Abstract: A rotary compressor arrangement is disclosed that includes a body centered at a shaft axis, a cylindrical piston arranged with respect to the body such that an inner volume is created between them, and guiding means arranged at an offset axis with respect to the shaft axis. Also disclosed is a cooling/refrigerant system that includes the rotary compressor arrangement.

Abstract: The electric machine comprises a cylindrical rotor with axial first air channels and a stator with axial second air channels. The outer surface of the stator is provided with cooling fins. There is a first air chamber at a first end of the rotor, a second air chamber and an adjacent third air chamber at a second end of the rotor. A first fan circulates internal air from the first axial air channels to the second air channels in a closed air circulation within the electric machine. A second fan blows external cooling air from the outside of the electric machine through the third air chamber and from the outlet opening of the third air chamber along the outer surface of the stator. The number of second air channels in the stator is three.

Abstract: An inlet guide vane assembly (60) is provided including a plurality of vane subassemblies (62) configured to rotate relative to a blade ring housing (64) to control a volume of air flowing there through. The inlet guide vane assembly (60) also includes a plurality of drive mechanisms (80). Each drive mechanism (80) is operably coupled to one of the plurality of vane subassemblies (62). The vane subassemblies (62) may be rotated independently.

Abstract: A rotary machine (1) in the form of an expander is shown. The Expander Induces a housing (5) having a cavity (9), inlet and outlet ducts (11, 12) communicating with the cavity (9), a rotor (2) having a rotor axis (A), a number of vanes (15a, 15b, 15c) movably received in respective grooves (18) in the rotor (2) and articulately connected about an axis (C) to one end of a control arm (14a, 14b, 14c) and in the other end rotatable supported in a fixed shaft (24) extending centrally through the cavity (9) in the housing (5), and at least one working chamber (9a) which is part of the cavity (9), The housing (5) includes an internally cylindrical intermediate part (5c), which part interact with the rotor (2) and the vanes (15a, 15b, 15c). The rotor (2) forms a reel configuration having respective radially extending flange portions (2a?, 2b?) which are rotatable together with the vanes, and against which the respective end surfaces of the vanes act.

Abstract: A metering pump with a special-shaped cavity comprising a housing, a rotor and two cover plates. The housing is a cylinder with a special-shaped surface inner cavity formed by combining two circular arc surfaces with two non-circular arc surfaces and a planar surface, an inlet and an outlet. The rotor comprises a rotor body and two pairs of combined sliding plates. The housing is matched with the cover plates for constituting a sealed cavity. When the rotor rotates, the non-circular arc surface of the special-shaped surface inner cavity can enable the two pairs of the combined sliding plates to slide in a cross manner so as to suck in fluid from the inlet and press out the fluid from the outlet. When the rotor rotates one cycle, four standard volumes are formed in a cavity body and the equal quantity of the fluid flows by the cavity body.

Abstract: A rotary engine is described including: (1) a rotor located within a housing, the rotor configured with a plurality of rotor vane slots; (2) a vane separating an interior space between the rotor and the housing into at least a trailing chamber and a leading chamber, where the vane slidingly engages a rotor vane slot; (3) a first passage through the vane, the first passage including a first exit port into the rotationally trailing chamber; and (4) a second exit port to the rotationally trailing chamber, where the first exit port and the second exit port connect to any of: (a) the first passage through the vane and (b) the first passage and a second passage through the vane, respectively. Optionally, one or more seals affixed to the vane and/or the rotor valve the first passage, the second passage, a vane wingtip, and/or a conduit through the rotor.

Abstract: A positive displacement rotary system may include a main rotor and a slotted rotor. The main rotor can include an interior cavity and a fixed vane (or blade) that is attached to the peripheral and side walls of that cavity. The slotted rotor is positioned within the main rotor interior and includes a slot for the main rotor blade. The main and slotted rotors rotate about parallel axes that are offset from one another. As the rotors turn, separate chambers are formed between the blade and an inter-rotor seal, with the inter-rotor seal located at or near a rolling contact between the outer surface of the slotted rotor and an inner perimeter wall of the main rotor cavity. The separate chambers contract and expand as the rotors rotate.

Abstract: PROBLEM TO BE SOLVED: To provide an axial piston hydraulic rotating machine having high stability of a piston shoe. SOLUTION: A circular internal static pressure pocket 23 communicated with a filler opening 9A, an inner peripheral land portion 22 formed on the outer periphery of the internal static pressure pocket 23, an external static pressure pocket 24 formed on the outer periphery of the inner peripheral land portion 22, and an outer peripheral land portion 25 formed on the outer periphery of the external static pressure pocket 24 are formed on the sliding surface in contact a piston shoe 9 with the swash palate 10. The inner peripheral land portion 22 is annularly formed around the filler opening 9A. Oil passing grooves 27 through which the internal static pressure pocket 23 communicates with the external static pressure pocket 24 are formed in parts of the inner peripheral land portion 22 on straight lines, passing through the center of the filler opening 9A.

Abstract: A compressor includes a screw rotor and a gate rotor. The screw rotor has a plurality of spirally extending groove portions disposed radially outwardly from the center axis of the screw rotor. The gate rotor has a plurality of tooth portions circumferentially arranged on an outer circumference to engage the groove portions. Preferably, an inclination angle of a groove portion side face contacting the tooth portions is inclined relative to a circumferential direction of the gate rotor varies. Alternatively a first plane contains the screw rotor center axis, a second plane orthogonally intersects the screw rotor center axis, a third plane orthogonally intersects the first and second planes, the gate rotor center axis is on the third plane, and the tooth portions do not overlap the first plane as viewed orthogonally relative to the third plane.

Abstract: A thermoformable acoustic sheet formed by a compressed fibrous web including high melt and adhesive thermoplastic fibres in which the adhesive fibres are at least partially melted so that in the compressed web the adhesive fibres at least partially coat the high melt fibres and reduce the interstitial space in the fibre matrix. Also included is a method of producing a thermoformable acoustic sheet which includes the steps of heating a fibre web including high melt and adhesive thermoplastic fibres to at least partially melt the adhesive fibres and compressing the web to form a sheet so that the adhesive fibres at least partially coat the high melt fibres to reduce the interstitial space in the fibre matrix.

Abstract: A motor for converting fluid pressure to rotational motivation and pump for moving fluid, comprising a first drum provided within a second drum. The first drum is provided with a pair of vanes, each provided with a generally heart-shaped slot around a drum shaft. The orientation of the drum shaft and shape of the slots cause the vanes to extend and retract relative to the inner drum as fluid pressure or mechanical motion rotate the inner drum relative to the outer drum.

Abstract: This invention relates to expansible chamber positive displacement pumps, motors, and engines and includes variable displacement features. It provides a different method of making vane, piston, and roller abutment pumping devices which has benefits in sealing, dynamic and pressure balancing, and increased rotational speeds; resulting in better performance and higher efficiency. Since this is a technology that is parallel to existing technologies, this application is complex.

Abstract: The invention refers to a hydrostatic pump or engine with infinitely variable debit or impulse of the rotative type, constituted by an external and fixed body (1) of cylindrical shape, and whose symmetry axis coincides with the axis (4) of the rotor (3); the named body is laterally fixed to two flat covers forming a case. A second body, or stator (2), with a cylindrical interior peripherical surface, and whose symmetry axis is in a coincident or parallel position with the rotor axis, is interposed at intervals between the rotor and the first body, being formed cameras (7) and (9), for the fluid circulation, and cameras (6) and (8), for the compensation and balance of forces acting in the interior and in the exterior of each stator side.

Abstract: A rotary-piston machine (10) comprising a housing (5) having a cavity (9), a rotor (2) received in the housing (5), which rotor (2) having a rotor axis (A) and a peripheral surface (21), inlet and outlet passages (3, 4) in communication with said cavity (9), one or more vanes (1) radially slideable received in slots (11) in the rotor (2), each vane (1) extending radially from the internal surface (20) of the housing (5) to the rotor axis (A), and at least one working chamber (9a) being part of the cavity (9) and is defined by the internal surface (20) of the housing (5), the peripheral surface (21) of the rotor (2) and the side surface of at least one vane (1).

Abstract: A rotor 1 forming screw teeth is projectingly provided at its outer end 2 on the axis thereof with a center shaft 3. The center shaft 3 is provided at its outer end 4 with a smaller-diameter shaft 5 or a concaved fitting hole. A separate rotor shaft 6 which is to be fitted over the smaller-diameter shaft 5 or fitted into the concaved fitting hole is provided with another concaved fitting hole 7 or smaller-diameter shaft. A metal shaft around which synthetic resin is molded is formed at its peripheral surface with a spiral groove or corrugated groove in the opposite revolutional direction with respect to the revolutional direction of the screw rotor. The spiral groove is formed with smooth arc curved line connecting profiles of adjacent grooves. The shaft is provided with a step, and synthetic resin is molded around the shaft surface to form a screw rotor.

Abstract: A rotor 1 forming screw teeth is projectingly provided at its outer end 2 on the axis thereof with a center shaft 3. The center shaft 3 is provided at its outer end 4 with a smaller-diameter shaft 5 or a concaved fitting hole. A separate rotor shaft 6 which is to be fitted over the smaller-diameter shaft 5 or fitted into the concaved fitting hole is provided with another concaved fitting hole 7 or smaller-diameter shaft. A metal shaft around which synthetic resin is molded is formed at its peripheral surface with a spiral groove or corrugated groove in the opposite revolutional direction with respect to the revolutional direction of the screw rotor. The spiral groove is formed with smooth arc curved line connecting profiles of adjacent grooves. The shaft is provided with a step, and synthetic resin is molded around the shaft surface to form a screw rotor.

Abstract: A multi-chamber rotary piston internal combustion engine includes an engine housing having interior walls defining a plurality of internal cylindrical cavities, at least one of the cavities being disposed in a first housing level and at least one other of the cavities being disposed in a second housing level spaced apart but adjacent to the first housing level. A plurality of rotary pistons and cylinders are movably mounted relative to the cavities which, in operation, cooperatively define, at least partially with the housing interior walls, a multiplicity of sequentially-arranged chambers including a gas intake chamber, and at least one gas compression chamber located in the first housing level and an ignition chamber, gas expansion chamber and a gas expulsion chamber located in the second housing level, with the cylinders, pistons and cavities being operatively arranged so that gas intake, compression, ignition, expansion and gas expulsion take place simultaneously during one revolution.

Abstract: An axial vane rotary device (14) includes a stator (16) with a cylindrical internal chamber (34) defined an annular outer wall (40) and two side walls (36, 38) of the stator. Each side wall has an annular cam surface (42, 44). A rotor (54) is rotatably mounted within the chamber. The rotor has an annular outer wall (66) and a plurality of angularly spaced-apart, axially extending slots (64) extending therethrough. A vane (68) is slidably received in each slot. The vanes reciprocate axially and alternatively expand and compress spaces between adjacent vanes and the cam surfaces as the rotor rotates. The cam surfaces have alternating first portions (92) and second portions (90). The second portions are further from the rotor than the second portions. The first portions of one said cam surface are aligned with second portions of another said cam surface. The slots extend radially outwards on the rotor to the annular outer wall thereof.

Abstract: An axial vane rotary device (14) includes a stator (16) with a cylindrical internal chamber (34) defined an annular outer wall (40) and two side walls (36, 38) of the stator. Each side wall has an annular cam surface (42, 44). A rotor (54) is rotatably mounted within the chamber. The rotor has an annular outer wall (66) and a plurality of angularly spaced-apart, axially extending slots (64) extending therethrough. A vane (68) is slidably received in each slot. The vanes reciprocate axially and alternatively expand and compress spaces between adjacent vanes and the cam sur-faces as the rotor rotates. The cam surfaces have alternating first portions (92) and second portions (90). The second portions are further from the rotor than the second portions. The first portions of one said cam surface are aligned with second portions of another said cam surface. The slots extend radially outwards on the rotor to the annular outer wall thereof.

Abstract: A pinned vane type, positive displacement, rotary device includes a tangentially translatable roller arrangement for sealing each of a plurality of rotatable blades that are pivotally attached to an inner hub and extend through blade spreader elements of an outer hub assembly to contact the interior surface of the device. Each of roller elements on either side of a respective blade is allowed to rotate about its own axis, while the unloaded one of the roller elements is allowed to translate tangentially relative to a circular path described by the outer hub assembly. The sealing arrangement accommodates pivoting of the blade about an axis that passes through the blade in the radial direction from the inner hub to the interior surface of the housing, so that the contact surface between each roller element and its associated blade has no gaps across the surface of the blade between outer hub assemblies.

Abstract: An axial vane rotary device (14) includes a stator (16)with a cylindrical internal chamber (34) defined an annular outer wall (40) and two side walls (36, 38) of the stator. Each side wall has an annular cam surface (42, 44). A rotor (54) is rotatably mounted within the chamber. The rotor has an annular outer wall (66) and a plurality of angularly spaced-apart, axially extending slots (64) extending therethrough. A vane (68) is slidably received in each slot. The vanes reciprocate axially and alternatively expand and compress spaces between adjacent vanes and the cam surfaces as the rotor rotates. The cam surfaces have alternating first portions (92) and second portions (90). The second portions are further from the rotor than the second portions. The first portions of one said cam surface are aligned with second portions of another said cam surface. The slots extend radially outwards on the rotor to the annular outer wall thereof.

Abstract: A positive displacement fluid handling apparatus comprises a hollow circular cylindrical vane guide with a plurality of slotted axial openings included in the cylindrical wall thereof and a plurality of vanes, wherein the hollow circular cylindrical vane guide is disposed rotatably within a circular cylindrical cavity included in the body of the apparatus in an eccentric and tangential relationship to the cylindrical wall of the cylindrical cavity and the plurality of vanes are disposed rotatably about the central axis of the circular cylindrical cavity and respectively engage and extend through the plurality of slotted axial openings included in the hollow circular cylindrical vane guide in such a way that the radial edges of the vanes slide on the circular cylindrical wall of the cylindrical cavity and, consequently, the motion of fluid moving from the inlet to the outlet of the apparatus through a crescent-shaped flow passage between the cylindrical wall of the cylindrical cavity and the hollow circular cy

Abstract: A compressor having a cylinder and a cylindrical rotational body housed within the cylinder. A spiral groove is formed in the outer peripheral surface of the rotational body, and a spiral blade is fitted in the groove so as to be freely retreated in and projected from the groove in the radial direction of the rotational body. The cylinder and the rotational body are rotated relative to each other by a drive mechanism. A fluid to be compressed is introduced into working chambers defined by the blade, the inner peripheral surface of the cylinder and the outer peripheral surface of the rotational body. The fluid is first guided into the first working chamber from a gas suction port, and then into the second and subsequent working chambers successively, whereby the fluid is compressed. An oil supply mechanism supplies pressurized oil to an oil supply hole formed in the rotational body.

Abstract: A seal assembly slidably mounted in a slot in the piston engages the cylindrical internal wall of the housing to form separate chambers. The housing has arcuate slots non-concentric with its cylindrical internal wall accommodating rollers connected to the seal assembly to maintain the seal assembly in constant and substantially uniform sealing engagement with the internal wall of the housing.

Abstract: A multiple or compound work cycle, eccentric rotor, fluid power translation device, featuring adjustable and reversible work output capability, essentially comprising: A symmetric rotor having a plurality of fixed radially extended vanes rotating closely between opposing co-axially adjustable confinement plates. An internal, eccentrically disposed annulus comprised of segmented concentric rings having co-axially protruding edges; said edges engaging circular, matching bearing grooves provided by said opposed confinement plates. The segments comprising each segmented ring being each penetrated by a rotor vane; two or more segments per vane thereby compelling co-rotation of said segments and locating said segments relative segments penetrated by adjacent rotor vanes.

Abstract: An air pump and compressor having a housing with a cylindrical internal chamber. A plurality of pairs of intake and exhaust valves mounted on the housing control the flow of air into and out of the chamber. A piston located within the chamber is mounted on a shaft rotated on the housing. The shaft has a primary eccentric that supports the piston in the chamber. A pair of secondary eccentrics spaced from the primary eccentric are mounted on the piston and housing to control the orbital movement of the piston. Seal assemblies slidably mounted in slots in the piston engage the inner cylindrical wall of the housing to form separate pumping chambers. Each pumping chamber is in communication with an intake valve and an exhaust valve so that on orbital movement of the piston the air flows into and is pumped out of each pumping chamber.

Abstract: A vane air pump has a vane holder which includes a main body. A vane extends outward from one side of the main body and a balance weight extends outward from the other side of the main body in a direction opposite to the vane. The balance weight is cast integrally with the main body. The method discloses integrally forming a balance weight with the main body of the vane holder.

Abstract: A sealing for a rotary impeller blade partially extending outwardly from a rotor of an impeller pump includes two sealing strips of plastics, the ends of which abut against the opposing side faces of the blade in the region of a slot found in the rotor, and two respective supporting members of metal. Each supporting member secured to the assigned sealing strips reliably supports the sealing strip whereby the sealing strips resist to vibrations occurring at high speeds of the pump during operation.

Abstract: In a vane-type compressor, the slotted rotor includes resilient slot sealing means in the form of leaf springs. Each spring extends between consecutive slots and has curved end portions projecting into the slots and sealingly engaging opposite sides of corresponding vanes.

Abstract: A vane type pump having a rotor with slots through which vanes extend and engage the inside of a cylindrical casing to pump upon rotation of the rotor. The slots have a longitudinal groove on each inner side facing each other and elongated carbon sealing elements are positioned in the grooves to sealably engage the vane extending therebetween. A leaf spring is positioned behind one sealing element in compression and its amplitude of movement, as a result of the dimensions of all the components, is limited to 0.6 mm or less.

Abstract: A vane type air pump having vanes with an edge that slidably engages the inside of a cylindrical casing and sides that slidably engage carbon sealing elements. The vanes are constructed of pre-impregnated glass cloth with the warp and weft positioned at acute angles to the sealing element to provide less and smoother wear on the sealing element and inhibit air leakage. A heavy density weave of glass cloth also reduces the wear.

Abstract: In a vane type compressor, in which a plurality of radial vanes are supported on a compressor shaft and extended through a rotary piston, each vane is formed of two wall portions spaced from each other and two ring portions receiving bearings for supporting the vanes on the shaft. The wall portions and the ring portions of each vane are formed as a one-piece element which may be produced by stamping-out and bending a sheet metal. A supporting structure of kernels of aluminum disposed in a honeycomb manner is inserted between two wall portions of each vane.

Abstract: In a vane type compressor including a plurality of radial vanes extending from a compressor shaft through the slots in a rotary piston elastic flexible tubes are inserted in the slots and interconnected between the respective vanes and the rotary piston, which serve as sealing members on the vanes. Each flexible tube has an elongated bead engaged in a groove formed either in the vane or in the rotary piston.

Abstract: An arrangement which seals three movable bodies with respect to one another, for example in a component used in a motor vehicle, is provided with first sealing bodies which are imbedded in a first rotating body. Sealingly secured in these first sealing bodies are sealing members which follow the circumference of the first rotating body as well as a respective sealing member extending in the axial direction of the rotating body. The sealing members are in sliding sealing engagement with sealing surfaces of angular sealing strips, such sealing surfaces extending normal to the direction of the sealing members which follow the circumference of the rotating body. The angular sealing strips are secured at the opposing ends of a reciprocable second body which radially traverses the rotating body. Preferably, these angular sealing strips are interconnected with the aid of a respective further sealing body positioned on the axial end surfaces of the second body.

Abstract: In a vane pump a hollow cylindrical rotor (7) is mounted for rotation about its axis within a housing (1) and is arranged to be driven by a belt driven pulley (54) mounted on one end (19) of the rotor. Extending eccentrically within the rotor (7) is a shaft (11) which has its opposite ends (10) and (24) fixed in passages (9) and (23) respectively in the end portions (5) and (15) of the housing (1) so that the shaft (11) is not rotatable. The vanes (27) of the pump are rotatably mounted on the shaft (11) so that they extend axially of the shaft and project radially through axially extending openings in the cylindrical wall of the rotor (7). The vanes (27) are thereby rotated on the shaft (11) when the rotor is driven, and the portions of the vanes projecting through the cylindrical wall of the rotor sweep a pump chamber (13) surrounding a portion of the rotor to convey fluid from an inlet to an outlet of the pump.

Abstract: In a method of regulating the delivery of the combustion fluid (i.e. air or mixture of air and fuel) to an internal combustion engine (1), the combustion fluid is conducted through a gas engine or positive displacement device capable of operating as a fluid motor or a fluid compressor (2) which is drivingly coupled with the internal combustion engine, and the flow rate through the device (2) is varied in the sense of the desired load change by means of a control device (3, 23) on the device. The positive displacement device (2) may be operated as a fluid motor and/or as a supercharger. As a fluid motor the work done by the expansion of the combustion gas is used to assist the engine (1), whereas the engine (1) drives the gas engine (2) when operating as a supercharger. In a preferred embodiment the device (2) is of the rotary vane type (FIG.

Abstract: A vane pump having a cylindrical drum which revolves in a fixed housing part about an axis extending eccentrically to the housing part. The cylindrical drum drives at least one vane which is rotatably supported in the center of the fixed housing part so that the vane passes through an opening in the wall of the cylindrical drum to the inner surface of the housing part. Spring parts are disposed as sealing elements in the vicinity of the opening and are secured on each side of the vane on the cylindrical drum. At a distance from the fastening location, lip sections bent outward in convex fashion toward the vane so that the spring parts press against the respective associated outer faces of the vane for forming a seal, and also for centering the vane inside the opening when the pump is shut off.

Abstract: A vane-piston pump having a rotor supported eccentrically in a pump housing. The rotor is provided with slits for the passage through it of the vanes, and sealing strips are disposed at either side of the slits. The vanes slide along these sealing strips. Each sealing strip is subjected to the force of its own spring, and under the force of this spring, each sealing strip is pressed against the vanes.In this manner the spring forces can be kept smaller, so that friction is reduced. The vane-piston pump is preferably used in motor vehicles for generating compressed air in order to operate exhaust-gas treatment apparatus.

Abstract: A vane type pump having a housing formed with an inlet chamber and an outlet chamber and having a cylinder portion, a cylindrical rotor mounted for eccentric rotation in the cylinder portion, and a plurality of vane mounted for concentric rotation in the cylinder portion. The rotor is formed with slots through which the vanes extend into a space defined between the inner peripheral wall of the cylinder portion and the outer peripheral wall of the rotor so as to divide the space to define a working chamber variable in volume for pumping effect. The inlet chamber is associated with the cylinder portion to define a fluid confinement initiating line at which the working chamber begins to be isolated from the inlet chamber when the forward end of one of the vanes passes the line.

Abstract: An orbital pump comprises a pump housing having first and second end walls and an intermediate annular, inwardly projecting wide wall member. First and second axial drive shaft portions are installed through corresponding housing end walls. A rotor, excentrically rotatably mounted to inner ends of the drive shaft portions, is installed in the housing with first and second rotor end flanges adjacent to the corresponding sides of the annular wall member so that the pump end walls, annular wall member and rotor end flanges divide the housing into an inlet plenum, a generally square compression chamber and an outlet plenum. A pair of orthogonally intersecting vanes mounted through the rotor divide the compression chamber into four pumping sub-chambers, ends of each vane being orthogonal to opposite sides of the compression chamber, and in tangential sliding contact therewith.

Abstract: A rotary vane machine utilizing tapered vanes which are rotatably connected to a stationary center shaft and which extend through openings in the wall of an off-center hollow cylindrical rotor into sliding contact with an inner wall of the machine. Working chambers are formed between the vanes outside of the hollow rotor. Roller seals are provided in the rotor wall openings to isolate the inside of the rotor from the working chambers. Rollers which form the seals are disposed, with a close tolerance, in slots formed in the rotor wall openings on each side of the tapered vanes. A small opening, which communicates with one of the working chambers, is formed in the back of each roller slot to admit pressurized fluid from the working chamber to help bias the roller seals into contact with the tapered vanes. A check valve may be provided in the small opening to maintain pressure behind the roller seal.

Abstract: A sealing arrangement in a rotary machine between the eccentric rotary piston and the separating slide engaging a recess in the piston. A spring-loaded strip is guided in a lengthwise slot of the rotary piston, and is in contact with each side wall of the separating slide throughout the entire length. The vertex formed by an obtuse angle of the front sides of the strip in the region of the center line of the strip, is in sliding-motion connection with the side wall of the separating slide. The center line of the strip forms an angle of substantially 55.degree. with the center line of the separating slide, at dead center. Compression springs associated with the rear side of the strip are held in blind holes which are spaced by a predetermined distance. The recess of the rotary piston which accommodates the separating slide, has a trapezoidal cross-section.

Abstract: A pump is comprised of a housing within which a rotary piston is rotatably mounted, to define therebetween an annular conveying channel between an inlet port and an outlet port. Annular sealing rings between the piston and housing seal the conveying channel at the periphery of the piston. A stopper extends into the conveying channel in the back flow path, and sealing elements are provided to seal the entire cross section of the back flow paths. Radially movable slides on the piston are resiliently urged into the conveying channel, the radial position thereof being controlled by a cam surface in the housing. The slides are urged radially outwardly by springs, and seals are provided on the piston for sealingly guiding the piston in the radial direction.

Abstract: Vane type rotary pumping device comprising a stationary housing member having a cavity extending therethrough, a rotor disposed in the cavity for rotation therein and having a plurality of radial openings therein, and vane members extending in each of the openings for sliding movement therein and rotary movement along with the rotor. An inlet passage and an outlet passage formed on spaced apart portions of the housing member communicate with the cavity. The cavity includes a circumferential channel extending from the inlet passage to the outlet passage to serve as a fluid pumping chamber. The vane members extend radially outwardly of the rotor and in pressure sealing relationship with the channel while being rotated through the channel by the rotor to pump fluid from the inlet passage to the outlet passage. The cavity also includes a circumferential wall portion between the outlet passage and the inlet passage over which the rotor passes with the vane members retracted within the rotor.

Abstract: A positive displacement rotary apparatus comprising a rotor having opposed faces on opposite sides thereof; a housing around the rotor and having opposed internal side walls facing the opposed faces of the rotor; and a plurality of circumferentially spaced vane means extending slidingly through the rotor in a direction substantially parallel to the rotational axis thereof and disposed radially outwardly from the axis of rotation of the rotor on substantially the same radius. An annular recess which periodically varies in depth and width over its length is formed in each of said internal side walls of the housing concentrically with respect to the axis of rotation of the rotor. The annular recesses slidingly receive opposite ends of the sliding vane means, and the bottoms of the recesses are equidistantly spaced from each other at all aligned points over the length of the recesses as measured along any one vane means having its opposite ends in the recesses.

Abstract: The disclosure herein describes a vane-type rotary internal combustion engine which includes two separate housings, a compressor housing and a motor housing; each housing includes an interior profile of a first order configuration with constant diametrical chord. A rotor is rotatably mounted in each housing and includes a series of arc-shaped segments disposed in circular alignment in the housing and equally spaced to define therebetween a series of elongated radial openings. The rotor of each housing includes also a system of partially unbalanced vanes slidably mounted in these openings and bearing at each extremity thereof against the interior profile of the related housing; each vane defines in the housing chambers of variable volume depending on the relative rotational position of each segment with respect to the housing profile. Both housings are similarly structured with the exception that the compressor housing includes two sections of constant radius.

Abstract: An annular ring is closed on each side by a side plate secured thereto thus forming a cylindrical chamber or casing. A rotor is mounted on a shaft which is supported axially by the side plates, the rotor being within the chamber. A plurality of pistons are mounted for pivotal action around the periphery of the rotor and are in sealing engagement with the side plates. These pistons have a transverse contact line engaging the inner surface of the annular ring. This inner surface is contoured so that a compression lobe and a power lobe are formed and as the rotor rotates, fuel and air is drawn in through an intake in the wall of the ring, is compressed by one of the pistons, and then firing takes place so that expansion occurs as the piston is passing through the power lobe with the residual gases being exhausted through the exhaust port. A complete cycle occurs through 360.degree.

Abstract: A vane type engine having a housing, a shaft journalled therein with a piston member mounted on the shaft and a plurality of vanes forming with the housing a piston member a plurality of chambers. A seal member supported in each opposite axial end face of the piston member and engaging the end walls of the housing, an insert supported in each vane and extending therethrough to engage at one end the seal member in the piston member and at the other end the base of the slot in which the vane is disposed, the fit between the insert and the vane extension being such as to prevent the passage of gas between the insert and the vane extension but to permit movement therebetween in the axial direction resulting from different expansion of the piston, vane and housing during operation.