UA65351A - Milking apparatus - Google Patents

Abstract

A milking apparatus contains teat cups, hoses, a pulsocollector, in which an additional high-frequency pulser with a adjustment-free throttle is made, a working chamber of which is connected with interwall chambers of the front pair of the teat cups and a working chamber of the main pulser is connected with the interwall chambers of the second pair of teat cups of the rear teats of an udder and is connected with control chambers of the main and auxiliary pulsers through the adjustment-free throttles.

Description

The invention relates to agriculture, namely to machine milking of cows with milking machines with a pulse collector.

A well-known milking machine, which consists of milking cups, a collector, hoses, main and auxiliary pulsators, where in the control chamber of the auxiliary pulsator, with the help of filled liquid, the operating mode of machine milking is regulated (Ass. USSR Mo1660638, IPC AO125/04, 1991). But this milking machine causes a simultaneous effect of variable vacuum pressure on both the front and rear teats of the udder and does not ensure the simultaneous end of milking from the front and rear teats of the udder.

Also known is the milking apparatus, which consists of milking glasses, a collector, hoses, the main and auxiliary pulsators, in which there is a regulating throttle for changing the air flow into the working chamber of the pulsator (Ass. USSR Me1794418, IPC AO15/02, 1993). The disadvantage of the presented milking machine is the unresolved layout of the main and auxiliary pulsators, and the presence of throttling devices for air intake, which leads to the complexity of the design, the decrease in the reliability of the milking machine and the non-simultaneous end of milk removal from the front and rear teats of the udder, which can lead to "idle" milking hind udders and causing mastitis.

The closest in terms of technical solution and technical essence is the milking machine with a pulse collector designed by IMESG (Ukraine, Professor A.I. Fenenko, etc.), which consists of milking cups, hoses and a pulse collector. Hrytsaenko, I.A. Buzun, V.S. Shebelnychenko and others. -

K.: Urozhai, 1987. - P. 55-58), but the reduced milking apparatus causes it to be overstayed on the udder for full milk removal from the udder, "idle" milking of the rear teats, insufficient udder massage during milking and udder disease for mastitis and the duration of machine milking is extended.

The invention is based on the task of improving the milking apparatus in such a way as to improve milk output with the simultaneous termination of milk yield from the front and rear teats of the cow's udder due to their paired milking and variable mode of action on the front and rear teats, and as a result, to improve the massage of the udder during the milking process and direct the work of the milking machine so as to eliminate "idle" milking of the rear teats of the udder and to eliminate mastitis in cows and to ensure the speed and completeness of milk removal from the udder.

The task is solved by the fact that in the milking apparatus, which consists of milking cups, a pulse collector, hoses, according to the invention, an additional high-frequency pulsator with a non-regulating throttle is made in the pulse collector, the working chamber of which is connected to the interwall chambers of the front pair of milking cups for the front milkers udders and directs variable high-frequency vacuum pressure to the teat rubber during the suction stroke in them, ensuring the vibrating action of the teat rubber on the front teats, and the working chamber of the main pulsator is connected to the interwall chambers of the second pair of milking cups for the rear teats of the udder and is connected to the control chambers of the main and auxiliary pulsators through non-regulating throttles, providing paired milking of the front and rear teats of the udder.

In Fig. the proposed milking device with a pulse collector is schematically shown.

The milking machine consists of two-chamber milking cups 71, pulse collector 2, hoses.

The pulse collector has a housing 3, in the lower part of which there is a milk collector 4 with nozzles 5 for connecting to the milking chambers of the milking cups using the milk tubes of the milking rubbers, as well as a nozzle 6 for connecting the milk vacuum hose to the lid of the milking bucket or the milk vacuum line. A chamber 7 of constant vacuum pressure is created in the milk collector of the collector 4. The adapter 8 of the main membrane pulsator with a central hole for the passage of the rod 9 of the valve-membrane mechanism is placed in the lower part of the housing C above the milk collector of the collector 4. In the upper part of the adapter 8, an annular groove 10 is made, which forms a chamber 11 of constant atmospheric pressure, and a groove 12 is a working chamber 13 of variable vacuum pressure of the main pulsator. Chamber 11 of constant atmospheric pressure is connected to ambient air through drilling 14 and filter element 15. The ring channel 16 in the upper part of the adapter 8 is connected through the drilling 17, the nozzle 18 with the working chamber 13.

The membrane 19 of the valve-diaphragm mechanism is located above the grooves of the adapter, which is installed in the annular groove 20 of the rod 9. And in the lower part of the rod, there is a valve 21 for periodically injecting vacuum pressure from the constant vacuum chamber into the working chamber. The membrane 19 has a hole 22, which coincides with the annular recess 23 of the insert 24 and the annular channel 16 of the adapter 8. The annular recess 23 through drilling 25 and the annular groove 26, then the labyrinth channel 27 in the annular insert 28 is connected to the control chamber 29 of variable vacuum pressure, which is placed above the membrane 19. From the lower side of the membrane 19, the control chamber 29 of the main pulsator is connected to the working chamber 13 through the labyrinth channel 27 of the ring insert 28, the hole 22 in the membrane 19 and drilling 17 and the nozzle 18. The labyrinth channel of the main pulsator provides a constant frequency of pulsations (60-70 pulses per minute), which enters through two nozzles through rubber tubes 18 into the interwall chambers of the rear pair of milking cups. An auxiliary high-frequency pulsator, which has a valve-membrane mechanism with a rod 30, a membrane 31, which is included in the groove 32 of the rod, is placed above the main membrane pulsator in the housing C. The membrane 31 separates the chamber 33 of constant vacuum and the control chamber 34. The chamber 35 of constant atmospheric pressure of the auxiliary pulsator is located in the middle part of the housing 3, which is connected to chamber 11 of constant atmospheric pressure of the main pulsator.

Air from the chamber 35 periodically enters the working chamber 40 of the auxiliary pulsator when the valve 41 of the stem 30 of the valve-membrane mechanism is open. From the working chamber 40 departs two nozzles 42 of variable vacuum pressure, which are connected by rubber tubes to the interwall chambers of a pair of milking cups for the front teats of the udder (the figure schematically shows one milking cup per front and rear pair of udder teats, respectively). The working chamber 40 of the auxiliary pulsator is connected to the control chamber 34, which is placed under the cover 47, through the channel 43, the annular groove 44 and the hole 45 in the membrane 31 and further through the labyrinth groove of a small length on the flat ring 46. The working chamber 13 of the main pulsator and the chamber 33 of the high-frequency the pulsator is connected to each other through the channel 48, the annular groove 49, drilling in the flat ring insert 28 and drilling 25 and further through the hole 22 in the membrane 17 and the nozzle 18. In the lower part of the adapter 8 above the milk chamber 7, a rubber slotted valve 51 is fixed, which on the horizontal plane has slits for the passage of vacuum and preventing the spread of milk to the working chamber 13 of the main pulsator.

The milking machine works as follows.

When the nozzle 6 of the pulsator is connected to a source of constant vacuum pressure with a milk hose, for example to a milking bucket or a milk pipe, a certain amount of vacuum pressure is established in the constant vacuum chamber 7, which acts on the valve 21 and opens the path of vacuum into the working chamber 13 and through the nozzle 18 spreads along rubber tubes in the interwall chamber of the rear pair of milking cups. At the same time, the vacuum from the chamber 7 enters the milking chambers of the milking cups from the milk collector through the nozzles 5 and the milk tubes of the milking rubbers of the milking cups. As a result, a suction stroke is created in a pair of milking cups, which are worn on the rear teats of the udder. At the same time, air from the chamber 11 of constant atmospheric pressure of the main pulsator enters from the environment through the filter element 15, channel 14, then through channels 39, 36 through drilling 38 it spreads into the chamber 35 of constant atmospheric pressure of the auxiliary pulsator. From the chamber 35, air enters the working chamber 40, and from it through the nozzles 42, then through the rubber tubes into the interwall chambers of the front pair of milking glasses, which are put on the front teats of the udder. A compression stroke occurs in the front pair of milking cups. The rarefaction that passes through the labyrinth channel 27 of the ring insert 28, through drilling 25, ring grooves 26, 49, channel 48 enters the chamber 33 and acts on the membrane 31, forcing the rod 30 to descend. The valve 41 closes the air supply from the constant atmospheric pressure chamber 35, but opens the vacuum supply from the chamber 33 to the working chamber 40. Next, vacuum enters the interwall chambers of the pair of front milking cups through the nozzles 42 and rubber tubes from the working chamber 40, as a result of which the suction stroke occurs. But the vacuum from the working chamber 40 passes through the channel 43, the annular groove 44, the hole 45 in the membrane 31, the short labyrinth path on the flat ring 46 and will fill the control chamber 34 of the auxiliary pulsator. As a result, during the suction stroke in the front milking cups, air is directed from the chamber 35 of constant atmospheric pressure through the working chamber 43 into the interwall of their chambers, which quickly passes through a short labyrinth path in the auxiliary pulsator into the control chamber 34. That is, 6-10 times during the arrival of vacuum the valve-membrane mechanism of the auxiliary pulsator rises and falls in the chamber 33, opening during the suction stroke in the front milking cups air entering them and the teat rubber bursts, which causes additional irritation of the front teats of the udder. In the main pulsator, the vacuum passes from the working chamber 13 to the control chamber 29 through the drilling 17, the ring channel 16, the hole 22 in the membrane, the ring channel 23, the drilling 25, the ring groove 26, the labyrinth path on the ring insert. Due to the fact that the membrane 19 is larger in plane than the valve 21 and the atmospheric pressure of the air from the constant atmospheric pressure chamber 11 acts on it from below, the valve-membrane mechanism will rise to the upper position. From the chamber 11, under the raised membrane 19, air passes through the shoulder into the working chamber 13, which spreads through the nozzles 18, rubber tubes into the interwall chambers of the rear pair of milking cups, which causes a compression stroke. Air also spreads through the channels, the hole in the membrane 19 and the labyrinth path into the control chamber 29 of the main pulsator and the cycle of the milking machine is repeated again, because the stem 9 of the valve-membrane mechanism will lower again due to the action of the vacuum from the milk chamber 7. The technological process of the milking machine is given in the table, where the following designations of chambers are adopted: Main pulsator: I - chamber 7 of constant vacuum pressure; PI - working chamber 13; PI - chamber 11 of constant atmospheric pressure; IM - control camera 29.

Auxiliary pulsator: Id - chamber 33 of constant vacuum; IId - working chamber 43; Under - chamber 35 of constant atmospheric pressure; IMD - control camera.

The vibrating action of the teat rubber in the front milking cups causes additional irritation of the front teats of the udder. In the front teats of the udder, a faster milking is created, which ends synchronously with the milking of the rear teats, in which the usual irritation is performed, but paired milking with the front teats. Paired milking of the front and rear teats with high-frequency oscillation of the teat rubber in the front pair of milking cups during the suction stroke improves the machine milking mode. In addition, milk extraction is carried out alternately - from only two teats at the same time, which eliminates the overflow of the milk collecting chamber of the collector and stops the reverse flow of milk into the main pulsator and milking cups, improving the evacuation of milk. The proposed mode of operation of the milking machine provides active massage of the udder due to alternate milking of the front and rear teats due to the oscillation of the front and rear quarters of the udder and creates a simultaneous termination of milk flow from the udder teats, eliminates "idle" milking of the rear teats, prevents udder mastitis. Alternating milking of two udders leads to a calmer milk release, provides an automatic mode of changing the effect of the vacuum pressure over the surface of the milk in the collector's milk tank to the operation of the valve-membrane mechanisms of the main and auxiliary pulsators, ensuring a stable and calm selection of milk from the udders.

Table

Scheme of operation of the milking machine

Rear | Front pair pair of glasses) glasses | poddiykova| interstitial| poddiykova| interstitial| And | "| | M du du under | IMdi

Suction Squeeze | 0 | 0 | 0 | « |o010|h-1/:/|0 (Compression |Suction| 0 | «x | 0 | o |01/5|-1 01 o0|0| «| h

Designation: "0" - rarefaction in the chamber; "-" - air in the chamber with atmospheric pressure.

! | - ! Shy r / Y t ge Their 11 ik. I !

E Z x Uh Mlk z i | | and in / and n and ОЙ I

E i GKU ri Ky

NVK is

Tires BY and tires and Shik and VADA / and I KH v nena nn M shen M zhe i i

And the moss is blowing. s i I -u Fo: Wed Zo her t /

Heh with her Fo ke shi what

Ach EK Met rt en / p 0 By, tn SCHO a o

Fan chi mice STILL I know them

Sun shk r 5 Mol ke pa os Za u y Vie h yo

WE

7h and a kt ; AND I

ШЧе боти уого осомін ше - еа а Еал т Шче па I Дню реншу | / y k- And y y ek y zh pi in Mn is visible

DG

Claims (1)

A milking machine containing milking cups, hoses, a pulse collector, which is characterized by the fact that the pulse collector has an additional high-frequency pulsator with a non-regulating throttle, the working chamber of which is connected to the interwall chambers of the front pair of milking cups for perception of variable high-frequency vacuum pressure by milking rubbers during tact suction in them to create a vibrating action of teat rubber on the front teats, and the working chamber of the main pulsator is connected to the interwall chambers of the second pair of milking cups of the rear teats and connected to the control chambers of the main and auxiliary pulsators through non-regulating throttles.