法国专利FR3026458A1 THERMOSTATIC DEVICE FOR CONTROLLING CIRCULATION OF A FLUID, AND THERMOSTATIC VALVE COMPRISING SUCH A

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专利摘要:
This device (2) comprises a thermostatic element (10); a main shutter (20), which is axially movable relative to a fixed seat to open and close a main valve and which is connected to the movable portion (12) of the thermostatic element to open the main valve, the main shutter and the thermostatic element being assembled to one another forming a first module (M1); a spring (50), which recalls the moving part towards the fixed part of the thermostatic element to control the closing of the main valve; a spring support yoke (40) which is interposed axially between the spring and a fixed housing; and a cradle (30) for supporting the first module, which is adapted to removably attach the first module thereto, axially interposing the cradle between the first module and the spring, which includes a bypass shutter (36), axially displaceable relative to a fixed seat of the stirrup so as to open / close a bypass valve when closing / opening the main valve, and which is connected to the stirrup axially movable, with interposition axial of the spring, while being retained permanently in the stirrup so as to maintain between them the spring in the compressed state. The spring, the stirrup and the cradle are assembled to each other independently of the first module, forming a second module (M2) separate from the first module.
公开号:FR3026458A1
申请号:FR1459080
申请日:2014-09-25
公开日:2016-04-01
发明作者:Jean-Michel Roman
申请人:Vernet SA；
IPC主号:

专利说明:

[0001] The present invention relates to a thermostatic device, as well as a thermostatic valve comprising such a device. The invention is particularly concerned with thermostatic devices and valves which are used in thermal engine cooling circuits, in particular those of motor vehicles, trucks, two-wheelers and stationary engines. This being the case, this field of application is not limiting of the invention, in the sense that the device and the valve in accordance with the invention can be used in various other fluid circuits, for example box cooling circuits. speed, water circuits, oil circuits, etc. In many applications of the fluidic field, in particular for the cooling of thermal engines, thermostatic valves are used to regulate the circulation of a fluid, that is to say, to distribute this fluid in different lanes, depending on the temperature of this fluid. These valves are said to be thermostatic, in the sense that the displacement of their internal shutter (s) is controlled by a thermostatic element, that is to say an element which comprises a body, containing a thermally expandable material. , and a piston, immersed in this thermally expandable material, the body and the piston being movable relative to each other in translation along the longitudinal axis of the piston. The invention is more specifically concerned with three-way valves, which distribute a fluid inlet between two fluid outlets or which supply a fluid outlet with two fluid inlets. These three-way valves are typically used to regulate the circulation of a cooling fluid vis-a-vis both a motor to be cooled by this fluid and a heat exchanger, in particular a radiator, cooling this fluid: when the fluid has too high a temperature at the valve, the latter sends it to the exchanger to be cooled before being sent to the engine to cool and returned to the valve, while when the fluid temperature is low enough at the valve, the latter sends the fluid directly to the engine where it is returned to the valve, via a bypass path not passing through the exchanger, commonly called bypass path . To do this, the valve includes a main valve, which controls the flow of fluid vis-à-vis the heat exchanger, and a bypass valve, which controls the flow of fluid in the aforementioned bypass: the The invention is concerned with valves whose same thermostatic element operates, in reverse, the main valve and the bypass valve. In this case, it is known that the mobile part of the thermostatic element is fixedly linked to the same crew including the shutter of the main valve and the shutter of the bypass valve, with the interposition of a return spring between this crew and a stirrup which, in use, is fixedly connected to a housing or a similar part, fixed to the valve housing to which the fixed part of the thermostatic element is fixedly connected. Providing further that the crew and the yoke, which, when the valve is in use, are movable relative to each other to open and close the bypass valve, are permanently restrained. to one another so as to maintain between them the return spring in the compressed state, the assembly, formed by the assembly of the thermostatic element, the crew, the stirrup and the return spring. , constitutes an integrated device with prestressed spring: such a device has the advantage of being able to be mounted in one piece on the aforementioned casings, in particular without resorting to a tool dedicated to the compression of the return spring. DE-U-20 2010 017 837 provides an example. On the other hand, the integration of these devices has the disadvantage of making them unmodifiable, in the sense that the design and dimensioning of such a device is specific to the mounting environment of this device. In particular, by design, the aforementioned crew freezes both the diameter of the shutter of the main valve and the diameter of the shutter of the bypass valve, which therefore limits the possibilities of using pre-existing thermostatic elements, of various shapes and sizes, and which makes it necessary to adapt the shape of the stirrup in a specifically dedicated manner. The cost of manufacturing and reassorting these devices is impacted. The object of the present invention is to provide a thermostatic device of the type mentioned above, which, while being simple to mount within a corresponding thermostatic valve, is more flexible.
[0002] For this purpose, the subject of the invention is a thermostatic device for regulating the circulation of a fluid, comprising: a thermostatic element, which includes a fixed part, intended to be fixedly attached to a first fluid channeling housing, and a movable portion, movable along an axis relative to the fixed part, away from this fixed part under the action of an expansion of a thermally expandable material of the thermostatic element; a main shutter, which is movable axially with respect to a fixed seat of the first housing so as to open and close a main valve and which is connected to the movable part of the thermostatic element so that, during the expansion of the thermodilatable material, the movable part of the thermostatic element drives the main shutter so as to open the main valve, the main shutter and the thermostatic element being assembled to one another forming a first module of the thermostatic device ; a spring, which is compressed in the axis and which remembers the moving part towards the fixed part of the thermostatic element during a contraction of the thermally expandable material so as to control the closing of the main valve; - A spring support bracket, which is intended to be fixedly connected to a second casing of the fluid to be fixed to the first housing, being interposed axially between the spring and the second housing; and - a support cradle of the first module: - which is adapted to bring the first module removably, axially interposing the cradle between the first module and the spring, - which includes a bypass shutter, axially movable by relative to a fixed seat of the caliper so as, on the one hand, to open a by-pass valve when closing the main valve and, on the other hand, to close the bypass valve during the closing of the main valve; opening the main valve, and - which is axially movably connected to the caliper, with axial interposition of the spring, while being retained permanently at the yoke so as to maintain the spring in the compressed state between them; , the spring, the stirrup and the cradle being assembled to each other independently of the first module, forming a second module of the thermostatic device, distinct from the first module. One of the ideas underlying the invention is to avoid having a "totally" integrated device, that is to say, each of which components would be specifically designed with respect to the other components to be assembled together. to others in a dependent way. Conversely, the invention seeks to be able to use, within the device according to the invention, various pre-existing thermostatic elements, and having particular shapes and sizes, and pre-existing main valve shutters, associated with these elements. thermostatic and available in various shapes and sizes, including various diameters. To do this, the invention provides that the device consists of two separate modules, namely a first module corresponding to the assembly of the thermostatic element and the shutter of the main valve, the realization of this assembly can be particularly economical because it can be based on the use of pre-existing parts available at low cost, and a second module corresponding to the assembly of the stirrup, the spring and a removable support cradle of the first module. One of the tips of the invention is that this cradle is designed to accommodate various shapes and dimensions of the first module, that is to say, various shapes and dimensions of the shutter of the main valve and / or the thermostatic element. the first module is attached to this cradle removably, in particular by being essentially, or only, placed on the cradle, before the first and second modules are associated within a thermostatic valve, being jointly mounted on the housings to which the fixed part of the thermostatic element of the first module and the stirrup of the second module are respectively fixedly connected. By providing that the cradle and the stirrup are assembled with the spring so as to maintain the spring in the compressed state between them, this spring is prestressed within the second module, the latter being in a way similar to a spring box: the assembly of the device according to the invention, on the aforementioned cases, is facilitated since a tool dedicated to the compression of the spring is not necessary. Thus, the device according to the invention dissociates from one another the assembly of the parts of the first module and the assembly of the parts of the second module, in order to facilitate the design of each of these modules and to integrate more easily to each of them pre-existing parts, which reduces the cost of manufacture and reassortment of the device according to the invention, while having a convenient device to mount on valve housings. In practice, the device according to the invention fits naturally within a three-way valve, as mentioned above. However, this device also has the advantage of being able to equip a two-way valve: in this case, the main valve of the device controls the flow of fluid between the two channels of the valve, while the bypass valve n provides no regulation between these two channels without hindering the regulation provided by the main valve. According to additional advantageous features of the device according to the invention, taken separately or in any technically possible combination: - the cradle is adapted to bring the first module removably, by linking them to each other at least by, or exclusively by, axial support of the first module, in particular of its main shutter, on the cradle; the cradle includes, at the axial opposite end of the bypass shutter, a ring which is substantially centered on the axis and against axially opposite faces of which a seal main shutter and an end turn of the spring when the first module is attached to the cradle; - The crown defines, on its face against which the end turn of the spring rests, a receiving housing and centering on the axis of said end turn; the cradle further includes a portion connecting the ring to the bypass shutter, this part being provided with through-openings for the circulation of the fluid and this part being arranged radially around and at a distance from the moving part of the element; thermostatic when the first module is attached to the cradle; - The cradle defines at least one radial wedging surface of the first module, which cooperates by complementarity of shapes with a frame of the main shutter when the first module is attached to the cradle; - The bypass shutter is monobloc, being in one piece with the rest of the cradle, this bypass shutter being for example come integrally with the crown through the connecting part thereof ; - The bypass shutter includes both a fixed part relative to the rest of the cradle, which cooperates with the seat of the caliper to open and close the bypass valve, and a load shedding part, which is movable relative to the fixed part of the bypass shutter, being moved against a return spring during an overpressure at the bypass shutter; the seat of the stirrup comprises, or even consists of, a cylindrical surface, which is substantially centered on the axis and inside which the bypass shutter is received in complementary manner to close the bypass valve; -pass, and the stirrup is provided with guide surfaces of the cradle in axial sliding, which guide surfaces are connected to the seat of the stirrup and are distributed around the axis, defining between them free passages of circulation of the fluid.
[0003] The invention also relates to a thermostatic valve, comprising first and second housings attached to each other, and a thermostatic device as defined above, including the fixed part of the thermostatic element and the stirrup are respectively fixedly attached to the first and second housings. As mentioned above, this valve is typically three-way, but can also be two-way for circuits without a bypass path. The invention will be better understood on reading the description which will follow, given solely by way of example and with reference to the drawings in which: FIG. 1 is a longitudinal section of a thermostatic valve according to FIG. invention; - Figure 2 is a perspective view of a longitudinal half-section of the thermostatic device belonging to the valve of Figure 1; FIG. 3 is a view similar to FIG. 2, showing only a portion of the device of FIG. 2; FIGS. 4 and 5 are views similar to FIG. 1, respectively showing operating configurations of the valve, different from one another and different from the operating configuration shown in FIG. 1; FIG. 6 is a view similar to FIG. 3, illustrating a variant of the thermostatic device according to the invention; and FIG. 7 is a longitudinal section of the variant of FIG. 6, showing a different operating configuration from that shown in FIG. 6.
[0004] FIGS. 1 to 5 show a valve 1 comprising a thermostatic device 2 for regulating the circulation of a fluid. This fluid is in particular a cooling fluid, the valve 1 then belonging for example to a cooling circuit of a heat engine, in particular of a motor vehicle engine. The device 2 is shown alone in FIG. 2, whereas, in FIGS. 1, 4 and 5, this device is arranged in casings 4 and 6 of the valve 1, it being noted that these casings 4 and 6 are fixed to the device 1. relative to one another, in particular firmly fixed to one another, when the valve 1 is in use as in Figures 1, 4 and 5. In practice, in the figures, the housings 4 and 6 are not shown only partially and schematically, their embodiment being not limiting of the invention. In all cases, when the valve 1 is in the service configuration, the casings 4 and 6 channel the fluid, by defining three channels 1A, 1B and 10 of fluid flow: these three channels constitute either an inlet and two fluid outlets , or two inputs and a fluid outlet for the valve 1. As an example which will be re-evoked later, when the valve 1 belongs to a cooling circuit of an engine, the channel 1A constitutes a fluid inlet of cooling, from the engine to be cooled, while, on the one hand, the channel 1B is a first output of the cooling fluid, sending it to a heat exchanger, in particular a radiator, designed to lower the temperature of the fluid passing through it, before this fluid is sent to the engine to be cooled, and secondly, the channel 10 constitutes a second output of the cooling fluid, which sends it directly to the engine to be cooled, without going through the aforementioned heat exchanger. It is understood that the channel 10 feeds a bypass, commonly called bypass. Thus, the cooling fluid sent to the engine by the valve 1 comes from the outputs 1B and 10 of the latter, and after having cooled this motor, is returned to the valve, specifically to its channel 1A.
[0005] The device 2 comprises a thermostatic element 10 which is centered on a geometric axis X-X. This thermostatic element 10 includes a body 12, centered on the X-X axis and containing a thermally expandable material such as a wax. The thermostatic element 10 also comprises a piston 14, whose longitudinal geometric axis is aligned on the axis XX in the device 2 and a terminal axial portion of which is immersed in the thermodilatable material contained in the body 12. The body 12 and the piston 14 are movable relative to each other in translation along the axis XX: under the effect of the expansion of the thermally expandable material, the piston 14 is deployed outside the body 12, while during a contraction of the thermally expandable material, the piston is retractable inside the body 12. Within the valve 1 when it is in use, the piston 14 of the thermostatic element 10 is fixedly connected to the 4. More specifically, in a manner known per se, the end portion of this piston 14, opposite to that immersed in the body 12, is fixedly connected to a portion 4A of the housing 4, arranged across the axis XX. In practice, various embodiments can be envisaged with regard to the fixed connection of the aforementioned end portion of the piston 14 to the portion 4A of the casing 4: this fixed connection can be made either solely by axial support or by removable fixing, type clipping or sliding fitting, either by permanent fastening type force fitting, overmoulding or addition of a mechanical holding system. In all cases, it is understood that, when the thermally expandable material of the body 12 of the thermostatic element 10 expands or contracts, the piston 14 is held stationary relative to the housing 4, because of the fixed connection of its end portion. aforementioned to this housing. The device 2 also comprises a main shutter 20 which is displaceable along the axis XX relative to a fixed seat 4B of the housing 4, so as to open and close a corresponding main valve: within the valve 1 in use, when the shutter 20 is pressed in sealed contact against the seat 4B as in the operating configuration shown in Figure 1, this shutter prevents the flow of fluid between the channels 1A and 1B, while, when the shutter 20 is removed from the seat 4B as in the operating configurations shown in Figures 4 and 5, the shutter 20 allows the passage of the fluid between the channels 1A and 1B, which, in the embodiment defined above, is, within the valve 1, passing at least a portion of the fluid entering the channel 1A in the output of the channel 1B. To control the shutter 20 in displacement, the latter is fixedly bonded to the body 12 of the thermostatic element 10 so that, within the valve 1 when it is in use, the axial displacement of the body 12 relative to the housing 4, resulting from the expansion of the thermally expandable material, causes a corresponding displacement of the shutter 20 so as to open the main valve by axially spacing this shutter 20 vis-à-vis the seat 4B. In the embodiment considered in the figures, the main shutter 20 comprises a rigid frame 22, typically metallic, which has a stepped annular shape, substantially centered on the axis XX, and whose periphery, turned radially opposite. the axis XX, is provided, for example by overmoulding, a flexible sealing gasket 24, typically polymer or rubber. The seal 24 constitutes the portion of the shutter 20, which cooperates with the seat 4B of the housing 4 to open and close the main valve, while the armature 22 constitutes the part of the shutter 20, which cooperates with the body 12 of the thermostatic element 10 for the purposes of the fixed connection of the shutter to this body 12, in particular by fitting tightly around this body 12 of the periphery, turned radially towards the axis XX, of this armature 22. Given its embodiment, the shutter 20 considered here is similar to a valve. Whatever the embodiment of the main shutter 20, it will be noted that the latter and the thermostatic element 10 are assembled to each other forming a first module M1 of the thermostatic device 2, which differs from the rest of this device in the sense that the connection connection between the shutter 20 and the thermostatic element 10, more precisely between the frame 22 of this shutter and the body 12 of this thermostatic element, is independent of the assembly links between the other components of the device 2, so that the module M1 is manipulated in one piece, distinctly from the rest of the device 2, in particular for the purpose of its assembly with the rest of this device. The thermostatic device 2 furthermore comprises a support cradle 30 for the module M1, which is designed so that this module M1 can be removably attached thereto. More specifically, in the embodiment considered here, and as clearly visible in FIG. 3, the cradle 30 has a tubular overall shape whose central axis is substantially coincident with the axis XX when the module M1 is attached to this cradle. , as clearly visible in FIG. 2. At its axial end turned towards the module M1, the cradle 30 is open axially, forming an opening 32 of axial access to the free internal volume of the cradle, while being surrounded externally by a crown 34, substantially coaxial with the remainder of the cradle 30 and extending continuously over the entire outer periphery of the cradle. On its axial side turned away from the rest of the cradle 30, the ring 34 has a face 34A designed to form an axial support for the seal 24 of the main shutter 20 when the module M1 is attached to the cradle 30 The opening 32 of the cradle 30 is, for its part, sized to axially engage the body 12 of the thermostatic element 10, as well as at least one peripheral portion, turned radially towards the axis XX, of the armature. 22 of the shutter 20, this engagement being provided without axial interference that would prevent the axial bearing of the seal 24 against the face 34A of the ring 34. In other words, the cross section of the opening 32, c that is to say, the section of the latter in a geometrical plane perpendicular to the axis XX, is greater than, or possibly adjusted to, the largest cross section of the body 12 and the frame 22, capable of interfering axially t with the cradle 30 when the module M1 is attached to the cradle and as its gasket 24 is not yet pressed axially against the face 34A of the ring 34. In the continuation of the foregoing considerations, and in accordance with a advantageous arrangement which is implemented in the embodiment considered in the figures, the opening 32 of the cradle 30 delimits radial fixing surfaces 34B of the module M1, which cooperate by complementarity of shapes, in particular by radial support, with the frame 22 of the shutter 20 when the module M1 is attached to the cradle: in other words, in its portions corresponding to the aforementioned wedging surfaces 32A, the cross section of the opening 32 is adjusted to that of the portion of the frame 22 arranged across this opening, as clearly visible in FIG. 1. With the above explanations in mind, it will be understood that when the module M1 is attached to the cradle 30, the latter is removably attached to it, in the sense that the connection between the cradle and the module M1 consists exclusively, or at least essentially, in an axial support of the shutter 20 on the ring 34 of the cradle, this support axial being freely reversible. As for the cooperation between the wedging surfaces 32A of the cradle 30 and the module Ml, it makes it possible to avoid a relative offset between the cradle and the module M1 when the latter is attached to the cradle: if necessary, in the event of interference radial between these wedging surfaces 32A and the module Ml, in this case between these surfaces 32A and the frame 22 of the shutter 20, it is understood that this interference does not bind the module M1 with the cradle 30, but induces a low resistance to the release of the module M1 vis-à-vis the cradle 30 when such clearance is desired, for example for maintenance of the device 2. More generally, in the continuation of the foregoing considerations, in addition to to be linked by axial support, the module M1 and the cradle 30 are optionally linked in another way, for example by clipping and / or fitting, as long as this other connection is removable as the axial bearing connection. At its end axially opposite to its ring 34, the cradle 30 includes a solid wall 36, which extends across the axis XX, being substantially centered on this axis, and which, in the embodiment considered on the figures, axially closes the free volume inside the cradle 30. This wall 36 is connected to the ring 34 by a running portion 38 of the cradle 30, which defines the internal free volume of the cradle and inside which are arranged without interference at at least a portion of the body 12 of the thermostatic element 10 and, if appropriate, a portion of the frame 22 of the shutter 20 when the module M1 is attached to the cradle 30. Thus, the current portion 38 of the cradle 30 is designed to be arranged radially and at a distance from the body 12 of the thermostatic element, without preventing the circulation of the fluid therethrough radially to the axis XX insofar as this running part 38 is provided with an opening 38A radially through: in the embodiment considered in the figures, this current portion 38 consists of arms 38B, which extend in length substantially parallel to the axis XX, each connecting the ring 34 to the wall 36 of the cradle 30, and which are regularly distributed about the axis XX, defining between them the openings 38A, as can be seen in Figure 3. According to an advantageous arrangement, which is also implemented in the embodiment considered in the figures, the cradle 30 is made in the form of a one-piece piece, by molding or machining, in the sense that the ring 34, the solid wall 36 and the running part 38 are integral with each other. others. The thermostatic device 2 further comprises a yoke 40 to which the cradle 30 is movably connected along the X-X axis, typically slidably along this axis. Within the valve 1 when it is in use, the bracket 40 is fixedly connected to the housing 6, the embodiment of this fixed link not being limiting of the invention. In the embodiment considered in the figures, the stirrup 40 has a tubular overall shape, whose central axis is substantially coincident with the axis XX when the valve 1 is in use, and which is open axially at its axial ends. opposed. At its end facing the axial opposite of the cradle 30, the yoke 40 defines an opening 42 of axial access to the internal free volume of the yoke and is externally surrounded by a coaxial flange 44 running continuously over the entire periphery outside of the stirrup. It is also at this end that the stirrup 40 is fixedly connected to the housing 6, by means of the axial support of its flange 44 against a portion 6A of the housing 6, which is arranged across the axis XX and through which 1C is provided: as mentioned above, other embodiments are possible with regard to the fixed connection between the stirrup 40 and the housing 6, in particular by cooperation between the collar 44 of this stirrup and the part 6A. of the housing 6, this fixed link being advantageously sealed by any appropriate means. In all cases, the opening 42 of the stirrup 30 opens axially into the track 1C, connecting the latter to the internal free volume of the stirrup 40, as clearly visible in FIG. 1. The opening 42 forms a seat 42A of cooperation with the wall 36 of the cradle 30 for the purpose of opening and closing a corresponding valve, other than the main valve mentioned above and described in this by-pass valve document, particularly in connection with the example of use of the valve 1, mentioned above. In the embodiment considered in the figures, the seat 42A consists of a cylindrical surface delimiting the opening 42, the cross section of this cylindrical surface being adjusted to that of the wall 36 of the cradle 30: more generally, it is understood that the seat 42A is arranged and sized to receive, along the axis XX, the wall 36 of the cradle 30 in a complementary manner, as in the operating configuration shown in FIG. 5, so that the wall 36 then closes the fluid passage inside the opening 42, in other words by closing the aforementioned bypass valve. Of course, when the wall 36 is axially distant from the seat 42A, the bypass valve is open in the direction where the fluid is free to pass through the opening 42 of the stirrup 40, thus flowing between the channels 1A and 10, as in the operating configurations shown in Figures 1 and 4. It is therefore understood that the wall 36 is a shutter of the bypass valve cooperating here by sliding axial engagement with the fixed seat 42A of caliper 40 to open and close the bypass valve.
[0006] At its opposite end axially to that defining the opening 42, the stirrup 40 defines an opening 46 for axial access to the internal free volume of the stirrup. This opening 46 is adapted to receive the cradle 30, so as to arrange and allow the axial displacement of the shutter 36 and the running part 38 of the cradle 30 in the free internal volume of the stirrup 40.
[0007] The opposite axial ends of the stirrup 40 are connected to each other by a running part 48 of the stirrup, which is provided with free passageways 48A for the circulation of the fluid so as to allow the flow of the fluid through this current wall 48, radially to the axis XX: when the bypass valve is open, the fluid passing through the opening 42 can thus join or come from outside the bracket 40, via these free passages 48A. In the embodiment considered in the figures, this running portion 48 of the stirrup 40 consists of arms 48B, which extend in length substantially parallel to the axis XX by connecting the opposite axial ends of the stirrup , and which are regularly distributed about the axis XX, as can be seen in FIG. 3. Advantageously, these arms 48 delimit, on their side facing the axis XX, 480 guide surfaces in axial sliding of the cradle 30, these 480 surfaces being adjusted on the cross section of the shutter 36 of the cradle, as clearly visible in Figure 3. By their connection to the seat 42A, it is understood that these surfaces 480 guide the shutter 36 on its displacement stroke axial vis-à-vis the caliper 40 to open and close the bypass valve.
[0008] The thermostatic device 2 further comprises a spring 50 which, within the valve 1 when it is in use, is provided to return the body 12 of the thermostatic element 10 to the piston 14 of this thermostatic element when a contraction of the thermally expandable material, so as to control the closure of the main valve via the drive, by the body 12, the shutter 20 vis-à-vis the seat 4B. For this purpose, the spring 50 is functionally interposed between the body 12 and the piston 14 of the thermostatic element 10 so as to be compressed in the axis XX when the body 12 and the piston 14 move axially apart from each other. the other. More precisely, the spring 50 is physically interposed, in the axis XX, between the cradle 30 and the stirrup 40, while axially interposing the cradle between this spring and the module M1, and while axially interposing the wedge between this spring and the housing 6. Thus, within the valve 1, the spring 50 rests, by one of its axial ends, against the bracket 40, the support force being taken up by the housing 6, whereas, by its opposite axial end, the spring 50 rests against the cradle 30, the corresponding bearing force being transmitted to the module M1. In the embodiment considered in the figures, an end turn 52 of the spring 50 is pressed against the collar 44 of the stirrup 40, more precisely against the face of this collar, opposite the portion 6A of the housing 6, while that the opposite end turn 54 of the spring 50 bears against the ring 34 of the cradle 30, more precisely against the face 34B of this ring, axially opposite its face 34A. According to an advantageous arrangement, which is implemented in the embodiment considered in the figures, the face 34B of the ring gear 34 is shaped to center the end turn 54 of the spring 50, delimiting a receiving housing 340 and centering of this end turn 54. In all cases, it is understood that when cradle 30 is moved axially relative to the stirrup 40 so as to bring its crown 34 close to the collar 44 of this stirrup and thus to axially bringing its shutter 36 of the seat 42A, the spring 50 compresses axially.
[0009] In addition, the cradle 30 and the yoke 40 are assembled to each other, with axial interposition of the spring 50 as explained above, so as to maintain between them this spring in the compressed state. To do this, the cradle 30 is retained permanently at the stirrup 40, limiting the amplitude of its axial mobility when the ring 34 deviates from the flange 44. In practice, various embodiments are possible to retain and still in relation to each other the cradle 30 and the stirrup 40 when the latter are spaced apart from one another with a distance considered as maximum, as is the case in FIGS. 2 and 3 In the exemplary embodiment considered in the figures, the opening 46 of the stirrup 40 is provided with hooks 46A, the recess of which is both axially open towards the opening 42 and substantially complementary to corresponding portions. the periphery of the shutter 36 of the cradle 30.
[0010] Taking into account the above explanations, it is understood that the cradle 30, the stretch 40 and the spring 50 are assembled to each other forming a module M2, which is shown alone in Figure 3 and which is separate from the module M1 described above. Indeed, the assembly of the cradle 30, the stirrup 40 and the spring 50 to each other is independent of the assembly of the thermostatic element and the shutter 20 to one another, being recalled that the module Ml, formed by the assembly of the thermostatic element 10 and the shutter 20, is provided within the device 2 to be removably attached to the cradle 30, in particular by linking the module M1 to the cradle Essentially, if not exclusively, by axial support. In other words, the module M2 constitutes, in a way, a spring box on which the module M1 is removably attached to together constitute the device 2, the modules M1 and M2 are then arranged together in the housings 4 and 6 to form the valve 1, as in Figures 1, 4 and 5. Because the modules M1 and M2 are distinct, resulting from respective assemblies which are independent of one another, it is understood that each of these modules M1 and M2 has a greater freedom of design, especially compared to a situation where the device 2 would be fully integrated. In particular, for the module Ml, this makes it possible to use, for the thermostatic element 10 and / or for the shutter 20, pre-existing parts. However, since, within the module M2 considered in isolation, the spring 50 is maintained in the compressed state, the device 2 associating this module M2 and the module M1 remains easy to set up within the valve 1 , in the sense that it is not necessary to resort to specialized tools to compress this spring during commissioning of the valve. The operation of the valve 1 will now be described with reference to Figures 1, 4 and 5, in the context of the example of use of this valve, mentioned above.
[0011] In the operating configuration shown in FIG. 1, the fluid entering via the channel 1A is, at the same time, prevented from circulating in the track 1B because of the closing of the main valve and sent entirely to the track 10 because the opening of the bypass valve, the fluid flowing passing successively through the free passages 48A and the opening 42 of the stirrup 40. Taking into account the above, it is understood that the section of passage of the fluid at the bypass valve may be adjusted relative to the need, by changing the diameter of the opening 42 and / or by changing the axial dimension of the free passages 48A. If the temperature of the fluid supplying the channel 1A increases, the thermodilatable material of the thermostatic element 10 expands, the heat of the fluid being transmitted to this thermally expandable material because the body 12 is swept by streams of fluid flowing through the openings 38A cradle 30. The axial displacement of the body 12 relative to the piston 14, which is fixed relative to the housings 4 and 6, causes the corresponding axial displacement of the shutter 20 and, therefore, the cradle 30 against which the shutter 20 is supported axially. As shown in FIG. 4, the main valve then opens progressively, by axially spacing the shutter 20 from the seat 4B, while at the same time the bypass valve closes progressively. , by axial approximation of the shutter 36 vis-à-vis the seat 42A. The fluid admitted in lane 1A is then distributed between lane 1B and lane 1C. If the temperature of the fluid supplying the channel 1A continues to increase, the main valve opens further, while the bypass valve closes further, correspondingly, until, if necessary, is completely closed, by closing the seat 42A by the shutter 36, as shown in FIG. 5. If the temperature of the fluid supplying the channel 1A subsequently decreases, the thermodilatable material of the thermostatic element 10 contracts and, under the decompression effect of the spring 50, the cradle 30 and, thereby, the module M1 are driven axially so as to gradually open the bypass valve and gradually close the main valve. Various arrangements and variants of the device 2 and the valve 1 described so far are also possible. By way of example: - rather than being monoblock as in the embodiment shown in Figures 1 to 5, the shutter of the bypass valve can, as in the variant of the module M2 shown in the figures 6 and 7 on which this shutter is referenced 36 ', include at the same time, a portion 36'A, which is fixed relative to the rest of the cradle 30 and which cooperates with the seat 42A of the stirrup 40 to open and close the by-pass valve functionally similar to the shutter 36, and a shedding portion 36'B, which is movable relative to the fixed portion 36'A and which is designed for, at a pressure of the fluid on this movable part 36B, as indicated by the arrows S in FIG. 7, move against a dedicated return spring 36'C integrated in the cradle 30; more generally, it will be understood that, within the module M2, the shutter of the bypass valve can therefore integrate a load shedding function; rather than fixedly binding the piston 14 of the thermostatic element to the housing 4, this may be the body 12 of this thermostatic element which is provided fixed with respect to the housing, the piston then constituting the moving part of the thermostatic element , providing the drive function described for the body 12 with reference to Figures 1 to 5; rather than being fixedly connected to the moving part of the thermostatic element, the shutter 20 can be mounted on this mobile part with a freedom of movement along the axis XX, provided that it is associated with a dedicated return spring; the shutter 20 then integrates a load shedding function in case of overpressure at the main valve; other embodiments than the hooks 46A may be envisaged to hold permanently to each other the cradle 30 and the stirrup 40 assembled movably along the X-X axis; in particular, this restraint can be provided by fitting, by a bayonet connection, etc. ; the materials constituting the various parts of the device 2 are not limiting; in order to reinforce the seal, joints or similar sealing pieces may be added at at least some of the contact interfaces between the parts of the device 2; and / or - the embodiment of the thermostatic element 10 is not limiting, in the sense that this element can, optionally, be controlled, that is to say integrate a heating electric resistance, or can have different diameters, etc.15

权利要求:
Claims (10)
[0001]
CLAIMS1.- Thermostatic device (2) for regulating the circulation of a fluid, comprising: - a thermostatic element (10), which includes a fixed part (14), intended to be fixedly attached to a first housing (4) of channeling the fluid, and a movable portion (12), movable along an axis (XX) relative to the fixed part, away from this fixed part under the action of an expansion of a thermally expandable material of the thermostatic element; a main shutter (20), which is axially displaceable with respect to a fixed seat (4B) of the first housing (4) so as to open and close a main valve and which is connected to the movable part (12) of the thermostatic element (10) so that, during the expansion of the thermally expandable material, the moving part of the thermostatic element causes the main shutter to open the main valve, the main shutter (20) and the element thermostatic device (10) being assembled to each other forming a first module (M1) of the thermostatic device (2); - a spring (50), which is compressed in the axis (XX) and which remembers the movable part (12) towards the fixed part (14) of the thermostatic element (10) during a contraction of the thermally expandable material in order to control the closing of the main valve; a stirrup (40) for supporting the spring (50), which is intended to be fixedly connected to a second casing (6) for channeling the fluid to be fixed to the first casing (4), by being interposed axially between the spring and this second housing; and - a cradle (30) for supporting the first module (M1): - which is adapted to bring the first module removably, axially interposing the cradle between the first module and the spring (50), - which includes a by-pass shutter (36; 36 ') movable axially with respect to a fixed seat (42A) of the stirrup (40) so as, on the one hand, to open a bypass valve upon closing of the main valve and, on the other hand, close the bypass valve when opening the main valve, and - which is connected to the stirrup (40) axially movably, with axial interposition of the spring (50), while being retained permanently in the stirrup so as to hold the spring in the compressed state between them, the spring (50), the stirrup (40) and the cradle (30) being assembled together. to the others independently of the first module (M1), forming a second module (M2) of the thermostatic device (2), distinct from the first module.
[0002]
2.- Device according to claim 1, characterized in that the cradle (30) is adapted to bring the first module (M1) removably, by linking them to each other at least by, or exclusively by , axial support of the first module, in particular of its main shutter (20), on the cradle.
[0003]
3.- Device according to one of claims 1 or 2, characterized in that the cradle (30) includes, at the axial opposite of the bypass shutter (36), a ring (34), which is substantially centered on the axis (XX) and against axially opposite faces (34A, 34B) from which a seal (24) of the main shutter (20) and an end turn (54) respectively rest. ) of the spring (50) when the first module (M1) is attached to the cradle.
[0004]
4.- Device according to claim 3, characterized in that the ring (34) defines on its face (34B) against which rests the end turn (54) of the spring (50), a housing (340) receiving and centering on the axis (XX) of said end turn.
[0005]
5.- Device according to one of claims 3 or 4, characterized in that the cradle (30) further includes a portion (38) connecting the ring (34) to the bypass valve (36; 36 '). ), this part being provided with through openings (38A) for circulating the fluid and this part being arranged radially around and at a distance from the mobile part (12) of the thermostatic element (10) when the first module (M1) is referred to the cradle.
[0006]
6.- Device according to any one of the preceding claims, characterized in that the cradle (30) defines at least one surface (32A) of radial wedging of the first module (M1), which cooperates by complementarity of shapes with a reinforcement ( 22) of the main shutter (20) when the first module is attached to the cradle.
[0007]
7.- Device according to any one of the preceding claims, characterized in that the bypass shutter (36) is in one piece, being integral with the rest of the cradle (30), this shutter of by -pass is for example material with the crown (34) via the portion (38) connecting them.
[0008]
8.- Device according to any one of claims 1 to 6, characterized in that the bypass shutter (36 ') includes both a portion (36'A) fixed relative to the restedu cradle ( 30), which cooperates with the seat (42A) of the yoke (40) to open and close the bypass valve, and a load shedding portion (36'B), which is movable relative to the fixed portion of the bypass shutter, being moved against a return spring (36'C) during an overpressure (S) at the bypass shutter.
[0009]
9.- Device according to any one of the preceding claims, characterized in that the seat (42A) of the stirrup (40) comprises, or even consists of, a cylindrical surface, which is substantially centered on the axis (XX) and within which the bypass shutter (36; 36 ') is complementarily received to close the bypass valve; and in that the stirrup is provided with axially slidable cradle guide surfaces (480) which guide surfaces are connected to the stirrup seat and are distributed about the axis (XX), defining between them free passages (48A) fluid circulation.
[0010]
10. Thermostatic valve (1), comprising first (4) and second (6) housings fixed to each other, and a thermostatic device (2) according to any one of the preceding claims, including the fixed part (14) of the thermostatic element (10) and the stirrup (40) are respectively fixedly connected to the first and second housings.

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同族专利:

公开号 | 公开日

WO2016046340A3|2016-05-19|

CN106716287B|2018-10-19|

US10386870B2|2019-08-20|

FR3026458B1|2016-10-21|

WO2016046340A2|2016-03-31|

CN106716287A|2017-05-24|

US20170308105A1|2017-10-26|

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FR3069610B1|2017-07-28|2020-01-10|Novares France|THERMOSTATIC VALVE|

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FR3076918B1|2018-01-12|2020-02-07|Vernet|INSTRUMENT THERMOSTATIC REGULATION DEVICE AND MIXER TAP COMPRISING SUCH A THERMOSTATIC REGULATION DEVICE|

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法律状态:
2015-09-24| PLFP| Fee payment|Year of fee payment: 2 |

2016-04-01| PLSC| Search report ready|Effective date: 20160401 |

2016-09-05| PLFP| Fee payment|Year of fee payment: 3 |

2017-08-24| PLFP| Fee payment|Year of fee payment: 4 |

2018-01-19| GC| Lien (pledge) constituted|Effective date: 20171212 |

2018-08-24| PLFP| Fee payment|Year of fee payment: 5 |

2019-08-22| PLFP| Fee payment|Year of fee payment: 6 |

2019-12-27| GC| Lien (pledge) constituted|Effective date: 20191114 |

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2021-08-11| PLFP| Fee payment|Year of fee payment: 8 |

优先权:

申请号 | 申请日 | 专利标题

FR1459080A|FR3026458B1|2014-09-25|2014-09-25|THERMOSTATIC DEVICE FOR CONTROLLING CIRCULATION OF A FLUID, AND THERMOSTATIC VALVE COMPRISING SUCH A DEVICE|FR1459080A| FR3026458B1|2014-09-25|2014-09-25|THERMOSTATIC DEVICE FOR CONTROLLING CIRCULATION OF A FLUID, AND THERMOSTATIC VALVE COMPRISING SUCH A DEVICE|

US15/513,604| US10386870B2|2014-09-25|2015-09-24|Thermostatic device for controlling the flow of a fluid, and thermostatic valve comprising such a device|

PCT/EP2015/072034| WO2016046340A2|2014-09-25|2015-09-24|Thermostatic device for controlling the flow of a fluid, and thermostatic valve comprising such a device|

CN201580052148.2A| CN106716287B|2014-09-25|2015-09-24|For controlling the thermostat and the thermostatic valve for including this device that fluid flows|

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