Rotary Batch Preheater

Abstract

Rotary heat-exchanger for glass batch and/or cullet, comprising a stationary casing having a gas inlet and outlet, and an interior region between the gas inlet and outlet; a chamber positioned in the casing rotatable with respect to the casing and configured to receive batch material or a mixture with cullet; at least one heat exchange tube in the casing in fluid communication with the gas inlet and outlet; a feeder in communication with the chamber and comprising a feeder housing configured to discharge the batch material or mixture of batch material and cullet into the chamber along an infeed length and in contact with the at least one tube; wherein the infeed length is a length effective to heat the batch or mixture with cullet material up to at least 100° C. in the infeed length. A method of preheating glass batch is also disclosed.

Claims

1. A rotary heat-exchanger, comprising: a. a stationary casing having a gas inlet, a gas outlet spaced from said inlet, and an interior region between said gas inlet and said gas outlet; b. a chamber positioned in said stationary casing, said chamber being rotatable with respect to said stationary casing and configured to receive batch material or a mixture of batch and cullet material; c. at least one heat exchange tube in said chamber in fluid communication with said gas inlet and said gas outlet, said at least one heat exchange tube having a first end and a second end spaced from said first end; d. a first tube plate attached to said first end of said at least one tube and a second tube plate attached to said second end of said at least one tube, and an outlet attached to said second tube plate and in communication with said chamber for discharging said batch material or mixture of batch and cullet material; e. a feeder in communication with said chamber, said feeder comprising a feeder housing configured to discharge said batch material or mixture of batch material and cullet into said chamber along an infeed length and in contact with said at least one tube; wherein said infeed length is a length effective to heat said batch or mixture of batch and cullet material up to at least 100° C. in said infeed length.

2. The rotary heat-exchanger of claim 1, further comprising an annular gap between said chamber and said stationary casing that is in fluid communication with said gas inlet and said gas outlet.

3. The rotary heat-exchanger of claim 1, wherein said feeder comprises a screw auger.

4. The rotary heat-exchanger of claim 1, wherein said feeder housing has a slot through which said batch material or mixture of batch material and cullet is discharged and distributed over said infeed length.

5. The rotary heat-exchanger of claim 1, wherein chamber has a total length between said first and second tube plates, and wherein said infeed length is at least ¼ of said total length.

6. The rotary heat-exchanger of claim 1, wherein said feeder comprises a driving force for dispersing said batch material or mixture of batch material and cullet into said chamber along said infeed length.

7. The rotary-heat exchanger of claim 1, wherein said driving force comprises a source of compressed air.

8. A method of preheating a batch or a mixture of batch and cullet, said batch or mixture comprising soda-lime glass comprising soda ash, said method comprising: introducing exhaust gas from a glass melting furnace into a rotary heat exchanger comprising at least one heat exchange tube, a stationary casing having a gas inlet in fluid communication with a source of said exhaust gas, a gas outlet spaced from said gas inlet, and an interior region between said gas inlet and said gas outlet, and a chamber in said interior region having a batch infeed length; causing said exhaust gas to flow through said at least one heat exchange tube; introducing said batch or mixture into said chamber along said infeed length of said chamber and rotating said chamber with respect to said stationary casing to allow said batch or mixture to contact said at least one heat exchange tube to transfer heat from said exhaust gas flowing through said at least one heat exchange tube to said batch or mixture to preheat said batch or mixture, wherein said infeed length is effective to allow said batch or mixture to reach a temperature of at least 100° C. in said infeed length; and discharging the preheated batch or mixture from said chamber.

9. The method of claim 8, wherein said infeed length is effective to form sodium carbonate monohydrate from said soda ash.

10. The method of claim 8, wherein said batch or mixture is introduced into said chamber through a slot in a feeder housing that distributes said batch or mixture over said batch infeed length.

11. The method of claim 8, wherein said batch or mixture is introduced into said chamber with a driving force.

12. The method of claim 11, wherein said driving force comprises a source of compressed air.

13. The method of claim 8, further comprising introducing said preheated batch or mixture to a glass melting furnace.

14. The method of claim 8, wherein said exhaust gas is introduced into a plurality of heat exchange tubes of said rotary heat exchanger, and wherein the rotation of said chamber allows said batch or mixture to contact said plurality of heat exchange tubes to transfer heat from said exhaust gas flowing through said plurality of heat exchange tubes to said batch or mixture to preheat said batch or mixture.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0094] The above and other aspects of the embodiments disclosed herein will now be described in further detail, by way of example only, with reference to the accompanying drawings, in which:

[0095] FIG. 1 is a cross-sectional view of the interior of a preferred embodiment of a rotary batch preheater;

[0096] FIG. 2 is an orthogonal cross-sectional view taken along line A-A of FIG. 1 of the interior of a preferred embodiment of the rotary batch preheater;

[0097] FIG. 3A is a cross-sectional view of a rotating drum chamber in accordance with certain embodiments;

[0098] FIG. 3B is a view of the rotating drum chamber taken along line B-B of FIG. 3A;

[0099] FIG. 4A is an end view of a batch infeed screw assembly in accordance with certain embodiments;

[0100] FIG. 4B is a bottom view of the infeed screw assembly of FIG. 4A;

[0101] FIG. 4C is a cross-sectional view taken along line C-C of FIG. 4B;

[0102] FIG. 5A is a schematic diagram of apparatus in accordance with the prior art;

[0103] FIGS. 5B and 5C are graphs of the batch temperature vs. distance and cumulative heat flux from end of drum along the length of the rotating drum for the apparatus of FIG. 5A;

[0104] FIG. 5D is a schematic diagram of apparatus in accordance with embodiments disclosed herein;

[0105] FIGS. 5E and 5F are graphs of the batch temperature vs. distance and cumulative heat flux from end of drum along the rotating drum for the embodiment of FIG. 5D;

[0106] FIG. 6 is a cross-sectional view of the interior of an alternate embodiment of the rotary batch preheater; and

[0107] FIG. 7 is a graph that shows the stoichiometric amount of water required (as a percentage of the total batch weight) for the formation of SCM from soda ash.

DETAILED DESCRIPTION

[0108] Embodiments disclosed herein concern themselves with the manufacture of soda-lime glass, the most common glass type manufactured. At a glass factory, a variety of raw materials are mixed and then melted in the furnace. The principal ingredients in the manufacture of soda-lime glass are silica sand (SiO.sub.2), limestone (calcium carbonate, CaCO.sub.3), and soda ash (sodium carbonate, Na.sub.2CO.sub.3). In addition, a variety of minor ingredients can be added to promote special properties, including sodium sulfate (Na.sub.2SO.sub.4), carbon (C), gypsum (CaSO.sub.4), aluminum oxide (Al.sub.2O.sub.3), selenium (Se), cerium, cobalt oxide, and others.

[0109] Most glass manufacturing operations assure that batch includes about 3-4% water when introduced to the furnace. If not naturally occurring as a contaminant in the raw materials, glass manufacturing operations often will add water to the batch. This is desirable to reduce dusting during material handling and to prevent segregation of the various batch constituents during handling and charging of the furnace.

[0110] As previously mentioned, a major problem with use of batch preheaters in the glass industry is formation of large agglomerates of batch inside the preheater. It has been discovered that these agglomerates are formed because of the heating of the combination of liquid water with soda ash in the preheater.

[0111] Soda ash will typically comprise 15% to 18% of the total batch mass, with ranges as wide as 12% to 20%. Soda ash is water soluble, hygroscopic, and will form a variety of hydrated forms when contacted with water. When soda ash is mixed with the water some of the soda ash dissolves into the liquid water. If batch with dissolved soda ash is subsequently heated and dried, the dissolved soda ash will leave a solid residue that will act as a cement to agglomerate the various mixture constituents together. This is the cause of agglomeration problems in the prior art batch preheaters.

[0112] When sodium carbonate anhydrous (SCA) is contacted with water, various hydrates can be formed, specifically sodium carbonate monohydrate (SCM), Na.sub.2CO.sub.3.H.sub.2O, sodium carbonate heptahydrate (SCH), Na.sub.2CO.sub.3.7H.sub.2O, and sodium carbonate decahydrate (SCD), Na.sub.2CO.sub.3.10H.sub.2O. When initially contacted with water at room temperature, SCA will dissolve into the water to its saturation concentration of about 32 g/100 ml. This dissolution is exothermic and heats batch material, normally to temperature above 40° C.

[0113] When subsequently heated, as in a batch and cullet preheater, the water will be evaporated and leave behind the SCA solute as a residue. This residue will act as a binder to adhere the grains of the batch material together and form an agglomerate. These agglomerates will clog the preheater device, preventing flow of the batch material and rendering the device inoperable. Formation of such agglomerates is a natural result of the transition of wet batch to dry batch upon heating.

[0114] The other main batch ingredients, silica sand and limestone, are not water soluble. As a result, when they are mixed with water and then heated, the water will evaporate but will not contribute to the residue of dissolved material.

[0115] Embodiments disclosed herein take advantage of several features regarding soda ash/water physicochemical properties, including some or all of the following: [0116] 1) Soda ash readily dissolves into water. Saturation concentration is between 31 and 34.5 g/100 ml depending upon temperature. The dissolution process is exothermic. [0117] 2) When the solution of soda ash and water is cooled to temperature below 32° C., Sodium Carbonate Decahydrate will be formed as a solid substance. [0118] 3) When water with dissolved soda ash is evaporated, the solute residue consists of sodium carbonate monohydrate if the temperature is greater than 35.4° C. [0119] 4) Sodium carbonate is hygroscopic. When anhydrous sodium carbonate is exposed to air temperature above 34.5° C. and with relative humidity greater than 72%, water vapor will be reacted with the sodium carbonate to form sodium carbonate monohydrate. This process is exothermic. [0120] 5) Sodium carbonate monohydrate (SCM) is a stable solid between temperatures of 34.5° C. and 109° C. [0121] 6) SCM thermally decomposes to sodium carbonate and water vapor at temperature above 109° C. The water does not go through a liquid phase. This process is endothermic. [0122] 7) SCM contains 85.48% Na.sub.2CO.sub.3 and 14.52% H.sub.2O by weight.

[0123] FIG. 7 shows the stoichiometric amount of water required (as a percentage of the total batch weight) for the formation of SCM from soda ash. Batches typically contain from 15% to 18% soda ash and from 3% to 4% water. Taking batch with 18% soda ash as an example, stoichiometric conversion of all the soda ash to SCM would consume batch water of 3.1%. Thus, if this batch were made with 4% water, residual water after SCM conversion would be 0.9%.

[0124] As discovered by Slade (U.S. Pat. No. 3,545,988) dry batch which has been treated by exposure to atmospheres with high humidity will transform SCA into SCM as a coating on the silica sand grains. The resulting treated batch exhibits substantially less dust generation during handling processes and in the furnace than untreated batch.

[0125] Another discovery made by the present inventor is that batch which has been treated as described above exhibits more rapid melting in the glass furnace than untreated batch. It is postulated that the SCM coating on the silica sand grains improves the rate of fluxing action for melting of the silica. Soda ash melts at lower temperature than silica, and molten soda ash will serve as flux to melt the silica at lower temperature than pure silica will melt.

[0126] A preferred embodiment is now described with reference to FIG. 1 and FIG. 2. While the description here specifies treatment of batch, it is to be understood that the material being treated could also be a mixture of batch and cullet. Wet batch depicted by arrow 1 is delivered to the inlet 2 of a feed screw housing 29. A screw auger 10 is positioned in the housing 29 and is equipped with a motor drive, not shown, and is rotated to feed batch into a chamber, such as a rotating structure or drum 4. Suitable rotational speeds of the screw auger 10 can be determined by those skilled in the art to achieve the desired infeed rate; the rotational speed of the infeed screw auger 10 will determine the batch throughput of the device. Batch free falls as illustrated at 3 from the feed screw housing 29 onto a surface of existing batch 34 inside rotating structure 4.

[0127] An embodiment of a rotating structure, drum, or chamber 4 alone is depicted in FIG. 3A. In the embodiment shown, the rotating structure or drum 4 rotates relative to stationary casing 88 and comprises a cylindrical shell 63 with tube plates 61 at either end. Suitable dimensions of the rotating structure 4 include a diameter of 1200 mm to 2400 mm, and a length of 2000 mm to 5000 mm. A plurality of tubes 6 are configured to be connected to the tube plates 61 and span the length of the cylindrical shell 63. Although any number of tubes 6 may be used, in some embodiments there may be between 50 to 200 tubes, with inside diameters of 30 mm to 70 mm and outside diameters of 38 to 78 mm, made of a thermally conductive material such as stainless steel or alumina ceramic, for example. Each tube plate 61 includes a plurality of holes respectively aligned with each tube and attached to each tube 6, such as with an external clamp on the tube to keep the tube from sliding out of the hole. The clamp acts as a flange at each end outside the tube plate, and a ceramic fiber gasket may be inserted between the flange and the tube plate to seal the tubes from the batch and gas, but allow them to thermally expand. Preferably each hole is round and has an inside diameter slightly larger than the outside diameter of the tube 6. Each tube plate 61 also may include a centrally located hole 62 with attached centrally disposed collars, the inlet cylinder 15 and outlet cylinder 9. Inlet cylinder 15 and outlet cylinder 9 extend beyond the stationary casing end walls and pass through the openings 84, 85. During start-up, the rotating structure 4 is partially filled with batch material 5 so that some of the tubes 6 are covered, e.g., about ¼ to about ⅓.sup.rd of the tube may be covered. The structure 4 is rotatable in the direction of arrow 7 by a motor and drive, not shown. The rotating assembly is supported by an inlet cylinder 15 and outlet cylinder 9, which may be journaled at 8, to be supported such as on rollers (not shown). The journaling 8 is configured to be radially outside of the stationary casing openings 84 and 85 as seen in FIG. 1. In operation, the structure 4 becomes filled with batch 5. As the structure or drum 4 is rotated, batch contained in the drum 4 is rotated as well until the top surface 11 (FIG. 3B) of the bulk batch reaches the material's angle of repose (the angle at which the material on the slope face is on the verge of sliding). If the batch is dry, the individual grains of batch will slide over the surface 11 down to the lower end of the batch surface 14 (FIG. 2, shown at 12). In this way, the batch material is constantly being contacted with the tubes 6 and the individual grains of batch material are mixed well several times each rotation of the rotating drum chamber 4.

[0128] Returning to FIG. 1, hot furnace exhaust gases 25 enter the stationary casing 88, which may be comprised of a circumferential side wall 22, gas inlet 24, gas inlet annular chamber 86, gas outlet annular chamber or plenum 87 spaced from gas inlet annular chamber or plenum 86, and gas outlet 18. Stationary casing 88 includes spaced annular end walls having central openings 84 and 85. Gases then flow from gas inlet plenum 86 in the direction of arrows 23 through all the tubes 6. They also flow in the direction of arrow 20 through the gap 21 between the rotating structure shell 63 and circumferential side wall 22. Gases exit (in the direction of arrows 19) the tubes 6 and gap 21 into the outlet plenum 87, to outlet 18 and are discharged as shown by arrow 17 from the device. The hot gases heat the thermally conductive surfaces of the tubes 6 and rotating structure shell 63. These hot surfaces are in contact with the batch 5 inside the chamber and heat the batch. Heat is transferred from hot furnace gases 25 to batch 5. Both the batch and the water in the batch are heated as they travel through the rotating structure 4. The outside surfaces of the stationary casing 88 may be covered with insulation 89 to mitigate or prevent heat losses in the overall system.

[0129] FIGS. 4A, 4B and 4C show a preferred mechanism for spreading the batch 5 evenly along the desired infeed length 33 in the rotating structure 4. A slot 30 in the bottom of the feed screw housing 29 is provided that allows batch 5 to pass (shown at 80 in FIG. 4A) through the housing 29 for the desired length 33. In some embodiments, the length of the slot 30 may be about ¼ to ½ of the length of the entire rotating structure 4. The batch 5 does not free flow through the slot 30 due to its moisture content; specifically, the moisture makes the batch 5 bridge over the slot 30. As auger 10 rotates in the housing 29, it continuously presses batch through the slot 30. The width 81 of the slot 30 is set so as to achieve uniform distribution of the batch, usually determined by test operation and adjustment. Typically slot 30 will be of width between ¼″ and 1″ wide. In some instances, the width of the slot 30 need not be uniform; it can be tapered so that it is narrower at one end compared to the other, for example.

[0130] The end 82 of screw housing 29 is typically left open or partially open so that any batch 5 carried by auger 10 that is not pressed through slot 30 is discharged out of the open end of the housing, as shown by element 83.

[0131] As additional batch 5 is fed into the rotating structure 4, the level of batch 5 rises until it spills at 35 over into the outlet cylinder 9. It travels along the bottom of cylinder 9 until it drops at 16 off the end of the cylinder 9. In steady state, the amount of batch 5 exiting at 16 the rotating structure 4 will equal the amount 3 of batch 5 fed into the rotating structure 4.

[0132] The rotating structure 4 and stationary casing 88 can be operated with a horizontal longitudinal axis. Alternatively, the axis may be inclined to horizontal so that gravity will facilitate the flow of batch through the device. In practice the incline angle can vary from 0° to 10° from horizontal.

[0133] In operation, as wet batch at initial temperature 20° C. (e.g., ambient temperature) is heated, the heat input first provides for sensible heating of the wet batch, up to temperature 100° C. For batch with 3% water, the sensible heat required is 68 kJ/kg of batch. After the wet batch is heated to 100° C., additional heat input is used for the latent heat of water evaporation. Again, for batch with 3% water, the latent heat required is 68 kJ/kg of batch.

[0134] FIGS. 5A, 5B and 5C depict prior art as a comparison to the design of the present invention. Prior art teaches feeding the wet material 40 into one end 41 of a rotating structure. FIG. 5C at 42 shows the cumulative heat flux from the hot gases into the batch as a function of distance from the infeed end. The cumulative heat flux steadily increases from 0 at the infeed point up to 100 kW at the end of the shell. The heat flux depends on the detail design of the machine, i.e., number of gas heat transfer tubes, diameter of shell, inlet gas temperature, etc.

[0135] For the example here we specify performance of the machine with batch (with 3% water) infeed rate of 1000 kg/h. The temperature profile of the batch material as it travels through the rotating structure shell is depicted in FIG. 5B, which shows temperature on the vertical axis as a function of distance along the length of the shell. The cold wet batch enters the shell at ambient temperature, taken here at 64 as 20° C. Heat is transferred from the tubes and the wet batch temperature increases in the region depicted by 44 until it reaches 100° C. This sensible heating requires 68 kJ/kg of wet batch, so it corresponds to the point where 19 kW (at 45 in FIG. 5C) of heat has been input from the hot gases. In this section of the shell, termed the wet zone 46 (FIG. 5A), the batch is wet as no water has yet been evaporated. After the wet batch temperature reaches 100° C., any further heat into the material will serve to evaporate water from the batch. Here at 47 in FIG. 5B, the temperature remains at 100° C. while the water evaporates. In this section of the shell, termed the evaporation zone 48 (FIG. 5A), the batch water content will be reduced from its inlet content (3%) to 0%. Complete evaporation of water from batch requires an additional 68 kJ/kg of batch and this point is reached when another 19 kW (for a total of 38 kW (at 49 in FIG. 5C)) of heat has been delivered. In these two zones, the wet zone 46 and the evaporation zone 48, the soda ash will form clumps and cake on the outside of the tubes 6 via the previously described process.

[0136] If the batch material is wet the individual grains of batch will adhere to each other and form clumps inside the device. These clumps will not release from the tubes and instead remain attached to the tubes during operation. Then upon further heating and drying, the clumps would form cakes (hard deposits) on the tubes and prevent efficient heat transfer from the hot gases into the batch.

[0137] The preferred embodiment per the present disclosure is shown in FIGS. 5D, 5E and 5F. Graphs for batch temperature (FIG. 5E) and Cumulative Heat Flux (FIG. 5F) from the end of shell are shown. The wet batch is introduced in a distributed fashion 3 over the infeed length 33. In certain embodiments, the machine is designed so that the infeed length provides a cumulative heat input rate of 39 kW over the infeed length, as shown by 50 in FIG. 5F. With 1000 kg/h of batch throughput, this heat input is enough to provide sensible heating up to 105° C. (72 kJ/kg) and latent heat of water evaporation of 68 kJ/kg. If the infeed is uniformly distributed, then the temperature shown at 51 in FIG. 5E of the entire infeed zone 65 (infeed length plus infeed width) will be 105° C. Then the entire infeed zone 65 will be dry and as such not susceptible to formation of clumps on the tubes. As the batch travels further along the drum through the downstream zone 66, its temperature is further increased by sensible heating from the hot gas tubes 6, as shown at 54 in FIG. 5E.

[0138] To summarize and generalize, if the amount of heat transferred into the batch in the infeed zone 65 exceeds that required to heat batch and water to temperature 51 above 100° C. and to evaporate all the water in the batch, the batch in the infeed zone 65 will be dry and at a temperature above 100° C. Generally, this will result if the infeed length is greater than the length of the wet zone plus the evaporation zone in the corresponding machine with material infeed according to prior art.

[0139] Referring again to FIG. 2, for a typical application, the mass flow rate of batch in the sheet flow 12 will be more than 100 times greater than the mass flow rate of wet batch infeed 3. The infeed 3 material quickly mixes with the sheet flow 12 material to form mixed material 39. For example, with infeed 3 moisture content of 3%, the moisture content of the mixed material 39 will be less than 0.03%. Batch with moisture levels less than 1% have been shown to behave like dry material. So, in accordance with embodiments disclosed herein, the mixed material 39 will behave like dry material and not create clumps or cakes on the tubes 6. This small amount of water is then evaporated using heat already in the batch to form water vapor, as depicted by arrow 28. Then, so long as enough heat is transferred into the batch to maintain its temperature greater than 100° C. in the infeed zone, the entire bulk of batch material will remain dry.

[0140] The interior atmosphere 13 of the rotating structure shell 4 becomes filled with water vapor evaporated from wet batch as described above. Some air may infiltrate into the shell 4 but the resulting interior atmosphere 13 will in general have high relative humidity (e.g., higher than 72%). If this atmosphere 13 has relative humidity greater than 72% then water vapor 38 will react with the SCA in batch 32 in the infeed zone 65 to form SCM. The reaction is exothermic and provides additional heat to the batch, aiding in the desired function to keep all batch in the infeed zone 65 warm and dry. Depending on the balance between amounts of SC and water in the batch, most if not all the liquid water can be converted to SCM in the device and all the SCA can be converted to SCM. As described earlier, this recrystallization of SCA to SCM has two significant benefits to the glass furnace process: [0141] 1. Subsequent handling of the batch will exhibit significantly reduced dust generation. [0142] 2. Subsequent melting of the batch will require shorter melting time and reduced melting energy.

[0143] As the batch travels further downstream in the device, its temperature increases as shown at 54 in FIG. 5E. When the temperature 55 exceeds 109° C. the SCM will begin to dehydrate, releasing the water molecule to form SCA and water vapor 31. This water vapor will pressurize the interior atmosphere 13 of the drum. Water vapor is vented 36 out of the device through the discharge plenum 37 (FIG. 1).

[0144] An alternate embodiment is depicted in FIG. 6. Infeed screw 56 is now just long enough to extend through the inlet cylinder 15. A pipe lance 57 is provided to direct compressed air 58 to discharge 59 from the lance into the batch as the batch discharges from the infeed screw 56. The compressed air serves to disperse the batch and project 60 it over the infeed length 33 of the drum 4. The length of the dispersion can be controlled by the amount of compressed air 58 delivered to the lance 57. Suitable amounts include amounts between 0.5 and 5 free air cfm. If the wet batch is dispersed uniformly over an infeed length 33 long enough that the amount of heat transferred into the batch in the infeed zone 65 exceeds that required to heat batch and water to temperature 51 above 100° C. and to evaporate all the water in the batch, the batch in the infeed zone 65 will be dry and at temperature above 100° C.

[0145] With prior art as depicted in FIG. 5A, a portion of the device is filled with wet material and there will be “wet zones” within the device. In the case of the material being batch, this wet material will have the tendency to form agglomerates or clumps between the tubes. In order to allow this material to release from the tubes, the tubes must be spaced widely apart from each other. For 50mm diameter tubes, this spacing must be, for example, a minimum of 150 mm apart, otherwise agglomerates will wedge between the tubes and fail to be carried through the device to the outlet. 50 mm diameter tubes spaced 150 mm apart results in 200 mm between centers of the tubes.

[0146] Dry batch exhibits a free-flowing characteristic, much like sand in an hourglass. It can flow through structures easily so long as the gap is wider than the piece of batch itself. With the embodiment described herein, there are no “wet zones”. As a result, the spacing between the tubes can be much less without the aforementioned problem with agglomerate formation between the tubes. For 50 mm diameter tubes the spacing between tubes can be as low as 50 mm. This results in 100 mm between centers of the tubes.

[0147] The amount of heat transferred from the hot gases to the batch and/or cullet is directly proportional to the amount of heat transfer area provided in the device, in this case the surface area of the tubes. With the 50 mm spacing enabled by the embodiment described herein, 4 times the number of tubes can be provided in the rotating structure, compared to the number of tubes that could be provided using prior art. Thus 4 times the heat transfer surface is provided in the same size device as prior art. In practice this manifests itself as higher batch temperature out of the device, a smaller and less expensive device, or a combination of the two.

[0148] When cullet is included with batch in the device, the tube spacing must be larger than the largest size piece of cullet. Cullet crushers can sometimes be provided to achieve the optimum size cullet for the device. A typical cullet size specification for a conventional modern crusher is 40 mm maximum size. Such cullet could be handled in the embodiment described herein with 50 mm tube spacing.

[0149] Additionally, the design of the embodiment described here with no “wet zones” will have lower maintenance requirements, as most maintenance is associated with cleaning and removing of accumulated agglomerates inside the device. Experience with the embodiment described herein is that the tubes are maintained in a “bare metal” condition.

EXAMPLE

[0150] Typical machine operation is described below.

[0151] A rotary heat exchanger with rotating chamber of diameter 2100 mm and length of 3650 mm is fitted with 204 tubes. Tubes are 60 mm diameter. The stationary casing is 2150 mm inner diameter so as to provide a gap of 25 mm between the rotating chamber and the stationary casing. Such a device presents 142 square meters of heat transfer area associated with the tubes. The rotary heat exchanger is inclined at an angle of 3° to the horizontal to facilitate batch movement. The chamber rotates at 5 rotations per minute.

[0152] 9000 kg/h of wet batch (with 3% moisture) at temperature 20° C. is fed into the chamber by a cantilevered screw feeder. The cantilevered screw feeder has a 1500 mm long slot hole cut in its bottom to provide an infeed length of 1500 mm, comprising 41% of the rotating chamber length. Batch infeed is uniformly distributed along the infeed length.

[0153] Hot furnace exhaust gases at 550° C. are introduced to the heat exchanger inlet and are cooled to 350° C. at the gas outlet. After steady state is reached, 9000 kg/h of batch exits the heat exchanger at temperature of 370° C. Visual observation confirms that there are no “wet zones” within the heat exchanger and no clumps or agglomerates are formed. The heat transfer rate calculates to be 41 W/m.sup.2-° K based on the tube surface area.

[0154] The same size device built with rotating chamber according to prior art would include 52 tubes. Wet batch is fed into the rotating chamber at one end. This design presents 36 square meters of heat transfer area associated with the tubes. Such device would manifest a “wet zone” comprising about 60% of the length of the chamber. In this wet zone, clumps would form and stick inside the chamber and after a short time the machine would have to be shut down. The agglomerates would block the infeed end of the rotating chamber and prevent additional infeed of wet batch. Even if it could avoid clump formation, the device would only heat the cullet/batch mix to 175° C. at the same heat transfer rate of 41 W/m.sup.2-° K.