DE4308297A1 - - Google Patents

Abstract

A flow control valve, in particular for hydraulic pressure media, has an effective cross-section for the pressure media that is variable as a function of temperature. In order to achieve a considerable variation of cross-section with a compact design, the flow control regulator is equipped with a memory element made of a metal alloy having a reproducible memory effect, by means of which the effective cross-section can be changed by a change of shape of the memory element caused by a change in its crystalline structure within a narrow temperature range. Such a flow control valve is used in a particularly advantageous manner in a regulating or controlling circuit of a hydraulic pump, for pilot controlled distributing valves, pressure valves, proportional control valves and flow control valves, for regulation and injection in compression and spark ignition.

Description

The invention relates to a flow valve, which in particular is used for hydraulic pressure medium and one effect has the same cross-section for the pressure medium, the temperature-dependent is subject to change.

Such a flow valve is from the hydraulic manual, 4th edition, 1982 from Vickers based in Bad Homburg v. d. H. be knows. It contains a temperature-sensitive light metal piston ben whose dimensions change with temperature, whereby the manually set cross-section for the pressure medium automatically narrows when the temperature rises, and vice versa increases with falling operating temperature. This is supposed to be a change change in the viscosity of the pressure medium with the temperature, the with a constant cross-section to different flow resistances and thus lead to different volume flows would be compensated. Light alloy is used in space common aluminum understood that a linear expansion con constant of 0.000024 per degree. The dimensions of a lightweight metal pistons therefore change as the temperature changes very little and can change the viscosity of the pressure using imperfect balance, especially since it is on a small one Construction method arrives and therefore the length of the light alloy piston can't be big. This is also the absolute longitude limited.

Flow valves are u. a. used to the speed of To control cylinders and control vibrations of variable pumps to dampen. If you start up a hydraulic system, it increases the temperature of the pressure medium and the system components of the ambient temperature gradually to the operating temperature at. During this temperature rise, the viscosity of the Pressure medium lower, so that the flow resistances ver wrestle and z. B. a cylinder initially only with a low  Speed can be traversed that is only with Errei the operating temperature to the desired speed sets. Likewise, change with changing temperature the flow resistances in a control loop of a variable displacement pump and thus the degree of damping of the control vibrations of the Ver control pump.

The invention has for its object to provide a flow valve a temperature-dependent change in the effective cross section for the pressure medium to develop so that even a small construction a sufficiently large cross-sectional changes tion is possible.

According to the invention, this object is achieved by a flow valve, the at least one made from a metal alloy, one contains repeatable memory effect having memory element, by taking place within a small temperature interval finding and based on a change in the crystal structure Shape change the effective cross section is changeable. Components made of a metal alloy with a memory effect, a so-called th shape memory alloy, change within temperature tervalls, in which the transition from one crystal structure to the other their crystal structure takes place, their dimensions by up to 5%. In percentage terms, this change is significantly greater than the tempera change in volume of solid bodies depending on the a temperature interval of e.g. B. show -40 to +100 degrees C. and the change in the size of the Vibrations of the lattice building blocks can be attributed. Nice small memory elements therefore show relatively large absolute ones Changes in shape, so that a flow valve according to the invention very much builds small. Do you want z. B. a control edge around 150 microns move, it is sufficient if you have a memory element from a Me valley alloy with a 4% change in length, one Length of the memory element of about 4 mm.

Advantageous embodiments of a Stromven according to the invention tils can be found in the subclaims.  

In particular, versions are preferred in which several Memory elements are present that differ in terms of their order distinguish between the conversion temperature. In this way the effective cross section for the pressure medium can be particularly well on a characteristic curve that shows the dependence of a variable, e.g. B. adjust the volume flow, the viscosity indicates. For the Cross-section are then not only two extreme values possible. The Rather, cross-section can also have at least one intermediate value between his two extreme values. More advantageous wise the shape change of a memory element is added a first transformation temperature for changing the shape of another ren memory element with a second transition temperature added.

The deformation of a memory element takes place within a tem temperature interval of about 10 degrees instead. Depending on the size of the entire temperature range in which a cross-sectional change should take place and depending on the number of memory elements different transition temperatures that you want to use the transition temperature intervals can be two Connect different memory elements directly to one another or have a distance from each other. Do you want z. B. a tempe cover temperature range from -10 degrees C to +50 degrees C, so you can use six different memory elements, their conversion temperature intervals of about 10 degrees directly the connect. The temperature range should be maintained can be expanded from 6 memory elements up to +70 degrees C, so you can select the transition temperature intervals so that between the transition temperature intervals of all or too there is only a gap between some memory elements. Since the aen The viscosity changes less and less with increasing temperature is, especially for the memory elements, the higher Have transition temperatures, a distance between the Provide temperature intervals. Through different distances between the transformation temperature intervals, the cross Cut change also adapted to a non-linear characteristic will.  

Such an adjustment is particularly advantageous but possible in that according to claim 6 several Memoryele elements are present that vary in size from their distinguish solute change of shape. You can do it differently large memory elements or memory elements that are related differ from each other in their percentage change in shape, ver turn. So you can z. B. in a temperature range in which the viscosity changes greatly for large cross-sectional changes a memory element with a large percentage change use. In a temperature range in which the Vis changes little, you can use a Memoryele use with a small percentage change in shape. In the two memory elements need the absolute size indistinguishable, so such a solution especially then It is an advantage if there is enough space available. Also is a memory element with certain external dimensions and egg ner small percentage change in shape u. U. easier to use than another memory element with much smaller dimensions and a large percentage change in shape.

In principle, it is possible to use a flow valve according to the invention to be used in a case where the valve is at low or should be completely closed at high temperature. In many ways use cases, it will suffice that the effective cross cut to a minimum value that is greater than zero is changeable. Then it is favorable if according to claim 12 for the pressure medium is a first pass with a fixed cross cut and a second pass with one through the least a memory element, preferably a cross that can be changed to zero cut exist. This ensures that even at a defect in the memory elements in any case a volume electricity is possible. The first pass is advantageous a hole during the second pass between a cone surface and a circular edge is formed.

The effective cross section is preferred by a change in size of the at least one memory element in the direction of a longitudinal axis of the flow valve changed. Is the passage with ver  changeable cross section between a conical surface and a circular edge, so the conical surface and the Edge relative to each other in the direction of the longitudinal axis of the flow valve other moves.

A distinction is made between the one-way effect and the memory element Two way effect from each other. The one-way effect is a memoryele element deformed at low temperature by an external force. If you then increase the temperature, the memory elements take like which is its original form before that of the external force acted deformation. During the subsequent cooling process no further change in shape. Memory elements with two-way effect remember both a high temperature as well as a low temperature form. Accordingly, they both change their shape when heating and cooling without external help. The shape of a memory element can also be reversed change that one way effect with the help of an external force always created anew. This external force must be strong enough be a temperature-dependent when the memory element cools down bring about change in shape, but must not be so big be that they change shape when heating the memory element would hinder. The last generation method described is a reversible temperature-dependent change in shape the cheaper one. Therefore, in the preferred embodiment provided according to claim 15 that an elastic Rückstellele ment or the pressure medium one on the at least one memory element acting restoring force. If pressure medium through the flow valve flows, a pressure difference occurs from which a force acting on the memory element results due to the memory element returns to its old shape when it cools down returns and is brought into its starting position. For Recovery is also sufficient if the memory element on all sides is exposed to the same pressure, so that an enlargement and Ver reduction of the effective cross-section also takes place if no pressure medium flows, but a certain pressure is there. However, the memory element comes after one  Recovery only then to a defined starting position, when pressure medium flows again.

In order to increase the restoring force that can be exerted by the pressure medium, can one of the at least one memory Element-supported baffle for the flowing pressure medium provide.

A particularly simple construction of a Flow valve according to the invention is obtained in that it according to Claim 17 a housing with a bore that is a constriction has, and that of the at least one memory element a valve element in the bore with a Control edge or a control surface axially opposite the veren movement is movable. The valve element can also be identical be with a memory element.

To the smallest and / or largest effective cross section of the To be able to adjust the flow valve is provided according to claim 18 see that the memory element on the housing side at a relative supports adjustable counter bearing to the housing.

The valve element is preferably movable through the bore performed, then also a guide of the memory element the valve element is possible.

In another appropriate construction, the existing which memory elements and the valve element and a possibly existing elastic return element with a carrier to egg ner summarized assembly. It is according to claim 21 provided that the at least one memory element and Valve element on a carrier inserted into a housing arranges and are guided and that the memory element from the back force can be pressed against a stop on the carrier. An even currently existing reset element is advantageously both directly or indirectly on the carrier and not on one side on the Ge housing and supported on one side on the carrier.  

By an embodiment according to claims 24, 25 and 26 with simple manufacture on the one hand good guidance of the Ven tilelements or secure attachment of the carrier in the housing ge ensures and a flow of pressure medium in the bore of the Ge house enables.

An execution according to An also appears to be particularly advantageous saying 29. Then the hole is in one with an Au externally threaded housing, especially in a cylinder screw. The housing can, therefore, together with the memory elements a larger unit can be screwed in. The Me moryelemente, the carrier and the reset element so small ge be built that they z. B. in a socket head screw size M 6 fit.

In a flow valve according to the invention, depending on the application case the cross section for the flow of the pressure medium so ver be changed that the volume flow over the entire area the occurring temperatures is constant. However, it is also possible to change the effective cross-section so that the Vo lumen flow decreases with increasing temperatures. Furthermore an embodiment is also conceivable in which the volume flow increases with increasing temperatures, but the increase is less than in the case where the cross section is constant remains.

Two embodiments of a fiction, referred to as nozzle current valve are shown in the drawings. Based the figures of these drawings, the invention will now he closer purifies.

Show it

Fig. 1 shows a longitudinal section through the first embodiment,

Fig. 2 is a view of the nozzle in the direction of arrow A of FIG. 1,

Fig. 3 is a view of the nozzle in the direction of arrow B of FIG. 1,

Fig. 4 shows a longitudinal section through an assembled assembly of the nozzle of FIGS. 1 to 3 consisting of a carrier, a plurality of memory elements and a return element,

Fig. 5 shows a longitudinal section through the second embodiment,

Fig. 6 is a plan view of the valve element in the direction of arrow D from Fig. 5 and

Fig. 7, the built-in block nozzle according to Fig. 5.

The nozzle of Figs. 1 to 4 comprises a housing 10 in the form of a cylinder screw which is provided with a through bore 11. Starting from one end face 12 of the housing 10 , the bore 11 initially has a bore section 13 , the axial length of which is somewhat less than 1/3 of the length of the housing 10 and the diameter of which is approximately 2/3 of the diameter of the housing 10 . In an axially short cone 14 , the drilling portion 13 merges into a bore portion 15 , the axial length of which is also approximately 1/3 of the length of the housing 10 and the diameter of which is only slightly smaller than the diameter of the bore portion 13 . On the Bohrungsab section 15 again follows a frustoconical section 16 of the bore 11 , the axial length of which is slightly less than half the axial length of the bore section 15 and in which the diameter of the bore 11 is down to about 1/4 of the diameter of the housing 10 decreased. This reduced diameter has a last bore section 17 with which the bore 11 ends on the second end face 18 of the housing 10 . A continuous slot 19 on the end face 18 of the housing 10 allows a screwdriver to be used and the housing 10 of the nozzle z. B. hen in the housing of a hydraulic pump.

In the sections 13 and 15 of the bore 11 of the housing 10 , an assembly is inserted, which comprises a carrier 25 , a plurality of memory elements 26 to 31 and a restoring element consisting of two plate springs 32 . The carrier 25 includes a central mandrel 33 , which has at one end an outer collar 34 which acts as a stop for the plate springs 32 . The two plate springs 32 , which are supported radially on the inside of the outer collar 34, are first pushed onto the mandrel 33 . The disk springs 32 are followed by the memory elements 26 to 31 , which are designed as round disks with a central opening. The fit between the memory elements 26 to 31 and the mandrel 33 allows a longitudinal movement of the memory elements on the mandrel. Finally, a sleeve 35 is pressed onto the mandrel 33 , which, as can clearly be seen in FIG. 2, has a square outer contour with broken corners 47 in a sectional plane perpendicular to the axis 36 of the mandrel 33 . These are provided with a radius that is matched to the diameter of the bore section 13 .

The outer diameter of the memory elements 26 to 31 corresponds to the diameter of an inscribed circle of the sleeve 35 . The memory element 31 lies against the sleeve 35 , which can be regarded as the collar of the mandrel 33 . All memory elements are thus pressed by the plate springs 32 against the sleeve 35 , which serves as a further stop of the carrier 25 .

All memory elements 26 to 31 are made of such metal alloys that they change their length in the direction of the axis 36 by about 4% when the lattice structure changes, in the so-called phase transition. In this respect there is no essential difference between the different memory elements. However, their transition temperatures are different. The behavior of the memory elements when the temperature rises, z. B. the transition temperature interval of the memory element 26 between's -10 and 0 degrees C, that of the memory element 27 between 0 and +10 degrees C, that of the memory element 28 between +10 and +20 degrees C, that of the memory element 29 between +20 and + 30 degrees C, that of the memory element 30 is between +30 and +40 degrees C and that of the memory element 31 is between +40 and +50 degrees C. The conversion temperature intervals of two different memory elements are therefore directly adjacent to one another. In addition to their transition temperature, the memory elements 26 to 31 also differ in their thickness in the direction of the axis 36 . This means that with the same percentage change in thickness during the phase transition, the absolute change in shape from memory element to memory element is different. It is greatest in the memory element 26 , which is acted upon directly by the plate springs 32 , and then decreases via the memory elements 27 , 28 , 29 and 30 to the memory element 31 .

A stepped bore 37 leads through the mandrel 33 and represents the first, smallest passage for the pressure medium.

The assembly shown in FIG. 4 is inserted into the bore 11 from the end face 12 of the housing 10 and is held by an interference fit between the broken corners 47 of the sleeve 35 and the wall of the bore section 13 . An adjustability of the carrier 25 relative to the housing is not provided. As can be seen clearly from Fig. 1, the outer diameter of the Memo ryelemente 26 to 31 is smaller than the diameter of the Bohrungsab section 15 , so that an annular gap 38 is present between the memory element and the housing 10 . The collar 34 of the mandrel 33 be found at the level of the bore section 16th A second passage 40 for the pressure medium, which can flow in the annular gap 15 , is formed between the conical surface of this bore section 16 and the circular outer edge 39, facing the conical surface, of the plate spring 32 lying on the collar 34 . At maximum cross section of this second passage 40 , section 17 of bore 11 limits the volume flow. If the memory elements change their axial extent, they push the edge 39 he mentioned closer to the conical surface 16 and thereby reduce the cross section of the second passage 40 . When cooling, the memory elements under the action of the two Tellerfe 32 again take a form of reduced axial length. The cross section of the second passage 40 increases again. With this change in cross-section, the change in shape of a memory element adds to the change in shape of the other memory elements. The plate spring 32 having the control edge 39 can be regarded as an adjustable valve element of the flow valve according to FIGS . 1 to 3.

It should once again be expressly pointed out that in the nozzle shown as the first exemplary embodiment, the cross section of the bore 37 , that is to say the first passage, is not influenced by the memory elements. Only the cross section between the conical surface 16 and the edge 39 can be changed . Thus there is always a minimum cross-section for the flow of the pressure medium.

It should also be emphasized that the nozzle described works independently of the direction of flow of the pressure medium both when it flows from the front side 12 to the front side 18 and when it flows from the front side 18 to the front side 12 of the housing 10 .

The nozzle according to FIGS. 5 to 7 also has a cylinder screw with a through bore 11 as housing 10 . However, the housing 10 is extended beyond the area with the Bohrungsab section 17 and has in this extension a section 45 of the bore 11 , the diameter of which is again larger than the diameter of the bore section 17 . In addition to this, the bore cut 13 now extends up to the frustoconical bore section 16 . A bore section 15 as in the first exemplary embodiment is not present. The valve element of the second embodiment is formed by a piston 46 , which has a square outer contour with broken corners 47 over most of its length. Have ken the gebrochenden Ec, as shown in Fig. 6, as well as the Gebro rupted corners of the sleeve 35 of the first embodiment has a radius. However, this is now so matched to the diameter of the drilling portion 13 that the piston 46 in the bore section 13 is guided movably. At its end 16 facing the bore section, a cross-sectionally circular projection 48 is formed on the piston 46 , which has a control edge 39 which interacts with the conical surface of the bore section 16 . The diameter of the projection 48 is slightly smaller than the diameter of a circle inscribed in the square outer contour of the piston 46 . A groove 57 in the projection 48 also ensures in the exemplary embodiment according to FIGS. 5 to 7 that the effective cross section for the pressure medium can only be changed to a minimum value which is greater than zero.

A blind bore 49 is made in the piston 46 from the end face opposite the shoulder 48 . Two memory elements 50 and 51 are inserted into these, which are of the same size, but differ in their transition temperatures. Both memory elements 50 and 51 can be moved longitudinally in the blind bore 49 in the direction of the axis 36 of the nozzle. The memory element 51 protrudes from the piston 46 and is in the position shown in FIG. 5 of the piston 46 on a cap nut 52 which is screwed onto the cylinder screw 10 and secured in a specific position by a lock nut 53 . The cap nut 52 has a plurality of bores 54 in its hat for the passage of pressure medium. As can be seen from FIGS. 5 and 7, compared to the embodiment according to FIGS . 1 to 4 longer Ge housing of the embodiment according to FIGS . 5 to 7 is necessary because the cheese head screw 10 must protrude over the lock nut 53 in order to To be able to screw the nozzle into a block 55 , as shown in FIG. 7.

It is assumed that the individual parts of the nozzle are shown in Fig. 5 in positions corresponding to a low temperature. The memory elements 50 and 51 have their smallest dimension in the direction of the axis 36 . If the temperature now rises above the transition temperature of the one memory element, it expands in the direction of the axis 36 and pushes the control edge 39 closer to the cone 16 . If the temperature continues to rise above the transition temperature of the second memory element, this also expands in the direction of the axis 36 and the distance between the control edge 39 and the cone 16 becomes even smaller or even zero. When the temperature drops, the memory elements return to their old shape when a restoring force acts on them. This restoring force is generated once by the pressure drop in the nozzle and by the flowing pressure medium on the face 56 acting as a baffle surface 56 of the piston boss 48 . Even if no pressure medium flows through the nozzle during the temperature reduction, but only a static pressure is present, the memory elements 50 and 51 return to their old form due to the force generated by the static pressure. However, the position of the piston 46 is then not exactly determined. Only when pressure medium flows again, the memory element 51 is pressed against the cap nut 52 . The position that the piston 46 then takes over the Ke gelfläche 16 is adjustable with the cap nut 52 . Depending on how far this is screwed onto the housing 10 , the cross section between the control edge 39 and the cone surface 16 is reduced from a different size starting size ver. Depending on the application and the wishes of the user, different nozzle cross-sections can be set.

While in the nozzles according to Figs. 1 to 4, the flow direction is arbitrary, is predetermined in the embodiment of FIGS. 5 to 7, a flow of the pressure medium in the direction of arrow D.

Also in the embodiment according to FIGS. 1 to 4, the pressure drop in the nozzle contributes to the restoring force to the at Memoryele elements when the pressure medium flows from the throat 17 forth in the nozzle. The pressure in front of the control edge 39 acts on an active surface on the front plate spring 32 and generates a force in the direction of the axis 36 . Under certain circumstances, the plate springs 32 can even be dispensed with and the control edge 39 can be configured on a memory element or on an additional steel disk. The steel disk, the memory elements and the sleeve 35 which may be present can be glued to one another in order to ensure that these parts abut one another.

Claims (32)

1. flow valve, in particular for hydraulic pressure medium, with an effective cross-section for the pressure medium, which can be changed depending on the temperature, characterized by at least one memory element ( 26 to 31 , 50 , 51 ) made of a metal alloy and having a repeatable memory effect, through the inside of which a small temperature interval taking place and based on a change in the crystal structure change in shape, the effective cross section can be changed. 2. Current valve according to claim 1, characterized in that a plurality of memory elements ( 26 to 31 , 50 , 51 ) are present which differ from one another in terms of their transition temperature. 3. Current valve according to claim 2, characterized in that the change in shape of a memory element ( 26 to 31 , 50 , 51 ) with a first conversion temperature for changing the shape of another memory element ( 26 to 31 , 50 , 51 ) with a second conversion temperature. 4. Current valve according to claim 2 or 3, characterized in that the transition temperature intervals of two under different memory elements ( 26 , 27 ; 27 , 28 ; 28 , 29 ; 29 , 30 ; 30 , 31 ) directly connect to each other. 5. Current valve according to claim 2, 3 or 4, characterized records that between the transition temperature intervals a distance between two different memory elements, preferably there is a distance of 5 degrees Celsius. 6. Current valve according to one of claims 2 to 5, characterized in that a plurality of memory elements ( 26 to 31 ) are present, which differ in terms of the size of their absolute shape changes. 7. Current valve according to claim 6, characterized in that at least two existing memory elements ( 26 to 31 ) visually differ from each other in size. 8. Current valve according to claim 6 or 7, characterized net that there are at least two existing memory elements visible their percentage change in shape from each other divorce. 9. Current valve according to one of claims 2 to 8, characterized in that the memory element ( 26 ) with the lowest transformation temperature has the largest absolute change in shape. 10. Current valve according to one of claims 2 to 9, characterized in that the memory element ( 31 ) with the highest order conversion temperature has the smallest absolute change in shape. 11. Current valve according to a preceding claim, characterized characterized in that the effective cross-section for the pressure medium can be changed down to a smallest value that is greater than zero is. 12. Current valve according to claim 11, characterized in that for the pressure medium, a first passage ( 37 ) with a fe most cross section and a further passage ( 40 ) with a through the at least one memory element ( 26 to 31 ) preferably variable to zero cross section available. 13. Flow valve according to claim 12, characterized in that the first passage is a bore ( 37 ) and that the second passage ( 40 ) is formed between a conical surface ( 16 ) and a circular edge ( 39 ). 14. Current valve according to one of the preceding claims, characterized by a longitudinal axis ( 36 ) and a changeability of the effective cross section by an axial dimensional change of the at least one memory element ( 26 to 31 , 50 , 51 ). 15. Current valve according to one of the preceding claims, characterized in that an elastic restoring element ( 32 ) or the pressure medium generates a restoring force acting on the at least one memory element ( 26 to 31 , 50 51). 16. Current valve according to claim 15, characterized by an at least one memory element ( 50 , 51 ) supported baffle surface ( 56 ) for the flowing pressure medium. 17. Current valve according to a preceding claim, characterized in that it has a housing ( 10 ) with a bore ( 11 ) which has a constriction, and that of the at least one memory element ( 26 to 31 , 50 , 51 ) itself Valve element ( 32 , 46 ) located in the bore ( 11 ) can be moved axially with respect to the constriction ( 17 ) with a control edge ( 39 ) or a control surface. 18. Current valve according to claim 17, characterized in that the memory element ( 50 , 51 ) is supported on the housing side on a rela tive to the housing ( 10 ) adjustable counter bearing ( 52 ). 19. Current valve according to claim 17 or 18, characterized in that the valve element ( 46 ) through the bore ( 11 ) is movably guided. 20. Current valve according to claim 19, characterized in that the at least one memory element ( 50 , 51 ) of the valve element ( 46 ) is guided. 21. Current valve according to claim 17 or 18, characterized in that the at least one memory element ( 26 to 31 ) and the valve element ( 32 ) on a in the bore ( 11 ) of the housing ( 10 ) fixed to the housing ( 25 ) arranged and are guided that the memory element ( 26 to 31 ) can be pressed by the restoring force against a stop ( 35 ) on the carrier ( 25 ), and that between the carrier ( 25 ) together with the memory element ( 26 to 31 ) and the valve element ( 32 ) and the housing ( 10 ) has space ( 38 ) for the flow of the pressure medium. 22. Current valve according to claim 21, characterized in that the at least one memory element ( 26 to 31 ) and the valve element with a central bore on a mandrel ( 33 ) of the carrier ( 25 ) are pushed that the memory element on one side against the Stop ( 35 ) can be pressed against the support ( 25 ) and that a possibly present reset element ( 32 ) is arranged on the other side of the memory element ( 26 to 31 ) and is supported on a further stop ( 34 ) of the support ( 25 ). 23. Current valve according to claim 22, characterized in that a plate spring ( 32 ) forms the elastic return element and the valve element. 24. Flow valve according to one of claims 17 to 23, characterized in that the valve element ( 46 ) or the carrier ( 25 ) at least in sections has a polygonal, in particular a regularly polygonal, in particular a square outer cone and at the corners ( 47 ) the outer contour contacts the wall of the bore ( 11 ). 25. Current valve according to claim 24, characterized in that the corners ( 47 ) of the outer contour are broken and provided with a Ra dius which corresponds at least approximately to the radius of the bore ( 11 ) of the housing ( 10 ). 26. Current valve according to claim 24 or 25, characterized in that the at least one memory element ( 26 to 31 ) has a circular outer contour, the diameter of the memo ryelements ( 26 to 31 ) preferably equal to the diameter of the inscribed circle of the regularly polygonal outer contour is. 27. Flow valve according to claim 22 or according to claim 22 and one of claims 23 to 26, characterized in that the first passage ( 37 ) for the pressure medium through the mandrel ( 33 ) of the carrier ( 25 ). 28. Flow valve according to claim 27, characterized in that the first passage ( 37 ) and the second passage ( 40 ) un directly in front of the mandrel ( 33 ) and in the region of the constriction ( 16 ) in the bore ( 11 ) of the housing ( 10 ) meet. 29. Current valve according to one of claims 17 to 28, characterized in that the bore ( 11 ) in a housing provided with an external thread ( 10 ), in particular in a cylin der screw. 30. Current valve according to one of the preceding claims, characterized in that a plurality of memory elements ( 26 to 31 ) are present which differ from one another in terms of their transition temperature, and in that the absolute size of the change in shape of the various memory elements ( 26 to 31 ) is selected in such a way that that the pressure medium flow is at least approximately independent of temperature. 31. Current valve according to one of the preceding claims, characterized in that the absolute size of the change in shape of at least one memory element ( 26 to 31 ) is selected such that the pressure medium flow is lower at a higher of two temperatures than at the lower temperature. 32. Use of a flow valve after a previous one Claim in a control or control circuit of a hydraulic Pump, for piloted displacement, pressure, proportional and servo valves, for controls and injections for diesel and petrol Engines.