RU2082903C1 - Rotary machine - Google Patents

Abstract

FIELD: mechanical engineering; pumps and engines. SUBSTANCE: rotary machine has housing with cylindrical bore and working medium inlet and outlet channels, stator rings installed coaxially in housing. Rotor with diametrically profiled slots accommodating rods with separating plates on ends is also installed in housing. Plates can move radially in rotor slots to form working chambers in stator rings. Both ends of each rod are rigidly connected with adjacent plates. Inner surface of stator ring is made in form of polygon coaxial with stator ring outer surface with number of working faces equal to number of plates. Length of faces is made to satisfy the condition L>2E+T, where L - length of working face of polygon; E - eccentricity of rotor setting relative to stator ring; T - width of contact surface of plate radial end. Contact surface of radial end of plate is made at right angle to rod axis. Width of contact surface of plate radial end exceeds thickness of plate. Longitudinal slot is made in central portion of each contact surface of plate. Resilient sealing member in form of plate bent in cross section to arc of circumference is placed in longitudinal slot. Rotor and stator ring are mechanically connected by gear train with gear ratio 1:1. EFFECT: enlarged operating capabilities. 5 cl, 4 dwg

Description

 The invention relates to the field of mechanical engineering and can be used in pumping and engine building.

 Known rotor machines containing a cylindrical housing, with a cylindrical stator ring concentrically mounted in bearings, a cylindrical rotor with eccentricity installed inside its radial grooves of which are spring-loaded plates touching the inner surface of the stator ring (DE, patent N 3315571, F 01 C 1/344 , 1985).

 The disadvantage of this solution is the high friction losses of the plates on the stator ring and the rotor, large leaks of the working medium along the plate ridges due to linear contact, as well as the large specific gravity and radial dimensions dictated by the need to limit the plate outflow from the rotor grooves according to jamming conditions.

 A rotary machine is also known, in which cylindrical rods are additionally installed in the grooves of the rotor, having longitudinal grooves in peripheral sections, in which spring-loaded plates are mounted with the possibility of radial movement. (SU, N 1665047, F 01 C 1/344, 1991).

 With this solution, friction losses are reduced by reducing the forces in the pair of plastic-rotor and the radial dimensions are reduced, since there is no need to limit the extension of the plates from the rotor grooves.

The objective of the invention is to eliminate noise during operation of the rotor machine, local wear of the stator ring, reduce leakage of the working environment and reduce friction losses. The technical result is achieved by the fact that both ends of each rod are rigidly connected to adjacent plates; and the inner surface of the stator ring is made in the form of a polyhedron coaxial with its outer surface with the number of working faces equal to the number of plates, while the length of the faces is made with the condition:
L> 2E + T,
where L is the length of the working face of the polyhedron;
E the eccentricity of the installation of the rotor relative to the stator ring;
T is the width of the contact surface of the radial end of the plate.

 A rigid connection of the rod with the plates leads to the implementation of a kinematically closed mechanism and the hysteresis of the movement of the parts of the mechanism is eliminated, which excludes the possibility of impacts when shifting the rods and the noise and wear associated with them. An additional effect is the mutual balancing, through a rigid connection with the rod, of centrifugal forces from opposing plates, which significantly reduces friction losses, because centrifugal forces from the plates in the prototype create the largest share of friction losses. An additional reduction in friction losses occurs due to the mutual compensation of the Coriolis and inertial forces with the tangential pressure force of the working medium on the plates.

 Also, the contact surface of the radial end of the plate is made at right angles to the axis of the rod, which allows the use of a rotary machine in operating conditions when the direction of the resulting force applied to the stator ring is obviously unknown or variable.

 And also the fact that the width of the contact surface of the radial end of the plate is greater than the thickness of the plate, which allows to reduce friction losses from forces synchronizing the rotation of the rotor and stator ring.

 Additionally, in the central part of each contact surface of the plate, a longitudinal groove is made in which an elastic sealing element is installed, having the shape of a plate bent in cross section, for example, along an arc of a circle, thereby reducing leakage of the working medium.

 And the fact that the rotor and the stator ring are kinematically connected by a gear transmission with a gear ratio of 1: 1, which allows you to transfer or select power from the stator ring.

 In FIG. 1 shows a rotary machine, a cross section; in FIG. 2 - enlarged view of the contact surface of the radial end of the plate; in FIG. 3 is a diagram of the forces acting in the kinematic mechanism in which the contact surface of the radial end of the plate is made at right angles to the axis of the rod; in FIG. 4 is a diagram of the forces acting in the kinematic mechanism in which the contact surface of the radial end of the plate is not made at right angles to the axis of the rod.

 The rotor machine comprises a housing 1, a stator ring 2 mounted concentrically rotatably in it 2, a rotor 3 eccentrically placed in the ring 2 with radial grooves 4. In the radial grooves 4 there are plates 5. In the rotor 3 there are made through diametrically profiled grooves 6 into which are passed rods 7, the ends of which are rigidly connected to adjacent plates 5. The inner surface of the stator ring 2 is made in the form of a polyhedron coaxial with its outer surface with the number of working faces 8 equal to the number of plates, p and faces this length is adapted to the condition: L> 2E + T, where L the length of the working face of the polyhedron; E the eccentricity of the installation of the rotor relative to the stator ring; T is the width of the contact surface of the radial end of the plate 9. The contact surface 9 of the radial end of the plate is made at right angles to the axis of the rod 7. The width of the contact surface 9 of the radial end of the plate is greater than the thickness of the plate 5. A longitudinal groove 10 is made in the center of each contact surface 9 of the plate 5, into which an elastic sealing element 11 having the shape of a plate curved in cross section, for example, in an arc of a circle, is installed. The rotor 3 and the stator ring 2 can be kinematically connected by a gear transmission with a gear ratio of 1: 1.

When the rotor 3 rotates, the lateral surfaces of the grooves 4 transmit torque to the plates 5, connected in pairs by the rods 7. The plates pass into rotation and the contact surfaces 9 press on the working faces 8 of the stator ring 2, which prevents the rotation of the plates (Fig. 3). A pair of forces F _syn is realized on the contact surfaces 9 of the opposing plates 5, the axis of action of which is spaced apart by an amount equal to the width of the contact surface 9. This pair of forces transmits torque to the stator ring 2, which starts to rotate at an angular speed equal to the angular velocity of the rotor 3. When the rotation of the plate 5 begin to move along the working faces 8, with a large reach from the grooves 4 ahead of the stator ring, with a small reach, lagging behind it. Thus, the relative reciprocating movement of each plate 5 is realized within its working face 8.

When you start the rotary machine on the contact surfaces 9 there are synchronizing the rotation of the force F _syn (Fig. 3), the value of which is equal to:
F _syn 2 • F _tr.s. • R / T / Z,
where F _tr.sk. friction force in the bearing of the stator ring;
R is the radius of application of the friction force in the bearing of the stator ring (radius of the outer surface of the stator ring 2);
T is the width of the contact surface of the radial end of the plate 9;
Z number of plates 5.

In practice, the moment transmitted to the stator ring 2 is determined by the width of the contact surface; therefore, it is necessary to increase it as soon as possible for structural reasons. At the UMD-12 installation, when starting F _{syn, it is} approximately equal to the friction force applied to the stator ring, which leads to some increase in friction losses when starting the rotor machine.

However, in the work on the plate in the radial direction, centrifugal forces F _c and hydro- or gas-static forces F _g act, the resultant of which is directed towards the largest projection of the plate, where the contact surface 9 overtakes the stator ring 2. Friction force F _tr.Lop. plate 5 about the working face 8 is always directed along the rotation of the stator ring 2. This force is approximately equal in magnitude to the resultant braking force of the stator ring 2, consisting of two components: the friction force of the stator ring bearing F _tr.s. and hydro- or gas-static force F _d acting directly on the stator ring and preventing rotation in the case of using a rotary machine as an engine. When using a rotary machine as a pump, this force does not occur. Thus, in operation, the stator ring 2 is driven into rotation by the friction force of the plates 5 about the stator ring 2, and the forces additionally arising on the contact surfaces 9 only synchronize the rotation of the stator ring 2 relative to the rotor 3. In practice, at optimal operating conditions, synchronization is performed by displacement the axis of application of the sum of the forces F _c and F _g relative to the axis of the plate 5, and additional synchronizing forces F _syn does not occur. When performing the contact surface 9 is not at right angles to the axis of the rod, the operation of the rotary machine remains the same (Fig. 4), but the ability to reverse the direction of rotation of the rotary machine disappears. However, the manufacturability of the plate is increased.

 When performing in the central part of the contact surface 9 of the plate 5 a longitudinal groove 10, and installing an elastic sealing element 11 having the shape of a plate bent in cross section, for example, along an arc of a circle, a sealing device is implemented that, while minimizing the complexity of the design, without additional volume, almost completely eliminates leakage of the working medium along the ridges of the plates 5, while being a virtually wear-free seal. Sealing occurs with an oil wedge implemented at the leading edge of the elastic element in any direction of movement of the plate. In this case, the oil wedge protects the element 11 from direct contact with the working face 8 and eliminates all gaps caused by manufacturing inaccuracies.

 If the power is removed or supplied through the stator ring, there is a need to connect the rotor and stator ring with a gear transmission with a gear ratio of 1: 1, through which the power will be transmitted.

 A rigid connection of the rods to the plates can be performed in various ways: welding, soldering, adhesive bonding. The rods can also be made in one piece with the plates.

Claims (5)

1. A rotary machine, comprising a housing with a cylindrical bore and channels for supplying and discharging a working medium, a stator ring coaxially mounted in the housing, a rotor eccentrically mounted in the housing with diametrically profiled grooves and rods placed in them with dividing plates at the ends, with the possibility of radial movement in grooves of the rotor and formation of working chambers in the stator ring, characterized in that both ends of each rod are rigidly connected to adjacent plates, and the inner surface of the itator ring is made in the form of a polyhedron coaxial with its outer surface with the number of working faces equal to the number of plates, while the length of the faces is made with the condition
L> 2E + T,
where L is the length of the working face of the polyhedron;
E the eccentricity of the installation of the rotor relative to the stator ring;
T is the width of the contact surface of the radial end of the plate.  2. The machine according to claim 1, characterized in that the contact surface of the radial end of the plate is made at right angles to the axis of the rod.  3. The machine according to claims 1 and 2, characterized in that the width of the contact surface of the radial end of the plate is greater than the thickness of the plate.  4. The machine according to claims 1 to 3, characterized in that a longitudinal groove is made in the central part of each contact surface of the plate, into which an elastic sealing element is installed, having the shape of a plate curved in cross section, for example along a circular arc.  5. The machine according to claims 1 to 4, characterized in that the rotor and stator ring are kinematically connected by a gear transmission with a gear ratio of 1 1.

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