| US1358330A | 1920-11-09 | |||
| SU382903A1 | 1973-05-25 | |||
| US4038022A | 1977-07-26 | |||
| GB815643A | 1959-07-01 |
| 1. | A method of heat delivery and waste heat recovery from the exhaust flue gases of an insulated heating apparatus including a burner, which comprises the steps of: directing said exhaust flue gases through a first passage within the insulating wall of said heating apparatus prior to final exhaust of said gases; directing oxygen containing gases through a second passage within the wall of said heating apparatus in heat exchange relationship with said first passage, and which substantially covers that surface area of said first passage which faces away from the combustion zone of the heating apparatus, for preheating said oxygen containing gases; directing said preheated oxygen containing gases to said burner; providing fuel to said burner; and combusting said fuel with said preheated oxygen containing gases within said burner. |
| 2. | The method of Claim 1, wherein said oxygen containing gas is air . |
| 3. | The method of Claim 1, wherein the step of directing preheated oxygen containing gases to said burner is accomplished within the wall of said e'ating apparatus. |
| 4. | The method of Claim 1, which comprises the further step of introducing second oxygen containing gases into said first passage, for combusting with combustible products in said hot flue gases. |
| 5. | The method of Claim 3, wherein said second oxygen containing gas is air. |
| 6. | The method of Claim 3, wherein said second oxygen containing gas is pure oxygen. |
| 7. | The method of Claim 3, wherein said gas is a mixture of oxygen and air. |
| 8. | A furnace which comprises: first passage means for directing exhaust flue gases within the wall of the furnace prior to final exhaust of said gases; second passage means for directing oxygen containing gases within the wall of the furnace in heat exchange relationship with said first p'assage means for preheating said oxygen contaLning gases; third passage means for directing preheated oxygen containing gases from said second passage means to said burner means; burner means for combusting fuel with the preheated oxygen containing gases inside the furnace; and means for providing fuel to said burner means. |
| 9. | The furnace of Claim 8, wherein: the walls of the furnace comprise refractor/ lining material; and said first, second and third passage means • are located completely within said refractory lining material. |
| 10. | The furnace of Claim 9, wherein: said second passage means is a recuperator for heat exchange from the hotter flue gases in said first passage means to the colder oxygen containing gases in said second passage means; and said second passage means is located along its length between said first passage means and said refractory lining material. |
| 11. | The furnace of Claim 10, wherein said first and second passage means are formed in a threesided groove in the refractory lininσ material of said furnace wall, with said recuperator substantially covering the three sides of the groove and forming a said first passage means when the groove and said recuperator are covered by a refractory partition comprising refractory lining material sealed to said refractory wall. |
| 12. | The furnace of Claim 10, wherein said oxygen containing gas is air . |
| 13. | The furnace of Claim 8, which further comprises means for introducing second oxygen containing gases into said first passage means, for combusting with combustible products in said flue gases. |
| 14. | An integrated furnace wall module, which comprises: an outer metal plate; a refractory lining covering the surface of said plate and attached therto; a multiplicity of channels within said refractory lining for exhausting flue gases; an air burner through said plate and said refractory lining; means for introducing flue gases from the combustion zone of the furnace into said flue duct; and means for exhausting flue αases from flue duct generally remote from said flue gas introduction means. |
| 15. | The integrated furnace wall nodule of Claim 14, which further comprises: a recuperator within said refractory lining in heatexchange relationship with said flue duct; a hot air conduit within said refractory lining connecting said recuperator to said burner; and means for introducing oxygen containing gases to be heated into said recuperator. |
| 16. | The integrated furnace wall module of Claim 15, wherein; said recuperator is recessed within a groove in said refractory lining and covers substantially the surface of the groove; and said flue duct is formed by a partition comprising refractory material sealed to said refractory lining over said recessed recuperator. |
| 17. | The integrated furnace wall module of Claim 16, wherein: said outer plate comprises connection means for connecting said module to other said integrated furnace wall modules; and the edges of said refractory lining are shaped to mate with the corresponding edges of other said modules to form a seal between said modules to prevent loss of heat between said refractory lining edges when said modules are connected. |
| 18. | The integrated furnance wall module of Claim 17, wherein the edges of said refractory lining are between said recuoerator and said outer metal plate, so that the seal between said connected modules is behind said recuperator to 25 itionally ensure that heat from a furnace thus formed is not lost between the moducles. |
| 19. | A furnace which comprises a Plurality of integrated wall modules as described in Claim 14. |
| 20. | A furnace which comprises a plurality of integrated wall modules as described in Claim 15. |
| 21. | A furnace which comprises a Plurality of integrated wall modules as described in Claim 17. |
| 22. | The integrated furnace wall module of Claim 14, wherein said refractory lining comprises soft refractory fiber material. |
| 23. | The integrated furnace wall module of Claim 22, wherein said flue duct is formed by a recessed groove in said refractory lining with a partition comprising refractory material sealed over the groove in airtight relationship with said refractory lining. |
| 24. | The integrated furnace wall module of Claim 23, wherein said flue duct covers at least twentyfive percent of the surface of the said refractory lining. |
Technical Field
This invention relates to a method and apparatus for waste heat recovery and reduction in 5 industrial furnaces and heating equipment.
Background Art
Three alternative methods for recovery of latent heat of flue gases escaping from high temperature furnace working chamber are common: (a)
10. use of waste heat to preheat combustion air; (b) use of waste heat for initial preheating of the work; and (c) use of hot flue gases for other low temperature operations such as drying or steam generation.
15 All three methods have come into wide use during the past decade. Steadily rising fuel prices have continually lowered the minimum size of furnace which can justify use of these heat recovery methods. Combustion air preheating by
20 recuperation is the most common method in use today because of the relatively low capital and operational costs involved. Recuperation also has the advantage of a good relationship between the availability of waste heat and the need for that
25 heat in the incoming combustion air.
Initially, the general concept of combustion air preheating was accomplished by means of a central external recuperator, hot air ducts and a set of hot air burners for heating the furnace.
30 More recently, the most common choice of heat recovery for industrial furnaces is utilization of an individual recuperator for each hot air burner. This has made it possible to reduce the cost of both recuperators and hot air burners through
volume production. As used in this manner, the recuperator can be either radiative, radiative- convective, or convective. It can be made of metal or refractory materials. Further development of this general concept has resulted in several specific improvements such as self-recuperative burners and side-by-side recuperator-burners, which have the common design approach of reducing the cost of the system by combining the recuperator and burner into one integral unit, eliminating the need for hot air ducting and in some cases reducinσ the amount of insulating material involved. However, these approaches have the obvious limitations of restricted capacity, limited heat recovery and large physical size for a given capacity. Although many self-reσuperative burners have been designed, few are used with success. The major disadvantage of these burners is that positioning the flue outlet very close to the flame envelope results in losing a significant part of the hot combustion product before its heat has been transferred to the load.
Another approach is the internal recuperator, which consists of stainless steel piping located in the existing furnace exhaust flue. Hence, this design uses the exhaust flue as the housing for a bundle of pipes which contain the combustion air being heated. The advantaαe of this approach is the utilization of the flue duct as the housing for the heat-exchanger, but the disadvantages are: a high pressure drop resulting in poor circulation 15 inside the furnace chamber, limited surface area of the heat exchanger and therefo e.reduced heat recovery, a complicated flue channel structure, and low durability of the castable refractory dividing
wall between the flue channel and the furnace 20 chamber.
In addition, it is desirable to prevent the loss of heat through the walls of the furnace, by the use of walls with good insulation.
Historically, this has been accomplished by means such as constructing the walls of the furnace with brick.
The development of new ceramic fiber based insulating materials having high thermal resistance, low density and specific heat made it possible to substitute heavy refractory furnace linings for light metal structures lined with ceramic blanket or blocks. This current improvement has changed the traditional design of furnace walls and has made it possible to fabricate furnace walls with prefabricated modules containing mild steel plate lined with ceramic fiber materials.
Disclosure of Invention
The present invention comprises a method of heat recovery and an apparatus for realization of heat recovery inside of the furnace refractory lining. The method of heat recovery comprises directing the exhaust gases through a system of channels inside the refractory wall where heat from the flue gases is transferred to the refractory lininq and also to the combustion air traveling inside of a heat exchanger also located inside said channels. The high temperature exhaust flue gases traveling along said channels increase the hot face temperature of the refractory wall and reduce the heat flux from the working chamber through the refractory wall.
An apparatus for the realization of the heat recovery method includes a flue duct, a recuperator, hot air piping and a hot air burner, all located inside the furnace wall refractory lining. The flue duct is formed by a multiplicity of channels located inside the refractory wall and directed along the wall. One channel wall is formed by a refractory partition dividing the working zone of the furnace from said channel. The other three channel walls are formed within the lining material by a recuperator structure positioned generally parallel to the walls of said channels. Flue gases which are exhausted from the working chamber of the furnace are directed into said channels and are moved through these channels by positive pressure existing inside the furnace working chamber. Because of the temperature differential between the flue gases and the combustion air in the recuperator, a significant portion of the latent heat of the flue gases is transferred to the combustion air running inside the recuperator. The partition wall dividing the working zone of the furnace from these internal channels is heated'by the flue ases traveling inside the channels. This reduces considerably heat losses from the working zone throuqh the refractory lining wall. Combustion air preheated by the recuperator moves along a hot air duct to a hot air burner. The wall structure- uses the furnace refractory lining as an insulating means for the hot air duct and also for the hot air burner. The hot air burner has a hot air inlet located inside the refractory lined wall.
The recuperative furnace wall may be made as modular units combining all of the elements of the invention. The furnace wall module may be used as
a heating device, for example, for preheating of ladles for molten metal t ansportation, or as a oreheater of tundish for a continuous caster. Different furnaces and heating apparatus can be designed with such multipurpose wall modules.
Another aspect of this invention provides a new heat recovery system for a heating apparatus, such as heat treating furnaces with controlled atmospheres, which is capable of recovering heat from flue gases containing combustible, components by combustion of the exhaust gases inside of the refractory lined wall. The additional heat generated by post-combustion of exhaust gases traveling through the channels positioned inside the refractory lining of furnaces is recovered by the same method and apparatus as described above. A controlled portion of an oxygen containing gas mixture (for example, air) is introduced and mixed with flue gases traveling through the channels inside the refractory lined wall for combustion of combustible components of the flue gases.
Therefore, it is an object of this invention to provide a method and apparatus to provide more effective heat recovery from hot flue gases escaping from furnaces, resulting in more efficient operation of said furnace.
It is another object of this invention to provide a more economical method and apparatus for heat recovery from hot flue gases esσaoinq from a furnace.
It is a further object of this invention to provide a nodular means for heat recovery from hot flue gases which may be adapted for use in a number of designs or types of furnaces and to significantly reduce custom engineering expenses.
Other objects, advantages and novel features of the present invention will become apparent from the following detailed description of the invention when considered in conjunction with the accompanying drawings.
Brief Description of the Drawings
Fig. 1 is a cut-away perspective view of a modular recuperative furnace wall unit according to the present invention. Fig. 2 is a side cross sectional view taken along lines II-II of Fig. 1.
Fig. 3 is a top cross sectional view taken along lines III-III of Fig. 2.
Best Mode for Carrying Out the Invention A modular recuperative furnace wall unit which incorporates the method of this invention is illustrated in Figs. 1 through 3, in which like numbers indicate like parts throughout the several views. The module comprises a metal shell 1 with flanges 2 for joining the modules together. The interior side of the metal shell 1 is lined with ceramic fiber lining 3 which provides insulation for the furnace. The ceramic fiber lining is rated for the temperature ranαe which will exist within the furnace. Slots 4 are formed within said lining and along with a parallel plate recuperator 5 positioned v/ithin said slots 4, and substantially covering the sides of the slot 4 which are formed by the fiber lining 3, define enclosed channel 6 for incoming air to be heated prior to combustion. A refractory partition 7 is placed over said slots 4 and forms a channel 8 for exhaust flue gases which enter channel 8 through openings 9. Vent o p enings 10 are at the top of channels 8 for
discharging flue gases. Cold air conduits 11 are connected to openings 12 to the channels 6 and provide the incoming air to the recuperator 5. The arrows in Figs. 1 through 3 show the flow of the various gases.
The channels 6, 8 and recuperator 5 generally form a U-shape covering substantially the height and width of the module. A hot air conduit 13 is connected at the lower part of channel 6 for delivering preheated air to hot air burner 14. Said hot air conduit 13 connects to the hot air chamber 15, which is located within the refractory lining 3. The burner 14 further comprises a refractory tile 16 located between said hot air chamber 15 and the working furnace chamber, and a fuel inlet pipe 17 for delivery of fuel to the combustion zone 18 of the burner 14.
As mentioned above, the modules are designed to be joined together. By ioining a plurality of such modules together with other appropriately designed modular pieces, including panels of only refractory material and corner pieces, it is seen that a complete furnace can be formed using a multiplicity of wall modules to provide a number of barriers to the furnace, each with the advantages disclosed herein. To provide a good seal between said modules, the embodiment shown in Fig. 3 has the vertical edges of the lining 3 designed so that adjoining module edges intermesh behind the recuperator 5 which provides additional coverinq over the joint.
In operation of the invention as illustrated in Figs. 1-3 one or more of said modules are incorporated as walls of a furnace. The hot flue gases exit from the furnace through opening 9 and travel along channels 8 and then exit the wall
module at vent openings 10. Incoming air is delivered by a blower into conduit 11 and into the incoming air channels 6 at the openings 12. The are travels along said channels 6 where it is heated by heat exchange means whereby heat is transferred from the flue gases in channel 8 through the recuperator 5 to the incoming air. This preheated air moves into the hot air conduit 13 and is introduced into the hot air burner 14. The hot air moves through the hot air .chamber 15 to the burner nozzle 19, where said hot air is combined with fuel delivered through the fuel inlet pipe 17. A flame is formed in said nozzle 19 and introduced within the furnace. In the operation of the hot air burner, the initial ignition of the burner can be made with the pilot 20 and a flame detector 21 may be used for the flame safety system.
In another embodiment, the combustion of the combustible components of the exhaust gases may be arranged inside the flue gas channels 8 by introducing a stream of oxvgen containing gas, such as air or pure oxygen, to be combined with the flue gases. The combustion of the combustible components of the flue gas with the oxygen containing gas will produce additional heat release the temperature of the flue gases. This additional heat will be recovered by the preheating of the combustion air and by heating the refractory partition 7.
From this illustrative embodiment, it can be seen that the invention results in significant improvements in the efficiency of the use of fuels in furnances. First, 'the recuperator, air ducts, and burner body are all within the refractory lining, which acts as insulation and provides more
efficient preheating of combustion air to the burner. Second, the location of the flue qas channels allows the latent heat of the flue gases to shield the working zone of the furnace from heat losses as well as providing additional useful radiative heat flux from the refractory partition between the flue gases and the furnace.
While the embodiments of the invention have been described in association with an industrial furnace application, it will be understood that other apparatus can be arranged and designed with the described wall modules. Moreover, while this invention has been described in detail with particular reference to the preferred embodiments thereof, it will be understood that variations and modifications can be effected within the spirit and scope of the method and apparatus of the invention as described herein before and as claimed.