HEAT EXCHANGER HAVING ENHANCED CORROSION RESISTANCE

Abstract
A heat exchanger for heating a fluid in an incineration plant, comprising at least one heat exchanger component wherein the side in contact with the flue gas has an oxide layer comprising an α-Al2O3 which protects the heat exchanger component against corrosion caused by corrosive compounds entrained or comprised by the flue gas.
Description
FIELD OF THE INVENTION

The present invention relates to a method of heat transfer from a flue gas in an incineration plant to a fluid.


BACKGROUND OF THE INVENTION

Heat exchangers are known in the field of incineration processes for transferring heat from flue gases to fluids for heating the fluids. One use of heat exchangers is for the heating of saturated steam from a boiler for converting the saturated steam into dry (also called superheated) steam more useable for example in power generation processes. Dry steam is for example used for driving steam turbines in power plants.


A heat exchanger typically includes a large number of heat exchanger components, each heat exchanger component having a wall with a first side in contact with a fluid to be heated and a second side in contact with a heating medium, which in an incineration process typically is flue gas generated by the incineration process. The heat exchanger components may be plates, as in a plate heat exchanger, but may alternatively be shaped as tubes, the inner and outer side of the tube wall defining the first and second side of the heat exchanger component. For producing superheated steam in an incineration plant for producing power the heat exchanger typically comprises a plurality of individual heat exchanger components in the shape of tubes, also called superheater tubes, through which the steam sequentially passes. The heat exchanger is placed in the path of the flue gasses so that the heat exchanger components are heated by the flue gas whereby heat is passed through the wall of the heat exchanger components to heat the steam within.


Different incineration processes burn different fuels. Common incineration plants for generating power burn waste. The waste may be household waste and/or other types of waste such as industrial waste etc. Such an incineration plant is also called a waste to energy incineration plant.


A problem related to the nature of the waste burnt in the incineration plant is that the flue gas, and/or the hot ashes entrained in the flue gas, to a lesser or larger extent depending on the exact nature of the waste being burnt, comprises corrosive compounds such as chlorine. The hot ashes entrained in the flue gasses condense onto the comparatively cooler surfaces of the heat exchanger, especially the heat exchanger components or super heater tubes, and form a sticky coating thereon. Chlorine present in this coating is highly corrosive and causes severe corrosion of the metal material of the heat exchanger components or superheater tubes.


The extent of corrosion is dependent on the temperature of the heat exchanger components. When superheating steam, the temperature of the heat exchanger components, through heat transfer between the steam and the heat exchanger component, is typically 30-50° C. higher than that of the steam. Higher temperature of the steam speeds up the corrosion process, thus, in order to ensure a useful life of the heat exchanger components the temperature of the steam to be superheated has to be limited. This however severely limits the efficiency of the incineration plant, particular as regards power generation where the efficiency of a steam turbine is dependent on the temperature of the steam.


Where tubes of inexpensive steel, containing mostly Fe (iron), are used as heat exchanger components for superheating steam, the maximum steam temperature is approximately 400° C. if excessive corrosion and an acceptable service life is to be achieved.


Approaches for allowing the steam temperature to be increase include providing tubes of inexpensive steel coated with more expensive alloys such as Inconel 625. Inconel 625 is a nickel based alloy forming a scale of chromium oxide on its surface when subjected to heat and corrosion. With this approach a steam temperature of approximately 440° C. is possible with the same speed of corrosion and service life as that possible using the tubes of inexpensive steel at 400° C.


However, still higher steam temperatures are desired in order to maximize the efficiency of incineration plants.


It is known from other technical fields to form thermal barriers comprising α-Al2O3, see for example EP1908857A2, however a thermal barrier prevents heat transfer and is thus not useable for protecting a heat exchanger component from corrosion. It is further known from JP4028914A to form a fire grate comprising α-Al2O3. A fire grate is however watercooled and thus only subjected to low temperatures when compared to the steam temperature in heat exchanger for superheating steam.


Further documents related to coating or barrier layers include EP2143819A1 WO2011100019A1, EP1944551A1, EP659709A1 and U.S. Pat. No. 5,118,647A.


In EP 1 164 330 is disclosed a superheater tube comprising nickel in order to reduce corrosion. According to EP 1 164 330 a higher efficiency, and lower corrosion is achieved by reheating the steam leaving the first turbine by using steam A′ from the steam drum. This gives a higher efficiency and a lower steam and pipe temperature.


SUMMARY OF THE INVENTION

It is thus an object of the present invention to provide a heat exchanger having enhanced corrosion resistance.


It is a further object of the present invention to provide a heat exchanger for increasing the efficiency of an incineration plant producing superheated steam.


It is a yet a further object of the present invention to provide a method for forming a scale for protecting a heat exchanger component against corrosion caused by corrosive compounds entrained or comprised by a flue gas.


At least one of the above objects, or at least one of further objects which will be evident from the below description, are according to a first aspect of the present invention achieved by the heat exchanger.


α-Al2O3, also called alpha-alumina, is an aluminium oxide which is highly corrosion resistant. Thus the protective oxide has the effect of increasing the corrosion resistance of the heat exchanger. As the corrosion resistance is increased the fluid can be heated at higher temperatures, thus allowing the efficiency of heating the fluid to be increased while still maintaining an acceptable service life of the heat exchanger.


The fluid may be any fluid suitable for being heated. Typically the fluid is water or steam. For a fluid such as steam the heat exchanger according to the first aspect of the present invention may be used with steam temperatures of above at least 480° C. with a service life of at least 5 years. It is further contemplated that steam temperatures of up to 600° C. can be used with at least 5 years of service life.


The incineration plant may incinerate fuels such as coal, other fossil fuels, biomass, demolition wood chips, refuse derived fuels, or waste. In the context of the present invention the term flue gas is to be understood as also comprising substances and particles generated by the incineration of a fuel. The flue gas may have a temperature of up to 1100° C. to 1200° C. where the flue gas is generated, i.e. where the incineration takes place.


Preferably the heat exchanger component is made of metal as metal has a high heat conductivity and is easily fabricated. The corrosion is typically heat corrosion.


In a preferred embodiment of the first aspect of present invention the fluid is steam and the heat exchanger is a superheater for superheating the steam. Preferably the steam is saturated as the heating of saturated steam takes place at high temperatures at which the enhanced corrosion resistance of the heat exchanger according to the first aspect of the present invention is useful.


In embodiments of the heat exchanger wherein the fluid is steam and the heat exchanger is a superheater the at least one heat exchanger component is preferably a tube, also called a superheater tube.


In a preferred embodiment of the first aspect of present invention the protective oxide of the heat exchanger is a scale. A scale is generally understood to be an oxide layer. The scale is up to 10 μm thick and comprises predominantly α-Al2O3. More preferably the scale comprises substantially only α-Al2O3. This is advantageous as it increases the corrosion resistance of the scale. The scale is preferably dense.


In a further preferred embodiment of the first aspect of the present invention the heat exchanger component is made from a precursor material forming a scale oxidation. Thus, a simple way of providing the heat exchanger component is provided. When the heat exchanger component is a superheater tube the superheater tube may typically have a diameter of 0.5 inches to 3 inches, corresponding to 12 to 77 mm. This heat exchanger component may for example be a tube or a plate


By an even further preferred embodiment of the first aspect of the present invention the heat exchanger component comprises a base material coated by a precursor material which forms a scale upon oxidation. The material costs of the heat exchanger component may be lessened since the base material can be a simple inexpensive corrosion liable steel whereas only the comparatively thinner coating need be of the precursor material. The coating need only have a thickness sufficient to allow forming of the scale and to avoid aluminium depletion in the alloy during operation.


This heat exchanger component may for example be a tube or a plate.


By a preferred embodiment of the first aspect of the present invention the precursor material is coated upon the base material by a welding process. This simple process may be used both for fabricating new heat exchange components and for retro-fitting existing heat exchanger components with the precursor material to increase the corrosion resistance of the existing heat exchanger component.


Welding is an example of applying the precursor material, but other methods known in the field may also be utilized for applying the precursor material. When welding, the coating may be from 1 mm to 20 mm thick.


By a preferred embodiment of the first aspect of the present invention the heat exchanger component comprises an inner tube covered by an outer tube, wherein the outer tube is made from a precursor material forming said scale upon oxidation. The advantage is that the material costs will be lessened since the inner tube can be made of a simple inexpensive corrosion liable steel whereas only the outer tube need be of the precursor material. Further the assembly of the inner tube with the outer tube may be made rapidly or automatically.


By a further preferred embodiment of the first aspect of the present invention a rational and effective way of providing a heat exchanger component is provided by co-extruding the inner and outer tube.


In an alternative embodiment of the heat exchanger component comprising an inner tube and an outer tube the outer tube is extruded onto the inner tube. In a preferred embodiment of the first aspect of present invention the precursor material of the heat exchanger comprises an alloy comprising at least 4-5 wt. % aluminium. Possible precursor materials should be an alloy having a minimum of 4-5 wt. % aluminium content. One exemplary precursor material is Haynes 214 alloy. Further exemplary precursor materials include the alloys in table 1.









TABLE 1







Constitution of exemplary alloys
















Alloy
C
Al
Cr
Ni
Co
Fe
Mo
W
Others



















IN 713C
0.12
6
12.5
Bal


4.2

0.8Ti, 2Cb, 0.012B, 0.10Zr


IN 713LC
0.05
6
12.0
Bal


4.5

0.6Ti, 2Cb, 0.1Zr, 0.01B


B-1900
0.1
6
8.0
Bal
10.0

6.0

1.0Ti, 4.0Ta, 0.1Zr, 0.015B


IN 100
0.18
6
10.0
Bal
15.0

3.0

1.0Ti, 4.0Ta, 0.1Zr, 0.015B


IN162
0.12
6.5
10.0
Bal


4.0
 2.0
1.0Ti, 1.0Cb, 2.0Ta, 0.1Zr, 0.02B


IN 713
0.18
5.5
9.5
Bal
10.0

2.5

4.6Ti, 0.06Zr, 0.015B, 1.0V


M 21
0.13
6
5.7
Bal


2.0
11.0
0.12Zr, 1.5Cb, 0.02B


M 22
0.13
6.3
5.7
Bal


2.0
11.0
3Ta, 0.6Zr


MAR-M 200
0.15
5
9.0
Bal
10.0
1.0

12.5
2Ti, 0.05Zr, 0.015B, 1.0Cb


MAR-M 246
0.15
5.5
9.0
Bal
10.0

2.5
10.0
1.5Ti, 1.5Ta, 0.05Zr, 0.015B


RENE 100
0.16
5.5
9.5
Bal
15.0

3.0

4.2Ti, 0.006Zr, 0.015B


TAZ-8A
0.12
6
6.0
Bal


4.0
 4.0
8Ta, 1Zr, 2.5Cb, 0.004B


TAZ-8B (DS)
0.12
6
6.0
Bal
 5.0

4.0
 4.0
8Ta, 1Zr, 1.5Cb, 0.004B









In a preferred embodiment of the first aspect of present invention the heat exchanger of the incineration plant in operation is subjected to corrosive compounds comprising chlorine while incinerating waste. The incineration plant may be a waste to energy incineration plant generating both heat for use in for example area heating and steam for electrical power generation. The waste may be household waste or industrial waste, preferably the waste is household waste or light industrial waste.


The α-Al2O3 is resistant to corrosive compounds such as S, O2, H2O, Cl2, N2, CO/CO2 etc. Other corrosive compounds which may form in an incineration plant include Na, Ca, Cu, K, Cl, S, Cr, Pb, Zn, Fe, Sn and Al.


In a preferred embodiment of the first aspect of the present invention the heat exchanger comprises a plurality of heat exchanger components. By this the heat exchanging capacity of the heat exchanger is increased. The heat exchanger is preferably a superheater comprising typically 150 to 300 superheater tubes.


In a preferred embodiment of the first aspect of the present invention the heat exchanger component of the heat exchanger is a tube. Such a heat exchanger component is easy to form and is suitable for heating a liquid in an incineration plant. Further a tube is suitable where the liquid is pressurized, such as for example superheated steam. Where the heat exchanger is a superheater and the heat exchanger component is a superheater tube, the superheater tube typically up to 6 m long.


At least one of the above mentioned and further objects are moreover achieved by a second aspect of the present invention pertaining to a method of forming a scale for protecting a heat exchanger component against corrosion caused by corrosive compounds entrained or comprised by a flue gas comprising the steps of: providing a heat exchanger component comprising a precursor material arranged for protecting the heat exchanger component after oxidation against said corrosion, said precursor material comprising aluminium; and oxidize the heat exchanger component at a temperature, atmosphere and for a time adopted to form the scale on the precursor material, wherein the scale comprises predominantly α-Al2O3.


By oxidizing the heat exchanger component at a temperature, atmosphere and for a time adapted to form a scale on the precursor material, the scale comprising predominantly α-Al2O3, an even and complete scale is provided on the heat exchanger component providing an effective protection of the heat exchanger component.


The temperature, atmosphere and time should be adapted such that a dense scale is formed. The scale formed during the oxidation step should have a thickness of 0.1 μm to 2 μm. The time needed will depend on the exact precursor material used.


The atmosphere should have a low partial pressure of oxygen, pO2. The pO2 should be below 10−8 atm, more preferably below 10−11 atm.


In a preferred embodiment of the method according to the second aspect of the present invention the method further comprises an additional step of assembling the oxidized heat exchanger component into a heat exchanger.


In an alternative embodiment of the method according to the second aspect of the present invention the method further comprises an additional step of assembling the heat exchanger component into a heat exchanger prior to the heat exchanger component is oxidized.


In a preferred embodiment of the second aspect of present invention the temperature of the precursor material is brought to at least 950° C., more preferably 1100° C. to 1200° C. The temperature has to be adapted so that α-Al2O3, as opposed to other types of aluminium oxides, is formed. If the temperature is too low, α-Al2O3 will not form.


In a preferred embodiment of the second aspect of the present invention a suitable atmosphere for the oxidation step for most precursor materials is provided. One such suitable atmosphere is an atmosphere comprising an Argon-Hydrogen mixture containing 2% water vapour.


In a preferred embodiment of the second aspect of the present invention the oxidation step for the precursor materials is at least 2 hours.





BRIEF DESCRIPTION OF THE DRAWINGS

The invention and its many advantages will be described in more detail below with reference to the accompanying schematic drawings, which for the purpose of illustration show some non-limiting embodiments, and in which



FIG. 1 shows a partial overview of a waste to energy incineration plant provided with a heat exchanger according to the first aspect of the present invention,



FIG. 2 shows, in side view, heat exchanger components, in the form of superheater tubes, of the heat exchanger according to the first aspect of the present invention, and



FIGS. 3A, 3B, and 3C show, in partial cutaway side view, first second and third embodiments of heat exchanger components, in the form of superheater tubes, of the first second and third embodiments of the heat exchanger according to the first aspect of the present invention.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the below description, one or more subscript roman numerals added to a reference number indicates that the element referred to is a further one of the element designated the un-subscripted reference number.


Further, A superscript roman numeral added to a reference number indicates that the element referred to has the same or similar function as the element designated the un-superscripted reference number, however, differing in structure.


When further embodiments of the invention are shown in the figures, the elements which are new, in relation to earlier shown embodiments, have new reference numbers, while elements previously shown are referenced as stated above. Elements which are identical in the different embodiments have been given the same reference numerals and no further explanations of these elements will be given.



FIG. 1 shows a partial overview of a waste to energy incineration plant 2. Waste 4 to be incinerated is fed into the incineration plant by a conveyor 6 onto a grate 8 on which the waste 4 is burnt. Flue gas resulting from the incineration of the waste 4 on the grate 8 rises upwards as illustrated by arrow 12. The flue gas 12 may have a temperature of up to 1100° C. to 1200° C. and is then led through the first second and third radiation passes 1014 and 16 to a horizontal convection pass 18 after which the flue gases are eventually led to a chimney and released to the atmosphere as indicated by arrow 20.


The walls 22 of the first second and third radiation passes 1014 and 16 are provided with tubes 24 to which water is fed for generating steam. The steam is then, as indicated by arrow 26, in turn led through superheaters 2830 and 32, each of which represents a heat exchanger, positioned in the horizontal convection pass 18. The superheaters 2830 and 32 are heated by the flue gas 12 passing through the convection pass 18 as illustrated by arrow 34. The heat from the flue gas 34 steam 26 so that the steam 26 is converted into superheated steam 36 which is led to a steam turbine (not shown) or similar consumer of superheated steam.


Additionally (not shown) the superheater 28 may be preceded by an evaporator for producing further saturated steam, the evaporator being placed upstream of the superheater 30 in the path of the flue gases 12, and being similar in construction to the superheater 28.


The flue gas 34 heating the superheater 2830 and 32 comprises inter alia corrosive compounds and particles of hot ash 38, not shown in FIG. 1, which particles of hot ash 38 may themselves comprise corrosive compounds.


The temperature of the steam 26 increases as it is led through the superheaters 2830 and 32. The lowest steam temperature of 250° C. to 300° C. is found in superheater 28 and the highest steam temperature is found in superheater 32. Thus the risk of corrosion is highest for superheater 32. In the incineration plant 2 all superheaters may be identical to the superheater 32, which superheater 32 is a heat exchanger according to the present invention. Alternatively, to save costs, only superheater 32 is a heat exchanger according to the present invention whereas superheaters 28 and 30 are superheaters consisting of conventional materials.


Each superheater 283032 comprises a number of superheater tubes representing heat exchanger components.



FIG. 2 shows superheater tubes, one of which is designated the reference numeral 40, of the superheater 32 in FIG. 1. As seen in FIG. 2, steam 26 runs through the superheater tubes 40 while flue gas 34 passes between the superheater tubes 40 to heat the superheater tubes 40 and the steam 26 running within the superheater tubes 40. The superheater tubes 40 may be joined to each other by bends, one of which is designated the reference numeral 42, which may be formed separate from the superheater tubes 40 and joined thereto, or which alternatively may be formed integrally with the superheater tubes 40.



FIG. 3A shows a first embodiment of a superheater tube 40, representing a heat exchanger component, of the super heater 32, representing a first embodiment of the heat exchanger according to the first aspect of the present invention.


Superheater tube 40 comprises a main tube 44 including a wall having a first side 46 in contact with the steam 26 and a second side 48 facing the flue gas 34. The main tube 44 is made from a precursor material which upon oxidation forms a scale 50 comprising α-Al2O3 at least on the second side.


Flue gas 34 passes the superheater tube 40 and deposits particles of hot ash 38 on the main tube 44, thus forming a sticky deposit 52 upon the second side 48 of the single material tube 44. Corrosive compounds comprised by the flue gas 34 and/or the particles of hot ash 38 are thus present in the sticky coating 52. Corrosion of the main tube 44 is however prevented, or at least diminished, by the scale 50 covering the second side 48 of the main tube 44.



FIG. 3B shows a second embodiment of a superheater tube 40′, representing a heat exchanger component, of a super heater 32′, representing a second embodiment of the heat exchanger according to the first aspect of the present invention.


Superheater tube 40′ comprises a main tube 44′, made from a material which does not form a scale comprising α-Al2O3 upon oxidation. Instead superheater tube 40′ comprises, on the second side 48 of the main tube 44′, a welded cladding 54 of a precursor material which upon oxidation forms the scale 50 comprising α-Al2O3. The scale 50 on the welded cladding 54 prevents, or at least diminishes, corrosion of the main tube 44′ due to corrosive compounds comprised by the flue gas 34 and/or the particles of hot ash 38.



FIG. 3C shows a third embodiment of a superheater tube 40″, representing a heat exchanger component, of a super heater 32″, representing a third embodiment of the heat exchanger according to the first aspect of the present invention.


Superheater tube 40″ comprises an inner tube 44″, representing a main tube, made from a material which does not form a scale comprising α-Al2O3 upon oxidation. Instead superheater tube 40″ comprises, on the second side 48 of the main tube 44″, an outer tube 56 made of a precursor material which upon oxidation forms the scale 50 comprising α-Al2O3. The scale 50 on the outer tube 56 prevents, or at least diminishes, corrosion of the inner tube 44″ due to corrosive compounds comprised by the flue gas 34 and/or the particles of hot ash 38. The superheater tube 40″ may be manufactured by co-extruding the main tube 44″ and the outer tube 56.












List of parts with reference to the figures:

















 2. Incineration plant



 4. Waste



 6. Conveyor



 8. Grate



10. First radiation pass



12. Flue gas



14. Second radiation pass



16. Third radiation pass



18. Horizontal convection pass



20. Arrow indicating flue gases being led eventually to a chimney



22. Walls of radiation passes



24. Tubes



26. Saturated steam



28. Superheater



30. Superheater



32. Superheater



34. Arrow indicating flue gas passing through convection pass



36. Superheated steam



38. Particles of hot ashes



40. Superheater tube



42. Bend



44. Main tube



46. First side



48. Second side



50. Scale



52. Sticky deposit



54. Welded cladding



56. Outer tube









Claims
  • 1. A method of heat transfer from a flue gas in an incineration plant to a fluid, the method comprising the steps of: providing at least one heat exchanger component comprising an inner tube and a cladding on an external surface of the inner tube, the cladding being fully made from an aluminum alloy precursor material;leading the fluid through the at least one heat exchanger component, the fluid being in contact with an internal surface of the inner tube;leading the flue gas resulting from incineration of a waste in the incineration plant into an atmosphere around the at least one heat exchanger component, the flue gas being in contact with an external surface of the cladding, the flue gas having a predetermined temperature of the flue gas, a predetermined percentage of oxygen in the atmosphere and a predetermined partial pressure of the oxygen;generating a protective oxide layer surrounding the cladding during operation of the incineration plant upon oxidation of the external surface of the cladding by being exposed to the oxygen at the predetermined temperature and the predetermined pressure, the protective oxide layer protecting the cladding from corrosive components of the flue gas, the protective oxide layer being a scale comprising alpha-Al2O3;continuously regenerating the protective oxide layer as the protective oxide layer is being worn by corrosion; andheating the fluid by the flue gas.
  • 2. The method of heat transfer according to claim 1, wherein the fluid is steam and the heat exchanger component is a superheater for superheating the steam.
  • 3. The method of heat transfer according to claim 1, wherein the precursor material comprises an alloy comprising at least 4 wt. % aluminium.
  • 4. The method of heat transfer according to claim 1, wherein the corrosive compounds comprises chlorine,
  • 5. The method of heat transfer according to claim 1, wherein the at least one heat exchanger component comprises a plurality of said heat exchanger components.
  • 6. The method of heat transfer according to claim 2, wherein a temperature of the at least one heat exchanger component is 30-50° C. higher than a temperature of the steam.
  • 7. The method of heat transfer according to claim 1, wherein the temperature of the flue gas is in the range of 1100-1200° C.
  • 8. The method of heat transfer according to claim 1, wherein the partial pressure of oxygen is below 10−8 atm.
  • 9. The method of heat transfer according to claim 1, wherein the scale formed during the oxidation has a thickness of 0.1 μm to 2 μm.
  • 10. The method of heat transfer according to claim 1, wherein the scale is even and complete.
  • 11. The method of heat transfer according to claim 1, wherein the inner tube is made from a material which does not form a scale comprising alpha-Al2O3 upon oxidation.
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. application Ser. No. 14/399,411 filed on Nov. 6, 2014 which is the U.S. National Phase of PCT/IB2012/052479 filed May 16, 2012 the entire content of which is incorporated herein by reference.

Continuations (1)
Number Date Country
Parent 14399411 Apr 2015 US
Child 16139276 US