EP1801514B1 - Flow evaporator for discharging a liquid - Google Patents

Description

The invention relates to a continuous evaporator for removing an accumulating liquid, for example a condensate, comprising an evaporation chamber, which has an inlet opening, an evaporation bottom, which limits the evaporation chamber in the installed state of the continuous evaporator substantially in the direction of gravity, and a steam outlet, and a liquid channel, which extends from the inlet opening to a water inlet opening arranged outside the evaporation chamber and which forms a vapor closure, in that it has a closure cross-section arranged completely below the inlet opening in the direction of gravity.

In a variety of technical devices, it is necessary to dissipate liquids that accumulates in these devices. An example is bilge water that occurs in ship's bladders.

For example, condensed water will precipitate in a control cabinet that is installed outdoors. Other appliances in which gas can condense and liquids then accumulate are air conditioners or condenser dryers for laundry.

In general, the resulting condensation is collected in such devices in a tub and can then be derived directly. Thus, the sump can be provided with an outlet valve, through which the liquid can be discharged to the outside. It is also possible to transport the liquids out of the devices via pumps.

However, direct discharge of the liquid is not always possible. In this case, the condensation can be evaporated or evaporated. The resulting steam is then led out of the electrical appliance.

In the US 2005/217299 A1 is a device for removing condensate from an air-liquid heat exchanger, in particular a heat exchanger, in a closed electronic device is arranged described. The apparatus comprises a condensate collection device, an evaporation chamber, an evaporator disposed in the evaporation chamber, and a gas outlet communicating with the evaporation chamber.

With this method, it must be ensured that the resulting steam must be directed out of the device in a targeted manner. Targeted means that the steam is directed out of the unit in a defined direction. It must be avoided that the steam gets back into the electrical appliance and re-precipitates in the appliance.

The EP 0 445 089 A1 relates to a method and a device for controlling the steam generation, by which overheating of the steam generator is to be prevented. The device comprises a water tank for receiving the water to be evaporated and the heating elements arranged in the water tank. Is provided via an insertion tube with a water seal, the lowest level above the tank bottom, but below the inlet opening through which the filled water enters the tank, is arranged.

The publication GB 1 578 269 A discloses an evaporation tank with a pipe opening therein. Furthermore, the evaporation tank has a steam outlet opening. The tube 2 serves to supply liquid into the evaporation container 3. For heating the liquid, a heating element is exchanged therein.

The present invention has for its object to provide a continuous evaporator, which is of simple design, can be manufactured inexpensively and is able to carry away fluid targeted.

This object is achieved in that a heating element is thermally conductively connected to the evaporation chamber and outside, preferably located above or below the evaporation chamber.

This solution is structurally simple and makes it easy and inexpensive to manufacture the continuous evaporator according to the invention.

The embodiment of the invention with the liquid channel as a vapor lock ensures that the steam generated in the evaporation chamber can not escape through the inlet opening. Thus, it is achieved that the steam to be transported away escapes substantially exclusively through the steam outlet opening and can thus be removed in a targeted manner. Additional components, such as inlet valves, are therefore not required.

The evaporator according to the invention thus forms a continuous evaporator, which is capable of continuously transporting condensate from an electrical appliance. When the level of condensation in the sump exceeds the level of the inlet of the installed evaporator, water will flow into the evaporation chamber. The liquid channel is then filled with liquid at least from the cross-sectional closure to the inlet opening and forms the vapor closure, which could also be referred to as vapor reflux valve. In the evaporation channel, the liquid spreads on the evaporation tray, is continuously evaporated or evaporated and the resulting vapor is discharged through the steam outlet.

In the following, for the sake of simplicity, only evaporation will be discussed. Evaporation, strictly speaking, the transition of a substance from the liquid to the gaseous state below the boiling point of the substance, in the context of this invention but also includes evaporation, so the mass transfer from the liquid to the gaseous state at boiling temperature, with a. The device according to the invention could therefore also be referred to as a continuous evaporator.

The direction of gravity is the direction in which the force of gravity acts on the evaporator in its mounted, operational orientation. The axis of gravity substantially coincides with the liquid level of the condensed water, which is e.g. in a sump of an electrical appliance accumulates, together, where liquid level is the water level axis of the liquid level to understand.

The term condensation is not limited to H ₂ O only. For the purposes of this invention, water or condensed water is any fluid that can accumulate in an electrical appliance and must be removed.

The term evaporation chamber in the sense of the present invention stands for the space of the continuous evaporator in which the thermally assisted mass transfer of the water from the liquid to the gaseous state takes place.

The continuous evaporator according to the invention can be further developed by different, mutually independent and individually advantageous embodiments. These refinements and the advantages associated with the respective embodiments will be briefly discussed below.

Thus, in a first advantageous embodiment, the water inlet opening can be arranged in the direction of gravity below the inlet opening. As a result, first, the length of the liquid channel can be shortened. Secondly, the liquid channel in this embodiment can be structurally simple, namely essentially straight.

In a further advantageous embodiment, the evaporation tray may be arranged in the direction of gravity below the inlet opening. This has the advantage that the part of the condensed water, which enters the evaporation chamber through the inlet opening and accumulates on the evaporation floor, can not immediately flow back into the liquid channel. Only when the liquid layer on the evaporation tray corresponds to the level difference between the evaporation tray as the lower level and the inlet opening as the upper level, the liquid from the chamber could again enter the liquid channel.

According to this embodiment, one can therefore also speak of the fact that the evaporation tray is designed as an evaporation tray or an evaporation basin. The evaporation tray holds the liquid located in the evaporation chamber substantially in the direction of gravity, but additionally forms a flow restriction perpendicular to the direction of gravity. This flow restriction prevents the backflow of water from the tub into the fluid channel.

A similar effect can be achieved according to a further advantageous embodiment by an overflow weir, which is arranged in the liquid channel.

Furthermore, the liquid channel may have a weir region, which limits the evaporation chamber in sections. Preferably, the weir portion of the liquid passage in the region of the inlet opening and extends substantially in the direction of gravity. Thus, the liquid channel is at least partially integrated into the wall of the evaporation chamber and reaches a continuous evaporator of compact design.

Another advantageous possibility to prevent the flow of condensate from the evaporation chamber into the liquid channel is an embodiment in which the liquid channel protrudes at least in sections from the evaporation bottom into the evaporation chamber. As a result, the projecting into the evaporation chamber portion of the liquid channel forms a Übenaufkragen. functionally equivalent to a weir in the form of the channel cross-section. Here, the inlet opening forms the weir crown over which the condensate overflows from the liquid channel into the evaporation chamber.

Furthermore, the cross-section of the liquid channel may be tapered in the region of the inlet opening in order to make it more difficult for the liquid to be removed from the evaporation chamber to flow back into the liquid channel. In this way, the area of the inlet opening is reduced, for example by the funnel-shaped tapering of the liquid channel in the region of the inlet opening. The version with an overflow weir in the liquid channel achieves a comparable effect, since the overflow weir also leads to a cross-sectional constriction.

According to an advantageous embodiment of the present invention, a hollow body can form the evaporation chamber. In principle, the evaporation chamber or the chamber forming and enclosing hollow body can be formed arbitrarily. In particular, however, such hollow bodies may be advantageous, which have a, based on the chamber volume large evaporation bottom. In this way, a large evaporation surface is provided for the mass transfer, which accelerates the evaporation.

Advantageously, the hollow body may be formed as an evaporation tube. The cross-sectional profile of the evaporation tube can be arbitrary, with cost considerations in particular standard tubes with round, oval or rectangular cross-sections are advantageous. Another advantage of a hollow body and in particular of an evaporation tube is that this embodiment is already equipped by its physical shape already with an inlet opening at one end and a steam outlet at its other end.

In a further advantageous embodiment, a channel-shaped fluid-flowable heat sink, which is connected to the heating element, comprise the evaporation chamber at least in sections. Preferably, the heat sink may be shaped to immediately form the evaporation chamber. To this Firstly, it is ensured that the evaporation chamber is heated as evenly as possible. Second, it can be dispensed with additional components for the evaporation chamber.

Alternatively, a hollow body through which fluid can flow may also be pressed in the channel-shaped heat sink.

In order to improve the heat transfer from the heating element in the evaporation chamber and at the same time to simplify the installation of the continuous evaporator, according to a further embodiment, a profile body form the heat sink. In addition, the hollow body has a further, separate from the heat sink cavity in which the heating element is arranged. For this purpose, the profile body may be formed of an extruded profile.

In order to secure the heating element in the cavity of the profile body and at the same time to ensure a good heat transfer from the heating element to the profile body, the heating element can be compressed in the cavity substantially free of air. Alternatively, a bonding, preferably with a good heat-conducting adhesive, or any other method of attachment is possible.

The heat transfer from the heating element into the evaporation chamber can also be improved by connecting the heating element directly, ie not indirectly via a heat sink, to the evaporation chamber and in particular to the evaporation basin. For example, the heating element can be wound around the evaporation chamber. It is also possible that the heating element forms the evaporation chamber at least in sections, preferably in the region of the evaporation bottom.

In principle, it is advantageous if the heat-conducting components, ie the profile body, the heat sink and the wall of the evaporation chamber are made of a good heat-conducting material, such as copper, aluminum or stainless steel.

In principle, any heating elements can be used in the continuous evaporator according to the invention, wherein advantageously electrical heating elements can be used. For example, a resistance heating element can form the heating element. It should be noted, however, that a resistance heating element, for example in the form of a heating wire or a hot plate, must be switched externally. In order to avoid unnecessary energy losses, therefore, a resistance heating element should be used in combination with a sensor, which monitors, for example, the level in the reservoir, and a control unit.

According to a particularly advantageous embodiment, the heating element may be a PTC (Positive Temperature Coefficient) element. PTC elements have the advantage that they are self-regulating and the continuous evaporator according to the invention does not require a sensor or control device according to this embodiment. The PTC element can be permanently powered without causing much energy loss. The idle power consumed, i. in the case that no condensation in the evaporation chamber is present, is very low. At the same time, it is ensured that, due to the special characteristics of PTC components, the power and thus the heat generated increases abruptly as soon as liquid flows into the evaporation chamber.

Of course, the PTC heating element can also be connected to an external control device and controlled by its signals. In this embodiment, even the low energy losses during idling of the PTC element can be avoided.

According to another embodiment, an inlet nozzle, which is fluid-tightly connected to the inlet opening, form the liquid channel. An advantage of this embodiment is that the inlet nozzle can be replaced and adapted to changing requirements of the continuous evaporator or the electrical appliance. This embodiment is particularly advantageous for the embodiment with an evaporation channel or an evaporation tube as the evaporation chamber, since the Inlet port can be connected directly to the inlet opening of the chamber or the pipe.

Further, a steam pipe may be connected to the steam outlet port. The connection can, as well as the connection between inlet nozzle and evaporator, in a known manner, for example by pressing, screwing or flanging be realized.

According to an advantageous embodiment, the cross-sectional area of the steam pipe may be greater than the cross-sectional area of the liquid channel. In this way, the steam outlet from the evaporation chamber through the steam pipe, provided, of course, that also the inlet opening is dimensioned correspondingly smaller than the steam outlet opening, easier.

In order to avoid that water from the steam pipe injected into the environment, the steam pipe sections may have a splash water protection area with extended pipe cross-section.

Of course, the steam pipe is not limited to pipes with a rigid wall. It is also flexible fluid lines, ie hoses can be used.

Furthermore, the continuous evaporator can be encased at least in sections by a housing. Preferably, the evaporation chamber or the complete continuous evaporator can be completely housed in the housing. The advantage of this is initially an improved sealing of the device according to the invention. Furthermore, the embodiment with housing avoids, in particular if the housing is made of a thermally insulating material, that the tub used for evaporation is also released to the environment. Negative influences from the outside on the heating power can be reduced by a housing. Finally, a housing made of insulating plastic also avoids that in the tub of the electrical appliance accumulated and to be removed condensate is heated. In addition to increased energy consumption, heating the condensed water leads to a reduced evaporation performance of a PTC element, because this provides its greatest performance at low temperatures, so especially with cold water.

Furthermore, the housing may have four feet, which is advantageous in that as a result, the contact area between the housing and the surrounding housing, the tub is reduced. The advantage of this is that in this way less heat is introduced from the housing into the tub.

According to a further advantageous embodiment, the steam pipe and / or the liquid channel may be formed as parts of the housing. Thus, the housing may have an inlet-side wall with the liquid channel and an outlet-side wall with the steam pipe. The ends of a hollow body in general, and in particular of an evaporation tube, can be connected to the liquid channel or the steam tube of the housing in a particularly simple manner at the inlet opening or the steam outlet opening. In this way, in particular the assembly and sealing of the housing is facilitated at the openings of the evaporation chamber.

Finally, according to a further embodiment, the inlet-side or the outlet-side wall may have a cable-discharge opening which is provided with a drip-off means. Through the Kabelausführöffnung the electrical leads of the heating element can be led out of the housing of the continuous evaporator according to the invention. The drip, for example, a bent in the direction of gravity roof, reduces the sealing effort of the heating element, as condensing water precipitating on the cable is discharged via the drip back into the tub outside of the continuous evaporator.

The invention will now be described by way of example with reference to the accompanying drawings. The different features can be combined independently of each other, as has already been explained above in the individual advantageous embodiments.

Fig. 1

eine schematisch geschnittene Darstellung einer ersten Ausführungsform eines erfindungsgemäßen Durchlaufverdunsters;

Fig. 2

eine schematische geschnittene Darstellung einer zweiten Ausführungsform des erfindungsgemäßen Durchlaufverdunsters;

Fig. 3

eine dritte Ausführungsform des erfindungsgemäßen Durchlaufverdunsters in einer perspektivischen Explosionsdarstellung; und

Fig. 4

die Ausführungsform der Fig. 3 symmetrisch geschnitten entlang der Längsachse des Durchlaufverdunsters.

Show it:

Fig. 1

a schematic sectional view of a first embodiment of a continuous evaporator according to the invention;

Fig. 2

a schematic sectional view of a second embodiment of the continuous evaporator according to the invention;

Fig. 3

a third embodiment of the continuous evaporator according to the invention in a perspective exploded view; and

Fig. 4

the embodiment of the Fig. 3 symmetrically cut along the longitudinal axis of the continuous evaporator.

Fig. 1 shows an exemplary embodiment of the continuous evaporator 1 according to the invention for transporting a liquid 2 from an electrical appliance 3. In installed outdoors, cabinets, Kondenstrocknem for laundry or in air conditioning accumulates in the interior of the electrical device 3 condensate 2. The condensate 2 is collected in a reservoir 4 and collected. The continuous evaporator 1 according to the invention is according to Fig. 1 installed in the reservoir 4. For the sake of clarity, in the schematic representation of Fig. 1 The details with regard to the installation of the continuous evaporator 1 in the reservoir 4 is omitted. It should be noted, however, that continuous evaporator 1 is mounted in a stationary manner in the reservoir 4.

The continuous evaporator 1 comprises in the in Fig. 1 an evaporation chamber 5. The evaporation chamber 5 has an inlet opening 6, an evaporation bottom 7 as well as a steam outlet opening 8. Through the inlet opening 6, in Fig. 1 shown on the left side of the evaporation chamber 5, condensed water 2 enters the evaporation chamber 5, as soon as the liquid level F in the reservoir 4 exceeds an evaporation level F _D. The spatial axis of the liquid level F corresponds to the direction of gravity g, which acts on the continuous evaporator 1 in the installed state.

The part of the condensate 2, which flows through the inlet opening 6, forms a liquid film 9 in the evaporation chamber 5 on the evaporation bottom 7. The evaporation bottom 7 delimits the evaporation chamber 5 in the installed state of the continuous evaporator 1 substantially in the direction of gravity g.

A heating element 10 is thermally conductively connected to the evaporation chamber 5. In Fig. 1 the heating element 10 is connected directly to the evaporation bottom 7. The heating of the evaporation bottom 7 caused that also the liquid film 9 is heated in the evaporation chamber 5 and the liquid state of matter in gaseous vapor 11 (in Fig. 1 symbolized by dots) is transferred.

The generated vapor 11 finally flows through the steam outlet 8, in FIG Fig. 1 lying on the right side of the evaporation structure 5, out of the evaporation chamber 5 out. The steam outlet 8 is connected to a steam pipe 30 through which the vaporized liquid 11 from the. Electric appliance 3 is removed, since the steam pipe 30 opens outside the electrical appliance 3.

So that the generated steam 11 leaves the evaporation chamber 5 essentially exclusively through the steam outlet opening 8, but in no case through the inlet opening 6, the continuous evaporator 1 according to the invention has a liquid channel 13. The liquid channel 13 extends from the inlet opening 6 to a water inlet opening 14. The water inlet opening 14 is arranged outside the evaporation chamber 5 and lies in the collecting basin 4.

The liquid channel of Fig. 1 is substantially U-shaped or J-shaped, wherein in particular the arc region in the direction of gravity g is completely below the inlet opening 6 and a closure portion 12 of the in Fig. 1 forms shown embodiment. The water inlet opening 14 is in the direction of gravity below the inlet opening 6, however, above the arc area. This arrangement causes the condensate 2 from a filling level F _F through the water inlet opening 14 into the arc region of the liquid channel 13 runs. As long as the liquid level F in the reservoir 4, although above the level F _F but Below the evaporation level F _D , only the liquid channel 13 fills with condensation 2. An evaporation takes place only when the water level F in the reservoir 4 and the corresponding water column in the liquid passage 13 exceeds the evaporation level F _D. Then liquid 2 flows into the evaporation chamber 5. In this state, the water column standing in the liquid channel 13 from the channel bend 12 to the inlet opening 6 forms a vapor seal 15 due to the siphon-shaped liquid channel 13. The vapor seal prevents the generated vapor 11 from flowing back through the liquid channel 13 can reach the interior of the electrical device 3.

In a simple way, the continuous evaporator 1 according to the invention thus realizes that the steam 11 generated can be transported in a targeted manner and essentially exclusively in one direction, namely through the steam outlet opening 8 from the continuous evaporator 1 and thus the electrical appliance 3.

In Fig. 2 is a further embodiment of the continuous evaporator 1 according to the invention shown schematically and in section. The presentation of the Fig. 2 shows only an enlarged section of the inlet zone of the continuous evaporator 1, ie the area in which the liquid channel 13 opens at the inlet opening 6 in the evaporation chamber 5. For the sake of clarity, reference is made in particular to the illustration in the region of the steam outlet opening 8, which is the illustration of FIG Fig. 1 corresponds, waives. The following is for parts whose function and / or structure identical or similar to parts of Fig. 1 is the same reference number as in Fig. 1 used.

Unlike the execution of the Fig. 1 is the evaporation tray 7 at the in Fig. 2 shown embodiment arranged in the direction of gravity below the inlet opening 6. The inlet opening 6 of Fig. 2 is thus formed in a side wall of the evaporation chamber 5, whereas the inlet opening 6 of the Fig. 1 in the region of the evaporation bottom 7, the liquid channel 13 is the Fig. 2 not only forms a vapor seal 15, but is essentially an overflow weir.

In particular, the weir section 41 of the liquid channel 13, that is the part of the liquid channel wall which forms a lateral chamber wall from the evaporation bottom 7 against the direction of gravity g, ensures that the evaporation chamber 5 of the execution of Fig. 2 In the area of the evaporation bottom 7, an evaporation trough or an evaporation basin is formed. The weir portion 41 thus forms a backstop for the liquid film 9 and prevents, even in the case of a drop in the condensed water level below the evaporation level F _D , the liquid film 9 remains in the evaporation chamber 5.

Furthermore, the execution of the Fig. 2 in that the liquid channel 13 is tapered in the region of the inlet opening 6, ie has a smaller channel cross-section D ₂ than in the region of the water inlet opening 14, where the channel cross-section D ₁ is

The cross-sectional constriction is generated by a second overflow weir 16, which is arranged in the liquid channel 13. In the process, a throttle section 17 initially adjoins the weir section 41 of the fluid channel 13. The throttle portion 17 extends perpendicular to the channel walls of the liquid channel 13 and parallel to the evaporation bottom 7. The length of the throttle portion 17 corresponds to the cross-sectional difference of D ₁ and D ₂ .

Starting from the end of the throttle section 17, which is spaced from the weir section 41, the overflow weir 16 begins. The overflow weir 16 again runs essentially parallel, but offset by the length of the throttle section 17, to the weir section 41 and ends in a weir crown 18.

In the schematic representation of Fig. 2 form Wehrabschnitt 41 and overflow weir 16 a two-stage weir with a substantially stair-step-shaped heel. Accordingly, the condensed water 2 flows after exceeding the evaporation level F _D first on the weir crown 18 of the overflow weir 16 on the throttle portion 17. From the throttle portion 17, the water passes over the edge at the junction of throttle section 17 and weir section 41 in the tub. The overflow direction of the condensate is symbolized schematically by arrows.

Furthermore, evaporation chamber 5 and liquid channel 13 of the Fig. 2 not how Fig. 1 , integrally formed at Fig. 2 the fluid channel is a short piece of pipe, an inlet nozzle 33, which is fluid-tightly connected to the inlet opening, screwed here. The water inlet opening 14 of the inlet nozzle 33 is located approximately at the level of the evaporation bottom and at the same time constitutes a sealing cross-section 12.

Fig. 3 shows a schematic exploded view of a third embodiment of the continuous evaporator according to the invention 1. Based on the Fig. 3 the advantages, in particular the advantages in the assembly of the continuous evaporator 1 according to the invention are explained below. For parts whose structure and / or function is similar or identical to parts of the previous embodiments, the same reference numerals as in Figs Fig. 1 and 2 used

The Durchlaufverdunster 1 the Fig. 3 is modular and consists of an evaporation tube 19, a heating element 10, a profile body 20 and a housing 21st

The evaporation chamber of the Fig. 3 is formed by a hollow body, namely the evaporation tube 19. The wall of the rectilinear evaporation tube 19 encloses and thus delimits the evaporation chamber 5: The open ends of the evaporation tube 19 form the inlet opening 6 at the inlet end and the vapor outlet opening 8 at the outlet end.

The heating element 10 is in the in Fig. 3 PTC heating elements 10 are known from the prior art and have, in addition to the heat-generating PTC element (not shown), two electrode body (not shown) and an insulating 42nd on. In this case, the plate-shaped PTC element is sandwiched between the two Elektrodenkörpem arranged so that the largest possible contact surface between the electrode body and PTC element consists The electrode body and the PTC element of a film-shaped insulating element, such as a thermally conductive polyimide film, eg Kapton film, enclosed. The electrode bodies are connected via contact lines 26 to a voltage source (not shown).

In a particularly advantageous embodiment, the film-shaped insulating element 42 can be rolled out of Kapton film, which is closed on one side after rolling to form a shell by heat seal.

The profile body 20 is formed by an extruded profile and initially has a fluid-flowable channel-shaped heat sink 22. The heat sink 22 forms a flow channel or a flow tube, into which the evaporation tube 19 can be inserted along an assembly direction M, which runs essentially in the flow direction of the evaporation tube 19 or the heat sink 22. The heat sink 22 comprises the evaporation chamber 5, which is formed by the evaporation tube 19, at least in sections. At the in Fig. 3 In the illustrated embodiment, the evaporation tube 19 is longer than the channel formed by the heat sink 22, so that the evaporation tube 19 protrudes from the heat sink 22 at both ends in the mounted state.

In order to fix the evaporation tube 19 in the heat sink 22, the heat sink has press beads 23. The Presswülste 23 can be pressed together, whereby the heat sink is deformed and compressed substantially without air gap around the evaporation tube 19. This has the advantage that, firstly, the evaporation tube 19 can be fastened in a simple manner in the heat sink 22 and, secondly, that the air gap-free compression allows a good heat transfer from the heat sink 22 to the wall of the evaporation tube 19.

The profile body 20 also has a further, separate from the heat sink cavity 24, which substantially corresponds to the shape of the heating element 10. The heating element 10 can be inserted in the mounting direction M in the cavity 24 of the profile body 20 and disposed in the cavity 24. The profile body 20 has in the region of the cavity 24 more press beads 25. In a similar way to Evaporation tube 19, the heating element 10 compressed air gap in the cavity 24 and mounted in the profile body.

The evaporation module 43 comprises the evaporation tube 19, the heating element 10 and the profile body 20. This unit ensures efficient heat transfer from the heating element 10 into the profile body 20, which preferably comprises an extruded profile a thermally conductive material such as aluminum. In the profile body, the heat is transported to the heat sink 22 and passed from the heat sink 22 via the wall of the evaporation tube 19 into the evaporation chamber 5.

According to the in Fig. 3 the embodiment shown, the heating element 10 is arranged in the direction of gravity g above the evaporation chamber 5 Advantageous here is that the contact lines 26 are then always above the evaporation chamber and thus the condensate level F are arranged. Further, the water inlet opening 14 is in this arrangement at a particularly low level F.

Of course, however, the heating element 10 may also be arranged in the direction of gravity g below the evaporation tube 19. This embodiment would have the advantage that then the heating element 10 directly to the bottom region of the evaporation chamber 5, on which the liquid film 9 (in Fig. 3 not shown) collects, adjoins. This would be advantageous in terms of the heat transfer into the liquid film.

The evaporation module 43 with evaporation tube 19, heating element 10 and profile body 20 can be easily inserted into the housing 21 and secured in the housing and sealed.

The housing 21 comprises a housing body 27, which has an insertion opening 28, through which the evaporation module 43 in the mounting direction M in the housing body 27 is insertable. In the mounting direction M, the housing body 27 is bounded by an outlet-side wall 29, which represents a first mounting shoulder for the inserted unit, whereby the evaporation module 43 is fixed in the mounted direction in the mounting direction M.

The outlet-side wall 29 also has a steam pipe 30 and an attachment point 31. The steam pipe 30 is connected in the mounted state of the continuous evaporator 1 with the steam outlet 8 (not shown) of the evaporation tube 19, which is described in detail below.

At the attachment point 31 of the continuous evaporator 1 can be attached, for example, be screwed in a sump.

The insertion opening 28 of the first housing part with the housing body 27 in the outlet-side wall 29 can be closed by a second housing part, namely the inlet-side wall 32. The inlet-side wall 32 thus forms a housing cover, which closes the interior of the housing body 27. The evaporation module 43 is completely enclosed by the housing 21 in the assembled state.

The inlet side wall 32 also has an attachment point 31 ', which corresponds to the attachment point 31 of the outlet side wall. Further, in the inlet side wall 32, an inlet port 33 is formed, which forms the fluid passage 13 (not shown). In the assembled state, the inlet opening 6 of the evaporation tube 19 is fluid-conductively connected to the inlet nozzle 33, which will be shown in detail below.

Finally, the inlet-side wall 32, opposite to the direction of gravity g above the inlet nozzle 33, has a cable discharge opening 34. The Kabelausführöffnung 34 is disposed substantially level with the heating element 10, so that the contact lines 26 of the heating element 10 through the Kabelausführöffnung 34 out of the housing 21 and outside the housing 21 with a voltage source (not shown) can be connected.

The Kabelausführöffnung 34 is provided on the outside of the inlet-side wall 32 with a drip 35. The dripping means 35 according to the in Fig. 3 embodiment shown is formed by an arcuate neck. The Abtropfstutzen 35 extends away from the outside of the wall 32 and is curved in the direction of gravity g. Condensation, which precipitates on the cable lines 25 outside the housing 21, runs along the drip means 35 in the direction of gravity g and thus can not get into the interior of the housing 21.

The housing 21 is further provided with four feet 40. Two feet 40 are arranged on the inlet-side wall 32 and the outlet-side wall 29. The housing wall 29, or 32 are on the surface to which the gravity g assigns perpendicular, arcuately cut out so that the outer edge regions of these surfaces form the feet 40. Since the housing body 27 in the direction of gravity g does not reach down to the feet, the housing is only on the four feet 40th

Fig. 4 shows the continuous evaporator of the Fig. 3 in the assembled state in a sectional view in the mounting direction M along the center axis of the evaporator 1. For parts whose function and / or structure is identical or similar parts of the previous figures, the same reference numerals as in the preceding figures are used.

Fig. 4 shows how the evaporation module 43 is accommodated with profile body 20, heating element 10 and the evaporation tube 19 in the housing body 27 of the housing 21. The ends of the evaporation pipe 19 are connected to the inlet port 33 of the inlet side wall 32 and the steam pipe 30 of the outlet side wall 29, respectively.

Further shows Fig. 4 in that the heating element 10 is arranged essentially at the level of the cable discharge opening 34 of the inlet-side wall 32, so that the contact lines 26 can be guided out of the housing 21. In order to seal the cable outlet opening, the cable lines 26 are encased with a sealing element 36. The sealing element essentially forms a plug which closes and seals the cable outlet opening 34

Furthermore, in Fig. 4 to recognize that the evaporation tube 19 protrudes beyond the profile body 20 at the inlet end and at the outlet end. Both the inlet-side wall 32 and the outlet-side wall 29 have recesses on their underside, ie the surface facing the interior of the housing, which serve as attachment paragraphs 37 and 38 for the evaporation tube 19. In the assembled state, the evaporation tube 19 is located at the respective end of the attachment paragraph 37 and 38 and is set both in the mounting direction M and perpendicular to the mounting direction M.

The inlet opening 6 at the upstream end of the evaporation tube 19 is connected to the liquid channel 13, which is formed by the inlet port 33 of the inlet side wall 32.

The inlet nozzle 33 forms substantially a 90 ° angle or arc and has a water inlet opening 14 through which condensate enters the liquid channel 13 at a rising level of condensation water. The liquid channel 13 is limited in the transition region to the evaporation tube 19 by a weir portion 41 of the inlet-side wall 32. The weir crown 18 of this weir section 41 lies in the direction of gravity above the water inlet opening 14.

In principle, the inlet zone of the continuous evaporator 1 of this embodiment thus essentially corresponds to the inlet zone of the continuous evaporator 1 of FIG Fig. 2 ,

Unlike the execution of the Fig. 2 the weir section 41 of FIG Fig. 3 but no step up. A narrowing of the inlet opening 6 is achieved in that the weir section 41 is pulled up in a straight line and extends to at least the central axis of the evaporation tube 1. In this way, it is ensured that a liquid film 9 (not shown) in the evaporation tube 19 can only get back into the liquid channel 13 when the liquid film 9 fills at least half the evaporation tube 19

The outlet-side end of the evaporation tube 19 with the steam outlet opening 8 abuts the outlet-side wall 29 in an analogous manner. In contrast to the inlet zone with the cross-section narrowing and water-accumulating weir region 41, however, the vapor tube 30 of the outlet-side wall 29 is connected to the evaporation tube 19 in a fluid-tight manner over almost the entire cross section of the vapor outlet opening 8. The cross-sectional area of the steam pipe 30 is greater than the cross-sectional area of the liquid channel 13, which promotes removal of the generated steam via the steam pipe 30.

In order to seal the connection point between the evaporation tube 19 and the attachment section 37 or 38 of the walls 32 and 29, at least one sealing element (in FIG Fig. 4 not shown), for example, a flat gasket between mounting shoulder 37 and 38 and the wall of the evaporation tube 19 may be arranged. A radial sealing of the evaporation tube 19 against the walls 32 and 29 is also possible.

Finally, the steam pipe 30 has a splash water area 39, in which the pipe cross-section is widened. In this way it is prevented that the water can escape from the steam pipe 30 into the environment.

The connection between the inlet-side wall 32 as a lid and the housing body 27 can be done in a simple manner by welding. Such a fluid connection, for example ultrasonic welding, has the advantage that it is possible to dispense with sealing means at the connection point. Alternatively, however, a screwing or gluing is possible.

Claims (23)

1. A flow evaporator (1) for discharging a liquid (2) that has collected, for example a condensate, comprising an evaporation chamber (5) that has an inlet opening (6), an evaporation base (7) which, in the fitted state of the flow evaporator (1), delimits the evaporation chamber (5) substantially in the direction of the force of gravity (g), a steam outlet opening (8), and a liquid channel (13) that extends from the inlet opening (6) to a water inlet opening (14) located outside of the evaporation chamber (5) and which forms a steam seal (15) by it having a seal cross-section (12) located entirely beneath the inlet opening (6) in the direction of the force of gravity (g), characterised in that a heating element (10) is connected to the evaporation chamber such as to conduct heat and is disposed above or beneath the evaporation chamber (5) or is wound around the evaporation chamber (5).
2. The flow evaporator (1) according to Claim 1, characterised in that the heating element (10) is located above or beneath the evaporation chamber (5) in the direction of the force of gravity (g).
3. The flow evaporator (1) according to Claim 1 or 2, characterised in that the water inlet opening (14) is located beneath the inlet opening (6) in the direction of the force of gravity (g).
4. The flow evaporator (1) according to any of the claims specified above, characterised in that the evaporation base (7) is located beneath the inlet opening (6) in the direction of the force of gravity (g).
5. The flow evaporator (1) according to any of the claims specified above, characterised in that the liquid channel (13) has a weir region (41) that delimits the evaporation chamber in part in the direction of the force of gravity (g).
6. The flow evaporator (1) according to any of the claims specified above, characterised in that an overflow weir (16) is located in the liquid channel (13).
7. The flow evaporator (1) according to any of the claims specified above, characterised in that the liquid channel (13) projects at least in part from the evaporation base (7) into the evaporation chamber.
8. The flow evaporator (1) according to any of the claims specified above, characterised in that the cross-section of the liquid channel (13) tapers in the region of the inlet opening (6).
9. The flow evaporator (1) according to any of the claims specified above, characterised in that a hollow body (19, 22), preferably an evaporation tube (19), forms the evaporation chamber (5).
10. The flow evaporator (1) according to any of the claims specified above, characterised in that a channel-shaped heat sink (22) through which fluid can flow and which is connected to the heating element (10) at least partially encompasses the evaporation chamber (5).
11. The flow evaporator (1) according to Claim 10, characterised in that the heat sink (22) forms the evaporation chamber (5).
12. The flow evaporator (1) according to Claim 10 or 11, characterised in that a profile body (20) forms the heat sink (22) and has an additional cavity (24) separated from the heat sink in which the heating element (10) is located.
13. The flow evaporator (1) according to any of the claims specified above, characterised in that the heating element (10) forms at least in part the evaporation chamber (5).
14. The flow evaporator (1) according to any of the claims specified above, characterised in that the heating element (10) has at least one PTC element.
15. The flow evaporator (1) according to any of the claims specified above, characterised in that an inlet nozzle (33), that is connected in a fluidtight manner to the inlet opening (6), forms the liquid channel (13).
16. The flow evaporator (1) according to any of the claims specified above, characterised in that a steam pipe (30) is connected to the steam outlet opening (8).
17. The flow evaporator (1) according to Claim 16, characterised in that the cross-sectional area of the steam pipe (30) is larger than the cross-sectional area of the liquid channel (13) in the region of the inlet opening (6).
18. The flow evaporator (1) according to Claim 16 or 17, characterised in that the steam pipe (30) has in part a splash water protection region (39) with a pipe cross-section that is extended in comparison to the steam pipe (30).
19. The flow evaporator (1) according to any of the claims specified above, characterised in that the flow evaporator (1) is at least partially surrounded by a housing (21).
20. The flow evaporator (1) according to Claim 19, characterised in that the housing (21) has four supporting feet (40).
21. The flow evaporator (1) according to Claim 19 or 20, characterised in that the steam pipe (3) and/or the liquid channel (13) are made as parts of the housing (21).
22. The flow evaporator (1) according to Claim 21, characterised in that the housing (21) has a wall (32) on the inlet side with the liquid channel (13) and a wall (29) on the outlet side with the steam pipe (30).
23. The flow evaporator (1) according to any Claims 19 to 22, characterised in that the wall (32) on the inlet side or the wall (29) on the outlet side has a cable outfeed opening (34) that is provided with a drip off means (35).

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