RU64855U1 - STAND FOR DIAGNOSTIC OF THE PULSATOR OF THE MILKING MACHINE - Google Patents

Abstract

The utility model relates to the agricultural field of dairy production, namely to the technology of machine milking, and more particularly, to the design of devices for the diagnosis of pulsators of milking machines. The task to be solved is the creation of a sufficiently simple and multifunctional stand for diagnosing the condition of the pulsator elements in a farm environment, including for independently checking the tightness and throughput of the throttle channel of the pulsator, which are the reason for quite frequent failures of milking machines. This problem is solved by the fact that in the known stand for the diagnosis of the pulsator of the milking machine, containing means for supplying air to the cavity of the pulsator, pressure and time control devices, according to the utility model, the stand contains a receiver, the input of which is connected through a shut-off valve to the air pump, the first output of the receiver is connected through the first crane switch to the nozzle of the middle chamber of the pulsator, the second output of the receiver is connected through the second crane switch and the auxiliary throttle nozzle, placed in the nozzle of the peripheral chamber of the pulsator, with its throttle channel, and the third output of the receiver is connected to a manometer to measure the rate of pressure drop in its volume, while the first and second crane switches are mechanically connected to the stopwatch for their independent start when the receiver volume is connected from one of the pulsator cameras. Description for 4 l., Fig. for 1 liter

Description

The utility model relates to the agricultural field of dairy production, namely to the technology of machine milking, and more particularly, to the design of devices for the diagnosis of pulsators of milking machines.

A known stand for monitoring the quality of the assembly of pulsators, containing a vacuum installation connected by a vacuum wire with the main and additional vacuum cylinders, to which are connected vacuum gauges and cranes of controlled pulsators (see ed. St. USSR No. 1777731, bull. No. 44, 1992 .).

A disadvantage of the known stand is the design complexity, due to the need to use a vacuum system for the simultaneous diagnosis of the health of several pulsators.

The closest technical solution to the proposed one is a device for diagnosing a milking machine pulsator, containing means for supplying air to the pulsator cavity, instruments for monitoring pressure and time of its change (see ed. St. USSR No. 1598930, bull. No. 38, 1990 - prototype).

A feature of the known device is the presence of an actuator, communicated through a vacuum valve with a vacuum system, the actuator is made in the form of a sealed container with a float indicator of pulse pressure, and the sealed container is connected to the pulsator via a throttle.

A disadvantage of the known device is that it is intended to verify only the assembly quality of the pulsator with the mandatory use of a vacuum system, as well as the lack of the ability to independently verify the tightness of the pulsator and the capacity of the throttle channel.

The task to be solved is the creation of a sufficiently simple and multifunctional stand for diagnosing the condition of the pulsator elements in a farm environment, including for independently checking the tightness and throughput of the throttle channel of the pulsator, which are the reason for quite frequent failures of milking machines.

This problem is solved by the fact that in the known stand for the diagnosis of the pulsator of the milking machine, containing means for supplying air to the cavity of the pulsator, pressure and time control devices, according to the utility model, the stand contains a receiver, the input of which is connected through a shut-off valve to the air pump, the first output of the receiver is connected through the first crane switch to the nozzle of the middle chamber of the pulsator, the second output of the receiver is connected through the second crane switch and the auxiliary throttle nozzle, placed in the nozzle of the peripheral chamber of the pulsator, with its throttle channel, and the third output of the receiver is connected to a manometer to measure the rate of pressure drop in its volume, while the first and second crane switches are mechanically connected to the stopwatch for their independent start when the receiver volume is connected from one of the pulsator cameras.

This embodiment of the test bench for the diagnosis of the pulsator allows, at minimal cost for purchased equipment in the conditions of poorly equipped mechanical workshops of farms, to manufacture a fairly simple device for diagnosing the condition of the elements of the pulsator, including for independently checking its tightness and throughput of the throttle channel, the integrity of the gaskets and pulsator membranes.

Figure 1 presents a block diagram of a stand.

The milking machine pulsator diagnostic stand includes a pulsator 1, a receiver 2, the input of which is connected via a shut-off valve 3 to the air pump 4. The first output of the receiver 2 is connected through the first crane switch 5 to the pipe 6 of the middle chamber 7 of the pulsator 1, and the second output of the receiver 2 through the second crane switch 8 and the auxiliary throttle nozzle 9 is connected in the area of the pipe 10 of the peripheral camera 11 of the pulsator 1 with its throttle channel 12, and the third output of the receiver 2 is connected to a pressure gauge 13 for measuring the rate of fall of the excess yes phenomena in its volume. The first and second crane switches 5, 8 are mechanically connected through contact elements, one of which is indicated by pos. 14, with stopwatch 15, 16 for their independent start when the volume of the receiver 2 is connected to one of the cavities of the pulsator 1. The pulsator 1 has a third chamber 17, which is separated from the middle chamber 7 by a membrane 18, as well as a movable valve 19. In this case, the peripheral chamber 11 of the pulsator 1 is provided with an axial hole, which, during the testing of the pulsator, is hermetically closed by a plug 20.

The device operates as follows.

According to the proposed utility model, for the diagnosis of these elements and the characteristics of the pulsator 1, a simpler and quite effective, compared with the commonly used evacuation, method of supplying air to the chambers of the pulsator 1 using an air pump 4, receiver 2, shut-off valve 3, switch valves 5, 8 and auxiliary throttle nozzle 9.

While checking the overall tightness of the pulsator 1 is as follows. With pump 4, with open valve 3 and closed shut-off valves 5, 8, fill the receiver 2 to an overpressure of about 20 kPa, fixed by a pressure gauge 13. After that, close valve 3 and open the tap switch 5 while turning on the stopwatch 15. Crane switch 8 it is closed. The pressure gauge 13 first shows a slight decrease in pressure due to air entering the chambers of the pulsator 1. Then, the pressure gauge 13 and stopwatch 15 are monitored for 10-100 s. The absence of pressure drop in the receiver indicates the complete tightness of the housing of the pulsator 1 and its elements, including the membrane 18, the inputs to the nozzles 6, 10, etc.

The presence of a leak or depressurization of the pulsator 1 is determined by the degree or rate of pressure drop in the receiver 2, indicated by the pressure gauge 13. Based on the recorded readings of the pressure gauge 13 and stopwatch 15, a graph of the pressure drop is plotted in time - pressure coordinates. The slope and shape of the pressure drop curve indicate the corresponding defects in the elements of the pulsator 1. The alternate replacement of its gaskets, membranes and other parts makes it possible to identify the characteristic malfunctions of each pulsator or their group.

Check the bandwidth of the throttle channel 12 of the pulsator 1 is carried out independently of previous measurements as follows. With pump 4, with open valve 3 and closed shut-off valves 5, 8, fill the receiver 2 to the previous overpressure (20 kPa), fixed by pressure gauge 13. After that, close valve 3 and open the tap switch 8 while stopwatch 15 is turned on (the switch 5 is closed).

In the absence of clogging of the throttle channel 12, the pressure gauge 13 shows a rapid decrease in pressure due to air entering the chamber 17 of the pulsator 1. If there is full or partial clogging of the throttle channel 12, the readings of the pressure gauge 13 change more slowly, which is recorded by the readings of the stopwatch 16.

According to the recorded readings of the manometer 13 and stopwatch 15, as in the determination of tightness, a graph of the pressure drop is plotted in the coordinates time - pressure. The slope and shape of the pressure drop curve indicate an increase in the hydraulic resistance of the throttle channel 12 of the pulsator 1 and the need for cleaning it. Further improvement of the described measurement procedure can help determine the degree of wear or aging of the gaskets and the elastic membrane of the pulsator.

The general tightness of the pulsator of the milking machine and the throughput of the throttle channel are the main diagnosed parameters for mechanics and machine milking operators, depending on the state of the constituent elements of its structure: body, valve, gaskets, process holes, membranes, etc. Even minor violations of the integrity of these elements and the throughput the ability of the throttle channel of the pulsator can disrupt the operation of milking machines due to a change in the time of its switching (share sec), which is associated with a change in the time of forward and reverse stroke of the pulsator valve.

The proposed implementation of the bench for the diagnosis of the pulsator of the milking machine allows, in conditions of poorly equipped mechanical workshops of farms, to manufacture this device and use it for alternately checking the tightness of the pulsator and the capacity of its throttle channel.

Claims (1)

A stand for diagnosing a pulsator of a milking machine, containing means for supplying air to the cavity of the pulsator, pressure and time control devices, characterized in that the stand contains a receiver, the input of which is connected through a shut-off valve to the air pump, the first output of the receiver is connected through the first a switch with a nozzle of the middle chamber of the pulsator, the second output of the receiver is connected through a second crane switch and an auxiliary throttle nozzle located in the nozzle of the peripheral chamber of the pulsator, with its throttle channel, and the third output of the receiver is connected to a manometer to measure the rate of drop of excess pressure in its volume, while the first and second crane switches are mechanically connected to stopwatch for their independent start when the receiver volume is connected to one of the pulsator chambers.