Source: https://patents.google.com/patent/EP1103992A1/en
Timestamp: 2020-08-05 04:42:22
Document Index: 141894709

Matched Legal Cases: ['art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 71', 'art 92', 'art 93', 'art 40', 'art 111', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 40', 'art 240', 'art 240', 'art 240', 'art 240', 'arts 240', 'art 171', 'art 171']

EP1103992A1 - Miniature electromagnetic valve and assembling procedure - Google Patents
Miniature electromagnetic valve and assembling procedure Download PDF
EP1103992A1
EP1103992A1 EP00403161A EP00403161A EP1103992A1 EP 1103992 A1 EP1103992 A1 EP 1103992A1 EP 00403161 A EP00403161 A EP 00403161A EP 00403161 A EP00403161 A EP 00403161A EP 1103992 A1 EP1103992 A1 EP 1103992A1
EP00403161A
EP1103992B1 (en
1999-11-24 Priority to FR9914775 priority Critical
1999-11-24 Priority to FR9914775A priority patent/FR2801416B1/en
2000-11-14 Application filed by Parker Hannifin Rak SA filed Critical Parker Hannifin Rak SA
2001-05-30 Publication of EP1103992A1 publication Critical patent/EP1103992A1/en
2008-09-10 Publication of EP1103992B1 publication Critical patent/EP1103992B1/en
Miniature solenoid valve comprising: a solenoid valve body (1), an electromagnet with a cylinder head (7) and a plunger core (9) movable relative to the cylinder head along a longitudinal axis (2), a pneumatic chamber (13), in which chamber freely opens a first conduit (31, 32) and, each through a seat (48, 49), a second and a third conduit (29, 30), the outlets of the second and third conduits being coaxial with the longitudinal axis (2) of the electromagnet and opposite one another, a first (15) and a second valves (50), framing with play the two seats, the first valve being carried by the plunger core and the second valve being carried by a movable assembly held in contact with the plunger core to be moved therewith, in which the two seats (48, 49) are provided at the end of a single piece (40) which internally comprises the ends (46, 47) of the second and third conduits, c ette piece being reported in the body (1) of the solenoid valve in the direction of the common axis (2) to the electromagnet and the seats and immobilized in a precise position along this axis and specific to each solenoid valve . <IMAGE>
The present invention relates to a solenoid valve miniature (pneumatic) whose design allows economical manufacturing processes guaranteeing performance of high quality.
The progression of pneumatic automation is linked to the miniaturization of its components and in particular solenoid valves for controlling the distribution. The builders are thus gradually spent in a few years of solenoid valves, the most small dimension was greater than 20 mm to solenoid valves whose dimension reaches 10 mm. However the making solenoid valves of this size goes through costly solutions that only provide reduced performance due to difficulties encountered in the control with precision of the dimensions of the parts which constitute its functional elements and assembly procedures to obtain quality constant from one solenoid valve to another. Indeed the decrease in dimensions resulted in decrease in fluid passage sections therefore pneumatic power available at the output of the solenoid valve and we see that in many cases the sum of manufacturing tolerances and mounting of the functional parts of the solenoid valve is, in these dimensions, of the same order of magnitude as one dimensions of the passage sections.
Furthermore on the electromagnetic level the power of these devices is carried out at very low power due to a very miniaturized winding. The effective stroke of the plunger core of the solenoid operation of the valve (s) is then extremely reduced.
It follows from these constraints that it is necessary to put implements an extremely careful manufacture of the parts of the solenoid valve and / or a complex mounting procedure so to make precise adjustments for each solenoid valve and individuals who penalize the cost price. We will quote for this purpose the document FR 2.643.370 which is an illustration of one of these expensive technological solutions.
For the record, we will also cite a certain number of documents such as DE 2,340,304, DE 1,871,835 U, DE 4,125,816, US 3,303,854 and FR 1,198,043 which all describe solenoid valves of a structure close to that of the invention but which are not adapted to a industrial miniaturization achievable at a cost acceptable.
By the present invention is meant to remedy these disadvantages by proposing a solenoid valve whose structure is simple to manufacture and assemble which leads to significant cost reduction, quality manufacturing constant and the possibility of obtaining a pneumatic power greater than that required for the sole management of distributors.
Indeed, another objective of the invention, which is achieved by the very design of this solenoid valve, is to constitute a direct control organ for small cylinders. These small cylinders have a fluid consumption pneumatic which requires internal passage sections of their control member corresponding to a diameter of about 1 mm, which is much greater than the cross-section of passage necessary to order distributors.
To this end, the subject of the invention is a miniature solenoid valve comprising:
a solenoid valve body,
an electromagnet with a cylinder head secured to the body and a plunger core movable relative to the cylinder head along a longitudinal axis of the electromagnet,
a pneumatic chamber formed in the body on the side of one end of the plunger core opposite the cylinder head, into which chamber freely opens a first conduit and, each through a seat, a second and a third conduit, the outlets of the second and third conduits being coaxial with the longitudinal axis of the electromagnet and opposite each other,
a first and a second valve, framing with play the two seats, the first valve being carried by the plunger core and the second valve being carried by a movable assembly kept in contact with the plunger core by an elastic return member to be moved with this the latter between a first position corresponding to the excited state of the electromagnet in which the plunger core is in abutment against the cylinder head and a second position corresponding to the absence of excitation of the electromagnet in which the first valve is in abutment against its seat, the two seats being formed at the end of a single part which internally comprises the ends of the second and third conduits, this part being attached in the body of the solenoid valve in the direction of the common axis to the electromagnet and to the seats and immobilized in a precise position along this axis and specific to each solenoid valve.
This first provision is that which allows to control industrially the relative position of seats relative to the stroke of the electromagnet and especially compared to the most effective part of this race, as will appear from the description below.
In a first embodiment, the crew above includes a set of spacers extending between the valves, outside said valve-holding part, of which the length is equal to the distance between the two seats increased by the desired stroke of each valves. Insofar as the material of the second valve is deformable, it may be better than the face of the second flap facing its seat is surmounted by a washer spacer support device, the distance between the bearing surface of the spacers of the surface of the active part of the valve decreasing in length spacers.
It results from this structure a great mastery pneumatic stroke. Indeed this mastery goes through the relationship between the dimensions of the seat piece and spacers. By choosing a metallic material for these organs and a manufacturing process by machining (bar turning), we obtain relatively little costly a great precision of their dimension. We additionally eliminates direct contact between the spacers metallic and the valves which are necessarily in a deformable material based on elastomer, avoiding inlays of these spacers in the surface of this material which, in operation, introduces hazards into the value of the stroke that we are trying to keep constant and in the relative position of the moving elements, especially if the steering efforts or the efforts resistant to overcome at the valves vary. We will notice that this washer adds a tolerance to control for determining the pneumatic stroke, which is not a problem because the manufacture of this washer (cutting) allows to respect tolerances tight.
By the way, to change the race, which determines the internal passage section of the solenoid valve there just change the seat part only, with therefore the same precision control.
In a second embodiment the part seat carriers and the moving crew are in material thermoplastic produced in the form of a cartridge pre-assembled comprising said part, the moving assembly with the second valve, a plug attached to the part seat holder on the side of the second valve and an elastic member reminder placed between the cap and the second valve, the moving part being formed by a stirrup made of thermoplastic comprising a cup for holding the second valve extended in one piece by at least two longitudinal branches parallel to the above common axis, crossing the seat-carrying piece and the ends of which are located on either side of the seat located in look of the first valve.
It will be noted in this case that the control of the pneumatic stroke takes place at the level of the realization of the cartridge in a simple way as will be described below.
One of the many advantages of this structure lies in the fact that, in the same valve body, through which we carry out in a standard way interface with external devices, we can put in place of the seat-carrying parts of the passage section of the different fluid and different lengths to define a stroke corresponding to the desired flow rate, which authorizes extremely standardized manufacture of solenoid valves different sizes. It will be recalled in this connection that, for maintain a passage section between seat and valve, for a given duct diameter, the stroke of the valve is equal to a quarter of this diameter. So we understand that if we want to double the passage diameter, so double the stroke, the increase in caliber requires increase the stroke by a value equal to a quarter of diameter of the lowest gauge and that it is easy to provide in the body of the solenoid valve (for example in plastic) a pneumatic chamber of dimensions unique for all calibers capable of containing the maximum stroke, setting the parameters governing the value of the stroke being achieved by independent parts valve body and reported to it.
Among the other features of the invention which will be described below, we will indicate that according to which the seat-holder part is of revolution provided externally from three axially clamping means spaced from each other for fixation in the body made of plastic and, between these clamping means, two outer grooves forming sections, second and third conduits between their terminal portion contained in the room and their portion arranged in the body, sections that are tight to each other and to each other of the pneumatic chamber. The assembly of this piece at valve body, in the pneumatic chamber, is achieved by simply pushing one by force into the other. This, associated with the fact that the body part forming the side wall of the pneumatic chamber is provided with an opening opening on the one hand in the area of the chamber containing the seat closest to the electromagnet and on the other hand, on the outer surface of the body opposite the laying surface to house a manual control, leads to a first method of manufacture of the particularly easy solenoid valve which provides all the details required for a quality and reliable solenoid valve.
Indeed, for the manufacture of solenoid valves with a seat-carrying part and a moving part metal and necklines, this process consists of the solenoid valve assembly, to be introduced through the orifice side of the manual control member before it place, a shim opposite the electromagnet, the thickness of the shim being equal to the desired stroke of the flaps and forcibly pushing the seat-holder part into the recess of the central core of the pneumatic chamber by a tool inserted through the end opening thereof before fitting the shutter until causing the abutment of the electromagnet core against its yoke and remove the shim. So, we got that the valve stroke corresponds precisely to the most efficient solenoid stroke, i.e. the one closest to the zero air gap, thus authorizing greater certainty of proper operation at power or low pneumatic flow and the realization of variants at high power (or high flow) when they are required.
In this regard, it will be recalled that, for a power given excitation, the force developed by the electromagnet is even higher than the plunger core is close to the breech and thus allows to better dominate the forces due to the pneumatic pressure applied to the seating section. However, these efforts depend on the section of the seat and therefore vary according to the desired flow rate so well that, for the same electromagnet, the resistant forces that it must overcome are different depending on the application solenoid valve. The mounting process indicated above allows you to be assured of a manufacturing which places the electromagnet in its condition optimal functioning, whatever the destination future of this solenoid valve, so the length of the stroke valves.
For the manufacture of solenoid valves in which the seat-carrying part and the moving part are prepared in cartridge, the invention relates to a second process which consists in assembling the cartridge, to calibrate the axial distance between the free ends of temples, stirrup and seat located next to the first valve and proceed to press fitting the cartridge into the body of the solenoid valve until a precise spacing between the first valve and its seat when the plunger core is resting on the cylinder head.
In this case, the above calibration is carried out by a partial fusion of the seat and the ends of the stirrup branches using an applied form tool hot on the corresponding end of the cartridge.
Finally, preferably, to obtain the aforementioned precise spacing, during the insertion of the cartridge in the body of the solenoid valve, we submit the electromagnet to a reference supply tending to attract the plunger against the cylinder head once reaches a determined air gap and stop sinking when the detachment of the first valve from its seat is found.
Other characteristics and advantages of the invention will emerge from the description of one of its modes preferred embodiment given below by way of example.
FIG. 1 is a view in longitudinal section of a first embodiment of a solenoid valve according to the invention,
FIG. 3 is a sectional view along line III-III of FIG. 1,
FIG. 4 is a sectional view along the line IV-IV of FIG. 1,
FIG. 5 is a sectional view along the line VV of FIG. 1,
FIG. 6 is a partial sectional view along the line VI-VI of FIG. 4,
FIG. 7 and FIG. 8 are detailed views along sections VII-VII and VIII-VIII of FIG. 1,
FIGS. 9A and 9B are two bottom views of the solenoid valve of FIG. 1 at the level of its pneumatic chamber,
FIGS. 10 and 11 schematically illustrate two possible associations of the solenoid valve of the invention with, for FIG. 10, a distributor and for FIG. 11, a connection base,
FIG. 12 illustrates a mounting method according to the invention with an alternative embodiment of the seat-carrying part.
FIG. 13 illustrates by a view in longitudinal section, a second embodiment of the solenoid valve according to the invention,
FIG. 14 is an exploded view of the main components of this solenoid valve,
FIG. 15 illustrates the principle used to calibrate the pneumatic stroke of the solenoid valve.
The solenoid valve shown in Figures 1 to 12 comprises an elongated body 1 having a general axis 2, of parallelepiped shape, therefore cross section substantially rectangular. Outwardly this body has four side surfaces including one surface upper 3, lower surface 4, parallel to axis 2 and forming the mounting surface of the solenoid valve. It is hollowed out into two main sections. In a first section 5 is housed an electromagnet 6 with a frame, a coil and a yoke 7 which are fixed to a wall terminal 8 of section 5 hollowed out.
In known manner the electromagnet has a plunger core 9 slidably mounted in a housing cylindrical which extends the cylinder head 7. A spring 10 housed in the plunger core 9 and acting on a piston 11 in pressing on the end surface of the cylinder head 7, tends to move the plunger core away from this cylinder head in the absence of excitement. When the electromagnet is energized, the magnetic forces involved overcome the effect of spring 10 for pressing the end 12 of the plunger core 9 against the end wall of the cylinder head 7 (zero air gap).
The end of the plunger opposite its surface 12 penetrates inside a second section 13 of the recess of the body 1 which forms the pneumatic chamber of the solenoid valve. This end is equipped with a plate 14 which is clipped to it, plate 14 of which the center is made of an elastomeric material which constitutes a first valve 15 of the solenoid valve. This valve 15, enclosed between the end of the core 9 and the plate 14, has been leveled so that its surface 16 faces the chamber 13 is flush with the radial surface of the plate 14. The recess of the body 1 which constitutes this chamber 13 opens out through a large opening 17 at one end longitudinal of the body 1 opposite to that which accommodates the electromagnet. This opening 17 is closed so final as will be seen below, with a plug 18, preferably metallic, fixed by crampons inside of the opening 17.
Inside the pneumatic chamber 13 on finds a central core 20 of axis 2 which is connected to the portions of the body 1 surrounding this chamber by walls radials such as 21, 22, 23 and 24 (Figure 4), the wall 24 being relatively thick and relatively wide and extending substantially perpendicular to the surface of pose 4.
The core 20 has a central recess cylindrical 25 of axis 2, more exactly formed of three stepped cylindrical sections 26, 27 and 28, section 26 smaller diameter being the one closest to the valve 15. In addition, the thick wall 24 has two conduits 29 and 30 opening into the recess 25 by one of their ends while their other end leads to outside the body 1 through the laying surface 4.
Furthermore, the body 1 has two other conduits 31 and 32, which form the alternative branches of the same functional duct, symmetrical to each other with respect to a plane perpendicular to face 4 and passing through axis 2 (the plane of figure 1), these conduits 31 and 32 opening outside the body 1 at the level of the laying surface 4 and by their other end, opening out in room 13. These conduits 31 and 32 are located in the same transverse plane of the solenoid valve.
Beyond the conduits 29 and 30, the body 1 has primers for conduits 33, 34 and 35 also located in the same transverse plane of the body at the level of the part of the chamber 13 closest to the plug 18, these primers being made perpendicular to the laying surface 4 and separated from the chamber 13 by a bottom 36, 37 and 38, bottom which constitutes a thin wall pierced for certain cases of use of the solenoid valve. The conduits that would thus formed form alternatives to conduits 31 and 32 for the same functional circuit as will be explained below. In this case, conduits 31 and 32 would remain primers, while they are represented drilled in the figures.
The solenoid valve has a functional part 40 housed by force in the recess 25 of the core 20 of the chamber 13, this part 40 being substantially shaped cylindrical with, in the alternative embodiment of the Figures 1 and 6, an outer surface which has three sets of ring spikes to cooperate with sections 26, 27 and 28 of the recess 25 in order to retain the part therein 40. In the variant shown in FIG. 12, on the one hand the recess 25 has only two cylindrical sections stepped and on the other hand room 40 has only two ring studs for cooperating with respectively each of the cylindrical sections of the recess 25. Between the two studs, the part 40 carries an O-ring 41 which seals between the two portions 25a and 25b of the recess 25 that this seal 41 determines between the crampons.
Between the crampons or between the crampons and the seal, part 40 has two grooves external 42, 43 into which respectively open two transverse conduits 44 and 45. From each of these transverse conduits, leave two sections of conduits axial 46, 47 opening onto the axial end faces of part 40. Around this outlet, each of the faces axial of the part 40 has a small bead 48, 49 which forms a seat on which a valve can be applied, such as the valve 15 for the seat 48 facing the electromagnet.
A second valve 50 is mounted in the chamber 13 opposite the axial end of the part 40 which carries the seat 49. This valve 50 is also made of a material elastomer. Insofar as this elastomeric material is not not of sufficient hardness, the valve 50 is surmounted on its face turned towards the seat, a washer metallic 51 which covers its periphery. Between this valve 50 and the plug 18 a spring 52 has been placed which tends to push the valve 50 towards the seat 49 but with a much less effort than that of the spring 10 which tends to press with the core 9 the valve 15 against the seat 48.
In the radial walls 22, 23, holes 53, 54, 55, 56 in which are freely mounted in sliding spacers 57, 58, 59, 60. These spacers are parallel to axis 2 and their longitudinal dimension is such that, the valves being permanently requested in reconciliation towards each other under the effect of spring 52, they maintain their spacing at a value which, measured between the active surfaces of the valves that is to say between the central surface areas which cooperate with the seats, is equal to the axial dimension of the part 40 increased by the desired stroke of the valves. In other words, the length of these spacers would greater than the axial length of the part 40 by a value equal to this stroke if the valve 50 was devoid of the metal washer 51, which may be the case when the valve material is of sufficient hardness to resist the sinking of the spacers and this during the lifetime of the solenoid valve. In the presence of washer 51, this value is reduced by the thickness washer 51.
The part of the body 1 which separates the chamber 13 from the upper surface 3 is provided with an orifice 61, the main function is to house a manual control of the solenoid valve. In this orifice 61 we set up a cylindrical insert 62 provided with external studs for its fixing when forced into the orifice 61, which has a cylindrical bore 63 with a shoulder upper 64, the end of this insert 62 being provided a diametral slot 65 receiving an elastic pin 66. This elastic pin 66 rests on a shoulder 67 port 61.
Inside the bore 63, we housed a cam member 70 sealingly turns in the bore 63 under the shoulder 64 and comprising a part flat 71 which crosses the pin 66. Under this part 71, the member 70 is extended by a cam 72 which, in the orientation angular imposed by pin 66, is discarded of the peripheral part of the radial surface of the plate 14 and which, when the member 66 is rotated in bore 63, against the elastic return effect of pin 66, comes into contact with this plate to push the moving core of the electromagnet towards of its breech. The rotary operation of this member 70 is allowed through a slot 73 accessible from the outside solenoid valve for a tool such as a screwdriver. This manual control can also be carried out, in a variant not shown, by a simple push-button slope, which enters the chamber 13, against the effort of a return spring, to push back the plate 14.
On the side of its end provided with the plug 18, the body 1 has an axial extension 80 forming a lower heel can be slipped into a housing provided for this purpose on the distributor or base to which is intended for the solenoid valve. The lower surface 81 of the heel 80 is coplanar with the mounting surface 4 of the solenoid valve.
At its other end, the body 1 contains all an electrical and electronic circuit 82 for supply and coil overvoltage protection electromagnet, circuitry with input terminals and output are formed by two pins 83, 84 in the form of teeth substantially perpendicular to the installation surface 4 and whose most extreme profile 85 in a parallel plane in the plane of Figure 1 is in the form of a substantially arc of circle whose center is located in the vicinity of the outgrowth heel 80. This profile will facilitate racking and removing the solenoid valve inside or outside the terminals females carried by a base associated with the distributor to which the solenoid valve will be fixed or by a connector of this distributor. Indeed, the natural movement of setting place of the solenoid valve consists first of all in accommodating the heel 80 in the housing which must receive it, the solenoid valve being slightly tilted down the side of this housing and then flip that solenoid valve around of the pseudo-joint formed by the heel placed in this housing in order to carry out electrical racking.
The body 1 is finally capped with a tip or cover 90 also made of plastic, attached by gluing with press fitting or cold welding in a reserve 91 provided on the outer surface of the body 1. This hood will have slots in its fitting part 92 to overlap pins 83, 84. It can also have an upper transparent part 93 through from which we can see the radiation of a diode light emitting indicator 86 belonging to circuit 82. Finally, the cover will be provided with an end tab 94 intended to receive a fixing screw 95.
The technique of making the body 1 by injection request to remove parts as much as possible massive plastic material to be injected. That's why that body 1 has a certain number of recesses external reserves such as those noted 96, 97 and 98 in the figures. The recess 96 may be covered with a plate 99 kept coupled to the body by the insert 62 belonging to the manual control while one of the recesses 98 can advantageously receive an insert metallic with one or two threaded holes forming an alternative means of attachment to the heel 80 or to the screw 95.
The laying surface 4 will have a grooving 100 surrounding each of the outlets of the conduits 29, 30, 31, 32, 33, 34 and 35 in order to seal the connection of these orifices with the complementary orifices which will provided on the body of the distributor or the base. According to whether or not the primers of conduits 31, 32 are put into service, 33, 34, 35, we will choose the flat joint of shape suitable for sealing to be carried out.
This is how Figure 9A illustrates a joint 101 which isolates the orifices 29, 30, 31 and 32. FIG. 10, by a schematic partial section, illustrates the fact that, on a distributor D, control of the drawer T takes place by two solenoid valves according to the invention, one having its conduit 31 connected to a pilot chamber C1 and the other having its conduit 32 connected to a control chamber C2. The solenoid mounting surfaces are equipped with a seal 101 (FIG. 9A) and the primers of conduits 33, 34, 35 are not pierced.
FIG. 9B illustrates a configuration joint 102 different and reserve 98 provided with an insert threaded 103. The seal 102 surrounds the orifices 29, 30 and 34 by isolating them, this last orifice 34 communicating with the chamber 13 by piercing its bottom 37 (Figure 5). The conduits 31 and 32 are left in this case in the state primers, as well as primers 33 and 35. The case the use of the solenoid valve is illustrated in figure 11. The solenoid valve is connected to a base 104 provided with a pressure line 105, common exhaust 106, and an output 107. The fixing of the solenoid valve on the base is provided by cooperation of the heel 80 with a housing 108 which it comprises for this purpose and by a screw 109 cooperating with the insert 103.
In FIG. 12, the diagram is illustrated method of fitting the part 40 seat carrier to inside the room 13 so inside the housing 25 of its core 20. At this stage of mounting the solenoid valve, the plunger core 9 of the electromagnet is placed in its housing with the valve 15 inside the chamber 13. The pneumatic part of the solenoid valve, that of right in Figure 1, is not yet equipped with its manual control, which allows to introduce into the chamber 13, transverse to axis 2, a thickness shim 110 whose active part is fork-shaped 112 extended by a gripping or maneuvering part 111, this fork having the function of preventing the seat 48 does not relate directly to the shim and either damaged by this contact. The thickness of the branches of the fork will be equal to the desired stroke increased by the height of the projection formed by the seat 48 relative to the end face of the part 40 which carries it. Thanks to a pushing tool 113, after having installed the shim of thickness 110, the part 40 is forced into the housing 25. During its penetration, the part 40 enters in contact with the shim 110 thickness, pushes it back direction of the electromagnet cylinder head while driving thus the plunger against the effect of the spring 10 until the core abuts on this cylinder head. At this moment the part 40 is perfectly put in place and position of seats 48 and 49 is optimal for benefit from an efficient stroke of the electromagnet. We will have noted that the pushing tool 113 has a surface active hollowed out 114 in its center to preserve integrity of the bead 49 forming a seat for the valve 50.
To complete the assembly of the solenoid valve, will suffice to install the spacers 57 to 60 in their holes, the washer 51, the valve 50 and the spring 52 and close the orifice 17 by the cap 18 clipped. Finally, we will end with the establishment of the manual command.
A variant of this method of setting up the room 40 seat holders inside room 13 consists in operating in the following manner. Before the introduction of the part 40 by the tool 113, we put in places spacers 57 to 60 in housings 53 to 56 formed in the radial walls 22 and 23. We then force the penetration of the part 40 using the tool 113 until this tool comes up against spacers 57 to 60 and until they themselves are stopped in translation by the core 9 which has come into abutment against the cylinder head 7. The thrust plane of the spacers on tool 113 will be identical to that which contains seat 49 so that when the sinking is stopped the part 40 will be at the precise position desired for the optimization of the stroke electromagnetic. This variant has the advantage, over the process with shim, to eliminate the recourse to the latter which is reduced in size therefore fragile and difficult to extract after pressing.
We will briefly explain the operation of a like solenoid valve. The conduit 29 communicates with a pressure source via distributor or equipped device of the solenoid valve. When the electromagnet is not excited, the spring 10 presses the valve 15 against the seat 48 and pushes the valve 50 against the effect of the spring 52 by means of spacers 57 to 60. The duct 31, 32 open freely in room 13, therefore communicates with the conduit 30 which is connected for example to a conduit common exhaust collection, via chamber 13, the conduit 47 which opens there through the uncovered seat 49, the duct 45 and the groove 43.
When the electromagnet is excited, the core is quickly and frankly called back against the cylinder head 7 which allows the spring 52 to repel the moving assembly formed by the valve 50, the washer 51 and the spacers 57 to 60. The valve 50 therefore comes to close the communication. between conduit 47 and chamber 13, conduit 44 of pressure then being opened on chamber 13 and the pressure from the duct 29 invades the duct 31, 32. It there is therefore a pressure that reaches a control of the distributor equipped by the solenoid valve allowing to change state or which reaches any other organ that the solenoid valve is responsible for supplying. When the electromagnet 6 ceases to be excited, this piloting or this organ is then purged because put at the exhaust because the spring 10 of the electromagnet switches communications inside room 13.
The variant of the solenoid valve according to the invention shown in Figures 13 and 14 resumes most of the elements already described with references incremented by a value 200. This is how it presents an elongated body 201, having a general axis 202, of parallelepiped shape, therefore cross section substantially rectangular. Outwardly this body has a lower surface 204, parallel to the axis 202 and forming the mounting surface of the solenoid valve. he has two main sections. A first section 205 is overmolded on an electromagnet 206 with a armature, a coil and a cylinder head 207. The plunger core 209 is moved aside by the spring 210 in the absence of excitement. The end of the plunger core opposite the breech enters a second section 213 of the body 201 which contains the pneumatic chamber of the solenoid valve. This end is fitted with a first valve 215 of the solenoid valve. The recess of the body 201 which constitutes this chamber 213 opens out through a wide opening 217 to one of the longitudinal ends of the body 201 opposite to the one containing the electromagnet. The pneumatic chamber 213 has a central recess 225 with a cylindrical axis 202, formed as in the variant already described, of three stepped cylindrical sections. Likewise, two conduits 229 and 230 opening into the recess 225 by one of their ends while their other end opens to the outside of the body 201 through the installation surface 204.
The conduits 231 to 235 have the same role as the conduits 31 to 35 of the previous figures.
The solenoid valve has a functional part 240 forcibly housed in the recess 225 of the chamber 213, this part 240 being of substantially cylindrical shape with an exterior surface that has three sets of ring studs to cooperate with the recess 225 so retain exhibit 240 there.
As in the previous embodiment, between the studs, piece 240 has two external grooves in which respectively open two conduits transverse. From each of these transverse conduits, leave two sections of axial conduits 246, 247 opening onto the axial end faces of the part 240. Around this outlet, each of the axial faces of the part 240 forms a seat 248, 249 on which can apply a valve, so valve 215 for seat 248 facing the electromagnet.
The second valve 250 is mounted opposite the seat 249. Between this valve 250 and a plug 218, a spring 252 tends to push back the valve 250 towards the seat 249 but with a much less effort than that of the spring 210 which tends to press the valve 215 against the seat 248.
In this variant, the second valve 250 is arranged in a cup 151 with an open bottom extended by two spacer arms 152, 153, all forming a stirrup 154. The branches 152, 153 pass through freely room 240 by framing the internal conduits so that their free end is close to seat 248 close to valve 215. They play the role of spacers of the previous variant and their length is adjusted in result.
In an advantageous embodiment of this second variant embodiment, the mobile assembly that form the stirrup 154 and the valve 250, the spring 252, the part (insert) seat carrier 240 and the plug 218 is preassembled into a cartridge 155 as illustrated by Figures 14 and 15. We see in these figures that the stirrup and the spring are kept engaged in the insert 240 by the plug 218 which is secured by any means to the insert. In this state, the valve 250 is pressed against the seat 249.
One of the advantages of this variant lies in the choice of making parts 240 and 154 by molding (injection) of plastic. We get a cost of much lower manufacturing than by turning like described above but at the expense of accuracy dimensional of the parts. But this one, as we have seen higher, is essential for good performance of the solenoid valve.
To remedy this, we carry out a recovery of the cartridge 155 assembled as illustrated in FIG. 15. This recovery consists, with adequate tools, in immobilize the stirrup 154 relative to the insert 240 (by example by means of jaws 156, 157 which press the arms 152, 153 of the stirrup against the internal surface of the through holes 158, 159 where they are housed) then to apply a tool of form 160 intended to conform to the times the end of these branches 152, 153 and the seat 248 insert 240. This tool can be of any kind appropriate. Preferably however, it will be carried out in the form of a hot punch which will carry out this conformation by partial fusion of the two parts at contact which it will be worn under pressure and for a specified time.
Each cartridge is thus provided with an axial offset of precise value between the free end of the branches 152, 153 and the seat 248 equal to the dimension denoted h in FIG. 15 at the nose of the tool, dimension which corresponds precisely to the stroke desired tire.
The cartridge 155 then forms a unit which is inserted into section 213 of body 201 by pushing in force in bore 225. During this controlled insertion the stirrup rests on the end of the core 209, disappears so that seat 248 comes into contact with valve 215. A continued sinking therefore causes displacement towards the cylinder head 207 of the core 209. It has been found that supplying the electromagnet under a determined voltage, causes the attraction of the nucleus against the breech for a determined air gap value. So we determined the reference voltage so that this value corresponds to the desired stroke of the core. So we stop the sinking of the cartridge when the core is attracted to the cylinder head while the electromagnet is supplied under this reference voltage. A simple signal of this attraction brutal can be the pressure that builds up in the conduits 231, 232 - while conduit 129 is connected to a source of pressure - due to the detachment of the valve 215 compared to seat 248.
The body 201 is provided with an orifice 261, the main function is to house a manual control of the solenoid valve 262 which acts as previously described on nucleus 209.
We will still note some details differentiating this variant from the previous one:
heel 280 is here located on the side of the electromagnet,
the tab 294 is itself in one piece with the body 201 and located at the "pneumatic" end of the solenoid valve. It receives a self-tapping fixing screw 295,
the cover of the solenoid valve is produced by a single piece 170 comprising a part 171 intended to be snapped onto the body 201 and a flap 172 hinged to the part 171 to cover the tab 294 and to be snapped onto it by a tongue 173 of its lower free end.
Miniature solenoid valve comprising:
a solenoid valve body (1, 201),
an electromagnet with a yoke (7, 207) secured to the body and a plunger core (9, 209) movable relative to the yoke along a longitudinal axis (2, 202) of the electromagnet,
a pneumatic chamber (13, 213) formed in the body on the side of one end of the plunger core opposite to the cylinder head, into which chamber freely opens a first conduit (31, 32; 231, 232) and, each through a seat (48, 49; 248, 249), a second and a third conduit (29, 30; 229, 230), the outlets of the second and third conduits being coaxial with the longitudinal axis (2, 202) of the electromagnet and opposite to each other,
a first (15, 215) and a second valve (50, 250), framing with play the two seats, the first valve being carried by the plunger core and the second valve being carried by a movable assembly maintained in contact with the plunger core by an elastic return member (52, 252) to be moved with the latter between a first position corresponding to the excited state of the electromagnet in which the plunger core is in abutment against the cylinder head and a second position corresponding to the absence excitation of the electromagnet in which the first valve (15, 215) bears against its seat (48, 248), characterized in that the two seats (48, 49; 248, 249) are arranged at the end of a single part (40, 240) which internally comprises the ends (46, 47; 246, 247) of the second and third conduits, this part being attached in the body (1, 201) of the solenoid valve in the direction of the common axis (2, 202) to the electromagnet and to the seats and immobilized in a precise position along this axis and specific to each solenoid valve.
Solenoid valve according to claim 1, characterized in that the moving crew includes a game spacers (57, 58, 59, 60) extending between the valves, outside said seat-carrying part (40), whose length is equal to the distance separating the two seats (48, 49) increased by the desired stroke of each valves (15, 50).
Solenoid valve according to claim 2, characterized in that the face of the second valve (50) facing its seat (49) is surmounted by a washer device (51) supporting the spacers (57-60), the distance between the bearing surface of the spacers of the surface of the active part of the valve (50) coming in reduction in the length of the spacers (57-60).
Solenoid valve according to claim 2, characterized in that the part (40) carrying the seats and the spacers (57,58,59,60) are metallic and produced by machining.
Solenoid valve according to claim 1, characterized in that the moving part is formed by a caliper (154) of thermoplastic material comprising a cup (151) for holding the second valve (250) extended in one piece by at least two branches longitudinal (152, 153) parallel to the above common axis, crossing the seat-carrying part (240) and the free ends are located on either side of the seat (248) located opposite the first valve (215).
Solenoid valve according to claim 5, characterized in that the moving part and the seat-carrying part (240) also in thermoplastic material are produced in the form of a preassembled cartridge (155) comprising said part (240), the movable assembly with the second valve (250), a fixed plug (218) on the part seat holder on the side of the second valve and an elastic member return valve (252) placed between the plug and the second valve.
Solenoid valve according to claim 1, characterized in that the seat-carrying part (40, 240) is of revolution provided externally with three means of axially spaced from each other for its fixing in the body (1, 201) of plastic material and between these means of clamping, of two external grooves (25a, 25b, 42, 43) forming sections of the second and third conduits, between their terminal portion formed in the room (40, 240) and their portion (29, 30; 229, 230) formed in the body, these sections being sealed between them and with respect to the pneumatic chamber (13, 213).
Solenoid valve according to claim 1, characterized in that the material body (1, 201) plastic is provided with a flat outer surface (4, 204) of installation, parallel to the abovementioned longitudinal axis (2, 202) with a fixing lug (94, 294) to one of its ends and a hooking heel (80, 280) to its other end.
Solenoid valve according to claim 8, characterized in that the body (201) is equipped opposite to its mounting surface (204) of a snap-on cover (170) having an articulated flap (172) for masking the tab fixing (294).
Solenoid valve according to claim 8, characterized in that the body (201) is molded onto the fixed parts of the electromagnet and have a recess central open at its end opposite the electromagnet, forming the pneumatic chamber (13, 213) and provided with a shutter (18, 218) permanently attached to the body (1, 201).
Solenoid valve according to claim 10, characterized in that the body (1) forms in the chamber pneumatic (13), a central core (20) provided with a recess (25) fitted with the part (40) seat carrier and connected to the rest of the body by at least one wall (24) extending substantially perpendicular to the surface external installation and in which the second and third conduits (29, 30).
Solenoid valve according to claim 11, characterized in that the body part (1) forming the side wall of the pneumatic chamber (13) is provided an orifice (61) opening on the one hand into the zone containing the seat (48) closest to the electromagnet and on the other hand, to the external surface (3) of the body (1) opposite the laying surface (4).
Solenoid valve according to claim 11, characterized in that the above-mentioned orifice (61) is equipped a manual control member (70) which includes a finger (72) for actuating the plunger core (9) of the electromagnet cooperating with the end of the latter.
Solenoid valve according to claim 8, characterized in that the aforesaid three conduits (29, 229; 30, 230; 31, 231 -32, 232) lead outside the body through its laying surface (4, 204).
Solenoid valve according to claim 14, characterized in that the first conduit has two branches, 31, 32; 231, 232) separate, symmetrical one of the other with respect to a plane perpendicular to the surface laying (4, 204) and passing through the longitudinal axis (2, 202) from the body.
Solenoid valve according to claim 15, characterized in that the body (1, 201) has at least a primer (33, 34, 35; 233, 234, 235) of a branch additional of the first duct, perpendicular to the laying surface (4, 204) and whose bottom (36, 37, 38) constitutes a wall to be drilled to establish communication between this primer and the pneumatic chamber (13, 213).
Method of mounting the seat-carrying part in the body of the solenoid valve according to claim 2, characterized in that it consists in setting up the spacers (57-60) in the body (1) and press down the seat carrier piece (40) in the pneumatic chamber by a tool (113) which also pushes the spacers (57-60) through the opening (17) before fitting the shutter until the nucleus stops (9) of the electromagnet against its cylinder head (7) by through the spacers.
Method of mounting the seat-carrying part in the body of the solenoid valve according to claim 12, characterized in that it consists in introducing through the orifice lateral (61) for housing the manual control member before its installation, a shim (110) in front the electromagnet, the thickness of the shim being equal to the desired stroke of the valves (15, 50), to force the piece (40) seat carrier in the pneumatic chamber (13) by a tool (113) introduced through the opening (17) end of the latter before fitting the shutter up to cause the abutment of the core (9) of the electromagnet against its cylinder head (7) and remove the shim thick (110).
Method of manufacturing a solenoid valve according to claim 6, characterized in that it consists to assemble the cartridge (155), to calibrate the axial distance measured between the free ends of the legs (152, 153) of the stirrup (154) and the seat (248) located next to the first valve (215) and to proceed with the force-controlled fitting of the cartridge (155) in the body (201) of the solenoid valve until a precise spacing between the first valve (215) and its seat (248) when the plunger core (209) is in support on the cylinder head (207).
Method according to claim 19, characterized in that the above calibration is carried out by a partial fusion of the seat (248) and the ends of the legs (152, 153) of the stirrup (154) by means of a tool form (160) hot applied to the end corresponding cartridge.
Method according to claim 19, characterized in that to obtain the precise spacing above, we submit, during the insertion of the cartridge (155) in the body (201) of the solenoid valve, the electromagnet to a reference diet tending to attract the plunger core (209) against the cylinder head (207) and to be stopped sinking when the first valve (215) detaches of its seat (248) is found.
EP20000403161 1999-11-24 2000-11-14 Miniature electromagnetic valve and assembling procedure Active EP1103992B1 (en)
FR9914775 1999-11-24
EP1103992A1 true EP1103992A1 (en) 2001-05-30
EP1103992B1 EP1103992B1 (en) 2008-09-10
EP20000403161 Active EP1103992B1 (en) 1999-11-24 2000-11-14 Miniature electromagnetic valve and assembling procedure
FR2801416A1 (en) 2001-05-25
EP0890730B1 (en) 2003-05-02 Adjustable metering valve for an internal combustion engine fuel injector, and relative method of adjustment
US5918635A (en) 1999-07-06 Low pressure solenoid valve
Owner name: PARKER HANNIFIN FRANCE S.A.S.
Ref document number: 60040200
Free format text: PARKER HANNIFIN FRANCE S.A.S.#17, RUE DES BUCHILLONS, ZI DU MONT BLANC#74100 VILLE LA GRAND (FR) -TRANSFER TO- PARKER HANNIFIN FRANCE S.A.S.#17, RUE DES BUCHILLONS, ZI DU MONT BLANC#74100 VILLE LA GRAND (FR)
Owner name: PARKER HANNIFIN MANUFACTURING FRANCE SAS, FR
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