RU116898U1 - ROTARY-VANE MACHINE - Google Patents

Abstract

1. A rotary vane machine containing a fixed body with an internal cylindrical bore forming a working chamber of the machine, and ports for supply and discharge of the working medium, communicated with the pressure and drain lines, respectively, a hollow cylindrical rotor with a drive and longitudinal radial profiled grooves with opposite concave arcuate surfaces, installed in a stationary housing eccentrically with respect to the bore of a stationary housing, blades-blades with lugs, having working and end surfaces, and installed in hinges, which, in turn, have a plano-convex shape, and the hinges are placed with the possibility of rotation in longitudinal radial profiled grooves of the rotor due to the interaction of its outer convex surface with their opposing concave arcuate surfaces, characterized in that more than one inner cylindrical bore is made in the stationary body, forming the working chambers of the machine, with supply and hole windows ode the working environment, communicated with the pressure and drain lines, respectively, adjacent bores of the housing are made eccentrically to each other, in the cylindrical rotor there is more than one cavity with longitudinal radial profiled grooves with opposing concave arcuate surfaces, and each of the cavities of the cylindrical rotor is aligned with the corresponding internal cylindrical bore of the stationary body, while the eyes of the blades are located inside the cavities of the rotor and are installed on axes coaxial with the axes of each of the inner cylindrical bores of the stationary body and made

Description

The utility model relates to the field of power engineering and can be used in the construction of rotor-blade mechanisms of rotor machines.

The closest technical solution selected for the prototype, and known from the existing level of technology, is a rotor-blade machine containing a fixed body with an internal cylindrical bore and the windows for supplying and discharging the working medium in communication with the pressure and drain lines, respectively, a hollow cylindrical rotor with a drive and longitudinal radial profiled grooves with opposite concave arcuate surfaces, eccentrically placed in the bore of the housing, mounted in hinges having flat-convex shape, blades having working and end surfaces, with eyes covering an axis coinciding with the axis of the body bore, the hinges being rotatably rotated in the longitudinal radial profiled grooves of the rotor due to the interaction of their external convex surface with their opposite concave arcuate surfaces (cm U.S. Patent 3892502, NCI 418/15, 1975).

The achievement of the required technical result — improving operational characteristics and reliability in a wider range of parameters — is prevented, for example, by significant pneumohydraulic and mechanical losses during the movement of dividing vanes in the radial grooves of the cylindrical rotor, as well as the phenomenon of jamming of hinges and blades, taking place at high friction coefficients.

This is observed as a result of deviation of the hinge surface profile interacting with the surface of the rotor groove, which can occur when the rotor is elongated, which is necessary to achieve these goals, as a result of deformation of the blade vanes.

In addition, the technical embodiment of such a design requires the use of certain structural methods due to the fact that the axis located in the hollow rotor and on which the blades are mounted is nevertheless fixed on a fixed casing.

This complicates the design of the machine as a whole.

The task to which the claimed utility model is directed is to create a rotor-vane machine that provides a qualitative improvement in operational characteristics and an increase in the productivity of the rotor-vane machine while increasing its resource.

The technical results obtained from the implementation of the claimed utility model include improving the reliability of a rotor-vane machine by preventing jamming of interacting elements of the rotor-vane mechanism, reducing friction in the working surfaces of friction, reducing general mechanical losses and, as a result, reducing pneumohydraulic losses of the rotor machine and increase its efficiency (efficiency).

The problem is solved, and the technical result is achieved by the fact that, in the rotor-blade machine, having a fixed body with an internal cylindrical bore, forming the working chamber of the machine, and the windows for supplying and discharging the working medium in communication with the pressure and drain lines, respectively, are hollow a rotor with a drive and longitudinal radial profiled grooves with opposite concave arcuate surfaces mounted in a fixed housing eccentric with respect to the bore motionless of the hull, vanes with vanes having working and end surfaces, and mounted in hinges, which, in turn, have a plano-convex shape, the hinges being placed with the possibility of rotation in longitudinal radial profiled grooves of the rotor due to the interaction of their external convex surface with their opposite concave arcuate surfaces, according to the utility model, more than one inner cylindrical bore is made in the fixed body, forming the working chambers of the machine, with supply windows and water of the working medium in communication with the pressure and drain lines, respectively, adjacent body bores are eccentric to each other, more than one cavity with longitudinal radial profiled grooves with opposite concave arcuate surfaces is made in the cylindrical rotor, and each of the cavities of the cylindrical rotor is aligned with its corresponding internal with a cylindrical bore of the fixed body, while the eyes of the blades are placed inside the rotor cavities and mounted on axes coaxial to the axes each of the inner cylindrical bores of the fixed body, and made, in turn, in the form of a single crank, the axes of which are relative to the adjacent parts of the crank coaxially to the axes of each of the inner cylindrical bores of the fixed body.

The axes of the spikes extreme with respect to the entire crank of it can be installed in the hollow cylindrical rotor and so that the axis of the corresponding spike is coaxial with the axis of the hollow cylindrical rotor.

The spikes, extreme in relation to the entire crank, can be installed in a hollow cylindrical rotor with the possibility of sliding in it.

At least one longitudinal recess can be made in the inner cylindrical bore of the stationary body, and in this case, it can be made with a cylindrical surface

The utility model is illustrated by drawings, where,

Figure 1 shows a side section of a rotary vane machine.

Figure 2 is a section aa of Figure 1.

Figure 3 is a section bb In Figure 1.

Figure 4 is a section CC of Figure 1.

Figure 5 shows a side section of a rotor-blade machine according to claim 2 of the formula of the utility model.

To increase the reliability of the rotor-blade machine by preventing jamming of interacting elements of the rotor-blade mechanism, reducing friction in the working surfaces of friction, and reducing the general mechanical losses in the claimed utility model, the following complex technical solutions were applied.

The rotor-blade machine has a fixed housing 1 with an inner cylindrical bore 2, forming the working chamber of the machine, and the windows for supplying 3 and outlet 4 of the working medium in communication with the pressure and drain lines, respectively (not shown).

A hollow cylindrical rotor 5 with a drive (not shown) and longitudinal radial profiled grooves 6 with opposite concave arcuate surfaces is mounted in the fixed body 1 eccentrically with respect to the bore 2 of the fixed body 1.

Working blades-blades 7 with eyes 8 are installed in hinges 9 having a flat-convex shape.

The hinges 9 are placed with the possibility of rotation in the longitudinal radial profiled grooves 6 of the hollow rotor 5 due to the interaction of their external convex surface with their opposite concave arcuate surfaces of the profiled grooves 6.

In the fixed housing 1, more than one inner cylindrical bore 2 is made, forming the working chambers of the machine, with windows for supplying 3 and outlet 4 of the working medium in communication with the pressure and drain lines, respectively.

Adjacent bores 2 of the housing 1 are eccentric to each other.

In a cylindrical rotor 5, more than one cavity 10 is made with longitudinal radial profiled grooves 6 with opposite concave arcuate surfaces.

Each of the cavities 10 of the cylindrical rotor 5 is combined with the corresponding inner cylindrical bore 2 of the stationary housing 1.

The eyes 8 of the blades 7 are placed inside the cavities 10 of the rotor and mounted on the axes 11, coaxial to the axes of each of the inner cylindrical bores 2 of the stationary body 1

The axis 11 is made together in the form of a single crank, the axes of which, in turn, with respect to the adjacent parts of the crank are aligned with the axes of each of the inner cylindrical bores 2 of the fixed housing 1.

The axis 12 of the extremes with respect to the entire crank of its spikes is mounted in the hollow cylindrical rotor 5 and so that the axis 12 of the corresponding spike is aligned with the axis of the hollow cylindrical rotor 5.

The spikes, extreme in relation to the entire crank, are installed in the hollow cylindrical rotor 5 with the possibility of sliding in it.

In the inner cylindrical bore 2 of the fixed housing 1, at least one longitudinal recess 13 is made, and in this case, it is made with a cylindrical surface.

Rotor-blade machine operates as follows.

The working medium moves from the inlet window 3 to the outlet window 4 (see arrows in Fig. 2) by the blades 7, which make reciprocating movements relative to the rotor 5 when it rotates, moving forward and backward from the hinges 9 in which they are placed with or without a gap but with the ability to slip.

To improve performance by increasing the length of the rotor 5 and reliable operation in a wider range of parameters by reducing the pneumohydraulic and mechanical losses during the movement of the blades 7 in the radial profiled grooves 6 of the cylindrical rotor 5, the axis 11 is made in the form of a crank not connected to the stator, and the crank spikes 12 are installed in the rotor 5 coaxially to its axis with the possibility of sliding in the rotor 5.

This fixation of the axis 11 of the blades 7 in the elements of the rotor allows you to avoid skewing too long axis in case of cantilever fastening in the case like the prototype, and, if necessary, increase the length of the rotor, and also provides the possibility of supplying and removing rotational energy from both ends of the rotor 5.

Moreover, in order to further increase the productivity of the machine by increasing the length of the rotor, more than one inner cylindrical bore 2 is made in the fixed housing 1, forming the working chambers of the machine, with the windows for supplying and discharging the working medium in communication with the pressure and drain lines, respectively.

Direct “scaling” to achieve the claimed technical result at a fixed speed of the drive is not possible, because, while increasing the linear sliding speeds of the ends of the blades 7 along the cylindrical bore 2 of the housing 1, which increases the wear rate of the ends of the blades and (or) leads to the need lower working pressure.

A direct increase in the length of the bore 2 and the inner bore 10 of the rotor 5 will lead to a decrease in stiffness (increase in working deformations) of the joints 9, which will increase the wear and the likelihood of jamming of the mechanism. Thus, the task to increase the performance of the rotor-blade machine can be achieved by performing more than one bore 2 of the housing 1 and by performing more than one corresponding inner bore 10 of the rotor 5, for example, 2 bores 2 of the housing 1 and the corresponding inner bores 10 of the rotor 5, as shown in FIG. 3.

To unload the rotor 5 from the radial working pressure in the stationary housing 1, the inner cylindrical bores 2 can be made eccentrically, while the unloading of the rotor is as follows.

When the rotor 5 is rotated clockwise in the central cylindrical bores 2 of the housing 1, the windows for discharging the working medium 4 are located, for example, on the right and the pressure acts on the rotor on the right.

In the lateral cylindrical bores 2 of the housing 1 made eccentrically central (s) cylindrical (s) of the bore (s) of the window of the outlet of the working medium 4 are located, for example, on the left and the pressure force acts on the rotor on the left.

Thus, the radial pressure forces in the central part of the rotor, acting on the right, are largely compensated by the radial pressure forces on the ends of the rotor, acting on the left.

If the length of the eccentric bores 2 of the housing 1 is not critical for the rigidity of the crank 11, then the outer spikes 12 of the crank 11 can be made without support in the rotor 5. If the length of the eccentric bores 2 of the housing 11 is critical for the rigidity of the crank 11, then the outer spikes 12 of the crank 11 be made with support in the rotor 5.

At least one longitudinal recess 13 can be made in the inner cylindrical bore 2, which can be made with a cylindrical surface in order to clean the rotor 5, to supply lubricant or other purposes, while the axis 11, made in the form of a crank, holds the blades 7 through the eyes 8 from getting into the longitudinal recess (s) 13 and jamming of the entire mechanism.

A rotary vane machine can be manufactured using traditional structural materials in experimental or mass production.

Claims (5)

1. A rotor-blade machine containing a stationary body with an internal cylindrical bore forming the working chamber of the machine, and the windows for supplying and discharging the working medium in communication with the pressure and drain lines, respectively, a hollow cylindrical rotor with a drive and longitudinal radial profiled grooves with opposite concave arcuate surfaces mounted in a fixed body eccentrically with respect to the bore of the fixed body, blade vanes with eyes having working and end surfaces surface mounted in hinges, which, in turn, have a plano-convex shape, the hinges being rotatably rotated in the longitudinal radial profiled grooves of the rotor due to the interaction of their external convex surface with their opposing concave arcuate surfaces, characterized in that in the stationary housing is made more than one internal cylindrical bore, forming the working chambers of the machine, with windows for supplying and discharging the working medium connected to the pressure and drain lines, respectively Advantageously, the adjacent body bores are eccentric to each other, more than one cavity with longitudinal radial profiled grooves with opposite concave arcuate surfaces is made in the cylindrical rotor, and each of the cavities of the cylindrical rotor is aligned with the corresponding internal cylindrical bore of the stationary body, while the blade eyes are placed inside rotor cavities and are mounted on axes coaxial to the axes of each of the inner cylindrical bores of the stationary body and made x, in turn, to a single crank, the axis of which relative to the adjacent parts of the crank are aligned axes of each of the internal cylindrical bores of the stationary housing. 2. The rotor-blade machine according to claim 1, characterized in that the axes of the extremes with respect to the entire crank of its tenons are installed in the hollow cylindrical rotor so that the axis of the corresponding tenon is coaxial with the axis of the hollow cylindrical rotor. 3. The rotor-blade machine according to claim 1, characterized in that the spikes extreme with respect to the entire crank are mounted in the hollow cylindrical rotor with the possibility of sliding in it. 4. The rotary vane machine according to claim 1, characterized in that at least one longitudinal recess is made in the inner cylindrical bore of the stationary body. 5. The rotor-blade machine according to claim 4, characterized in that at least one longitudinal recess in the inner cylindrical bore of the stationary body is made with a cylindrical surface.