DE383599C - Auxiliary pulsator piston valve for milking machines - Google Patents

Description

GERMAN EMPIRE

ISSUED AL OCTOBER 15, 1923

REICH PATENT OFFICE

PATENT LETTERING

CLASS 45 g GROUP 3

(L 53737 Uli45g)

The De Laval Separator Company of New York, V. StA.

Auxiliary pulsator piston valve for milking machines. Patented in the German Empire on August 10, 1921.

According to the Union Treaty of June 2, 1911, priority is due to this application of the application in the United States of America dated February 18, 1921.

The invention relates to milking machines in which a positively actuated Main pulsation valve causes pneumatic pulsations in a pipe in turn either a single pulsator

valve on the milking machine unit for the purpose of generating pneumatic pulsations in the to bring about the line leading to the teat cups or actuate an auxiliary pulsator valve, to avoid pneumatic pulsations in an auxiliary

to generate line. Such auxiliary valves and auxiliary lines are also used. to transmit pulsations to a single pulsator valve of a milking machine unit.

Both the aforementioned pulsator valve and

also the auxiliary valve can be viewed as auxiliary pulsators by their effect pneumatically through a line of one

ίο main pulsator is regulated.

The main pulsations are generated by connecting the main pulsation line to the External kift and generated with a partial vacuum. The mentioned auxiliary pulsators are by means of a stepped piston through the action of atmospheric pressure, one partial Vacuum and pulsation. When the pulsation wave after about one Line is equally divided between the atmospheric line and the vacuum line runs, the effect of the auxiliary pulsator will be such that equal pauses at the end each of the two strokes will occur, and the vacuum and outside air waves will be of equal length. This is an essential one Requirement in particular where the individual pulsator, which is part of the milking machine unit forms, is arranged to operate two pairs of teat cups alternately, one pair with the outside air and the other is connected to the vacuum at the one hub, while the ver j bindings are reversed in the other case. It is evident that if the j Vacuum waves and outside air waves are of different lengths, the way the j both milk sets will be unequal. j To get the air out of a pipe: to convey a longer time is necessary j than to fill this pipeline, and each ι farther from the main valve the observations are made, the greater is for that reason the twisting of the pulsation wave. As a result, the ι Auxiliary pulsators of known design are known not to have pulsations with air waves and vacuum waves of equal length. In other words, it becomes unbalanced Waves formed. The difference in known systems can be so considerable that the usefulness of the system is thereby considerably reduced.

According to the invention, an auxiliary coil comes

sator for use when it is actuated by a primary shaft, even if this is not balanced, creates auxiliary waves that are almost balanced.

The innovation is accordingly that

in the auxiliary pulsator piston valve of the milk machine, in which a valve alternately connects the auxiliary pulsation line with the vacuum line and the outside air and a main pulsation line is arranged so that the pressure on one end of the valve piston results in its control in both directions, a control air chamber for is provided between the chamber and the Hauptpulsationsleitung influencing the Druckeis of \ ^T entilkolbens at the other end, and a connecting path, whereby the absolute pressure in the chamber to such an intermediate height between the limit pressures of the pulsations is held that the Hilfspulsationsleitung for approximately equally long periods is kept in contact with the vacuum and with the outside air.

A pneumatically operated device for balancing the valve piston weight can be used and to counteract the inclination of the piston, longer at the bottom than at the top; to remain, to be harnessed. ! In the drawing, an embodiment j of the invention is shown, for example, and although is

Fig. Ι a cross section through the auxiliary valve,

'■ Fig. 2 illustrates in a sectional view and in enlarged scale the upper end of the piston and cylinder.

α denotes the valve housing, which has five annular spaces b, c, d, e and f which surround a cylinder g in which a piston goes up and down. This entilkolben \ ⁷ has two hollow cylindrical parts / and j, which are interconnected by a neck. A bore χ runs in the longitudinal direction through this neck and forms a close connection between the hollow cylindrical ends.

The annular space b is in free communication with the lower end of the cylinder g and with the main pulsation line /. The space c communicates with the outside air through a filter m and with the interior of the cylinder g through a duct η. The space d is in communication with one or more auxiliary pulsation tubes 0 and through a channel p with the interior of the cylinder g. The space e is in communication with the vacuum tube r and through a channel s with the interior of the cylinder. The space / communicates with the upper end of the cylinder g through channels t.

^{A chamber α 1} is located above the cylinder and in free communication with its interior, but separated from the space f by a plate u which has a soft surface. The upper end of the piston has an annular rib ν of a smaller diameter than. the piston which, when it is at its upper end of its stroke, comes into contact with the soft support of the plate 11

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and the chamber f and an annular space above the piston closes off from the central part of the cylinder. When working, the main pulsation is transmitted to the lower end of the cylinder. Through the bore χ , this lower space of the cylinder is in free, albeit throttled, connection with the Kammerze /. The latter is so large with respect to this bore χ that pressure changes in the pulsations are not transferred to it. The pressure in the chamber is almost uniform and has a value halfway between the extreme limits of the pulsation wave. When a high pressure wave comes from the pipe I , the piston moves upwards. If there is a low pressure wave, the piston moves towards the bottom.

The pneumatic forces are such that, if the weight of the piston were not present, the upward and downward strokes would be of equal duration. However, the weight of the piston has the consequence that it will stay longer at the bottom than at the top. When the piston is at the upper end, the rib ν contacts the underside of the plate u and closes the space / and the annulus above the piston and outside the rib from communication with the interior of the piston and the chamber w . However, the leakage around the piston, which never closes completely tightly, towards the vacuum channel s reduces the pressure in the chamber f and on the annular surface outside the rib ν sufficiently to counterbalance the weight of the piston.

When the piston is in its lower position, the air has access to the auxiliary pulsation tubes 0 through the sieve m, the chamber c, the channel n, the groove k, the channel p and the chamber d. When the piston is in its upper position, air escapes from the tubes 0 through the chamber d, the channel p, the throat space k, the channel s and i the chamber e to the vacuum tube r.

The auxiliary pulsator thus generates a balanced auxiliary pulsation regardless whether the main pulsation is balanced or not.

In the exemplary embodiment, the auxiliary valve is used to generate auxiliary pulsations in a pulse line or in several such lines at the same time. The invention but is not limited to such a device, rather it also includes one any arrangement of channels and chambers for generating pulsations alternately in one and in the other of two Auxiliary pulsation lines.

In the description is of a 'connection speaking with the outside air and with a vacuum, these expressions close but also all degree differences in the absolute pressure.

Claims (3)

Patent Claims: 1. Auxiliary pulsator piston valve for milking machines, in which a valve alternately connects the auxiliary pulsation line with the vacuum line and the outside air and a main pulsation line is arranged to control the pressure on one end of the valve piston • in both directions, characterized by a control air chamber (w) to influence the pressure at the other end of the valve piston and a narrow connection path (x) between the chamber (w) and the main pulsation line (I). 2. auxiliary pulsator piston valve according to claim i, characterized by a pneumatically controlled device for balancing the valve piston weight and counteracting the tendency of the piston to stay longer below than above. 3. auxiliary pulsator piston valve according to claim, characterized by a relatively small one in connection with the upper end of the valve cylinder on the circumference standing air chamber (/) with a leakage path to the vacuum connection and a device at the end of the piston, which then, when the piston reaches the end of its upward stroke, the connection between the two air chambers. 1 sheet of drawings.