NO170819B - MICROELECTROVENT VALVE WITH A SIMPLE DIAFRAGMA - Google Patents

Abstract

The solenoid provides flow switching to at least two ways and comprises a body with a recess from which the fluid arrival and departure conduits open and a single membrane, serving the role of shutter to these positioned by means of a rocker which closes it against one or the other of the conduits in e to the alteration of the position of a slider which moves in the valve body under the action of an electromagnet. The membrane (23) is made up of an external flexible part (36) and a central part (37) in which is embedded the rocker (24), which has a rod perpendicular to the plane of the membrane and engaging in a recess (12) in the slider (3). The slider is pivoted on an axis (21) traversing the rocker.

Description

This invention relates to a reversible microelectrovalve for use with any fluid, and particularly aggressive or contaminated fluids. The invention relates in particular to a microelectrovalve with a rocker arm and a single diaphragm.

There are microelectrovalves that utilize two flexible diaphragms that are made of plastic material and can be deformed with the help of an electromagnet to close certain openings and open others. However, the latter can cause certain disadvantages because this type of microvalve is difficult to adjust due to the majority of parts they consist of. FR patent document no. 2 609 518 shows a microelectrovalve which is intended to remove these disadvantages in that it is reversible between at least two positions and comprises a valve housing with a recess which is connected to inlet and outlet channels for fluid, as well as a movable part which serves as a closing device for one or the other channel and can be moved using the core of an electromagnet. In this microelectrovalve, the moving part is a diaphragm with an oriented deformation which is brought to close one of the channels by means of a rocker arm, the rocker arm being moved from one of its equilibrium positions, which corresponds to any of the two closing positions of the diaphragm, by by a control device which is moved in the longitudinal direction of the valve housing by the core of the electromagnet.

Preferably, this control means consists of a sleeve which slides into the valve housing, the control sleeve being placed inside a well which leads through the valve housing along its longitudinal axis. One of the ends of the sleeve releases a mouth outlet in the well and the middle part has an opening for the insertion of a cam connected to the rocker arm. In FR patent no. 2 609 518 a preferred embodiment is described where the rocker arm has the shape of a crown with preferably a conical surface which, by means of a spring device, rests against a corresponding surface of the closing diaphragm, to bring the latter towards at least one opening, while opens to at least one opening next to it. The diaphragm thus coupled to the movement of the rocker arm is allowed to rock about an axis by a ball being placed on a seat in the valve housing to be centered on the diaphragm.

In order to limit the number of components and thereby make their assembly easier, it has been considered to cast the channel support plate directly together with a ball and also to form the diaphragm and rocker arm in one piece.

On the basis of the aforementioned conditions and a further development based on research in this area, the purpose of the present invention is to produce a microelectrovalve of a type similar to that shown in FR patent document no. 2 609 518, but which is improved with regard to miniaturization , simple construction and operational accuracy.

The invention therefore relates to a microelectrovalve for reversal between at least two positions and which comprises a valve housing which is connected via a recess to inlet and outlet channels for fluid, and a single diaphragm which serves as a closing device for said channels in that the diaphragm is arranged to be moved via a rocker arm of the core of an electromagnet to thereby bring the diaphragm towards one or the other channel, depending on the position taken by a sliding sleeve inside the valve housing when moving in the valve body's longitudinal direction by means of the electromagnet core, and where said diaphragm and rocker arm constitute an assembly , the diaphragm comprising an outer part which is flexible and a middle part in which the rocker arm is embedded, and part of the rocker arm is designed as a knob at right angles to the plane of the diaphragm to be arranged in a recess in said sleeve.

On this background of known technology in principle from the above-mentioned FR patent document and DE patent document no. 3 503 357,

US patent document no. 3 067 764 and no. 4 251 053, and GB patent document no. 1 226 481 have the microelectrovalve according to the invention as a distinctive feature that said assembly of diaphragm and rocker arm is connected to a shaft which is passed through the rocker arm and stored in vanes in one piece with the valve body. The diaphragm is preferably clamped between the edges of an opening in a side part of the valve housing and a profiled support plate that closes said opening, the profile of the side part essentially having the shape of a wide open V with two longitudinal flanges which are also V-shaped and surround the opening .

Further advantages and distinctive features of the invention appear from the subsequent description of an example of a preferred embodiment, which is also shown in the accompanying drawings, where: Fig. 1 is a schematic representation of the micro-electrovalve,

seen in cross-section from the side,

fig. 2 shows the valve housing, seen in cross-section from the side,

fig. 3 shows the valve housing, seen from below,

fig. 4 is an enlarged representation of the support plate, which is attached to the underside of the valve housing, seen in cross-section from the side,

fig. 5 is an enlarged view of the support plate shown in FIG

fig. 4, top view,

fig. 6 and 7 show the diaphragm with rocker arm, set respectively

from above and in cross-section from the side.

The micro-electrovalve shown in the drawings is made of a plastic material and is essentially designed as a square box which forms a valve housing 1. In a cylindrical well 2 which is drilled along the longitudinal axis of the valve housing, a control sleeve 3 is placed. A cylindrical end 4 of the guide sleeve, which slides into the well, can lie flush with the well's outlet. A chamber 6 is then formed between the bottom of the well and the other end of the sleeve. This chamber is connected to the outside of the valve housing through an opening, in which a movable core 7 of an electromagnet

(not shown) is fitted. The core is arranged at one end with a core head which is shaped like a hook 8 for engagement with a jaw 5 at the end of the sleeve 3. Furthermore, a spring 10 is placed between the bottom of the chamber 6 and the sleeve. In the sleeve 3 there is a shallow recess 12 which has a depth less than the thickness of the sleeve and which is oriented radially in relation to the axis AA<1> of the valve housing.

A side part 34 of the valve housing 1, which has the shape of a wide open V, is arranged with an elongated opening 32 at right angles to the recess 12 in the sleeve. As is more clearly evident from fig. 2 and 3, this elongate opening 32 is arranged centered in relation to a pit 33 which is essentially oval in shape and whose hollow part is produced by casting said side part 34 of the valve housing. The pit 33 and the opening 32 are centered in relation to the V tip. Similarly, two longitudinal V-shaped flanges are arranged on each side of the pit's longitudinal edges so that they overhang and surround the pit 33 and the opening 33 in their longitudinal direction. The edges in the pit 33 are designed so that they form a seat for the tight diaphragm 23 which is clamped between the valve housing and a support plate 16 which is screwed into the valve housing. Together with the support plate 16, the diaphragm forms a chamber 17 with a small volume.

Three small channels 18, 19, 20 for supplying or discharging fluid are drilled through the support plate 16 and open into said chamber 17. Two of these channels 18, 19 open into the chamber in an elevated area on the bottom of the support plate 16, while the third channel 20 opens directly onto the bottom of the support plate. The shape and profile of the support plate can be seen more clearly from fig. 4 and 5, which show that it has an upper V-shaped surface area 40 which is adapted to the side part 34 of the valve housing. The three channels 18, 19, 20 open onto the bottom of an elongated hollow pit 41, in which the diaphragm 23 can also be fitted. On the side edges which lie on each side of the pit 41, the support plate 16 is provided with side ribs 42 which are intended to cooperate with recesses 35 (fig. 3) in the side part 34 of the valve housing in order to achieve perfect placement of the support plate on the valve housing and maintain axial correctness location of axle 21.

The special structure of the diaphragm can be seen in greater detail in fig. 6 and 7. The diaphragm 23 consists of an outer flexible part 36 which is very soft and has a slightly V-shaped profile similar to the profile of the valve body, as well as an oval shape and a size corresponding to that of the pit 33, and an elongated central part 37 in which a rocker arm 24 is embedded, a lower surface of the rocker arm coincides with the profile of the diaphragm and an upper part of the rocker arm is designed as a cam at right angles to the plane of the diaphragm, and which through the opening 32 engages with a recess 12 in the sleeve 3. In the rocker arm 24 there is a through hole 38 which has an elongated shape to avoid lateral displacement of the diaphragm 23. When the diaphragm is clamped between the valve housing 1 and the support plate 16, the hole 38 is aligned with an opening 39 arranged at the V-shaped tip formed by the longitudinal flanges of the valve body, which form wings overhanging the hollow pit 33. A shaft 21 running through both the opening 39 in the valve body and the hole 38 in the rocker arm secures the diaphragm's location and constitutes its pivot axis. It is noted that said shaft is thereby located on the side of the diaphragm that does not come into contact with the fluid.

As shown in fig. 1, the cam 27 on the rocker arm is arranged so that it has a slight lateral inclination into the recess 12 in the sleeve 3, and is thus held against the edge of the recess. This lateral inclination means that the diaphragm is set at an angle and that the soft part of the diaphragm is thereby brought into close contact with the opening of the channel 19, while the channel 18 has an open connection with the chamber. This position is the electrovalve's rest position where the electromagnet is not energized. With the pressure from the spring 10, the sleeve 3 is held, as shown in the drawing, in a position all the way to the right, and the free end 4 of the sleeve is then flush with the outlet for the well 2. Fluid supplied to the chamber 17 via the channel 20 can thereby flow freely towards the channel 18.

When the electromagnet becomes live, the core 7 over its hook head 8 exerts a pulling force on the jaw 5 at the end of the sleeve 3, so that the pressure exerted by the spring 10 is counteracted. The sleeve 3 is then moved to the left, away from the position shown in fig. 1. While this movement is in progress, the edge of the recess 12 comes into contact with the edge of the cam 27, and the rocker arm 24 is driven above its rocker point. At the same time, the diaphragm is rotated about the shaft 21 and set at an angle in a position opposite to the previous one, being released from the channel 19 and then brought towards the channel 18. A flow passage is then created between the channel 20 and the channel 19. Due to the elevation of the mouths for the channels 18, 19 in relation to the bottom of the pit, the middle part 37 of the diaphragm is able to be pushed down on its seat, so that poor sealing due to impurities is avoided.

When the electromagnet is no longer current-carrying, the sleeve 3 is again driven under the biasing pressure from the spring 10 back to the position shown in fig. 1, and the spring pressure then ensures, via the rocker arm, that the sleeve is held firmly in this position. It should be noted that a user can also operate the sleeve himself by pushing on the sleeve end 4 which is flush with one side of the electrovalve. In other words, it is possible to activate the valve manually in the event of a failure of the electromagnet.

Since the chamber 17 between the diaphragm 23 and the support plate 16 is small in size, the dead volume of the fluid is also small, which facilitates cleanliness. Furthermore, the single diaphragm not only serves as a sealing disk on its seat, but it also ensures complete tightness between the outer parts of the valve and its well 2, in which the sleeve slides. This tightness is ensured both for liquid fluids under pressure and for gaseous ones fluids under high or low pressure, possibly in vacuum. The mass of the valve housing has been reduced without the cross-section of the flow of the fluid passage through the channels 18, 19, 20 being limited for this reason.

Such reversible microvalves can be fixed in series in a regulated space, as it is easy to make connections to the channels, which are located on the same side. This type of microvalve is manufactured with the advantage of materials that can resist aggressive fluids, and is preferably suitable for use in medical analysis devices, as well as in food production and the like.

Claims (6)

1. Micro-electrovalve for reversing between at least two positions and comprising a valve housing (1) which is connected via a recess (17) with inlet and outlet channels (18, 19, 20) for fluid, and a single diaphragm (23) which serves as a closing device for said channels in that the diaphragm is arranged to be moved via a rocker arm (24) by the core of an electromagnet in order to thereby bring the diaphragm towards one or the other channel, depending on the position taken by a sliding sleeve (3) inside in the valve housing by movement in the longitudinal direction of the valve housing using the electromagnetic core, and where said diaphragm (23) and rocker arm (24) form an assembly, the diaphragm comprising an outer part (36) which is flexible and a middle part (37) in which the rocker arm (24) is embedded, and part of the rocker arm is designed as a knob (27) at right angles to the plane of the diaphragm to be arranged in a recess (12) in said sleeve (3), characterized in that said assembly of diaphragm (23) and rocker arm (24) is closed a shaft (21) which is guided through the rocker arm and supported in wings (35) in one piece with the valve housing (1). 2. Micro-electrovalve according to claim 1, characterized in that the recess (12) in which the rocker arm's cam-shaped part (27) is designed to be arranged, has a shallow depth that is less than the thickness of the sleeve (3), and is radially oriented in relation to the valve body's axis (ÅA1 ). 3. Microelectrovalve according to claim 1, and where said diaphragm (23) is clamped between the edges of an opening (32) in a side part (34) of the valve housing and a profiled support plate (16) which closes said opening, characterized in that said side part's (34) profile essentially has the shape of a wide-open V with two longitudinal flanges (35) which are also V-shaped and which surround the opening (32). 4. Micro-electrovalve according to claim 3, characterized in that said opening (32) is centered in relation to a pit which is essentially oval in shape and is hollowed out by casting the side part (34) of the valve housing, said pit serving as a seat for the tight diaphragm (23). 5. Micro-electrovalve according to claim 3, characterized in that the side part (34) of the valve housing is designed with recesses (35) for cooperation with corresponding side ribs (42) arranged on both sides of the support plate (16). 6. Microelectrovalve according to claim 1, characterized in that the shaft (21) is guided through an object (38) with an elongated cross-section arranged transversely in the rocker arm (24).