SE434694B - MILK MACHINE PULSOR VALVE - Google Patents

Description

Ch 10 15 20 25 30 35? 8033l | 5-3 or atmospheric pressure to the outlet opening), a situation arises when both the negative pressure and the atmospheric pressure openings are connected to each other and / or to the outlet opening.

This can give rise to an unstable function and / or a varying or undesired output pulse profile.

Certain types of conventional pulsator valves normally, unless manufactured with excessively tight manufacturing tolerances, have all the openings interconnected at some stage of their operation.

It is therefore an object of the invention to provide a pulsator valve which offers a tutigutt alternative.

The invention thus consists of a pulsator valve, which comprises a valve housing with a plurality of valve ports and a diaphragm with the edge attached to the valve housing and operable by the pressure difference on both sides of the diaphragm to open and close predetermined valve ports in the desired manner by bending the diaphragm.

To the person skilled in the art, many variations in the embodiment and widely differing applications of the invention will be apparent without departing from the scope of the invention, as will be apparent from the appended claims. The embodiments shown and the following description are examples only and are not intended to be limiting. A suitable embodiment of the invention will be described in the following with reference to the accompanying drawings in which Fig. 1 shows a cross section through a pulsator valve according to the invention, arranged as a reversing valve, Fig. 2 shows a cross section through a pulsator valve according to the invention, arranged as a non-reversing pulsator, Fig. 3 shows a partial view of the pulsator valve shown in Fig. 2, comprising an additional throttling means for effecting a desired mode of operation, and Fig. H shows a cross section through an alternative embodiment of a pulsator valve according to the invention, arranged in a "self-influencing" way. (eg 10 15 20 30 7803316-3 The valve has a valve housing, which consists of a base part 10 and a hat part 9, which parts are suitably made of plastic. The valve comprises a membrane 6 of a synthetic rubber, for example neoprene, or of a natural rubber or a flexible plastic, the diaphragm with its edge being fastened between the valve housing 10 and the valve cap 9. Both the valve housing and the diaphragm are substantially circular in plan view.The valve housing has different inlet and outlet ports, as will be apparent from the following detailed description of the mode of action of the valve, and the valve housing also contains an inner valve 7 with a valve surface 28 for co-operation with a seat 15, which can be actuated by means of a rod during the movement of the diaphragm 6.

The structure and use of the valve, when arranged as a simple, reversing pulsator valve of servotype, is as follows: The diaphragm 6, which at rest normally abuts against an annular valve seat 11, is held downwards against the valve seat 11 and bends against a stop 12 by the action of a negative pressure on its underside, due to a port 8 being connected to atmospheric pressure. An opening 3 connects the outer cavity of the teat cup to a negative pressure which acts through a port 2 via the opening between the valve 7 and the valve seat 16.

When a negative pressure from a guide member is applied to the chamber 15 via the port 8, this balances the negative pressure applied to the underside of the diaphragm 6 over the surface bounded by the annular seat 11, the diaphragm 6 being lifted from the stop 12 and bringing the valve 7 into abutment against the seat 16 The port 3 is connected to the teat cup and in this phase is separate from both the negative pressure and the atmospheric pressure.

Since the negative pressure applied to the chamber 15 through the port 8 acts over the entire upper surface of the membrane 6, the membrane bends in an annular manner and is lifted from the seat 11 and tends to form a catenary between its center and its outer periphery, so that the port 3 the chamber 1U is connected to the chamber 13 and the port 1 allows air with atmospheric pressure to flow through the port 3. The speed at which this air is allowed to flow in is regulated by a throttle opening 17 in a plug 4 which is inserted in the opening 1. ga 10 15 20 25 30 35 78033læ5-3 u This in turn.stvr the degree of compression to which the tension knuckle rubber is exposed. When the control negative pressure is removed from the port 8, and air with atmospheric pressure is allowed to flow in, the pressure in the chamber 15 increases so that the membrane 6 returns to abutment against the seat 11, whereby the connection between the chambers 13 and 14 is interrupted, and the teat cup outer cavity is shut off from atmospheric pressure. At this stage, the teat cup port 3 is momentarily closed against both the negative pressure and the atmospheric pressure.

The negative pressure of the system, which acts on the underside of the valve 7, then pulls the valve downwards, away from the net 16, and the diaphragm 6 downwards to abut against the stop 12.

The source of negative pressure is then reconnected to the outer cavity of the teat cup through the space between the valve 7 and the seat 16, the chamber 1H and the port 3. It should be seen that the diaphragm bends both times, when switching from one position to the other, to ensure the connection with both the negative pressure and the atmospheric pressure is switched off, before either pressure is connected to the outer cavity of the teat cup. Neither the waveform of the controlling negative pressure nor the speed at which the control signal is transmitted to the gate 8 affects the "sharpness" of the output pulse, since it is entirely dependent on the movement of the diaphragm 6 when suitable pressure conditions have been reached between the upper and lower diaphragm surfaces. More specifically, the valve of the reversing servotype shown in Fig. 1 has a trip-type movement that occurs at a specific negative pressure level due to the change in pressure distribution across the diaphragm that occurs when the valves open.

The valve may also be arranged to operate as a simple, non-reversing pulsator, as shown in Fig. 2.

In this case, a negative pressure signal to the gate 8 results in an output negative pressure from the gate 3 towards the outer teat cup cavity. In this mode of operation a modified diaphragm Ba is used, which has an annular recess 18 on each side between its central hub part and its outer jug, which diaphragm 6a has the same thickness in its hub part and in the edge respectively as the reversing the diaphragm 6 according to Fig. 1. This recess 18 leaves a clearance of about 0.5 mm between the diaphragm Ba and the annular seat 11.

When the source of negative pressure is connected to port 1 and no negative pressure signal is transmitted to port 8, the atmospheric pressure in the chamber 15 presses the diaphragm Ga downwards to abut against the seat 11, bending the center of the diaphragm 6a downwards and lowering the valve 7 relative to the seat 16. Atmospheric pressure is now switched through port 3 to the outer cavity of the teat cup via the open valve 7 and the chamber 14.

When a negative pressure signal from a controlling pulsator or some other source is applied to the gate 8, the pressure in the chamber 15 drops. The atmospheric pressure in the chamber 1M presses the center of the diaphragm upwards, until the valve 7 is brought into abutment against the seat 16. The diaphragm is bent upwards between the central hub part of the diaphragm 6a and the place where the diaphragm abuts the annular seat 11.

As the pressure difference between the chambers 1H and 15 increases, the diaphragm 6a releases from the annular seat 11 so that it assumes a catenary shape between the central hub part and its outer edge. The outer cavity of the teat cup is in this case connected via the port 3 and the chambers 1H and 13 to the source of negative pressure, which in this case is connected to the port 1.

It should be seen that the connection between the chambers 13 and 1H is established very quickly, since the flexible diaphragm "snaps" away from the seat 11, provided that the pressure change in the chamber 15 is rapid.

When pulsator valves are to be used in such a way that the output from a pulsator is used to give impulse to the next unit, a suitable port 3a (Fig. 3) can be arranged to the chamber 1U. It may be advantageous to be able to restrict the flow of air through the ports 3 or Ba to control the degree of compression of a teat cup rubber or to allow the transmission of a signal pulse to other pulsators in a chain pulse system. This can be accomplished by fitting a plug U with a throttle opening 17 in port 1 or 2 and / or fitting a plug 19 (Fig. 3) with a throttle opening 20 in ports 3 or Ba. The opening 20 is dimensioned to provide the required throttling. The upper edge of the plug 19 abuts sealingly against the lower surface of the diaphragm 6a in the same way as the seat 11.

The pulsator can also be modified to operate "self-actuating", as shown in Fig. H. In this embodiment the hat part 9 in the previously described embodiments is replaced by a curved hood 21. The central valve has been replaced by a valve 7a having an axial channel 26 which prevents the upper end of the valve stem from openings 27. This embodiment provides a pulse ratio of about 1% H: 60 between negative pressure and atmospheric pressure, which pulse ratio can, however, be modified by arranging a further opening 25. and a flap valve 24 in a cage 23 over the upper end of the channel 26.

When the valve 24 is lifted by the air flowing upwards in the duct 26, air can flow out both through the valve opening thus formed and through the opening 25.

When air is evacuated from the chamber 22, the valve 2H is closed, whereby the air can only flow out through the opening 25.

By changing the size of the opening 25 and the opening ZH of the valve, the pulse ratio between negative pressure and atmospheric pressure can be determined.

When the negative pressure system is connected to the opening 2, air is evacuated from the chamber 1U, and residual atmospheric pressure in the main chamber 22 bends the center of the diaphragm 6 downwards until it engages the stop 12, fully opens the valve 7a (leaves the seat 16) and connects the negative pressure system via the chamber 14 with the gate 3.

As the pressure in the chamber 22 is lowered so as to approach the pressure in the chamber 1U, the diaphragm returns to its original rest position, thereby bringing the valve 7a into abutment against the seat 16. Atmospheric pressure acting on the underside of the diaphragm via the annular chamber 13 lifts the diaphragm 6 away from the seat 11. The diaphragm 6 hereby bends upwards between its central hub part and its outer edge.

When the valve 7 has been closed and the diaphragm 6 is lifted from the seat 11, air with atmospheric pressure can flow through the port 1, the chambers 1É and 1H and the duct 26 into the hood chamber 22.

As the pressure in the chamber 22 increases, the diaphragm 6 returns to its rest position, in which it closes the opening between the diaphragm 6 and the seat 11. Low pressure from the source of negative pressure in connection with the port 2 then allows the atmospheric (or almost atmospheric) pressure in the chamber 22 to press the diaphragm 6 downwards to abut against the stop 12, whereby the valve 7 is opened and the negative pressure system via the port 1 and the chambers 1u and 13 is connected to the port 3. The work process is repeated almost automatically.

If the device is to be used as a main pulsator, the port 3 can be connected directly to a teat cup device and / or to the signal port 8 in the servo pulsators shown in Figs. 1 and 2.

A pulsator valve of the type described above has the advantages that it is simple and inexpensive to manufacture and has a minimal number of moving parts, which results in a long service life without wear problems.

In addition, the function of the valve gives a sharp waveform, which in a simple way leaves a desired result for a milking machine. The flexibility of the diaphragm is used so that the opening and closing of the diaphragm and the valve 7 are not synchronized. Each valve is closed before the other valve is opened, which ensures that direct air flow from the air supply opening to the source of negative pressure is prevented.

The valve also has the advantage that, by changing the connections to the various ports and by replacing simple components in the valve, it can be used as a main valve, non-reversing servo valve, reversing servo valve or chain pulse coupled servo valve or in any other of the known pulsator systems or processes and as a release device, auxiliary device, milk lifter or actuating pulsator. 7803345-3

Claims (6)

10 15 20 25 m 35 7803345-3 8 PATBNTKRQ'_ Fulsator valve intended for a milking machine and having a valve housing (9, 10), a diaphragm (6) which is attached along its periphery to the valve housing (9, 10) dividing its interior into a first chamber (15) and a cavity (13, 1U), an annular valve seat (11) in the cavity, so located that in one of the positions of the diaphragm (6) it cooperates with the diaphragm to form an annular valve (6, 11) which, when closed by the diaphragm abutting the valve seat, divides the cavity (13, 14) into an inner chamber (1H) and an outer annular chamber (13), a further valve seat (16) forming a first part of a further valve (7, 16), and a valve body (7) which is connected to the diaphragm (6) by means of a valve stem, the valve body (7) forming a second part of the further valve and being movable by the diaphragm (6) for abutment against the further valve seat for closing the additional valve in one of the positions of the diaphragm, the additional valve seat (16) being located around an opening (2) leading from the inner chamber (14) out of the valve housing and wherein the diaphragm (6) is arranged to, when deformed during operation by applying negative pressure in the first chamber (15) and / or the inner chamber (14), bring either of the annular valve (6, 11) and the further valve (7, 16) to closed and the other ~ to the open position, while during a transitional stage it keeps both valves closed. Pulsator valve according to claim 1, characterized in that the inner chamber (14) has two openings (2, 3) leading out of the valve housing (9, 10), one of which is the previously mentioned opening ( 2), which is then located coaxially with the annular valve seat (11). Pulsator valve according to claim 2, characterized in that an additional opening (Sa) is arranged in the inner chamber (14) leading out of the valve housing (9, 10), this opening having a surrounding valve seat which is arranged to abut during operation against a portion of the diaphragm (6) in any of its positions for closing this opening. 10 15 20 25 30 7803345-3 9 Pulsator valve according to one of Claims 1 to 3, characterized in that the diaphragm (6) rests against the annular valve seat (11) at rest and keeps the further valve (7, 16) open. Pulsator valve according to one of Claims 1 to 3, characterized in that the diaphragm (6) is located to move freely from the annular valve seat (11) when it is at rest, while the further valve (7, 16) is localized. - to be closed when the membrane (6) is at rest, and open when the first chamber (15) is applied atmospheric pressure and the annular chamber (13) is applied negative pressure. Pulsator valve according to one of Claims 1 to 3, characterized in that the valve body (7a) of the further valve (7, 16) has a hollow valve stem forming a passage (26) between the first chamber (22) and the inner chamber (14). ), the diaphragm (6) being located to close the annular valve (6, 11), when it is at rest, and the further valve (7, 16) being arranged to be at least slightly open, such as: the diaphragm (6), when negative pressure is applied to the opening (2) controlled by the further valve (7, 16), initially bends inwards into the inner chamber (1H) while air is evacuated from the first chamber (22) to, then pressure equalization achieved between the first chamber and the inner chamber is lifted from the annular valve seat (11) so that air from the annular chamber (13) can be led to the inner chamber (ih) and through the passage of the hollow valve stem (26) to the first chamber (22), whereby the membrane (6) is caused to move due to pressure equalization between the first and the inner chamber for automatic repetition of the same work cycle.