SU41782A1 - Method and device for milking dairy cattle - Google Patents

Description

This invention relates to a method for milking dairy cattle and a milking tool. The proposed milking method, carried out by means of a two-chamber teat cup, consists in the fact that in order to create normal conditions for nipple rest, besides the usual two milking cycles (sucking, compression), a third intermediate rest stroke is introduced, during which atmospheric nipples are supplied air.

To carry out these three strokes in an ordinary push-pull milking machine with a two-chamber teat cup, the milk collection fork is replaced by a distribution device in which the nipple approaches the normal ones to create conditions for periodic rest by completely communicating with the atmospheric air, the cavity of the distribution body is equipped with two elastic membranes mounted on a vertically moving rod with a channel for the passage of atmospheric air. One of the membranes is made larger in size and length (295)

A dispenser for disengaging the teat cup with the hearth, together with another diaphragm, also designed to control the air inlet, in order to realize a more late supply of atmospheric air under the teat into the inter-chamber space of the teat cup.

The drawing shows a distribution device in vertical section, which performs three-stroke operation of the milking machine.

A conventional two-chamber milking cup of a two-stroke milking machine consists of a metal sleeve 38 and a tubular rubber 37 located inside it. At the upper end of the milking cup there is a rubber seal 39 for keeping the glass from falling off from the nipple. Two rubber tubes are attached to the teat cup, of which tube 12 serves to apply a periodic vacuum under the cow's nipple, and tube 2 to bring alternating vacuum into the inter-chamber space 36 to compress rubber 37.

In a two-stroke machine during milking, there are two strokes - sucking and compression. Both cycles of their actions are equal every 50 / o pulse time. In addition to these two cycles, the proposed milking method introduces a third intermediate rest stroke, during which atmospheric air is supplied to the nipples. At the same time, as in a conventional push-pull machine, the first beat is equal to 50% of the pulse; the second cycle — compression — also does not differ from the compression cycle in a two-chamber machine, due to the fact that there is a vacuum in the inner chamber, and an atmosphere in the inter-chamber space, but in time the compression stroke in the proposed method proceeds only 10% of the pulse time, and in conventional two-chamber machines 50% of the pulse. By reducing the time of the squeeze cycle, a heart rate of 40 ° / o of heart rate is entered. This beat is characterized by the application of atmospheric pressure under the cow's nipple and into the inter-chamber space.

The cavity of the distributor housing is provided with two elastic membranes 5 and 7, mounted on the rod 15, which can move in the vertical direction. The membrane 5 is made larger and eaten ;, it is used to divide the teat cup with blueberry. The diaphragm 7 is designed to control the air intake in order to achieve a more late supply of atmospheric air under the nipple, rather than into the inter-chamber space of the teat cups. For passage of atmospheric air, the rod 15 is provided with a channel 8.

The action of the switchgear is as follows. During the sucking stroke, the milk from the teat cup enters the rubber tube 2 into chamber 3. It then flows through the annular opening 4 to the rubber membrane 5, from where it passes through the tube 10 into the hose 21 and then into the milking bucket. From the pulsator, located on the tube 17, a variable vacuum flows into the chamber 18, and from there through the tubes 14, 19 and the rubber hose 12 into the inter-chamber space 36 of the teat cups. When the pulsator forms a vacuum in chamber 18, this will correspond to the first beat of the pulse, i.e. sucking. At this time, the membrane 5, having the same vacuum on both sides, will be in a free state. The membrane 7 will have atmospheric pressure from above and a vacuum from below, so that the rod 15 connected to both membranes will experience pressure from top to bottom, so that it will take down the lower position at which channel 8 connecting the atmosphere with chamber 3 will be blocked . The lowered membrane 5 allows the milk to flow freely through the opening 4 of Chamber 3 into chamber 13. Thus, during the stroke of the cow's nipple, as well as in chambers 18, 13 and 3, there is a vacuum.

The next compression stroke occurs during the period when the vacuum in chamber 18 is changed to atmospheric pressure. Atmospheric pressure in chamber 18 is not singing immediately. The transition from vacuum to full atmosphere takes about B 0.1 seconds. During this transition, the membrane 5 begins to rise up and, reaching the edges of the hole 4, will block it and thereby separate the chamber 3 from the chamber 13. The membrane 5, lifting up, moves also the rod 15 connected to it upwards, thanks to which the chamber 3 through hole 6 and channel 8 are connected to the atmosphere. Channel 8 has a diameter of 2 mm, which is quite enough to quickly fill the chamber 3 with air and through the hose 2 of the chamber 35 under the cow's nipple, but the diameter of the channel 8 is not sufficient to reduce the vacuum in chamber 13 noticeably when the membrane is lifted up. As soon as atmospheric pressure is formed in chamber 3, and consequently, under the cow’s nipple in chamber 35, the nipple’s rest time begins. The rubber 37 of the teat cup, having experienced atmospheric pressure from the side of the chamber 35 and from the side of the chamber 36, will take a free position, giving rest to the nipple. Thus, during the rest tact, there is atmospheric pressure in chambers 18 and 3, and 13 vacuum in chamber.

The atmospheric pressure set in chamber 3 balances the pressure of the meme