DE379451C - Interrupter for milking machines - Google Patents

Description

GERMAN EMPIRE

ISSUED
AUGUST 20, 923

REICH PATENT OFFICE

PATENT LETTERING

CLASS 45 g GROUP

(E 26011 IIIJ4sg)

Max Eickeraeyer in Berlin. Interrupter for milking machines.

Addition to patent 320159.

Patented in the German Empire on December 15, 1920. Longest duration: February 11, 1934.

Interrupter for sucking milking machines in which two moved by air pressure Organs control each other are known. From the well-known breakers of this type, the interrupter according to patent 320159 differs in that the two reciprocating piston valves that control each other are not articulated are connected to each other and are not moved by springs, but only

by air pressure. Interruptors of this type can only serve their purpose if in the Milk cups a sufficiently powerful suction effect during the individual pulsations is generated with sufficient duration.

This requirement is met with the present interrupter design. The breaker is only operated with suction air, the air pressures occurring lie between the to external air pressure, d. H. the pressure prevailing in the atmosphere (atmospheric pressure), and a suction pressure generated in a pipeline. Different types of execution such a breaker are shown in Figs.

Fig. Ι shows the interrupter housing α _Λ with two cylinders I) ₁ and C ₁ . A piston slide moves in each, which is formed by the rod Ci ₁ or C ₁ with leather sleeves f _v {„, f _s or ^ ₁ , g . The cuffs Z ₁ and g ₁ are used to control the channels Hi ₁ and W ₁ or ^ ₁ and Z ₁ . The interrupter is connected to the vacuum line through the nozzle 0 and with the atmosphere through the nozzle ρ as. The bores of the connection piece p are in each position of the slide between the sleeves f \ or gfj. The bores of the nozzles ο always open into the room parts ^ ₁ or g ₂ . The hose connectors r lead to the teat cups. Fig. Ι shows the large piston valve formed by rod (I ₁ in the middle position and the smaller piston valve formed by rod e _x in the right end position. In this position, the channel ^ ₁ opens into the space part q., Of the cylinder connected to the vacuum line C ₁ , while channel Z ₁ is in connection with that part of the space of cylinder C ₁ which is connected to the outside air by connecting piece P. Accordingly, the large piston valve of cylinder _{1 is} moved to the right from the position shown Cuffs f _t have released channels m _x and M ₁ , channel Ui _{1 is} connected to the vacuum line via space q _{± , channel K 1} to the atmosphere, and the small piston slide is pushed from the right end position drawn into the left end position The speed can be regulated by means of the screw S. As soon as the large piston valve has passed the central position on its way from left to right, the space ν is through d s channel Wi ₁ to the vacuum line and the space w by channel W ₁ with the atmosphere \ ^r Getting Connected. Due to the pressure difference thus generated in the spaces ν and w and due to the different cross-sectional areas of the collars f., And f ₃ , the movement of the piston valve to the right end position is supported. .

This pressure difference in spaces ν and w counteracts the backward movement of the piston valve from the right end position and only allows the large piston valve to move from right to left when the force acting on the piston ends is greater than the pressure difference in spaces ν and w, or if in the teat cup lines Y ₁ connected to the cylinder ends a sufficient pressure difference, that is to say also a sufficient suction effect, is reached. To prevent both piston slides from being in the middle position at the same time, the sleeves h and i are provided with beads that push an intermediate piece, which consists of two balls χ and a spacer sleeve, back and forth in the bore y when moving back and forth. The length of the spacer sleeve and the beads are dimensioned so that

h and i cannot be in the middle position at the same time. The sleeves s are firmly connected to the cylinder b _x . Fig. 2 shows the cross section through the middle of the interrupter housing O ₁ .

Fig. 3 shows another embodiment of the breaker. The housing a., Contains a large cylinder b., And two small c ₂ . In the large cylinder, a piston provided with four collars shifter operates d "and in. The two small cylinders each provided with a four 'cuffs spool e, j and e _3. The divided by the individual sleeves of the spool e "cylinder chambers provide with relevant, of \ the cuffs of the spool e ₃ off! divided spaces by transverse channels, which are not shown in j in the figure, in connection. The spaces enclosed by the cuffs f and g are constantly in contact with the atmosphere through nozzles p , the neighboring spaces q remain permanently connected to the vacuum line through nozzles 0. On the piston rod d ₂ is a driving cross member /; attached, by means of which the two small piston valves are dragged. The control channels are arranged in such a way that the piston slide d. ,, before it effects the reversal of the small slides e ₂ and e ₃ , which are under counterpressure, must drag them. In Fig. 3, the large piston valve is drawn in the middle position, with the sleeves / channels k “ and L covering. The left end of the cylinder b “is connected to the atmosphere through the channel JM ₂ and the right end through the channel M ₂ to the vacuum line. The large piston slide is therefore moved from the left to the right from the position shown, the driver h dragging the small piston slide e ₂ and e _3. As long as the great KoI

benschieber has not yet reached the central position, it releases channel I ₂ for the vacuum line and channel k ₂ for the atmosphere. As a result, the small piston valves e ₂ and e _{s were} pressed into their end position and can only be dragged by the driver h when the pressure on the large piston valve d " is sufficient to overcome the counterpressure on the two small piston valves ίο , or if a sufficient pressure difference, that is to say also sufficient suction, is achieved in the teat cup lines r ₂ connected to the end spaces of the cylinder b _2. Before the large piston slide has reached the 1 real end position, it drags the small piston slide into the right end position, whereby the channels, and n ₂ are reversed and the backlash begins again in the opposite direction. The air supply to the large cylinder can be regulated using the adjusting screws s. The hose connectors r ₁ , which are expediently connected directly to the channels m 2 ' and W ₂ , lead to the: teat cups.

Fig. 4 and 5 show an embodiment of the interrupter, which is characterized by particular simplicity, insofar as all movement processes take place within a cylinder. The cylinder contains a piston D with double collars G at the ends and a slide H with four collars which is not connected to the piston D. Through the connection P is the. space j partitioned off by the valve cuffs F is in contact with the atmosphere, while ^! the neighboring rooms Q through the Stut-! zen O are connected to the suction air line j. ■,

In Fig. 4 the slide H is drawn in the central position, through which it is removed from the piston D | is towed. In Fig. 4 there are! both pistons in their left end position, where <the channel K with the atmosphere and the; Channel L in connection with the suction air line | dung stands. The space T, which is enclosed by the cuffs G ₁ and G ₂ at the ends of the piston D , is: in Fig. 4 through channel K under the pressure of the outside air. The outside air reaches the left cylinder through the equalization duct M. end, while the right end of the cylinder through channel L connectedness with the suction air O, which is. As a result, the piston D is pushed from left to right until channel M ! is covered by the sleeves of the piston D. From this moment on, the left end space of the cylinder is closed and the amount of air contained therein expands as the piston movement continues. The length of this expansion path is chosen so that the piston slide D does not come to a complete standstill, but only its movement takes place slowly until the desired suction effect is achieved in the right erid space of cylinder A or until a sufficient pressure difference, i.e. also sufficient suction effect, is achieved in the teat cup lines R connected to the channels K and L. As soon as the cuff G _{1 of} the piston D has released channel M and outside air can enter the left end space of cylinder A through channel / C, the movement of piston D is accelerated and not interrupted even when the sleeve G ₂ at the other end of the piston covers channel N. The piston D finally encounters slide H and begins to drag it.,

Fig. 4 shows the slide H ₁ after it has been dragged into its central position. As soon as it has exceeded this central position under the action of the piston D , the channels K and L are reversed, after which the game begins again.

The screws 5 ¹ are also used here, as in the types according to Fig. 1 and 3, to regulate the piston movement. The path of the slide H is limited by a stop U.

Claims (3)

Patent Claims: 1. Interrupter for milking machines according to patent 320159, characterized in that that at least one of the control slide before it reverses, one of its direction of movement must overcome the opposite air pressure, which only after Beioo at the beginning of the reversal changes direction and supports the effect of the operating pressure. 2. Interrupter according to claim 1, characterized in that of two or more control slides working in separate cylinders of different cross-section, only the smaller cross-section is under counter pressure against which it is _{dragged by the other control slide by means of n 0} drivers. 3. L ^T nterbrecher according to claim 1, characterized in that two or more slide working in a cylinder such that the is an from the other overall ng drags. For this 1 sheet of drawings.