DE2812830C2 - - Google Patents

Description

The invention relates to a pulsator valve. This is esp specially designed as a pulsator valve for a milking machine.

Most common milking machine systems have a pulsator valve provided to alternatively connect between a Milking cup coat and a flexible inner milking cup and a vacuum connection or an atmospheric pressure connection deliver. If you put a vacuum on the space between the teat cups connecting the coat and the inner milking cup, this affects the Counteracts the effect of a vacuum inside a milking cup. As a result, the inner milking cup takes its natural again Liche shape, which is usually cylindrical. If the space between the teat cup shell and the inner milking applies atmospheric pressure or other pressure, the inner teat cups pressed together. This leads to one Squeeze the teat.

In the currently used types of pulsator valves can be a plate, a swinging blade or a coil as a valve serve element. This can be done through various mechanisms be operated. When operating most of the pulsator construction There is a phase in which the moment in which the valve element moves from one position to the other (i.e. when there is a change in connection between the off let and the vacuum or the atmospheric pressure) Vacuum and atmospheric pressure openings are connected to each other and / or to the outlet. This can cause disturbances in the milking process and / or the milking pulse is a variable or undesirable "pulse" - Has profile.

For some types of commonly used pulsator valves are all openings in one phase of an operating cycle  otherwise connected, unless not unrealistically low manufacturing tolerances exist.

Also in the pulsator valve known from AU-PS 2 44 431 two valves are provided, which in such a way in Connection are that when switching the two valves at least temporarily both valves are open.

The object of the present invention is based on above-mentioned prior art to open a pulsator valve show that avoids the disadvantages mentioned above and enables milking with high efficiency.

This task is solved by a pulsator valve according to the teaching of claim 1.

The pulsator valve according to the invention has a housing with several connection openings. A membrane is included its edge attached to the housing. By creating under different pressure on both sides of the membrane these are bent and thus close or open certain ones Valve openings or connection openings.

The pulsator valve according to the invention can not only be used for Milking machines but also with other machines be brought about.

The invention is based on a preferred Aus leadership form with reference to the drawings he purifies.

Fig. 1 is a sectional elevation of a pulsator valve according to the invention, which is set to "reverse operation".

Fig. 2 shows a sectional elevation through an inventive pulsator valve, which is set as a "reversible" pulsator.

FIG. 3 shows a section of the pulsator valve shown in FIG. 2, in which an additional plug is provided for an opening in order to enable a specific, desired operating mode.

Fig. 4 is a sectional elevation of an alternative imple mentation form of a pulsator valve according to the invention, which is designed "self-activating".

In the preferred embodiment of the invention Pulsator valve, which in various alternative configurations NEN can be arranged, the following constructive Characteristics on.

The valve has a housing which consists of a lower part 10 and a cover 9 . These are preferably molded from a suitable plastic material. The valve contains a membrane 6 made of a synthetic rubber, for example made of neoprene, or of a natural rubber or of flexible plastic material. It is edge-fastened via its edge between the lower part 10 and the cover 9 . When viewed from above, the valve housing and the diaphragm are essentially circular. The valve housing has various inlet and outlet openings, which are explained in more detail in the following description of the operation of the valve. The housing further comprises an inner valve 7 with a valve disk 28 which is in engagement with a valve seat 16 . The inner valve 7 can be actuated by moving the membrane 6 via a shaft.

Arrangement and use of the valve when switching as a "Reversing" slave pulsator valve) is described below.

When the membrane 6 is at rest, it normally contacts the annular valve seat 11 . It is pressed onto the valve seat 11 by a vacuum on its underside and bent to the stop 12 because the opening 8 is connected to atmospheric pressure. The opening 3 connects the space between the teat cup shell and the inner teat cup with vacuum, which is supplied through the opening 2 and through the opening between the valve's 7 and the valve seat 16 . If a vacuum signal is exerted on the chamber 15 through the opening 8 by a transmitter or another source, this compensates for the vacuum exerted on the underside of the membrane 6 on the area surrounded by the annular seat 11 . As a result, the membrane 6 lifts up from the stop 12 , where the valve 7 closes against the valve seat 16 . The opening 3 is connected to the teat cup and at the same time separated from the vacuum line and the atmospheric pressure line.

Since the signal applied to the chamber 15 via the opening 8 acts in a vacuum on the entire surface of the membrane 6 , it deforms in an annular manner, lifting off from the valve seat 11 and striving to assume a wavy line between its center and its outer circumference. As a result, the opening 3 is connected via the chamber 14 to the chamber 13 and the opening 1 , so that air from atmospheric pressure can pass through to the opening 3 . The speed at which this air can flow is regulated through the opening 17 and the plug 4 ge. The plug 4 is inserted into the opening 1 . Here again the extent of the compression of the milking cup is determined. When the signal vacuum is removed from the opening 8 and atmospheric air is allowed to enter, the pressure in the chamber 15 increases . As a result, the membrane 6 forms back and is again in contact with the valve seat 11 , whereby the connection between the chambers 13 and 14 is interrupted and the space between the teat cup jacket and the teat cup be therein is separated from the atmospheric pressure. At this moment, the teat cup opening 3 is briefly closed off from the vacuum line and from the atmospheric pressure line.

The system vacuum acting on the underside of the valve 7 then pulls the valve down from the valve seat 16 and the membrane 6 down to the stop 12 . Then the vacuum connection is reconnected to the space between the teat cup shell and the teat cup through the space between the valve 7 and the valve seat 16 , and through the chamber 14 and the opening 3 .

When changing from one position to the other, the membrane deforms each time. This ensures that both the vacuum and atmospheric pressure are turned off before vacuum or atmospheric pressure are connected to the space between the teat cup and the teat cup. Likewise, the waveform of the "signal" or the frequency of exposure of the signal to the opening 8 does not affect the "sharpness" of the outlet pulse, since it is entirely dependent on the function of the membrane 6 , which in turn is a function of the appropriate pressure conditions on the The top and bottom of the membrane is. In particular, the valve in the embodiment as a reversing sensor, as shown in FIG. 1, has a trigger function which occurs at a specific vacuum size due to the change in the pressure distribution through the membrane when the valves open.

You can also assemble the valve so that it works as an "inverted" pulsator, as shown in Fig. 2.

In this embodiment, a vacuum signal on the opening 8 leads to the creation of a vacuum from the opening 3 in the space between the teat cup shell and the teat cup. In this embodiment, a modified membrane is used with an annular recess 18 on both surfaces between the central hub and the outer edge of the membrane, which otherwise has the same diameter as the "inverting" membrane 6 in FIG. 1 for the central hub and the edge. This recess 18 results in a distance of approximately 0.5 mm between the membrane 6 a and the annular valve seat 11 .

If the vacuum connection is connected to the opening 1 and no vacuum signal is present at the opening 8 , the atmospheric pressure in the chamber 15 presses the membrane 6 a down until it is in contact with the valve seat 11 . As a result, the center of the membrane 6 a is bent downward and the valve 7 is lowered relative to the valve seat 16 . Now atmospheric pressure is connected through the opening 2 through the open valve 7 and the chamber 14 to the space between the teat cup jacket and the teat cup.

When a vacuum signal is applied to the port 8 from a donor pulsator or other source, the pressure in the chamber 15 is reduced. Then the atmospheric pressure in the chamber 14 presses the center of the membrane 6 a upwards until the valve 7 touches the valve seat 16 . Then the membrane is deformed upwards between its central hub and the point at which it touches the annular valve seat 11 . As the pressure difference between the chambers 14 and 15 increases, the membrane 6 lifts off from the annular valve seat 11 , a wave-shaped curve being formed between the central hub and the outer edge of the membrane. Then the space between the teat cup and teat cup is connected via the opening 3 , the recesses 14 and 13 to the vacuum connection which is connected to the opening 1 in this embodiment.

It can be seen that the connection of the chambers 13 and 14 takes place very quickly, while the flexible membrane "snaps away" from the Ven valve seat 11 , but provided that the pressure change in the chamber 15 takes place quickly.

If the pulsators are to be used in a "ripple" circuit, ie if the outlet signal of a pulsator is to provide the signal for the subsequent unit, a suitable opening 3 a ( FIG. 3) can be provided which creates a connection to chamber 14 . It may be advantageous if one is able to inhibit the passage of air through the openings 3 or 3 a , so as to control the degree of compression of the teat cup or the time at which a signal pulse to other pulsators in a ripple or Cascade system is applied to delay. This can be achieved in that a stopper 4 with a one conforms to the openings 1 and 2 the gas flow inhibitory bore and / or on the openings 3 or 3 a a plug 19 (Fig. 3) conforms with a bore 20. The size of the bore 20 is chosen so that it creates the desired inhibition. The upper edge of the plug 19 creates a seal against the lower surface of the membrane 6 a in a similar manner to the valve seat 11 .

The pulsator can also be modified to operate as a "self-activating" embodiment, as shown in FIG. 4. In this configuration, the cover 9 of the configurations described above is replaced by a hood 21 . The inner valve is replaced by a valve 7 a , which has an axial passage 26 which connects the upper end of the valve spindle with openings 27 . This configuration results in a pulse ratio of approximately 50:50 vacuum: air. However, this pulse ratio can be modifi ed by providing an opening 25 and a flap valve 24 which are arranged in a cage 23 above the upper end of the passage 26 .

When the valve 24 is raised by air rising through the passage 26 , air can escape through the valve opening thus formed, as well as through the bore 25 . When the air has escaped from the chamber 22 , the valve 24 closes and the air can escape through the bore 25 . The vacuum: air-pulse ratio can be determined by adjusting the size of the bore 25 and the opening of the valve 24 .

When the vacuum system is connected to the opening 2 , air is evacuated from the recess 14 and residual air pressure in the hood interior 22 deforms the center of the diaphragm 6 downwards until it reaches the stop 12 . This leads to a complete opening of the valve 7 a from the valve seat 16 and to a connection of the vacuum system through the recess 14 to the opening 3 .

While the pressure in the hood interior 22 is lowered to reach the pressure in the recess 14 , the membrane returns to its original rest position, whereby the Ven valve 7 a on the valve seat 16 is closed. On the underside of the membrane above the annular chamber 13, an effective atmospheric pressure leads to the lifting of the membrane 6 away from the seat 11 . The membrane 6 bends upwards between its central hub and its outer edge in a wave-like manner.

With the closing of the valve 7 a and the lifting of the membrane 6 from the seat 11 , air can then flow under atmospheric pressure through the opening 1 , the cutouts 13 and 14 and the passage 26 into the hood interior 22 .

As the pressure in the hood interior 22 increases , the membrane 6 returns to its rest position, whereby the opening between the membrane 6 and the seat 11 is closed.

Low pressure from the vacuum line in the opening 2 then causes the atmospheric (or almost atmospheric) pressure in the hood interior 22 to push the membrane 6 down against the stop 12 , thereby opening the valve 7 and the vacuum system via the opening 1 and the Chambers 14 and 13 are connected to the opening 3 . Then this cycle is repeated automatically.

If the device is to be operated as a transmitter pulsator, the opening 3 can be connected directly to a teat cup arrangement and / or to the signal opening 8 of slave pulsators shown in FIGS . 1 and 2.

A pulsator valve as described above is simple and inexpensive to manufacture and has a minimum of moving parts, as a result of which a long operation is possible without wear problems. In addition, the valve easily generates a sharp, wavy signal. This is very desirable in a milking machine. The bending capacity of the membrane is used in such a way that the opening and closing processes of the membrane and the valve 7 do not run synchronously. Each valve closes before the other valve opens. This ensures that there is no air movement from the air supply opening directly to the vacuum line.

The valve has the further advantage that you can by plugging of connections to different openings and through exchange simple components in the valve this as an encoder, reversible Slave, reverse taker or slave arrangement or in any what other known pulsator systems or sequences as a trigger, amplifier, milk lifter or trigger pulsator can use.

Claims (4)

1. pulsator valve with a housing which is essentially divided into two chambers by a membrane, one chamber being permitted with a plurality of connection openings, two of which can be closed by valve disks and therefore represent two valves, the first valve disk being separated from the membrane is formed and the second valve plate is operatively connected to the diaphragm via actuating means and the valve plates are arranged such that when the first valve is fully open, the second valve is closed - and vice versa -, characterized in that the actuating means ( 7 c) for the second Valve plates ( 28, 28 a) are connected to the diaphragm ( 6, 6 a) and have dimensions such that when changing between the open state of the first valve ( 6, 6 a ; 11 ) to the open state of the second valve ( 16; 28, 28 a) the first valve is closed before the second valve opens - and vice versa. 2. Pulsator valve according to claim 1, characterized in that the second chamber also has a connecting opening ( 2 ). 3. Pulsator valve according to claim 2, characterized in that at least two connection openings ( 2, 8 ) in the housing are arranged coaxially to the center of the membrane ( 6, 6 a ) and one of the connection openings is annular. 4. Pulsator valve according to one of claims 1 to 3, characterized in that the membrane ( 6, 6 a) consists of flexible plastic material, natural rubber or a synthetic rubber.