BE1013061A3 - Distributor device for remote fluid including water. - Google Patents

Abstract

Fluid distributor device, in particular for a hydraulic remote control, comprising at least one pressure reducer 2 mounted in a body 1 and a control member 19 capable of modifying the calibration of the reducer provided by a calibration spring; the calibration spring 28 is unique and is a helical spring whose winding pitch is variable, whereby the fluid pressure regulation curve obtained by actuation of the control member causing compression at least partial of the calibration spring has a variable slope.

Description

       

   <Desc / Clms Page number 1>
 



  Fluid distributor device, in particular for hydraulic remote control.



   The present invention relates to improvements made to fluid distributing devices, in particular for hydraulic remote control, such as those called "hydraulic manipulators", comprising at least one pressure reducer mounted in a body and a control member capable of modifying the setting of the reducer , which gear unit comprises a plunger displaceable, by the aforesaid control member, in a cavity of the body which comprises, on one side, a housing in which is disposed a calibration spring of the gear unit and, on the other side, a bore in
 EMI1.1
 which an active part of the diver can be moved to
 EMI1.2
 perform the fluid pressure reduction function, ----- C ------------ Cl ----------------- the above active part and extending substantially in said
 EMI1.3
 housing, said rod part comprising,

   at its free end, an enlarged head defining a first shoulder and, on the side of its junction with the aforementioned active part, a second shoulder on which rests said calibration spring whose other end is supported on a cup which is coaxial to the rod portion and which is pushed elastically in abutment against the above-mentioned control member.



   In traditional arrangements of a device such as above, the calibration spring is a conventional helical spring: such a device is described for example in documents FR 2 376 978 or FR 2 507 732. The regulation curve of the hydraulic pressure provided by known devices of this type is substantially linear and its slope is determined by the stiffness of the spring.



   For certain fields of use, users wanted to be able to have more complex regulation curves, with a variable slope (for example the slope of the regulation curve being more pronounced towards the end of travel of the control member). This is how a dispensing device is known, the curve of which

 <Desc / Clms Page number 2>

 the answer is twofold: such a device is shown in fig. 1 of the accompanying drawings.



   This known device comprises a body 1 (which can be constituted by the union of several parts to facilitate the positioning of the internal components) in which is arranged at least one fluid pressure reducer 2. This reducer comprises a plunger 3 capable of move into a cavity 4 formed in the body 1.

   This cavity 4 comprises, on one side, an enlarged housing 5 in which is arranged a calibration spring 6 bearing between a shoulder 7 of the plunger and a cup 8 movable in the housing 5 in the vicinity of the free end of the plunger and , on the other side, a bore 9 in which an active part 10 of the plunger can be moved to ensure the function of reducing the pressure of the fluid which is supplied by an inlet orifice (not visible) connected to the bore 9 by a conduit 12 opening radially therein, while an outlet orifice 13 is located at the end of the bore 9. The active part or piston 10 of the plunger has an axial recess 22 opening at the base of the piston 10 on the side of the outlet orifice 13, and a radial bore 23 communicating with the axial recess 22.



   The plunger 3 further comprises a rod part 14, surmounting the active part 10 and extending substantially in the cavity 5 while being surrounded coaxially by the calibration spring 6; this rod portion 14 crosses the cup 8 and ends in an enlarged head 15 defining a shoulder 16 for retaining the cup.



   A return spring 17, coaxial with the rod 14, is interposed between the cup 8 and a shoulder defined in the body 1, to push the cup upwards, that is to say towards its position defining a minimum setting.



   The cup 8 is surmounted by a movable pusher 18 with free sliding in a bore of the body and projecting partially outside the body so as to be in contact with a cam 19 able to pivot around an axis under the action

 <Desc / Clms Page number 3>

 an actuating member such as a handle 21.



   The operation of this device is known and reference may be made, for example, to the aforementioned documents FR 2 376 978 or FR 2 507 732 for further details.



   In this known device as described above, the regulation spring 6 is a standard helical spring, constituted by a metallic wire of homogeneous geometry, in particular of constant section, configured in a helical winding of constant pitch and diameter constant. As indicated above, this linear regulation spring alone confers a linear regulation curve with a slope determined by the stiffness of said spring.
 EMI3.1
 



  If one wishes to obtain a regulation curve at uva¯ &verbar; c, vc. ssc 2 vCow o¯¯ s va aca cJ oub¯coo v Co v C Fcwwco different), it is known to add to the preceding spring 6 a second spring of different characteristics.



   Given the limited space available inside the pressure reducer, we were led to arrange the second regulating spring 24 inside the pusher 18 hollowed out for this purpose.



   As illustrated in FIG. 1, the pusher 18 is provided with an axial recess 25 extending over almost its entire length, so that the second regulating spring 24 which is housed therein does not extend, at the uncompressed state (case illustrated in fig. 1), that over part of the length of the recess 25, an empty gap remaining at the top of the recess.



   At its lower end, the second spring 24 is supported on an additional plunger 26 guided in the recess 25 and resting on the head 15 of the plunger 3. The additional plunger 26 is extended upwards by an axial finger 27 which serves as a guide for the spring that surrounds it.



   When the pusher 18 is pushed down under the action of the inclination of the cam 19, only the spring of

 <Desc / Clms Page number 4>

 regulation 6 is in operation at the start of the stroke of the pusher 18, and this as long as the second spring 24 does not come into contact with the bottom of the housing 25 hollowed out in the pusher. The regulation curve is then linear with a slope determined by the characteristics of the regulation spring 6.



   As soon as the second spring 24 comes into contact with the bottom of the housing 25, the regulation characteristic is defined by the two springs 6 and 24 which then act in series: the regulation curve always remains linear, but with a slope determined by the characteristics of the two springs 6 and 24.
 EMI4.1
 



  Such an assembly therefore meets the requirements of the
 EMI4.2
 practical and gives satisfaction with the result obtained.



  - LOU. This. t-U-L. , -Lct ufi. L. -Li. CCj-ull U. U U. j-ùJU-LL-Ll- bci L-. UU. /
 EMI4.3
 complicated, because it is necessary to machine the pusher in a special way (it is no longer a standard pusher) and it is also necessary to implement additional parts (second spring 24, additional pusher 26). The cost of the device is thereby increased.



   In addition, such an arrangement certainly makes it possible to provide a double-slope regulation curve while remaining under still relatively simple structural conditions. On the other hand, it is impossible, in practice, to produce by means of this kind a structure providing a regulation curve having linear segments in number at least equal to three, or else a curvilinear regulation curve with progressive growth if this is wish.



   It will be noted now that the small dimensions of the component parts of the device (Figure 1 is significantly enlarged compared to reality) and the close positions of each other of the pressure reducers within the body (four reducers arranged in a cross and two to two opposite) leave no room available for the installation of regulation springs

 <Desc / Clms Page number 5>

 additional. The arrangement illustrated in Figure 1 is in practice the only possible resolution in such a small and crowded space.



   The object of the invention is essentially to remedy the aforementioned drawbacks and to propose an improved and economical arrangement which makes it possible to obtain any shape regulation curve without adding parts and without modifying the parts present (in particular by retaining pushers). standards without additional machining), with ultimately a manufacturing cost as low as possible.



   For these purposes, the device of the invention is characterized in that the calibration spring is unique and is a helical spring whose winding pitch is variable, whereby the regulation curve at the pressure and the fluid obtained by actuation of the control member causing at least partial compression of the calibration spring has a variable slope.



   Thus, in practice, the same number of parts is kept as in a previous device, which proves to be particularly advantageous because of the very great difficulty, even the impossibility of having an increased free space in the radial direction within of the device.



   In practice, user requests most often relate to regulation curves with two successive linear sections having different slopes.



  In this case, provision is made for the helical calibration spring to have at least two successive sections having different winding pitches.



   However, the general conditions for implementing the invention make it possible to respond, if necessary, in an equally simple manner and without modifying the environment within the device, to requests for more complex regulation curves, comprising multiple linear segments of different slopes or even of curvilinear appearance, or combining linear sections and

 <Desc / Clms Page number 6>

 curvilinear sections: to this end, provision is made for the helical calibration spring to have a continuously variable winding pitch over at least part of its length so that the regulation curve is curvilinear over at least part of its length.



   Thanks to the provisions of the invention, the desired regulation curve is obtained by using a single helical spring comprising turns wound in an appropriate manner, which spring simply comes in place of the simple helical spring traditionally used. The other parts of the device remain identical to what they were and do not have to undergo any modification.
 EMI6.1
 tions. In other words, all remote control devices
 EMI6.2
 are built the same way, with the same HJCt parts. t. iL-C:. , -t-C'-tdQ -'- H C-L <. C C CU. JLCI-L. jL C
 EMI6.3
 each pressure regulator is based solely on the choice of the appropriate single spring.



   This results in substantial savings not only for manufacturing, but also for assembly and maintenance.



   The invention will be better understood on reading the detailed description which follows of certain embodiments given solely by way of purely illustrative examples.



   In this description, reference is made to the appended drawings in which: - Figure 2 is a partial simplified diagram, in section, of a dispensing device arranged in accordance with the invention; - Figure 3 is a simplified view showing a helical spring with double winding pitch making it possible to obtain a regulation curve with two linear segments of different slopes; - Figure 4 is an example of a control curve with two linear segments of different slopes capable of being obtained using the spring of Figure 3;

 <Desc / Clms Page number 7>

 - Figures 5A and 5B are simplified views showing respectively two helical springs for obtaining complex regulation curves;

   and - Figure 6 is a graph showing two complex regulation curves capable of being obtained with the springs of Figures 5A, 5B respectively.



   Figure 2 shows, in section, part of a dispensing device arranged in accordance with the invention.



  The device of FIG. 2 differs from that of FIG. 1 essentially by the fact that the regulation spring 6 of FIG. 1, of helical type, is here replaced by a helical spring of particular type 28,
 EMI7.1
 examples of which will be given later. The unique spring
 EMI7.2
 28 sufficient to provide 1 alone, the regulation curve DV> LG &verbar; t¯CC, I C OCVV ± XA COOVs z V C c9 a = a, vss w s ¯. a¯., ¯w¯> s corresponding specific (housing 25 of the pusher, support bowl 26 and guide finger 27) no longer necessary: the pusher 18 is thus a standard pusher, full, provided at its base, the recess necessary for the free movement of the upper end of the rod 14 of the piston 3.



   Under these conditions, it can be seen that the regulating device illustrated in FIG. 2 is of a structure similar to that of a conventional device as it appears in the drawings of documents FR 2 376 978 or FR 2 507 732; the regulation spring 28 itself retains substantially the same overall geometry (length, external diameter), only the conformation of its winding being modified.



   To obtain a double slope regulation curve 29 such as that illustrated in FIG. 4 (forces plotted on the ordinate, height of the spring winding plotted on the abscissa on an inverted axis oriented with values increasing to the left ) -that is to say comprising for example a first linear section 30 having a predetermined slope corresponding to the major part of the

 <Desc / Clms Page number 8>

 regulation stroke, followed in the terminal part of the regulation stroke of a second linear section 31 of increased slope, a regulation spring 28 is used, a characteristic of which varies from a predetermined threshold.



   In practical terms, the characteristic retained is preferably the winding pitch of the spring wire as illustrated in FIG. 3: the spring 28A has a first section 33 with relatively close turns and a second section 34 with relatively less close turns, all the turns having substantially the same winding diameter and being made of the same metal wire, everywhere having the same composition and the same section.



   When the spring 28A begins to be compressed, the first section 33 with relatively close turns, which have a lower stiffness, is only active in practice and provides a regulation varying linearly according to the first section 30 of the curve 29 of FIG. 4. When all the turns of the first section 33 have become contiguous, the second section 34 with more spaced turns, therefore with greater stiffness, becomes active and provides regulation according to the second section 31 of increased slope of the curve 29 in FIG. 4.



   A double-winding spring as illustrated in FIG. 3A can be manufactured without particular difficulty and is of acceptable cost. It is thus possible to produce a regulating device whose cost does not greatly exceed that of a conventional device.



   The arrangements in accordance with the invention can, moreover, be implemented for obtaining much more complex regulation curves, always remaining within the simple structural context illustrated in FIG. 2.



   For example, the spring 28D illustrated in Figure 5A extends the arrangement illustrated in Figure 3 to an increased number

 <Desc / Clms Page number 9>

 of sections of different steps (here the steps are increasing and four in number) respectively 39.40, 41 and 42. Such a spring leads to the regulation curve 43 illustrated in FIG. 6, which is made up of four successive linear sections 44,45, 46 and 47 which have different and increasing slopes.



   Also for example, the spring 28E illustrated in FIG. 5B is constituted by a wire of identical section, wound on a single diameter, with a progressively variable pitch. Such a spring provides a curvilinear regulation curve 48 (fig. 6) without a single point (continuous curvature).



   Of course the arrangements which have been previously described can be combined, so as to obtain
 EMI9.1
 couce coue o. e regu. d-dcj. on souna-Lcee tcc'mo-i. ndj. bun u. e section (s) linear (s) and curvilinear (s)).


    

Claims (3)

 CLAIMS 1. Fluid distributor device, in particular for hydraulic remote control, comprising at least one pressure reducer (2) mounted in a body (1) and a control member (19) capable of modifying the setting of the reducer, which reducer (2 ) comprises a plunger (3) which can be moved, by said abovementioned control member, into a cavity (4) of the body (1) which comprises, on one side, a housing (5) in which is positioned a reduction spring of the reduction gear and, on the other side, a bore (9) in which an active part (10) of the plunger (3) can be moved to perform the function of fluid pressure reducer, said plunger (3) comprising a rod part (14) surmounting the above-mentioned active part (10) and extending substantially in said housing, said rod part (14) comprising, at its free end,  an enlarged head (15) defining a first shoulder (16) and, on the side of its junction with the said active part (10), a second shoulder (7) on which said calibration spring (6) rests, the other of which end is supported on a cup (8) coaxial with the rod portion (14) and pushed elastically (17) bearing against the above-mentioned control member, characterized in that the calibration spring (28) is unique and is a helical spring with variable winding pitch.  2. Device according to claim 1, characterized in that the helical calibration spring (28) has at least two successive sections (33,34) having different winding pitches, whereby the regulation curve (29) consists of at least two successive line segments (30,31) of different slopes.  <Desc / Clms Page number 11>    3. Device according to claim 1, characterized in that the helical calibration spring (28E) has a continuously variable winding pitch over at least part of its length, which makes the regulation curve (48) curvilinear over at least part of its length.