HU207390B - Thermically controlled valve - Google Patents

Abstract

The present invention relates to a thermally controlled valve, in particular a condensate drain valve, and a compression closure cooperating with it, filled with a vaporizing medium, which is a wall part capable of stroke movement in connection with the closure member, and a spring acting in the closing direction on the closure part. It is an object of the present invention that the spring is formed as a plate spring (14), the runners (5) have a rigid wall portion (6) and a wall portion (7) capable of carrying stroke movement, a rigid wall portion (6) and a membrane (7). at their edges are joined to each other and form a recording space (8) for the vaporizing medium, and that the plate spring (14) lies on the front side of the membrane (7) opposite the rigid wall part (6) and lies in its periphery with a ring disc (16), while the inner region of the plate spring (14) engages in the closure portion (9) or the associated closure holder. EN 207 390 B Description range: 14 pages (including 5 sheets)

Description

BACKGROUND OF THE INVENTION The invention relates to a thermally controlled valve, in particular to a condensate drain valve and an expansion vessel filled with a sealing member, a vaporizing medium having a movable wall portion operably connected to the sealing member and a spring acting on the closure.

One such method is described in DE-PS 23513. In the case of a valve known from the prior art, a spring acting in the opening direction of the closure provides the advantage that the valve retains its open position even in the event of a failure of the expansion sleeve. This feature of the valve is required in some applications. The closing force acting on the closure against the opening force of the spring is determined by the pressure difference between the high pressure and low pressure sides of the valve. In order to ensure opening throughout the valve's entire application pressure range, the known valves have a spring that is so strong that it can defeat the closing force acting on the closure even in the event of maximum pressures.

If this known valve is to be closed with perfect expansion joints at the highest possible pressure, due to the relatively high closing force of the closure portion, the vaporizing medium should be able to provide only a relatively small additional low closing force. However, if this valve is used at low pressure, the closing force of the closure portion is also low. However, given that the spring force is high, a relatively high additional locking force with the evaporating medium must be obtained. This closing force, which results from the pressure difference between the inside of the expansion housing and the high pressure side of the valve, is transmitted to the closing portion by the known moving valve portion of the expansion housing. However, the force transmitted by the wall portion causes very high stresses in the wall portion and therefore the application range and the service life of the known valves are limited.

It is an object of the present invention to provide a thermally controlled valve of the type mentioned in the introduction which can be used over a high pressure range and in which the membrane has a long life.

The spring is formed as a plate spring, the expansion member has a rigid wall portion and the stroke-moving wall portion is formed as a membrane, the rigid wall portion and the membrane edges are interconnected and form a receiving space for the vaporizing medium. it lies on the opposite end face and rests on an annular disk in its wind region, while the inner region of the disk spring engages the closure portion or the closure portion connected thereto.

At each stroke position, the diaphragm is supported on its entire radial surface by a plate spring of low construction height. The closing force resulting from the pressure difference between the pressures on the receiving side and the high pressure side of the expander is transmitted directly to the closure and to the disk spring. If this force were transmitted directly through the diaphragm only, relatively high voltages would arise, which, in turn, could be completely eliminated with the valve of the present invention. Essentially, only a relatively small voltage is transmitted to the diaphragm resulting from the stroke movement. In this way, the valve of the invention can be used over a wide range and the diaphragm has a long life.

Various embodiments of the invention contained in the dependent claims provide further advantages.

Preferably, the annular disk of the present invention is firmly connected to the expander at its outer edge and has a recess for receiving the disc spring on its side toward the expander. In this way, the expansion housing, the closure portion, the plate spring and the counter bed form a building unit that can be completely prefabricated. In addition, the counter bed limits the stroke of the plate spring and thus the stroke of the diaphragm in the closing direction. In this way, the expansion sleeve can be subjected to high internal pressures, i.e. strong overheating.

Preferably, the diaphragm is provided centrally with a calotte-shaped bearing recess, and the closure or associated closure portion holder has a head disposed within the bearing recess, which has an axial abutment surface on the rim of the bearing recess for the disk spring. In this way, the membrane has no disturbing intrinsic voltage.

An especially flat expansion vessel is obtained which can withstand high external pressures if the wall portion of the expansion vessel is plate-shaped and provided with a central pot-shaped rupture having an inside diameter larger than the outer diameter of the closure. as the inner diameter of the support member of the closure portion connected to the closure member and the stop member for the membrane in the flushing. Even at low altitudes, flushing provides adequate storage space for the evaporating medium. The wall portion and the abutment portion support the diaphragm in an open position, just in its bending zone and in the region of the closure portion. In this way, the expansion bag is resistant to very high external pressures such as water strikes.

It is technologically advantageous if the stop member is a disc which is fixed at its outer edge in the wall portion in the region of the flush edge.

The pressure difference allowed for the diaphragm can be increased practically as long as a sufficiently large opening spring spring is provided to support the diaphragm. To close the valve, the spring force must exceed the pressure of the evaporating medium. In the lower part of the application range this should occur at a sufficiently low temperature. Given the lack of suitable evaporative media, the lower range of application is limited to this extent.

Increasing the area of application can be achieved by providing a valve spring second to the front face of the diaphragm facing the wall portion and a stop for the outer edge of the second spring spring.

The additional second plate spring allows it to be supported on the entire radial surface of the diaphragm from the outside to the inner edge, thus also being open. From the differential pressure

The opening force is transmitted directly to the second plate spring and the closing spring. The membrane is not exposed to high tension causing injury. In this way, the application range of the valve can be increased, as opposed to a valve where only one disk spring receives application. In a solution where the second disk spring is preferably configured as an opening spring and the closure portion has a conveyor that engages the opposite end of the second disk spring diaphragm, the spring force of each disk spring is directed toward the opening position of the closure portion. When the valve is open, the second plate spring is either unstressed or prestressed. The spring force generated by the second plate spring is transmitted to the closing portion by the conveyor.

By dividing the opening spring force into two disc springs, the voltages in each disc spring are very small and thus their service life is significantly increased.

It is possible to keep the spring force of the second disc spring at a low value, but the spring force must be at least high enough to ensure the support function of the disc spring in the upper application range of the valve. A second plate spring so dimensioned can rest on the outer edge of the diaphragm without affecting its service life. In this case, there is no need for a membrane side bed for the second plate spring.

In the case where the second disk spring is designed as a lock spring, the forces of the two disk springs are opposed to one another. In this way, particularly high-spring disk springs can be used which have a remarkably high bearing capacity. This, in turn, allows for an extremely large application range. By compensating the spring force with each other, the spring force exerted by the disc springs on the closing portion can be very small.

A particularly advantageous conveying guide may be achieved if the valve is configured such that the closure portion has a conveyor which engages the inner edge region of the second plate spring, which is on the opposite face of the diaphragm. This is particularly advantageous when the closing force of the second plate spring is selected to be as low as possible, for example only so high that its supporting capacity is sufficient to support the diaphragm over the entire upper pressure range. The opening force to be transmitted from the second plate spring is transmitted by the conveyor to the closing member. Due to the low closing force of the second plate spring, it can rely directly on the diaphragm in the lower pressure range to close the valve, without affecting the service life of the diaphragm.

It may be desirable if the closure portion has a conveyor that engages the inner region of the second plate spring at its front facing the diaphragm. This is particularly advantageous if the second plate spring has a very high closing force. If, in this conveying conduit, the second disk spring moves in the upper pressure range as a result of a differential pressure acting on the diaphragm in the opening direction of the closure portion, the displacement of the closure portion under the opening action of the first spring. Despite the fact that the second plate spring does not exert an opening force on the closing portion in this transfer guide, the valve is still open correctly.

The foregoing advantages can also be achieved by providing the valve of the present invention with the closure portion having transducers engaging the inner peripheral edge of the second plate spring on each end face thereof.

If the valve of the present invention is configured such that the first disk spring has a flat-action force path curve and both disk springs are arranged so that they are struck in the flat-running curve range, both in the open position and in the closed position, the spring forces exerted by the two disc springs on the closing portion compensate each other almost throughout the entire closing stroke. This is particularly advantageous with regard to the choice of vaporizing medium.

With respect to the second plate spring, it is advantageous if the wall portion of the expansion bag has a counter-bed for the second plate spring. It may be advantageous if the wall portion is formed in the form of a plate and has a recess for receiving a second plate spring on its side towards the membrane.

This is particularly advantageous if, for reasons of strength, for example, the spring strokes must be smaller than the shape of the wall sections would allow.

Known valves of the type mentioned in the introduction are opened depending on the amount of fluid to be discharged. For smaller quantities, the closing portion takes up a throttle position. In practice, however, it has been shown that in such a throttle position, for example when condensate is drained, the valve seat and closure are subject to extreme wear. This is especially the case when continuously smaller volumes have to be drained. To overcome the above, in a preferred embodiment of the invention, the spring is formed as a spring spring acting as a spring spring, and the spring spring acting as spring spring is arranged to have a stroke between the force maximum and the force minimum of the force curve. The valve thus formed is subject to slight wear even at lower discharge volumes.

The opening force exerted by the snap spring on the closing portion decreases during the creeping stroke of the closing portion from the fully open position to the closing position, but increases during the opening stroke from the closing position to the fully open position. Therefore, when the opening temperature is reached, it closes into the fully open position of the closure, that is, in small quantities, it exceeds the amount produced by the spring elastic expansion sleeve, which is constantly drained. Thus, less material is removed in less time. The valve closes immediately after being drained from its fully open position. The traditional spring, the so-called spring. In the case of a snap spring instead of a creeping spring, wear-off throttle positions are eliminated.

HU 207 390 B

According to the invention, it is preferred that the spring spring formed as a spring spring is a monostable spring spring which is arranged so that, in the closed position of the valve, it is in its stroke position just before the minimum force. As a result of this solution, very fast opening and closing strokes of the closure can be provided at the same force maximum. A drip spring is considered to be monostable when the direction of the spring force remains the same under the stroke of the spring, i.e., no change of thrust to thrust occurs.

It is a preferred embodiment of the invention that, in addition to the spring spring formed as a spring spring, there is an additional creep spring and the spring spring and the spring spring acting as a spring spring are arranged to sum up their strokes.

The disc spring acting as a spring spring and the auxiliary creeping spring may advantageously be combined in a single element, whereby the creeping spring is formed as the spring tongues of the disc spring. In a preferred embodiment, the expansion bag is downstream of the valve seat and downstream of the valve seat is a chamber and a closure portion operable with the valve formed in the chamber opening, the closure portion being coupled to the second sealing member in a limited relative stroke. In this embodiment, when the smallest amount passes through the first closing position of the valve during the opening process, an additional closing force is applied to the second closing portion in the chamber and an additional opening force to the first closing portion. This additional opening impulse results in the closure member being pressed into its fully open position even in this position. In addition, after performing the relative stroke, the second closure member is moved from its secure sealed position to its fully open position. Thus, even for the smallest quantities, it is possible to suddenly open completely and then close as quickly.

In a further preferred embodiment of the invention, the wall-moving portion of the membranes is formed as a membrane acting on the closure portions and the plate spring rests on the closure side surface of the membrane. The force resulting from the difference in pressure between the inside and outside of the expansion housing is absorbed by the disk spring. Thus, relatively high tensile stresses are eliminated. The expansion sleeve is only subjected to relatively low bending stress resulting from the stroke movement. Despite the rapid opening and closing movement, the valve of the present invention provides a long diaphragm lifetime for a very large application range.

The invention will be described in detail with reference to the drawings, in which:

Fig. 1 is a sectional view of an embodiment of a valve according to the invention in an open position, a

Figure 2 is a sectional view of a further embodiment of the valve in the closed position of the valve, a

Figure 3 is a sectional view of another embodiment of the valve, also in the open position of the valve,

Figure 4 is a further exemplary embodiment of the expansion sleeve of the valve of Figure 3, with the valve partially open,

Figure 5 is a further embodiment of the expansion sleeve of Figure 3, a

Fig. 6 is a sectional view of a fourth embodiment of the valve according to the invention in the open position, a

Figure 7 is a sectional view of a fifth embodiment of the valve of the present invention in the open position, a

Fig. 8 illustrates the force curve of the valve of Fig. 6, a

Figure 9 is a plan view of the disc spring of the valve of Figure 7, a

Figure 10 is a graph of the valve stroke of Figure 7, a

Figure 11 is a fragmentary sectional view of the expansion housing in a partially open position.

As shown in Figure 1, a partition (4) is provided between the high pressure side (1) and the low pressure side (2). The partition (3) separates the low pressure and high pressure sides of the valve body (not shown). On the high pressure side (1) of the seat (4), an expansion sleeve (5) is provided which has a rigid wall part (6) and a membrane (7). Together, they define the receiving space for the evaporating medium (8). The membrane (7) acts on the closure (9) on the flow side of the seat (4). The seat element (4) is provided with a valve seat (10) for the closure portion (9).

The diaphragm (7) has a calotte-shaped bearing recess (11) extending centrally into the receiving space (8). Therein lies the head 12 of the closure portion 9 in the form of a calotte, which may be rigidly connected to the membrane 7 or, as the case may be, rests thereon. At the height of the edge of the bearing recess (11), the head (12) has an abutment surface (13). To this surface, there are six inner edges of a plate spring (14) in the opening direction. At the same time, the plate spring (14) is located on the front face of the diaphragm (7) opposite the wall portion (6). Further, the disc spring (14) is disposed in a recess (15) which serves as a bearing surface with an outer edge, which recess is formed on a concavely annular annular disk (16). The ring disc (16) is provided on its inner edge (17) with retaining means which abut against the seat element (4). At the outer edge of the annular disk (16), it is firmly and tightly bonded to the membrane (7) and the wall portion (6), preferably welded.

The wall portion (6) is plate-shaped and provided with a central pot-shaped flushing (18). The internal diameter of this flushing is substantially larger than the outer diameter of the closure portion (9). In this way, even at a relatively low construction height, the flushing (18) provides an adequate receiving space (8) for the vaporizing medium. The puncture (18) comprises a perforated object (19). This disk is fixed to the wall portion (6) at the edge of the flush (18), for example by spot welding.

In the cold state, the vaporizing medium in the receiving space (8) is condensed and the vapor pressure is practically zero. The diaphragm (7) and the closure (9) are in the open end position by the force of the plate spring (14) and by the pressure of the high pressure side (1). In this position, the membrane (7) is supported on a large surface by the wall portion (6) and the disk (19). because

The disc (19) provides a stop surface for the diaphragm (7), the diaphragm (7) also supporting the closure (9).

When the expansion bag (5) is heated by the surrounding condensate, evaporation takes place in the receiving space (8). In the receiving space (8), the pressure of the evaporating medium corresponding to the current temperature is formed. If the temperature and thus the internal pressure in the receiving space (8) are sufficiently high, the membrane (7) rises from the wall portion (6) and the disk (19). Meanwhile, the diaphragm (7) rests on the plate spring (14) and the head (12) of the closure (9). When the appropriate temperature and internal pressure rises, the closing part (9) is moved in the closing direction against the action of the diaphragm (7) and the plate spring (14) and tightly pressed against our valve (10). During the entire closing stroke, the diaphragm (7) is supported by a large surface on the plate spring (14) and the head (12) of the closing portion (9). The closing force resulting from the pressure difference between the receiving space (8) and the high pressure side (1) is absorbed by the disk spring (14). Thus, the membrane (7) is not loaded with this force, but is subjected to only a relatively small bending stress resulting from the stroke movement. Thus, the diaphragm (7) can be used at high pressure differences and has a long service life.

When the expansion housing (5) is exposed to the opening temperature, the internal pressure of the receiving space (8) decreases until the opening force of the plate spring (14) exceeds the prevailing closing force and the diaphragm (7) and the closing part (9) position. Meanwhile, the diaphragm (7) does not need to exert an opening force on the closure (9), but it could not, since the closure (9) is not secured to the diaphragm (7).

If the head (12) of the closure (9) and the diaphragm (7) are firmly connected to each other, the latter can exert an opening force on the closure (9). This allows the valve to open even if the disk spring (14) fails, for example, breaks or softens.

If the expansion sleeve (5) is subjected to very high overheating, which causes an extremely high internal pressure, the annular disk (16) supports the disk spring (14) and thus the diaphragm (7). Thus, even in such a case, the membrane (7) is not overloaded.

The embodiment of Fig. 2 differs from the embodiment of Fig. 1 in that it has two closures and two valve seats. Downstream of the valve seat (10) is a second valve seat (20) and a chamber (21) is located between the two valve seats. Our first valve (10) cooperates with a first annular closure (22). Our second valve (20) cooperates with a second closure portion (23) arranged in the chamber (21) which is connected to the first to allow limited relative movement. The first closure portion (22) is sealed in the closure portion holder (24). The closure support 24 has a head 12 located centrally in the bearing recess 11 and an abutment surface 13 for the plate spring 14.

In the embodiment of Figure 2, the closure portions (22,23) open and close sequentially due to their relative displacement relationship. In this way, even for the smallest quantities, a periodic operation mode is provided, which eliminates erosion wear on the sealing sites.

In the exemplary embodiment of Fig. 3, the membrane (7) is centered on the closure (9) and the transfer bracket (25), fixed and sealed, preferably by welding the three parts together. The transfer holder (25) is located in the receiving space (8), i.e. on the side of the membrane (7) towards the wall portion (6). Instead of the closure portion (9), as in Fig. 2, a closure portion holder may be mounted on the diaphragm (7) which carries one or two closure portions and has an abutment surface (13). A second disk spring (26) is disposed between the membrane (7) and the wall portion (6) in the receiving space (8). The wall portion (6) has a recess (27) which serves as a counter-plate for the outer edge of the second plate spring (26). The counter spring (28) serves to support the outer edge of the plate spring (26) towards the diaphragm. The conveyor carrier (25) has a conveyor (29) extending beyond the inner wind region of the plate spring (26). The spring force of the second disk spring (26) acts in the opening direction of the closure.

In the cold state, the diaphragm (7) and the closure (9) are held in the open end position of the two disk springs (14 and 26) and the pressure on the high pressure side (1). This end position is defined by the stop (30) of the wall portion (6). The stops (30) engage the closure (9). However, they may alternatively or additionally be attached to a conveyor holder (25) rigidly connected to the closure (9).

In the open end position, the diaphragm (7) is supported by a second plate spring (26) over a large surface against a differential pressure acting in the opening direction.

If the expansion bag (5) is exposed to rising temperature, the vapor pressure corresponding to the current temperature is generated in the receiving space (8). This vapor pressure exerts a closing force on the closing portion (9). As soon as the vapor pressure in the receiving space (8) exceeds the pressure of the high pressure side (1), the diaphragm (7) rises slightly from the second plate spring (26) and rests on the first plate spring (14). When the closing temperature is reached, the vapor pressure in the receiving space (8) is so high that the closing portion (9) moves in the closing direction against the resulting spring force of the two disk springs (14, 26) and seals over the valve seat (10). During the entire closing stroke, the diaphragm (7) is supported by a large surface of the plate spring (14).

When the expansion bag (5) reaches the opening temperature, the vapor pressure in the receiving space (8) decreases. For this, the spring force acting in the opening direction [the spring force of the plate springs (14, 26)] exceeds the closing force dependent on the differential pressure. The membrane (7) and the closure (9) are thus moved to the opening position. The diaphragm (7) is supported on the large surface by the plate spring (14).

The opening and closing functions of the valve in the application of lower pressure ranges will now be described.

Lower pressure range refers to pressures at which, at the closing temperature, the resultant spring force of the plate springs (14, 26) acting in the opening direction exceeds the closing force exerted by the pressure on the closing portion (9).

HU 207 390 Β

Upper pressure range, on the other hand, refers to pressures at which, at the closing temperature, the spring force of the disc springs (14, 26) acting in the opening direction is less than the pressure exerted by the pressure on the closing portion (9).

The mode of operation in the upper pressure range differs from the mode of operation in the lower pressure range in that the diaphragm (7) rests on the second disk spring (26) during the opening and closing strokes under the effect of a differential pressure.

If, in the closing position, there is, for example, a large increase in pressure in the receiving space (8) due to high overheating, the diaphragm (7) also rests on the first plate spring (14) in the upper pressure range.

The diaphragm (7) is thus supported on a consistently large surface throughout the entire application range during both the opening and closing stroke, and is subject only to a slight bending strain resulting from the stroke movement. The second plate spring (26) has made it possible to substantially increase the application pressure range of the valve upwards when using the available evaporative media.

In the embodiment of Fig. 3, the second plate spring (26) may also be formed as a lock spring. This reduces the resulting spring force acting on the closing portion (9) in the opening direction. This has a positive effect on the choice of vaporizing media and the the size of the application pressure range. If the disk spring (26) is designed as a lock spring, the counter-membrane side counter (28) required for the outer edge of the second disk spring (26) may be missed. Otherwise, the operation corresponds to the operation described above.

In the embodiment of Figure 4, the second plate spring (26) is designed as a lock spring. The conveyor carrier (25) has a conveyor (31) in the inner edge region of the second plate spring (26), which engages the end face toward the diaphragm. In this way, the inner wind region of the plate spring (26) does not lie on the membrane (7). This is particularly advantageous with high spring forces. When the second disk spring (26) strikes in the opening direction due to the prevailing pressure difference, the closing portion (9) follows the second disk spring (26) under the action of the first disk spring (14). The advantages mentioned with regard to the application pressure range and the support of the membrane (7) are also given in this embodiment.

By acting against the spring forces of the disc springs (14, 26), very powerful disc springs (14 and 26) can be used which reliably support the diaphragm (7) even at very high pressure differences. The resultant spring force acting on the closing portion (9) in the opening direction is relatively small. A particular advantage is provided by the use of disc springs (14,26) which have a characteristic curve horizontally and / or in the stroke range used. they run flat because the resulting spring force remains approximately constant during the stroke.

In the embodiment of Figure 5, the second plate spring (26) is also configured as a lock spring. The conveying carrier (25) has one conveyor (29,31) on each side of the membrane (7). Thus, both closing and opening forces can be transmitted directly from the plate spring (26) to the transfer holder (25) and thus to the closing portion (9).

In the valve of the present invention, the diaphragm may consist of one or more overlapping diaphragm lamellae. The diaphragm lamellae provide particularly high flexibility. The membrane or membrane lamellae may be in the form of planar lamellas or may be formed by concentrated waves. The waves are intended to bridge the radial dimensional changes that occur during impact.

Preferably, a membrane (7) consisting of two overlapping membrane lamellae (37, 38) is used (Figure 11). The membrane (7) is clamped between the wall portion (6) and the annular disk (16) in a pre-flushed state, i.e. in the opening end position, and welded thereto. In this way, tensile stresses at the membrane (7) are eliminated.

The plate springs (14,26) are non-punctured or with or without punctures. they may be provided with radial incisions.

The embodiment of Fig. 6 differs from the embodiment of Fig. 1 in that the closure part (9) is fastened to the resiliently flexible membrane (7), which forms the striking wall part of the expansion bag (5). The closure (9) has a conveyor (32) located on the opposite side of the plate spring membrane (14). In addition, the plate spring (14) is designed as a bistable snap spring.

The valve opening and closing operation is explained in detail in the diagram of Figure 8. On the ordinate, the force (F _f ) of the disk spring (14) and the force (F _v ) exerted on the closure (9) by the internal pressure of the expansion sleeve (5) and the pressure of the medium to be drained. The abscissa is marked with stroke (H), while the opening boundary of the closure portion (9) is denoted by "auf" and the boundary of the closing position is denoted by "zu". The "zu" boundary lies before the minimum force position of the bistable disk spring stroke (33). The force (F _v ) is substantially constant during the stroke.

In the cold state, the vaporizing medium condenses in the receiving space (8) and the vapor pressure is zero. The diaphragm (7) and the closure (9) are in the "auf" open position as a result of a differential pressure acting on the plate spring (14) and the opening. The pressure difference is between the receiving space (8) and the high pressure side (1).

When the expansion chamber (5) warms up, there is evaporation in the receiving space (8) and a pressure corresponding to the vapor pressure curve is generated. When the force (F _v ) in the closing direction resulting from this and the pressure of the fluid to be discharged exceeds the force (Ff) of the plate spring (14) in point b, the closing force (9) is displaced in equilibrium in the closing direction. As soon as the characteristic curve (33) reaches the force maximum at point c, the equilibrium (F _f and F _v ) forces is overturned. The disc spring stroke (14) begins. The closure (9) moves out of its open position and moves until it is seated firmly on the valve seat (10) at point (d) in the diagram in its closed position. During the snap stroke, the direction of force of the bistable disk spring (F _f ) changes at point (e). The plate spring (14) no longer acts in the opening direction on the closing portion (9) through the stop surface (13) but in the closing direction through the conveyor (32).

HU 207 390 Β

The direction of force must be changed to open the valve (F _v ). For this, the temperature of the medium and thus the pressure in the receiving space (8) must be reduced. After such a change in direction of action, the membrane (7) acts as an incident part of the force (F _v ) in the opening direction, against the action of the disk spring (14), on the closure (9) fixed to the membrane (7). During cooling, the closing part (9) first remains in the closed position marked "zu", while at the temperature (t ₃ ), the force spring with the plate spring (14) does not balance. Since there is a decreasing tendency of the closing force (Ff) of the plate spring (14) before the force minimum, the closing part (9) is moved from its closing position to the "auf" opening position at point g. During the opening stroke, the force of the bistable disk spring (K _f ) at this point changes its direction of action.

In the event of a repeated temperature rise, the closure (9) first remains open until the equilibrium between the forces (F _f and F _v ) is reached at (b). The closure then occurs as previously described.

Thus, the closure portion (9) does not assume a wear-inducing position during the opening or closing process.

In the embodiment of Fig. 7, an intermediate chamber (21) is provided after the valve seat (10), the valve seat (20) located at its outlet opening. Our first valve (10) cooperates with an annular closure portion (22), while our second valve (20) cooperates with a second closure portion (23) located in the chamber (21). The second closure portion (23) is connected to the first closure in a manner allowing limited stroke movement between them. The first closure portion (22) is sealed in a closure portion (24) having a centered head (12) in the recess (11) of the diaphragm (7) and an abutment surface (13) for the plate spring (14). There is no need for a form sealing connection between the membrane (7) and the head (12). The disk spring (14), as illustrated in Fig. 9, has a closed annular region (34) from which, as an additional creep spring (35), the tongues spring radially inward. The region (34) is designed as a monostable snap spring while the tongues, as mentioned, act as a creep spring. The plate spring (14) rests on the closing face face of the diaphragm (7).

The closure locations formed by successive downstream valve portions close and open sequentially due to the relative displacement capability of the two closing portions (22, 23). In the diagram of FIG. 10, i.e., the force curve (36), on the monostable plate spring (36), the "auf" and "zu" boundary lines indicate the opening end position and the closing position of the closure part (23). The closure portion is configured such that the closing force exerted by the medium pressure on it is less than the difference in force between the locations indicated in (a) to (c) of the characteristic curve (36).

In the exemplary embodiment of Fig. 7, the valve moves at a rising temperature from the opening end position "auf" (point b) to point c of the force curve (36). The two closure portions (22 and 23) have a fully open position at point (c), from there (t [temperature]) the closing movement occurs in a snap action. During the suction stroke, the closure portion (23) first rests sealingly on our valve (20) (d). Meanwhile, the closing portion (22) continues to perform a squeeze stroke until it sits up on the valve seat (10) in its closed position.

The closure portion (22) is in the closed position at the force minimum of the characteristic curve (36). In the event of a decrease in temperature, the slow opening of the closure portion (22) first begins, up to the force minimum (temperature t ₂ ), from where the opening movement is abruptly continued to the fully open position. During the fast closing movement, after the relative stroke has been completed, the closing portion (22) also rapidly moves the closing portion (23) from its sealed position (point f) to its fully open position (point h).

If the closing position of the closure portion 22 is at or below the force minimum of the characteristic curve 36, the slow opening movement of the closure portion 22 is omitted. The latter happens in a snap.

The combination of the snap-action monostable disk spring (14) with the two closure portions (22,23) has the advantage that the closure portion (23) will jump from its fully open position to its fully sealed position and thus reverse motion. Further, during the opening process, a large flow cross-section between the valve seat (10) and the closure (22) is released before the closure (23) allows the flow of the medium. In this way, the erosion, abrasion effect on the valve parts is reliably eliminated.

Quick opening and closing is independent of the amount of fluid to be discharged, that is to say, even with the smallest amount discharged. The movement is actually initiated by a change in pressure in the chamber (21). Otherwise, the disc spring (14) causes opening and closing in a reliable manner.

During the stroke movement, the monostable disk spring (14) rests not only on the stop face (13) of the closure member (24), but simultaneously on the end face of the diaphragm (7). During the full stroke, the diaphragm (7) is supported by the disk spring (14) over a large surface, so that the force resulting from the pressure difference between the receiving space (8) and the high pressure side (1) is absorbed by the disk spring (14). stress. Thus, the diaphragm (7) can be used at very high pressure differences, and despite the rapid stroke movements, the diaphragm is long-lasting.

In the valve of the present invention, the diaphragm may consist of a single diaphragm or a plurality of disposed diaphragm lamellae. The membrane lamellae provide particularly high flexibility. The membrane or membrane lamellae may have a flat surface or be provided with centralized waves. The waves absorb radial dimensional changes during the stroke without warping the membrane.

Preferably, the membrane (7) is comprised of two overlying membrane lamellae (37,38) which are provided with concentric waves (Fig. 11).

In its open position, the membrane (7) is a part of the wall (6) and the wall (6)

EN 207 390 Β (16) is tightened between the welding discs and welded to them. Thus, tensile stresses in the membrane (7) are eliminated.

Claims (21)

A thermally controlled valve, in particular a condensate drain, with an expanding housing filled with our valve and a sealing member cooperating therewith, with a movable wall portion operable in engagement with the closure member, and a spring acting on the closure portion in the closing direction (14). ), the expansion body (5) has a rigid wall portion (6) and the stroke-moving wall portion is formed as a diaphragm (7), the rigid wall portion (6) and the diaphragm (7) being interconnected at their edges furthermore, the disk spring (14) rests on the front face of the diaphragm (7) opposite to the rigid wall portion (6) and lies on its annular rim (16), while the inner region of the disk spring (14) engages in a closure portion (9) or a closure portion holder (24) connected thereto. (Priority: Sep 16, 1988, Number P 3,831,474.6) Thermally controlled valve according to claim 1, characterized in that the annular disk (16) is firmly connected at the outer edge of the annulus (5) and with a recess (14) on its side towards the annulus (5). 15) has. (Priority: 09/16/1988, Number: P 3 831474.6) 3. A thermally controlled valve according to any one of claims 1 to 3, characterized in that the diaphragm (7) is provided with a centrally or calotte bearing recess (11) and the closure (9) or its associated closure holder (24) in a recess ( 11) has a disposed head (12) provided with an axial stop surface (13) for the plate spring (14) at the edge of the recess (11) of the bearing. (Priority: 16.9.1988, Issue: P 3 83 1 474.6) 4. Thermally controlled valve according to any one of claims 1 to 3, characterized in that the wall portion (6) of the expansion housing (5) is formed in the form of a plate and has a central pot-shaped flushing (18) having an inner diameter larger than the outer diameter or. as the inside diameter of the closure member bracket (24) connected to the closure member, and a stop member for the diaphragm (7) is provided in the flush (18). (Priority: Sep 16, 1988, Number P 3 831474.6) Thermally controlled valve according to claim 4, characterized in that the stop part is a disc (19) which is held on its outer edge in the wall portion (6) in the region of the flush (18) edge area. (Priority: Sep 16, 1988, Number P 3 831474.6) Thermally controlled valve according to claim 1, characterized in that there is a second plate spring (26) for abutment on the end face of the diaphragm (7) towards the wall portion (6) and an outer edge region of the second plate spring (26). . (Priority: Jul 28, 1989, Number P 3,925,032.6) Thermally controlled valve according to claim 6, characterized in that the second plate spring (26) is designed as an opening spring and the closing part (9) has a conveyor (29) which is provided with a membrane (7) of the second plate spring (26). clinging to the opposite front. (Priority: July 28, 1989, Number: P 3925032.6) Thermally controlled valve according to claim 6, characterized in that the second plate spring (26) is designed as a lock spring. (Priority: July 28, 1989, Number P 3,925,032.6) Thermally controlled valve according to Claim 8, characterized in that the closure part (9) has a conveyor (29) which engages in the inner edge region of the second plate spring (26), on the opposite side of the diaphragm (7). (Priority: Jul 28, 1989, Number P 3,925,032.6) Thermally controlled valve according to claim 8, characterized in that the closure part (9) has a conveyor (31) which engages in the inner region of the second plate spring (26) towards the end of the diaphragm (7). (Priority: July 28, 1989, Number P 3,925,032.6) Thermally controlled valve according to Claim 8, characterized in that the closure part (9) has transducers (29, 31) which engage in the inner edge region of the second plate spring (26) on each end face. (Priority: July 28, 1989, Number P 3,925,032.6) 12. A 8-11. Thermally controlled valve according to any one of claims 1 to 3, characterized in that the first disc spring (14) has a force path characteristic having a flat running characteristic and both disc springs (14,26) are arranged so that both the open position of the valve and in their closed position their stroke position is in the range of a flat running curve. (Priority: July 28, 1989, Number: P 3925032.6) 13. A 6-12. Thermally controlled valve according to any one of claims 1 to 4, characterized in that the wall portion (6) of the expansion housing (5) has a counter-branch for the second plate spring (26). (Priority: 08/27/1989, Number: 3,925,032.6) Thermally controlled valve according to claim 13, characterized in that the wall portion (6) is formed in the form of a plate and has a recess (27) on its side towards the diaphragm (7) for receiving the second plate spring (26). (Priority: July 28, 1989, Number: P 3925032.6) 15. A 6-14. Thermally controlled valve according to any one of claims 1 to 3, characterized in that the wall part (6) has a stop (30) which cooperates with the closing part (9) and limits its opening stroke. (Priority: July 28, 1989, Number P 3,925,032.6) 16. A thermally controlled valve, in particular a condensate drain valve, a cooperating sealing member, an expansion medium filled with a vaporizing medium, the movable wall portion being operatively connected to the closure member, and at least one spring acting on the closure portion in the closing direction, Β that the spring is formed as a spring spring acting as a spring spring (14) and that the spring spring (14) spring spring acting as a spring spring is arranged such that the force maxima (c) and force min of the force stroke (33, 36) (a) (Figure 6). (Priority: 09/16/1988, Number: P 3 831487.8) A thermally controlled valve according to claim 16, characterized in that the disc spring spring (14) formed as a spring spring is a monostable spring spring arranged in such a way that the minimum force (a) on the force curve (36) ). (Priority: Sep 16, 1988, Number P 3 831487.8) Thermally controlled valve according to claim 16 or 17, characterized in that it has an auxiliary creep spring (35) and is arranged to sum up the strokes of the creep spring (35) and the spring spring acting as a spring spring (14). (Priority: Sep 16, 1988, Number P 3 831487.8) Thermally controlled valve according to claim 18, characterized in that the creep spring (35) is designed as spring tongues of the plate spring. (Priority: Sep 16, 1988, Number P 3 831487.8) 20. Thermally controlled valve according to any one of claims 1 to 3, characterized in that the expansion sleeve (5) is downstream of the valve seat (10) and has a chamber (21) and a closure (23) after the valve seat (10). arranged to cooperate with our valve (20) formed in the opening of the chamber (21), and the closure portion (23) is connected to the other closure portion (22) in a limited relative stroke motion. (Priority: Sep 16, 1988, Number P 3,831,487.8) 21. A thermally controlled valve according to any one of claims 1 to 3, characterized in that the wall portion of the expansion housing (5) capable of stroke movement is formed as a diaphragm (7) acting on the closure portions (22, 23) and ) on its side surface. (Priority: 09/16/1988, Number: 3,831,487.8)