DE10110024A1 - Fluid heating device using exhaust heat, e.g. refuse incinerators has adjusting device to vary exhaust gas volume passing through eat exchanger during operation - Google Patents

Abstract

The system has heat exchangers (5) to heat a fluid using waste heat. An adjusting device, e.g. swing valve and ventilator (4,7), is used to vary the exhaust gas volume passing through the heat exchanger during operation of the system. An exhaust gas tube system (2,3) permits the exhaust to escape to the atmosphere in different ways when coming from the appliance (1), which generates it. The heat exchanger is located within a section of the tube system, e.g. a by-pass, through which the exhaust may pass but is not forced to pass.

Description

The present invention relates to a device according to the Preamble of claim 1 and a method according to the Preamble of claim 21, d. H. one plant and one Process for heating a liquid by exhaust gas heat using one of the liquid to be heated flowed through and passed by the exhaust gas heat exchanger.

Such a device and such a method are in example from using the so-called calorific value known working heating systems.

In such heating systems, part of the heating the energy required for the water is obtained from the exhaust gases; the Exhaust gases are generated by a heat rope through which water flows sheared past and warm the inside Water.

Experience shows that this gives you a considerable Part of the energy contained in the exhaust gas can be used.

Nevertheless, it is rather the exception that occurs in hot exhaust gases to use held energy.

Especially with incinerators through which garbage or substances dangerous for the environment and / or humans are burned, the exhaust gases are generally unused into the Left free. Here there are obviously technical Difficulty increasing the energy contained in the exhaust gases use.

The present invention is therefore based on the object the system according to claim 1 and the method according to  Develop the preamble of claim 21 such that this also applies to systems other than heating systems, ins can also be used especially in incineration plants.

This object is achieved by the in Patentan claim 1 claimed system or by the claim 21 claimed methods solved.

The system according to the invention is characterized in that an adjusting device is provided, by which during the operation of the plant, the proportion of the exhaust gas, the heat metexchanger happens, is changeable; the invention The process is characterized in that during operation bes the plant the portion of the exhaust gas that the heat exchanger happens, is changeable.

By changing the proportion of the exhaust gas that the heat happens, it is possible to change the temperature of the exchanger to control or regulate warming liquid. More precisely says it is possible regardless of the amount of exhaust gas generated, and any liquid regardless of the exhaust gas temperature to bring quantities to any temperature. With that the device according to the invention and the inventive The method can also be used in cases where the exhaust gas generating device not depending on the tempera tur of the liquid to be heated can be operated but such as an incinerator or a Diesel engine to generate electricity in continuous operation and in solely dependent on the type and amount of ver burning substances or the size of the elec trical energy must be operated.

Advantageous developments of the invention are the Unteran say, the following description and the figure bar.  

The invention is illustrated below with the aid of an embodiment game explained with reference to the figure.

The figure shows the structure of a described below system for heating a liquid by exhaust gas warmth.

In the system described below is the by Exhaust gas heat to be heated liquid water used for heating is used by rooms. However, it was already on this Point out that this is not a limitation consists. The heated water can also be used for any other Purposes can be used, and any other Liquids can be heated as water.

The system described below uses the exhaust gases of one Incinerator, more specifically, the exhaust gases from the Burning of color particles, which occur during operation an offset press, and which ones because they don't are allowed to get into the atmosphere, have to be burned. These paint particles are removed by a suction device aspirated and in one by a gas blower burner-formed incinerator burned.

At this point it should be pointed out that the system described below also for the use of Ab Gases can be used by any other furnace originate, whereby neither on the design of the furnace, nor on the material burned in the furnace, still in the manner of Combustion, still an on the intended use of the stove restriction exists. In addition, the described To able to be used for the use of exhaust gases by any other facilities originate in their operation Exhaust gases arise. Such other facilities are at for example, but by no means exclusively with diesel, Gasoline, gas, etc. powered engines for power generation.  

In Fig. 1, a system is shown by which the exhaust gases from a furnace for heating water are used.

The system shown includes an outgoing from an oven 1 exhaust pipe 2 , an outgoing from the exhaust pipe 2 and further back into this bypass pipe 3 , an on the branch of the bypass pipe 3 provided by the exhaust pipe 2 , adjustable flap 4 , one in the bypass tube 3 provided heat exchanger 5 , a downstream of the heat exchanger 5 before seen temperature sensor 6 , a downstream of the heat exchanger 5 provided fan 7 , one at the rear (be downstream of the exhaust gas stream) connected end of the heat exchanger 5 , the water to be heated approaching return line 8 , one connected to the front (upstream of the exhaust gas flow) end of the heat exchanger 5 , the heated water dissipating before run line 9 , a provided on the feed line 9 low water protection 10 , one on the feed line 9 before seen temperature sensor 11 , a in the flow line 9 provided solenoid valve 12 , a provided in the return line 8 solenoid valve 13 , an outgoing from the supply line 9 line with a pressure relief valve 14 , a provided at the foot point of the exhaust pipe drip pan 15 for catching conditions in the exhaust pipe 2 and / or in the bypass pipe 3 condensing liquid , and a further collecting trough extending over the entire arrangement for collecting liquid emerging from the arrangement.

The system also contains a motor, not shown in the figure, for adjusting the flap 4 , and a control device, also not shown in the figure, for controlling the position of the flap 4 and the fan 7 .

When exhaust gas flows through the bypass pipe 3 , it passes through the heat exchanger 5 and thereby heats the water pumped through it.

In the example considered, the exhaust gas temperature at the start of the bypass tube 3 is approximately 400 ° C, and after the heat exchanger approximately 80 ° C. There is of course no restriction to this. The temperatures mentioned can be much lower or higher, independently of one another.

How much exhaust gas flows through the bypass pipe 3 depends on the position of the flap 4 .

The flap 4 can be in a position referred to below as the first end position, hereinafter referred to as the second end position, and preferably also assume one or more intermediate positions. The first end position of the flap 4 is a position in which the flap 4 closes the opening to the bypass tube 3 , so that little or no exhaust gas can flow into the bypass tube 3 . The second end position of the flap 4 is a position in which the flap 4 closes the exhaust pipe 2 at a location above the branch of the bypass pipe 3 from the exhaust pipe 2 , so that the exhaust gas can (must flow completely into the bypass pipe 3 ). The intermediate positions are positions in which a portion of the exhaust gas flows through the bypass tube 3 and the other portion is passed on via the exhaust tube 2 , where it depends on the exact position of the flap 4 , how large the respective proportions are.

The position of the flap 4 is changed in the example considered from dependent on the temperature of the water in the flow line 9 detected by the temperature sensor 11 . As a result, the position of the flap 4 can be used to set how strongly the water flowing through the heat exchanger 5 is heated. If the water temperature is too high, the position of the flap 4 is changed so that less or no exhaust gas flows through the bypass tube 3 ; could or should the water temperature be higher, the position of the flap 4 is changed so that more exhaust gas flows through the bypass tube 3 .

This is a very important point because - unlike in a heating system, which when a certain Water temperature is simply turned off - can a Ver the furnace cannot be switched off at any time. If, when and how long an incinerator is switched off depends solely depending on whether this is just burning something has or not. To the temperature one through the exhaust gases warmed water can under no circumstances be taken into account. Apart from that, the shutdown of incinerators leads to in many cases, the ab gas temperature. The exhaust gas temperature only drops when that increases burning material stops burning or glowing what for example, incinerators for hours or days can take.

The position of the flap 4 is fer ner in the example considered in dependence on the detected by the temperature sensor 6 exhaust gas temperature, more specifically depending on the rear of the heat exchanger 5 prevailing exhaust gas temperature changed. If this exhaust gas temperature is too high, the position of the flap 4 is changed so that less or no exhaust gas flows through the bypass tube 3 ; could exhaust gas temperature be higher, the position of the flap 4 can be changed so that more exhaust gas flows through the bypass tube 3 . This allows the fan 7 to be protected from damage.

For the sake of completeness, it should be noted that if the water temperature becomes too high, the position of the flap 4 is changed in any case, in particular regardless of the exhaust gas temperature, so that less or no exhaust gas flows through the bypass tube 3 , and then If the exhaust gas temperature becomes too high, the position of the flap 4 is changed in any case, in particular regardless of the water temperature so that less or no exhaust gas flows through the bypass tube 3 .

The position of the flap 4 is changed in the example considered fer ner depending on the lack of water 10 . De tektiert the lack of water 10 a lack of water, the position of the flap 4 is changed so that no more exhaust gas can flow through the bypass tube 3 .

The position of the flap 4 can be changed by an electric motor or by another drive mechanism. This electric motor is controlled directly by the sensors 6 , 10 and 11 , or by a control device working depending on these sensors.

The amount of exhaust gas flowing through the bypass pipe 3 is determined not only by the flap 4 but also by the fan 7 . This sucks the hot exhaust gas into the bypass pipe 3 and blows the cooled exhaust gas back into the exhaust pipe 2 . The fan 7 runs in the example considered at constant speed, but is switched off when the flap 4 is brought into a position in which no exhaust gas can get into the bypass tube 3 .

However, it would also be conceivable to use a fan with variable speed, and then not only via the flap 4 , but also to determine via the fan which portion of the exhaust gas emitted by the furnace 1 is passed through the bypass pipe 3 .

Under certain circumstances, it would even be possible to omit the flap 4 , and to adjust the proportion of the exhaust gas emitted by the furnace 1 through the bypass pipe exclusively by adjusting the speed of the fan.

It should be obvious and requires no further explanation that there are still further possibilities by which the proportion of the exhaust gas emitted by the furnace 1 can be passed through the bypass pipe 3 . Which option is ultimately used is of subordinate importance. It is important "only" that a setting device is provided, by means of which the portion of the exhaust gas which passes through the heat exchanger can be changed during operation of the system.

The other components of the system, more precisely the Ven tile 12 to 14 and the sumps 15 and 16 are protective devices by which damage to the shown location or damage to the surrounding area from existing devices such as the printing press can be prevented

The system described above can be in various ways Terms to be modified.

For example, instead of the bypass tube 3, an outgoing gas pipe 2 or directly from the point at which the exhaust gases arise, outgoing second exhaust pipe is provided, which does not open again in the first exhaust pipe 2 , but instead introduces the exhaust gases into the atmosphere ,

Furthermore, it can be provided to provide the flap 4 in the tube containing the heat exchanger.

Regardless of this, the change in the flap position and of fan operation additionally or alternatively in depend depending on any other parameters, for example depending on the need for hot water, or depending on others Set measured exhaust gas and / or water temperatures gene.

The system and method described enable lichen it regardless of the details of practical Realization that liquids can flow out of any Exhaust gases originating from sources are astonishingly simple Let it heat up exactly as required.  

LIST OF REFERENCE NUMBERS

1

oven

2

exhaust pipe

3

Bypass pipe

4

flap

5

heat exchangers

6

temperature sensor

7

fan

8th

Return line

9

supply line

10

Water indicator

11

temperature sensor

12

Solenoid valve on

9

13

Solenoid valve on

8th

14

Pressure relief valve

15

drip tray

16

second drip pan

Claims (40)

1. Plant for heating a liquid by exhaust gas heat using a heat exchanger ( 5 ) through which the liquid to be heated flows and passed through the exhaust gas, characterized in that an adjusting device ( 4 , 7 ) is provided, by which the portion during operation of the plant of the exhaust gas that passes through the heat exchanger is changeable. 2. Installation according to claim 1, characterized in that the installation contains an exhaust pipe system ( 2 , 3 ) which enables light that the exhaust gas can get into the atmosphere in various ways from the device generating the gas ( 1 ). 3. Plant according to claim 2, characterized in that the heat exchanger ( 5 ) is provided in a region of the exhaust pipe system ( 2 , 3 ), which can be passed by the exhaust gas, but need not be passed. 4. Installation according to claim 2 or 3, characterized in that the installation comprises an exhaust pipe ( 2 ) and a branch pipe branching off from the exhaust pipe and at another point of the exhaust pipe again opening into this bypass pipe ( 3 ), and in that the heat exchanger ( 5 ) either in the bypass pipe or in the part of the exhaust pipe which extends between the branch point and the outlet point. 5. Plant according to one of the preceding claims, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas comprises an adjustable flap ( 4 ). 6. Plant according to claim 5, characterized in that the flap ( 4 ) in front of the heat exchanger ( 5 ) containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) is provided. 7. Plant according to claim 5, characterized in that the flap ( 4 ) in the heat exchanger ( 5 ) containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) is provided. 8. Installation according to claim 6 or 7, characterized in that the flap ( 4 ) can be brought into a first position in which it closes the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) containing the heat exchanger ( 5 ). 9. Installation according to one of claims 6 to 8, characterized in that the flap ( 4 ) can be brought into a second position in which it the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) containing the heat exchanger ( 5 ) open holds. 10. Plant according to claim 9, characterized in that the flap ( 4 ) is arranged so that it closes the heat exchanger ( 5 ) not containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) in the second position. 11. Plant according to one of claims 8 to 10, characterized in that the flap ( 4 ) in one or more intermediate positions between the first position and the second position can be brought. 12. Plant according to one of the preceding claims, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas comprises a fan ( 7 ). 13. Plant according to claim 12, characterized in that the fan ( 7 ) in the heat exchanger ( 5 ) containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) is provided, and in that the exhaust gas contains hot exhaust gases into the heat exchanger tendency part ( 3 ) of the exhaust pipe system ( 2 , 3 ) are sucked in and cooled exhaust gases are blown out of the part of the exhaust pipe system containing the heat exchanger. 14. Installation according to one of the preceding claims, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas in dependence on the temperature of the shear leaving the Wärmetau liquid works. 15. Plant according to claim 14, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas ensures that the heat exchanger is passed by less or no exhaust gas when the temperature of the liquid leaving the heat exchanger exceeds a certain limit. 16. Plant according to claim 14 or 15, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas ensures that the heat exchanger is passed by more exhaust gas when the temperature of the heat exchanger leaving liquid falls below a certain limit. 17. Plant according to one of the preceding claims, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas depending on the temperature of the exhaust gas works. 18. Plant according to claim 17, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas ensures that the heat exchanger is passed by less or no exhaust gas when the exhaust gas temperature one exceeds a certain limit. 19. Plant according to claim 17 or 18, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas ensures that the heat exchanger is passed by more exhaust gas when the exhaust gas temperature a certain limit under steps. 20. Installation according to one of the preceding claims, characterized in that the adjusting device ( 4 , 7 ) for changing the heat exchanger ( 5 ) passing portion of the exhaust gas ensures that the heat exchanger is passed by less or no exhaust gas when an improper system condition is detected or damage to the system is to be feared. 21. A method of heating a liquid by exhaust gas heat using a flow of the liquid to be heated and passed by the exhaust gas heat exchanger ( 5 ), characterized in that the proportion of the exhaust gas that passes through the heat exchanger is changeable during operation of the system , 22. The method according to claim 21, characterized in that the system contains an exhaust pipe system ( 2 , 3 ), which it makes it possible for the exhaust gas to be led into the atmosphere in various ways by the device generating the exhaust gas ( 1 ). 23. The method according to claim 22, characterized in that the heat exchanger ( 5 ) is provided in an area of the exhaust pipe system ( 2 , 3 ) which can be passed by the exhaust gas, but does not have to be passed. 24. The method according to claim 22 or 23, characterized in that the system comprises an exhaust pipe ( 2 ) and one branching from the exhaust pipe and at a different location of the exhaust pipe as the bypass pipe ( 3 ) opening into it, and in that the heat exchanger ( 5 ) is provided either in the bypass pipe or in the part of the exhaust pipe which extends between the branch point and the outlet point. 25. The method according to any one of claims 21 to 24, characterized in that the change of the portion of the exhaust gas passing through the heat exchanger (59) is carried out by adjusting an adjustable flap ( 4 ). 26. The method according to claim 25, characterized in that the flap ( 4 ) is provided in front of the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) containing the heat exchanger ( 5 ). 27. The method according to claim 25, characterized in that the flap ( 4 ) in the heat exchanger ( 5 ) containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) is provided. 28. The method according to claim 26 or 27, characterized in that the flap ( 4 ) can be brought into a first position in which it closes the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) containing the heat exchanger ( 5 ). 29. The method according to any one of claims 26 to 28, characterized in that the flap ( 4 ) can be brought into a second position in which it the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) containing the heat exchanger ( 5 ) ent open holds. 30. The method according to claim 29, characterized in that the flap ( 4 ) 50 is arranged so that in the second position it closes the part ( 3 ) of the exhaust pipe system ( 2 , 3 ) which does not contain the heat exchanger ( 5 ). 31. The method according to any one of claims 28 to 30, characterized in that the flap ( 4 ) can be brought into one or more intermediate positions lying between the first position and the second position. 32. The method according to any one of claims 21 to 31, characterized in that the change in the portion of the exhaust gas passing through the heat exchanger ( 5 ) takes place via a fan ( 7 ). 33. The method according to claim 32, characterized in that the fan ( 7 ) in the heat exchanger ( 5 ) containing part ( 3 ) of the exhaust pipe system ( 2 , 3 ) is provided, and that hot exhaust gases into the heat exchanger containing the fan Part of the exhaust pipe system are sucked in and cooled exhaust gases are blown out of the part of the exhaust pipe system containing the heat exchanger. 34. The method according to any one of claims 21 to 33, characterized in that the change in the heat exchanger ( 5 ) passing portion of the exhaust gas depending on the temperature of the liquid leaving the heat exchanger he follows. 35. The method according to claim 34, characterized in that the change of the heat exchanger ( 5 ) passing on part of the exhaust gas takes place so that the heat exchanger of less or no exhaust gas is passed when the temperature of the liquid leaving the heat exchanger determines a exceeds the limit. 36. The method according to claim 34 or 35, characterized in that the change of the heat exchanger ( 5 ) pass the portion of the exhaust gas so that the heat exchanger is passed by more exhaust gas when the temperature of the heat exchanger leaving a certain liquid Falls below the limit. 37. The method according to any one of claims 21 to 36, characterized in that the change of the portion of the exhaust gas passing through the heat exchanger ( 5 ) takes place as a function of the temperature of the exhaust gas. 38. The method according to claim 37, characterized in that the change of the heat exchanger ( 5 ) passing on part of the exhaust gas takes place so that the heat exchanger is passed by less or no more exhaust gas when the exhaust gas temperature exceeds a certain limit. 39. The method according to claim 37 or 38, characterized in that the change of the heat exchanger ( 5 ) pass the proportion of the exhaust gas so that the heat exchanger is passed by more exhaust gas when the exhaust gas temperature falls below a certain limit value. 40. The method according to any one of claims 21 to 40, characterized in that the change of the portion of the exhaust gas passing through the heat exchanger ( 5 ) takes place in such a way that less or no exhaust gas is passed through the heat exchanger when the system is in an improper condition has been detected or damage to the system is to be feared.