WO2008054244A1 - Machine rotative à palette coulissante - Google Patents
Machine rotative à palette coulissante Download PDFInfo
- Publication number
- WO2008054244A1 WO2008054244A1 PCT/RU2007/000534 RU2007000534W WO2008054244A1 WO 2008054244 A1 WO2008054244 A1 WO 2008054244A1 RU 2007000534 W RU2007000534 W RU 2007000534W WO 2008054244 A1 WO2008054244 A1 WO 2008054244A1
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- WO
- WIPO (PCT)
- Prior art keywords
- rotor
- working
- housing
- insulating
- power
- Prior art date
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C15/00—Component parts, details or accessories of machines, pumps or pumping installations, not provided for in groups F04C2/00 - F04C14/00
- F04C15/0003—Sealing arrangements in rotary-piston machines or pumps
- F04C15/0023—Axial sealings for working fluid
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03C—POSITIVE-DISPLACEMENT ENGINES DRIVEN BY LIQUIDS
- F03C2/00—Rotary-piston engines
- F03C2/30—Rotary-piston engines having the characteristics covered by two or more of groups F03C2/02, F03C2/08, F03C2/22, F03C2/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
- F03C2/304—Rotary-piston engines having the characteristics covered by two or more of groups F03C2/02, F03C2/08, F03C2/22, F03C2/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having both the movements defined in sub-group F03C2/08 or F03C2/22 and relative reciprocation between members
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C2/00—Rotary-piston machines or pumps
- F04C2/30—Rotary-piston machines or pumps having the characteristics covered by two or more groups F04C2/02, F04C2/08, F04C2/22, F04C2/24 or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
- F04C2/34—Rotary-piston machines or pumps having the characteristics covered by two or more groups F04C2/02, F04C2/08, F04C2/22, F04C2/24 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 groups F04C2/08 or F04C2/22 and relative reciprocation between the co-operating members
- F04C2/344—Rotary-piston machines or pumps having the characteristics covered by two or more groups F04C2/02, F04C2/08, F04C2/22, F04C2/24 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 groups F04C2/08 or F04C2/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the inner member
- F04C2/3448—Rotary-piston machines or pumps having the characteristics covered by two or more groups F04C2/02, F04C2/08, F04C2/22, F04C2/24 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 groups F04C2/08 or F04C2/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the inner member with axially movable vanes
Definitions
- the invention relates to mechanical engineering and can be used in rotary vane pumps, hydraulic motors, hydrostatic differentials and transmissions with increased efficiency at high pressure.
- Known rotary vane machines containing two nodes mounted with the possibility of mutual rotation namely, the housing with input and output ports and the rotor with vane chambers in which the gates are located with the possibility of movement relative to the rotor: axial (patent US570584), radial (patent US894391 ) or rotary (patents US1096804 and US2341710), and the working chamber in them is limited by the end surfaces of the rotor and the housing.
- the inlet cavity hydraulically connected to the inlet port and the outlet cavity hydraulically connected to the outlet port are separated by two insulating jumpers of the housing.
- One of them is in sliding insulating contact with gates moving during the rotation of the rotor from the inlet to the outlet cavity, and is hereinafter called the direct transfer limiter.
- Another is called a backward transfer limiter.
- the known hydrostatic component EP0269474 which we adopted as the closest analogue, in which the deforming effect of the working fluid pressure on the surface of the sliding insulating contact between the working parts of both nodes is reduced. It consists of two nodes, namely, the housing and the rotor, mounted with the possibility of mutual rotation.
- the housing with inlet and outlet ports contains a working part of the housing, called by the authors as the “carrier track”, on which the forward transfer limiter and the reverse transfer limiter are made in the form of rim sections with a track between the input and output cavities.
- the rim with the track also acts as a guide cam for the gate drive.
- the rotor consists of two parts: the working part of the rotor, called by the authors “the holder of the plates”, on the working end surface of which an annular groove is made, which connects to the slide chambers, in which there are sliders installed with the possibility of changing the degree of extension in the annular groove, and the support part, called the “reference flange”.
- the authors envisioned a design in which slide chambers and an annular groove are also made in the supporting part. In this case, the supporting part of the rotor contacts the supporting part of the housing in the form of a second track carrier.
- the working part of the housing in contact with sliding with the working part of the rotor (plate holder), isolates the working chamber in the annular groove, which is divided by the backward transfer stop (the rim section most overlapping the ring groove) and the direct transfer stop (rim section, least overlapping annular groove), which is in sliding insulating contact with the gates, to the inlet cavity of the working chamber hydraulically connected to the inlet port and the outlet cavity of the working chamber hydraulically connected annuyu to the output port.
- the backward transfer stop the rim section most overlapping the ring groove
- the direct transfer stop rim section, least overlapping annular groove
- the authors envisage the execution of one of the nodes, rotor or housing, adaptive, that is, including power chambers of variable length, kinematically connecting the working and supporting parts of the adaptive node with the possibility of their mutual axial movements and tilts, at least sufficient to approximate the holder blades to the track carrier, i.e.
- each power chamber includes a power cavity hydraulically connected to the working chamber and means for its isolation, and changing the length of these power chambers leads to the indicated mutual movements of the working and supporting parts of the specified node, and the pressure forces of the working fluid in the power cavities are directed so as to push the power chambers and bring the working part of the housing and the working part of the gun closer ora each
- the rotor is made adaptive, i.e. includes power chambers of variable length kinematically connecting its working and supporting parts, i.e. plate holder with a supporting flange, with the possibility of their mutual axial movements.
- the cylindrical force cavities in communication with the working chamber are oval in cross-section and are made at the end of the plate holder on the back side of the annular groove.
- Insulation means are installed in them in the form of axial cylindrical piston elements, referred to by the authors as “sealing cups”, which abut against the support flange and, sealing the working chamber, press the end surface of the plate holder to the end surface of the track carrier.
- the authors indicate that the fluid pressure forces pushing the plate holder away from the track carrier are transmitted through power chambers to the static contact of the piston movable element with a deformable support flange, which eliminates the axial deformations mentioned end insulating surfaces of the plate holder.
- the clamping force of the working part of the rotor to the working part of the housing depends on the size of the power chambers and determines the level of friction losses between the indicated working parts.
- the aforementioned contact of the piston movable element with the supporting flange is not absolutely static, because the mismatch of the axes of rotation of the working and supporting parts causes the movement of the end surface of the movable element along the surface of the support flange.
- cavities are made that are hydraulically connected to the force cavities in the plate holder.
- good insulation is required simultaneously in two sliding insulating contacts of the surfaces of each movable element with both the inner cylindrical surface of the cavity of the power chamber and the flat surface of the support flange. For this, it is necessary to ensure with high accuracy the perpendicularity between the generatrix of the cylindrical insulating surface of the cavity of the power chamber and the flat insulating surface of the support flange at any pressure and at any angle of rotation of the rotor.
- the axis of rotation of the plate holder may deviate from the axis of rotation of the support flange by a certain angle. This angle determines the angular amplitude of the cyclic inclinations that the insulating surface of the support flange makes relative to the end surface of the movable element during rotation of the rotor assembly.
- the deformation of the support flange under the action of pressure forces of the working fluid significantly increases the indicated amplitude of the cyclic slopes and causes a curvature of its flat insulating surface.
- EP0269474 also describes the design of a hydrostatic component in which the housing is adaptive, not a rotor, i.e. power chambers of variable length with movable elements are placed in the housing unit between the working part of the housing, i.e. track carrier, and the supporting part of the housing. And in this design, the inclination of the supporting part of the housing relative to the working part of the housing, due to deformation and technological reasons, as well as the curvature of a flat insulating surface, will lead to an increase in leakage.
- the hydrostatic component described in EP0269474 requires high manufacturing accuracy, does not provide isolation of the power chambers and the working chamber during deformations, and does not allow at a high pressure to simultaneously achieve low leakage and low friction losses.
- the objective of the present invention is to provide isolation of the working chamber and power chambers of variable length in a wide range of deformations and technological tolerances and associated mutual inclined and transverse movements of the working and supporting parts of the adaptive node and to increase the efficiency of rotary vane machines at high pressure.
- a rotary vane machine consisting of two nodes, namely, the housing and the rotor, mounted with the possibility of mutual rotation.
- the housing with input and output ports contains a supporting part of the housing and a working part of the housing, on which a forward transfer limiter and a reverse transfer limiter are made.
- the rotor includes the supporting part of the rotor and the working part of the rotor, on the working end surface of which an annular groove is made, which is connected to the slide chambers in which there are gates installed with the possibility of changing the degree of extension in the annular groove.
- the working and supporting parts of one node are located between the connected connecting part of the working and supporting parts of another node.
- the supporting part of the housing contacts the supporting part of the rotor, and the working part of the housing contacts sliding with the working end surface of the working part of the rotor and isolates the working chamber in the annular groove.
- the return transfer limiter and the direct transfer limiter located in the sliding insulating contact with the gates divide the working chamber into an input cavity hydraulically connected to the input port and an output cavity hydraulically connected to the output port.
- At least one of the two nodes of the rotary vane machine, the rotor or the casing is adaptive, that is, includes power chambers of variable length kinematically connecting the working and supporting parts of the adaptive node with the possibility of their mutual axial movements and inclinations.
- the amplitude of these axial displacements and inclinations is at least sufficient to provide a sliding insulating contact between the working parts of both nodes of the rotor vane machine during their mutual rotation, and changing the length of these power chambers leads to the indicated mutual movements of the working and supporting parts of the adaptive node.
- Each power chamber of variable length (hereinafter referred to as the power chamber) includes a power cavity of variable length hydraulically connected to the working chamber (hereinafter referred to as the power chamber) and means for its isolation.
- the pressure forces of the working fluid in the power cavities are directed so as to extend the power chambers and bring the working part of the housing and the working part of the rotor closer to each other.
- the difference lies in the fact that in each power chamber the means for isolating its power cavity include at least two movable elements.
- movable elements are installed with the formation of sliding insulating contacts between the following pairs of surfaces: the insulating surface of one of the movable elements and the insulating surface of one part of the adaptive node, the insulating surface of another movable element and the insulating surface of the other part of the adaptive node and between the insulating surfaces of the movable elements.
- both insulating surfaces are made cylindrical and at least in one spherical, and in the remaining indicated contacts the pairs of contacting surfaces are selected in such a way that they retain a sliding insulating contact during the indicated mutual movements of the working and supporting parts of the adaptive assembly .
- both insulating surfaces are either flat or spherical.
- spherical and flat insulating surfaces are preferably performed on the hydrostatically unloaded part of the adaptive assembly and on the hydrostatically unloaded mobile elements.
- the support (item 2) or the binder (item 3) is not unloaded and deformable under pressure
- cylindrical surfaces are performed on movable elements and on any of these parts, or between movable elements.
- a cylindrical surface is understood in the most general sense as a surface formed by parallel movement of a straight line along a given closed loop. If necessary, the cylindrical surface can be made with an oval or other cross-section. In the following examples of the invention, a preferred embodiment of cylindrical surfaces with a circular cross section is shown.
- the clamp of the working part of the rotor to the working part of the housing in the absence of pressure is ensured by the fact that the power chambers include elastic elements.
- the shapes, sizes and arrangement of the power cavities are chosen in such a way that the sum of the elastic forces of these elastic elements and the pressure forces of the working fluid in the power chambers pressing the working part of the rotor to the working part of the housing exceeds the sum the pressure forces of the working fluid in the working chamber, pushing the working part of the rotor away from the working part of the housing, and the friction forces in these rotor elements that impede the approach of the working part of the rotor to the working part of the body and, at a predetermined value, preferably not exceeding 5% of said sum of the pressure forces repelling working part of the rotor from the working part of the housing.
- the shape and dimensions of the power cavities are chosen so as to provide hydrostatic clamping of the working parts to each other, namely, the shapes, sizes and arrangement of the power cavities are selected so that the sum of the pressure forces of the working fluid in the power chambers pressing the working part of the rotor to the working part of the housing exceeds the sum of the pressure forces of the working fluid repelling the working part the rotor from the working part of the housing by a predetermined amount, preferably not exceeding 5% of the indicated sum of pressure forces repelling the working part of the rotor from the working part of the housing.
- the supporting cavities are made, the shape, dimensions, quantity and location of which are selected so that the difference between the pressure forces of the working fluid repelling the working parts of the rotor and the housing , and the pressure forces of the working fluid, repelling from each other the supporting parts of the rotor and the housing, does not exceed another predetermined, preferably small, value.
- Hydrostatic unloading of a part of the adaptive assembly protects it from axial deformations under the pressure of the working fluid and significantly reduces friction losses between it and the corresponding part of another assembly.
- the shapes and sizes of these pairs of insulating surfaces are selected so that the sum of the pressure forces of the working fluid pressing these surfaces to each other, exceeded the sum of the opposing pressure forces of the working fluid, repelling them from each other.
- the indicated excess value is small, i.e. not exceeding 10% of the product of pressure in the force cavity by the cross-sectional area of its cylindrical insulating surfaces.
- the aforementioned hydrostatic clamping of the movable elements is achieved by the fact (clause 8) that for each pair of said insulating surfaces, the cross-sectional area of the power cavity by a plane passing through the internal boundary of the sliding insulating contact of these surfaces is selected to be less than the cross-sectional area of the cylindrical insulating surfaces of the power cavity by at least 50% of the projection area onto the specified plane of the specified sliding insulating contact.
- the area of one insulating surface exceeds the area of the other insulating surface so that each section of the surface of a smaller area retains sliding insulating contact with the surface of a larger area at any angle of rotation of the rotor throughout the range of these mutual displacements of the working and supporting parts of the adaptive node.
- the proposed solution for the isolation of power chambers and the working chamber of a rotary vane machine can be embodied in various designs. They differ in that of the nodes of the rotary vane machine, the rotor or the casing is made adaptive, as well as the type of power circuit, i.e. one of the two nodes includes a connecting part, which takes on the axial tensile forces of the working fluid pressure, compensating them with its elastic deformation.
- Rotary vane machines with a power circuit to the housing correspond to traditional arrangements in which the rotor assembly is located between the working and supporting parts of the housing.
- the assembly of the working and supporting parts of the housing located between the working and supporting parts of the rotor is hereinafter referred to as the operating unit of the housing.
- the working and supporting parts of the housing are located between the working and supporting parts of the rotor, which includes the connecting part of the rotor, and at least one of these parts of the rotor is mounted with axial movement and slopes relative to the connecting part, and power chambers of variable length are made between the specified part of the rotor and the rotor connecting part and kinematically connect said rotor part to the connecting part, the surfaces of the sliding insulating contact between the rotor connecting part and the movable element being cylindrical.
- variable-length power chambers are made between the supporting part of the casing and the working part of the casing connected to the operating unit of the casing, which is located between the working and supporting parts of the rotor, connected by the connecting part of the rotor.
- hydrostatic means are proposed to prevent deformation of the insulating housing surfaces, the performance of which depends on the type of power circuit.
- the working or supporting parts of the housing are made integral, namely, assembled from external power and internal functional elements, between which, at least one anti-deformation chamber is made opposite the annular groove, hydraulically connected to the working camera.
- the number, location, shape and dimensions of the anti-deformation chambers are selected so that the resultant of the pressure forces of the liquid on the internal functional element of the housing part from the rotor side and the forces of the liquid pressure from the side of deformation chambers does not exceed a predetermined value, preferably not exceeding 20% of the indicated pressure forces side of the rotor.
- anti-deformation chambers of variable length can also be made similar to the above-described power chambers, in which isolation at mutual tilts of the parts of the assembly is ensured by a combination of three types of sliding movements of the moving elements: axial with mutual axial sliding of cylindrical insulating surfaces, inclined during mutual sliding of spherical insulating surfaces, as well as transverse during mutual sliding of flat or other spherical surfaces.
- the anti-deformation chamber contains an anti-deformation cavity of variable length and means for its isolation, including at least two movable elements installed with the formation of sliding insulating contacts between the following pairs of surfaces: the insulating surface of one of the moving elements and the insulating surface of the functional element of the housing part , the insulating surface of another movable element and the insulating surface of the power element of the housing part and between the insulating surfaces the rests of the movable elements, moreover, in at least one of these contacts, both insulating surfaces are cylindrical and at least in one are spherical, and in the remaining indicated contacts the pairs of contacting surfaces are selected in such a way that they maintain a sliding insulating contact when the specified change in the angle of mutual inclination. In this case, either (item 16), in at least one of these contacts, both insulating surfaces are made flat, or (item 17), in at least two of these contacts, the insulating surfaces are made spherical ..
- the working and supporting parts of the housing are connected to the operating unit of the housing, and between the supporting parts of the housing and rotor opposite the annular groove, hydraulically connected supporting cavities are located opposite the annular groove and hydraulically connected with it so that the pressure in each supporting cavity is equal to the pressure in the working chamber opposite the cavity in the annular groove, and the number, shape and size of the supporting cavities are selected so that the resultant
- the pressure forces on the supporting part of the housing from the side of the supporting part of the rotor and the pressure forces on the working part of the housing from the side of the working part of the rotor did not exceed a predetermined value, preferably not exceeding 5% of the indicated pressure forces repelling the working part of the rotor from the working part of the housing.
- the transmission of these balancing pressure forces between the working and supporting parts of the housing is provided by the above-described power chambers.
- the specified transfer of balancing pressure forces between the parts of the body is ensured either through their rigid connection, or through anti-deformation chambers, either directly between the body parts, or between the functional and power elements of the parts of the operating unit of the body.
- variable-length anti-deformation chambers can also be made similar to the above-described power chambers, in which the insulation the mutual tilting of the parts of the node is ensured by a combination of three types of sliding movements of the moving elements: axial during mutual axial sliding of cylindrical insulating surfaces, inclined when imnom sliding spherical insulating surfaces and transverse with mutual sliding of the flat or other spherical surfaces.
- the anti-deformation chamber contains an anti-deformation cavity of variable length and means for its isolation, including at least two movable elements installed with the formation of sliding insulating contacts between the following pairs of surfaces: the insulating surface of one of the moving elements and the insulating surface of the working part of the housing, insulating the surface of the other movable element and the insulating surface of the supporting part of the housing and between the insulating surfaces of the movable elements, Therefore, in at least one of these contacts, both insulating surfaces are cylindrical and at least in one they are spherical, and in the remaining indicated contacts, the shapes of the pairs of contacting surfaces are selected in such a way that they retain a sliding insulating contact at the indicated change in the angle of mutual tilt. Moreover, either (clause 16), in at least one of the indicated contacts, both insulating surfaces are made flat, or (item 17), in at least two of these contacts, the insulating surfaces are made spherical.
- Figure 1 Rotary vane machine with an adaptive rotor and a power circuit on the housing, an axial section in a plane passing through the backward transfer limiter.
- Figure 2 Rotary vane machine with an adaptive rotor and a power circuit on the housing, an axial section in a plane passing through the input and output ports.
- Fig.Z Rotary vane machine with an adaptive rotor and a power circuit on the housing, a cut in a plane perpendicular to the axis of rotation and passing through the annular groove.
- Figure 4 Rotary vane machine with an adaptive housing and a power circuit on the housing, an axial section in a plane passing through the backward transfer stop.
- Figure 5 Rotary vane machine with an adaptive casing and a power circuit on the casing, an axial section in a plane passing through the input and output ports.
- Fig - Rotary vane machine with an adaptive rotor and a power short circuit to the rotor, a cut in a plane perpendicular to the axis of rotation and passing through the annular groove.
- Fig.9 Rotary vane machine with an adaptive rotor and a power short circuit to the rotor, a cut in a plane perpendicular to the axis of rotation and passing through the supporting cavity.
- Figure 10 An embodiment of a power chamber with spherical surfaces of a sliding insulating contact between movable elements.
- 12 is an embodiment of a power chamber with flat surfaces of a sliding insulating contact between movable elements.
- 13 is an embodiment of a power chamber with cylindrical surfaces of a sliding insulating contact between movable elements.
- Fig. 14 shows an embodiment of a power chamber with three movable elements and cylindrical surfaces of a sliding insulating contact between them.
- Fig. 15 is an embodiment of a power chamber with a movable sleeve in the working part of the rotor.
- Fig. 16 is an embodiment of a power chamber with an elastic element operating in tension.
- 17 is an embodiment of a power chamber with an elastic element operating in tension.
- Fig - View of the deformation of the end and cylindrical surfaces of the deformable part of the adaptive node under the action of axial pressure forces of the working fluid the deformable part is fixed in the center.
- Fig - View of the deformation of the end and cylindrical surfaces of the deformable part of the adaptive node under the action of axial pressure forces of the working fluid the deformable part is fixed in the center.
- Fig - View of the deformation of the end and cylindrical surfaces of the deformable part of the adaptive node under the action of axial pressure forces of the working fluid, the deformable part is fixed around the perimeter.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit on the housing, a hydrostatically unloaded supporting part of the rotor, the axis of rotation of which is inclined relative to the axis of rotation of the working part of the rotor, an axial section in the plane passing through the backward transfer stop.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit to the housing, a hydrostatically unloaded supporting part of the rotor, the axis of rotation of which is inclined relative to the axis of rotation of the working part of the rotor, axial section in the plane passing through the input and output ports.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit on the housing, a hydrostatically unloaded supporting part of the rotor, the axis of rotation of which is inclined relative to the axis of rotation of the working part of the rotor, a section in a plane perpendicular to the axis of rotation and passing through an annular groove.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit on the housing, a hydrostatically unloaded supporting part of the rotor, the axis of rotation of which is inclined relative to the axis of rotation of the working part of the rotor, a section in a plane perpendicular to the axis of rotation and passing through the supporting cavity.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit to the housing, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual tilt of the rotational axes of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the functional and power elements of the supporting part of the housing, axial section in a plane passing through the backward transfer stop,
- Fig - rotary vane machine with an adaptive rotor, a power circuit to the housing, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual inclination of the rotational axes of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the functional and power elements of the supporting part of the housing, axial section in the plane passing through the input and output ports Fig - Rotary vane machine with an adaptive rotor, a power circuit to the housing, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual inclination of the rotational axes of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the functional and power elements of the supporting part of the housing, a section in a plane perpendicular to the axis of rotation and passing through the annular groove.
- Fig. 29 - Rotary vane machine with an adaptive rotor, a power circuit to the housing, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual tilt of the rotational axes of the working and support parts of the rotor and with anti-deformation chambers of variable length between the functional and power elements of the support part of the housing, a section in a plane perpendicular to the axis of rotation and passing through the anti-deformation chambers of variable length.
- Fig.ZO - Rotary vane machine with an adaptive rotor, a power short circuit to the rotor, a hydrostatically unloaded support part of the rotor, a variator of the angle of the mutual axes of rotation of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the working and supporting parts of the housing, an axial section in the plane passing through the back transfer limiter.
- Fig - Rotary vane machine with an adaptive rotor, a power circuit on the rotor, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual tilt of the rotational axes of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the working and supporting parts of the housing, an axial section in the plane passing through the input and output ports.
- Fig - Rotary vane machine with an adaptive rotor, a power short circuit to the rotor, a hydrostatically unloaded support part of the rotor, a variator of the angle of mutual tilt of the rotational axes of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the working and supporting parts of the housing, a section in the plane, perpendicular to the axis of rotation and passing through the annular groove.
- Fig.ZZ a rotary vane machine with an adaptive rotor, a power short circuit to the rotor, a hydrostatically unloaded support part of the rotor, a variator of the angle of the mutual axes of rotation of the working and supporting parts of the rotor and with anti-deformation chambers of variable length between the working and supporting parts of the housing, a cut in the plane, perpendicular to the axis of rotation and passing through the anti-deformation chambers of variable length.
- the rotary vane machine in Fig.1 - Fig.Z is made with an adaptive rotor and a power circuit on the housing.
- Parts of the housing 3 and 4 are connected by a connecting part 5 of the housing, which receives the tensile axial forces of the working fluid pressure and is made in the form of a hollow body, inside which an adaptive rotor is placed.
- the connecting part of the housing can be placed inside the hollow rotor.
- the connecting part of the housing can also be made together with the working or supporting part of the housing as a single part.
- the rotor support part 2 is mounted on the housing support part 4 by a thrust rolling bearing 6.
- the rotor working part 1 is kinematically connected to the rotor support part 2 by a rotation synchronizing hinge (not shown in the figures) and power chambers 7. Due to the choice of shapes and the dimensions of the power chambers 7, the working part 1 of the rotor is hydrostatically balanced in the axial direction. Cylindrical force cavities 8 are made in the supporting part of the rotor, which is subject to axial deformations under the influence of the indicated pressure forces.
- a cylindrical movable element 9 is installed with the formation of a sliding insulating contact, having its spherical surface in sliding insulating contact with the spherical surface of another movable element 10, which with its flat surface is in sliding insulating contact with a flat surface on the rotor working part 1 .
- the rotary vane machine in Figure 4, Figure 5 is made with an adaptive housing and a power circuit to the housing.
- the connecting part 5 of the housing, including the power flange 11, connects the working 3 and supporting 4 parts of the housing, between which are located the working 1 and supporting 2 parts of the rotor, which in this design are made as two end parts of a single rotor, conventionally divided in Fig. 4 by a dashed line .
- the working and supporting parts of the rotor can be performed as separate parts from which the rotor is assembled.
- With the power flange 11 through the power chambers 7 is connected to the supporting part 4 of the housing. It is in sliding insulating contact with the surface of the supporting part 2 of the rotor.
- the connecting part of the housing can be connected by means of power chambers with the working part of the housing or with both parts of the housing.
- the supporting parts of the rotor and the housing can be connected by means of a thrust bearing. Between the supporting part 2 of the rotor and the supporting part 4 of the housing, support cavities 15 are made.
- the number, location of the shape and dimensions of the supporting cavities 15, taking into account the area of the sliding insulating contact of the supporting parts of the rotor and the housing, is selected so that the pressure forces on the supporting part 4 of the housing the sides of the power chambers 7 exceeded the pressure forces that repel the support part 4 of the housing from the support part 2 of the rotor by a predetermined amount, preferably small, not exceeding 10% of the maximum value of these repulsive forces.
- the support cavity 15 is made in the supporting part of the housing.
- the support cavities can be made in the support part of the rotor, for example, in the form of an extension of the slide chambers.
- the supporting part 4 of the adaptive body is hydrostatically unloaded and is not subject to deformation under pressure.
- the cylindrical force cavities 8 are made in the power flange 11, which is subjected to axial deformations under the influence of the indicated pressure forces.
- a cylindrical movable element 9 is installed with the formation of the sliding insulating contact. Its spherical surface is in the sliding insulating contact with the spherical the surface of another movable element 10, which with its flat surface is in sliding insulating contact with a flat surface on the supporting part 4 of the housing.
- the rotary vane machine in Fig.6 - Fig.9 is made with an adaptive rotor and a power circuit on the rotor.
- the working 3 and supporting 4 parts of the housing, forming the operating unit 12 of the housing, are located between the working 1 and supporting 2 parts of the rotor, which are connected by a connecting part 13 of the rotor, which receives the tensile axial pressure forces of the working fluid and is made in the form of a shaft with a power flange 14.
- the connecting part of the rotor can be made in the form of a hollow body, inside which the operating unit of the housing is located.
- the rotor supporting part 2 is connected to the rotor connecting part 13 by means of power chambers 7.
- the rotor connecting part can be connected by means of power chambers to the working part of the rotor or to both parts of the rotor.
- the flat insulating surfaces of the rotor support part 2 and the housing support part 4 are in a sliding insulating contact, and between them there are support cavities 15 hydraulically connected to the force cavities 8 channels 16 in the rotor support part 2 and hydraulically connected to the working chamber by channels 17 in the operating unit 12 buildings.
- the shape and dimensions of the support cavities 15 are selected so that the pressure forces on the rotor support part from the side of the power chambers 7 exceed the pressure forces repelling the rotor support part 2 from the support part 4 of the housing operation unit 12 by a predetermined amount, preferably small, not exceeding 5% from the indicated repulsive forces.
- the supporting part 2 of the rotor is hydrostatically balanced and gets rid of deformations.
- Such constructions with hydrostatic balancing of the working and supporting parts of the adaptive rotor are described in more detail in RU 2005113098.
- the power flange 14 is subject to axial deformation. It has cylindrical force cavities 8. In each of them, a cylindrical cylindrical insulating contact is installed with the formation of a sliding insulating contact movable element 9. Its spherical surface is in sliding insulating contact with the spherical surface of another movable element 10, which with its flat surface is in sliding insulating contact with a flat surface on the supporting part 2 of the rotor.
- the operating unit 12 of the housing is made as a single part, the two end parts of which are the working 3 and supporting 4 parts of the housing, conventionally divided in FIG. 6 by a dashed line, and connected to the crankcase 50, on which the cam drive mechanism 28 is fixed gateways.
- the working 3 and supporting 4 parts of the housing can be performed as separate parts assembled into the operating unit of the housing.
- FIG. 5 with a power circuit to the housing and an adaptive housing unit
- rotary vane machines with a power circuit to the rotor can also be executed with an adaptive casing rather than a rotor.
- power chambers are made between the working and supporting parts of the adaptive operating unit of the housing.
- cylindrical, spherical and flat insulating surfaces are made with reasonable accuracy, allowing deviations from the ideal cylindrical, spherical or flat, shapes within the limits determined by the viscosity of the liquids used and the range of working pressures.
- the indicated deviations do not exceed: 2-5 microns for spherical or flat insulating surfaces and 5-15 microns for cylindrical undeformed surfaces.
- the implementation of cylindrical insulating surfaces on self-aligning spring-loaded sealing rings (like piston rings) can significantly (tens of times) increase the specified permissible deviations.
- the working part 3 of the housing in contact with sliding with the working end surface 18 of the working part 1 of the rotor, isolates in the annular groove 19 a working chamber.
- the return transfer stop 20 and the direct transfer stop 22 located in a sliding insulating contact with the gates 21 divide the working chamber into an input cavity 23 hydraulically connected to the input port 24 and an output cavity 25 hydraulically connected to the output port 26.
- the gates located in the gate chambers 27 21 are kinematically connected with a cam mechanism 28 of the gate drive mounted on the housing, defining the nature of the cyclic movement of the gate 21 relative to the annular groove 19 during the mutual rotation of the rotor assemblies and Pusa.
- the sliders 21 and the cam mechanism 28 of the drive of the sliders are made with the possibility of axial movement, and in Fig.7, Fig.8 - with the possibility of pivoting movement around an axis parallel to the axis of rotation of the rotor.
- other types of gate movement relative to the working part of the rotor are possible, for example, radial, as well as other types of gate mechanism, for example, using an electric or hydraulic drive.
- the annular groove 19 has a rectangular cross-section
- the direct 22 and the reverse transfer stops 20 are fixed in the axial direction
- the reverse transfer stop 20 is in sliding insulating contact with the walls and the bottom of the annular groove 19.
- the reverse transfer stop may be in sliding insulating contact with both the surface portions of the annular groove and with the sliders. Executions are also envisioned in which forward or reverse transfer stops are axially movable to control capacity.
- the sliders 21, kinematically connected with the slide drive mechanism 28, cyclically move relative to the annular groove 19 as follows: they slide from the outlet cavity 25 into the slide chambers 27 to the position where they move past the return transfer stop 20, then extend from the slide chambers 27 to the inlet cavity 23 before the position in which, being in sliding insulating contact with the direct transfer stop 22 and overlapping the annular groove 19, are moved to the output cavity 25. Sliding along the direct transfer stop 22, the sliders 21 provide a cyclical change in the volumes of the input 23 and output 25 cavities, the flow of working fluid through the input port 24, transferring it from the input cavity 23 to the output cavity 25 and displacing it to the output port 26.
- the adaptive unit parts between which the power chambers 7 are made, perform axial, inclined and lateral movements relative to each other.
- the movable elements 9 make axial movements with respect to the force cavities 8 with the axial sliding of their cylindrical insulating surfaces
- the moving elements 10 make oblique movements with respect to the moving elements 9 with the mutual sliding of their spherical insulating surfaces and lateral movements relative to the corresponding part of the adaptive unit during mutual sliding their flat insulating surfaces.
- the combination of these three types of sliding movements in pairs of cylindrical, spherical and flat insulating surfaces maintains the isolation of the power cavities 8 during the indicated movements of the parts of the adaptive node.
- FIG. 10 - Figure 17 shows examples of power chambers, which in different versions of the rotary vane machine are made between different parts of the adaptive nodes, but for consistency are shown between the working 1 and supporting 2 parts of the rotor.
- the surfaces of the sliding insulating contact (hereinafter the insulating surfaces) between the movable elements 9 and 10 are made spherical, and the surfaces of the sliding insulating contact between the movable element 10 and the hydrostatically unloaded part of the adaptive node are made flat.
- the rotor working part 1 includes movable sleeves 32 with which the movable element 10 is in contact.
- the surfaces of the sliding insulating contact between the movable elements 9 and 10 are made flat, and the surfaces of the sliding insulating contact between the movable element 10 and the hydrostatically unloaded part of the adaptive node, for example, the working part 1 of the rotor is made spherical.
- the cross-sectional areas of the force cavity 8 by the planes P1 and P2, (Fig. 10 - Fig. 17) passing through the internal boundaries of the sliding insulating contact of these surfaces are chosen smaller, than the cross-sectional area of the cylindrical insulating surfaces of the power cavity, at least 50% of the projection area on the specified plane of the specified sliding insulating contact.
- the shapes of the contacting spherical insulating surfaces of the means of isolating the power cavities are selected so as to ensure the absence of self-braking or the absence of jamming of the moving elements at specified friction coefficients in pairs of sliding insulating contacts.
- the radius of curvature and the radii of the inner and outer borders of the spherical surfaces are selected so that the angles “ ⁇ ” of FIG. 10, 11 between the flat surface and the tangents to the spherical surface in the axial section plane are in the range of 20 - 70 degrees.
- the flat 30 and spherical 31 insulating surfaces are not subject to pressure deformations and provide insulation during mutual radial and inclined movements of the working and supporting parts.
- the deformations under pressure of the support part or the connecting part do not break the insulation between the cylindrical insulating surfaces 33.
- the surfaces of the sliding insulating contact between the movable element are cylindrical of the power chamber and that part of the adaptive assembly that is deformed under the action of axial working pressure forces fluid, balancing the indicated forces with its elasticity.
- the cylindrical insulating surfaces 33 on this part are executed either as the inner walls of the power cavity 8 of Fig. 10, Fig. 11, or as the outer walls of the power protrusion 34 of Fig. 12. In the latter case, the power cavity 8 is formed between the power protrusion 34 and the inner walls of the movable element 9.
- Fig - Fi.21 shows the deformation of the flat and cylindrical surfaces of the deformable part, balancing its elasticity applied on one side of the pressure of the working fluid F.
- this deformable part may be as a supporting part of the rotor or housing, and the power flange of the connecting part. Deformations are calculated for a pressure of 30 MPa and are shown in Fig. 18 - Fig. 21 with an increase of 100 times relative to the size of the part. Arrows indicate the direction of pressure forces. Bold oblique hatching marks the sections of the deformable part fixed in the calculations.
- Fig. 18 and Fig. 19 correspond to deformations of the deformable part, which is fixed in the center, such as, for example, the power flange 14 of the rotor connecting part 13 of Fig. 6, Fig.
- Fig.20 and Fig.21 correspond to the deformations of the deformable part, which is fixed around the perimeter, such as, for example, the supporting part 2 of the rotor of Fig.1.
- the same nature of the deformations will have a power flange 11 of the connecting part 5 of the housing of FIG. 4. It can be seen that the initially flat end surface of the deformable part under the influence of pressure forces bends, turning in Fig. 18, Fig. 19 into a convex, and in Fig. 20, Fig. 21 - into a concave surface. At low pressures, the inclined movements of the movable elements 10 of the power chambers 7 partially compensate for the deformations of the deformable part.
- Spring O-rings 35 can be mounted on a movable element, for example, as in the versions of Fig. 11, Fig. 16, Fig. 17, or on the corresponding part of the adaptive assembly.
- the invention also provides for the execution of a rotary vane machine, in which both parts of the adaptive node are hydrostatically unloaded.
- Fig.22 - Fig.29 shows a rotary vane machine with a power circuit on the housing and power chambers 7 between the working 1 and supporting 2 parts of the rotor.
- the flat insulating surfaces of the rotor support part 2 and the housing support part 4 are in a sliding insulating contact, and support cavities 15 are made between them, hydraulically connected to the force cavities 8 channels 16 in the rotor support part 2.
- the shape, arrangement and dimensions of the support cavities 15 are selected so that the pressure forces on the rotor support part from the side of the power chambers 7 exceed the pressure forces repelling the rotor support part 2 from the housing support part 4 by a predetermined amount, preferably small, not exceeding 5% of specified repulsive forces. In this way, the supporting part 2 of the rotor is also hydrostatically balanced and gets rid of deformations.
- Hydrostatic balance of both parts of the rotor allows you to perform a flat or spherical insulating surface on any of these parts and provides freedom in choosing the location of the power cavity.
- power cavities 8 are made in the working part 1 of the rotor and are a continuation of the slide chambers 27.
- Other examples of possible versions of the power chambers between two hydrostatically unloaded parts of the rotor are shown in Fig.13, 14, where the force cavities 8 are made between the movable elements 9, 10, 29.
- the surfaces of the sliding insulating contacts of both parts of the rotor with the moving elements 9, 10 are spherical, and the surfaces of the sliding insulating contact of the moving elements with each other are made Lindric.
- the presence of two pairs of spherical insulating surfaces 31 provide isolation during mutual radial and inclined movements of the working and supporting parts of the adaptive node.
- the working part 3 of the adaptive housing of FIG. 4, FIG. 5 is made composite, that is, assembled from a functional element 45, which, in contact with the working part 1 of the rotor, isolates the working chamber in the annular groove 19, as well as the power element 44, the purpose of which is described Further.
- the working and supporting parts of the adaptive rotor of the above versions are shown for simplicity as single parts.
- the invention assumes that in other versions, one or another part of the rotor can also be made integral, that is, as an assembly of several elements, one of which performs the main function of this part of the rotor and is called hereinafter the functional element of this part of the rotor.
- the functional element of the working part of the rotor includes an annular groove connected to the slide chambers.
- That part of the adaptive unit, which is made integral, in addition to its functional element also includes additional elements, including those that can be made with an opportunity backlash or other movements relative to the functional element of this part.
- additional elements of the adaptive unit part may be in sliding insulating contact with the movable elements of the power chambers and thereby participate in the isolation of the power cavities.
- additional elements of the adaptive node part are such elements, including movable ones, whose position relative to the functional element of this part does not change from the mutual axial and inclined movements of the working and supporting parts of the adaptive node during mutual rotation of the rotor and the housing, as a result of which the friction between them and other elements of the adaptive unit part is not essential for the movable isolation of the power cavities.
- the movable elements of the means for isolating the power cavities are such movable elements, the position of which varies from the indicated mutual axial and inclined movements and which are therefore hydrostatically unloaded in the manner described above to reduce friction and ensure the synchronization of their movements necessary for isolation.
- FIG. 15 shows the design of the working part of the rotor and power chambers, preferred in terms of manufacturability and compactness for rotary vane machines with an adaptive rotor and axial movement of the gates.
- the working part of the rotor 1 includes a functional element 51, in which an annular groove 19 is made, as well as insulating sleeves 32, which have a cylindrical surface that is in sliding insulating contact with the cylindrical surface of the gate 21, as well as a first flat surface that is in sliding insulating contact with the flat surface of the movable element 10 means of isolating the power cavity 8.
- the sleeve 32 also has a second flat surface in sliding contact with the flat surface of the functional ementa 51 with the possibility for self-aligning the vanes 21, which reduces the accuracy requirements for performing vane chambers in the working part 1 of the rotor.
- the diameters of the holes in the movable elements 9 and 10 exceed the diameter of the gate 21, which allows axial movement of the gate 21 with immersion in the power cavity 8 and allows to reduce the axial dimensions of the rotary vane machine.
- the position of the insulating sleeve 32 of the working part of the rotor relative to the functional element 51 of the working part of the rotor depends only on the position of the gate 21 and does not change with the indicated mutual movements of the parts of the adaptive rotor. Therefore, there is no need for synchronized movements of the sleeve 32 and the movable elements 9 and 10 and, accordingly, axial hydrostatic unloading of the sleeve 32 is not required.
- the specified contact of the flat surfaces of the functional element 51 and the sleeves 32 of the rotor working part transfers the pressure forces of the working fluid from the power chambers 7 to the functional element 51, thereby hydrostatically balancing the working part of the rotor as a whole and preventing axial deformation of both the functional element 51 and the bushings 32 of the working part of the rotor.
- the movable elements 9 and 10 are hydrostatically unloaded in the axial direction, as a result of which the axial movements of the element 9 relative to the supporting part 2 of the rotor cause synchronous, insulating, inclined and lateral movements of the element 10 relative to the sleeve 32 and the functional element 51 of the working part 1 of the rotor and, conversely, the movements of the element 10 cause synchronous movements of the element 9.
- the adaptive assembly includes elastic elements that press the end insulating surfaces of the adaptive unit parts to the end insulating surfaces of the parts of another node.
- the elastic elements 36 in the form of compression springs are installed in the power chambers 7 and also provide clamping in pairs of spherical and flat insulating surfaces of the insulation means of the power cavities 8 in the absence of pressure.
- the shapes, sizes and arrangement of the power cavities 8 are chosen so that the sum of the elastic forces of these elastic elements 36 and the pressure of the working fluid in the power chambers 7, pressing the working part 1 rotor to the working part 3 of the casing, exceeds the sum of the pressure forces of the working fluid (in the working chamber and in the gaps between the end insulating surfaces of the rotor and the casing) that repel the working part 1 of the rotor from the working part 3 housing, and friction forces that prevent the approach of the working part of the rotor to the working part of the housing, by a given value.
- the specified excess value small, namely, not exceeding 5% of the indicated sum of pressure forces repelling the working part 1 of the rotor from the working part 3 of the housing.
- the indicated repulsive forces oscillate when the rotor rotates, especially for versions with an adaptive body, therefore, the excess is determined relative to the maximum value of the repulsive forces.
- the present invention assumes that any of the nodes of the rotary vane machine, the rotor or the housing, can rotate relative to the chassis of the unit on which another node of the rotary vane machine is mounted.
- a design is possible in which both the rotor and the housing rotate relative to the chassis of the unit, for example, if the rotary vane machine is a link in the hydrostatic differential or hydromechanical transmission.
- the adaptive assembly is carried out, mounted on the chassis, then to reduce friction losses at low pressures, it is preferable to reduce the elastic forces of the elastic elements 36 to the minimum necessary level, selected taking into account the friction forces in the power chambers 7 in the absence of pressure. If the adaptive assembly is made, which rotates relative to the chassis of the unit, then the shape of the spherical surfaces and the elastic forces of the elastic elements 36 are chosen so as to prevent centrifugal forces from breaking the sliding insulating contact between the spherical surfaces and between the flat surfaces at maximum rotation speed. At rotational speeds of the order of several thousand revolutions per minute, centrifugal forces acting on moving elements weighing tens of grams can reach hundreds of newtons.
- the ratio between the centrifugal force acting on the movable element 10 and the pressing force balancing it from the side of the elastic element 36 is determined by the shapes of the insulating surfaces, for example, for the versions of FIG. 10, 11, the angles “ ⁇ ” between the flat and spherical surfaces. Therefore, for given angles “ ⁇ ”, an increase in the maximum rotation frequency requires a corresponding increase in the pressing forces of the moving elements due to the elastic reaction of the elastic elements.
- the elastic element 37 in the form of a spiral spring is fixed at one end to the movable element 9 with a cylindrical surface, and the other end to that part of the adaptive node, the flat insulating surface of which is in contact with the flat insulating surface of the moving element 10 (in this case, working part 1 of the rotor).
- the tensile elastic element 37 in this case tends to compress and presses the movable elements to each other and to the specified part of the node.
- the elastic element 37 can be executed working on compression and complemented by an element, for example, traction, which converts the compressive force into the compressive force of the moving elements to each other and to the specified part of the adaptive node.
- Fig shows the performance power chambers 7 with two movable elements 9 and 10, the cylindrical surfaces of which are in sliding insulating contact with the cylindrical surfaces of the power cavities 8 in the working and supporting parts of the adaptive node, and the third movable element 29, the spherical surfaces of which are in sliding insulating contact with the corresponding spherical the surfaces of the above movable elements 9 and 10.
- the tensile elastic element 37 in the form of a spiral spring is fixed between the movable elements 9 and 10 and presses each other all three movable elements 9,10 and 29 against each other.
- the elastic reaction force of the elastic element 37 does not affect the pressure force of the parts of the rotor to the parts of the housing, and can be chosen large enough so that for a given mass movable elements 29, rotor speed and the shape of spherical surfaces, compensate for the centrifugal forces acting on the movable elements 29.
- separate elastic elements can be used cients, e.g. laid outside the force chambers.
- the shape and dimensions of the power cavities 8 are chosen in such a way as to provide hydrostatic clamping of the working parts to each other, namely, that the total cross-sectional area of the power cavities 8 by a plane perpendicular to the axis of rotation of the rotor exceeds the projection area of the annular groove on the same plane by at least 50% of the projection area on the specified plane of the sliding insulating contact that of the working part of the rotor with the working part of the housing.
- the specified excess value so that the specified hydrostatic clamp is small, namely, not exceeding 5% of the indicated sum of pressure forces repelling the working part of the rotor from the working part of the housing.
- the necessary range of the indicated mutual axial, transverse and inclined movements of the working and supporting parts is determined taking into account technological tolerances, thermal gaps and deformations of elements under the action of pressure forces of the working fluid.
- the invention also provides for the following versions of rotary vane machines with an adaptive rotor, in which the range of these mutual motions of the working and supporting parts is selected based on a given magnitude of the change in the volume of the power chambers during the mutual rotation of the rotor and the housing.
- the volume of the power chambers connecting the working and supporting parts of the rotor is changed during rotation of the rotor so that the pressure of the working fluid, which is separated in the power chamber from the inlet cavity with the inlet pressure, reaches the outlet pressure the moment the power chamber is connected to the outlet cavity.
- the axis of rotation of the supporting part of the rotor is tilted relative to the axis of rotation of the working part of the rotor by an angle depending on the difference between the inlet and outlet pressure.
- the supporting part 4 of the housing is installed with a fixed slope of its flat end insulating surface relative to the flat end insulating surface of the working part 3 of the housing at a predetermined angle ⁇ around an axis parallel to the straight line passing through the limiters of direct 22 and reverse 20 transfer.
- This angle of inclination ⁇ determines the amplitude of the mutual tilts of the working and supporting parts of the rotor, the amplitude of the volume change of each power chamber 7 and the degree of pressure change in it from the moment of its separation from the input cavity 23 to the moment of its connection with the output cavity 25.
- the tilt angle variator 39 includes a hydraulic cylinder 40 mounted on a power element 52 (described in more detail below) of the housing supporting part 4.
- the cavity 41 of the hydraulic cylinder 40 is hydraulically connected to the working chamber (for the pump - with the outlet cavity, for the hydraulic motor - with the inlet).
- the piston 42 is kinematically connected with the functional element 53 of the support part 4 of the housing and is supported by a spring 43.
- the position of the piston 42 and the angle of inclination ⁇ of the axis of rotation of the rotor support part 2 relative to the axis of rotation of the rotor working part 1 change.
- This angle determines the amplitude of the mutual tilts of the working and supporting parts of the rotor, the amplitude of the change in the volume of the power chamber 7 and the degree of pressure change in it from the moment of its separation from the input cavity 23 to the moment of its connection with the output cavity 25.
- the working and supporting parts of the operating unit of the case are either fixed with a mutual inclination, or, as in Fig. ZO - Fig. ZZ, with the possibility of changing removable mutual tilt by means of a variator of the angle of inclination 39, made similar to the above between the working and supporting parts of the operating unit 12 of the housing.
- a change in the indicated angle of inclination leads to a change in the amplitude of the mutual axial, transverse and inclined movements both in pairs of cylindrical surfaces 33 and in pairs of flat 30 and spherical 31 insulating surfaces.
- the necessary degree of change in the volume of the power chambers reaches several percent, and the indicated angle of mutual tilt reaches units of degrees.
- the mutual axial displacements of cylindrical insulating surfaces in this case reach units of millimeters, and the mutual transverse displacements in pairs of spherical and flat insulating surfaces reach tenths of a millimeter.
- the dimensions of these insulating surfaces are selected so that in a given range of mutual axial, transverse and inclined movements of the working and supporting parts of the adaptive unit, a sliding insulating contact is maintained in all pairs of contacting insulating surfaces between the insulation means of the power cavities.
- the area of one of them exceeds the area of the other by a predetermined amount selected in such a way that each part of the surface of a smaller area retains sliding contact with the surface of a larger area for any angle of rotation of the rotor in the entire range of the indicated mutual movements, Fig.10 - Fig.17.
- the invention provides hydrostatic means of preventing deformation case insulating surfaces that are in sliding insulating contact with the flat end surfaces of the working and supporting parts of the rotor.
- the 27 is made of an external power element 52 and an internal functional element 53, between which at least one is connected to the working chamber and sealed by the perimeter of the anti-deformation chamber 54.
- the number, location, size and shape of the anti-deformation chambers are selected so that the resultant of the fluid pressure forces on the inner functional element 45, 53 of the housing part from the rotor side and the fluid pressure forces from the antideform of the chambers 46, 54 did not exceed a predetermined value, preferably a small one, not exceeding 20% of the pressure forces from the rotor side.
- the anti-deformation chambers 46, 54 are located opposite the cavity in the annular groove 19 in which high pressure is set (for the pump, opposite the outlet cavity 25, for a hydraulic motor, opposite the inlet cavity 23), and are hydraulically connected to the cavity. If high pressure can occur both in the outlet and in the inlet cavity, then different antideformation chambers are performed opposite each of them. In a preferred embodiment, individual anti-deformation chambers are also performed opposite the forward and reverse transfer zones in the working chamber, i.e. opposite the limiters direct and reverse transfer, and are hydraulically connected to opposite sections in the working chamber.
- the shape and dimensions of the anti-deformation chambers are chosen so that the distribution pressure between the functional and power elements of the corresponding part of the housing was close to the pressure distribution between the functional element and the rotor, for example, giving the anti-deformation chamber 46, 54 an arcuate shape, the transverse dimensions of which are close to the transverse dimensions of the annular groove 19, and the area is close to the area of that part of the surface functional element 45, 53, which is subjected to high pressure from the rotor side.
- separate cylindrical anti-deformation chambers are made in an arc opposite the annular groove, the total area of which is chosen in the same way.
- the preferred technology and dimensions option involves the execution of anti-deformation chambers between the functional and power elements of the housing part, preferably Fig. 26 - Fig. 29, like power chambers of variable length in Fig. 10 - Fig. 14, Fig. 16, Fig. 17, described in detail above.
- variable-length anti-deformation chamber 55 contains a variable-length anti-deformation cavity 47 and means for its isolation, including at least two movable elements 48 and 49.
- These movable elements are installed with the formation of sliding insulating contacts between the following pairs of surfaces: between the insulating surface of one of the moving elements and the insulating surface of the functional element 53 of the supporting part of the housing, between the insulating surface of another movable element and the insulating surface with lovogo support member 52 of the housing and between the insulating surfaces of the moving elements 48 and 49.
- both insulating surfaces are cylindrical and, in at least one of them are spherical, and in the other indicated contacts, the shapes of the pairs of contacting surfaces are selected in such a way that they maintain a sliding insulating contact at the indicated change in the angle ⁇ of mutual inclination.
- Mutual sliding of cylindrical insulating surfaces provides insulation during mutual axial movements of the working and supporting parts of the housing, and mutual sliding of insulating spherical surfaces provides insulation during mutual inclined movements of these parts.
- both insulating surfaces are either flat or spherical.
- the anti-deformation chambers of variable length 55 are equipped with elastic elements 57 in the form of springs.
- the functional element 53 of the supporting part of the housing is substantially hydrostatically balanced and it is preferable to perform flat (as on the rotor supporting part 2 of FIG. 10, 11, FIG. 16) or spherical (as on the rotor working part 1 of FIG. 12) insulating surface.
- the power element 52 is subject to pressure deformations, therefore, it is preferable to carry out cylindrical insulating surfaces of the anti-deformation chambers on it and, if necessary, strengthen their insulation by means of spring-loaded sealing rings. Such a preferred embodiment is shown in FIG. 26 to FIG. 29.
- the functional element 53 of the supporting part 4 of the housing has the ability to tilt relative to the power element 52 of the supporting part 4 of the housing and, thus, relative to the working part 3 of the housing, changing the mutual inclination of the axes of rotation of the supporting 2 and working 1 parts of the rotor.
- hydrostatic means for preventing deformation of the insulating housing surfaces include supporting cavities 15 made between the supporting part 2 of the rotor and the supporting part 4 of the operating unit 12 of the housing . Due to the above selection of the shape, location and size of the support cavities 15, the pressure forces on the housing support part 4 from the side of the rotor support part 2 and the pressure forces on the housing work part 3 from the side of the rotor work part 1 differ by no more than a predetermined, preferably small, value.
- Figb - Fig.9 shows that the support cavity 15 is located opposite the annular groove 19 and connected to it by channels 17, so that the pressure in each support cavity 15 is equal to the pressure in the opposite cavity of the working chamber in the annular groove 19.
- the transverse dimensions of the support cavities 15 and the sliding insulating contact between the supporting parts of the rotor 2 and the housing 4 are close to the transverse dimensions of the annular groove 19 and the sliding insulating contact between the working parts 1 of the rotor and 3 of the housing. Therefore, a symmetrical distribution of the pressure of the working fluid is formed on both sides of the operating unit 12 of the housing.
- the working 3 and supporting 4 parts of the housing are rigidly connected to the operating unit of the housing 12, for example, when the operating unit of the housing 12 is designed as a single part as in Fig. B, as well as in versions with an adaptive operating unit of the housing, the indicated symmetry of the compressive pressure forces is effective prevents deformation of flat insulating surfaces of the working 3 and supporting 4 parts of the operating unit 12 of the housing.
- the invention provides for the execution between the working and supporting parts the operating unit of the housing of the anti-deformation chambers, the number, location, size and shape of which are selected so that the resultant of the fluid pressure forces on the casing part from the rotor side and the fluid pressure forces from the anti-deformation chambers does not exceed a predetermined value, preferably small, not exceeding 20% from pressure forces from a rotor.
- each of the parts of the operational unit is made of two elements, functional and power, with anti-deformation chambers between them, similar to the above for power circuit on the housing.
- the preferred technology and dimensions option involves the execution of anti-deformation chambers between the working and supporting parts of the operating housing unit Fig. ZO - Fig. ZZ like power chambers of variable length in Fig.10 - Fig.14, Fig.16, Fig.17, described in detail above.
- the variable-length anti-deformation chamber 56 contains a variable-length anti-deformation chamber 47 and means for its isolation, including at least two movable elements.
- movable elements 48 and 49 are installed with the formation of sliding insulating contacts between the following pairs of surfaces: the insulating surface of one of the moving elements and the insulating surface of the working part of the housing, the insulating surface of the other moving element and the insulating surface of the supporting part of the housing and between the insulating surfaces of the moving elements 48 and 49 .
- both insulating surfaces are cylindrical and at least in one are spherical, and in the remaining indicated contacts, the shapes of the pairs of contacting surfaces are selected in such a way that they retain sliding insulating contact at a specified change in the angle of mutual inclination.
- both insulating surfaces are either flat or spherical.
- the variable-pressure anti-deformation chambers 56 are provided with spring elastic elements 57.
- the working 3 and the supporting 4 parts of the operating unit 12 of the housing are substantially hydrostatically balanced, and the cylindrical surfaces can be performed on any of them (as on the supporting part 2 of the rotor in the power chambers of Fig. 10 - Fig. 12, Fig. 16, Fig. 17) or between movable elements (as in the power chambers of Fig. 13, Fig. 14).
- the specified hydrostatic balancing of the working and supporting parts of the operating unit of the housing significantly reduces the deformation of the housing insulating surfaces and significantly improves the insulation of the working chamber.
- the proposed rotary vane machine provides: - isolation of the working chamber and power chambers in a wide range of axial clearances between the nodes of the rotary vane machine by performing at least one node adaptive, i.e. containing a working and supporting part and power chambers of variable length with cylindrical pairs of insulating surfaces; - isolation of the working chamber and power chambers in a wide range of mutual inclined and transverse movements of the working and supporting parts of the adaptive node due to the isolation of the power chambers with spherical and flat pairs of insulating surfaces; - isolation of the working chamber and power chambers in a wide range of pressures and corresponding deformations due to the fact that cylindrical insulating surfaces of the means of insulation of the power chambers are made on the deformable component of the adaptive unit, allowing the installation of self-adjusting spring-loaded sealing rings, as well as through the use of hydrostatic means to prevent deformation of the casing insulating surfaces;
- the specified isolation of the working chamber and power chambers provides high volumetric efficiency, and in combination with hydrostatic unloading of friction pairs and high full efficiency at high pressure of the working fluid.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Rotary Pumps (AREA)
- Hydraulic Motors (AREA)
- Actuator (AREA)
Description
Claims
Priority Applications (5)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP07835023A EP2090782A4 (en) | 2006-10-30 | 2007-10-02 | ROTARY SLIDING PALLET MACHINE |
CA2667689A CA2667689C (en) | 2006-10-30 | 2007-10-02 | Rotor vane machine |
EA200900588A EA013809B1 (ru) | 2006-10-30 | 2007-10-02 | Роторная шиберная машина |
CN2007800489656A CN101636587B (zh) | 2006-10-30 | 2007-10-02 | 转子叶片机 |
US12/447,786 US20110189045A1 (en) | 2006-10-30 | 2007-10-02 | Rotary vane machine |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
RU2006138903 | 2006-10-30 | ||
RU2006138903/06A RU2327900C1 (ru) | 2006-10-30 | 2006-10-30 | Роторная шиберная машина |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2008054244A1 true WO2008054244A1 (fr) | 2008-05-08 |
Family
ID=39344502
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/RU2007/000534 WO2008054244A1 (fr) | 2006-10-30 | 2007-10-02 | Machine rotative à palette coulissante |
Country Status (8)
Country | Link |
---|---|
US (1) | US20110189045A1 (ru) |
EP (1) | EP2090782A4 (ru) |
CN (1) | CN101636587B (ru) |
CA (1) | CA2667689C (ru) |
EA (1) | EA013809B1 (ru) |
RU (1) | RU2327900C1 (ru) |
UA (1) | UA92685C2 (ru) |
WO (1) | WO2008054244A1 (ru) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US8277208B2 (en) | 2009-06-11 | 2012-10-02 | Goodrich Pump & Engine Control Systems, Inc. | Split discharge vane pump and fluid metering system therefor |
US20130156564A1 (en) * | 2011-12-16 | 2013-06-20 | Goodrich Pump & Engine Control Systems, Inc. | Multi-discharge hydraulic vane pump |
CN105822543B (zh) * | 2016-06-02 | 2018-03-06 | 李钢 | 一种转子径向力平衡的叶片泵 |
Citations (11)
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US570584A (en) | 1896-11-03 | Charles g | ||
US894391A (en) | 1907-06-06 | 1908-07-28 | Julius Wilhelm Von Pittler | Rotary engine. |
US1096804A (en) | 1913-07-03 | 1914-05-12 | Henry S Vaughn | Rotary pump. |
US2341710A (en) | 1942-02-18 | 1944-02-15 | Harold M Gingrich | Compressor or pump |
US3348494A (en) | 1967-01-23 | 1967-10-24 | Halbergerhutte G M B H | Rotary piston machine |
EP0269474A1 (fr) | 1986-10-16 | 1988-06-01 | Compagnie De Construction Mecanique Sulzer | Composant hydrostatique à palettes axiales et à placage axial |
RU2123602C1 (ru) * | 1997-05-30 | 1998-12-20 | Александр Николаевич Зимников | Роторная машина |
US5975868A (en) * | 1996-06-29 | 1999-11-02 | Luk Fahrzeug-Hydraulik Gmbh & Co. Kg | Vane pump precompression chamber |
RU2175731C1 (ru) * | 2000-05-23 | 2001-11-10 | Зимников Александр Николаевич | Обратимый насос |
RU2005113098A (ru) | 2005-04-26 | 2006-11-20 | Александр Анатольевич Строганов (RU) | Роторная шиберная машина |
RU2005129000A (ru) | 2005-09-13 | 2007-03-20 | Юрий Михайлович Волков (RU) | Способ создания равномерного потока рабочей жидкости и устройство для его осуществления |
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US2633803A (en) * | 1947-05-22 | 1953-04-07 | William J Carey | Rotary pump or motor |
US2957429A (en) * | 1956-06-01 | 1960-10-25 | James C Fisk | Axially shiftable vane pump |
US2977889A (en) * | 1957-02-11 | 1961-04-04 | James C Fisk | Fluid pressure power converter |
US3250223A (en) * | 1962-05-14 | 1966-05-10 | Trojan Corp | Vane impulsion apparatus |
US3586467A (en) * | 1968-06-01 | 1971-06-22 | Krupp Gmbh | Rotary displacement machine |
US3822965A (en) * | 1972-11-02 | 1974-07-09 | Trw Inc | Pumps with servo-type actuation for cheek plate unloading |
DE10200471A1 (de) * | 2002-01-09 | 2003-07-10 | Karl Bittel | Axialflügelmaschine |
RU2215903C1 (ru) * | 2002-05-28 | 2003-11-10 | Строганов Александр Анатольевич | Роторная машина |
US7479001B2 (en) * | 2006-03-03 | 2009-01-20 | Stroganov Alexander A | Rotor sliding-vane machine with adaptive rotor |
-
2006
- 2006-10-30 RU RU2006138903/06A patent/RU2327900C1/ru active IP Right Revival
-
2007
- 2007-10-02 US US12/447,786 patent/US20110189045A1/en not_active Abandoned
- 2007-10-02 CA CA2667689A patent/CA2667689C/en not_active Expired - Fee Related
- 2007-10-02 WO PCT/RU2007/000534 patent/WO2008054244A1/ru active Application Filing
- 2007-10-02 EA EA200900588A patent/EA013809B1/ru not_active IP Right Cessation
- 2007-10-02 CN CN2007800489656A patent/CN101636587B/zh active Active
- 2007-10-02 EP EP07835023A patent/EP2090782A4/en not_active Withdrawn
- 2007-10-02 UA UAA200905009A patent/UA92685C2/ru unknown
Patent Citations (11)
Publication number | Priority date | Publication date | Assignee | Title |
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US570584A (en) | 1896-11-03 | Charles g | ||
US894391A (en) | 1907-06-06 | 1908-07-28 | Julius Wilhelm Von Pittler | Rotary engine. |
US1096804A (en) | 1913-07-03 | 1914-05-12 | Henry S Vaughn | Rotary pump. |
US2341710A (en) | 1942-02-18 | 1944-02-15 | Harold M Gingrich | Compressor or pump |
US3348494A (en) | 1967-01-23 | 1967-10-24 | Halbergerhutte G M B H | Rotary piston machine |
EP0269474A1 (fr) | 1986-10-16 | 1988-06-01 | Compagnie De Construction Mecanique Sulzer | Composant hydrostatique à palettes axiales et à placage axial |
US5975868A (en) * | 1996-06-29 | 1999-11-02 | Luk Fahrzeug-Hydraulik Gmbh & Co. Kg | Vane pump precompression chamber |
RU2123602C1 (ru) * | 1997-05-30 | 1998-12-20 | Александр Николаевич Зимников | Роторная машина |
RU2175731C1 (ru) * | 2000-05-23 | 2001-11-10 | Зимников Александр Николаевич | Обратимый насос |
RU2005113098A (ru) | 2005-04-26 | 2006-11-20 | Александр Анатольевич Строганов (RU) | Роторная шиберная машина |
RU2005129000A (ru) | 2005-09-13 | 2007-03-20 | Юрий Михайлович Волков (RU) | Способ создания равномерного потока рабочей жидкости и устройство для его осуществления |
Non-Patent Citations (1)
Title |
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See also references of EP2090782A4 * |
Also Published As
Publication number | Publication date |
---|---|
EP2090782A4 (en) | 2012-03-07 |
CN101636587B (zh) | 2012-08-08 |
EP2090782A1 (en) | 2009-08-19 |
UA92685C2 (en) | 2010-11-25 |
EA200900588A1 (ru) | 2009-08-28 |
RU2327900C1 (ru) | 2008-06-27 |
CA2667689C (en) | 2016-06-28 |
CN101636587A (zh) | 2010-01-27 |
US20110189045A1 (en) | 2011-08-04 |
EA013809B1 (ru) | 2010-08-30 |
CA2667689A1 (en) | 2008-05-08 |
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