CS18490A3 - Positive-displacement rotary sinusoidal pump - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a volumetric rotary sinusoidal pump with a sliding partition, in particular for pumping mixtures with the possibility of incompressible impurities.

There are known volumetric rotary sinusoidal pumps, which form a double sine wave, and the suction and discharge ports are separated from each other by a sliding partition with an inserted sliding sleeve. The pumps achieve relatively high performance, but they are not very advantageous in terms of lifetime. Over one revolution of the piston, the baffle performs two vibrations, limiting the speed of rotation of the piston and increasing the wear of the baffle. Pumps with a single sinusoidal piston have the advantage of problematic sealing of the suction space from the discharge, usually without check valves.

The aforementioned disadvantages are substantially mitigated by the invention, which is a rotary sinusoidal pump with a rotary sinusoidal piston and a movable partition, the cylindrical working chamber of which consists of a hollow body consisting of a chamber part which forms a casing and two opposing bearing parts which form a planar The circular base of the working chamber is based on the fact that the single piston stored in the working chamber in the shape of a low cylinder is formed by a cylindrical body, the height of which is equal to the height of the cylindrical worker and the piston collar wound on the shell of the cylindrical body, the penetration curve of the piston collar and cylindrical the body is an ellipse, which forms an angle of 25 ° to 35 ° with the working chamber axis, whose main axis is identical to the diagonal of the cylindrical axial section by the circumferential curve of the piston collar is an ellipse, whose main axis coincides with the diagonal axis of the cylindrical section in the working chamber and the outer axis coincide with the diameter of the cylindrical working chamber, wherein in each point of the penetration curve the piston collar is perpendicular to the shell of the cylindrical body, and in the chamber part of the hollow body forming the worker, the sliding groove is located on one side of the sliding groove. , a suction channel is formed and a relief channel is formed on the other side of the sliding groove with an outlet relief opening on the surface of the corona section, one of the bearing parts of the hollow body of the one side of the sliding opening being a continuation of the sliding groove formed in the working chamber base inlet a dispensing aperture that extends in the wall of the bearing portion as an angled displacement conduit with an outlet discharge aperture on the surface of the bearing portion, and a second, opposed, bearing portion has an inlet dispensing aperture 2 and a discharge conduit formed from the other side of the sliding aperture mirrored the outlet discharge holes lie in line with the outlet relief hole.

It is a further object of the invention that the suction channel has a circular inlet suction opening and the outlet suction opening is a triangular shape, the shape of the inner surface of the suction channel in the wall of the co-moral part being connected to the shape of the piston collar.

It is a further object of the invention that the inlet vent opening in the working chamber is rectangular with rounded corners.

Finally, it is an object of the invention that the movable partition has a cylindrical sealing sleeve rotatably mounted in the cylindrical groove with an axial slot for the piston collar.

The higher effect of the invention lies in the simple design of the use of suction or discharge valves. The shape of the piston collar curve allows for a good sealing of the slide valve in each of its positions, so that the suction and discharge spaces are not interconnected during the duty cycle and the pump performance is reduced. The pump is able to pump the medium containing even small non-compressible objects, because the shape of the piston collar curve allows them to be pushed into the discharge channels without the self-clamping braking of the piston by an uncompressible object, the pump being therefore, they are also very suitable for mixtures of food character. 1 shows an axonometric view of a partial cross section of the pump, FIG. 2 shows a partial cross-sectional view of the pump in a plane determined by the piston axis and the oscillating channels, FIG. Fig. 4 is a sectional view of the pump in the root determined by the partition and the rotor axis, i.e. in the plane AA of Fig. 3; 5 is a diagonal cross-sectional view of the full lid in place k '! FIG. 6 is a view of the bearing portion perpendicular to the base, FIG. 3 is a perspective view of the bearing portion perpendicular to the base, FIG. Fig. 10 shows a view of the chamber portion perpendicular to its axis, Fig. 11 shows a diagonal cross-section of the chamber portion in place of the sliding groove with the exposed outlet suction opening in a plane. FIG. 10, FIG. 12 is a view of a chamber portion perpendicular to the plane of the inlet opening and FIG. 13 is a view of the chamber / portion perpendicular to the plane of the outlet port, FIGS. FIGS. 16 and 17 show a straight and axonometric view of the sealing sleeve and FIG. 18 a direct view of the piston with the shaft and FIG. Figure 20 shows a section of the pump in a plane perpendicular to the partition defined by the longitudinal axis of the partition, that is to say in the plane B-S of Figure 4.

The pump housing according to the invention is formed by a hollow body 1, which is closed from one side by a full lid 41 and from a second side, in the direction of drive of the piston 2, by a through lid 42. The hollow body 1 consists of a chamber part 2 which forms a low-chamber working chamber housing in its cavity. cylinders and bearing parts 3 * which form the base 32 of the working chamber 21d in the chamber part 2 of the body 1, the cylinder of the working chamber 21 sliding 2 of the sliding groove 22mory 21 formed the outlet suction side of the sliding groove 22 is in the housing of the working chamber 21, is formed in parallel with the indentation 22 for receiving the partition 8. is a cylindrical working opening 231 of the suction channel 23 in the housing and an inlet relief opening 241 of the relief channel 24 formed of the second chamber of the working chamber 21. The outlet suction opening 231 is triangular shape and the continuing suction channel 22 extends into the inlet wall in the chamber section wall 2 suction hole 232 of circular shape. The rectangular inlet relief hole 241 with rounded corners and the relief channel 24 pass through the wall of the chamber portion of body 1 until the outlet relief hole 242 on the surface of the chamber portion 2 retains this shape. The bearing portions 2 of the hollow body 1 abut both sides of the chamber portion 2 and form planar circular bases 32 of the personnel of the chamber 21. A bearing recess 35 is provided in the center of the annular bases 32 to receive the bearings 33 of the piston 2 and the gaskets 34. The sliding groove 22 which is formed throughout At the height of the working chamber 21, at the point of contact with the bearing parts 2, the sliding opening 31 passing through the bases 32 passes through the walls of the bearing parts 2 of the housing 1. From one side of the sliding opening 31, an inlet discharge opening 361 is formed in the base bearing part 2, which continues in the - 4 - wall of the bearing part 2 as the angled discharge channel 36 with the circular outlet outlet opening 362 on the bearing part 2 surface. a discharge port 361 and a discharge channel 36 formed mirror-like. The outlet discharge orifices 362 are located on the surface of the body 1 in a straight line with the outlet relief hole 242. The full lid 41 and the through lid 42 abut the inner surfaces 44 to the circular annular bases 32 of the bearing portions 2 in both sides. a sliding recess 43 ' is formed by the two lids 41, 42, which is a continuation of the sliding opening 31 in the bearing portion 2 and the sliding groove 22 in the chamber portion 2 of the body 1. The rotor shaft 51 is supported by the through lid 42, which carries the piston 2 ' 1. The piston 3 is formed by a cylindrical body 52 whose height is equal to the height of the cylindrical working chamber 21, and the piston collar 53 wound onto the casing body 52. The ellipse is clamped with the axis by the penetration curve of the piston collar 53 and the cylindrical body 52. the working chamber of the 21 30 angle 30u whose main axis is identical to the diagonal of the axial incisor body The circumferential curve of the piston collar 53 is a lip whose main axis is identical to the diagonal axis of the cylindrical working chamber 21 and the minor axis coincides with the diameter of the cylindrical working chamber 21. a movable partition 8 is inserted in a position perpendicular to the surface of the cylindrical body 22 of the piston 2 of the sliding groove 22, of the sliding openings 31 and of the sliding protrusions 42, in which a cylindrical sealing sleeve 9, whose axis is perpendicular to the axis of the working chamber, is rotatably mounted in the cylindrical groove 81 21. A plunger collar 22 is inserted into the axial slot 91 in the sealing sleeve 9. As shown above, the outlet relief hole 242 and the two outlet discharge holes 362 are located on the surface of the body 1 in a straight line. The overlaps are the outlet orifice 6, the cavity of which connects the discharge channels 36 and the relief channel 24 to the annular outlet 6l. The inlet port 7, the cylindrical body 52 and the piston collar 53 are arranged upstream of the intake duct 23 and the working chamber 21 is divided into two portions divided by 4 into separate spaces which rotate about the axis of the working chamber 21 when the piston 2 is rotated. .

Each section has one discharge channel 36, the suction channel 23-5 and the relief channel 24 common to both parts. The parts of the worker 21 are alternately suction and discharge, and the movable tray 8 separates the suction and discharge spaces at each stage. Due to the location of the suction port 23 with respect to the two discharge ports 36, the suction and discharge spaces are not connected. During pumping, the outlet suction opening 231 is gradually exposed. The advancing piston collar 33 moves the partition 8 and increases the suction path advantageously with the sinusoidal half-wave. After the 90 ° piston collar 33 is rotated, the partition 8 is at one dead center, after 180 ° rotation when the intake space reaches the maximum volume, the partition 8 is at the second dead center and the inlet inlet 231 is closed. The inlet discharge orifice 361 begins to obscure and the working space, previously sown, now displacing, decreases. In the second part of the working chamber 21, the process proceeds in the same way, but is displaced by 180 [deg.], The second suction channel 23 is used, the pump according to the invention can be used not only for pumping pure media but also for mixtures of food character with incompressible additives.

Claims (3)

- 6 - PATENT CLAIMS \ t A rotary sinusoidal rotary sinusoidal pump with a movable partition, the cylindrical working chamber of which comprises a hollow body consisting of a chamber portion which comprises a housing and two opposing bearing portions which are formed. the flat circular bases of the working chamber, characterized in that the piston (5) housed in the working chamber (21) in the form of a cylindrical cylinder is formed by a cylindrical body (52) whose height is equal to the cylindrical working height the chamber (21) and the piston collar (53) wound on the housing of the cylindrical body (52), the penetration curve of the piston collar (53) and the cylindrical body (52) being an ellipse which forms an angle 25 with the working chamber axis (21) ° to 35 °, the main axis of which is identical to the diagonal axis of the cylindrical body (52) and the circumferential curve of the piston collar (53) is an ellipse whose major axis corresponds to the diagonal of the axial section a cylindrical working chamber (21) and a minor axis coincident with the diameter of the cylindrical working chamber (21), where each point of the penetration curve is a piston collar (53) perpendicular to the casing body (52) and in the chamber part (2) of the hollow body (1) the forming chamber of the working chamber (21) is from one side of the sliding groove (22) in which the partition (8) is mounted, the suction channel (23) is formed and the other side of the sliding groove (22) is provided with a relief channel (24) with an outlet relief opening ( 242) on the surface of the chamber part (2), one of the bearing parts (3) of the hollow body (1) having on one side a sliding opening (31) which is a continuation of the sliding groove (22) in the base (32) the working chamber (21) forms an inlet discharge opening (361) which continues in the wall of the bearing part (3) as a bent discharge channel (36) with an outlet discharge opening (362) on the surface of the bearing part ( 3), and the second, opposite, the bearing part (3) has an inlet discharge opening (361) and the discharge channel (36) formed from the other side of the sliding hole (31) mirror and outlet discharge holes (362) lie in line with the outlet relief hole (242). - 2. A rotary sinusoidal pump according to claim 1, wherein the suction port (23) has a circular inlet suction opening (232) and the outlet suction port (231) is triangular in shape, wherein the shape of the inner surface of the suction port (23) in the wall of the chamber part (2) is connected to the shape of the piston collar (53). - 7 - 3. A rotary sinusoidal pump according to claim 1, wherein the inlet relief opening (241) in the housing of the working chamber (21) is rectangular with rounded corners. The rotary sinusoidal pump according to claim 1, wherein the movable partition (8) has a cylindrical sealing sleeve (9) rotatably mounted in the cylindrical groove (81) with an axial slot (91) for the piston collar (53). Agent: