DE4407363A1 - Remote heating system for returning condensate to heating station - Google Patents

Abstract

The steam main (010) supplies a heating station (1) with steam, through a branch pipeline (7) containing a pressure reducer (9), and with condensate, through a second branch line (8) containing a separator (11) and a non-return valve (12). The steam and condensate are combined in a mixer (6), e.g. a spray mixer, immediately prior to passing through the heat exchanger (5). It is then returned to the steam generator via a second condensate line (23) having a pump (27) to increase pressure when needed. The steam pressure at the steam inlet (13) to the mixer is equal to or less than the condensate pressure at the condensate inlet (14). The steam main can optionally feed an intermediate vessel from which separate steam and condensate lines feed the mixer.

Description

To transport heat over more or less large District heating systems are known that use a steam Have generator, he pressurized steam testifies. At least one is usually good at the steam generator insulated steam pipe connected to the steam leads to at least one heat consumer. The heat ver is also via a condensate return line device connected to the steam generator. In the heat consumption The steam becomes more vigorous, giving up its heat condensed. The resulting condensate becomes the steam via the condensate return line producer traced so that it contained in the system ne water as steam and as condensate in the circuit is.

In addition to the con condensation, but falls in the steam line by never completely avoidable Heat loss on additional condensate, the so-called tes drainage condensate must be removed.  

DE 41 25 170 A1 describes a steam-heat transfer state tion known, both on a remote steam line a steam-carrying branch line as well as a condensate leading branch line are connected. To the Steam-carrying branch line is in the condensate build-up working heat consumer connected, the condensate connected to a condensate return line is. There are between the condensate outlet Heat exchanger and the condensate return line two remote controlled Ven tile and a condenser arranged between the valves sat pump provided. The heat exchanger is used in one Hot water network as a heat source and is connected to the hot water network connected with a supply and a return line sen. In the relatively cold water leading return line device, a heat exchanger is provided, which has an on finally the drainage removed from the remote steam pipe tion condensate is supplied and with another Connection connected to the suction side of the condensate pump is. Accordingly, these become both those in the heat exchanger accumulating condensate as well as the remote steam drainage condensate fed, both in the condensate back management feeds.

To use the contained in the drainage condensate Thermal energy is the additional one in the return line device of the heat exchanger Lich.

Also from DE 41 25 170 A1 already mentioned above a steam heat transfer station is known in which a steam heat exchanger working in the condensate accumulation at the beginning to a remote steam line and on the output side a condensate pump to a condensate return line connected. The resulting in the remote steam line Drainage condensate is connected to the remote steam line Branch line taken with an injection cooler connected is. The desuperheater lies in the steam  Connect the heat exchanger to the condensate return line end of the condensate line and is of that in the steam heat exchanger resulting condensate lower temperature flowed through. In the desuperheater, that becomes Remote steam pipe coming relatively hot drainage con densat from the cold coming in from the heat exchanger cooled condensate so that the mixture with a the condensate pump does not reach too high a temperature and from this into the condensate return line is fed.

The drainage con taken from the remote steam line densat heats the incoming from the steam heat exchanger Condensate. Especially when in the heat of steam exchanger only little energy should be implemented and thus the inflow of chilled condensate to the injection is cooler, the temperature increase can be considerable be. This temperature increase can be a strong problem stress on the following system parts ha ben, which is why it is necessary to add a condensate pump use the condensate with a high temperature without Can claim damage. In addition, the in the Remote steam line drainage condensate contained heat energy not used.

It is known from practice that remote steam drainage condensate in a ventilated, i.e. open condensate to collect the mel container. For returning the remote steam drainage condensate in the condensate return a pump is provided on the suction side to the Condensate collection container and on the pressure side to the condensate return line is connected. The pump is over a level switch provided on the condensate tank controlled.

The condensate collector and the pump mean one installation work not to be neglected. In the the heat contained in the drainage condensate  not used. It can also happen that a large Part of the hot, only in the atmospheric pressure standing condensate collection tank discharged se condensate. This way is going on all the time Water lost from the district heating system, who adds that must. Dissolved gases and salts are released into the distance heating system, introduced. The remote steam drainage con densat can also contain gases in the condensate collector detach from the air and drag it into the steam system pen.

In addition, it is known for systems in which the Back pressure is less than the vapor pressure that Remote steam drainage condensate via a condensate drain ter directly into the condensate return line sen.

This system also contains this in the condensate ne heat not used. In addition, the hot remote steam drainage condensate in the condensate return line Cause steam strikes. Finally, you can opt for the Customer billing errors arise when paying energy used according to the amount of condensate discharged is calculated.

Based on this, it is an object of the invention, a Steam heat transfer station to provide a good energy gi exploitation with low investment costs. It is also an object of the invention to provide a method for the return of steam line drainage condensate to indicate the good use of energy by steam enables that generated in a steam generator and over a steam line to a steam heat transfer station is listed.

The focus is on creating a steam-heat transfer state tion related part of the above task is by  a steam heat transfer station with the characteristics of Pa claim 1 solved.

The steam pipe, will be at the steam heat transfer sta tion both steam, which serves as the actual heat transfer medium, as well as drainage condensate taken in the Steam line is incurred and to avoid loading drive disorders must be dissipated. During the extraction mene steam in the branch line via a pressure reducer valve is led to the mixing device, that gets Drainage condensate bypassing the pressure reducer valve directly to the mixer without major pressure loss direction. In the mixing device, the drainage condensate added to the steam again. The mixing device device is arranged in front of the heat exchanger, so that this with the mixture formed in the mixing device is supplied from drainage condensate and steam.

In the heat exchanger is thus both in the steam containing heat as well as that in the drainage condensate sat contained heat used. Thus, be considerable amounts of heat contained in the drainage condensate Use fed. The use is made possible without that additional heat exchangers were required, as in the prior art is the case.

During the good heat utilization of the steam heat transfer station by operating the condensate heat costs are reduced by the simple construction of the steam Heat transfer station, especially due to the lack of it additional heat exchanger, the investment costs low held.

In addition, the temperature of the steam heat Transfer station condensate released relatively low. The originally very hot taken from the steam pipe Drainage condensate is run through together with the steam led the heat exchanger, taking much of its heat  delivers. A cool down at the outlet of the heat exchanger Condensate discharged into the condensate return line is fed. In contrast to solutions, at which the hot drainage condensate directly into the con the return line is fed in, remains Condensate temperature is consistently low here. Even if relatively much drainage condensate from the steam line is removed, the temperature of the condensate rises return condensate to be fed an adjustable limit. Therefore one can feed the largely cooled condensate into the con a pump can be used is designed for only low operating temperatures. In contrast to pumps that can withstand higher temperatures and have to be able to process, only result from pumps designed for low temperatures hardly seal problems or other technical difficulties. The for condensate with only lower temperatures put pumps are considerably cheaper, what the investment costs when installing the steam heat transfer station noticeably lowers.

Finally, due to the low condensate temperature Reliable steam hammer in the condensate return line avoided.

The steam line and the mixing device can be in one be arranged at different heights. Because the branch steam line and the drainage condensate line What water / steam (drainage condensate) can develop the difference in height result in a pressure difference. In addition to the This static pressure difference can be another Difference in pressure due to different flow resistances in the branch line and the drainage condensate result. If the pressure reducing valve doing so is dimensioned and adjusted so that in the branch tion prevail at the steam connection of the mixing device The pressure is at most as great as that in the drainage  Rungskondensatleitung prevailing at the mixing device Pressure, it is ensured that the drainage condensate reliably in the mixing device and via this in the Heat exchanger is introduced without steam in the Ent water condensate line could penetrate.

To avoid the drainage condensate uncontrolled steam into the mixing device and there ultimately also penetrate into the heat exchanger can, a Kon in the drainage condensate line steam trap can be provided. This blocks the drainage as soon as there is no drainage con densat is fed into this. However, it is sufficient Drainage condensate present, it gives the drainage rungskondensatleitung free, so that the drainage con densat can flow freely to the mixing device. Of the Steam traps can drain from the resulting condensate to be controlled automatically.

To prevent steam from entering the mixer facility in the drainage condensate line can be in the same a backflow preventer can be arranged. This is advantageous between the steam trap and the Mixing device provided. This prevents the Steam traps through the drainage condensate line returning steam would be misdirected.

For hydraulic balancing of the drainage line is between the steam trap and the mixer device provided a throttle valve.

If the drainage condensate line essentially is arranged horizontally, needs the pressure reduction Ornamental valve in the branch line is only a small one Bring about pressure difference. The drainage increases condensate line on the other hand, is overwhelmed by the height difference the pressure at the end of the drainage condensate line lower, which is why in the branch line  device from the pressure reducing valve a correspondingly low pressure must be set. Performs the drainage condensate line, however, over long distances with large Downward slope so that the resulting pressure under the vapor pressure of the relatively hot drainage con densats falls, it can lead to vapor bubbles and thus to Steam blows come in the drainage condensate line. Due to the horizontal arrangement of the drainage condensers This is avoided by using a cable. It may be enough if the between the steam trap and the mixer section of the drainage condensate tion is arranged horizontally.

Although it is easily possible to use the drainage con the condensate and the steam can be taken separately from the steam line men, for example by the branch line and Ent water condensate line separately at different Points of the steam line are connected, it is advantageous if the drainage condensate line on a connection device provided in the branch line device is connected, it via the branch line is connected to the steam line. The between the Connection device and the steam line located Ab cut of the branch line carries both steam and Drainage condensate in the connection device. In this separates the steam from the drainage con densat, so that in the other sections of the branch essentially only steam and drainage condensation line only drainage condensate be performed. The connection device can in simple a collection connected to the steam line be vessel from which the branch line and the drainage Guide condensate line away.

To ensure that both steam and drainage tion condensate introduced into the connecting device should lead to the connection device Supply line in a lower, lower area of the  Steam line must be connected. It is advantageous if the section leading to the connecting device the branch line from the steam line to the collecting vessel downward slope. This will start in the steam line falling drainage condensate reliably from the Steam line removed, even if only relatively little Steam is removed and the flow rate of the the same should not be too big.

In addition, if the between the connecting device tion and the pressure reducing valve lying section of the Branch line from the connection device to the Pressure reducing valve rises, can in the branch line dewatering condensate formed against the flow direction of the steam in the connecting device run back.

The one between the mixing device and the pressure reducer valve-located section of the branch line can be from the Pressure reducing valve towards the mixing device exhibit. The mixing device, which is preferred because of the horizontal training of the drainage condensate tion approximately at the same level with the connecting device lies, can thus easily on the branch line getting closed. The pressure reducing valve is applied the highest point of the branch line. Yourself between that Pressure reducing valve and the mixing device in the Ab branch line possibly forming in small quantities Condensate is fed to the mixing device and without further processed.

The mixing device can in a simple manner as a be spray cooler. This enables the Mi dewatering condensate and steam without dehumidification standing of steam strikes or the like. This mixing For example, furnishings can be placed directly on the entrance flange of the heat exchanger to be placed, causing results in a particularly compact design of the system.  

The heat exchanger uses the heat contained in the steam by condensation of the steam. The heat exchanger can be a regulated in its power consumption by accumulation of condensate ter heat exchanger. This is depending on the current lei decrease between 0 and 100% filled with condensate, so that further ent fed through the mixing device water condensate not the operation of the heat exchanger impaired.

If only in the condensate return line there is low pressure, that can be on the heat exchanger sufficient condensate pressure on the outlet side for Return. However, if in the condensate return a relatively high pressure, it is advantageous if the heat exchanger on the output side a condensate pump to the condensate return line connected. The condensate pump can be from one Bypass line be bridged into which a backflow prev which is switched on, the condensate being pushed back from the condensate return line into the heat exchanger prohibits.

To cause the condensate to rise too far above the heat exchanger and the mixing device and in particular to avoid flooding the branch line with condensate, can be in the branch line between the pressure reducing valve til and the mixing device a level monitor is provided be that gives a signal when the maximum condensate height is reached. This signal can be from a tax direction evaluated for a lowering of the Kon densatpegels ensures.

A burst of steam from the steam line into the Condensate return line is closed under all circumstances avoid. This can be done on the condensate side of the heat exchanger a temperature monitor or a temperature sensor is provided be the signa an excessive rise in temperature  lized and reliable striking through this related control prevented.

The one on a process for recycling drainage condensate directed part of the task is by a ver drive with the features of claim 26 solved. According to the steam pipe process is both steam and also drainage condensate removed. Because of that Relaxing the steam will cause a pressure difference leads so that the steam and the drainage condensate a mixing device with different pressures can be led. The steam did a little bit lower or at most the same pressure as dewatering condensation. A mixture is in the mixing device formed from drainage condensate and steam, which as Heating medium is supplied to the heat consumer. By doing Heat consumers are therefore both drainage condensate and steam are used for heating.

The energy balance is particularly favorable if one Cooling of the drainage condensate before the mixer tion is avoided, so that this with almost its ge entire heat content of the mixing device and thus last is finally also supplied to the heat consumer.

In the drawing is an embodiment of the invention shown. Show it:

Fig. 1 district heating system with a steam heat transfer station, in a highly schematic, from sectional and simplified representation and

Fig. 2 shows the district heating system of FIG. 1 in a schematic, highly simplified representation, in which the pipe routing at the steam heat transfer station is indicated.

In Fig. 1 a section of a district heating system is shown, in which steam is supplied as a heat transfer medium to a heat transfer station 1 . This is connected on the outlet side to a steam line 010 and on the outlet side to a condensate return line 012 , which comes from or leads to the steam generator.

The steam line 010 is a thermally largely insulated remote steam line, via which steam is brought in from the further away steam generator and which supplies the heat transfer station 1 with steam, further heat transfer stations not shown in FIG. 1 being provided. The condensate return line 012 is a collecting line which returns the condensate accumulating in the heat transfer stations to the steam generator.

The heat transfer station 1 has a heat exchanger 5 , which is the interface between the device formed by the steam line 010 and the condensate return line 012 th steam network and a hot water network, not shown. The heat exchanger 5 is connected eingangssei tig with a mixing device 6, and a dehydration condensation pipe 8 is connected to the steam line 010 via a branch line 7, wherein branch line in the From 7 a pressure reducing valve 9 is located.

In the drainage condensate line 8 , a manually operated shut-off valve 10 , a steam trap 11 and a backflow preventer 12 are provided. The backflow preventer 12 is located between the condensate drain 11 and the mixing device 6 .

The fed from the branch line 7 and the drainage condensate satleitung 8 mixing device 6 is an injection cooler with a steam connection 13 to which the branch line 7 is located and a water connection 14 to which the drainage condensate line 8 is connected. The mixing device 6 formed by the injection cooler allows steam introduced via the branch line to be introduced into the dewatering condensate without steam strikes or the like being expected.

The connected to the mixing device 6 heat exchanger 5 is a heat insulation 16 having hot water container 17 , from which several vertical steam heating coils 18 are added, which are operated and regulated with condensate accumulation. The steam heating coils 18 lie on a common, on the top of the warm water tank 17 arranged input flange 20 on which the mixing device 6 is placed. On the output side, ie at their respective lower ends, the steam heating coils 18 are contained in a condensate base 21 which divides a condensate chamber in the hot water tank 17 , which is connected via an output flange 22 to a condensate line 23 leading to the condensate return line 012 .

The steam heating coils 18 are in contact with the circulating water in the hot water circuit, which is fed to the hot water tank 17 in its lower region via a hot water return flange 24 and via a hot water supply flange 35 provided in its upper region is removed from this.

In the above-mentioned condensate line 23 , an electrically operated condensate pump 27 is provided which overcomes any pressure drop between the condensate discharged from the heat exchanger 5 and the condensate collected in the condensate return line 012 .

The condensate pump 27 is bridged by a one Rückflußverhin those 28 having bypass line 29 so that the accumulating in the heat exchanger 5 condensate flow around the elec tric condensate pump 27 and can deal with it, if it has by itself a sufficient pressure. In addition, a valve 30 with flow characteristic setting is provided in the bypass line 29 .

In addition, in the condensate line 23 between the condensate pump 27 and the outlet flange 22, a manual shut-off valve 31 and a valve 32 with a flow characteristic line setting in series. In order to monitor the temperature of the condensate flowing from the heat exchanger 5, a temperature sensor 33 is provided in the vicinity of the outlet flange 22 in the condensate line 23 . This emits a temperature signal, which is evaluated by a control device not shown.

On the pressure side of the condensate pump 27 in the condensate line 23 are also two mutually parallel switched engine shut-off valves 35 and in series with a backflow preventer 36 and a valve 37 with a flow characteristic line setting.

In addition to the temperature sensor 33 provided in the outlet flange 22 of the heat exchanger 5 in the condensate line 23 , a level monitor 38 is provided for monitoring the operation of the heat transfer station 1 , which is provided in the branch line 7 in the mixing device 6 . The level monitor 38 emits a signal as soon as the condensate has reached a certain level and penetrates too far into the branch line 7 . This signal is fed to the control device, which causes a corresponding setting of the engine shut-off valves 35 in connection with a specific switching on and off of the condensate pump 27 .

The spatial arrangement of the branch line 7 and the drainage condensate line 8 results from FIG. 2. The branch line 7 taps the steam line 010 into a lower section 40 , which is located so low that drainage condensate located in the steam line 010 into the branch line 7 can flow in. The Abzweiglei device 7 leads as both steam and drainage condensate supply line 41 with a slope to a collecting vessel 42nd

The collecting vessel 42 is a substantially cylindrical closed container, from whose bottom 43 the drainage condensate line 8 branches off. The drainage condensate 8 leads from the bottom 43 via the condensate drain 11 substantially horizontally to the mixing device 6th The branch pipe 7 is connected to the collection vessel 42 in the region of its wall, while serving as the lead 41 portion of the branch line to drop to the collection vessel 42 7, the vessel by the collection 42 leading away part of the branch line rises reducing valve to the pressure 9 out of. The pressure reducing valve 9 is located at the highest point of the branch line 7 , which drops relatively steeply starting from the pressure reducing valve 9 to the mixing device 6 . At least in its last section, the branch line 7 leads almost vertically to the mixing device 6 . The level monitor 38 is also arranged in this vertical section.

The heat transfer station 1 described so far functions as follows:
In normal operation, both drainage condensate and steam flows into the collecting container 42 via the feed line 41 . The entrained drainage condensate collects in the collecting vessel 42 in the lower region and flows into the condensate drain 11 via the drainage condensate line 8 . This lets the condensate through the drainage condensate line 8 to the mixing device 6 essentially with the pressure prevailing in the steam line 010 .

The steam separated from the drainage condensate in the collecting vessel 42 flows over the section of the branch line 7 which rises up to the pressure reducing valve 9 , condensate forming in this line section flowing back through the gradient of the branch line 7 to the collecting vessel 42 . The steam flows through the pressure reducing valve 9 , on the output side of which it comes out with a pressure which is significantly lower than the pressure prevailing in the steam line 010 . From the pressure reducing valve 9 , the steam passes through the further section from the branch line 7 to the mixing device 6 , in which it is mixed with the drainage condensate. The mixture of steam and drainage condensate flows into the steam coils 18 , which are cooled by the water flowing in the hot water tank 17 . The steam which has flowed in condenses in the steam heating coils 18 , with both the condensate formed as a result and the dewatering condensate introduced being cooled further. In the condensate bottom 21 , the condensate is cooled to such an extent that it has emitted the vast majority of the contained heat energy to the water held in the hot water tank 17 . The cooled condensate is fed into the condensate return line 012 via the condensate line 23 , the pressure increase required for feeding being effected by the electric condensate pump 27 .

Even if no heat energy is to be emitted from the heat transfer station 1 , the drainage condensate is reliably removed. In this case, the steam heating coils 18 are completely flooded with condensate, so that the condensate is up into the mixing device 6 . Dewatering condensate arriving from the steam line 010 flows via the feed line 010 into the collecting container 42 and from there to the condensate drain 11 . This allows the dewatering condensate to flow via the dewatering condensate 8 into the mixing device 6 at high pressure, so that the condensate level rises there continuously. When the drainage condensate in the branch line 7 begins to rise and the level monitor 38 it reaches, it emits a signal which causes the control device to switch on the condensate pump 27 and to open the engine shut-off valves 35 for a short time. However, steam is introduced into the heat exchanger 5 neither via the branch line 7 nor via the drainage condensate line 8 . Thus, when the heat transfer station 1 is stopped, drainage condensate is discharged and fed back into the condensate return line 012 , but the steam heating coils 18 are never subjected to steam. Overheating of the same is thus reliably ruled out.

Claims (27)

1. district heating system for supplying steam generated by a steam generator to at least one heat consumer station ( 1 ),
with a steam line ( 010 ) connected to the steam generator for leading the steam from the steam generator to the heat consumer station ( 1 ),
with a steam-carrying branch line ( 7 ) connected to the steam supply line, for connecting the heat consumer station ( 1 ) to the steam line ( 010 )
with a pressure reducing valve ( 9 ) provided in the branch line ( 7 ), for at least partially relieving the steam,
with a condensate-carrying drainage condensate line ( 8 ) which is connected to the steam line ( 010 ), wherein it is at least temporarily fed with drainage condensate,
with a three connections ( 13 , 14 ) having a mixing device ( 6 ), the first connection ( 13 ) of which is connected to the steam-carrying branch line ( 7 ), the second connection ( 14 ) of which is connected to the drainage condensate line ( 8 ) and the third connection of which to a heat consumer ( 5 ) is connected,
the heat consumer ( 5 ) is connected on the input side to the mixing device ( 6 ) and on the output side to a condensate return line ( 012 ). 2. District heating system according to claim 1, characterized in that the pressure reducing valve ( 9 ) is dimensioned and adjusted such that the prevailing pressure in the branch line ( 7 ) at the steam connection ( 13 ) of the mixing device ( 6 ) is as large as the pressure prevailing in the drainage condensate line ( 8 ) at the mixing device ( 6 ). 3. District heating system according to claim 1, characterized in that the pressure reducing valve ( 9 ) is dimensioned and set such that the pressure prevailing in the branch line ( 7 ) at the steam connection ( 13 ) of the mixing device ( 6 ) is lower than that in the pressure of the drainage condensate line ( 8 ) at the mixing device ( 6 ). 4. District heating system according to claim 1, characterized in that a condensate drain ( 11 ) is provided in the drainage condensate line ( 8 ). 5. District heating system according to claim 4, characterized in that the steam trap ( 11 ) is automatically controlled by the accumulation of the drainage condensate. 6. District heating system according to claim 1, characterized in that a non-return valve ( 12 ) is provided in the drainage condensate line ( 8 ). 7. District heating system according to claim 6, characterized in that the backflow preventer ( 12 ) between the condensate drain ( 11 ) and the mixing device ( 6 ) is provided. 8. District heating system according to claim 1, characterized in that the drainage condensate line ( 8 ) is arranged horizontally or with a falling or rising component. 9. District heating system according to claim 5, characterized in that between the condensate drain ( 11 ) and the mixing device ( 6 ) located section of Ent drainage condensate line ( 8 ) is arranged horizontally. 10. District heating system according to claim 1, characterized in that the drainage condensate line ( 8 ) to an in the branch line ( 7 ) provided connec tion device ( 42 ) is connected. 11. District heating system according to claim 10, characterized in that the connecting device ( 42 ) a collecting vessel ( 42 ) with a to the steam line ( 010 ) connected supply line ( 41 ), at least one to the pressure reducing valve ( 9 ) leading steam outlet connection and a condensate outlet connection. 12. District heating system according to claim 11, characterized in that the drainage condensate line ( 8 ) is connected to the condensate output connection of the collecting vessel ( 42 ). 13. District heating system according to claim 10, characterized in that the section ( 7 ) leading to the connecting device ( 42 ) of the branch ( 7 ) is connected in a lower, lower-lying area of the steam line ( 010 ). 14. District heating system according to claim 10, characterized in that the section of the branch line ( 7 ) leading to the connecting device ( 42 ) from the steam line ( 010 ) to the connecting device ( 42 ) has a gradient. 15. District heating system according to claim 10, characterized in that between the Verbindungsein direction ( 42 ) and the pressure reducing valve ( 9 ) lying de section of the branch line ( 7 ) from the connec tion device ( 42 ) to the pressure reducing valve ( 9 ) rises. 16. District heating system according to claim 1, characterized in that between the mixing device ( 6 ) and the pressure reducing valve ( 9 ) lying section of the branch line ( 7 ) from the pressure reducing valve ( 9 ) to the mixing device ( 6 ) has a gradient. 17. District heating system according to claim 1, characterized in that the mixing device ( 6 ) is an injection cooler. 18. District heating system according to claim 1, characterized in that the mixing device ( 6 ) is placed directly on the heat exchanger ( 5 ) on its input flange ( 20 ). 19. District heating system according to claim 1, characterized in that the heat consumer station ( 1 ) is a heat transfer station ( 1 ). 20. District heating system according to claim 1, characterized in that the heat exchanger ( 5 ) is a heat exchanger operated in the condensate accumulation ( 5 ). 21. District heating system according to claim 1, characterized in that the heat exchanger ( 5 ) is a condensate jam in its power consumption regulated heat exchanger shear ( 5 ). 22. District heating system according to claim 1, characterized in that the heat exchanger ( 5 ) is connected on the output side via a condensate pump ( 17 ) to the condensate return line ( 012 ). 23. District heating system according to claim 22, characterized in that the condensate pump ( 27 ) is bridged by a bypass line ( 29 ) into which a backflow preventer ( 28 ) is connected. 24. District heating system according to claim 1, characterized in that in the branch line ( 7 ) between the pressure reducing valve ( 9 ) and the mixing device ( 6 ) a level monitor ( 38 ) is provided which emits a signal when a maximum condensate level he is enough. 25. District heating system according to claim 1, characterized in that a temperature sensor ( 33 ) is provided on the condensate side of the heat exchanger ( 5 ). 26. A method for returning drainage condensate into a channel arranged between a steam line and a condensate return line, which has at least one heat consumer, the method
Both the drainage condensate and the steam intended for the heat consumer are removed at the same point with the same pressure,
the drainage condensate is separated from the steam,
the steam is partially released,
the dewatering condensate is mixed with the partially relaxed steam and whereby
the mixture of the drainage condensate and the partially relaxed steam is fed to the heat consumer. 27. The method according to claim 26, characterized in that that the drainage condensate separated from the steam sat the mixing device without significant heat lust is fed.