaft hole 310.
  • the wall of the shaft hole 310 is provided with a roller 94.
  • the outer side of the disc has a protruding cylinder.
  • An air inlet 330 is formed in the cylinder.
  • the inner diameter of the end cap 3 is smaller than the outer diameter. It can be inserted into the machine.
  • the end cap 3 inserted into the casing 2 has a straight groove 370 and a straight hole 3210; the end cap 4 is a disc with a circular groove on the inside, and the periphery of the disc has some mounting ears.
  • the shaft hole 410 can pass through
  • the inner diameter of the power output shaft 11 and the end cover 4 is smaller than the outer diameter. It can be inserted into the casing 2.
  • the end cover 4 inserted into the casing 2 has a straight groove 470 and a straight hole 4210.
  • the straight hole 4210 is installed inside Push rod 9211, the lower end of the push rod 9211 is bent.
  • FIG. 39 is an external view of the turning wheel 1 in FIG. 38 after reversing. As can be seen from the figure, one end of the turning wheel 1 is closed, and the surface of the closed body has a circular groove 101 with a convex point, and the outer body 14 is connected to two sections outside the runner 1, forming two wheels.
  • FIG. 40 is a sectional view of the combined structure of FIG. 38. From the figure, the combined structure of the components can be seen.
  • the power output shaft 11 is inserted into the end cover 3, penetrates the end cover 4, is inserted into the end cover 3, and passes through the end cover 4.
  • a roller 94 is installed, and a roller 94 is also installed on the inner wall of the middle part of the casing 2.
  • the power output shaft 11 also has an outer body 111 on one end of the end cover 3, which can push the push rod 921 to move when rotating The push rod 921 in turn pushes the rotating rod 922 to rotate.
  • the rotating rod 922 rotates with 9221 points as a turning point.
  • a small amount of the push rod 921 is used to push one end of the rotating rod 922 to produce a larger one at the other end of the rotating rod 922.
  • the circular groove 101 on the surface of the closed body at the right end of the runner 1 is inserted into the bend of the lower end of the push rod 9211.
  • the push rod 9211 can be pushed to move, and the push rod 9211 in turn pushes the rotation rod 922 to rotate.
  • the rotation rod 922 rotates with 9221 points as a turning point.
  • FIG. 41 is a working cross-sectional view of the air compression unit in the eighth embodiment of the present invention, which can explain the operation of the air compression unit in the eighth embodiment of the present invention.
  • the dotted line and the arrow in the figure indicate the process of air flow.
  • the arc arrow in the middle indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction.
  • the outer wall surface of the wheel 1 is a circular shape with an outer body 14
  • the inner wall surface of the casing 2 is circular, and there is at least one or / at least one contact surface between the outer body 14 on the runner 1 and the inner wall of the casing 2;
  • Air enters the air compression wheel from the axial flow air compression cylinder 12 through the air inlet 130 in the outer body 14.
  • the baffle 51 is pushed by the rotating rod 922, and instantly
  • the outer wall of the runner 1 contacts to form the air compression cavity 01, and the outer body 14 can continue to rotate to compress the air.
  • the compressed air pushes the valve block 971 through the air outlet 2410 and enters the air storage cylinder 981.
  • the spring 913 can control the valve Block 971 circulates air under pressure in one direction.
  • FIG. 42 is a working cross-sectional view of a work unit in the eighth embodiment of the present invention, which can explain the work situation of the work unit in the eighth embodiment of the present invention.
  • the dotted line and the arrow in the figure indicate the flow of gas, fuel, and water.
  • the arc arrow inside the wheel 1 indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction.
  • the outer wall surface of the wheel 1 is provided with two external bodies 14
  • the inner wall surface of the casing 2 is circular. There is at least one or / at least one contact surface between each of the two outer bodies 14 on the runner 1 and the inner wall of the casing 2.
  • the air in the air storage cylinder 981 has pressure.
  • the valve block 972 is pushed open, supplied to the burner 7 through the intake pipe 232, and then enters the power chamber 02 through the air inlet 2320, and the fuel supplied by the burner 7 is burned in the power chamber 02 to generate thermal work to promote the external body 14.
  • the spring 914 in the air storage cylinder 981 is the control valve block 972 that can only circulate the air under pressure in one direction.
  • the push rod 922 pushes it.
  • the baffle 51 can be pushed instantly
  • the power chamber 02 is formed by contact with the outer wall of the runner 1.
  • the exhaust gas in the power chamber 02 after the work is turned to the outlet 240 is discharged with the runner 1.
  • the casing 2 is also equipped with a temperature measuring sprinkler 8, a seal ring 962 and 963.
  • Embodiment 9 provides an external combustion runner (or swivel) engine, an air compression unit and a work unit thereof. It is composed of separate swivel (rotor) 1.
  • the structure of this embodiment can be manufactured as an external combustion rotor (or swivel) engine composed of at least one air compression unit and at least one work unit, each air compression unit Can be manufactured with at least one air compression chamber 01, each work unit can be manufactured with at least one power chamber 02, each working unit is connected in series or / parallel or / series and parallel or / phase set or / at least two of the above
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an internal combustion runner (or runner Body) engine, internal and external combustion type runner (or swivel) engine and runner (or swivel) pump (or heat pump or vacuum pump).
  • FIG. 43 is an external view of Embodiment 9 of the present invention, which is composed of a runner 1, a casing 2, end caps 3 and 4, a burner 7, an air storage burner 982, and the like. It is installed in the casing 2 and can be rotated.
  • Axial-flow air compression cylinder 12 is fixedly connected to the runner 1, and the power output shaft 11 is fixedly connected to the axial-flow air compression cylinder 12.
  • the two ends of the runner 1 each have two symmetrical straight
  • a round rod 511 protruding from the runner 1 is installed in a straight slot; the lower part of the casing 2 is provided with a mounting seat 21, and the mounting seat 21 has a mounting hole for mounting a runner engine.
  • the two ends of the casing 2 have some ends.
  • Covers 3 and 4 have mounting holes 220.
  • the upper part of the cabinet has an air inlet 230, an outlet gas 241, and an inlet pipe 232.
  • the outlet gas 241 and the inlet pipe 232 are connected to the air storage burner 982, and the air storage burner 982 is equipped with combustion.
  • the temperature measuring water sprayer is not shown in this figure, but it can be set on the casing 2 or the air storage burner 982.
  • the end cap 3 is a disc with a circular groove, and the periphery of the disc has mounting ears.
  • a seal 961 is installed on the outer ring of the air outlet 340, and an outer ring is provided in the round groove of the end cover 3.
  • Jing body 381, the outer Jing body 381 can push the baffle installed in the runner 1 to move when the runner 1 rotates;
  • the end cover 4 is a disc, and there are some mounting ears on the periphery, and there are mounting holes on the ears 420, a shaft hole 410 is provided at the center of the end cover 4, a roller 94 is installed on the wall of the shaft hole 410, and the power output shaft 11 can be inserted.
  • the end cover 4 also has an air inlet 430.
  • FIG. 44 is an external view of the turning wheel 1 in FIG. 43 after reversing.
  • the turning wheel 1 has four disks, and the two disks constitute a wheel.
  • the symmetrical baffle plate 51 has two symmetrical straight grooves on each disc. The baffle plate 51 can be moved in the straight groove.
  • the baffle plate 51 has a round rod 511 that protrudes out of the rotary wheel 1.
  • FIG. 45 is a cross-sectional view of a combined structure according to a ninth embodiment of the present invention, and each part can be seen from the figure
  • the baffle 51 When the baffle 51 is turned to the outer body 81 of the housing 2, the round rod 511 connected to it is taken by the outer body 281 inside the housing 2 and the outer body 381 inside the end cover 3. It is pushed by the outer body 481 in the end cover 4 to force the baffle 51 to protrude.
  • the baffle 51 is turned to the inner body 271 of the housing 2, it is pressed in by the inner body 271; the air inlet 230 corresponds to It is an air compression wheel, and the intake pipe 232 corresponds to a power wheel.
  • the gas supplied by the intake pipe 232 enters the power wheel through the air inlet 2320.
  • FIG. 46 is a working cross-sectional view of the air compression unit in the ninth embodiment of the present invention. This figure can explain the operation of the air compression unit in the ninth embodiment of the present invention.
  • the dashed line and the arrow in the figure indicate the air flow process.
  • the arc arrow indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction. It can be seen from the figure that the outer wall surface of the runner 1 is a circular shape, and the inner wall surface of the casing 2 is a circular shape with an inner body 271.
  • the outer wall of the rotor 1 and the inner body on the inner wall of the casing 2 There is at least one or / at least one contact surface between 271; when the runner 1 rotates, air enters the machine from the air inlet 230, the baffle 51 turns to the wattle of the inner body 271, and the baffle 51 begins to extend. With the rotation, the baffle 51 is fully extended to contact the inner wall of the casing 2 to form an air compression chamber 01. The compressed air is pushed through the air outlet 2410 to open the valve body 971 and enter the air storage combustion cylinder 982.
  • the spring 913 can control the valve
  • the body 971 can flow gas under pressure in one direction.
  • FIG. 47 is a working cross-sectional view of a work unit in a ninth embodiment of the present invention. This figure can explain the work situation of the work unit in the ninth embodiment of the present invention.
  • the dashed line and the arrow in the figure indicate the flow of gas and fuel.
  • the inner arc arrow indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction. It can be seen from the figure that the outer wall surface of the runner 1 is a circular shape, and the inner wall surface of the casing 2 is a circular shape with an inner body 271.
  • the outer wall of the rotor 1 and the inner body on the inner wall of the casing 2 There is at least one or / at least one contact surface between 271; when the pressured air in the air storage combustion cylinder 982 pushes open the valve body 972 into the combustion After combustion with the fuel supplied by the burner 7, the high-temperature and high-pressure gas is generated in the chamber, which enters the power chamber 02 in the casing 2 through the air inlet pipe 232 and the air inlet 2320, generates thermal work, and pushes the baffle 51 to make the rotation After the wheel 1 rotates, the baffle 51 is turned to the wattage of the inner body 271, and the baffle 51 starts to extend.
  • the baffle 51 With the rotation, the baffle 51 is fully extended to contact the inner wall of the cabinet 2 to form a power chamber 02.
  • the rear exhaust gas is discharged from the air outlet 240; the spring 914 can control the valve block 972 to circulate the pressured air in one direction, and a seal ring 962 is also installed at the burner 7.
  • Embodiment 10 provides an internal combustion runner (or swivel) engine.
  • the air compression unit and the work unit are composed of
  • the separated swivel (rotor) is made up of 13 ⁇ 4.
  • the structure of this embodiment can be manufactured as an external combustion rotor (or swivel) engine composed of at least one air compression unit and at least one work unit.
  • Each air compression unit can Manufactured with at least one air compression cavity 01, each work unit can be manufactured with at least one power cavity 02, and each working unit is connected in series or / parallel or / series / parallel or / phase set or / at least two structural relationship combinations above;
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) engine ⁇ Internal and external combustion runner (or swivel) engine and runner (or swivel) pump (or heat pump or vacuum pump).
  • FIG. 48 is an external view of Embodiment 10 of the present invention. As can be seen from the figure, it is composed of a runner 1, a casing 2, end caps 3 and 4, a burner 7, a temperature measuring sprinkler 8, and the like. It is installed in the case 2 and can be rotated.
  • the axial flow air compression cylinder 12 is fixedly connected to the runner 1.
  • the lower part of the case 2 has a mounting seat 21, the mounting seat 21 has a mounting hole 210, and the periphery of both ends of the casing 2 has Some end cover installation holes 220 and some vent holes 280, and the casing 2 is also provided with a burner 7 and a temperature measuring sprinkler 8; the end cover 3 is a circular disk with a circular groove, and a shaft hole 310 in the center is always open. , There are some mounting holes 320 and some vent holes 330 in the periphery, and three air outlet holes 340.
  • the round cover of the end cover 3 can be inserted into one end of the runner 1.
  • the end cover 4 is a circular disk with a circular groove, and the circular groove can be inserted.
  • At the other end of the runner 1 there are mounting holes 420 on the periphery of the end cap 4, which extend outside the end cap 4.
  • a round tube is formed to form an air inlet 430, and an air filter can be arranged in the air inlet 430.
  • FIG. 49 is an external view of the runner 1 in FIG. 48.
  • the runner 1 is externally connected as one body or / fixedly connected or / fixedly installed four disks, and the two disks form a pair to form air.
  • Compression wheels and power wheels, each disc has an arc-shaped groove.
  • the air compression wheel is provided with a rotating plate 54 and an elastic piece 541.
  • the rotating plate 54 can rotate in the arc-shaped groove.
  • the power wheel is provided with a rotating plate 53 and an elastic piece 531.
  • the rotating plate 53 can rotate in the solitary groove.
  • the figure also shows a power output shaft 11 which is fixedly connected to the axial-flow air compression cylinder 12.
  • FIG. 50 is a working cross-sectional view of a work unit in Embodiment 10 of the present invention.
  • This figure can explain the work of the work unit in Embodiment 10 of the present invention.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrow in 1 indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction. It can be seen from the figure that the outer wall surface of the runner 1 is a circular shape, and the inner wall surface of the casing 2 is a circular shape with an inner body 271.
  • the outer wall of the rotor 1 and the inner body on the inner wall of the casing 2 There is at least one or / at least one contact surface between 271; when the pressured air enters the power chamber 02 through the air inlet 2320, and the fuel supplied by the burner 7 is burned in the power chamber 02, thermal work is generated, pushing The rotating plate 53 causes the rotating wheel 1 to rotate. After the rotating plate 53 has passed through the wattle of the body 271 in the casing 2, due to the thrust of the shrapnel 531 and the high-pressure gas generated by the fuel combustion, the rotating plate 53 will quickly turn.
  • the water sprayer 8 can measure the temperature in the casing 2 and can spray water into the casing 2; the casing 2 has some ventilation holes 280 for air circulation.
  • FIG. 51 is a working cross-sectional view of an air compression unit according to the tenth embodiment of the present invention.
  • This figure can explain the operation of the air compression unit according to the tenth embodiment of the present invention.
  • the dashed line and the arrow in the figure indicate the air flow process.
  • the arc-shaped arrow indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction. It can be seen from the figure that the outer wall surface of the runner 1 is round, and the inner wall surface of the casing 2 is a round shape with an inner body 271.
  • FIG. 52 is a cross-sectional view of the combined structure of Embodiment 10 of the present invention.
  • the combined structure of each component is shown in the figure.
  • the dashed lines and arrows in the figure indicate the flow of air.
  • Air enters into the air inlet 430 on the end cover 4.
  • the air chamber 40 and the air intake chamber 40 have a plurality of ventilation holes 440 on the periphery, and air enters the plurality of ventilation holes 280 in the casing 2 from these ventilation holes 440, reaches the plurality of ventilation holes 330 on the end cover 3, and enters the end cover.
  • the hole 4410 enters the air inlet 2310 in the casing 2, enters the air compression wheel, and the air compressed by the air compression wheel flows into the air storage chamber 203 in the middle section of the casing 2, and the pressured air in the air storage chamber 203 opens the valve
  • Block 972 enters the power wheel from the air inlet 2320 and burns with the fuel supplied by the burner 7 in the power chamber 02.
  • rollers 94 are installed at the middle section of the runner 1, and balls are installed at both ends. 95.
  • the spring 914 can control the valve block 972 to circulate the pressured air in one direction.
  • the end cap 3 has an extension.
  • the exhaust pipe 34, the air compression wheel is provided with a rotating plate 54 and an elastic piece 541
  • the power wheel is provided with a rotating plate 53 and an elastic piece 531
  • the power output shaft 11 is fixedly connected to the axial-flow air compression cylinder 12, and the extended end is shown in FIG. 53
  • FIG. 57 to FIG. 57 are an external view, a structural cross-sectional view, and a working cross-sectional view of Embodiment 11 of the present invention
  • Embodiment 11 provides an internal combustion runner (or swivel) engine. Its air compression unit and work unit are composed of Separate swivel (rotor) 1 configuration.
  • the structure of this embodiment can be manufactured as an external combustion runner (or swivel) engine composed of at least one air compression unit and at least one work unit.
  • Each air compression unit can Made into At least one air compression cavity 01, and each work unit can be manufactured to have at least one power cavity 02, and each working unit is connected in series or / parallel or / series / parallel or / phase set or / at least two structural relationship combinations described above; this embodiment
  • the structure can also be manufactured into a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) engine, internal and external combustion Type runner (or swivel) engine and runner (or swivel) pump (or heat pump or vacuum pump).
  • FIG. 53 is an external view of Embodiment 11 of the present invention. As can be seen from the figure, it is composed of a runner 1, a casing 2, end caps 3 and 4, a burner 7, a temperature measuring sprinkler 8, and the like.
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected to the axial-flow air compression cylinder 12.
  • the runner 1 is fixedly connected to the outer body 14.
  • the lower part of the casing 2 is provided with a mounting base 21 and a mounting base 2. There are mounting holes 210, and the upper part of the casing 2 has two protruding cylinders.
  • the upper port of the cylinder is closed by two covers 931.
  • the casing 2 is equipped with a burner 7 and a temperature measuring sprayer 8, the machine
  • the upper end of the inner wall of the casing 2 has a straight groove 270; the end cover 3 is a circular disk with a circular groove in the middle, and a shaft hole 310 is opened at the center.
  • Its circular groove can be inserted into one end of the runner 1.
  • the end cover 4 is also a circular disk with a circular groove in the middle. The groove can be inserted into the other end of the runner 1.
  • the end cover 4 has a protruding cylinder, and the cylinder is an air inlet. 430, it has some mounting holes 420 around it.
  • FIG. 54 is an external view of the runner 1 in FIG. 53. As can be seen from the figure, three external bodies 14 are fixedly connected to two sections of the runner 1 to form an air compression wheel and a power wheel, respectively. There is an air inlet 120, and the power output shaft 11 is fixedly connected in the axial-flow air compression cylinder 12.
  • FIG. 55 is a working cross-sectional view of a work unit in the eleventh embodiment of the present invention.
  • This figure can explain the work situation of the work unit in the eleventh embodiment of the present invention.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates, and it can also be manufactured that the runner 1 rotates in the opposite direction. It can be seen from the figure that
  • the outer wall surface of the wheel 1 is provided with two outer wattle bodies 14, and the inner wall surface of the housing 2 is circular. There is at least one or two between the two outer wattle bodies 14 on the runner 1 and the inner wall of the housing 2.
  • the air under pressure enters the power chamber 02 from the air inlet 2320, and burns with the fuel supplied by the burner 7 in the power chamber 02, generating thermal work and pushing the outer body 14,
  • the runner 1 is rotated, and the outer body 14 forces the baffle 52 to retract during the rotation.
  • the spring 911 pushes the baffle 52 to extend.
  • the casing 2 extends out of the cylinder, the port of the cylinder is closed by a cover 931, and the gas after work is discharged from the air outlet 2420.
  • the periphery of the casing 2 has a plurality of ventilation holes 280.
  • the temperature measurement is installed on the casing.
  • the water sprayer can measure the temperature of the power chamber 02 and spray water to the power chamber 02.
  • FIG. 56 is a working cross-sectional view of the air compression unit in the eleventh embodiment of the present invention. This figure can explain the operation of the air compression unit in the eleventh embodiment of the present invention.
  • the dashed line and the arrow in the figure indicate the air flow process.
  • the arc arrow inside 1 indicates the direction in which the wheel 1 rotates, and the wheel 1 can also be manufactured to rotate in the opposite direction.
  • the outer wall surface of the runner 1 is a circular shape with an outer wattle body 14, the inner wall surface of the casing 2 is a round shape, and the outer wattle body 14 on the runner 1 and the inner wall of the casing 2 There is at least one or / at least one contact surface therebetween; it can be seen from the figure that air flows in from the air inlet 120 on the runner 1, because the baffle 52 is extended by the thrust of the spring 911, The outer wall contacts to form the air compression cavity 01. After the air is compressed in the air compression cavity 01, the valve block 971 is pushed out through the air outlet 2410, and the outer body 14 forces the baffle 52 to retract during the rotation.
  • the baffle 52 After the wattle part is turned over the baffle 52, the baffle 52 is pushed out by the spring 911, and the spring 9113 ⁇ 43 ⁇ 4 is extended into the cylinder of the casing 2.
  • the port of the cylinder is closed by the cover 931, and there are multiple Ventilation hole 280.
  • FIG. 57 is a cross-sectional view of the combined structure of the eleventh embodiment of the present invention.
  • the combined structure of the components can be seen from the figure.
  • the dashed lines and arrows in the figure indicate the air flow process, and air enters through the air inlet 430 on the end cover 4 Intake chamber 40, the periphery of the intake chamber 40 has a plurality of vent holes 440, and air enters the plurality of vent holes 280 in the casing 2 through the vent holes 440, and passes through the plurality of vent holes 330 in the cover 3 to the return air chamber 30
  • the air in the return air chamber 30 is fed into the axial air compression Tube 12, the compressed air enters the air compression wheel from the air inlet 120 on the air compression wheel, and the compressed air enters the air storage chamber 203 in the middle section of the casing 2 and is supplied to the power wheel; as can be seen in the figure
  • Two pieces of baffle plate 52 are respectively installed in the casing 2 corresponding to the air compression wheel and the power wheel.
  • Two springs 911 are respectively formed in two protruding cylinders on the casing 2.
  • the ports of the two protruding cylinders are formed by two
  • the cover 931 is closed, and rollers 94 are installed at both ends and the middle of the runner 1.
  • the power output shaft 11 is fixedly connected to the axial-flow air compression cylinder 12.
  • the end cover 3 has an extended exhaust pipe 34.
  • the outer surface of the cover 4 has an extended cylinder, and an air filter can be installed in the cylinder.
  • Embodiment 12 provides a rotor (or swivel) pump (or heat pump or vacuum pump).
  • the structure of the example can be manufactured as a rotor (or swivel) pump (or heat pump) that has a compression unit or / has at least two phases connected in series or / parallel or / series / parallel or / phase sets or / a combination of at least two of the above structural relationships Or vacuum pump), each compression unit can be manufactured with at least one compression chamber 01; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) Engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • FIG. 58 is an external view of Embodiment 12 of the present invention.
  • the runner 1 is a circular cylinder, which is divided into two barrel-shaped spaces in the middle, and the shaft center is connected as a whole or / fixedly connected or / Fixedly installed power input shaft 11, two pairs of symmetrical baffle plates 51 are installed between the power input shaft 11 and the runner 1, the baffle plate 51 can be reciprocated axially, and the two sides of the baffle plate 51 are inserted into the power input
  • the end covers 3 and 4 have an integrally connected housing, and the end covers 3 and 4 have symmetrical mounting holes 320 And 420, the bottom of the end caps 3 and 4 each have a mounting seat 321 and a mounting hole 3210, and the shaft centers of the end caps 3 and 4 each have a shaft hole 310 and 410 for passing in or out of the power input shaft 11
  • FIG. 59 is a sectional view of the combined structure of the twelfth embodiment of the present invention.
  • the runner 1 is completely enclosed in the end covers 3 and 4 with the housing. 1
  • One end of the upper power input shaft 11 protrudes out of the end cover 3, and the other end is just flush with the end surface of the end cover 4, and can extend out of the end cover 4, and can also be wrapped in the end cover 4.
  • Two compression units Two pairs of baffle plates 51 arranged symmetrically inside can be reciprocated axially in the runner 1.
  • a spring 911 which moves with the baffle plate 51 is installed between the two axially installed baffle plates 51.
  • FIG. 60 is a cross-sectional view of each mark in FIG. 59.
  • the rotary slope body 34 is a rotary slope body, and the slope is formed by the angle of rotation rather than the distance.
  • the tangent of the cross section is radial.
  • the gyro body 34 has only a 180-degree gyro angle, that is, the turn angle from the start to the top of the slope is only 180 degrees;
  • the cross-sectional views of G3-G3 are the sections that rise to 180 degrees, that is, the sections that reach the top of the slope. From the sections marked in the figure, the cross-section of the baffle 51, the cross-section of the outlet 340, and the cross-section of the runner 1 can be seen.
  • FIG. 61 is an external view of a thirteenth embodiment of the present invention.
  • This embodiment provides a rotor (or swivel) pump (or heat pump or vacuum pump) integrally connected to a motor.
  • the structure of this embodiment can be manufactured as A compression unit or a rotor (or swivel) pump (or a heat pump or a vacuum pump) having at least two phases connected in series or / parallel or / series / parallel or / phase sets or / a combination of at least two of the above structural relationships, each compression
  • the unit can be manufactured with at least one compression chamber 01; its structure can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), internal combustion Runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine Motivation.
  • one end of the runner 1 is a spiral cone slope body 141 and the other end is a rotor 13 of the motor.
  • the end covers 3 and 4 are There is an integrated housing, with symmetrical mounting holes 320 and 420 on the end covers 3 and 4, the bottom of the end covers 3 and 4 are provided with a mounting seat 321 and a mounting hole 3210, and the shaft centers of the end covers 3 and 4.
  • Each has a shaft hole 410 for inserting the rotating shaft 11, and an end 330 has an inlet 330 and an outlet 340.
  • the end cap 3 is provided with a baffle that reciprocates. The baffle is pushed in by the sliding wall surface of the spiral cone slope body 141 and is pushed out by a spring. The cylinder in which the spring is installed is closed by the cover 931.
  • a stator 41 of the motor is fixedly installed in the end cover 4, and the power of the stator 41 is introduced from the terminal box 42 on the end cover 4.
  • the structure of their working units is different from that of the working units of the first to eleventh embodiments of the present invention, and it forms a baffle or / rotating plate or / stopper or / rotating of the working unit.
  • the block is reciprocated or / rotated axially or obliquely, which makes these two embodiments work differently from the previous embodiments.
  • the wattle body is formed by directly processing the swivel or / end cover or isolation plate or / is fixedly connected or / fixedly installed on the swivel or / end cover or / isolated plate.
  • FIG. 62 is a working cross-sectional view of the fourteenth embodiment of the present invention; the fourteenth embodiment provides an internal combustion runner (or swivel) engine, which has an air compression chamber 01 and a power chamber 02 in the same working unit.
  • Its structure can be manufactured as an internal combustion rotor (or swivel) with one working unit or / at least two working units connected in series or / parallel or / serial / parallel or / phase set or / at least two structural relationships Engine, each working unit can be manufactured with at least one air compression cavity 01 and at least one power cavity 02, the outer wall surface of the runner 1
  • the inner wall surface of the casing 2 is circular or non-circular, there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the casing 2, the outer wall of the runner 1 and the stopper
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel, and the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction; as can be seen from the figure,
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected to the axial flow air compression cylinder 12, and the space in the axial flow air compression cylinder 12 has an oval shaft 483 fixedly connected to the end cover;
  • the runner 1 of this embodiment is provided with four pieces of baffle plates 51.
  • Each end of the baffle plate 51 is provided with a roller 94, an internal push rod 921 and a spring 911 are installed, and an end of each push rod 921 is provided with a roller. 941.
  • the roller 941 is in contact with the elliptical shaft 483.
  • the spring 911 can make the baffle There is a certain pressure when the 51 is in contact with the inner wall of the casing 2 to ensure the seal of the baffle 51 at work; air from the air inlet 2310it ⁇ After the baffle 51 rotates through the air inlet 2310, air compression occurs.
  • the compressed air pushes the valve disc 974 through the air outlet 2410, and then passes through an elbow to reach the inlet.
  • the air port 2320 enters the power chamber 02, and burns in the power chamber 02 with the fuel supplied by the burner 7, generating thermal work, pushing the baffle 51 to rotate the runner 1, and the exhaust gas after work is discharged from the air outlet 2420;
  • the upper part of the casing 2 has a protruding cylinder.
  • the cylinder is provided with a stopper 62 and a spring 915.
  • the port of the cylinder is closed by a cover 932.
  • the stopper 62 is always maintained by the spring by the thrust of the spring 915
  • the outer wall of 1 can contact the air compression chamber 01 and the power chamber 02, and the burner 7 is also installed with a sealing group 962.
  • a temperature measuring water sprayer can be installed on the casing 2.
  • FIG. 63 is a working cross-sectional view of a fifteenth embodiment of the present invention.
  • the fifteenth embodiment provides an internal combustion runner (or swivel) engine, which has an air compression chamber 01 and a power chamber 02 in the same working unit.
  • each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02.
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the casing 2 is a circular or eccentric circular ring.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), wind Runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or Vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel, and the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates.
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected with the axial-flow air compression cylinder 12, and the runner 1 is provided with four pieces of baffle plates 52.
  • the two pieces of baffle plates 52 are a pair, and each pair of baffle plates 52 can push each other through a spring 911.
  • Air enters the casing 2 from the air inlet 2310. When the baffle 52 rotates After the air inlet 2310, an air compression chamber 01 is formed to compress the air. The compressed air is pushed through the air outlet 2410 to open the valve disc 974 and enter the air storage chamber 201 in the casing 2.
  • the pressured air in the air storage chamber 201 The air pushes the valve block 972 through the air inlet 2320 and enters the combustion chamber, and burns with the fuel supplied by the burner 7.
  • the high-temperature and high-pressure gas generated after combustion enters the power chamber 02 through the air inlet 2330, and pushes the baffle 52 to make the rotation Wheel 1 rotates, the exhaust gas after work is discharged from the air outlet 2420 ;
  • Spring 914 can be controlled one-way valve 972 blocks the flow of air having a pressure; burner mounting ring 962 fitted at 7; Further, this embodiment may also be installed on the housing sprinkler temperature 2.
  • FIG. 64 is a working cross-sectional view of the sixteenth embodiment of the present invention; the sixteenth embodiment provides an internal combustion runner (or swivel) engine whose structure can be manufactured with one work unit or / with at least two The internal combustion runner (or swivel) engine in which the work units are connected in series or / parallel or in series / parallel or in combination with at least two structural relationships, each work unit can be manufactured with at least one power chamber 02, The outer wall surface of the runner 1 is circular, and the inner wall surface of the casing 2 is round.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine ( Or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction. As can be seen from the figure, The axis of the wheel 1 and the axis of the casing 2 are not at the same place.
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the runner 1 is fixedly connected to the axial-flow air compression cylinder 12, and the runner 1 is provided with four pieces.
  • Rotating rotary block 61 two of which are pushed away by spring 912, and the other two rotary blocks 61 are pushed away by spring piece 611.
  • the pressured air pushes open valve block 972 from intake port 230 into the combustion chamber, and
  • the fuel supplied by the burner 7 is twisted to generate high-temperature and high-pressure gas, enter the power chamber 02, generate thermal work, push the rotary block 61, and rotate the rotary wheel 1, and the spring 914 can control the valve block 972 to circulate the pressured air in one direction.
  • the exhaust gas after performing work in the power chamber 02 rotates with the runner 1, and is discharged from the air outlet 240.
  • the stopper 62 and the runner 1 The outer wall of the tube is in contact with each other, so that the power chamber 02 is isolated from the air outlet 240 and extends beyond the end of the cylinder. Closed by a cap 932; installed at the burner 7 is further equipped with a seal 962; Further, the housing 2 can be mounted on the sprinkler temperature.
  • FIG. 65 is a working cross-sectional view of a seventeenth embodiment of the present invention.
  • Internal combustion runner (or swivel) engine its structure can be manufactured to have one work unit or / at least two work units connected in series or in parallel or in series or parallel or in phase set or in at least two structural relationships
  • Each work unit can be manufactured with at least one power chamber 02.
  • the outer wall surface of the runner 1 is circular, and the inner wall surface of the casing 2 is provided with an inner body.
  • the shape of 271 has at least one or / at least one contact surface between the outer wall of the runner 1 and the inner body 271 on the casing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or a rotor).
  • Engine or prime mover
  • wind runner or swivel
  • external combustion runner or swivel
  • internal and external combustion runner or swivel
  • runner or Swivel
  • pump or heat pump or vacuum pump.
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be manufactured to turn the runner 1 in the opposite direction.
  • the housing 2 can be rotated, the axis of the runner 1 and the axis of the housing 2 are at the same place, the axial flow air compression cylinder 12 is fixedly connected to the runner 1, and three wheels are mounted on the runner 1.
  • the rotating blocks 61, 61 are pushed and closed by the shrapnel 611 and the inner body 271 inside the casing 2, and the pressured air pushes open the valve disc 974 from the air inlet 230.
  • the inside of the casing 2, and the combustion feeder 71 The supplied fuel is burned in the power chamber 02 after the igniter 72 o'clock, generating thermal work, pushing the rotary block 61 to rotate the wheel 1, and the water sprayer 81 and the thermometer 82 spray water to the power chamber 02 and Measure the temperature of the power chamber 02; the exhaust gas after work is discharged from the air outlet 240.
  • FIG. 66 is a working cross-sectional view of the eighteenth embodiment of the present invention.
  • the eighteenth embodiment provides an internal combustion runner (or swivel) engine whose structure can be manufactured to have one work unit or / at least two
  • the internal combustion runner (or swivel) engine in which the work units are connected in series or / parallel or in series / parallel or in combination with at least two structural relationships, each work unit can be manufactured with at least one power chamber 02
  • the outer wall surface of the runner 1 is a circular shape with an outer wattle body 14, and the inner wall surface of the casing 2 is a round shape.
  • the structure can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) engine, and internal and external combustion Runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the flow of gas and fuel.
  • the solitary line arrow in the runner 1 indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction; the axis of the runner 1 and the machine
  • the axis of the shell 2 is at the same place.
  • the runner 1 is fixedly connected to the axial flow air compression cylinder 12, the runner 1 is fixedly connected to the outer body 14, and the outer body 14 has a straight groove.
  • a stopper 62 is installed in the groove.
  • the block 62 is kept in contact with the inner wall of the casing 2 due to the thrust of the spring 911.
  • the turning block 61 is installed at the air inlet 230 on the casing 2.
  • a temperature measuring sprinkler can also be installed on the casing 2.
  • FIG. 67 is a working cross-sectional view of Embodiment 19 of the present invention.
  • Embodiment 19 provides an internal combustion runner (or swivel) engine, and its structure can be manufactured to have one work unit or / at least two
  • each work unit can be manufactured with at least one power chamber 02
  • the outer wall surface of the runner 1 is a circular shape with two outer corner bodies 15, and the inner wall surface of the casing 2 is a round shape. There is at least one between the two outer corner bodies 15 on the runner 1 and the inner wall of the housing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), external combustion Runner (or swivel) engine, internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the casing 2 are at the same position.
  • the runner 13 ⁇ 4 ⁇ machine The housing 2 can be rotated.
  • the runner 1 is fixedly connected to the axial-flow air compression cylinder 12.
  • the runner 1 is fixedly connected to the two triangular bodies 15.
  • the pressured air enters the power chamber 02 from the air inlet 230 and the burner 7.
  • the supplied fuel is burned in the power chamber 02, generating thermal work, pushing the triangular body 15 to rotate the runner 1, the spring 915 can push away the turning block 61 to form the power chamber 02, and the exhaust gas after work is discharged from the air outlet 240;
  • a temperature measuring water sprayer can also be installed on the casing 2.
  • FIG. 68 is a working cross-sectional view of Embodiment 20 of the present invention.
  • Embodiment 20 provides an internal combustion runner (or swivel) engine, and its structure can be manufactured to have one work unit or / at least two
  • the internal combustion runner (or swivel) engine in which the work units are connected in series or / parallel or in series / parallel or in combination with at least two structural relationships, each work unit can be manufactured with at least one power chamber 02,
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the casing 2 is circular or / non-circular, and there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the casing 2;
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), or an external combustion runner (or swive
  • runner Internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the wheel 1 is installed in the casing 2 and can be rotated.
  • the axial flow air compression cylinder 12 is fixedly connected to the runner 1.
  • the axial flow air compression cylinder 12 has a non-rotating crankshaft 484.
  • the crankshaft 484 is hinged with two rotatable The push rod 922 and the push rod 922 are twisted with the push rod 921 inserted into the baffle 51.
  • a spring 911 is also installed in the baffle 51.
  • Two sets of baffles 51 are installed on the runner 1, and the two sets of push rods 922 are twisted together.
  • the inner wall of the casing 2 is an eccentric inner circular body 274. Air under pressure enters the casing 2 from the air inlet 230, is fed into the fuel supplier 73 and is ignited by the igniter 72.
  • the fuel is burned in the power chamber 02, generating thermal work, pushing the baffle 51 to rotate the runner 1, and the exhaust gas after the work is discharged from the air outlet 240.
  • the casing 2 can also be To install a temperature measuring sprinkler.
  • At least one set of various air inlets, air outlets, fuel feeders, and igniters may be further provided at corresponding positions on the casing 2 to realize the runner (or swivel) 1 bidirectional Turn.
  • FIG. 69 is a working cross-sectional view of Embodiment 21 of the present invention.
  • Embodiment 21 provides an internal combustion type runner (or swivel) engine. Its structure can be manufactured with a work unit or at least An internal combustion runner (or swivel) engine in which two work units are connected in series or / parallel or in series / parallel or in combination with / at least two of the above structural relationships. Each work unit can be manufactured with at least one power chamber.
  • the outer wall surface of the runner 1 is a round shape with an outer body 14 and the inner wall surface of the casing 2 is a round shape.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), external combustion Runner (or swivel) engine, internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner (or swivel) engine or prime mover
  • external combustion Runner or swivel
  • internal and external combustion type runner or swivel
  • runner or swivel pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas, fuel, and water.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be manufactured to turn the runner 1 in the opposite direction.
  • the runner 1 is fixedly connected to the axial-flow air compression cylinder 12 inside, and the runner 1 is fixedly connected to an outer body 14.
  • the runner 1 is installed in the casing 2 and can be rotated.
  • the pressured air pushes open the valve block 972 via
  • the air inlet 2320 enters the power chamber 02, and burns with the fuel supplied by the burner 7 to generate thermal work, pushes the outer body 14, and rotates the runner 1, and the rotor 53 is quickly pushed away by the shrapnel 531 and the supplied air.
  • the power chamber 02 is formed, and the exhaust gas after work is discharged from the air outlet 2420.
  • the casing 2 is provided with a temperature measuring sprinkler 8, and the casing 2 also has some vent holes 230.
  • FIG. 70 is a working cross-sectional view of Embodiment 22 of the present invention
  • Embodiment 22 shows an internal combustion runner (or swivel) engine having two power chambers 02 in the same work unit.
  • Structure can be made with one work unit or / with at least two in series
  • An internal combustion runner (or swivel) engine that combines at least two structural relationships in combination with or in parallel or in series or in parallel or in phase sets or in a fan, each of the work units can also be manufactured with one or two In the above power chamber 02, the outer wall surface of the runner 1 is circular, the inner wall surface of the casing 2 is a circular shape with two inner corner bodies 275, and the outer wall of the runner 1 and the two inner corner bodies 275 on the casing 2
  • There is at least one or / and at least one contact surface between each; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be manufactured so that the runner 1 rotates in the opposite direction.
  • the compressed air cylinder 12, the runner 1 is provided with three rotating plates 55, and each rotating plate 55 is pushed away by the elastic piece 551, and is closed by a half-cut body 275 fixedly connected to the inner wall of the casing 2.
  • the pressured air opens the valve.
  • Block 972 enters the power chamber 02 and the fuel supplied by the burner 7 from the air inlet 2320 and burns in the power chamber 02 to generate thermal work.
  • the rotary plate 55 is pushed to rotate the runner 1, and the exhaust gas after the work is performed from the two outlets.
  • the valve block 972 the air inlet 2320, and the air outlet 2420 have two each, and the burner 7 and the temperature measuring sprinkler 8 installed on the casing 2 are also each
  • the inner wall of the casing 2 is fixedly connected to two symmetrical half-cut bodies 275, and the casing 2 also has some ventilation holes 230.
  • FIG. 71 is a working cross-sectional view of Embodiment 23 of the present invention.
  • Embodiment 23 provides an internal combustion runner (or swivel) engine. Its structure can be manufactured with a work unit or / with at least Two internal combustion rotor (or swivel) engines that are connected in series or / parallel or in series / parallel or in phase sets or / combined with at least two structural relationships described above as power units, and each power unit can be manufactured with at least one power chamber 02,
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the casing 2 is a circular shape with a tangent body 276, and at least one or / there is between the outer wall of the runner 1 and the tangent body 276 on the casing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or Swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the runner 1 is fixedly connected with the axial-flow air compression cylinder 12, and the runner 1 is externally provided with two turning plates 55.
  • the turning plate 55 is pushed away by the elastic sheet 551, and is closed by an inner cutout 276 fixedly connected to the inner wall of the casing 2.
  • the pressured air pushes open the valve block 972, enters the power chamber 02 from the air inlet 2320, and combusts with the fuel supplied by the burner 7 to generate thermal work.
  • the rotary plate 55 is pushed to rotate the rotary wheel 1.
  • the air outlet 2420 is discharged, and the temperature measuring water sprayer 8 can measure the temperature of the power chamber 02 and can spray water.
  • FIG. 72 is a working cross-sectional view of the twenty-fourth embodiment of the present invention.
  • the twenty-fourth embodiment provides an internal combustion runner (or swivel) engine, and its structure can be manufactured with a work unit or / Two internal combustion rotor (or swivel) engines that are connected in series or / parallel or I-series parallel or / phase sets or / at least two of the above structural relationships as a power unit, and each power unit can be manufactured with at least one power chamber 02, the outer wall surface of the casing 2 is circular, the inner wall surface of the runner 1 is a circular shape with an inner body 171, and at least one or between the outer wall of the casing 2 and the inner body 171 on the runner 1 / Has at least one contact surface; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion rotor Wheel (or
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows outside the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the casing 2 is inside the runner 1, and the inner wall of the runner 1 has an inner body 171 connected as one body or / fixed connection or / fixed installation; when air under pressure enters from the air inlet 230 in the twister 7
  • the fuel supplied by the power chamber 02 and the burner 7 is combusted to generate heat gas, and work is performed in the power chamber 02 to push the inner body 171 to rotate the runner 1 and the rotor mounted on the casing 2
  • the plate 54 is quickly pushed away by the elastic sheet 541 and the pressured gas.
  • a temperature measurement can be installed on the casing 2. Water sprinkler or / water sprinkler or / thermometer.
  • FIG. 73 is a working cross-sectional view of the twenty-fifth embodiment of the present invention.
  • the twenty-fifth embodiment provides an internal combustion runner (or swivel) engine, and its structure can be manufactured with a work unit or at least Two internal combustion rotor (or swivel) engines that are connected in series or / parallel or I-series parallel or / phase sets or / at least two of the above structural relationships as a power unit, each power unit can be manufactured with at least one power chamber 02.
  • the inner wall surface of the runner 1 is circular
  • the outer wall surface of the casing 2 is a circular shape with an outer body 24.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), or an external combustion runner (Or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner or swivel engine (or prime mover)
  • a wind runner or swivel) engine (or prime mover)
  • an external combustion runner Or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the flow of gas and fuel.
  • the arc arrows outside the runner 1 indicate the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the casing 2 is inside the runner 1, and the outer wall of the casing 2 has an outer body 24 which is integrated or / fixedly connected or / fixedly installed.
  • the outer body 24 has an air inlet 230 and an air outlet 240, and the runner
  • the inner wall of 1 is provided with two rotating plates 54, and elastic plates 541 are installed at the rotating plate 54.
  • the gas enters the power chamber 02 to perform work, and pushes the rotary plate 54 to rotate the rotary wheel 1.
  • the rotary plate 54 is quickly pushed away by the shrapnel 541 and the thermal gas, and is closed by the outer body 24.
  • the exhaust gas after the work is discharged from the air outlet 240 ;
  • a temperature measuring sprinkler or / water sprinkler or / temperature measuring device can be installed on the casing 2.
  • FIG. 74 is a working cross-sectional view of the twenty-sixth embodiment of the present invention.
  • the twenty-sixth embodiment provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured to have a compression unit Or / has at least two phases in series or / parallel or / serial / parallel or / phase set or /
  • the above-mentioned at least two structural relationships are combined with a rotary wheel (or swivel) pump (or heat pump or vacuum pump) of the compression unit, and each compression unit can be manufactured with at least one compression chamber 01, and the outer wall surface of the rotor 1 is circular.
  • the inner wall surface of the casing 2 is round.
  • At least one contact surface between the outer wall of the runner 1 and the inner wall of the pump casing 2. There is at least one or / there is between the outer wall of the runner 1 and the stopper 62. At least one contact surface; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), or an internal combustion runner (or Swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the runner 1 It is not at the same place as the shaft center of the pump casing 2, the axial flow compression cylinder 12 is fixedly connected to the runner 1, and two symmetrical baffles 51 are installed in the runner 1, each spring 911 in the two baffles 51 is inserted into one
  • the transmission lever 921, the transmission lever 921 can push the relative distance between the two baffles 51 during the rotation.
  • the spring 911 can finely adjust the contact force between the baffle 51 and the inner wall of the pump casing 2.
  • At least one set of various inlets and outlets may be further provided at the corresponding positions on the pump casing 2, so that the rotary wheel (or swivel body) can be turned in one direction.
  • FIG. 75 is a working cross-sectional view of Embodiment 27 of the present invention.
  • Embodiment 27 provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured with a compression unit Or / has at least two rotors (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or in series / parallel or / phase sets or / combined with at least two structural relationships above, each compression unit Can be manufactured with at least one compression chamber 01, runner 1
  • the outer wall surface of the rotor 1 is round, the inner wall surface of the pump housing 2 is round, there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the pump housing 2, the outer wall of the runner 1 and the stopper 62 There is at least one or / at least one contact surface between them; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the runner 1 Internally connected to the axial flow compression cylinder 12, two symmetrical baffles 52 are also installed in the runner 1, a push spring 911 is installed between the two baffles 52, and the axes of the runner 1 and the inner wall of the pump casing 2 are not at the same place.
  • the inner wall of the pump casing 2 has an inner chord body 274. When the runner 1 rotates, the fluid enters the pump casing 2 from the inlet 2310.
  • the upper part of the pump casing 2 has a straight groove.
  • a stopper 62 is installed in the groove. The stopper 62 is urged by the spring 915 and always contacts the outer wall of the runner 1, so that the inlet 2310 and the outlet 2410 are in the pump.
  • the upper part of the shell 2 does not form a channel.
  • At least one set of various inlets and outlets may be further provided at corresponding positions on the pump casing 2, so that the rotary wheel (or swivel body) can be turned in one direction.
  • FIG. 76 is a working cross-sectional view of the twenty-eighth embodiment of the present invention.
  • the twenty-eighth embodiment provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured with a compression unit Or / has at least two rotors (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or in series / parallel or / phase sets or / combined with at least two structural relationships above, each compression unit It can be manufactured with at least one compression chamber 01, the outer wall surface of the runner 1 is round, the inner wall surface of the pump casing 2 is round, and there is at least one or / at least one between the outer wall of the runner 1 and the inner wall of the pump casing 2.
  • the dashed line and arrow in the figure indicate the process of fluid flow.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and the runner 1 can also be manufactured to rotate in the opposite direction.
  • the runner 1 can be seen from the figure It is not at the same location as the shaft center of the pump casing 2.
  • the runner 1 is fixedly connected with the axial flow compression cylinder 12.
  • the runner 1 is provided with four turning blocks 61, two of which are pushed away by the spring 912, and the other two
  • the rotating block 61 is pushed away by the shrapnel 611, and they are all closed by the inner wall of the pump casing 2.
  • the rotating wheel 1 rotates, the fluid enters the pump casing 2 from the inlet 2310, and as the rotating block 61 rotates, a compression chamber 01 is formed, The compressed fluid flows out from the outlet 2410.
  • the upper part of the pump casing 2 has a straight groove.
  • the stopper 62 is in the groove.
  • the stopper 62 is urged by the spring 915 and always contacts the outer wall of the runner 1, so that the inlet 2310 and the outlet 2410 are at The upper part of the pump casing 2 cannot form a channel.
  • FIG. 77 is a working cross-sectional view of Embodiment 29 of the present invention.
  • Embodiment 29 provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured to have a compression unit Or / has at least two rotor (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or / serial / parallel or / phase sets or / combined with at least two of the above structural relationships, and each compression unit It can be manufactured with at least one compression chamber 01, the outer wall surface of the rotor 1 is circular, the inner wall surface of the pump casing 2 is a circular shape with an inner body 271, the outer wall of the rotor 1 and the inner surface of the pump casing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine ( Or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates, and the rotor 1 can also be manufactured to rotate in the opposite direction.
  • the axial flow compression cylinder 12 is fixedly connected, and three rotating blocks 61 are installed on the runner 1.
  • the elastic piece 611 can push away the rotating block 61, and the inner wall of the pump casing 2 is fixedly connected to the external wing body 271.
  • the external wing body 271 can push and close the rotating block. 61;
  • runner 1 rotates, fluid flows from The port 2310 enters the pump casing 2, and the rotary block 61 forms a compression chamber 01 with the rotation of the rotary wheel 1, and the compressed fluid flows out from the outlet 2410.
  • FIG. 78 is a working cross-sectional view of Embodiment 30 of the present invention.
  • Embodiment 30 shows a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured with a compression unit or /
  • a compression unit or /
  • Each compression unit can be manufactured. It is formed with at least one compression cavity 01.
  • the outer wall surface of the runner 1 is a circular shape with an outer body 14.
  • the inner wall surface of the pump casing 2 is a round shape.
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates, and the runner 1 can also be manufactured to rotate in the opposite direction.
  • the runner 1 The axial flow compression cylinder 12 is fixedly connected internally, and a fault is formed on the scrolls constituting the axial flow compression cylinder 12.
  • a fault is formed on the scrolls constituting the axial flow compression cylinder 12.
  • the inlet 1310 of the body 14 enters the pump casing 2.
  • the outer body 14 rotates with the runner 1 to form a compression chamber 01.
  • the compressed fluid pushes open the valve disc 974 and is pushed out from the outlet 2410.
  • the pump casing 2 is provided with a rotating block. 61.
  • the rotating block 61 is pushed out by the spring 912, and is in contact with the outer wall of the rotating wheel 1.
  • the port where the spring 912 is installed is closed by the cover 931.
  • FIG. 79 is a working cross-sectional view of the thirty-first embodiment of the present invention.
  • the thirty-first embodiment provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured to have a compression unit Or / has at least two rotors (or swivels) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or in series / parallel or in phase sets or / combined with at least two structural relationships
  • the unit can be manufactured with at least one compression cavity 01, the outer wall surface of the runner 1 is a circular shape with two outer corner bodies 15, and the inner wall surface of the pump casing 2 is a round shape.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover ), Wind runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates, and the runner 1 can also be manufactured to rotate in the opposite direction.
  • the runner 1 The axial flow compression cylinder 12 is fixedly connected internally, and there is a fault on the scroll constituting the axial flow compression cylinder 12, and the fluid of the axial air compression cylinder 12 flows from the outlet 120 on the runner 1 into the pump casing 2, and the runner 1
  • the two symmetrical triangular bodies 15 are fixedly connected externally.
  • the triangular body 15 forms a compression cavity 01 during rotation.
  • the compressed fluid pushes open the valve disc 974 and is pushed out from the outlet 2410.
  • the rotating block 61 is installed in the pump casing 2 and is formed by the elastic sheet. 611 pushed away.
  • FIG. 80 is a working cross-sectional view of Embodiment 32 of the present invention.
  • Embodiment 32 provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured with a compression unit Or / has at least two rotor (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or / serial / parallel or / phase sets or / combined with at least two structural relationships above It can be manufactured with at least one compression cavity 01, the outer wall surface of the runner 1 is round, the inner wall surface of the pump casing 2 is round, and there is at least one or between the stopper 62 on the runner 1 and the inner wall of the casing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), or an internal combustion runner (Or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed lines and arrows in the figure indicate the process of fluid flow.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and the rotor 1 can also be manufactured to rotate in the opposite direction.
  • the runner 1 The outer wall is circular, but its circle center is not at the same axis as the axis of the shaft.
  • the wheel 1 is fixedly connected to the axial-flow air compression cylinder 12.
  • the wheel 1 is also equipped with a stopper 62, and the stopper 62 is spring 915. It is pushed out and always contacts the inner wall of the pump casing 2.
  • a baffle 51, The plate 51 is pushed out by the spring 911 and is pushed in by the runner 1 and is always in contact with the outer wall of the runner 1.
  • the fluid When the runner 1 rotates, the fluid enters the pump casing 2 from the inlet 2310, and the runner 1 forms a compression cavity 01 during rotation
  • the compressed fluid pushes open the valve disc 974 and flows out from the outlet 2410;
  • the cover 931 is a tube opening for closing the spring 911.
  • At least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or the swivel) 1.
  • FIG. 81 is a working cross-sectional view of Embodiment 33 of the present invention.
  • Embodiment 33 provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured to have a compression unit Or / has at least two rotors (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or in series / parallel or / phase sets or / combined with at least two structural relationships above, each compression unit It can be manufactured with at least one compression cavity 01, the outer wall surface of the runner 1 is oval or non-circular, the inner wall surface of the pump casing 2 is round, the two stoppers 62 on the runner 1 and the pump casing There is at least one or / at least one contact surface between the inner walls of 2; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or Prime
  • the dashed lines and arrows in the figure indicate the process of fluid flow.
  • the arc arrows in the runner 1 indicate the direction in which the runner 1 rotates, and the rotor 1 can also be manufactured to rotate in the opposite direction.
  • the runner 1 is an oval-shaped outer wall.
  • the runner 1 is fixedly connected with the axial flow compression cylinder 12.
  • the runner 1 is symmetrically provided with two stoppers 62.
  • the two stoppers 62 are pushed out by two springs 915, and are always connected to the inner wall of the pump casing 2.
  • a baffle 51 is installed on the upper part of the pump casing 2.
  • the baffle 51 is pushed out by the spring 911 and is pushed in by the runner 1 and always contacts the outer wall of the runner 1.
  • the runner 1 rotates, the fluid enters the pump from the inlet 2310 Inside the casing 2, the rotary wheel 1 forms a compression chamber 01 during rotation, and the compressed fluid flows out from the outlet 2410.
  • the cover 931 is a cylinder opening that closes the spring 911. In this embodiment, it can be symmetrical at the lower part of the pump casing 2. Install the inlet, outlet and baffle to form the second compression chamber 01.
  • at least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or the swivel) 1.
  • FIG. 82 is a working cross-sectional view of Embodiment 34 of the present invention.
  • Embodiment 34 shows a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and its structure can be manufactured to have a compression unit Or / has at least two rotor (or swivel) pumps (or heat pumps or vacuum pumps) that are connected in series or / parallel or / serial / parallel or / phase sets or / combined with at least two of the above structural relationships, and each compression unit It can be manufactured with at least one compression cavity 01.
  • the outer wall surface of the runner 1 is a circular shape with an outer body 14.
  • the inner wall surface of the pump casing 2 is a round shape.
  • the outer body 14 and the pump casing 2 on the rotor 1 There is at least one contact surface between the inner walls of the inner wall; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), internal combustion Type runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the arc arrow in the runner 1 indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the inside of the runner 1 The axial flow compression cylinder 12 is fixedly connected, and the scroll forming the axial flow compression cylinder 12 has a cross section.
  • the fluid in the axial flow compression cylinder 12 enters the pump casing 2 from the inlet 120 through the cross section.
  • the outer body 14 fixedly connected to the outer wall of the runner 1 forms a compression cavity 01, and the compressed fluid is pushed out of the valve block 972 through the outlet 240;
  • the pump casing 2 is equipped with a rotating plate 54 which is pushed by the elastic sheet 541 It is opened and closed by the outer body 14; there are also some through holes 230 in the pump casing 2.
  • FIG. 83 is a cross-sectional view of a cooling hole in the casing or / the pump casing or / the casing in the present invention. It can be seen from the figure that the casing or / the pump casing or the / the casing 2 has a layer of through holes 280 and One layer of cooling holes 290, the arrows on the figure indicate the direction of the cooling fluid entering and leaving the casing or / pump casing or / housing 2; the cooling fluid enters the casing or / pump casing or / housing 2 from the inlet 2930 and exit 2940 flows out, and the cooling fluid flows from one cooling hole 290 to another cooling hole 290 in the casing or / pump casing or / housing 2.
  • the cooling hole 290 in the figure is marked with "+" to indicate inflow and marked with "-" Means outflow.
  • FIG. 84 is a working cross-sectional view of the thirty-fifth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover).
  • This embodiment has four sets of work units. It can also be made into two or three or four or more sets of work units, and its structure can also be made to have one work unit or at least two phases in series or in parallel or in series or parallel or in phase.
  • a fluid runner (or swivel) engine (or prime mover) that sets or / combines at least two structural relationships described above to perform work units, and each work unit can be manufactured to have at least one power cavity 02, 021, 022, 023; (Or runner) 1
  • the outer wall surface is a circle shape, the inner wall surface is a circle shape with an inner wattle body, and the swivel (or runner) 101
  • the outer wall surface is a circle shape, and the inner wall surface is a garden with an inner wattle body
  • the inner wall surface of the casing 2 is a circular shape with an inner body
  • the outer wall surface of the inner casing 201 is a round shape
  • the inner wall surface is a circular shape with an inner wall
  • the outer wall surface of the inner casing 202 is a garden.
  • Shape there is at least one contact between the outer wall of the swivel (or runner) 1 and the inner body in the casing 2 There is at least one contact surface between the inner body of the swivel (or runner) 1 and the outer wall of the inner casing 201.
  • the outer wall of the swivel (or runner) 101 and the inner body of the inner casing 201 There is at least one contact surface between them, and there is at least one contact surface between the inner body in the swivel (or runner) 101 and the outer wall of the inner casing 202;
  • the structure of this embodiment can also be manufactured as a wind turbine (or runner) Body) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) ) Pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1, 101, and it can also be made into a swivel (or runner) 1, 101 turning in the opposite direction; from As can be seen in the figure, the work fluid is pushed away from the inlet 230 of the rotating plate 54 on the housing 202 to enter the first work unit, perform work in the power chamber 02, push the swivel (or runner) 101, and work in the first work unit.
  • the fluid after doing work pushes the rotating plate 541 from the outlet 1410 to enter the second work unit, performs work in the power chamber 021, pushes the rotating plate 541, and rotates the swivel (or runner) 101 to perform work in the second work unit
  • the housing 2 is pushed away from the outlet 2410.
  • the upper rotating plate 542 enters the third work unit, performs work in the power chamber 022, and pushes the swivel (or runner) 1.
  • the fluid after the third work unit does work, pushes the rotating plate 543 away from the outlet 1420 to enter the third work unit.
  • the four work units perform work in the power chamber 023, push the rotating plate 543 to rotate the swivel (or runner) 1, and the fluid after the work is performed in the fourth work unit is discharged from the outlet 240 on the casing 2.
  • FIG. 85 is a working cross-sectional view of the thirty-sixth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover).
  • This embodiment has four sets of work units. It can also be manufactured into two or three or four or more sets of work units; its structure can also be manufactured with one work unit or at least two phases in series or / parallel or / serial / parallel or / phase
  • a fluid runner (or swivel) engine (or prime mover) that sets or / combines at least two structural relationships as described above, each of which can be manufactured to have at least one power chamber 02, 021, 022, 023;
  • the inner and outer wall surfaces of the body (or runner) 1 are rounded, the inner and outer wall surfaces of the swivel (or runner) 101 are rounded, the inner wall surface of the casing 2 is rounded, and the inner and outer wall surfaces of the inner casing 21 are In the shape of a circle, the outer wall surface of the inner
  • the structure of this embodiment can also be manufactured as Wind runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, Rotary (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1, 101, and it can also be made into a swivel (or runner) 1, 101 turning in the opposite direction; from It can be seen in the figure that the work fluid enters the first work unit from the inlet 230, performs work in the power chamber 02, and pushes the baffle 51, which can be moved back and forth, to rotate the swivel (or runner) 101, and the first work unit
  • the fluid after doing work flows from the outlet 2410
  • the outlet 2410 is in communication with the inlet 2310 of the second work unit, and the fluid flowing from the first work unit enters the second work unit, performs work in the power chamber 021, and pushes the baffle 51, which can be reciprocated, to rotate ( (Rotary wheel) 101, the fluid after the work is performed in the second work unit, enters the third work unit through the outlet 2420 and the
  • At least one set of various inlets and outlets may be provided at the corresponding positions on the casing 2, the casings 21 and 22, and the runner (or swivel) 1 and the runner ( (Or swivel) 101 two-way rotation.
  • FIG. 86 is a working cross-sectional view of the thirty-seventh embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover).
  • This embodiment has three phased work units, and It can be manufactured into two or more than three sets of work units; its structure can also be manufactured to have one work unit or / have at least two phases in series or / parallel or / series and parallel or / phase sets or / the above at least
  • a fluid runner (or swivel) engine (or prime mover) that combines two structural relationships to perform a work unit, and each work unit can be manufactured with at least one power chamber 02, 021, 022; a swivel (or runner) 1
  • the outer wall surface is round, the inner and outer wall surfaces of the turning body (or runner) 101 are all round shapes, the inner wall surface of the housing 2 is a round shape with a transmission body 393 and a separator, and the outer wall surfaces of the inner housing 201 are
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1, 101, and it can also be made into a swivel (or runner) 1, 101 turning in the opposite direction; from It can be seen in the figure that the work fluid enters the first work unit from the inlet 230, and the rotating plate 54 is driven away by the driving rod 921 and the transmission body 392 to form a power chamber 02. The fluid entering the first work unit is under power.
  • Cavity 02 performs work, pushes the rotating plate 54 to rotate the swivel (or runner) 1, and the fluid after the first work unit performs work enters the second work unit from the outlet 2410 and the inlet 2310 of the second work unit,
  • the turning block 61 mounted on the turning body (or runner) 101 is pushed away by the transmission body 393 on the inner wall of the casing 2 to form a power chamber 021, and the fluid entering the second work unit performs work in the power chamber 021 to push the rotation
  • the swivel (or runner) 101 is rotated, and the fluid after performing work in the second work unit is entered from the swivel (or runner) 101 through the inlet 1310 controlled by the turn plate 541 to enter the third work.
  • the rotating block 5411 is pushed by the transmission body 394 on the inner wall of the casing 2.
  • the elastic force and the force from the fluid of the second work unit make the rotating plate 541 turn away to form a power chamber 022.
  • the fluid entering the third work unit does work in the power chamber 022 and pushes the rotating plate 541 to make the rotation (or rotation)
  • the wheel) 101 rotates, and the fluid after the work is performed by the third work unit is discharged from the outlet 240 on the casing 2.
  • the swivel body (or runner) 1 is integrally connected or / fixedly connected or / fixed with a scroll (or heat sink) 12 to form an axial flow compression dish (or heat sink).
  • FIG. 87 is a working cross-sectional view of the thirty-eighth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover).
  • This embodiment has three phased work units, and Can be made into two or more than three sets of work units; its structure can also be made to have one work unit or / have at least two phases in series or / parallel or / string
  • a fluid runner (or swivel) engine (or prime mover) that performs a power unit in parallel or in a phase set or in a combination of at least two structural relationships described above, and each power unit can be manufactured with at least one power chamber 02, 021, and 022;
  • the inner and outer wall surfaces of the swivel (or runner) 1 are rounded, the inner and outer wall surfaces of the swivel (or runner) 101 are rounded, the inner wall surface of the casing 2 is rounded, and the inner and outer wall surfaces of the inner casing 201 are It is circular
  • the dashed line plus arrow in the figure indicates the fluid flow process
  • the solitary line arrow indicates the turning direction of the swivel (or runner) 1, 101, and it can also be made into a swivel (or runner) 1, 101 turning in the opposite direction; from It can be seen in the figure that the work fluid enters the first work unit from the inlet 230, performs work in the power chamber 02, and pushes the baffle 51, which can be moved back and forth, so that the swivel (or the runner) 1 rotates, and the first work unit
  • the fluid after doing work flows from the outlet 2410 to the inlet 2310 of the second work unit, enters the second work unit, performs work in the power chamber 021, and pushes the stopper 62 which can be moved back and forth to make the body (or runner) Turn 101, the fluid after the second work unit does work, enter the third work unit through the port 630 on the stopper 62, and do work in the power chamber 022.
  • the swivel (or runner) 1 has an integral or / fixed connection or / fixedly installed scroll (or heat sink) 12, forming an axial flow compression cylinder (or heat sink).
  • the thirty-eighth embodiment it can be aligned on the housing 2, the housing 201 and the stopper 62. At least one set of various inlets and outlets are provided at the corresponding positions, and the runner (or swivel) 1 and the swivel (or swivel) 101 can be rotated in both directions.
  • FIG. 88 is a working cross-sectional view of the thirty-ninth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover), and this embodiment has three sets of work units; It can be manufactured into two or more than three sets of work units; its structure can also be manufactured to have one work unit or / have at least two phases in series or / parallel or / series and parallel or / phase sets or / the above at least A fluid runner (or swivel) engine (or prime mover) that combines two structural relationships to perform a work unit, each work unit can be manufactured to have at least one power chamber 02, 021, 022; a swivel (or runner) 1
  • the outer wall surface is round, and the inner and outer wall surfaces of the swivel (or runner) 101 are round.
  • the inner wall surface of the casing 2 is a round shape with transmission bodies 393, 394 and a separator.
  • the inner wall surface of the inner casing 21 It is a garden shape with an inner wattle body.
  • the outer wall surface of the inner case 21 is a garden shape with an outer wattle body.
  • the structure of this embodiment can also be manufactured as a wind turbine (or swivel) Engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (Or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the solitary line arrow indicates the turning direction of the swivel (or runner) 1, 101, and it can also be made into a swivel (or runner) 1, 101 turning in the opposite direction; from It can be seen in the figure that the work fluid flows from the first work unit of the inlet 2303 ⁇ 4A, and the baffle 51 is pushed out by the transmission body 392 during rotation to form the power chamber 02, and the fluid entering the first work unit performs work in the power chamber 02 The baffle 51 is pushed to rotate the swivel (or runner) 1 and the fluid after the first work unit performs work enters the second work unit from the outlet 2410 and the inlet 2310 of the second work unit, and is installed in the rotor.
  • the turning block 61 on the body (or the runner) 101 is pushed away by the transmission body 393 on the inner wall of the casing 2 to form a power cavity 021.
  • the fluid of the second work unit performs work in the power chamber 021, and the turning block 61 is pushed to rotate the rotation body (or the wheel) 101.
  • the fluid after the work is performed in the second work unit is passed through the openings 630 and 630 on the turn block 61.
  • the inlet (i.e. 130i) on the swivel (or runner) 101 which is controlled by the swivel plate 54.
  • the third work unit, the swivel plate 54 mounted on the swivel (or runner) 101 receives the transmission body on the inner wall of the casing 2.
  • FIG. 89 is a working cross-sectional view of the forty embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has an air compression unit and a work unit, and two work units. It has a phase-set relationship; its structure can also be manufactured as a fluid runner with one work unit or / at least two phases connected in series or / parallel or / series-parallel or / phase-set or / at least two types of structural relationships (Or swivel) engines, each work unit can be manufactured with at least one air compression cavity 01 and at least one power cavity 02; the inner and outer wall surfaces of the swivel (or runner) 1 are circular, and the inner part of the casing 2 The wall surface is a circular shape with a transmission body 392 and a separator.
  • the outer wall surface of the inner casing 21 is a circular shape with an outer body.
  • the inner wall of the swivel (or runner) 1 and the outer surface of the outer wall of the inner casing 21 There is at least one contact surface between the body, and there is at least one contact surface between the outer wall of the swivel (or the runner) 1 and the separator on the inner wall of the casing 2;
  • the structure of this embodiment can be manufactured into two or more sets Work unit, the structure of this embodiment can also Causes fluid runner (or swivel) engine (or prime mover), wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or Swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1. It can also be made into a swivel (or runner) 1. Turning in the opposite direction; you can see from the figure Out, air enters air from inlet 230 In the air compression unit, the baffle 511 is pushed out by the transmission member 391 and the transmission body 392 to form an air compression cavity 01.
  • the valve sheet 974 is opened from the outlet 2410 to flow out, and the air outlet channel 2420, the air outlet channel 2420 communicates with the air inlet 2310 of the work unit, the compressed air enters the work unit from the air inlet 2310, mixes with the fuel supplied by the burner 7, and is ignited, turning (or turning) 1
  • the upper baffle 51 is pushed out by the driving rotor 922, the transmission member 391, and the transmission body 392 to form a power chamber 02.
  • a mixture of fuel and air is burned in the power chamber 02 to generate thermal gas to perform work and push the rotary plate 51,
  • the turning body (or runner) 1 is rotated, and the exhaust gas after work is discharged from the outlet 240 on the casing 2.
  • the swivel (or runner) 1 is integrally connected or / fixedly connected or / fixed with a vortex (or heat sink) 12, a vortex (or heat sink) 12 has a port 180 between them to form an axial flow Compression cylinder (or radiator).
  • a spring 911 is installed between the transmission member 391 and the baffle plate 511, and a spring 912 is installed between the transmission rod 922 and the baffle plate 51. 'The transmission member 391 and the transmission rod 922 are driven by the turning point 9222, and the transmission rod is transmitted. 922 uses the turning point 9221 as a fixed point to generate a rotational movement.
  • FIG. 90 is a diagram of an embodiment of a transmission relationship of four phased wheels (or swivels) or / turns in the present invention; it can be seen from the figure that the power output shaft or / power input shaft 11 is connected as a whole or / Fixed connection or / Fixed installation of three gears with different diameters 1011, 1021, and 1031.
  • Gear 1011 and gear 1012 are in a direct drive relationship.
  • Gear 1021 and gear 1022 are in a direct drive relationship.
  • Gear 1031 and gear 1032 are in a direct drive relationship.
  • the transmission shafts 1013, 1023, and 1033 are respectively sleeved in the gears 1012, 1022, and 1032.
  • the gears 1012 and the transmission shaft 1013 are in a one-way transmission relationship.
  • the gears 1022 and the transmission shaft 1023 are in a one-way transmission relationship. There is a unidirectional transmission relationship between 1032 and the transmission shaft 1033.
  • the transmission shafts 1013, 1023, and 1033 are respectively driven by each wheel (or swivel) or / swivel.
  • This embodiment of the transmission relationship is applicable to a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) composed of at least two sets of swivel runners (or swivels) or / turns.
  • Engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (Or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the power transmission between the set of wheels (or swivels) or / rotations can also be achieved by other transmission methods.
  • FIG. 91 is a working cross-sectional view of forty-first embodiment of the present invention.
  • the embodiment provides an internal combustion runner (or swivel) engine, and its structure can be manufactured to have one work unit or / at least two work units
  • each work unit can be manufactured to have at least one power chamber.
  • the outer wall surface of the wheel 1 is circular, the inner wall surface of the housing 2 is a ring formed by a hyperbola, and there is no contact surface between the outer wall of the runner 1 and the inner wall of the housing 2; the structure of this embodiment can also be manufactured as a fluid rotor. Wheel (or swivel) engine
  • the axial-flow air compression cylinder 12 has a non-rotating shaft 481, and the shaft 481 is connected by ball or roller 92.
  • Three rotatable transmission rods 921 are articulated with a piece of baffle plate 51 that can be reciprocated linearly.
  • the three pieces of baffle plate 51 are symmetrically and radially mounted on the runner (or swivel) 1 and the baffle plate 51 and Runner
  • Balls or rollers 91 are installed between 1 to make the baffle 51 move flexibly.
  • the housing 2 is at the same axis as the fixed shaft 481.
  • the rotation axis of the runner (or swivel) 1 Not at the same location as their axis, air with a certain pressure enters the casing 2 from the air inlet 230, mixes with the fuel supplied by the fuel feeder 71, is pushed and compressed, and is ignited at the igniter 73. It burns in the power chamber 02, generates thermal work, pushes the baffle 51, and rotates the runner (or swivel) 1.
  • At least one set of various air inlets, air outlets, combustion inlets, and igniters may be further provided at corresponding positions on the casing 2 to realize the runner (or swivel) 1 Turn in both directions.
  • FIG. 92 is a working cross-sectional view of the forty-two embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 its structure can be manufactured as an internal combustion runner with one working unit or / with at least two phase series 3 ⁇ 4 or / parallel or I series parallel or / phase set or / at least two structural relationships (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle that can move back and forth. 51.
  • the transmission rod 921 and the revolving fan-shaped rotating plate 54, the elastic piece 541, the inner wall surface of the casing 2 is a circular or / eccentric circular ring with an equal diameter, and at least between the outer wall of the runner 1 and the inner wall of the casing 2.
  • One or / has at least one contact surface; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), external combustion Type runner (or swivel) engine, The external combustion runner (or twist) of the engine, the wheel (or rotors) a pump (or pump or a vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the turning direction of the swivel (or runner) 1. It can also be made into a swivel (rotor) 1. Turning in the opposite direction; it can be seen from the figure The axis of the runner 1 and the center of the inner wall of the casing 2 are not at the same place. Air enters the working unit from the inlet 130 on the swivel (or runner) 1 controlled by the turning plate 54, and the baffle 51 is on the transmission rod. Pushed out by 921, after passing through the outlet 240 on the casing 2, an air compression cavity 01 is formed, and it is turned into an empty space.
  • valve block 975 is pushed open from the outlet 2410 and flows into the air storage chamber 201 in the casing 2.
  • the pressured air in the air storage chamber 201 is pushed through the inlet 2310 to open the valve block 976 to enter
  • the combustion chamber 03 in the machine is mixed with the fuel supplied by the burner 7 and is ignited to generate thermal gas. It enters the power chamber 02 from the inlet 2320 of the power chamber 02 to perform work, and pushes the baffle 51 to make the body (or runner). 1 turns, the exhaust gas after work is discharged from the outlet 240 on the casing 2.
  • the swivel (or runner) 1 is integrally connected or / fixedly connected or / fixed with a scroll (or heat sink) 12, forming an axial flow compression cylinder (or heat sink).
  • Each pair of baffles 51 push each other through a transmission pestle 921; when the rotating plate 54 on the swivel (or the runner) 1 is turned to the outlet 240, due to the elasticity of the elastic piece 541 and the pressure of the air in the axial compression cylinder, Push to open, so that the air in the axial-flow air compression cylinder flows into the working unit from the inlet; the valve blocks 975 and 976 are ejected by springs 912 and 913, respectively, to control the air to flow only in one direction; the outlet 2410 of the air compression chamber 01 An air outflow device 99 is fixedly installed.
  • the air outflow device 99 is connected to a control valve outside the machine, and can control the ability of the air compression chamber 01 to compress air and supply pressured air to the outside.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, and burners may be further provided at corresponding positions on the casing 2 to realize bidirectional rotation of the runner (or swivel) 1.
  • FIG. 93 is a working cross-sectional view of the forty-third embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle 51 that can reciprocate.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or Prime mover), wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) Pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1. It can also be made into a swivel (or runner) 1. Turning in the opposite direction; you can see from the figure Out, the axis of the runner 1 and the center of the inner wall of the casing 2 are not at the same place.
  • the rod 921 is pushed out, and after passing through the outlet 240 on the casing 2, an air compression chamber 01 is formed.
  • the valve sheet 974 is opened from the outlet 2410 and flows into the casing 2
  • the air storage chamber 201 and the pressurized air in the air storage chamber 201 enter the combustion chamber 03 of the machine through the inlet 2310 and the control valve block 977, mix with the fuel supplied by the burner 7, and are ignited to generate a thermal gas.
  • the baffle 51 is pushed to rotate the swivel (or runner) 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2.
  • the swivel (or runner) 1 is integrally connected or / fixedly connected or / fixed with a scroll (or heat sink) 12, forming an axial flow compression cylinder (or heat sink).
  • Each pair of baffles 51 push each other through a transmission rod 921; when the rotating plate 54 on the swivel (or runner) 1 is turned to the outlet 240, due to the elastic force of the elastic sheet 541 and the pressure of the air in the axial flow compression cylinder, Push it open, so that the air in the axial-flow air compression cylinder flows into the work unit from the inlet; the valve disc 974 controls the air to flow only in one direction; the casing 2 is fixed with an air outflow device 99, and the air outflow device 99 and the machine
  • the air storage chamber in the shell 2 is in communication, and the air outflow device 99 is connected to a control valve outside the machine, and can supply pressured air to the outside and supply air to the air storage chamber 201.
  • a control valve 977 can control the flow into the combustion chamber inside the machine.
  • air flow rate 03; in the combustor 03 to the casing 2 is fixed at a sprinkler 81 mounted with.
  • the casing 2 can also be fixedly equipped with a temperature measuring sprinkler or a temperature measuring device or a smoke measuring device or an exhaust gas acid-base measuring device. Wait.
  • At least one set of various air inlets, air outlets, burners, and water sprayers may be further provided at corresponding positions on the casing 2 to realize the runner (or swivel) 1 bidirectional Turn.
  • FIG. 94 is a working cross-sectional view of the forty-fourth embodiment of the present invention; this embodiment provides an internal combustion rotor (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( Or rotating) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle 52 that can reciprocate.
  • the inner wall surface of the casing 2 is circular or / non-circular, and there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the casing 2;
  • the structure of the embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) engine, Internal and external combustion Wheel (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the turning direction of the swivel (or runner) 1. It can also be made into a swivel (or runner) 1. Turning in the opposite direction; you can see from the figure The axis of the runner 1 and the center of the inner wall of the casing 2 are not at the same place.
  • the air enters the working unit from the inlet 230 on the casing 2 and the baffle 52 is pushed out to the casing 2 by the drive of the transmission lever 922.
  • the inner wall of the casing contacts the outlet 240 on the casing 2 to form the air compression cavity 01.
  • the valve disc 974 is opened from the outlet 2410 and flows into the casing 2.
  • the air storage chamber 201 and the pressured air in the air storage chamber 201 enter the internal combustion chamber 03 through the inlet 2310 and the control valve block 976, mix with the fuel supplied by the burner 7, and are ignited to generate a thermal gas.
  • the inlet 2320 of the power chamber 02 enters the power chamber 02 to perform work, and pushes the baffle 52 to make the body (or runner)
  • the swivel (or runner) 1 is integrally connected or / fixedly connected or / fixed with a scroll (or heat sink) 12, forming an axial flow compression cylinder (or heat sink).
  • Each baffle 52 is driven by a transmission shaft 922, and the baffle 52 and the transmission shaft 922 are movably connected through a rotation shaft 521.
  • Each transmission shaft 922 is driven by the same off-axis fixed shaft 482, and the fixed shaft 482 is fixed.
  • the fixed shaft 482 and the fixed body 481 are integrally connected or fixedly connected or fixedly installed.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, and burners may be further provided at corresponding positions on the casing 2 to realize the turning (or turning) of the runner 1 direction.
  • FIG. 95 is a working surface view of the forty-fifth embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and Power chamber 02, whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle 51 that can reciprocate.
  • the outer wall of the runner 1 and the casing 2 There is at least one or / at least one contact surface between the inner walls.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or original Motive), external combustion runner (or swivel) engine, Internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel runner (or swivel) 1. It can also be made into a swivel (or runner) 1 turning in the opposite direction; from the figure It can be seen that the runner After the rotor plate 54 on the rotor 1 passes through the outlet 240 on the casing 2, the air from the rotor 1 is controlled by the rotor plate 54 due to the elasticity of the elastic piece 541 and the pressure of the compressed air in the axial-flow air compression cylinder in the rotor 1.
  • the opened and closed inlet 130 enters the working unit, and the baffle plate 51 is pushed by the transmission body 392 during rotation with the runner 1 to protrude into contact with the inner wall of the casing 2, and rotates through the outlet 240 on the casing 2 to form air.
  • Compression chamber 01 transferred to air Compression chamber 01 is pushed and compressed, and then the valve disc 974 is opened from the outlet 2410 and flows into the combustion chamber 03 in the machine. It is mixed with the fuel supplied by the burner 7 and ignited to generate heat.
  • the gas enters the baffle plate 51 from the inlet 2310 of the power chamber 02 and is pushed by the transmission body 392 during the rotation with the runner 1 to protrude to the power chamber 02 formed in contact with the inner wall of the casing 2 to perform work and push the baffle plate 51 so that The runner 1 rotates, and at this time, the runner plate 54 passes through the contact surface between the runner 1 and the casing 2 and closes, so that the inlet 130 on the runner 1 is closed; the exhaust gas after work is discharged from the outlet 240 on the casing 2.
  • the rotating wheel 1 is integrally connected or / fixedly connected or / fixed with a scroll (or heat sink) 12, forming an axial flow compression cylinder or / radiation cylinder.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, and burners may be provided at corresponding positions on the casing 2 to realize bidirectional rotation of the runner (or swivel) 1.
  • FIG. 96 is a working cross-sectional view of the forty-sixth embodiment of the present invention.
  • This embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( Or swivel) engine, each working unit It can be manufactured with at least one air compression cavity 01 and at least one power cavity 02;
  • the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle 52, a transmission rod 921, a piston 53 and a reciprocating wheel
  • the rotating transmission lever 922, the inner wall surface of the casing 2 is a circular or / eccentric ring with an equal diameter; the structure of this embodiment can also be manufactured as a fluid runner (or s
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1. It can also be made into a swivel (or runner) 1. Turning in the opposite direction; turning on the transmission body 481 The double-headed arrow indicates that the rotating body transmission 481 can rotate in 3 ⁇ 4 direction. The rotation of the rotating transmission body 481 is controlled automatically or manually by the outside of the machine. As can be seen from the figure, the axis of the rotating wheel 1 and the center of the inner wall of the casing 2 are not the same.
  • the axis of the runner 1 is the same as the axis of the rotating transmission body 481
  • the axis of the rotating transmission body 481 is not the same as the axis of the transmission shaft 482
  • the baffle 52 is pushed out by the driving rod 921, and after passing through the inlet 230 on the casing 2, a compression chamber 01 is formed, and the air in the compression chamber 01 is transferred
  • the fuel mixture is pushed and compressed, and at the same time, it is compressed by the piston 53 installed on the runner 1.
  • the piston 53 is pushed and pulled by the transmission lever 922 while rotating with the wheel 1, and reciprocates in the piston straight cylinder.
  • the transmission lever 922 Connected with the piston through the rotating shaft 531 Then, the transmission lever 922 is driven by the transmission shaft 482 at the eccentric position on the rotation transmission body 481.
  • the rotation shaft 482 and the rotation transmission body 481 are connected as one body or / fixed connection or / fixed installation.
  • the piston 53 can be adjusted
  • the cross-sectional shape of the working surface of the piston 53 is circular or / ellipsoidal or / square or / rectangular or / rectangular with solitary edges or a combination of the aforementioned shapes.
  • the air-fuel mixture is pushed and compressed to Burn, enter the power chamber 02 to do work, push the baffle 52 to rotate the runner 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2; there are some vent holes 280 in the casing 2, which can circulate gas or / cool fluid.
  • the rotation transmission body 481 may be fixed and not rotated.
  • Temperature measurement spray can also be fixed on the casing 2 Water meter or / thermometer or / water sprinkler or / smoke meter or / exhaust gas acid and alkali meter.
  • at least one set of various air inlets, air outlets, fuel feeders, and igniters may be further provided at corresponding positions on the casing 2 to realize the runner (or swivel) 1 Turn in both directions.
  • FIG. 97 is a working cross-sectional view of the forty-seventh embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the runner 1 is equipped with a baffle 51 that can reciprocate.
  • the transmission rod 921, the reciprocating fan-shaped piston 54 and the reciprocating transmission rotating rod 922, the inner wall surface of the casing 2 is a circular or / eccentric circular ring with an equal diameter; the structure of this embodiment can also be manufactured as a fluid rotating Wheel (or swivel) engine (or prime mover), wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) Engine, runner (or turn ) Pump (or heat pump or vacuum pump).
  • the dashed lines and arrows in the figure indicate the fluid flow process, and the arc arrows indicate the turning direction of the swivel (or runner) 1.
  • the axis of the runner 1 and the axis of the rotating transmission body 481 are at the same place, the axis of the turning transmission body 481 and the axis of the driving shaft 482 are not at the same place, and air is opened and closed from the runner 1 by the rotating piston 5
  • the inlet 130 enters the working unit, and the baffle 51 is pushed out by the driving rod 921.
  • the air compression chamber 01 is formed, and the air transferred into the air compression chamber 01 is pushed and compressed.
  • the rotary piston 54 mounted on the runner 1 is extended and compressed, and the rotary piston 54 is driven while rotating with the runner 1
  • the rotating rod 922 is pushed and pulled and reciprocated in the sector piston cylinder.
  • the rotating piston 54 rotates with the rotating shaft 541 as the turning point.
  • the transmission rotating rod 922 and the rotating piston 54 are movably connected through the rotating shaft 542.
  • the transmission rotating rod 922 is received by the rotating transmission body 481.
  • the transmission shaft 482 is driven at the eccentric position, and the transmission shaft 482 and the rotating transmission body 481 are integrally connected or fixedly connected or fixedly installed.
  • the compression capacity of the rotating piston 54 can be adjusted, and the working surface of the rotating piston 54
  • the cross-sectional shape is square or / rectangular or / rectangular with curved edges or a combination of the above.
  • the air is pushed and compressed into the power chamber 02, mixed with the fuel supplied by the fuel feeder 71, and ignited by the igniter 73.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, fuel feeders, and igniters may be further provided at corresponding positions on the casing 2 to realize the runner (or swivel) 1 Turn in both directions.
  • FIG. 98 is a working cross-sectional view of the forty-eighth embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the power chamber in the same working unit. 02, its structure can be manufactured as an internal combustion runner (or a rotating unit with at least two working units in series or / parallel or / series and parallel or / phase sets or / at least two structural relationships above) Body) engine, each working unit can be manufactured with an air compression chamber 01 and at least one power chamber 02;
  • the runner 1 is equipped with a baffle 51 and a transmission rod 921 that can move back and forth, and the outer wall surface of the runner 1 is four
  • the arc walls are staggered, and the inner wall surface of the casing 2 is a circular or / eccentric ring with an equal diameter.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), wind turbine Wheel (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or true Empty pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the casing 2 The center of the inner wall is not at the same place.
  • the baffle 51 is pushed out by the driving rod 921. After passing through the inlet 230 on the casing 2, a compression chamber 01 is formed.
  • the air transferred into the compression chamber 01 is mixed with the fuel supplied by the fuel feeder 71 to form a fuel mixture, and is further pushed and compressed to enter the power chamber 02, and is ignited by the igniter 73 to generate a thermal gas.
  • the baffle 51 is pushed to rotate the runner 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2.
  • the baffle 51 is pushed by the transmission rod 921 and always keeps contact with the inner wall of the casing 2.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, fuel feeders, and igniters may be further provided at corresponding positions on the casing 2 to realize the turning (or turning) of the rotor in one direction.
  • FIG. 99 is a working cross-sectional view of the forty-ninth embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • Power chamber 02 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined working units with at least two structural relationships ( (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall of the runner 1 is equipped with a revolving plate 54 and a transmission rod 921 that can reciprocate in a fan-shaped manner.
  • the shell 2 is provided with a baffle plate 51 that can be moved back and forth.
  • the outer wall surface of the runner 1 is a circular shape, and the inner wall surface of the casing 2 is a circular or / eccentric circular ring.
  • the structure of this embodiment is also manufactured as a fluid runner. (Or swivel) engine (or prime mover), wind turbine (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine , Runner (or swivel) pump (or Or vacuum pumps).
  • Dotted arrow in the figure The head indicates the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates.
  • the runner 1 rotates in the opposite direction. As can be seen from the figure, the axis of the runner 1 and the center of the inner wall of the casing 2 are not in the center. At the same place, air enters the working unit from the inlet 230 on the casing 2 and the rotating plate 54 is driven away by the drive rod 921. After passing through the inlet 230 on the casing 2, the compression cavity 01 is formed, and the compression cavity 01 is turned into the compression cavity 01. The compressed air is pushed and compressed, and enters the power chamber 02.
  • the fuel supply device 71 supplies fuel with a higher pressure than the compressed air. The fuel is compressed and spontaneously ignites to generate thermal gas.
  • the rotating plate 54 makes the rotating wheel 1 rotate, and the exhaust gas after work is discharged from the outlet 240 on the casing 2.
  • the rotating plate 54 is pushed by the transmission rod 921 and always keeps contact with the inner wall of the casing 2;
  • the power switch (controller) that controls the energizing and energizing direction is controlled by the transmission mechanism on the runner engine.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • FIG. 100 is a working cross-sectional view of Embodiment 50 of the present invention.
  • This embodiment provides a fluid runner (or swivel) engine (or prime mover). Its structure can be manufactured with a work unit or / At least two fluid runner (or swivel) engines (or prime movers) which are connected in series or / parallel or / series / parallel or / phase sets or / at least two of the above structural relationships to perform work units, and each work unit can be manufactured into There is at least one power chamber 02, 021; the runner 1 is equipped with a baffle 51 that can be moved back and forth, the outer wall surface of the runner 1 is circular, the inner wall surface of the casing 2 is oval, and the outer wall of the runner 1 and the machine There is at least one or / at least one contact surface between the upper and lower inner walls of the shell 2; the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), internal combustion runner
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the machine The center of the inner wall of shell 2 is at At the same place, the fluid with energy enters the work unit from the inlet 230 on the casing 2.
  • the baffle 51 is pushed out by the transmission body 392 during the rotation of the runner 1, forming a power chamber 02.
  • the fluid entering the work unit is under power.
  • At least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or swivel) 1.
  • FIG. 101 is a working cross-sectional view of the fifty-first embodiment of the present invention.
  • This embodiment provides a fluid runner (or swivel) engine (or prime mover). Its structure can be manufactured with a work unit or / A fluid runner (or swivel) engine (or prime mover) with at least two phases connected in series or / parallel or / serial / parallel or / phase set or I combined with at least two of the above structural relationships to perform work units, and each work unit can be manufactured It has at least one power chamber 02; the runner 1 is equipped with a baffle plate 51 that can be moved back and forth, and the casing 2 is equipped with a stopper 62 and a spring 914 that can be moved back and forth.
  • the outer wall surface of the runner 1 is circular, and the housing 2
  • the upper half of the inner wall surface is semi-ellipsoidal or / arc-shaped, and the lower half is semi-circular.
  • the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), internal combustion Type runner (or swivel) engine, external combustion type runner (or swivel) Machines, inside and outside the ignition wheel (or twist) of the engine, the wheel (or rotors) a pump (or pump or a vacuum pump).
  • the dashed line plus arrow in the figure indicates the fluid flow process, and the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the machine The center of the inner wall of the casing 2 is not at the same place.
  • the fluid with energy enters the work unit from the inlet 230 on the casing 2.
  • the baffle 51 is pushed out by the transmission body 392 during the rotation of the runner 1 to form a dynamic movement. Force cavity 02, the fluid entering the work unit performs work in power cavity 02, pushing the baffle 51 to rotate the runner 1, the fluid after the work flows out from the outlet 240 on the casing 2, and the baffle 51 follows the runner 1 During rotation, it is pushed by the transmission body 392 to always contact the inner wall of the casing 2.
  • the upper portion of the casing 2 is provided with a stopper 62 to isolate the inlet 230 and the outlet 240.
  • the stopper 62 is pushed by at least one spring 914, and the spring 914 is
  • the cover 932 is enclosed in the casing 2.
  • At least one set of various inlets and outlets can be further provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or swivel) 1.
  • Fig. 102 is a working cross-sectional view of the fifty-second embodiment of the present invention; this embodiment gives a Xuan fluid runner (or swivel) pump (or heat pump or vacuum pump). Its structure can be manufactured with a compression unit or / A fluid runner (or swivel) pump (or a heat pump or a vacuum pump) having at least two phases connected in series or / parallel or in series / parallel or in phase sets or / combined with at least two structural relationships above, each compression unit It can be manufactured with at least one compression chamber 01; the pump housing 2 is equipped with a baffle plate 51 that can move back and forth, the upper half of the outer wall surface of the runner 1 is semi-circular, and the lower half is semi-ellipsoidal or / arc The inner wall surface of the pump casing 2 is circular.
  • the ellipse or / arc top of the runner 1 is equipped with a stopper 61 and a spring 913 that can reciprocate.
  • the outer wall of the top of the upper half of the runner 1 and the pump casing 2 There is at least one or / at least one contact surface between the inner walls, at least one or / at least one contact surface between the inner wall of the pump casing 2 and the stopper 61 mounted on the runner 1; the structure of this embodiment can also be manufactured Into fluid runner (or swivel) engine (or prime mover), wind runner (or Body) of the engine (or prime mover), an internal combustion runner (or twist) of the engine, external combustion runner (or twist) of the engine, and external combustion runner (or twist) of the engine.
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the fluid flows from the inlet of the pump casing 2 230 enters the compression unit.
  • the top of the upper half of the ellipse of the runner 1 passes through the top of the pump casing 2 to form a compression chamber 01.
  • the fluid entering the compression unit is pushed by the runner 1 and flows out of the outlet 240.
  • the baffle 51 is followed by the runner.
  • the rotating transmission body 393 pushes to always contact the outer wall of the runner 1, and always isolates the inlet 230 and the outlet 240,
  • the transmission body 393 is at least one non-circular ring body provided outside the pump casing 2 and rotates synchronously with the runner 1; the stopper 61 is pushed by a spring 913 and always contacts the inner wall of the pump casing 2; A roller or a roller or a ball 941 rolls on the transmission body 393.
  • At least one set of various inlets and outlets can be further provided at the corresponding positions on the pump casing 2 to realize bidirectional rotation of the runner (or swivel) 1.
  • FIG. 103 is a working cross-sectional view of the fifty-third embodiment of the present invention; this embodiment shows a fluid runner (or swivel) pump (or heat pump or vacuum pump). Its structure can be manufactured with a compression unit or / A fluid runner (or swivel) pump (or a heat pump or a vacuum pump) having at least two phases connected in series or / parallel or / series and parallel or / phase sets or / combined with at least two structural relationships above, each compression unit It can be manufactured with at least one compression cavity 01; the outer wall surface of the runner 1 is ellipsoidal or / hyperbolic solitary, and the tops of the ellipsoidal or / hyperbolic solitary on the runner 1 are each equipped with reciprocating Block 61 and spring 913.
  • the inner wall surface of the pump casing 2 is circular.
  • the pump casing 2 is equipped with a baffle plate 52 that can move back and forth.
  • the outer wall of the top of the elliptical or hyperbolic solitary shape on the runner 1 and the pump There is at least one or / at least one contact surface between the inner walls of the casing 2, and at least one between the inner wall of the pump casing 2 and the elliptical or / hypercurve arc-shaped stoppers 61 on the runner 1 Or / has at least one contact surface;
  • the structure of this embodiment can also be manufactured as a fluid runner (or ) Engine (or prime mover), wind runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner Wheel (or swivel) engine.
  • the dotted line and arrow in the figure indicate the fluid flow process, and the solitary line arrow indicates the direction in which the rotor 1 rotates. It can also be made that the rotor 1 rotates in the opposite direction.
  • the fluid flows from the inlet of the pump casing 2 230 enters the compression unit, and the top of the ellipse on the runner 1 passes through the top of the pump casing 2 to form a compression chamber 01.
  • the fluid entering the compression unit is pushed by the runner 1 and flows out from the outlet 240.
  • the baffle 52 is subjected to a hydraulic cylinder (pneumatic pressure). Cylinder) 29 is always in contact with the outer wall of runner 1 to isolate inlet 230 and outlet 240.
  • At least one inlet pipe 291 and at least one outlet pipe 292 are connected to the hydraulic cylinder (pneumatic cylinder) 29.
  • the hydraulic cylinder (pneumatic cylinder) ) 29 in and out of liquid (Gas) is controlled by the synchronous control mechanism; the stopper 61 is ejected by the spring 913, and is always in contact with the inner wall of the pump casing 2.
  • At least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the two-way rotation of the runner (or swivel) 1.
  • FIG. 104 is a working cross-sectional view of the fifty-fourth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover). Its structure can be manufactured with a work unit or / A fluid runner (or swivel) engine (or prime mover) having at least two phases connected in series or / parallel or / series / parallel or / phase sets or / combined with at least two structural relationships described above as a work unit, and each work unit can be manufactured Has at least one power cavity 02; the outer wall surface of the runner 1 is triangular, and the three corners of the runner 1 are each equipped with a baffle plate 51 that can reciprocate, and the inner wall surface of the casing 2 is round or non-round Toroidal; the structure of this embodiment can also be manufactured into a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (or swivel) engine,
  • the dashed line and arrow in the figure indicate the fluid flow process
  • the arc arrow indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the machine The center of the inner wall of the casing 2 is not at the same place.
  • the fluid with energy enters the work unit from the inlet 230 on the casing 2.
  • the baffle 51 is pushed out by the transmission fluid (gas) 924 as the runner 1 rotates to form a power chamber.
  • the fluid entering the work unit performs work in the power chamber 02, pushes the baffle 51 to rotate the runner 1, the fluid after the work flows out from the outlet 240 on the casing 2, and the baffle 51 is rotating with the runner 1.
  • the transmission fluid (gas) 924 it is always in contact with the inner wall of the casing 2.
  • the transmission fluid (gas) 924 is injected into the liquid (gas) pressure cylinder that pushes the three baffles 51, and the liquid (gas) passes between the baffles 51.
  • Transmission fluid (gas) 924 in the pressure cylinder drives each other, and at least one hydraulic (gas) pressure cylinder is provided in the runner 1.
  • FIG. 105 is a working cross-sectional view of the fifty-fifth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover). Its structure can be manufactured with a work unit or / Fluid runner (or swivel) engine with at least two phases connected in series or / parallel or / series / parallel or / phase set or / combined with at least two structural relationships as a power unit
  • each work unit can be manufactured with at least one power chamber 02, the runner 1 is set outside the casing 2, the runner 1 is equipped with a baffle 51 that can reciprocate, and the inner wall surface of the runner 1
  • the runner 1 is equipped with a reciprocating baffle 51, and the outer wall surface of the casing 2 is a circular or non-circular ring.
  • the casing 2 is equipped with a stopper 62 and a spring 914 that can reciprocate.
  • the runner 1 There is at least one or / at least one contact surface between the inner wall of the housing and the outer wall of the housing 2, and there is at least one or / at least one contact surface between the inner wall of the runner 1 and the stopper 62 mounted on the housing 2.
  • a fixed transmission body 393 is provided outside the wheel 1; the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, external combustion Type runner (or swivel) engine, internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line plus arrow in the figure indicates the fluid flow process, and the arc arrow indicates the direction of rotation of the runner 1.
  • the axis of the runner 1 is not at the same center as the inner wall of the casing 2, and the fluid has energy.
  • the baffle 51 It enters the work unit from the inlet 230 in the casing 2.
  • the baffle 51 is pushed out by the fixed transmission body 393 during the rotation of the runner 1, forming a power chamber 02, and the fluid entering the work unit is in the power chamber 02. Do the work, push the baffle 51 to make the runner 1 rotate, and the fluid after the work flows out from the outlet 240 in the casing 2.
  • the baffle 51 always keeps contact with the outer wall of the casing 2 while the runner 1 rotates.
  • the stopper 62 on 2 is ejected by a spring 941, and always keeps contact with the inner wall of the runner 1.
  • the end of the baffle 51 is equipped with a roller or / roller or / ball 941 to roll on the transmission body 393.
  • At least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or the swivel) 1.
  • FIG. 106 is a working cross-sectional view of fifty-sixth embodiment of the present invention.
  • a fluid runner (or swivel) engine (or prime mover) whose structure can be manufactured to have a work unit or / have at least two phases in series or / parallel or / series and parallel or / phase sets or / at least two of the above Fluid rotor (or swivel) engine with a combination of structural relationships and work units
  • each work unit can be manufactured to have at least one power chamber 02, the runner 1 is set outside the casing 2, and the outer wall of the casing 2 is equipped with a rotating plate 53 and an elastic piece 531 which can reciprocate in a fan shape.
  • the inner wall surface of the wheel 1 is a circular shape with an inner body, and the outer wall surface of the casing 2 is a round shape. There is at least one or / at least one piece between the outer wall of the casing 2 and the inner body on the inner wall of the runner 1.
  • the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (or swivel) engine, Internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the internal inlet 230 enters the work unit.
  • the rotating plate 53 After the rotating plate 53 is turned over by the inner body, it is pushed away by the shrapnel 531 and the work fluid to form the power chamber 02.
  • the fluid entering the work unit performs work in the power chamber 02 to push the inner body.
  • the runner 1 is rotated, and the fluid after the work flows out from the outlet 240 in the casing 2.
  • the runner 53 is always in contact with the inner wall of the runner 1; the outer wall of the runner 1 is connected as a whole or / fixedly connected or / Fixedly installed heat sink 121.
  • FIG. 107 is a working cross-sectional view of a fifty-seventh embodiment of the present invention.
  • this embodiment provides a fluid runner (or swivel) engine (or prime mover) whose structure can be manufactured with a work unit or / Fluid runner (or swivel) engine with at least two phases connected in series or / parallel or / series / parallel or / phase set or / combined with at least two structural relationships as a power unit
  • each work unit can be manufactured to have at least one power chamber 02, the runner 1 is set outside the casing 2, and the inner wall of the runner 1 is equipped with a rotating plate 53 and an elastic piece 531 which can reciprocate in a fan shape.
  • the inner wall surface of the wheel 1 is circular, and the outer wall surface of the casing 2 is a circular shape with an external wattle.
  • the structure of this embodiment can also be manufactured into a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (or swivel) engine, inside and outside Combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line plus arrow in the figure indicates the fluid flow process, and the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the fluid with energy from the casing 2 The internal inlet 230 enters the work unit, and the rotating plate 53 is driven away by the elastic sheet 531 and the working fluid as the rotor 1 rotates to form a power chamber 02.
  • the fluid entering the work unit performs work in the power chamber 02 and pushes the rotating plate 53
  • the runner 1 is rotated, and the fluid after the work flows out from the outlet 240 in the casing 2.
  • the rotor 53 is always in contact with the outer wall of the casing 2 while the runner 1 rotates; there is a sandwich in the runner 1, and the sandwich There are scrolls or / radiating fins 12 connected in one body or / fixed connection or / fixed installation to form a through hole 180.
  • FIG. 108 is a working cross-sectional view of the fifty-eighth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover). Its structure can be manufactured with a work unit or / A fluid runner (or swivel) engine (or prime mover) having at least two phases connected in series or / parallel or / series / parallel or / phase sets or / combined with at least two structural relationships to perform a power unit, and each power unit can Manufactured with at least one power chamber 02.
  • the runner 1 is equipped with a baffle plate 521 that can be moved back and forth. The baffle plate 521 is pushed out by a rack on the inside of the baffle 521.
  • the rack is fixed or / can control bidirectional rotation of the transmission body 394
  • the outer wall surface of the runner 1 is round.
  • the inner wall surface of the casing 2 is a round shape with an inner body. There is a gap between the outer wall of the runner 1 and the inner body on the inner wall of the casing 2.
  • At least one or / has at least one contact surface; the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (Or swivel) engine, internal and external combustion runner (or ) Of the engine, the wheel (or rotors) a pump (or pump or a vacuum pump).
  • the dotted line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates, and it can also be manufactured that the runner 1 rotates in the opposite direction;
  • the two-way arrow in the body 394 indicates that the transmission body 394 can be controlled by the external or automatic manual control of the two-way rotation.
  • the fluid with energy enters the work unit from the inlet 230 on the casing 2, and the baffle 521
  • the fluid entering the work unit performs work in the power chamber 02.
  • the baffle 521 is pushed to rotate the runner 1, and the fluid after the work is removed from the casing 2.
  • the upper outlet 240 flows out, and the baffle plate 521 is always in contact with the inner wall of the casing 2 while rotating with the runner 1.
  • FIG. 109 is a working cross-sectional view of a fifty-nine embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover), and the runner 1 of this embodiment is installed in the casing 2 Inside, its structure can be manufactured as a fluid runner (or a swivel body) with one work unit or at least two phases connected in series or / parallel or / series / parallel or / phase sets or / combined with at least two structural relationships ) Engine (or prime mover), each work unit can be manufactured with at least one power chamber 02, the runner 1 is equipped with an arc-shaped baffle 522 that can be reciprocated by arcs, and the projection of the arc-shaped baffle 522 is from the inside of it
  • the curved rack is driven by part of the external gear on the transmission body 394 which is fixed or can control bidirectional rotation.
  • the outer wall surface of the runner 1 is round, and the inner wall surface of the casing 2 is The circular shape of the wattle body has at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wattle on the inner wall of the casing 2.
  • the structure of this embodiment can also be manufactured as a wind turbine (or a swivel) ) Engine (or prime mover), internal combustion runner (or swivel) engine, external Combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the arc arrow indicates the direction in which the runner 1 rotates, and it can also be manufactured to rotate the runner 1 in the opposite direction.
  • the two-way arrow inside the transmission body 394 indicates that the transmission body 394 can be received outside the machine. Automatic or / manual control of bidirectional rotation; it can be seen from the figure that the fluid with energy enters the work unit from the inlet 230 on the casing 2 and the arc-shaped baffle 522 is driven by the transmission body 394 during the rotation with the runner 1.
  • the fluid entering the work unit performs work in the power chamber 02, pushing the arc-shaped baffle 522 to rotate the runner 1, and the fluid after the work flows out from the outlet 240 on the casing 2 Board 522 It keeps in contact with the inner wall of the casing 2 while rotating with the runner 1.
  • FIG. 110 is a working cross-sectional view of a sixty embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has an air compression unit and a work unit, and two work units.
  • the runner 1 is installed between the casing 2 and the inner casing 201, the air compression unit is sleeved in the work unit, and the runner 1 is equipped with a baffle 51 that can be reciprocated; its structure can be manufactured into
  • Internal combustion runner (or swivel) engine of a t-power unit each air compression unit can be manufactured with at least one air compression cavity 01
  • Each work unit can be manufactured with at least one power cavity 02; swivel
  • the inner and outer wall surfaces of 1 are round, the inner wall surface of cabinet 2 is round or non-round, and the outer wall of inner casing 201 is round or non-round.
  • the direction of rotation can also be manufactured as a swivel (rotary wheel) 1 Turning in the opposite direction; it can be seen from the figure that the axis of the wheel 1 and the center of the inner wall of the casing 2 and the inner casing 201 The center of the outer wall is not the same.
  • the center of the inner wall of the casing 2 is the same as the center of the outer wall of the inner casing 201.
  • the baffle 51 is on the inner wall of the receiving casing 2. It is pushed out to form the air compression chamber 01.
  • the valve disc 974 is pushed out from the outlet 2410 and flows into the air outlet channel 2420 in the inner casing 201.
  • the air outlet channel 2420 and the casing 2 The air inlet 2310 communicates with The compressed air enters the internal combustion chamber 03 from the air inlet 2310, is mixed with the fuel supplied by the fuel supplier 72, and is ignited by the igniter 73 to generate thermal gas.
  • the baffle 51 on the runner 1 is received by the inner casing.
  • the push of 201 is extended to form the power chamber 02, and the thermal gas generated by the combustion chamber 03 inside the machine enters the power chamber 02 to perform work, and the rotary plate 51 is pushed to rotate the runner 1, and the exhaust gas after the work is emitted from the outlet 240 on the casing 2. discharge.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or / temperature measuring device or / water sprinkler or / smoke measuring device.
  • At least one set of various air inlets, air outlets, material feeders, and igniters may be respectively provided at corresponding positions on the upper case 201 of the casing 2 to realize the runner ( Or turn) 1 two-way rotation.
  • FIG. 111 is a working cross-sectional view of the sixty-first embodiment of the present invention; this embodiment provides an internal combustion rotor (or swivel) engine.
  • This embodiment has an air compression unit and a work unit. The units are in a nested relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the air compression unit is sleeved in the work unit.
  • the runner 1 is equipped with a baffle 51 that can be moved back and forth. Its structure can be manufactured.
  • each air compression unit can be manufactured with at least one air compression cavity 01
  • Each work unit can be manufactured with at least one power cavity 02; the inner and outer wall surfaces of the runner 1 are round, the inner wall surface of the casing 2 is a round shape with an inner body, and the outer wall surface of the inner casing 201 is Garden shape with outer wattle, There is at least one or / at least one contact surface between the inner wall of the wheel 1 and the outer body on the outer wall of the inner casing 201, and at least one or / between the outer wall of the runner 1 and the inner body on the inner wall of the casing
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), or an external combustion runner (Or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat Pump or vacuum pump).
  • a fluid runner or swivel engine (or prime mover)
  • an external combustion runner Or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat Pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the air outlet channel 2420 in the inner casing 201 is in communication with the air inlet 2310 on the casing 2. Compressed air enters the internal combustion chamber 03 from the air inlet 2310, and is supplied by the fuel feeder 72. The fuel is mixed and ignited by the igniter 73 to generate thermal gas.
  • the baffle 51 on the runner 1 is pushed out by the external body on the outer wall of the inner casing 201 to form a power chamber 02 and the heat generated by the combustion chamber 03 in the machine.
  • the gas enters the power chamber 02 to do work, pushes the rotary plate 51 to rotate the runner 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2; the valve disc 973 is led by the spring 913 to make the air compressed by the air compression chamber 01 Can only circulate in one direction Channel 2420, while the air in the outlet passage 2420 to outlet 2410 can not.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or / temperature measuring device or / water sprinkler or / smoke measuring device.
  • FIG. 112 is a working cross-sectional view of the sixty-second embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover). This embodiment has two work units and two work units. The units are in a nested relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the runner 1 is provided with a rotating block 54 and a rotating plate 53, and an elastic piece 531 that can be reciprocated in a fan-shaped manner.
  • Its structure can also be manufactured Forming a work unit or / having at least two phases connected in series or / parallel or / series / parallel or / phase set or / at least two structural relationship groups above ⁇ : a fluid runner (or swivel) engine (or original Motive), each work unit can be manufactured with at least one power cavity 02; the inner and outer wall surfaces of the runner 1 are round, the inner wall surface of the casing 2 is a round or non-round ring, and the outer of the inner housing 201 The wall surface is circular or non-circular.
  • At least one or / at least one contact surface between the inner wall of the runner 1 and the outer wall of the inner casing 201, and there is a gap between the outer wall of the runner 1 and the inner wall of the casing 2.
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the casing 2 The center of the inner wall and the center of the outer wall of the inner casing 201 are not at the same place.
  • the center of the inner wall of the casing 2 is the same as the center of the outer wall of the inner casing 201.
  • the fluid with energy enters the inner work from the inlet 230 in the inner casing 201.
  • the turning block 54 on the runner 1 is pushed in by the inner wall of the casing 2, and then the turning plate 53 is pushed out to form the power chamber 02.
  • the fluid entering the internal work unit performs work in the power chamber 02, pushing the turning block 54 and
  • the rotating plate 53 causes the runner 1 to rotate, and the fluid after performing work flows out from the outlet channel 2410.
  • the outlet channel 2410 communicates with the inlet 2310 on the casing 2.
  • the fluid flowing from the outlet channel 2410 flows into the inlet 2310 and enters the external work unit.
  • the rotating plate 53 on the wheel 1 is closed by the push of the outer wall of the inner casing 201, and then the rotating block 54 is turned away.
  • the rotating block 54 is simultaneously driven away by the elastic piece 531 to form a power chamber 021.
  • the fluid entering the external work unit is in Power cavity 021 does work and pushes
  • the rotating block 54 causes the rotating wheel 1 to rotate, and the fluid after work is discharged from the outlet 240 on the casing 2.
  • FIG. 113 is a working cross-sectional view of the sixty-third embodiment of the present invention; this embodiment provides an internal combustion rotor (or swivel) engine.
  • This embodiment has an air compression unit and a work unit, and two work The units are in a nested relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the air compression unit is sleeved in the work unit.
  • the runner 1 is equipped with a baffle 55 that can be moved back and forth. Its structure can be manufactured.
  • each air compression unit can be manufactured with at least one air compression cavity 01, and each work unit can be manufactured with at least one power Cavity 02;
  • the inner and outer wall surfaces of the runner 1 are circular, the inner wall surface of the casing 2 is circular or / non-circular, and the outer wall surface of the inner casing 201 is circular or / non-circular
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (or swivel) ) Engine, internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • a fluid runner (or swivel) engine or prime mover
  • an external combustion runner (or swivel) ) Engine Internal and external combustion type runner (or swivel) engine
  • runner (or swivel) pump or heat pump or vacuum pump.
  • the dashed line plus arrow in the figure indicates the fluid flow process
  • the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the casing 2 The center of the inner wall and the center of the outer wall of the inner casing 201 are not the same.
  • the center of the inner wall of the casing 2 is the same as the center of the outer wall of the inner casing 201.
  • Air enters the air compression unit from the inlet channel 230 in the inner casing 201.
  • the stopper 55 on the runner 1 is pushed out by the inner wall of the casing 2 to contact the outer wall of the inner casing 201 to form an air compression chamber 01.
  • the air entering the air compression unit is pushed and compressed in the air compression chamber 01
  • the flow from the channel 550 on the stopper 55 flows into the work unit, and the stopper 55 on the runner 1 is pushed out by the outer wall of the inner casing 201 to contact the inner wall of the casing 2 to form a power chamber 02 and enter the air of the work unit. It is mixed with the fuel supplied by the burner 7 and is ignited to generate thermal gas. It performs work in the power chamber 02, pushes the stopper 55, and rotates the runner 1.
  • the exhaust gas after the work is discharged from the outlet 240 on the casing 2.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • At least one set of various air inlets, air outlets, and burners may be respectively provided on the housing 2 and the corresponding positions on the housing 201, so that the runner (or swivel) can be realized. 1 Bidirectional rotation.
  • FIG. 114 is a working cross-sectional view of a sixty-fourth embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has an air compression unit and a work unit. The units are in a nested relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the air compression unit is sleeved in the work unit.
  • Multiple fan-shaped rotating plates 53 and 54 and elastic pieces 531 and 541; its structure can be manufactured to have an air compression unit and a work unit or / have at least two phases in series or / parallel or / serial / parallel or / phase set Or / the above-mentioned at least two structural relationships are combined with an air compression unit and an internal combustion runner (or swivel) engine having at least two phase-series or / parallel or / series-parallel or / phase-wound power units.
  • Each air compression unit may Manufactured to have at least one air compression chamber 01, each work unit can be manufactured to have at least one power chamber 02; the inner and outer wall surfaces of the runner 1 are round, and the inner wall surface of the casing 2 is a round shape with an inner body
  • the outer wall surface of the inner casing 201 is a circular shape with an outer body. There is at least one or / at least one contact surface between the inner wall of the runner 1 and the outer body on the outer wall of the inner casing 201.
  • the runner 1 There is at least one or / at least one contact surface between the outer wall and the inner body on the inner wall of the casing 2.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), wind Runner (or swivel) engine (or prime mover)
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the air from the inner casing 201 The inlet channel 230 enters the air compression unit, and the rotating plate 53 on the runner 1 is forced to turn away from the contact with the outer wall of the inner casing 201 by the elastic force of the elastic sheet 531 and the force of the compressed air to form an air compression chamber 01, and enter the air compression After the air of the unit is pushed and compressed in the air compression chamber 01, it flows into the work unit from the channel 1310 formed on the runner 1 after turning away from the rotary plate 53, and the rotary plate 54 on the rotary 1 receives the elastic force and heat of the elastic sheet 541. The force of the gas is forced to turn away from contact with the inner wall of the casing 2 to form a power chamber 02.
  • the air entering the work unit is mixed with the fuel supplied by the burner 7 and is ignited to generate a thermal gas in the power chamber 02.
  • the rotary plate 54 is pushed to rotate the runner 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • FIG. 115 is a working cross-sectional view of the sixty-fifth embodiment of the present invention.
  • a fluid runner (or swivel) engine (or prime mover) this embodiment has two work units, and the two work units are in a set relationship, and the runner 1 is installed between the casing 2 and the inner casing 201
  • the rotating wheel 1 is provided with a rotating plate 53 capable of reciprocating fan-shaped rotation and a baffle plate 51 capable of reciprocating movement; its structure can be manufactured to have a work unit or / have at least two phases connected in series or / parallel or / serial / parallel or /
  • a fluid runner (or swivel) engine (or prime mover) that works as a unit or / combined with at least two structural relationships described above, each of which can be manufactured with at least one power chamber 02, 021; the inside and outside of runner 1.
  • the wall surfaces are all round.
  • the inner wall surface of the casing 2 is a round shape with transmission bodies 392, 393 and a separator.
  • the outer wall surface of the inner casing 201 is a round shape with an outer wattle.
  • the structure of this embodiment can also be manufactured as a wind wheel (or swivel) to start (Or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump ( Or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, the arc arrow indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction.
  • the fluid with energy comes from the inner casing
  • the inlet channel 230 in 201 enters the internal work unit.
  • the baffle 51 on the runner 1 is pushed by the transmission body 392 on the inner wall of the casing 2 to protrude into contact with the outer wall of the inner housing 201 to form a power chamber 02 and enter the inner work.
  • the fluid of the unit performs work in the power chamber 02, and pushes the baffle 51 to rotate the runner 1.
  • the fluid after the work enters the external work unit from the channel 130 controlled by the runner 53 on the runner 1, and the rotor 53 on the runner 1
  • the fluid flowing out of the power chamber 02 is driven to turn into contact with the inner wall of the casing 2 to form a power chamber 021.
  • the fluid entering the external work unit performs work in the power chamber 021, and pushes the rotary plate 53 to rotate the runner 1.
  • the fluid is discharged from the outlet 240 on the casing 2; while the rotating plate 53 rotates with the rotating wheel 1, it is closed by the push of the transmission body 393 on the inner wall of the casing 2, and at the same time, the channel 130 on the rotating wheel 1 is closed to isolate the inlet Channel 230 and outlet 240.
  • FIG. 116 is a working sectional view of the sixty-sixth embodiment of the present invention.
  • This embodiment has two work units. The two work units are in a set relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the rotating wheel 1 is provided with a rotating block 54 and a rotating plate 53 that can be reciprocated in a fan-shaped manner; its structure can be manufactured to have a work unit or / have at least two phases connected in series or / parallel or / series and parallel or / phase sets or /
  • the fluid runner (or swivel) engine (or prime mover) that combines the above-mentioned at least two structural relationships as a work unit, each work unit can be manufactured with at least one power chamber 02; the inner and outer wall surfaces of the runner 1 are circular,
  • the inner wall surface of the casing 2 is a circular shape with an inner wattle, and the outer wall surface of the inner casing 201 is a round shape with an outer wattle.
  • the inner wall of the runner 1 and the outer wattle on the outer wall of the inner casing 201 There is at least one or / at least one contact surface between them, and there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner body on the inner wall of the casing 2; the structure of this embodiment can also be made into wind Runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine Motive, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • wind Runner or swivel engine (or prime mover)
  • internal combustion runner (or swivel) engine Motive
  • external combustion runner (or swivel) engine internal and external combustion runner (or swivel) engine
  • runner (or swivel) pump or heat pump or vacuum
  • the dashed line plus arrow in the figure indicates the fluid flow process, and the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the fluid with energy is from the inner casing 201
  • the inner inlet channel 230it is the internal work unit.
  • the rotary plate 53 on the runner 1 is closed by the push of the inner body on the inner wall of the casing 2.
  • the rotary block 54 is pushed out to contact the outer wall of the inner casing 201 to form
  • the fluid of the work chamber inside the power chamber 02 t performs work in the power chamber 02, pushes the rotary block 54, and rotates the runner 1, and the fluid after the work flows from the channel 130 on the runner 1 which is controlled by the turning plate 53 to open and close to perform work
  • the rotating plate 53 on the runner 1 is pushed away by the fluid flowing out of the internal work unit to turn into contact with the inner wall of the casing 2 to form a power chamber 021.
  • the fluid entering the external work unit does work in the power chamber 021 and pushes the rotating plate 53,
  • the runner 1 is rotated, and the fluid after work is discharged from the outlet 240 on the casing 2.
  • FIG. 117 is a working cross-sectional view of the sixty-seventh embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine. This embodiment has the air compression chamber 01 and the same in the same working unit. The power chamber 02 and the runner 1 are provided with a stopper 55 and a reciprocating movement.
  • Transmission rod 921 whose structure can be manufactured as an internal combustion runner having one working unit or / having at least two phases connected in series or / parallel or / series / parallel or / phase sets or / combined working units of at least two structural relationships ( (Or swivel) engine, each working unit can be manufactured with at least one air compression chamber 01 and at least one power chamber 02; the outer wall surface of the runner 1 is circular, and the inner wall surface of the casing 2 is circular or / eccentric An equal-diameter ring, there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the casing 2; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or original Motive), wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (Or heat
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction. As can be seen from the figure, the axis of the runner 1 and the machine The center of the inner wall of the casing 2 is not at the same place.
  • the cross-sectional shape of the stopper 55 is a wide and narrow convex shape. Air enters the working unit from the inlet 230 on the casing 2 and the stopper 55 is pushed out by the drive rod 921. It is in contact with the inner wall of the casing 2 and passes through the inlet 230 on the casing 2 to form an air compression cavity 01.
  • the air transferred into the air compression cavity 01 is pushed and compressed and retracted from the stopper 55 in the runner 1.
  • the formed channel 130 flows into the stopper 55 and is pushed by the transmission rod 921 to the power cavity 02 formed by contact with the inner wall of the casing 2, and is mixed with the fuel supplied by the burner 7 and ignited to generate a thermal gas in the power cavity 02
  • push the stopper 55 to make the runner 1 rotate, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2; the two symmetrically installed stoppers 55 push each other through the transmission rod 921; on the casing 2 Can also be fixed with a temperature measuring sprinkler or / temperature measuring device or / water sprinkler Or / smoke measuring device or / exhaust gas acid-base measuring device, etc.
  • At least one set of various air inlets, air outlets, and burners may be provided at corresponding positions on the casing 2 to realize bidirectional rotation of the runner (or swivel) 1.
  • FIG. 118 is a working sectional view of the sixty-eighth embodiment of the present invention.
  • the runner 1 of this embodiment is installed in the casing 2.
  • the runner 1 is provided with a baffle plate 51 that can move back and forth, a rotating transmission rod 922, and a rotating shaft.
  • each work unit can be manufactured with at least one power chamber 02;
  • the outer wall surface of the runner 1 is a circle shape, and the inner wall surface of the casing 2 is a round shape with an inner body, the runner
  • the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), Internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line plus arrow in the figure indicates the fluid flow process
  • the arc arrow indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction
  • the two-way arrow in the rotation transmission body 393 indicates that the rotation transmission body 393 can be subjected to
  • the automatic or / manual control outside the machine can rotate in both directions; it can be seen from the figure that the fluid with energy enters the work unit from the inlet 230 on the casing 2 and the baffle 51 that rotates with the runner 1 is pushed by the rotation transmission rod 922 Extend into contact with the inner wall of the casing 2 to form the power chamber 02, and the fluid entering the work unit performs work in the power chamber 02.
  • the baffle 51 is pushed to rotate the runner 1, and the work fluid is discharged from the outlet 240 on the casing 2.
  • the rotation transmission rod 922 is rotated by the rotation shaft 9221. While the rotation transmission rod 922 is rotating with the wheel 1, one end of the rotation transmission rod 922 is pushed by the inner body or the inner angle body on the rotation transmission body 393 to generate rotation, and the other end is rotated.
  • Push the baffle 51; the rotating transmission body 393 can be automatically or / manually controlled outside the machine to produce a direction of rotation, its axis is the same as the axis of the wheel 1, the internal transmission body or internal angle body of the transmission transmission body 393 in difference ,
  • the baffle 51 can be pushed out at different angles by turning the transmission lever 922.
  • FIG. 119 is a working cross-sectional view of the sixty-ninth embodiment of the present invention.
  • This embodiment provides a runner (or swivel) pump (or heat pump or vacuum pump).
  • the runner 1 of this embodiment is installed at Inside the pump casing 2, the runner 1 is provided with a baffle plate 51 that can be reciprocated; its structure can be manufactured with a compression unit or / has at least two phases in series or / parallel or / serial / parallel or / phase sets or / the above
  • At least two structural relationships are combined with a rotary wheel (or swivel) pump (or heat pump or vacuum pump) of the compression unit, and each compression unit can be manufactured with at least one compression cavity 01; the outer wall surface of the rotor 1 is circular, and the pump casing
  • the inner wall surface of 2 is in the shape of a circle with an inner body.
  • the structure of this embodiment can also be manufactured.
  • fluid runner (or swivel) engine or prime mover
  • wind runner (or swivel) engine or prime mover
  • internal combustion runner (or swivel) engine or external combustion runner (or turn) Body
  • internal and external combustion runner (or swivel) engine are examples of fluid flow process.
  • the solitary line arrow indicates the direction in which the wheel 1 rotates, and it can also be manufactured to turn the wheel 1 in the opposite direction.
  • the two-way arrow in the rotation transmission body 392 indicates that the rotation transmission body 392 can be subjected to.
  • Automatic or / manual control outside the pump can rotate in both directions; it can be seen from the figure that the fluid enters the compression unit from the inlet 230 on the pump casing 2 and the baffle 51 that rotates with the runner 1 is pushed out by the rotating transmission body 392 It is in contact with the inner wall of the pump casing 2 to form a compression chamber 01. The fluid entering the compression unit is pushed and compressed in the compression chamber 01 and discharged from the outlet 240 on the pump casing 2.
  • the cross-sectional shape of the rotating transmission body 392 is an eccentric scroll or / Eccentric solitary line ring, whose axis is at the same position as the axis of the wheel 1.
  • the rotating transmission body 392 can be controlled by the pump externally or / manually to generate bidirectional rotation.
  • the internal transmission body of the rotating transmission body 393 is in a different position.
  • Angle, the transmission baffle 51 can be extended at different angles to adjust and control the volume when the compression chamber 01 is formed, and adjust the compression capacity of the compression chamber 01.
  • the distance between the inlet 230 and the outlet 240 on the pump casing 2 is also adjusted. At least one channel 2410.
  • the opening and closing of the channel 2410 is controlled by a valve plate 977 installed on the pump casing 2 which can be controlled automatically or manually to adjust the working capacity of the rotary pump (or heat pump or vacuum pump); Inside, there are vortex fins or / radiating fins 12 connected as a whole or / fixedly connected or / fixedly installed.
  • FIG. 120 is a working cross-sectional view of a seventy embodiment of the present invention; this embodiment provides a rotary wheel (or swivel) pump (or heat pump or vacuum pump), and the rotary wheel 1 of this embodiment is installed on the pump Inside the casing 2, the rotating wheel 1 is provided with a rotating plate 63 capable of reciprocating fan-shaped rotation and a reciprocating transmission rod 921; its structure can be manufactured to have a compression unit or / have at least two phases connected in series or / parallel or / series and parallel Or / phase set or / combination of at least two structural relationships of the rotor (or swivel) pump (or heat pump or vacuum pump) of the compression unit, each compression unit can be manufactured with at least one compression chamber 01;
  • the wall surface is circular, and the inner wall surface of the pump casing 2 is a circular shape with an inner body.
  • the structure of the embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, Combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed lines and arrows in the figure indicate the fluid flow process.
  • the arc arrows indicate the direction in which the wheel 1 rotates. It can also be manufactured to turn the wheel 1 in the opposite direction.
  • the two-way arrows in the rotation transmission body 392 indicate that the rotation transmission body 392 can be subjected to.
  • the automatic or / manual control outside the pump can rotate in both directions; it can be seen from the figure that the fluid enters the compression unit from the inlet 230 on the pump casing 2, and the rotary plate 63 that rotates with the rotary wheel 1 is pushed away by the drive rod 921
  • the inner wall of the pump casing 2 contacts to form the compression chamber 01, and the fluid entering the compression unit is pushed and compressed in the compression chamber 01 and discharged from the outlet 240 on the pump casing 2;
  • the cross-sectional shape of the rotating transmission body 392 is provided with an outer body Or the shape of the outer corner body, whose axis is the same as the axis of the wheel 1, the rotation transmission body 392 can be automatically or / manually controlled outside the pump to produce a rotation, and the transmission outer body on the rotation transmission body 393 Or / the outer corner body is turned to different angles, and the baffle 51 can be
  • FIG. 121 is a working cross-sectional view of the seventy-first embodiment of the present invention; this embodiment provides a runner (or swivel) pump (or heat pump or vacuum pump), and the runner 1 of this embodiment is installed in a pump casing.
  • the runner 1 is provided with a baffle 51 and a transmission rod 921 that can be moved back and forth; its structure can be manufactured with a compression unit or / at least two phases in series or / parallel or / parallel Rotary (or swivel) pump (or heat pump or vacuum pump) of a compression unit combined with / combined or / at least two of the above structural relationships, each compression unit can be manufactured with at least one compression chamber 01; runner 1
  • the outer wall surface is round, and the inner wall surface of the pump casing 2 is round; the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine ( Or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process.
  • the solitary line arrow indicates the direction in which the rotor 1 rotates, and it can also be made to rotate the rotor 1 in the opposite direction.
  • the two-way arrow in the rotor 1 indicates that the rotor can be automatically controlled by the pump. Or / manual control can move up and down in both directions; it can be seen from the figure that the fluid enters the compression unit from the inlet 230 on the pump casing 2 and the baffle 51 that rotates with the runner 1 is pushed out by the drive rod 921 to the pump casing
  • the inner wall of 2 is in contact with each other to form the compression chamber 01.
  • the fluid entering the compression unit is pushed and compressed in the compression chamber 01 and discharged from the outlet 240 on the pump casing 2.
  • the rotor 1 can be controlled automatically or / manually by the outside of the pump.
  • the bidirectional movement reaches the effective volume when the control compression chamber 01 is formed, and the compression capacity of the control compression chamber 01 is adjusted.
  • the baffle 51 is There is no working ability without generating a moving rotary pump (or heat pump or vacuum pump);
  • the rotary wheel 1 has a scroll or / radiating fin 12 connected as a whole or I fixed connection or I fixed installation.
  • the wheel 1 can also move left or right or / arc automatically or manually.
  • At least one set of various inlets and outlets can be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or swivel) 1.
  • each Work cell can be manufactured with at least one air compression chamber 01 and at least one power chamber
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover) ), Wind runner (or swivel) engine (or prime mover), external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump ( Or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction. As can be seen from FIG.
  • the wattle of the wattle body is equipped with a rotatable rotating plate 974, and the baffle 974 is subjected to the elastic force of the elastic piece 9741.
  • the cross-sectional shape of the two-way rotating plate 55 is arc-shaped, and the rotating plate 974 is rotated by a midpoint rotating shaft.
  • the inlet 230 on 2 enters the working unit.
  • the lower end of the two-way rotating plate 55 is driven by the transmission shaft 551 to contact the inner wall of the casing 2. After passing through the inlet 230 on the casing 2, an air compression chamber 01 is formed.
  • the air in the air compression chamber 01 is pushed and compressed, and the rotary plate 974 is pushed away from the gap between the runner 1 and the inner body on the inner wall of the casing 2 to enter and the rotary plate 55 is driven by the drive shaft 551 to rotate to the lower end.
  • the power chamber 02 formed in contact with the inner wall of the cabinet 2 is mixed with the fuel supplied by the combustion feeder 72 and ignited by the igniter 73 to generate thermal gas.
  • the work is performed in the power chamber 02 and the rotary plate 55 is pushed to make the rotary The wheel 1 rotates, and the exhaust gas after work is discharged from the casing 2.
  • FIG. 123 is a transmission diagram of a transmission body driving a transmission shaft 551 in the present embodiment.
  • the transmission body is a circular groove with a portion of internal and external teeth provided in the end cover 3, and the transmission shaft 551 rotates with the rotation.
  • the wheel 1 rotates, when it is turned to part of the internal or external teeth on the transmission body, the rotating shaft 551 will be forced to rotate, driving the two-way rotating plate 55 connected to it or / fixedly connected or / fixedly installed.
  • the casing 2 can also be fixedly equipped with a temperature measuring sprinkler or / temperature measuring device or / water sprinkler or / smoke measuring device or / exhaust gas acid and alkali measurement ⁇ ⁇ And other.
  • the rotating body of this embodiment may also be provided on the isolation plate or / and other fixed bodies.
  • at least one set of various air inlets, air outlets, fuel feeders, and igniters may be further provided at corresponding positions on the casing 2 to implement the runner (or swivel) 1 Turn silently.
  • FIG. 124 to FIG. 125 are working sectional views and transmission diagrams of the seventy-third embodiment of the present invention.
  • This embodiment provides an internal combustion rotor (or swivel) engine.
  • This embodiment is in the same working unit.
  • Rotary wheel 1 is equipped with rotating plates 63 and 64 that can reciprocate fan-shaped rotation, transmission shafts 631 and 641, and valve disc 974.
  • Its structure can be manufactured with a working unit or / with at least Internal combustion runner (or swivel) engine with two working units in series or in parallel or in parallel or in series or in parallel or in phase sets or in at least two structural relationships, each working unit can be manufactured with at least one air compression Cavity 01 and at least one power cavity 02;
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the casing 2 is a circular shape with an inner body, the outer wall of the rotor 1 and the inner wall on the inner wall of the casing 2
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or original Motive), external combustion runner (or swivel) engine And external ignition wheel (or twist) of the engine, the wheel (or rotors) a pump (or pump or a vacuum pump
  • the dashed line plus arrow in the figure indicates the fluid flow process, and the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the inner portion of the inner wall of the casing 2 There is at least one channel 2410 in the body, and a valve disc 973 is installed at the exit of each channel 2410. Air is pushed from the inlet 130 controlled by the rotary plate 63 on the runner 1 to open the valve piece 974 and enter the working unit, and the rotary plate 64 Driven by the transmission shaft 641, it is turned into contact with the inner wall of the casing 2 to form an air compression cavity 01.
  • the air transferred into the air compression cavity 01 is pushed and compressed to pass from the channel 2410 in the inner body on the inner wall of the casing 2.
  • the valve disc 973 is pushed open to enter the power chamber 02 formed by the end of the rotating plate 63 driven by the transmission shaft 631 to contact the inner wall of the casing 2, and it is mixed with the fuel supplied by the burner 7 and is ignited to generate a thermal gas Do it in power chamber 02 Work, push the rotary plate 63 to rotate the runner 1, and the exhaust gas after the work is discharged from the outlet 240 on the casing 2; there is a connection between the runner 1 and the power output shaft 11 or / fixed connection or / fixed installation ⁇ ⁇ Scroll ⁇ // ⁇ ⁇ 12 ⁇ It is provided.
  • the transmission shafts 631 and 641 have external bodies connected together or / fixedly connected or / fixedly installed. Or / external body or / convex body, the transmission body is a circular ring groove with inner and outer body or inner and outer angle body or inner and outer convex body provided in the end cap 3, and the transmission shafts 631 and 641 rotate with the wheel 1,
  • the rotating shafts 631 and 641 will be forced to rotate, driving the shaft to be integrated with one another or / fixedly connected or /
  • the fixedly installed rotating plates 63 and 64 rotate synchronously; the external wing body or external horn body or external convex body of the transmission is provided on the inner ring 393 in the end cover 3; the end cover 3 can also be seen from the figure
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • the rotating body of this embodiment may also be provided on the isolation plate or / and other fixed bodies.
  • FIG. 126 is a working cross-sectional view of a seventy-fourth embodiment of the present invention; this embodiment provides an internal combustion runner (or swivel) engine.
  • This embodiment has the air compression chamber 01 and the same in the same working unit.
  • the power chamber 02, the rotor 1 is equipped with rotating plates 63 and 64 that can reciprocate in a fan shape, and transmission shafts 631, 641, and 642.
  • Its structure can be manufactured with a working unit or / at least two phases in series or / parallel or
  • the outer wall surface of the runner 1 is circular
  • the inner wall surface of the casing 2 is a circular shape with an inner body.
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or prime mover), an external combustion runner (Or swivel) engine, internal and external combustion runner (or Body) of the engine, the wheel (or transfer Body) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the inner watts on the inner wall of the casing 2 The body has at least one arc-shaped groove, and each arc-shaped groove is provided with a rotating plate 62 capable of reciprocating fan-shaped rotation.
  • the rotating angle of the rotating plate 62 is controlled by a control lever 927 provided on the casing 2 which can be automatically or manually controlled.
  • the two-way arrow on the control lever 927 indicates that the control lever 927 can move in both directions.
  • a spring 913 is installed between the rotating plate 62 and the casing 2 to control the unidirectional air flow. The air enters the working unit from the inlet 230 on the casing 2 and rotates.
  • the plate 64 is driven by the transmission shaft 641 to contact the inner wall of the casing 2 to form an air compression cavity 01.
  • the air transferred into the air compression cavity 01 is pushed and compressed, and from the inner body on the inner wall of the casing 2
  • the arc-shaped groove pushes away the rotating plate 62, which is driven by the rotating plate 63 to the power chamber 02 formed in contact with the inner wall of the casing 2 driven by the transmission rotating shaft 631, mixed with the fuel supplied by the burner 7, and ignited.
  • the rotating wheel 1 has a scroll or a heat sink or a fixed connection or a fixed installation.
  • Sheet 12 there are two transmission bodies 395, 396, both transmission bodies 395, 396 are fan-shaped bodies or / angle bodies or / convex bodies, and the rotation of the transmission bodies 395, 396
  • the axis is the same as the axis of the wheel 1.
  • the transmission body 395 directly transmits the transmission shaft 631 which is connected to the rotating plate 63 or is fixedly connected or fixed.
  • the transmission body 396 transmits the The transmission rotating shaft 642, and the transmission rotating shaft 642 are connected with the rotating plate 64 as a whole or fixedly connected or fixedly installed through a part of the external gear transmission.
  • the transmission rotating shaft 631 is connected as a whole or / fixed connection or I fixed.
  • the installed external body or / external body or / convex body, part of the external gear is on the transmission shaft 641, and the external shaft or / outer body is connected on the transmission shaft 642 as a whole or fixedly connected or fixed.
  • the two-way arrows on the transmission bodies 395 and 396 indicate that the transmission bodies 395 and 396 can be controlled by the external or automatic manual control of the two-way rotation.
  • the casing 2 can also be fixedly provided with a temperature measuring sprinkler or a temperature measuring device or a water sprinkler or a smoke measuring device or an exhaust gas acid-base measuring device.
  • the rotating body of this embodiment may also be provided on the isolation plate or / and other fixed bodies.
  • FIG. 127 is a working sectional view of the seventy-fifth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover), and the runner 1 of this embodiment is installed in the casing 2, the casing 2 is provided with a rotating plate 55 that can be reciprocated; its structure can be manufactured to have a work unit or / at least two phases in series or I parallel or I series parallel or / phase sleeve or / at least two of the above
  • This structural relationship is combined to make a 3 ⁇ 4-unit fluid runner (or swivel) engine (or prime mover), and each work unit can be manufactured with at least one power chamber 02; the outer wall surface of the runner 1 is equipped with an outer body.
  • the inner wall surface of the casing 2 is in the shape of a circle.
  • the structure of this embodiment can also be manufactured into Wind runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine, Runner (or swivel) pump (or heat pump or vacuum pump) ).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates.
  • the runner 1 rotates in the opposite direction.
  • the fluid with energy pushes one end of the rotating plate 55 into the work unit from the inlet 230, and the other end of the rotating plate 55 also turns away, so that the outlet 240 on the casing 2 It is opened to form the power chamber 02, and the fluid entering the work unit performs work in the power chamber 02, pushing the runner 1 to rotate, and the fluid after the work is discharged from the outlet 240 on the casing 2.
  • the outer body on the runner 1 turns to At the outlet 240, the inlet 230 and the outlet 240 are closed, and the next turn is t.
  • the turn plate 55 is rotated by the rotating shaft 551.
  • the connection between the rotating wheel 1 and the power output shaft 11 is integrated or fixed connection or fixed. Installed scroll or heat sink 12.
  • FIG. 128 is a working cross-sectional view of the seventy-sixth embodiment of the present invention; this embodiment provides a runner (or swivel) pump (or heat pump or vacuum pump).
  • the runner 1 of this embodiment is installed at Inside the pump casing 2, the runner 1 is provided with a reciprocating baffle 51 and a reciprocating transmission rod 921; its structure can be manufactured to have a compression unit or / have at least two phases connected in series or / parallel or / string Rotary (or swivel) pump (or heat pump or vacuum pump) pump (or heat pump or vacuum pump) that combines compression units in parallel or / phase sets or / at least two of the above structural relationships, each compression unit can be manufactured with at least one compression chamber 01; runner 1
  • the outer wall surface is circular, the inner wall surface of the pump casing 2 is round, and there is at least one or / at least one contact surface between the outer wall of the runner 1 and the inner wall of the pump casing 2; the structure of this embodiment can
  • the dashed line and arrow in the figure indicate the fluid flow process, and the solitary line arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the pump The center of the inner wall of the casing 2 is not at the same place.
  • the fluid enters the compression unit from the inlet 230 on the pump casing 2, and the baffle plate 51 that rotates with the runner 1 is pushed by the transmission rod 921 to contact the inner wall of the pump casing 2 to form compression.
  • the fluid entering the compression unit is pushed and compressed in the compression cavity 01 and discharged from the outlet 240 on the pump casing 2.
  • the two symmetrically installed baffles 51 push each other through the transmission rod 921; It can be seen that there is an inlet and outlet 250 on the pump casing 2.
  • the two-way arrow at the inlet and outlet 250 indicates that the transmission fluid (gas) can enter and exit the inlet and outlet 250.
  • the dashed line and the two-way arrow in the inlet and outlet 250 indicate the transmission fluid (gas).
  • the pump casing 2 is provided with an arc-shaped bar 59 that can be arc-shaped, and a bidirectional arrow next to the solitary bar 59 indicates that the solitary bar 59 can move in a two-way arc.
  • the transmission of the extracted transmission fluid (gas) can be Arc movement, since the movement of the arcuate strip 59, can be adjusted to control the effective volume of the compression chamber 01 is formed when, can control the pump working capacity adjustment wheel (or heat pump) is.
  • At least one set of various inlets and outlets may be provided at the corresponding positions on the pump casing 2 to realize the bidirectional rotation of the runner (or swivel) 1.
  • FIG. 129 is a working sectional view of the seventy-seventh embodiment of the present invention.
  • a rotary wheel (or swivel) pump (or heat pump or vacuum pump).
  • the rotary wheel 1 of this embodiment is installed in a pump casing 2.
  • the rotary wheel 1 is provided with a baffle 51 and a reciprocating transmission rod 921.
  • each compression unit can be manufactured with at least one compression cavity 01;
  • the outer wall surface of the runner 1 is circular, the inner wall surface of the pump casing 2 is circular, the outer wall of the rotor 1 and the pump casing 2
  • the structure of this embodiment can also be manufactured as a fluid runner (or swivel) engine (or prime mover), a wind runner (or swivel) engine (or Prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine.
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates. It can also be made that the runner 1 rotates in the opposite direction.
  • the axis of the runner 1 and the pump The center of the inner wall of the casing 2 is not at the same place.
  • the fluid enters the compression unit from the inlet 230 on the pump casing 2, and the baffle plate 51 that rotates with the runner 1 is pushed by the transmission rod 921 to contact the inner wall of the pump casing 2 to form compression.
  • the fluid entering the compression unit is pushed and compressed in the compression cavity 01 and discharged from the outlet 240 on the pump casing 2.
  • the two symmetrically installed baffles 51 push each other through the transmission rod 921; It can be seen that the pump housing 2 has a control lever 927.
  • the two-way arrow next to the control lever 927 indicates that the control lever 927 can be controlled by the pump to move automatically or / manually in both directions.
  • the pump housing 2 is equipped with a rotatable arc-shaped rotating plate 58, arc.
  • the rotary plate 58 can be rotated in both directions by the pushing or driving of the control pestle 927. Due to the rotation of the solitary rotary plate 58, the effective volume when the compression cavity 01 is formed can be controlled, and the rotary pump (or heat pump or vacuum pump) can be controlled and adjusted. ) Ability to work.
  • At least one set of various inlets and outlets can be set at the corresponding positions on the pump casing 2 to realize the two-way rotation of the runner (or swivel) 1.
  • FIG. 130 is a working cross-sectional view of the seventy-eighth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover).
  • the runner 1 of this embodiment is installed Inside the casing 2, the rotating wheel 1 is provided with a rotating plate 55 that can be reciprocated; its structure can be manufactured to have a work unit or / have at least two phases connected in series or / parallel or / series and parallel or / phase sets or /
  • the fluid runner (or swivel) engine (or prime mover) that combines the above-mentioned at least two structural relationships as a work unit, each work unit can be manufactured with at least one power cavity 02; the outer wall surface of the runner 1 is a circular shape, and the machine
  • the inner wall surface of the shell 2 has a circular shape with an inner body.
  • the structure of this embodiment can also Manufactured into wind runner (or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) Engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the wheel 1 rotates. It can also be made that the wheel 1 rotates in the opposite direction.
  • the turn plate 55 on the wheel 1 When turning over the inner body in the casing 2, the fluid with energy pushes one end of the turn plate 55 from the inlet 230 to form a power cavity 02, and the other end of the turn plate 55 also turns away, so that the exit on the runner 1 140 turns on, the fluid entering the work unit performs work in power chamber 02, pushes the rotary plate 55 to rotate the runner 1, and the fluid after work is discharged from the outlet 140 on the runner 1, and when the rotary plate 55 on the runner 1 turns to
  • the turn plate 55 is forced to turn off, and at the same time, the exit 140 on the turn wheel 1 is closed, and then itA ⁇ is turned to perform work in the next round, the turn plate 55 is rotated by the rotation shaft 551; the turn wheel 1 A scroll or heat sink 12 is integrally connected with the power output shaft 11 or / fixedly connected or / fixedly installed.
  • FIG. 131 is a working cross-sectional view of the seventy-ninth embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover). This embodiment has two work units and two work units. The units are in a nested relationship.
  • the runner 1 is installed between the casing 2 and the inner casing 201.
  • the runner 1 is provided with a rotating plate 61 and 62 and an elastic piece 612 that can be reciprocated in a fan shape.
  • Its structure can be manufactured to have a A power unit or a fluid runner (or swivel) engine (or prime mover) having at least two phases connected in series or / parallel or / series / parallel or / phase sets or / combined with at least two structural relationships described above as a power unit, each The work unit can be made with at least one The power chamber 02; the inner and outer wall surfaces of the runner 1 are round, the inner wall surface of the casing 2 is a round shape with an inner body, and the outer wall surface of the inner casing 201 is a round shape with an outer body.
  • At least one contact surface between the inner wall of 1 and the outer body on the outer wall of the inner casing 201, and at least one or / there is between the outer wall of the runner 1 and the inner body on the inner wall of the casing 2.
  • At least one contact surface; the structure of this embodiment can also be manufactured into a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (or swivel) Engine, internal and external combustion runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dotted line and arrow in the figure indicate the fluid flow process, and the arc arrow indicates the direction in which the runner 1 rotates.
  • the fluid with energy enters the inner work unit from the inlet 230 in the inner casing 201, and the runner After the turning plate 61 on 1 is turned over the outer body on the outer wall of the inner case 201 with the runner 1, due to the elastic force of the elastic piece 612 and the thrust of the fluid, it quickly turns away from contact with the outer wall of the inner case 201 to form a power chamber. 02, The fluid of the internal work unit performs work in the power chamber 02, and pushes the rotary plate 61 to rotate the rotary wheel 1.
  • the rotary plate 61 While the rotary plate 61 is turned away, due to the elastic force of the elastic sheet 612 and the fluid thrust, the rotary plate on the rotary wheel 1 62 is also forced to turn into contact with the inner wall of the casing 2 to form a power chamber 021, and the channel 130 on the runner 1 is opened.
  • the fluid that performs work in the internal work unit passes through the channel 130 and simultaneously enters the external work unit to perform work.
  • the fluid flows out from the outlet 240 on the casing 2.
  • FIG. 132 to FIG. 133 are working cross-sectional views and transmission diagrams of the eighty embodiment of the present invention; this embodiment provides a fluid runner (or swivel) engine (or prime mover), and this embodiment has two work Unit, the two work units are in a set relation, the runner 1 is installed between the casing 2 and the inner casing 201, and the runner 1 is provided with a rotating plate 61 and 62 that can reciprocate in a fan shape; its structure can be manufactured into A fluid runner (or swivel) engine (or prime mover) with a power unit or / with at least two phases connected in series or / parallel or / series / parallel or / phase sets or / at least two structural relationships combined to perform a power unit Each work unit can be manufactured with at least one power cavity 02; the inner and outer wall surfaces of the runner 1 are circular, the inner wall surface of the casing 2 is a circular shape with an inner body, and the outer wall surface of the inner casing 201 is Garden shape with outer
  • a contact surface; the structure of this embodiment can also be manufactured as a wind turbine (or swivel) engine (or prime mover), an internal combustion runner (or swivel) engine, an external combustion runner (or swivel) engine , Internal and external combustion type runner (or swivel) engine, runner (or swivel) pump (or heat pump or vacuum pump).
  • the dashed line and arrow in the figure indicate the fluid flow process, the arc arrow indicates the direction in which the runner 1 rotates, and it can also be made that the runner 1 rotates in the opposite direction; as can be seen in Figure 132, the fluid with energy is from the inner shell
  • the inlet 2310 in the body 201 enters the internal work unit.
  • the turn plate 62 on the runner 1 rotates with the runner 1 on the outer wall of the inner casing 201, it is connected with the turn plate 62 as a whole or / is fixedly connected or /
  • the fixedly installed rotating transmission shaft 621 is driven by the transmission body 392 and the thrust of the fluid, and quickly turns away from contact with the outer wall of the inner casing 201 to form a power chamber 02.
  • the fluid entering the internal work unit performs work in the power chamber 02.
  • the rotary plate 62 is pushed to rotate the runner 1, and the fluid after the internal work unit performs work flows out from the outlet channel 2410 on the inner casing 201; the fluid with energy enters the outer work unit from the inlet 230 on the casing 2 and the runner
  • the rotating transmission shaft 611 connected to the rotating plate 61 as a whole or / fixedly connected or / fixedly received by the transmission body 392 Transmission and fluid thrust quickly turn away from the case 2
  • the fluid enters the outer work units acting in the power chamber 021, pushing the rotating plate 61, so that the wheel 1 is rotated, the outer work units work fluid flowing out from the outlet of the housing 2240.
  • the transmission body 392 and the end cover 3 are connected as a whole or fixedly connected or fixedly installed. It is a curved bar with teeth on both sides; the rotating transmission shafts 611 and 621 are partially external The rotating shafts of the gears 691 and 692, and the arc arrows next to the rotating transmission shafts 611 and 621 indicate the directions in which they rotate with the rotating wheel 1.
  • the figure also shows the inlet 3310 and the outlet of the end cover 3 corresponding to the inner housing 201 3410.
  • FIG. 134 is a partial cross-sectional view of the first embodiment of a baffle 51 installed on the runner (or swivel) 1 or the swivel 1 in the present invention; the arc on the runner (or swivel) 1 or / the swivel 1 in the figure
  • Line arrow Represents the direction of rotation of the revolver (or swivel) 1 or / revolver 1 can also be manufactured as revolver (or swivel) 1 or / revolution 1 turns in the opposite direction;
  • the straight arrow in the baffle 51 indicates the stop
  • the plate 51 can be moved back and forth linearly; it can be seen from the figure that a roller 91 can be installed on both sides of the lower part of the baffle plate 51, and reciprocates with the baffle plate 51.
  • a rollable roller 91 is in contact with both sides of the baffle plate 51.
  • the top of the baffle plate 51 is provided with a straight bar 53 capable of reciprocating movement, and the straight bar 53 is ejected by at least one spring 913.
  • FIG. 135 is a partial cross-sectional view of a second embodiment of a baffle 51 on a runner (or swivel) 1 or a swivel 1 of the present invention; ⁇ on the runner (or swivel) 1 or / on the swivel 1
  • the line arrows indicate the turning direction of the turning wheel (or turning body) 1 or / turning body 1.
  • baffle 51 can also be manufactured as the turning wheel (or turning body) 1 or / turning body 1 turning in the opposite direction; the straight arrow in the baffle 51 It indicates that the baffle 51 can move linearly back and forth; as can be seen from the figure, three rollable rollers are installed on each of the two walls of the notch on the runner (or the swivel) 1 or the swivel 1 91.
  • the roller 91 is in contact with both sides of the baffle 51; the top of the baffle 51 is provided with two straight bars 53 that can be reciprocated, and each of the straight bars 53 is ejected by at least one spring 913.
  • FIG. 136 is a partial cross-sectional view of the third embodiment of the baffle 51 on the runner (or swivel) 1 or the swivel 1 in the present invention; the arc on the runner (or swivel) 1 or / the swivel 1 in the figure
  • the line arrows indicate the turning direction of the turning wheel (or turning body) 1 or / turning body 1. It can also be manufactured as the turning wheel (or turning body) 1 or / turning body 1 turning in the opposite direction; the straight arrow in the baffle 51 It shows that the baffle 51 can be moved back and forth linearly; it can be seen from the figure that a roller 91 can be installed on the lower side of the baffle 51, and reciprocates with the baffle 51.
  • a rollable roller 91 is in contact with one side of the baffle 51; a top 53 of the baffle 51 is provided with a straight bar 53 that can be reciprocated, and the straight bar 53 is ejected by at least one elastic sheet 914, and the straight bar 53 Lower one
  • a rollable roller 911 that reciprocates with the straight bar 53 is mounted on the surface, and in contact with a side wall of the mounting groove on the top end of the baffle plate 51 during movement; It is also equipped with a roller 911 that can roll, and this roller 911 is in contact with one side of the straight bar 53.
  • FIG. 137 is a partial cross-sectional view of a fourth embodiment of a baffle 51 on a runner (or swivel) 1 or a swivel 1 in the present invention; an arc on the runner (or swivel) 1 or / the swivel 1 in the figure
  • the line arrows indicate the turning direction of the turning wheel (or turning body) 1 or / turning body 1, and can also be manufactured as turning wheel (or turning body) 1 or / turning body 1 turning in the opposite direction; the two-way straight arrow in the baffle 51 It indicates that the baffle 51 can move linearly back and forth; it can be seen from the figure that a roller 91 is installed on each of the upper and lower sides of the baffle 51, and reciprocates with the baffle 51.
  • FIG. 138 is a partial cross-sectional view of a fifth embodiment of a baffle 51 on a runner (or swivel) 1 or a swivel 1 in the present invention; an arc on the runner (or swivel) 1 or / the swivel 1 in the figure
  • the line arrows indicate the turning direction of the turning wheel (or turning body) 1 or / turning body 1, and can also be manufactured as turning wheel (or turning body) 1 or / turning body 1 turning in the opposite direction; the two-way straight arrow in the baffle 51 It indicates that the baffle 51 can move linearly back and forth; it can be seen from the figure that a roller 91 is mounted on both sides of the upper part of the baffle 51, and reciprocates with the baffle 51.
  • the baffle 51 and the runner (or The wall surface of the installation groove on 1 or / rotation 1 is in contact with the grooves on both sides extending from the installation groove; on the runner (or rotation) 1 or /
  • Each of the two side walls is also provided with a roller 91 that can roll, and the roller 91 is in contact with both sides of the baffle 51;
  • the top of the baffle 51 is provided with a straight bar 54 that can be reciprocated, and the straight bar 54 is composed of at least one Top spring 913.
  • FIG. 139 is a partial cross-sectional view of a sixth embodiment of a baffle 51 on a runner (or swivel) 1 or a swivel 1 in the present invention; an arc on the runner (or swivel) 1 or / on a swivel 1
  • Line arrow Represents the direction of rotation of the runner (or swivel) 1 or / turn 1 can also be manufactured as the runner (or swivel) 1 or / turn of swivel 1 in the opposite direction;
  • the two-way straight arrow in the baffle 51 indicates the stop
  • the plate 51 can move linearly back and forth, and the two-way straight arrow in the push rod 95 indicates that the push rod 95 can move linearly back and forth; as can be seen from the figure, the installation on the wheel (or the swivel) 1 or / the swivel 1
  • Three wall rollers 91 are mounted on the two wall surfaces of the groove and on both
  • Each roller 91 is in contact with the baffle plate 51.
  • the top of the baffle plate 51 is provided with a piece that can be moved back and forth.
  • the straight bar 54 is ejected by at least one spring 914, and the spring 914 is pushed by the pushing rod 95.
  • the pushing rod 95 is installed in the baffle 51 and is driven by a transmission mechanism.
  • each of the upper and lower surfaces of the baffle plate 51 is provided with a roller 91 capable of rolling, and moves back and forth with the baffle plate 51, and moves with the housing 2 or / the pump housing 2 or / the housing
  • the wall surfaces of the mounting grooves on the body 2 are in contact with each other.
  • a rollable roller 91 is also installed on each of the two wall surfaces of the housing 2 or / the pump housing 2 or / the housing 2
  • the rollers 91 are in contact with both sides of the baffle 51; the top of the baffle 51 is provided with two rollers 94 that can roll.
  • FIG. 141 is a partial cross-sectional view of a second embodiment of a baffle plate 51 installed on the casing 2 or the pump casing 2 or the casing 2 in the present invention; the two-way straight arrow in the baffle plate 51 indicates that the baffle plate 51 can be moved back and forth linearly.
  • the two-way straight arrow in the pushing pestle 95 indicates that the pushing lever 95 can move back and forth linearly; as can be seen from the figure, a roll 91 can be installed on both sides of the lower side of the baffle plate 51 and reciprocates with the baffle plate 51.
  • a notch on the side wall of the casing 2 is also provided with a roller 91 that can roll, and the roller 91 is in contact with one side of the baffle 51;
  • the top of the baffle 51 is provided with a straight line that can be reciprocated.
  • the strip 54 and the straight strip 54 are ejected by at least one spring 914.
  • the spring 914 is pushed by the push rod 95.
  • the push rod 95 is installed in the baffle 51 and is driven by a transmission mechanism.
  • the pushing rod 95 is provided with a ball 911, and the ball 911 moves with the pushing rod 95.
  • FIG. 142 is a partial cross-sectional view of a third embodiment of a baffle plate 51 installed on the casing 2 or the pump casing 2 or the casing 2 in the present invention; a bidirectional straight arrow in the baffle plate 51 in the figure indicates that the baffle plate 51 can be moved back and forth linearly; As can be seen from the figure, three rollable rollers 91 are mounted on each side of the baffle 51, and they move back and forth with the baffle 51, and move with the casing 2 or / the pump casing 2 or / the housing The wall surface of the installation groove on 2 and the grooves on both sides of the installation groove are in contact; the top of the baffle 51 is provided with a roller 94 that can roll, the roller 94 rolls on a bearing pad 93, and the bearing pad 93 is composed of at least one spring 913 bombs.
  • FIG. 143 is a partial cross-sectional view of a first embodiment of an arc-shaped baffle plate 52 on the runner (or swivel) 1 or the swivel 1 in the present invention; on the runner (or swivel) 1 or / on the swivel 1
  • the arc arrow indicates the direction of rotation of the wheel (or swivel) 1 or / the swivel 1, or it can be manufactured as the wheel (or swivel) 1 or / the swivel 1 rotates in the opposite direction;
  • the bi-directional arc arrow indicates that the solitary baffle 52 can be moved back and forth solitary lines.
  • two rollable rollers 91 are installed on each side of the solitary baffle 52, and follow the curved baffle. 52 reciprocating arc movement, contacting the wall surface of the installation groove on the runner (or the rotation body) 1 or / the rotation body 1 and the two grooves extending from the installation groove during the movement; the top of the solitary baffle 52 Equipped with a straight bar 55 that can be reciprocated, ejected by at least one spring 913.
  • FIG. 144 is a partial cross-sectional view of the first embodiment in which an isolated baffle 52 is installed on the casing 2 or the pump casing 2 or the casing 2 in the present invention; the two-way solitary arrow in the curved baffle 52 in the figure indicates the isolated baffle
  • the plate 52 can be moved back and forth in an arc.
  • the wall of the installation groove on the casing 2 or / the pump casing 2 or / the housing 2 and the two sides of the extension groove of the installation groove are installed together.
  • FIG. 145 is a partial cross-sectional view of the first embodiment of the rotary plate (or swivel) 1 or the swivel plate 62 on the swivel 1 according to the present invention; the arc on the runner (or swivel) 1 or / the swivel 1 in the figure
  • the line arrows indicate the direction of rotation of the runner (or swivel) 1 or / the swivel 1.
  • the rotation plate 62 can also be manufactured as a runner (or (Rotation) 1 or / rotation 1 rotates in the opposite direction; the bidirectional arc arrow next to the rotation plate 62 indicates that the rotation plate 62 can be reciprocated fan-shaped; as can be seen from the figure, the rotation plate 62 is rotated by the rotation shaft 65, and the rotation The shaft hole on the plate 62 is a waist-shaped hole.
  • the rotating plate 62 is rotated on the bearing pad 95.
  • the bearing pad 95 is spring-loaded by the spring 915. When the rotation plate 62 is turned away, the spring plate 915 will be extended outward.
  • the top of 62 is equipped with a straight bar 55 that can be moved back and forth, and is ejected by at least one spring 913.
  • 146 is a partial cross-sectional view of the first embodiment of the straight baffle 51 equipped with rollers 91 on the side of the present invention; a two-way straight arrow in the straight baffle 51 in the figure indicates that the straight baffle 51 can move back and forth linearly; As can be seen in the figure, three rollers 91 that can roll are mounted on the side of the straight baffle 51.
  • FIG. 147 is a partial cross-sectional view of the first embodiment of the arc-shaped baffle plate 52 equipped with balls 92 on the side of the present invention; the bidirectional arc arrow in the arc-shaped baffle plate 52 indicates that the arc-shaped baffle plate 52 can be moved back and forth; As can be seen in the figure, the side of the arc-shaped baffle 52 is provided with three balls 92 that can roll.
  • FIG. 148 is a partial cross-sectional view of the first embodiment of the arc-shaped rotating plate 62 equipped with balls 92 on the side of the present invention; the two-way solitary arrow next to the arc-shaped rotating plate 62 in the figure indicates that the lone-shaped rotating plate 62 can reciprocate; It can be seen that the side of the arc-shaped rotating plate 62 is provided with a ball 92 that can roll, and the top of the arc-shaped rotating plate 62 is provided with a roller 94 that can be rolled.
  • FIG. 149 is a partial cross-sectional view of the first embodiment of the straight rotating plate 61 equipped with rollers 91 on the side of the present invention; a bidirectional solitary arrow next to the straight rotating plate 61 in the figure indicates that the straight rotating plate 61 can reciprocate; It can be seen that a side of the straight turning plate 61 is provided with a roller 91 that can roll, and a straight bar 55 that can be reciprocated is mounted on the top of the straight turning plate 61.
  • the straight length 55 is ejected by at least one spring 913, and the straight turning The plate 61 is reciprocated in a fan shape with a rotating shaft 65.
  • FIG. 150 is a partial cross-sectional view of the first embodiment of the first embodiment in which two rollers 91 and balls 92 are mounted on both front and side surfaces of the straight baffle 51;
  • the two-way straight arrows in the straight baffle 51 in the figure indicate that the straight baffle 51 may Reciprocating linear movement; it can be seen from the figure ⁇ that the two positive sides of the straight baffle 51
  • Each side is equipped with two rollers 91 that can roll, and on its side are two rollers 92 that can be rolled.
  • the role of the roller 91 may be replaced by the ball 92, and the role of the ball 92 may also be replaced by the roller 91.
  • the role of the spring 913 may be replaced by the elastic sheet 914, and the same elastic sheet 914 The function of the spring can also be replaced by the spring 913.
  • Figures 134 to 150 are only part of the examples, and other methods can be used to make the baffle or / rotary plate or / stopper or / rotary block flexibly reciprocate or / reciprocate.
  • FIGS. 134 to 150 and other methods are applicable to various rotor (or swivel) engines (or prime movers) and runner (or swivel) pumps (or heat pumps or vacuum pumps) in the present invention.
  • 151 to 152 are partial cross-sectional views of the first embodiment of the synchronous mechanical transmission mechanism in the present invention; this embodiment is applicable to various fluid runner (or swivel) engines (or prime movers) and wind runners ( Or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or (Rotor) pump (or heat pump or vacuum pump); it can be seen from FIG. 151 that the two pieces of baffle plate 51 are pushed by one end of two transmission rotating rods 922, and the other end of the transmission rotating rod 922 is inserted into the circular groove of the end cover 3.
  • the baffle 51 and the transmission lever 922 are both installed in the wheel 1, and when the wheel 1 rotates, the transmission lever 922 turns to the cut of the circular groove 3910, and then rotates at the rotation point 9221 after receiving force.
  • the figure also shows the combined structure of the casing 2, the inner body 271 on the inner wall of the casing 2, and the power output shaft 11.
  • FIG. 152 is a cross-sectional view of the arrow mark in FIG. 151. From the figure, the shape of the inner side of the end cap 3, especially the shape of the circular groove 3910, can be seen. There is everything above it.
  • the transmission lever 922 can be forced to rotate.
  • the power output shaft 11 passes through the central shaft hole of the end cover 3.
  • 153 to 154 are partial cross-sectional views of the second embodiment of the synchronous mechanical transmission mechanism in the present invention; this embodiment is applicable to various fluid runner (or swivel) engines (or prime movers) and wind runners ( Or swivel) engine (or prime mover), internal combustion runner (or swivel) engine, external combustion runner (or swivel) engine, internal and external combustion runner (or swivel) engine and runner (or (Rotary) pump (or heat pump or vacuum); it can be seen from FIG. 153 that the two rotating blocks 62 are pushed by two driving rods 921, and the two driving rods 921 are pushed by one end of the two driving rods 922, respectively.
  • the transmission rotating rod 922 penetrates the first section of the rotating wheel 1 and is inserted at the cam 392 in the end cover 3.
  • the rotating block 62, the driving rod 921, and the transmission rotary pestle 922 are all installed in the rotating wheel 1.
  • the transmission When the rotating rod 922 is turned to the convex portion of the cam 392, it is rotated at the rotating point 9221 after being stressed, and the transmission rod 921 is pushed, and then the turning block 62 is opened; the case 2 and the inner wall of the case 2 are also shown in the figure.
  • FIG. 154 is a cross-sectional view of the arrow mark in FIG. 153.
  • the shape of the inner side of the end cap 3, especially the shape of the cam 392, has a protruding portion below, which can force the transmission lever 922 to generate When rotated, the power output shaft 11 passes through the central shaft hole of the end cover 3.
  • FIG. 155 is a cross-sectional view of the first embodiment of the fuel feeder 71 in the present invention. As can be seen from the figure, it has a straight hole 70 with a protruding mounting member 75 in the middle. Install the seal ⁇ 962, there is a thread 79 under the seal ring 962.
  • FIG. 156 is a cross-sectional view of the second embodiment of the fuel feeder 72 in the present invention. As can be seen from the figure, it has a curved hole // inclined hole 700, and a protruding connecting piece 75 in the middle. A sealing group 962 is installed under the setting member 75, and a thread 79 is arranged below the sealing ring 962.
  • FIG. 157 is a sectional view of the first embodiment of the igniter 73 in the present invention.
  • the center of the igniter 73 passes through a conductor or conductor 721 with an insulator, and the lower conductor or conductor 721 is connected to the discharge electrode 722.
  • FIG. 158 is a cross-sectional view of the first embodiment of the burner 7 in the present invention. As can be seen from the figure, it has a straight hole 70, and the ignition element 723 is installed in the straight hole 70.
  • the ignition element 723 is composed of a conductor or a wire with an insulator. 721 supplies power.
  • FIG. 159 is a cross-sectional view of the second embodiment of the burner 7 according to the present invention. As can be seen from the figure, it has a straight hole 70 that communicates with an empty slot 710 at the lower end of the burner 7, and the ignition element 723 is installed here. In the empty slot 710, power is supplied by a conductor or conductor 721 with an insulator.
  • the outer wall of the burner 7 has a thread 79 and a seal ring 962 at the lower part.
  • Embodiment 160 is a cross-sectional view of Embodiment 3 of the burner 7 according to the present invention. As can be seen from the figure, it has a straight hole 70, an ignition element 723 is installed in the straight hole 70, and a power source is provided by a conductor or conductor 721 with an insulator.
  • the middle section of the burner 7 has a protruding integral mounting member 75.
  • a sealing ring 962 is installed under the mounting member 75, and a thread 79 is arranged below the sealing ring 962.
  • FIG. 161 is a cross-sectional view of the fourth embodiment of the burner 7 in the present invention. As can be seen from the figure, it has a bent hole // oblique hole 700, and the ignition element 723 is installed in the bent or / oblique hole 700.
  • the conductor or / conductor 721 supplies power
  • the burner 7 has a protruding mounting member 75 integrally formed thereon, and a sealing ring 962 is installed under the mounting member 75, and a thread 79 is provided under the sealing ring 962.
  • FIG. 162 is a cross-sectional view of the fifth embodiment of the burner 7 according to the present invention. It can be seen from the figure that it has a curved or / oblique hole 700, and a straight hole 70. The lower port of the straight hole 7 communicates with the curved hole. In the lower part of the or oblique hole 700, the ignition element 723 is installed at the lower port of the straight hole 70 in the bent or oblique hole 700, and the power is supplied by a conductor or conductor 721 with an insulator.
  • a burner 7 has a protruding
  • An integral mounting member 75 is provided under the mounting member 75, and a sealing ring 962 is installed under the mounting member 75.
  • a thread 79 is formed under the sealing ring 962.
  • FIG. 163 is a cross-sectional view of Embodiment 6 of the burner 7 in the present invention. It can be seen from the figure that it has a straight hole 70 and a bent hole or / slanted hole 700, and the lower port of the bent or / slanted hole 700 Connected to the lower part of the straight hole 70, the ignition element 723 is installed in a curved hole in the straight hole 70 or / At the lower port of the slanted hole 700, power is supplied by a conductor or wire 721 with an insulator.
  • the burner 7 has a protruding mounting member 75, which is provided with a sealing ring 962 and a sealing ring 962. There is a section of thread 79.
  • Figure 164 is a cross-sectional view of the first embodiment of the temperature measuring sprinkler 8 in the present invention. It can be seen from the figure that it has a straight hole 80, a temperature measuring element 823 is embedded in the lower part, and a conductor or a wire with an insulator is passed through. 821 leads the measurement signal, and the temperature measuring sprinkler 8 has a protruding mounting member 85 integrally formed thereon, and a thread 89 is provided under the mounting member 85, and a sealing ring 963 is installed under the thread 89.
  • FIG. 165 is a cross-sectional view of the second embodiment of the temperature measuring sprinkler 8 according to the present invention. It can be seen from the figure that it has a straight hole 80, and an empty slot 840 is located in the lower part of the temperature measuring element 824.
  • the measuring signal is led out by a conductor or / wire 821 with an insulator.
  • the temperature measuring water sprayer 8 has a protruding connecting piece 85, and a sealing ring 963, a sealing ring 963 are installed under the mounting piece 85. There is a section of thread 89.
  • 166 is a cross-sectional view of the first embodiment of the water sprayer 81 in the present invention. It can be seen from the figure that it has a straight hole 80, and the water sprayer 81 has a protruding connecting member 85, a mounting member. A seal ring 963 is installed under 85, and a thread 89 is provided under the seal ring 963.
  • FIG. 167 is a cross-sectional view of the first embodiment of the thermometer 82 in the present invention.
  • the lower part is embedded with a temperature measuring element 822, and a measurement signal is drawn out through a conductor or / wire 821 with an insulator.
  • the middle part of 82 has a protruding integral mounting member 85.
  • a sealing ring 963 is installed under the mounting member 85, and a thread 89 is provided under the sealing ring 963.
  • FIG. 168 is a principle block diagram of Embodiment 1 of an internal combustion type runner (or swivel) engine connected to auxiliary equipment according to the present invention.
  • the thick solid line and the arrow in the figure represent pipes and fuel, neutral water or / acid water or / alkali
  • the direction of the flowing water the thin line indicates the connecting conductor or / connecting wire with insulators
  • the double thin line indicates the power output shaft 11 and the generator VI-1, the mechanical drive shaft of the starting motor ⁇ -1;
  • the frame and the frame I Represents an internal combustion runner (or swivel) engine
  • ⁇ -1 is an electric fuel pump
  • ⁇ -2 is a motor
  • ⁇ -3 is a control regulator
  • ⁇ - 4 is a fuel container
  • ⁇ -5 is a filter
  • ⁇ -6 is a one-way pressure valve
  • IV-1 is an electric water pump
  • IV-2 is a motor
  • IV-3 is a temperature control regulator
  • IV-4 is a water container
  • the generator VI-1 and the starter motor VH-1 may be combined into a starter generator.
  • at least one outboard combustion chamber may be provided outside the internal combustion runner (or swivel) engine I and connected to the internal combustion runner (or swivel) engine I to become an internal and external combustion runner (Or swivel) engine.
  • the fuel pump ⁇ -1 or / water pump IV-1 may be directly mechanically driven by the power output shaft 11 or / connected to the internal combustion runner (or swivel) engine I as a whole or / fixedly connected or / fixed Installation.
  • the generator VI-1 and the starter motor VH-1 may be integrally connected with the internal combustion runner (or swivel) engine I or / fixedly connected or / fixedly installed.
  • an external air supply device may be added.
  • a cooling device may be added.
  • FIG. 169 is a principle block diagram of the second embodiment of the internal combustion type runner (or swivel) engine connected to auxiliary equipment according to the present invention.
  • the thick solid lines and arrows in the figure represent pipes and fuel, air, neutral water or / acid water or / Alkaline water and cooling fluid flow direction, thin lines indicate connecting conductors or / connecting wires with insulators, double thin lines indicate power output shaft 11 and generator VI-1, cooling fluid pump V-1, fan V-3
  • the mechanical transmission shaft; I and I in the box represent internal combustion runner (or swivel) engines, ⁇ -1 is an electric fuel pump, ⁇ -2 is a motor, ⁇ -3 is a control regulator, and ⁇ -4 is a fuel Container, ⁇ -5 is the filter, ⁇ -
  • V-1 is a cooling flow Body mechanical pump
  • V-2 is radiator
  • V-3 is fan
  • VI-1 generator
  • VI-2 rectifier regulator
  • VI-3 power distribution controller
  • VI-4 is battery
  • internal combustion type A runner (or swivel) engine I is equipped with a burner 7 and a temperature measuring water jet 8, a power output shaft 11 of the internal combustion runner (or swivel) engine I and a cooling fluid mechanical pump V-1, and a fan V- 3.
  • the mechanical transmission shaft of generator VI-1 has a mechanical transmission relationship.
  • at least one external combustion chamber may be provided outside the internal combustion runner (or swivel) engine I and connected to the internal combustion runner (or swivel) engine I to become an internal and external combustion runner (Or swivel) engine.
  • the fuel pump ⁇ -1 and the water pump IV-1 may be directly mechanically driven by the power output shaft 11 or / connected with the internal combustion runner (or swivel) engine I as a whole or / fixedly connected // fixedly installed Assume.
  • the cooling fluid pump V-1 and the generator VI-1 may be connected with the internal combustion runner (or swivel) engine I as a whole or / fixedly connected or / fixedly installed.
  • the generator VI-1 can be made as a starter generator, and can start the internal combustion runner (or swivel) engine I through the power output shaft 11 or / directly.
  • the fuel can be supplied in both electric and mechanical ways.
  • FIG. 170 is a principle block diagram of Embodiment 3 of an internal combustion type runner (or swivel) engine connected to auxiliary equipment according to the present invention.
  • the thick solid line and the arrow in the figure indicate pipelines and natural materials, air, neutral water, or / acid water.
  • the thin line represents the connecting conductor or / connecting wire with insulators
  • the double thin line represents the power output shaft U and the generator VI-1
  • the frame and I in the box represents an internal combustion runner (or swivel) engine
  • ⁇ -1 is a fuel electric pump
  • ⁇ -2 is a motor
  • ⁇ -3 is a control regulator
  • ⁇ -4 is a fuel container
  • ⁇ -5 is a filter.
  • ⁇ -6 is a one-way pressure valve
  • ⁇ -7 is a fuel mechanical pump
  • ⁇ -8 is a fuel regulator
  • ⁇ -9 is a one-way pressure valve
  • m-i is an electric air pump
  • m-2 is a motor.
  • m-3 is a one-way pressure valve
  • IV-1 is a water electric pump
  • IV-2 is a motor
  • IV-3 is a thermostat
  • IV-4 is a water container
  • IV-5 is a filter
  • IV-6 is a one-way pressure valve
  • VI-1 is a generator
  • VI-2 is a rectifier Voltage regulator
  • VI-3 is power distribution controller
  • VI-4 is battery
  • internal combustion rotor (or swivel) engine I A burner 7 and a temperature measuring injector 8 are installed on the power output shaft 11 of the internal combustion runner (or swivel) engine I, and the mechanical drive shaft of the fuel mechanical pump ⁇ -7 and the generator VI-1 has a mechanical transmission relationship. .
  • At least one outboard combustion chamber may be provided outside the internal combustion runner (or swivel) engine I and connected to the internal combustion runner (or swivel) engine I to become an internal and external combustion runner (Or swivel) engine.
  • the fuel mechanical pump ⁇ -7 or / generator VI-1 may be integrated with the internal combustion type runner (or swivel) engine I or / fixedly connected or / fixedly installed.
  • the generator VI-1 can be made into a starter generator and can directly start the internal combustion runner (or swivel) engine I through the power output shaft 11 or /.
  • a cooling device may be added.
  • FIG. 171 is a principle block diagram of the first embodiment of the connection between the external combustion type (or swivel) engine and auxiliary equipment in the present invention.
  • the thick solid lines and arrows in the figure represent pipes and fuel, air, heat gas, neutral water, or / The direction of flow of acidic water or alkaline water and cooling fluid.
  • Thin lines indicate connecting conductors or wires with insulators.
  • Thin lines indicate power output shaft 11 and generator VI-1.
  • Fuel mechanical pump H-7 Cooling fluid.
  • the mechanical drive shaft of the pump V-1 and the fan V-3; the frame and I in the frame represent the external combustion rotor (or swivel) engine, ⁇
  • -1 is a fuel electric pump
  • ⁇ -2 is a motor
  • ⁇ -3 is a control regulator
  • ⁇ -4 is a fuel container
  • ⁇ -5 is a filter
  • ⁇ -6 is a one-way pressure valve
  • ⁇ -7 is a fuel machine.
  • Pump, ⁇ -8 is a fuel regulator
  • ⁇ -9 is a one-way pressure valve
  • m-1 is an air pump
  • ffl-2 is a motor
  • ⁇ 1-3 is a one-way pressure valve
  • IV-1 is an electric water pump
  • IV- 2 is the motor
  • V-1 is a cooling fluid mechanical pump
  • V-2 is a radiator
  • V-3 It is a fan
  • VI-1 is a generator
  • VI-2 is a rectifier regulator
  • VI-3 is a power distribution controller
  • VI-4 is a battery, and it is an external combustion chamber, an external combustion runner (or a swivel) )
  • a temperature measuring water jet 8 is fixedly installed on the engine I, and the power output shaft 11 and fuel of the runner (or swivel) of the engine I are fixedly installed.
  • Mechanical pump ⁇ -7, cooling fluid mechanical pump V-1, fan V-2, generator VI-1 mechanical transmission shaft has a mechanical transmission relationship.
  • a burner is fixedly installed on the external combustion runner (or swivel) engine I, and a corresponding fuel supply device is provided to become an internal and external combustion runner (or swivel) engine.
  • the electric fuel pump ⁇ -1 and the electric water pump IV-1 may be directly mechanically driven by the power output shaft 11 or / connected with the external combustion runner (or swivel) engine I as a whole or / fixedly connected or / Fixed installation.
  • the fuel mechanical pump ⁇ -7 or the / generator VI-1 may be connected to the internal combustion runner (or swivel) engine I as a whole or / fixedly connected or / fixedly installed.
  • the generator VI-1 can be made as a starter generator, and can directly start the external combustion rotor (or swivel) engine I through the power output shaft 11 or / and directly.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Structures Of Non-Positive Displacement Pumps (AREA)
PCT/CN2001/001560 2000-11-23 2001-11-15 Moteur a rotor et pompe a rotor WO2002041682A2 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU2002221487A AU2002221487A1 (en) 2000-11-23 2001-11-15 Rotor motor and rotor pump

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN00128027A CN1355375A (zh) 2000-11-23 2000-11-23 转轮(或转体)发动机和转轮(或转体)泵

Publications (1)

Publication Number Publication Date
WO2002041682A2 true WO2002041682A2 (fr) 2002-05-30

Family

ID=4592909

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2001/001560 WO2002041682A2 (fr) 2000-11-23 2001-11-15 Moteur a rotor et pompe a rotor

Country Status (3)

Country Link
CN (1) CN1355375A (fr)
AU (1) AU2002221487A1 (fr)
WO (1) WO2002041682A2 (fr)

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CN115307391A (zh) * 2022-07-25 2022-11-08 湖北烁砺新材料科技有限公司 一种耐火纤维厚板烘干装置
CN116174213A (zh) * 2023-04-21 2023-05-30 山东翁派斯环保科技有限公司 一种弯管喷涂装置

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CN106337733B (zh) * 2016-11-02 2017-09-15 狄庆会 一种旋转发动机及其连续燃烧做功方法
CN106438386A (zh) * 2016-11-09 2017-02-22 四川农业大学 一种离心式农田自动排水装置
CN107725183B (zh) * 2017-11-14 2019-12-27 杨弟强 一种矢量发动机
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CN212479407U (zh) * 2020-06-26 2021-02-05 吴邦宝 外燃输入式注气发动机
CN112709631A (zh) * 2020-12-29 2021-04-27 杨孝海 一种转子发动机
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CN114564817A (zh) * 2022-01-20 2022-05-31 南京航空航天大学 一种扇环形入口转矩形出口隔离段设计方法
CN114564817B (zh) * 2022-01-20 2024-06-07 南京航空航天大学 一种扇环形入口转矩形出口隔离段设计方法
CN115307391A (zh) * 2022-07-25 2022-11-08 湖北烁砺新材料科技有限公司 一种耐火纤维厚板烘干装置
CN115307391B (zh) * 2022-07-25 2023-03-21 湖北烁砺新材料科技有限公司 一种耐火纤维厚板烘干装置
CN116174213A (zh) * 2023-04-21 2023-05-30 山东翁派斯环保科技有限公司 一种弯管喷涂装置

Also Published As

Publication number Publication date
AU2002221487A1 (en) 2002-06-03
CN1355375A (zh) 2002-06-26

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