FR2543652A1 - Electromagnetically actuated flow valve - Google Patents

Abstract

An electromagnetically actuated 2 way flow control valve has the flow between inlet and outlet controlled by a diaphragm poppet operating against a seat. The moving core of the actuator has a plug that controls flow through a pilot channel in a fixed tube. A pilot flow path from the inlet is established by a small orifice and channel to the underside of the core. When the electromagnetic actuator is energised the plug lifts clear of the pilot channel and flow passes down the tube to cause a pressure drop and the diaphragm poppet moves clear of the seat to allow flow to pass to outlet.

Description

Solenoid valve, especially for washing machines
The present invention relates to solenoid valves, in particular for washing machines, such as washing machines, dishwashers and the like.

The invention particularly relates to a solenoid valve of known type comprising
a valve body having an internal cavity,
an annular inlet passage opening into said interior cavity and communicating with a source of pressurized liquid,
an outlet opening,
an annular wall serving as a valve seat which delimits said outlet opening and which is surrounded by said annular inlet passage,
a flexible membrane fixed along its periphery to the wall of said interior cavity and having a central part cooperating with said valve seat, for controlling the flow of liquid between said annular inlet passage and said outlet opening, this membrane being provided with at least one opening communicating the annular inlet passage and said interior cavity,
a reinforcing element fixed in a central opening of the membrane and traversed by a passage which communicates with said interior cavity by means of a restricted orifice, and
an electromagnet comprising a movable core, a guide element of the movable core, a spring which pushes the movable core towards a closed position of said orifice and an electromagnetic coil to move the movable core from said position shutter.

 In known solenoid valves of the type mentioned above, in the closed position of the valve, the membrane is held against its seat under the effect of different pressures acting on its two faces. The face of the membrane facing the outlet opening is indeed subjected to atmospheric pressure, while the opposite face is subjected to the pressure of the water distribution network (transmitted from the annular inlet passage to the interior cavity valve through the opening in the membrane). When the electromagnet is excited, the movable core moves away from said reduced orifice, made in the reinforcement element of the membrane, and consequently the passage inside the reinforcement element makes the interior cavity communicate. of the valve with the outlet opening. It follows that the pressure inside the valve cavity decreases, and that the membrane moves away from its seat, directly communicating the inlet and the outlet of the valve. Naturally, in order to obtain correct functioning of the valve, it is necessary that at this time, the movable core of the electromagnet is displaced by a sufficient length to prevent it from again being able to obstruct the passage of the reinforcement element of the membrane, when the latter is in the open position. This implies that a relatively long stroke is adopted for the movable core and therefore that an electromagnet of relatively high power is used.

 The present invention aims to provide an improved type solenoid valve for adopting an electromagnet of limited power.

 In order to achieve this objective, the present invention relates to a solenoid valve of the type mentioned at the beginning of this description, the main characteristic of which resides in the fact that said restricted orifice cooperating with the movable core of the electromagnet, is practiced in a fixed element relative to the body of the valve and communicates in leaktight manner, with said passage of the reinforcement element of the membrane.

 According to a preferred embodiment, said reinforcing element of the membrane is mounted so as to be able to move on said fixed element.

 In addition, according to a preferred embodiment, the sealing of the connection between the interior passages of the fixed element and of the reinforcing element of the membrane is achieved by means of a cap made of flexible material, surrounding the 'fixed element and having one end fixed to the latter and the opposite end mounted so as to be able to slide, while ensuring sealing, on the reinforcing element of the membrane.

 Another preferred feature of the preferred embodiment of the invention is that the fixed element consists of a journal through which an axial passage passes.

has said orifice restricted at one of its ends, cooperating with the movable core of the electromagnet, and the fact that this pin is fixed in the center of a bell-shaped element, in turn fixed to the inside the valve body cavity. The element having the restricted orifice with which the movable core of the valve electromagnet cooperates does not move as a result of a displacement of the membrane towards the open position, it follows that the stroke of the core movable necessary to control the opening of the valve is much shorter than that required in the solenoid valves according to the known technique, which allows to adopt electromagnets of lower power.

Other characteristics and advantages of the invention will emerge from the description which follows, with reference to the appended drawing, given solely by way of nonlimiting example, in which
FIG. 1 is a solenoid valve in section according to the known technique, and
Figure 2 is a solenoid valve according to the present invention.

 Figure 1 shows a solenoid valve according to the known technique, comprising a body 1 having an interior cavity 2, an inlet fitting 3 and an outlet fitting 4. The inner cavity 2 communicates with the outlet fitting 4 through an opening in outlet 5 which is delimited by an annular wall 6 serving as a valve seat. The annular wall 6 defines, with the wall of the interior cavity 2, an annular inlet passage 7 communicating with the inlet connector 3. The reference 8 designates a flexible membrane fixed along its periphery to the wall of said interior cavity and having a central part cooperating with the valve seat constituted by the annular wall 6, in order to control the flow of liquid between the annular inlet passage 7 and the outlet opening 5. The membrane 8 is provided with at least one opening 8a which communicates the annular inlet passage 7 and the interior cavity 2. The membrane 8 also has a central reinforcing element 9 which is fixed in a central opening in the membrane and which is crossed by a passage 10 communicating the outlet opening 5 and the interior cavity 2. The passage 10 consists of a restricted orifice 11 adjacent to the face of the reinforcing element 9 which faces the interior cavity 2. The reference 12 designates an electromagnet comprising a movable core 13, in the form of a cylindrical axis, mounted so as to be able to move in a guide element 14 which comprises a tubular guide part 15 closed at one end 16 and whose opposite end 17 has the shape of an inverted cup. The periphery of the membrane 8 is clamped between a circular seat of the valve body and the basic peripheral edge of the guide element 14 of the movable core 13. At its turned end towards the interior cavity 2, the movable core 13 is provided with a rubber lining 18, intended to cooperate with the restricted orifice 11 in the reinforcing element 9 of the membrane 8. A spring 19 mounted inside of the guide element 14, between the movable core 13 and the closed end 16 of the tubular portion 15, tends to push the movable core 13 towards a position for closing the restricted orifice 11. An electromagnetic coil 20 drives, when excited, the remoteness of the mob nucleus island 13 of the closed orifice closed position 11. The various parts of the valve described above are made of plastic, except for the core 13 which is metallic, and the membrane 8 which is made of rubber .

The operation of the known solenoid valve shown in Figure 1 is as follows
When the coil 20 of the electromagnet 12 is not energized, the valve is in the position shown in Figure 1. In this position, the membrane 8 is in contact with the valve seat 6, and therefore , the connection between the annular inlet passage 7 and the outlet opening 5 is interrupted. In addition, the movable core 13 of the electromagnet 12 is held by the spring 19 against the restricted orifice 11, which means that the outlet opening 5 and the interior cavity 2 do not communicate either through the passage 10. The water which arrives at the annular inlet passage 7 can flow into the interior cavity 2 by passing through the opening 8a of the membrane 8 until this interior cavity is filled. It follows that the membrane 8 is pressed against seat 6 under the effect of different pressures acting on the two opposite faces. In fact, the face of the membrane 8 facing the outlet opening 5 is subjected to atmospheric pressure, while the face of the membrane 8 facing the interior cavity 2 is subjected to the pressure of water. It is observed that the membrane 8 is held against its seat essentially under the effect of the pressure difference mentioned above and that the spring 19 has the sole function of holding the movable core 13 against the reinforcing element 9 of the membrane . The valve is opened by exciting the electromagnetic coil 20.

This excitation causes the moving core 13 to move away from the reinforcing element 9. There is therefore communication between the internal cavity 2 and the outlet opening 5 through the restricted orifice 11 and the passage 10 of the element. reinforcement 9 of the membrane. Consequently, in the internal cavity 2, a pressure drop is immediately created relative to the pressure existing in the annular inlet passage 7; as a result, the membrane 8 lifts causing the inlet 3 and the outlet 4 to communicate directly with the valve. The valve is closed by cutting off the excitation of the electromagnet 12. In this case, the movable core 13 is pushed by the spring 19 against the reinforcing element 9 of the membrane, so as to close off the restricted orifice 11, and to allow ae to restore the hydraulic pressure in the interior cavity 2 which always communicates with the inlet of the valve through the opening 8a of the membrane 8. Consequently, the membrane 8 returns in contact with the seat 6, interrupting the connection between inlet 3 and outlet 4.

 Known valves of the type described above; being actuated by water pressure, function correctly whatever the value of the hydraulic pressure on the inlet fitting 3 In practice, the pressure on the fitting 3 can vary between 0.2 or 0.3 bar and 10 bars, depending on the point of the water pipe to which the solenoid valve is connected.

For correct operation of the valve under opening conditions, it is necessary to provide for a displacement of the reinforcing element 9 of the membrane sufficient to avoid constriction at the outlet opening 5. Consequently, the displacement of the movable core 13 at the time of opening must be relatively large, to avoid that when the membrane is in the open position, the movable core can again close the restricted opening 11. The electromagnet must therefore have sufficient power to guarantee this relatively large displacement of the mobile core
The solenoid valve according to the invention, shown in FIG. 2, makes it possible to significantly reduce the necessary stroke of the movable core, so as to allow the adoption of an electromagnet of reduced power.

 In Figure 2, parts similar to those of the solenoid valve shown in Figure 1, are designated by the same reference.

 The main difference compared to the valve shown in Figure 1, lies in the fact that in the valve of Figure 2, the restricted orifice 11 is not made in the reinforcing element 9 of the membrane, but in a fixed element 21 traversed by an internal passage 22 which includes said restricted orifice 11 and which communicates in leaktight manner, with the internal passage 10 of the reinforcing element 9 of the membrane.

 In the embodiment shown, said fixed element 21 has the shape of a cylindrical journal whose end facing the movable core 13 is forcibly fixed in a central orifice 23 of a bell-shaped element 24 fixed to inside the cavity 2. Still with reference to the particular example described, the bell-shaped element 24 has a central part inserted in the tubular portion 15 of the guide element 14 of the movable core, and a portion base device 25 clamped between the periphery of the membrane 8 and the base peripheral edge of the guide element 14. The bell-shaped element 24 is further provided at its base with a circular book 26 mounted at the inside the base edge of the membrane 8.

The bell-shaped element 24 also has at least one opening 27 which communicates the internal cavity 2 and the cavity 28 towards which the movable core 13 is turned.

 The reinforcing element 9 of the membrane has a tubular central part 9a which is mounted so as to be able to move on the fixed journal .21. The reference 29 designates a sealing cap, made of flexible rubber, which surrounds the tubular part 9a of the reinforcing element 9 and the fixed pin 21. The sealing cap 29 is fixed at one end to the reinforcing element 9 and comprises at the opposite end, a sealing ring 30 mounted so as to be able to slide on the pin 21. The adhesion of the sealing cap 29 on the fixed pin 21 is favored by the fact that said cap is subjected externally at water pressure and internally at atmospheric pressure.

The operation of the valve shown in the
Figure 2 is as follows
When the electromagnet (not shown in the
Figure 2) is not energized, the valve is in the closed position (shown in Figure 2). In this position, the membrane 8 is in contact with the valve seat 6, which means that the connection between the inlet 3 and the outlet 4 is interrupted. The movable core 13 is in the closed position of the restricted orifice 11, so that the communication between the internal cavity 2 and the outlet opening 5 through the opening 27, the orifice 11, the passage 22 and the passage 10 is interrupted. The diaphragm 8 is held against its seat 6 under the effect of the various pressures acting on its two faces. Indeed, in a manner analogous to that which occurs in the case of the valve of FIG. 1, the internal cavity 2 communicates the inlet 3 through the opening 8a of the membrane 8, so that it is under water pressure, while the face of the membrane facing the outlet opening 5 is subjected to atmospheric pressure .

 The valve is opened by controlling the excitation of the electromagnet. Following this excitation, the movable core 13 moves under the action of the spring 9, moving away from its closed position of the restricted orifice 11. The internal cavity 2 and the opening are thus communicated outlet 5 through the opening 27, the cavity 28, the orifice it; passage 22 and passage 10.

There is therefore a pressure drop inside the interior cavity 2 which causes the raising of the membrane 8 and the opening of the communication between the inlet 3 and the outlet opening 5. During the displacement of the membrane 8, the reinforcing element 9 slides on the fixed pin 21 and the cap 29 slides on the pin 21. The element 21 does not move during the opening, the stroke of the movable core 13 necessary to guarantee correct operation of the valve at the time of opening is relatively short, which means that the power required of the electromagnet is substantially lower than that which is necessary in the case of the valve of the
Figure 1.

 When the electromagnet is no longer energized, the movable core 13 closes the orifice 11 thus cutting off the communication between the interior cavity 2 and the outlet opening 5. Consequently, inside the cavity 2, the water pressure is restored and the membrane 8 is again brought into contact with the seat 6, in the cut-off position of the connection between the opening 3 and the inlet 4 of the valve.

 The present invention obviously extends to other models which pursue the same objective by using this same innovative concept.

Claims (6)

 1. Solenoid valve, in particular for washing machines, such as washing machines, dishwashers and the like, comprising  a valve body 11) having an internal cavity (2),  an annular inlet passage (7) opening into said interior cavity (2) and communicating with a source of pressurized liquid,  an outlet opening (5),  an annular wall (6) serving as a valve seat which delimits said outlet opening (5) and which is surrounded by said annular inlet passage (7),  a flexible membrane (8) fixed along its periphery to the wall of said interior cavity (2) and having a central part cooperating with said valve seat (6), for controlling the flow of liquid between said annular passage inlet (7) and said outlet opening (5), this membrane (8) being provided with at least one opening (8a) which communicates the annular inlet passage * (7) and said interior cavity (2 ),  a reinforcement element (9) fixed in a central opening of the membrane (8) and traversed by a passage (10) which communicates with said interior cavity (2) through a restricted orifice (11),  an electromagnet (12) comprising a movable core (13), a guide element (14) of the movable core, a spring (19) which pushes the movable core (13) towards a closed position of said restricted orifice (11 ), and an electromagnetic coil (20) for moving the movable core (13) away from said closed position,  characterized in that said restricted orifice (11) cooperating with the movable core (13) of the electromagnet is formed in a fixed element (21) relative to the body of the valve and communicates in leaktight manner, with said passage ( 10) of the reinforcing element (9) of the membrane (8).  2. Solenoid valve according to claim 1, characterized in that the reinforcing element (9) of the membrane (8) is mounted so as to be able to slide on said fixed element (21).  3. Solenoid valve according to claim 2, characterized in that the reinforcing element (9) of the membrane (8) is provided with a sealing cap (29) made of flexible material, surrounding the fixed element (21) and having one end fixed to the latter and the opposite end mounted so as to be able to slide on the reinforcing element (9) of the membrane (8).  4. Solenoid valve according to claim 2, characterized in that -the fixed element (21) consists of a pin traversed by an axial passage (22) which includes said restricted orifice (11) at one end of the pin cooperating with said movable core (13), and in that said journal is fixed to the center of a bell-shaped element (24) which is in turn fixed inside the interior cavity (2).  5. Solenoid valve according to claim 4, characterized in that said bell-shaped element (24) has at least one passage (27) which passes through it.  6. Solenoid valve according to claim 4, in which the periphery of the membrane (8) is clamped between a circular seat of the body (1) of the valve and a circular base edge of said guide element (14) of the movable core (13 ), characterized in that said fixed bell-shaped element (24) has a base circular edge (25) clamped between the edge of the membrane and said base edge of the guide element (14) of the movable core ( 13).