RU50078U1 - PULSE COLLECTOR OF THE MILKING MACHINE - Google Patents

Abstract

The utility model relates to agriculture, in particular to the pulsator of milking machines. The objectives of the utility model is to improve the milking mode and increase operational reliability. The problem is solved in that in a pulse collector containing a housing with nozzles in which there are constant and variable vacuum chambers and a control, a cover having an opening, spring-loaded hollow stem and valve, the valve being located above the cover, and the upper part of the rod placed in the opening of the cover, the cover is provided the piston mounted on the rod, the housing is equipped with four float chambers with drain and bypass holes and floats, on the side surface of which grooves are made. Bypass holes are made on the side surface of the float chambers and are located at the level of the nozzle holes. The housing is equipped with a partition for closing the float chambers, while the partition has openings. The claimed design of the pulse collector protects the nipples of the udder of the animal before and after milk transfer, as well as during milking of the animal, increases operational reliability, is technologically advanced to manufacture.

Description

The technical solution relates to agriculture, in particular to the pulsator of milking machines.

A known pulse collector of a milking machine comprising a milk collection chamber communicated by a channel with a pulsator, a collector, the housing of which is equipped with four milk reception chambers isolated from each other, with conical float valves placed in them, the upper cylindrical part of which is placed in the guides, is located above the holes of the milk pipes, and bypass holes [1] are made in the bottom of the milk reception chambers.

The disadvantage of such a pulse collector is the complexity and low-tech design since guides ensuring the performance of conical float valves complicate the design and at the same time create difficulties during washing.

Another disadvantage is that the pulse collector is not reliable in operation. when the drain hole is clogged in the milk receiving chamber, the vacuum does not enter the nipple and milking may not start.

In addition, in the known pulse collector, the conical part of the float valve located in the bypass hole constantly seeks to block the passage section of this hole, due to which milking can cease prematurely with insufficiently intense milk transfer.

Known pulsator milking machine, comprising a housing,

equipped with a cover having an opening and nozzles in which a membrane is connected connected to a spring-loaded hollow stem having a spring-loaded valve located above the cover, the upper part of the rod is placed in the opening of the cover, in the housing there are also constant and variable vacuum chambers and a control chamber. [2].

The disadvantage of the pulse collector is that it does not protect the milky nipples of the udder of the animal from a working vacuum, i.e. overexposure of teatcups after cessation of milk flow is not excluded.

Another disadvantage is the unreliability in operation, since with the destruction of the membrane the pulsation stops.

In addition, the spring installed in the housing is poorly washed and can serve as a source of pathogenic microflora.

The objective of the utility model is to improve the milking mode and increase the operational reliability of the pulse collector.

The problem is solved in that in a pulse collector containing a housing with nozzles in which there are constant and variable vacuum chambers and a control, a cover having an opening, spring-loaded hollow stem and valve, the valve being located above the cover, and the upper part of the rod located in the cover opening, the cover equipped with a piston mounted on the rod, the housing is equipped with four float chambers with drain and bypass holes and floats, on the side surface of which grooves are made. Bypass holes are made on the side surface of the float chambers and are located at the level of the nozzle openings. The housing is equipped with a partition for closing the float chambers, while the partition has openings.

The essence of the utility model is illustrated in the drawing, where

- figure 1 shows a diagram of the pulsator during the sucking cycle;

- figure 2 shows a diagram of the pulse collector during a rest cycle.

The pulse collector comprises a housing 1 with milk nozzles 2, a constant vacuum chamber 3 located between the housing 1 and the milk collection chamber 4, which has a milk outlet 5 and is connected to the housing 1 by a cover 6 with air tubes 7. The housing 1 is equipped with four float chambers 8 with them placed floats 9 having horizontal annular grooves 10. On the side surface of the float chambers 8, bypass holes 11 are made, located at the level of the holes of the milk pipes 2, and in the bottom of the float chambers 8 drain holes 12. The float chambers 8 and the constant vacuum chamber 3 are closed by a partition 13 having an opening 14 located above the float chambers 8 and an opening 15 located above the constant vacuum chamber 3. In the cover 6, connected to the upper part of the housing 1, there is a hollow rod 16, with a plate piston 17 fixed thereon, dividing the variable vacuum chamber 18 from the control chamber 19.

Along the perimeter of the hole 20 made in the cover 6, protrusions 21 are made between which a pin 23 is fixed, fixed in the spring 22, and connected to the hollow stem 16, while a valve 24 is located on the upper part of the spring 22, which is located above the protrusions 21 of the cover 6.

To prevent clogging of the drain holes 12 of the float chambers 8 and the holes 14 made in the baffle 13, the floats 9 have needles 25 placed in these holes with a gap, which ensures horizontal movement of the floats 9 in the float chambers 8 during milking.

To protect the valve 24 and to clean the air entering the pulse collector on the cover 6, a perforated cap 26 is installed, having a bolt 27, restricting the rise of valve 24 fixed to the spring 22.

To regulate the number of pulsations, the cover b is equipped with a pipe 28 in which a screw 29 is installed.

The pulse collector operates as follows.

When you turn on the pulsokollekotra from the chamber 3 of constant vacuum, the vacuum penetrates into the chamber 18 of a variable vacuum, and from the latter through the air nozzles 7 into the interwall chambers of the teat cups (not shown). At the same time, from the chamber 18 of variable vacuum, the vacuum penetrates the upper part of the hollow rod 16, attracting the valve 24 to it, and through the holes 12,14 and 11 made in the float chambers 8 and through the milk pipes 2, the vacuum penetrates into the suction cups of the milking parlors cups (not shown) and with a simultaneous discharge in both chambers of the milking cups, a “sucking” stroke occurs.

Under the action of the pressure difference in the control chamber 19 and in the chamber 18 of an alternating vacuum, the spring-loaded piston 17 mounted on the hollow stem 16 is lowered. And when lowering the piston 16 below the passage sections of the openings of the air pipes 7, air enters the inter-wall chambers of the milking cups from the control chamber 19, and vacuum enters the suction cups, due to which the nipple rubber compresses the nipple of the udder of the animal and a “compression” stroke occurs.

With lowering the upper end of the rod 16 below the protrusions 21 made in the lid 6, the spring-loaded valve 24 is released from the hollow rod 16, letting air into the chamber 18 of variable vacuum, and from the latter through the holes of the float chambers 8 into the suction cups of the milking cups, recreation".

With the penetration of atmospheric pressure into the chamber 18 of an alternating vacuum, under the action of the spring 22, the hollow rod 16 mounted on the piston 17, with the valve 24 rise. Moreover, the valve 24 rises to the stop in the bolt 27, and the stem 16, under the action of the lower part of the spring 22, approaches the valve 24, the latter is attracted to the stem 16 by the action of suction, the suction of air stops and the “sucking” stroke occurs.

At the beginning of milking at the lower position of the floats 9, vacuum is sucked

penetrates into the float chambers 8 through the hole 14 and through the non-density of the holes 12 and 11. From the float chambers 8, the vacuum penetrates into the suction chambers through the holes of the milk pipes 2, due to the deviation of the floats 9 from these holes. Moreover, the vacuum is formed small (gentle) but sufficient so that under the influence of intra-pressure pressure, the milk fills the float chambers 8.

With the filling of the float chambers 8, the floats 9 float with the annular grooves 10 located at the level of the openings of the milk pipes 2 and the bypass holes 11, after which milking occurs at nominal vacuum, and the main flow of milk is evacuated along the annular groove 10 through the bypass holes 11 into the chamber 3 constant vacuum, and from the latter through the milk branch pipe 5 into the milk wire (not shown).

With the end of the milk transfer, the float chambers 8 are gradually emptied through the drain holes 12, the floats 9 are lowered, reducing the cross sections of the bypass holes 11, the vacuum gradually decreases to gentle, individually for each nipple of the udder of the animal.

The proposed design of the pulse collector protects the nipples of the udder of the animal from the working vacuum before and after milk transfer. And during intense milk transfer, a nominal vacuum is maintained in the suction cups, since the valve is released from the rod and lets air into the float chambers at a given vacuum in a variable vacuum chamber, for example at 45:50 kPa, which eliminates the formation of a vacuum higher than the nominal under the nipples of the animal’s udder . At the same time, the pulse collector is reliable in operation, since the membrane is replaced by a piston, and the spring-loaded valve is protected by a perforated cap.

The claimed design of the pulse collector protects the nipples of the udder of the animal before and after milk transfer, and also during milking of the animal, increases operational reliability, is technologically advanced to manufacture.

Claims (3)

1. The pulsator of the milking machine, comprising a housing with nozzles, in which there are constant and variable vacuum chambers and a control, a cover having an opening, spring-loaded hollow stem and valve, the valve being located above the cover and the upper part of the rod located in the opening of the cover, characterized in that the cover is equipped with a piston mounted on the rod, the housing is equipped with four float chambers with drain and bypass holes and floats on the side surface of which grooves are made. 2. The pulse collector according to claim 1, characterized in that the bypass holes are made on the side surface of the float chambers and are located at the level of the nozzle openings. 3. The pulse collector according to claim 1, characterized in that the housing is provided with a partition for closing the float chambers, the partition having openings.