EP2721212A1 - Method and system for recovering heat in a drying section of a machine for producing a material web - Google Patents

Abstract

The invention relates to a method for recovering heat in a drying section (2) of a machine for producing a material web, in which drying section the material web is dried at least by a heatable drying cylinder (TZ) and by hot air by means of at least one high-temperature drying element (3), an exhaust air flow (LA) being produced thereby. At least part of the waste heat of the exhaust air flow (LA) is fed to an evaporation system (4) arranged in the exhaust air flow (LA) of the high-temperature drying element (3) by means of at least one heat exchanger (W1) in order to generate steam (D) for at least one steam consumer (V). The invention is characterized in that processed feed water or fresh water is used as a starting fluid (AM) for generating steam (D), said water being heated by means of waste heat from the exhaust air flow (LA) and fed into the evaporation system (4) and, in the evaporation system, either being at least partially evaporated such as to produce a mixture of steam and condensate (DKW1), preferably completely evaporated such as to produce steam (D) at the at least one heat exchanger (W1), or being heated in the heat exchanger (W1) and depressurized after exiting the heat exchanger (W1).

Description

 Method and system for heat recovery in a dryer section of a machine for producing a material web

The invention relates to a method for heat recovery in a dryer section of a machine for producing a material web, in particular a fibrous web in the form of a paper, board or tissue web, in which the material web at least with a heated drying cylinder and by means of at least one high-temperature drying element with hot air under Accumulation of an exhaust air stream is dried; wherein at least a portion of the waste heat of the exhaust air stream is supplied to a arranged in the exhaust air stream of the high-temperature drying element evaporation system for generating steam for at least one steam consumer via at least one heat exchanger. The invention further relates to a system for heat recovery for a dryer section of a machine for producing a material web, in particular a paper, board or tissue web.

Drying sections comprising at least one drying cylinder which can be heated by steam and at least one high-temperature drying element which is designed and arranged to at least indirectly apply hot air to the fibrous web are previously known from the prior art in different embodiments. The steam / condensate mixture produced by steam in the drying cylinder is fed to at least one condensate separator, the steam from the condensate separator being fed to the live steam or a live steam or high pressure steam mixture and at least a portion of the condensate from the condensate separator downstream of at least one drying cylinder to a heat exchanger is supplied in the exhaust air stream of the high-temperature drying element. The Condensate is heated in this case and absorbs the energy of the exhaust air. Such a method or such a device is known for example from the publication AT 506 077 B1. In this a method and an apparatus for heat recovery in a dryer section of a paper machine is disclosed, wherein the paper web is dried with a steam-heated drying cylinder and a hot-air-acted high-temperature hood. The exhaust steam from the steam system is fed to a steam separator. A portion of the condensate from the steam separator is recycled in a separate circuit via a heat exchanger to the same and single steam separator and fed to the condensate through the heat exchanger heat from the exhaust air of the high-temperature drying element. This embodiment was based on the object to provide a comparison with the previous state of the art improved and easier controllable heat recovery process. The improvement was seen in the fact that the heating of the condensate in said heat exchanger does not completely lead to evaporation, since the steam or the vapor / condensate mixture is recycled to said condensate. An elaborate control of the condensate flow through the heat exchanger to account for the evaporation capacity of the heat exchanger, which in turn depends on an optionally fluctuating exhaust air temperature, can be omitted in this embodiment.

A condensate separator is understood to mean a device which is suitable for separating steam from condensate. For these other names are used, such as steam separator or separator.

The invention has for its object to improve a method and apparatus for heat recovery over the prior art, so that the offered energy of the exhaust air flow of the at least one high-temperature drying element is used thermodynamically at the highest possible level. The object of the invention is achieved by the features of claims 1 and 10. Advantageous embodiments are described in the subclaims. An inventive method for heat recovery in a dryer section of a machine for producing a material web, in particular a fibrous web in the form of a paper, board or tissue web, in which the material web at least with a heated drying cylinder and by means of at least one high-temperature drying element with hot air to attack a Exhaust air stream is dried; wherein at least a portion of the waste heat of the exhaust air stream is supplied to a arranged in the exhaust air flow of the high-temperature drying element evaporation system for generating steam for at least one steam consumer via at least one heat exchanger; is characterized in that is used as the starting fluid for the production of steam treated feedwater or fresh water, which is fed by waste heat from the exhaust air flow preheated in the evaporation system and in this either at least partially to form a mixture of steam and condensate, preferably completely under formation steam is evaporated on the at least one heat exchanger or heated in the heat exchanger and is expanded after the exit from the heat exchanger.

A steam consumer is understood to mean a device to which steam is to be supplied for operation. This can be carried out with condensate return or free of condensate return. A steam consumer free from condensate recirculation means a steam consumer to whom the steam is merely discharged, whereby the condensate accumulating in the respective application is released to the environment and is not collected. Such steam consumers are, for example, steam humidifiers which apply steam to the fibrous web in the end region of the dryer section or steam blower boxes. Under treated feed water is water, especially fresh water, river water or sea water, etc understood or a mixture of these, which has been subjected to at least one treatment process, ie at least partially desalted and / or degassed and / or descaled or a combination of these.

The advantage of the solution according to the invention is the provision of steam for at least one steam consumer, who himself must have no independent condensate return or treatment, with optimal utilization of the waste heat from the exhaust air flow of a high-temperature drying element, such as a blast hood. The provision of steam takes place with optimum utilization of the waste heat occurring in any case within the dryer section, in particular at least one exhaust air stream of a high-temperature drying element.

In order to extract as much energy as possible from the exhaust air stream, it is used in addition to heating the treated feed or fresh water before it is fed into the evaporation system. The treated feedwater or fresh water is preheated by means of waste heat from the exhaust air stream to a temperature in the range of in each case including 50 ° C to 150 ° C, preferably 80 ° C to 120 ° C.

For optimal energy utilization, the fed into the evaporation system treated feedwater or fresh water in the flow direction of the exhaust air flow thermally coupled with this after the heat engineering coupling of the evaporation system with the exhaust air stream. The leadership of the evaporation system at least indirectly via the exhaust air flow in the flow direction is thus upstream of the leadership of the feed fluid to be fed in the form of treated feedwater or fresh water. The majority of the energy can thus be used for heating or at least partial evaporation. The leadership of the treated feedwater or fresh water in the evaporation system is carried out in a first training on at least one heat exchanger in the exhaust stream under at least partial evaporation, preferably complete evaporation. Due to the evaporation in the heat exchanger, a much smaller amount of starting fluid in the form of treated feedwater or fresh water to produce the same amount of steam is required as in the known solutions. Due to the already occurring in the heat exchanger evaporation and the lower required amount of feed water a much lower pressure at the inlet for the feed water in these is required, whereby the required energy consumption for the arranged in the feed to the heat exchanger pumps can be significantly reduced. Low required pressures increase operational safety. Furthermore, investment costs can be saved, since the design of the individual components must be made only on the lower pressures to be set.

Another advantage of this solution is that expensive switching and valve arrangements for additional control of the vapor pressure level can be avoided. The solution according to the invention is thus characterized by a particularly simple structure. The number of components for control and / or regulation is limited to a minimum.

If the guidance via the at least one heat exchanger according to a second embodiment is free of evaporation, the treated feed water or fresh water fed into the evaporation system is merely heated therein. This is heated in the heat exchanger to temperatures ranging from in each case including 150 ° C to 230 ° C, preferably 190 ° C to 220 ° C and then expanded after exiting the heat exchanger. The heat exchanger is configured to be capable of generating steam from the output fluid passing thereinto by obtaining the required phase transition. The heat exchanger can be varied be executed and the construction and design of which can be done to realize the various possibilities of steam generation. Preferably, the heat of a heat-emitting mass flow is transferred via at least one surface to the fluid to be evaporated. According to a particularly advantageous embodiment of this includes a steam generator such as a steam boiler, in particular waste heat boiler. Depending on the requirements of the heat exchanger at least indirectly, ie directly or via further transmission elements downstream steam consumers steam in the form of saturated steam or superheated steam is provided.

Preferably, the vapor present at the exit from the heat exchanger and produced from the starting fluid in the form of treated feed water or fresh water or the vapor portion of a mixture of steam and condensate is at least indirectly, i. fed directly or via further transmission paths and / or the exiting the heat exchanger exiting fluid functional elements and units.

The direct supply is only possible with complete evaporation under adjustment of the required, the steam consumers to be supplied steam characterizing parameters. If a mixture of steam and condensate is generated, the steam present at the outlet from the heat exchanger and produced from the starting fluid or the mixture of steam and condensate is guided at least via a condensate separation stage. This ensures that condensate contained in the steam exiting from the heat exchanger is reliably separated.

In the connection of the output from the heat exchanger or the downstream Kondensatabscheider to the steam generator means for influencing the exiting fluid, in particular steam, for example in the form of pressure-influencing means may be provided. In the simplest case, these comprise at least one valve device. About this can Pressure level in the respective steam or a mixture of steam and condensate line leading to the specific needs of the application can be quickly and easily adjusted. In a particularly advantageous embodiment, the evaporation system can be coupled to a plurality of steam consumers, with this steam being provided for the individual steam consumers with different pressure levels. For this purpose, the steam present at the exit from the heat exchanger and produced from the starting fluid or the mixture of steam and condensate is fed to at least two or more further condensate separation stages, with the production of vapor streams of different pressure levels. As a result, steam flows for different steam consumers with different demands on the parameters of the steam to be provided in an overall system can be provided by simple means and fed to them.

Advantageously, the individual Kondensatabscheidestufen be followed for the realization of steam flows with different pressure levels in succession. However, it is also conceivable to arrange and run them in parallel, in which case the steam or the mixture of steam and condensate which is output at the heat exchanger must be distributed in a corresponding manner to the individual parallel branches.

According to a further development of an embodiment with at least one or more condensate separation stages, the condensate produced at least in the last condensate separation stage and no longer supplied to any further condensate separation stage is respectively supplied to the input for the output medium at the heat exchanger. There, this can be reheated and evaporated in a simple manner.

As separately and continuously supplied to the evaporation system fluid is according to an advantageous embodiment of water, especially fresh water used, which is continuously supplied via a fresh water supply system and is fed by utilizing heat from the exhaust air stream preheated in the evaporation system. In a particularly advantageous manner, the pressure in the flow of the output fluid at the entrance to the heat exchanger and / or in the vapor stream or the stream of a mixture of vapor and condensate after the exit from the heat exchanger and / or between the individual Kondensatabscheidestufen and / or this downstream control and / or controllable. Due to the diversity of the possibilities of influencing the individual mass flows in the evaporation system, this can meet a variety of different requirements despite the simple design with minimal effort.

The solution according to the invention, in particular with continuous supply of treated feed water or fresh water, is particularly suitable for providing steam for at least one steam consumer in the form of a steam blow unit which has no condensate return. In terms of apparatus, the system for heat recovery in a dryer section of a machine for producing a material web, in particular a fibrous web in the form of a paper, board or tissue web, comprising at least one heatable cylinder and at least one high-temperature drying element for at least indirectly loading the material web, in particular fibrous web with hot air with an associated exhaust air system, at least one evaporation system for generating steam for at least one steam consumer, which is thermally coupled via at least one arranged in the exhaust air heat exchanger with this, characterized in that the evaporation system connected to at least one supply unit for fresh water or treated feed water is, wherein the connection is thermally coupled to the exhaust system of the high-temperature drying element. Thermoelectric coupling means all possibilities of interaction between two systems to be coupled to one another, which have an influence on the heat capacity of the individual systems, such as heat transfer and heat transfer, heat storage, etc

For optimum utilization of the available via the exhaust air heat, the heat technology coupling between the exhaust and the evaporation system in the flow direction in the exhaust air system considered upstream of the heat engineering coupling the connection of the evaporation system with at least one unit for fresh water or treated feedwater. For this purpose, the starting fluid is passed before the inlet into the heat exchanger via a pre-heating device arranged in the exhaust air flow, wherein the preheating device is connected downstream of the heat exchanger in the exhaust air flow.

With regard to the generation of steam by utilizing waste heat from the exhaust air system, there are basically the following possibilities:

According to a first embodiment, the at least one heat exchanger for heat-technical coupling between the exhaust air system and the evaporation system is designed and arranged to be suitable for at least partially evaporating it in the evaporation system via this guided fresh water or treated feed water. In a particularly advantageous embodiment, the heat exchanger is designed as a waste heat or exhaust gas boiler, comprising means for generating steam from condensate by using exhaust air as the heat carrier. With regard to the advantages, reference is made to the comments on the method claim.

According to a second embodiment, the at least one heat exchanger for heat-technical coupling between the exhaust air system and the evaporation system is designed and arranged to be suitable, the only in the evaporation system via this guided fresh water or treated feed water heat. In this case, the heat exchanger downstream means for relaxing the heated fresh or treated feedwater.

In an advantageous embodiment, the output for steam or a mixture of steam and condensate at the heat exchanger at least one, preferably a plurality of parallel or series-connected Kondensatabscheidestufen, comprising at least in each case downstream of a Kondensatabscheider whose steam outlet at least indirectly coupled to at least one steam consumer is. About the Kondensatabscheidestufen steam and condensate can be separated from not yet completely evaporated condensate, the condensate can be fed to the heat exchanger again. Additional facilities for condensate treatment can be dispensed with. Furthermore, steam flows with different pressure levels can be provided.

The coupling of the Kondensatabscheidestufen with the steam consumer can, with complete evaporation directly, with only partial evaporation via at least one, preferably a plurality of parallel or in series with each other switched Kondensatabscheidestufen, comprising at least one Kondensatabscheider done. About this can be separated from not yet completely evaporated condensate steam and condensate, the condensate can be fed to the heat exchanger again. Additional facilities for condensate treatment can be dispensed with. Furthermore, steam flows with different pressure levels can be provided.

In an advantageous further development, means for influencing the streams, in particular vapor streams, are arranged between the outlet for condensate of a condensate separator and the heat exchanger and / or the outlet for steam or a mixture of steam and condensate on the heat exchanger and a condensate separator and / or a steam consumer. The individual steam flows can thus according to the requirements for different, these decreasing consumers will be provided.

Preferably, upstream of the input for output fluid at the heat exchanger and / or the outlet for steam or a mixture of steam and condensate on the heat exchanger and a condensate and / or a steam consumer means for influencing the streams, steam streams, in particular means for pressure control and / or pressure control are arranged , The individual streams, in particular vapor streams can thus be provided in accordance with the requirements for different, these decreasing consumers.

The solution according to the invention is explained below with reference to a figure. It details the following:

FIG. 1 shows a schematized, highly simplified illustration of the invention

 Basic structure and the basic function of a heat recovery system according to the invention for a steam consumer free of condensate return;

FIG. 2 shows an inventive system for heat recovery according to FIG. 1 for use for steam supply for a steam consumer in a machine for producing a tissue web. FIG. 1 shows, in a schematically greatly simplified representation, the basic structure and basic function of a heat recovery system 1 for a dryer section 2 of a machine not shown here in detail for producing a material web, in particular a fibrous web, in the form of a paper, board or tissue web. in which the generation of steam from an output fluid AM for at least one steam consumer V within the dryer section 2 or another area of the machine for producing a fibrous web via a in the exhaust air flow of a High-temperature drying element arranged evaporation system 4 takes place. In this saturated steam, ie saturated steam is generated, which can no longer absorb fluid. The drying section 2 comprises at least one drying cylinder TZ, which is wrapped at least partially by a high-temperature drying element in the form of a high-temperature hood 3, forming a distance over a partial area of its outer circumference. The high-temperature hood 3 serves at least indirectly for applying hot air to a fibrous web guided at least indirectly around the outer circumference of the drying cylinder TZ, ie, directly or on a covering. The air system for the hot air of the high-temperature hood 3, not shown here, is preferably, but not necessarily designed as a recirculation system and usually has a circulating air blower not shown here with a subsequent gas burner for heating the circulating air carried out. In this case, a large part of the circulating air, which is passed through the high-temperature hood 3, circulates directly in this recirculation system. However, since the circulating air can absorb only a finite degree of water, circulating circulating air is partially removed via an exhaust system 5 and replaced by supply air. The exhaust system 5 can be designed in various ways. This is not shown here in detail. It is crucial that at least a part, preferably the entire exhaust air LA to be discharged from the air system is guided via at least one heat exchanger W1, which is designed and designed to be suitable depending on the steam generation type, steam DW1 or at least a mixture of steam and condensate DKW1 from the output fluid AM for generating steam or at least to heat. In the former case, the heat exchanger W1 is preferably designed in the form of a steam generating device, wherein in this heat heat is transferred from the exhaust air LA to the output fluid AM under at least partial evaporation. The heat exchanger W1 is located in the exhaust air LA. The exhaust air LA is supplied via at least one input 7 to the heat exchanger W1. At the output 8 of the present after heat release to the output fluid AM for generating steam exhaust air LA ^' output. The Output fluid AM is supplied to at least one input 10 of the heat exchanger W1, heated therein and at least partially evaporated. The steam DW1 or the mixture of steam and condensate DKW1 is output at at least one output 1 1 of the heat exchanger W1.

FIG. 1 shows, by way of example, an embodiment for generating steam from a starting fluid AM continuously supplied to the process from the outside in the form of treated feedwater or fresh water which, after conversion and supply to a steam consumer V, is not only partially traceable. Such steam consumers V, in which no condensate is trappable during operation and is therefore not traceable, can be embodied, for example, in the form of a steam blow box by means of which steam D is blown directly onto a fibrous web. The evaporation system 4 is supplied as output fluid AM processed feedwater or fresh water FS for generating steam from a supply unit 6, not shown in detail, which is designed and designed to be suitable to provide fresh water FS continuously. The fresh water FS is preferably preheated before evaporation on the heat exchanger W1, wherein the preheating is preferably also carried out by utilizing the heat of a mass flow. According to a particularly advantageous embodiment, the heat of the exhaust air flow LA of the exhaust air system 5 is used for this purpose. For this purpose, the output fluid AM used for generating steam, in particular fluid in the form of fresh water FS, is conducted via a preheater in the form of a heat transfer device 9. Furthermore, the exhaust air flow LA is guided via the heat transfer device 9. The heat transfer device 9 is also arranged in the exhaust air LA of the exhaust air system 5. Preferably, the heat exchanger W1 and the heat transfer device 9 are arranged in series in the exhaust air flow, wherein according to a particularly advantageous embodiment, the arrangement of the heat exchanger W1 of the arrangement of the heat transfer device 9 is upstream, since for preheating substantially lower amounts of heat are required, as for evaporation. Also, more heat can be removed at the heat exchanger W1 of the exhaust air LA than in the area acting as a preheater heat transfer device 9. For this purpose, the exhaust air LA is first passed through the heat exchanger W1 and exits at the exit as exhaust air LA ^' , which heat was removed for evaporation from. This has a lower energy potential than the incoming at the entrance 7 of the heat exchanger W1 exhaust air LA. LA ^' emerges at least at an input 12 into the heat transfer device 9 preheating at the output 13 from this as exhaust air LA ^" , which can be discharged into the environment.

The guide of the output fluid AM via the heat transfer device 9, in particular the preheater by supplying at least one input 14 and the output of the preheated output fluid AM ^' at least one output 15th

The heat transfer device 9 is executed in the simplest case as a heat exchanger. In this regard, a variety of designs is conceivable in which the heat technically can be brought together in operative connection media in the DC, counter or cross-current to each other. The heating of the starting fluid AM takes place in dependence on the temperature of the exhaust air flow to temperatures in the range between 70 ° C and 1 10 ° C. The output fluid AM ^' output at the heat transfer device 9 and thus preheated is fed to the evaporation system 4 in the inlet to the heat exchanger W1.

As already stated, the heat exchanger W1 can be designed as a steam generator. The pressure in this can be controlled and / or regulated via a pump device P1 in front of the input 10. Preferably, at least one pump device P1 is arranged in the inlet for this, via which the pressure level of the incoming and the steam generation underlying preheated output fluid AM ^{'is set} in the heat exchanger W1. Evaporates within the heat exchanger W1 only a part of the output fluid AM ^' is formed a mixture of steam and condensate DKW1, which requires further processing until the vapor content contained in this can be supplied to the steam consumer V. For this purpose, the heat exchanger W1 at the output 1 1 at least one Kondensatabscheidestufe comprising at least one Kondensatabscheider S1 downstream. This is so integrated into the system 1 for heat recovery, that the separated condensate K1 is also supplied to the heat exchanger W1 and evaporates. For this purpose, at least one inlet 16 of the condensate separator S1 is connected to the outlet 11 for the mixture of steam and condensate DKW1 formed from the outlet fluid AM ^' when it evaporates within the heat exchanger W1. An outlet 18 for the condensate K1 is at least indirectly connected to the inlet 10 of the heat exchanger W1, here connected via the coupling of the supply line of the output fluid AM with the input 10 of the heat exchanger W1.

Due to the pressure conditions within the condensate S1, the condensate can vaporize and ascend as so-called Brüdendampf, the separated steam and the Brüdendampf then yield the steam D, which is output at the outlet 17 of the Kondensatabscheiders S1 and preferably fed directly to a steam consumer V, in particular steam blower box becomes.

Within the connection between heat exchanger W1 and condensate separator S1, in particular the inlet 16 for the mixture of steam and condensate DWK1, means 19 for influencing at least one parameter characterizing the mixture, in particular for influencing the pressure, are provided. These include at least one or a plurality of valve devices, in particular control and / or regulating valve devices.

As already stated, the heat exchanger W1 can be designed as a steam generator in a first embodiment. According to a second embodiment, this merely serves to heat free from evaporation of the starting fluid. The heated starting fluid in this case, after exiting the heat exchanger relaxes under the formation of steam, for which purpose the means 19 can be used.

The pressure in the heat exchanger W1 can be controlled and / or regulated here via a pump device P1 in front of the inlet 10. Preferably, at least one pump device P1 is arranged in the inlet to this, via which the pressure level of the incoming output fluid AM is set in the heat exchanger W1. If only part of the starting fluid evaporates, a mixture of steam and condensate is formed which requires further processing until the vapor content contained in it can be supplied to the steam consumer V or further. For this purpose, the heat exchanger W1 at the output 1 1 at least one Kondensatabscheidestufe comprising at least one Kondensatabscheider S1 downstream. This is so integrated into the system 1 for heat recovery, that the separated condensate K1 is also supplied to the heat exchanger W1 and evaporates. For this purpose, at least one input 16 of the condensate separator S1 is connected to the output 11 for the mixture of steam and condensate DKW1 formed from the starting fluid AM during evaporation within the heat exchanger W1. An outlet 18 for the condensate K1 is at least indirectly connected to the inlet 10 of the heat exchanger W1, here connected via the coupling of the supply line of the output fluid AM with the input 10 of the heat exchanger W1.

Due to the pressure conditions within the Kondensatabscheiders S1 can evaporate the condensate. The output at the output 17 of the condensate S1 steam D is supplied to the steam consumer V with the required pressure.

Within the connection between heat exchanger W1 and condensate separator S1, in particular the inlet 16 for the mixture of steam and condensate DWK1, means 19 for influencing at least one parameter characterizing the mixture, in particular for influencing the pressure, are provided. These include at least one or one Variety of valve devices, in particular control and / or regulating valve devices.

The solution according to the invention is not limited to the embodiment shown in the figure. Advantageous further developments, concerning the same inventive concept, are also included. It is crucial that the heat of an exhaust air stream, which occurs in any case in a high-temperature hood, at least partially used to generate steam in an evaporation system 4, wherein the resulting steam can be supplied to steam consumers either in the dryer section itself or other customers. According to a particularly advantageous embodiment, the steam supply for steam blow units, in particular steam blow boxes. Figure 2 shows a particularly advantageous application of a system 1 for heat recovery for use for steam supply for a steam consumer V in a machine for producing a tissue web. The basic structure and the basic function of the system 1 correspond to that described in FIG. The same reference numbers are therefore used for the same elements. The consumer V is part of a arranged between a headbox 20 and a drying cylinder TZ1 sheet forming module VAT. The pulp suspension is introduced via the headbox 20 in a gap formed between bands 21 and 23 in a former 22 in the wrap area of this with a roller 24, which is followed by a drainage area. The fibrous web is then guided with the belt 21 through the sheet forming module VAT to the drying cylinder TZ1. The endlessly circulating belt 21 is in the form of a loop and surrounds the roller 24 with its inner circumference over a partial region of its outer circumference. The band 21 further encloses with its outer periphery a portion of the outer periphery of a suctionable roller 25 of the sheet forming module VAT. The belt 21 is present as a sieve belt with embossing surface. This ensures the three-dimensional structure of the fibrous web. The endless circulating belt 23 encloses with a Part of its outer periphery a portion of the outer periphery of the roller 24. The tape 23 is present as a wire belt and is separated after a first dewatering zone in the wrapping area with the roller 24 from the belt 21. The fibrous web is then fed with the belt 21 on to a combined pressing and through-flow drying unit 26 of the sheet forming module VAT. The pressing and through-flow drying unit 26 forms a prolonged drainage area in which the fibrous web is guided in the wrapping area with the besaugbaren roller 25 between two belts, the belt 21 and another, designed as a felt belt belt 28. In the dewatering area, an air-permeable, endlessly circulating press belt 27 is provided, which presses the belts 21 and 28 against the outer circumference of the suctionable roller 25 under tension at least in a partial region of the wrap-around area of the suctionable roller 25. Within the loop formed by the press belt 27, a hood 29 is arranged, which acts on the guided between the belts 21 and 28 fibrous web with dry medium. The throughflow drying unit is a drying unit which discharges drying medium - steam or air or a mixture - through the fibrous web. For this purpose, the surface of the suctionable roller 25 is perforated, and in this or at the free surface area free from the belt area with the belts 21, 28, a suction device is provided for extracting the moisture-laden air. According to the invention, the steam generated in the evaporation system 4 is now supplied to a consumer V in the form of the hood 29. The steam is supplied to the hood 29 with the following parameters: pressure in the range of respectively 0.2 barg to 1.5 barg, preferably 0.4 barg to 0.8 barg and temperature in the range of each including 105 ° C to 135 ° C, preferably 1 10 ° C to 125 ° C.

The steam / condensate mixture K of the drying cylinder TZ is treated separately. The evaporation system provided for this purpose is either free from a coupling to the evaporation system 4 or else coupled to a condensate separator in it. In both embodiments shown in Figures 1 and 2, it is conceivable, before the input 10 at the heat exchanger W1 and / or the output 1 1 for steam or a mixture of steam and condensate DKW1 on the heat exchanger W1 and a condensate S1 and / or at least one Steam consumer V means / means for influencing the steam flows to the individual steam consumers, in particular to arrange means / devices for pressure control and / or pressure control. Furthermore, it is conceivable to expand the evaporation system 4 by further Kondensatabscheidestufen. Also conceivable is the coupling of the evaporation system 4 with a plurality of consumers, which can be supplied individually or in groups with steam as needed, the required parameters in the respective connection of the evaporation system 4 with the individual consumer V via corresponding means / devices are adjustable ,

LIST OF REFERENCE NUMBERS

1 system for heat recovery

 2 drying section

 3 high-temperature hood

 4 evaporation system

 5 exhaust air system

 6 deployment unit

 7 Exhaust air inlet at the heat exchanger

 8 Exhaust air outlet at the heat exchanger

 9 heat transfer device, preheater

 10 input output fluid at the heat exchanger

 1 1 outlet steam or mixture of steam and

 Condensate on the heat exchanger

 12 Exhaust air inlet to heat transfer device, preheater

 13 Exhaust air outlet on heat transfer device, preheater

 14 input output fluid at the

 Heat transfer device, preheater

 15 output fluid at the

 Heat transfer device, preheater

 16 input condensate separator S1

 17 Steam outlet at condensate separator S2

18 Condensate outlet on condensate separator S1

19 funds

 20 headbox

 21 band

 22 shaper

 23 band

24 roller 25 suctionable roller

 26 press unit

 27 press belt

 28 band

 29 hood

 AM output fluid

AM ^' preheated output fluid

 FS fresh water

 D, D1 steam

 DW1 steam

 DKW1 Mixture of steam and condensate

 K vapor / condensate mixture

 K1 condensate

 LA exhaust air

LA ^' exhaust air after passing through the heat exchanger

P1 pumping device

 S1 condensate separator

 TZ, TZ1 drying cylinder

Claims

claims

Method for heat recovery in a dryer section (2) of a machine for producing a material web, in particular a fibrous web in the form of a paper, board or tissue web, in which the web of material at least with a heated drying cylinder (TZ) and by means of at least one high-temperature drying element ( 3) with hot air under attack of an exhaust air stream (LA) is dried, wherein at least a portion of the waste heat of the exhaust air stream (LA) arranged in the exhaust air stream (LA) of the high-temperature drying element (3) evaporation system (4) for generating steam (D) for at least one steam consumer (V) is supplied via at least one heat exchanger (W1);

characterized,

that as the starting fluid (AM) for the production of steam (D) treated feedwater or fresh water is used, which is fed by waste heat from the exhaust air stream (LA) preheated in the evaporation system (4) and in this either at least partially to form a mixture Steam and condensate (DKW1), preferably completely vaporized with formation of steam (D) in at least one heat exchanger (W1) or heated in the heat exchanger (W1) and after the output from the heat exchanger (W1) is expanded.

Method according to claim 1,

characterized by

that the treated feedwater or fresh water before being fed into the evaporation system (4) by means of waste heat from the exhaust air stream (LA) to a temperature ranging from 50 ° C to 150 ° C, preferably 80 ° C to 120 ° C preheated. Method according to claim 1 or 2,

characterized by

in that the treated feedwater or fresh water fed into the evaporation system (4) is heated in the heat exchanger (W1) to temperatures in the range of from 150 ° C to 230 ° C, preferably 190 ° C to 220 ° C.

Method according to one of claims 1 to 3,

characterized by

that the fed-in feed water or fresh water to be fed into the evaporation system in the flow direction of the exhaust air flow (LA) is thermally coupled to the exhaust air flow (LA) after the thermo-technical coupling of the evaporation system (4).

Method according to one of claims 1 to 4,

characterized by

in that the vapor (D) present at the outlet (1 1) from the heat exchanger (W1) or the vapor portion of a mixture of steam and condensate (DKW1) or the fluid expanded after leaving the heat exchanger (W1) at least one condensate separation stage (S1) the output (17) of which for steam (D) is at least indirectly coupled to the at least one steam consumer (V).

Method according to one of claims 1 to 5,

characterized,

in that the steam (D) present at the outlet (11) from the heat exchanger (W1) or the vapor portion of a mixture of steam and condensate (DKW1) is supplied to at least two further condensate separation stages connected in series or in parallel to produce steam flows of different pressure levels, the respective output (17) this is coupled for steam (D) at least indirectly, each with a steam consumer (V).

Method according to one of claims 5 or 6,

characterized,

the condensate (K1) deposited in the individual condensate separation stages (S1) is fed to the inlet (10) of the heat exchanger (W1) for treated feedwater or fresh water.

Method according to one of claims 1 to 7,

characterized,

that the pressure in the flow of the in the evaporation system (4) out of the inlet (10) in the heat exchanger (W1) and / or in the steam flow (DW1) or mixture of steam and condensate (DKW1) to the output (1 1) from the heat exchanger (W1) is controlled and / or regulated.

Method according to one of claims 1 to 8,

characterized,

in that the steam (D) is provided for at least one steam consumer (V) from the group of steam consumers mentioned below:

- a steam box (V)

 a hood (29) of a flow-through drying unit of a sheet forming module (VAT);

 - A steam required for operation secondary consumers.

System (1) for heat recovery in a dryer section (2) of a machine for producing a material web, in particular a fibrous web in the form of a paper, board or tissue web, comprising at least one heatable cylinder (TZ) and at least one high-temperature drying element (3) for at least indirect loading of the material web, in particular fibrous web with hot air, with an associated exhaust air system (5), at least one Evaporation system (4) for generating steam (D) for at least one steam consumer (V), which is at least one in the exhaust system (5) arranged heat exchanger (W1) with this thermally coupled;

 characterized,

 in that the evaporation system (4) is connected to at least one supply unit for treated feed water or fresh water, the connection being thermally coupled to the exhaust air system (5) of the high-temperature drying element (3).

1 1. System (1) according to claim 10,

 characterized,

 that the heat engineering coupling between the exhaust air and the evaporation system (4) in the flow direction in the exhaust system (5) considered upstream of the heat engineering coupling of the connection of the evaporation system (4) with at least one supply unit for treated feed water or fresh water.

12. System (1) according to claim 10 or 1 1,

 characterized,

 in that the at least one heat exchanger (W1) for heat-technical coupling between exhaust air system (5) and evaporation system (4) is designed and arranged to be suitable for at least partially evaporating the treated feedwater or fresh water in the evaporation system (4).

13. System (1) according to claim 10 or 1 1,

 characterized,

in that the at least one heat exchanger (W1) for the heating-technical coupling between exhaust air system (5) and vaporization system (4) is designed and arranged to be suitable in the evaporation system (4) via this guided fresh water or treated feed water free of evaporation to heat and the heat exchanger (W1) means are arranged downstream of the heated fresh or treated feed water to relax.

14. System (1) according to one of claims 10 to 13,

 characterized,

 in that at least one, preferably a plurality of condensate separation stages connected in parallel or in series with each other, comprising at least one respective condensation separator (S1), the steam outlet (17) of which is at least indirectly connected to the outlet (11) at the heat exchanger (W1) Steam consumer (V) is coupled. 15. System (1) according to one of claims 10 to 14;

 characterized,

 in front of the inlet (10) for output fluid (AM) at the heat exchanger (W1) and / or the outlet (1 1) for steam (DW1) or a mixture of steam and condensate (DKW1) at the heat exchanger (W1) and a condensate separator ( S1) and / or a steam consumer (V, V1, V2,

V3) means / means for influencing the steam flows to the individual steam consumers, in particular means / devices for pressure control and / or pressure control are arranged.