SE458817B - pulsator - Google Patents

Description

458 817 can only be made jerkily using shock-like axial forces.

In addition, the threaded bolt is not available during the operation of the pulsator, so the proposed solution for setting the beat number is only suitable for fixed presetting. The object of the invention is to provide a pulsator of the type described above, at which the desired speed can be set in a simple manner without disassembly of the pulsator.

This has been achieved in that the throttling channel is arranged as a ring segment channel on one side of an externally accessible, rotatable disc and that the ring segment channel is connected by a bore to the other side of the disc, which delimits the first damping chamber, and the disc with the ring segment channel abuts a flat surface in the pulsator housing and the ring segment channel are thereby connected to the channel opening into the flat surface.

By turning the disc, it becomes possible to change the effective length of the ring segment channel between the channel opening into the flat surface and the bore leading to the first damping chamber.

As a result, the flow resistance also changes and as a result the pulsator frequency.

Since the setting of the pulsator frequency is preferably to be carried out by a person skilled in the art, it has been arranged that the disc is provided with a cylindrical shoulder, which is mounted in a casing part forming the flat surface in such a way that grooves arranged in the shoulder become accessible from the outside by a tool. The setting of the disc is possible with this solution only with a special tool.

This can also be achieved in that the throttle channel is formed by a chamber between the tooth goose on a threaded bolt and the tooth bottom in a threaded bore, the length of the throttle channel being variable by changing an externally accessible threaded bolt screwing depth.

The accompanying drawing shows an exemplary embodiment of the invention, which will be explained in more detail below. Fig. 1 shows an axial section along the channel through an embodiment of the pulsator, and Fig. 2 shows a section A-A through the pulsator according to Fig. 1. Fig. 3 shows on a much larger scale the choke channel in the form of a threaded connection. 458 817 In Fig. 1, 1 is denoted by the pulsator housing, the damping chambers 2, 3 of which are connected to each other by the channel 4 and the choke point 7 formed by the choke channel 5 and the bore 6. The throttle channel 5 and the bore 6 designed as an annular segment channel are arranged in the rotatable disc 9, which abuts sealingly with the annular segment channel 8 against the flat surface 10. The disc 9 has a cylindrical shoulder 12 provided with grooves 11, which is mounted in a casing part 13 forming the flat surface 10.

The damping chambers 2, 3 are connected via membranes 14, 15, which are connected to each other by a rod 16, separate from the working chambers 17 and 18. To the rod 16 is attached a slide 19, which through the channels 20, 21, 22 causes the change of the pressure in the teat cups (not shown) from negative pressure to atmospheric pressure in a manner known per se.

The two working chambers 17 and 18 are fed during operation of the pulsator alternately with negative pressure and atmospheric pressure, whereby by means of the membranes 14, 15 an axial movement of the rod 16 is obtained. The speed at which the rod 16 is thereby displaced is mainly dependent on the flow resistance, as well as the flow medium hermetically enclosed in the damping chambers 2, 3, must be overcome when switching from one damping chamber to the other. This flow resistance is predominantly determined by the throttle channel 5 at the throttle point 7, which is formed by the ring segment channel 8. By rotating the disc 9 and the associated angular displacement between the bore 6 and the channel 4, the length of the portion between the bore and the channel 4 can of the ring segment channel 8 changes, thus also changing the flow resistance at the throttle point 7. Since the flow resistance of a channel changes proportionally to its length, the new pulsator enables very sensitive and accurate settings of the pulsation frequency.

It can be seen from Fig. 2 how by turning the disc 9 the arcuate, effective length "L" of the choke channel 5 can be changed. 458 817 A further possibility for changing the effective length of the throttle channel 5 appears from the embodiment according to Fig. 3. The throttle channel 5 is here formed by the chamber 23 between the goose 24 on the threaded bolt 25 and the tooth bottom 26 in the threaded bore 27. By selecting the screw-in depth of the threaded bolt 25 sets the number of effective threads and thus the total length of the throttle channel 5 between the channel 4 and the bore 6.

Claims (3)

'458 817 Patent claims A pulsator for milking machines, in which the pulsation frequency is determined by the displacement of a hermetically enclosed amount of a flow medium between two attenuation chambers (2, 3) connected by a channel (7) connected to each other, which are limited each of the diaphragms (14, 15), and the throttle point (7) is formed by a throttle channel (5), the length of which is variable, characterized in that the throttle channel (5) is arranged as a ring segment channel (8) on one the side of an externally accessible, rotatable disc (9) and that the ring segment channel (8) is connected by a bore (6) to the other side of the disc (9), which delimits the first damping chamber (2), and the disc ( 9) with the ring segment channel (8) abuts against a flat surface (10) in the pulsator housing (1) and the ring segment channel (8) is thereby connected to the channel (4) opening into the flat surface (10). Pulsator according to Claim 1, characterized in that the disc (9) is provided with a cylindrical shoulder (12) which is so mounted in a housing part (13) forming the flat surface (10) that in the grooves arranged on the shoulder (12) become accessible from the outside by means of a tool. 3. Pulsator for milking machines, in which the pulsation frequency is determined by the displacement of a hermetically enclosed amount of a flow medium between two attenuation chambers connected by a channel provided with a restrictor, which are each bounded by a membrane, and the throttle is formed by a throttle channel , the effective length of which is variable, characterized in that the throttle channel (5) is formed by a chamber (23) between the tooth goose (24) on a threaded bolt (25) and the tooth bottom (26) in a threaded bore (27). ), the length of the throttle channel (5) being variable by changing a screw-in screw thread depth (25) accessible from the outside.