RU2111654C1 - Pulsator - Google Patents

Abstract

FIELD: agriculture, in particular, milking equipment. SUBSTANCE: pulsator has control chamber divided by flexible membrane into two parts. Vacuumized bellows is positioned in lower part of membrane, which is communicated with atmosphere. Pulsator automatically maintains pulsation frequency in milking unit at atmospheric pressure fluctuations, particularly, under mountainous conditions. EFFECT: increased efficiency, simplified construction and enhanced reliability in operation. 1 dwg

Description

 The invention relates to agriculture, in particular to pulsators for milking installations.

 Known pulsator, consisting of a housing with a control, constant and variable vacuum chambers, membranes and interconnected by a rod of the upper and lower valves [1].

 The specified pulsator does not provide a stable pulsation frequency in the milking machine with atmospheric pressure fluctuations, in particular in high altitude conditions.

 The closest technical solution is a pulsator, also consisting of a housing with a control, constant and variable vacuum chambers, a membrane and interconnected by a rod of the upper and lower valves, an adjusting screw of a special design [2].

 However, this pulsator does not provide a stable pulsation frequency in the milking machine when the atmospheric pressure fluctuates in automatic mode, but requires constant manual adjustment.

 The aim of the present invention is to eliminate the above drawbacks, preventing injury to the mammary gland of animals and increasing productivity during milking.

 This goal is achieved by the fact that the control chamber of the pulsator is divided by an elastic membrane into two parts, the lower of which is connected to the atmosphere and is equipped with a vacuum bellows installed in it.

 The pulsator device is shown schematically in the drawing.

 The housing 1, in which a constant atmospheric pressure chamber 17 is separated from the control chamber 2 by an elastic membrane 3, in which a vacuum bellows 5 is located, to which an elastic membrane 3 is pressed. The constant atmospheric pressure chamber 17 is connected by an opening 4 to the atmosphere. The constant vacuum chamber 6, separated from the control chamber 2 by an elastic membrane 7, has a constant vacuum pipe 8, and there is a lower valve 10 connected by a rod 9 to the upper valve 11 located in the variable vacuum chamber 14. There is also a channel 12 in the housing 1 in which the adjusting screw 13 is installed. The variable vacuum chamber 14 has a nozzle 15 and an opening 16 that communicates this chamber 14 with the atmosphere.

 The proposed pulsator operates as follows.

 Using the adjusting screw 13 in the pulsator, the optimal ripple value is set. At this point, the evacuated bellows 5 and the elastic membrane 3 occupy the lowest position. The constant vacuum created by a vacuum pump (not shown) in the nozzle 8 and the constant vacuum chamber 6 acts on the elastic membrane 7, moves up the lower valve 10, the rod 9 and the upper valve 11, closing the hole 16. In this case, the chamber 14 is disconnected from the atmosphere and connected to a constant vacuum chamber 6, from which the vacuum propagates in the pipe 15, channel 12 and in the control chamber 2. As the vacuum deepens in the control chamber 2, the force acting downward on the elastic membrane 7 increases, then a moment occurs at which the force acting on the membrane 7 downward exceeds the force acting on the same membrane 7 upward, and the upper valve 11, tearing away from the hole 16, closes the chamber of constant vacuum 6, and atmospheric air fills the cavity of the chamber of variable vacuum 14, pipe 15 connected to milking cups (not shown), channel 12 and control chamber 2.

 The described pulsation cycle is repeated periodically with a frequency that was previously set by the adjusting screw. With a decrease in atmospheric pressure, the evacuated bellows 5 expands and stretches the elastic membrane 3, reducing the volume of the control chamber 2 in proportion to the decrease in atmospheric pressure, and automatically maintains a given pulsation frequency. With an increase in atmospheric pressure, the process proceeds in the reverse order, while also maintaining a given pulsation frequency.

 The proposed device can be practically implemented on pulsators, commercially available.

 The prototype of the proposed pulsator has worked in the conditions of one of the farms of the Kabardino-Balkarian Republic for more than one year and has shown good results both in terms of labor productivity and in the absence of breast diseases in dairy animals.

Sources of information
1. Melnikov S.V. Mechanization of livestock farms. -M .: Kolos, 1969, p. 280, FIG. 142.

 2. Copyright certificate of the USSR N 323107, cl. A 01 J 5/10, 1972 (prototype).

Claims (1)

 A pulsator comprising a housing with control, constant and variable vacuum chambers, a membrane, upper and lower valves interconnected by a rod and an adjusting screw, characterized in that the control chamber is divided into two parts by an elastic membrane, the lower of which is connected to the atmosphere and is equipped with her vacuum bellows.