RU2147175C1 - Teat cup - Google Patents

Abstract

FIELD: agriculture, in particular, milking equipment. SUBSTANCE: teat cup has sleeve with boss and teat liner embraced with sucker. Teat liner is positioned within boss. Elastic membrane with openings is positioned within boss perpendicular to axial line. Membrane divides cavity within boss into two chambers. Central opening in upper chamber has diameter exceeding that of openings in membrane and sucker, and side openings in lower chamber are adapted for communicating with atmosphere. Sucker surface adjoining to membrane is provided with axial openings and is positioned for overlapping these openings with membrane in initial position of teat cup. When pressure in upper chamber of boss and in teat liner sucker is changed, teat cup performs vertical oscillating motions relative to teat with increasing frequency by the end of milking process. As a result, teat is weakened and lengthened to maximum extent to provoke milk-producing reflex. Such construction eliminates breaking of connection between teat and udder due to creeping of teat cup over teat. EFFECT: increased efficiency by providing full milking and eliminating necessity for manual stripping operation. 1 dwg

Description

 The invention relates to the design of machines for milking cows and, in particular, to milking cups of milking installations.

 Known two-chamber milking cups, including a sleeve, nipple cylindrical rubber with a suction cup [1].

 The disadvantage of such a teatcup is that during milking, the teats are significantly lengthened and the teatcups crawl onto the teats and udders of the cow. From this, the communication of the nipple with the milk tank is disrupted and the milking is interrupted prematurely, which causes unclean delivery of cows.

 Known for a milking cup, including a sleeve, a flat nipple rubber with a suction cup, in which a hole is made for communication with the atmosphere [2].

 The disadvantage of such a teatcup is that air constantly enters through the hole in the suction cup, and this reduces the vacuum under the nipple. As a result, the teatcups may fall off the nipples, as well as an increase in air flow and load on the vacuum pump.

 The closest in technical essence is the known milking cup, comprising a sleeve, a nipple cylindrical tube with a suction cup, a housing with an additional suction cup mounted coaxially on the sleeve [3].

 The main disadvantage of such a teatcup is the instability of work due to poor retention on the nipple. When the massage stroke from compression of the nipple rubber there is a buoyancy force, sometimes exceeding the suction. The teatcup is held mainly due to the frictional forces that occur at the places where the teats come in contact with the teat tube and the vacuum in the cavity of the suction cup, which expands the teat in this area. In this milking cup, air from the inter-wall chamber enters an additional suction cup, and from there, due to pressure differences, into the cavity of the main suction cup of the teat tube and further under the nipple, reducing the already low holding capacity of the milking cup. The milking cup falls off the nipple, because the friction force is not able to hold it due to insufficient friction area (the length of the nipple in the teat tube is small, since an additional suction cup takes up a considerable length of the milking cup).

 The objective of the invention is aimed at creating a milking cup, capable of providing clean milking with reduced labor costs for manual operations in accordance with the technology of machine milking.

 The technical result consists in creating a milking cup, which eliminates the violation of the message of the nipple with an udder due to crawling on the nipple.

 The technical result is achieved by the fact that in the teat cup containing a sleeve with a tide, inside which there is a teat tube with a suction cup covering it, in the tide of the sleeve, perpendicular to the center line, an elastic membrane with a hole is installed that divides the tide into two chambers, in the upper of which there is a central the hole is made with a diameter larger than the diameters of the holes of the membrane and suction cup, and in the bottom there are side holes for communication with the atmosphere, while the surface of the suction cup adjacent to the membrane is provided with an axial nymi holes and mounted to overlap them in the starting position the membrane cup.

 The drawing shows the proposed milking glass.

 The milking cup consists of a sleeve 1, inside of which a teat tube 2 is fixed using a cone 3 and a suction cup 4, in which holes 5 are made. In the upper part of the sleeve there is a tide 6, the inner space of which is divided by elastic membrane 7 into two chambers I and II. The outer diameter of the membrane has a girdle 8, which is rigidly fixed inside the wall of the tide 6, and the inner surface is freely adjacent to the suction cup 4 with the possibility of overlapping holes 5 in the initial position. The chamber I has an opening 9 made axially to the teat tube, the diameter of the opening 9 being larger than the inner diameter of the central opening of the suction cup 4. In the chamber II, there are side openings 10 connecting it to the atmosphere.

 A milking cup works as follows.

 When the milking cup is connected to the pulsator, collector and vacuum source after putting on the udder nipple, the milk removal process occurs as in a conventional two-chamber cup. Moreover, the surface of the hole 9 does not contact the surface of the nipple and the chamber I through the annular space is connected with the atmosphere, therefore, atmospheric pressure is established in the chambers I and II. The membrane 7 tightly overlaps the holes 5, since a vacuum is created inside the suction cup 4, which facilitates the nipple. As milk is dispensed and the nipple lengthens with a decrease in its diameter, a glass gradually creeps onto the nipple. The surface of the hole 9 abuts against the base of the nipple, thereby blocking the annular space connecting the chamber I with the atmosphere. The vacuum from under the nipple and the inner cavity of the suction cup penetrates into chamber I, which leads to a decrease in pressure in it compared to chamber II. From the pressure drop, the membrane 7 bends upward, and air from the chamber II passes through the gap between the surfaces of the suction cup 4 and the membrane 7 into the chamber I and through the holes 5 into the cavity of the suction cup 4 and then under the nipple. In this case, there is a decrease in vacuum under the nipple and a decrease in the force that contributes to the crawl of the teatcup on the nipple. As a result, the glass begins to move down from the base of the nipple. Chamber I through the formed annular space between the nipple and the hole 9 will connect with the atmosphere, the membrane 7 will again tightly block the holes 5 of the suction cup 4. Then the process will be repeated.

 The teatcup will make reciprocating (oscillatory) movements relative to the nipple with increasing frequency towards the end of milking, when the nipple relaxes and its maximum elongation. Oscillatory movements of the teatcup with the periodic release of portions of air inside the teat tube additionally irritate the nerve endings of the nipple and the udder, which stimulates the milk flow reflex, improves blood circulation in the nipple and eliminates the violation of the nipple's message with the udder. This contributes to the complete dispensing of milk and the elimination of manual milking operations from machine milking technology.

Sources of information:
1. V.F. Korolev Milking machines. - Engineering, 1969, p. 29.

 2. A.S. N 203372 Milking glass. - Publ. in B.I. N 20, 1967.

 3. A.S. N 1250223 Milking cup. - Publ. in B.I. N 30, 1986.

Claims (1)

 A milking cup containing a sleeve with a tide, inside of which there is a nipple tube with a suction cup covering it, characterized in that in the tide of the sleeve, perpendicular to the center line, an elastic membrane is installed with an opening that divides the tide into two chambers, in the upper of which the central hole is made with a diameter larger diameters of the holes of the membrane and suction cup, and in the bottom there are side holes for communication with the atmosphere, while the surface of the suction cup adjacent to the membrane is provided with axial holes and Credited with the possibility of overlap of their membrane in the initial position of the glass.