CA2331165A1 - Electrostatic batch preheater - Google Patents
Electrostatic batch preheater Download PDFInfo
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- CA2331165A1 CA2331165A1 CA002331165A CA2331165A CA2331165A1 CA 2331165 A1 CA2331165 A1 CA 2331165A1 CA 002331165 A CA002331165 A CA 002331165A CA 2331165 A CA2331165 A CA 2331165A CA 2331165 A1 CA2331165 A1 CA 2331165A1
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- Prior art keywords
- batch material
- batch
- tunnel
- gases
- glass
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Classifications
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B3/00—Charging the melting furnaces
- C03B3/02—Charging the melting furnaces combined with preheating, premelting or pretreating the glass-making ingredients, pellets or cullet
- C03B3/023—Preheating
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B3/00—Charging the melting furnaces
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/50—Glass production, e.g. reusing waste heat during processing or shaping
Abstract
A method for heating glass batch materials before use in a glass melting furnace, the glass batch material comprising solid particle raw materials or cutlet, or a mixture of the two, the method comprising the steps of:
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material; and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material; and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
Description
ELECTROSTATIC BATCH PREHEATER
The invention relates to a method and apparatus for preheating raw materials for glass production using waste heat from the glass melting process. The invention uses electrostatic forces to improve the performance of conventional methods of preheating glass batch materials. Additionally, the electrostatic forces act to remove fine particulate matter from the glass furnace exhaust gases, thus achieving simultaneous pollution emission reduction.
Glass is made by heating and melting a mixture of solid raw materials to a liquid state. The melting is done inside of a furnace and necessarily requires substantial amounts of heat. Typically, this heat is generated by the combustion of fossil fuels with the exhaust gases from the combustion leaving the furnace. Exhaust gas temperatures immediately after the furnace are quite high, typically 1300°C-1450°C.
Combustion air preheaters are normally included which recover some of the heat in these gases. Even so, gas temperatures at the discharge to atmosphere are quite high, thus substantial amounts of heat are wasted. The cost of fuel for the furnace is a major component in the cost of making glass.
The raw materials for glass are typically called batch. The word frit generally refers to an assemblage of various pulverous materials including silica sand, limestone, soda ash, salt cake, and a variety of other minor ingredients. The material and mixture ratios are carefully chosen to produce glass of the desired properties and quality. Generally these materials are prepared in a finely divided form to promote their melting rates. Sizes are typically 100 to 200 ~.m diameter with a maximum size of 1 mm. Also, recycled glass, either from the factory or from external sources, is used as a raw material. This recycled glass is called cutlet. For ease of handling cutlet is generally crushed to sizes less than 50 mm before use in the glass furnace.
Sometimes, cutlet is pulverised to sizes similar to the other raw materials.
For the purpose of further description, the word batch will be used to mean frit alone, cutlet alone, or a mixture of frit and cutlet, the cutlet being either crushed or pulverised.
The invention relates to a method and apparatus for preheating raw materials for glass production using waste heat from the glass melting process. The invention uses electrostatic forces to improve the performance of conventional methods of preheating glass batch materials. Additionally, the electrostatic forces act to remove fine particulate matter from the glass furnace exhaust gases, thus achieving simultaneous pollution emission reduction.
Glass is made by heating and melting a mixture of solid raw materials to a liquid state. The melting is done inside of a furnace and necessarily requires substantial amounts of heat. Typically, this heat is generated by the combustion of fossil fuels with the exhaust gases from the combustion leaving the furnace. Exhaust gas temperatures immediately after the furnace are quite high, typically 1300°C-1450°C.
Combustion air preheaters are normally included which recover some of the heat in these gases. Even so, gas temperatures at the discharge to atmosphere are quite high, thus substantial amounts of heat are wasted. The cost of fuel for the furnace is a major component in the cost of making glass.
The raw materials for glass are typically called batch. The word frit generally refers to an assemblage of various pulverous materials including silica sand, limestone, soda ash, salt cake, and a variety of other minor ingredients. The material and mixture ratios are carefully chosen to produce glass of the desired properties and quality. Generally these materials are prepared in a finely divided form to promote their melting rates. Sizes are typically 100 to 200 ~.m diameter with a maximum size of 1 mm. Also, recycled glass, either from the factory or from external sources, is used as a raw material. This recycled glass is called cutlet. For ease of handling cutlet is generally crushed to sizes less than 50 mm before use in the glass furnace.
Sometimes, cutlet is pulverised to sizes similar to the other raw materials.
For the purpose of further description, the word batch will be used to mean frit alone, cutlet alone, or a mixture of frit and cutlet, the cutlet being either crushed or pulverised.
Glass furnaces emit various pollutants with their exhaust gases, most commonly particulate matter (fine dust) and S02. The particulate matter is especially difficult to collect because it is of diameter less that 1 ~m and the exhaust gas temperatures are high. Typically very large electrostatic precipitators are utilised, often preceded by absorption towers for chemical reaction of various reagents with the S02 pollution.
Other gaseous pollutants are sometimes present, specifically, HF and HCI acid gases. Many local regulations require reduction of the amounts of these pollutants that are emitted to the atmosphere.
US Patent Specification No. 4 696 690 described a device in which furnace exhaust gases are passed through "flow ducts" inside a batch bunker. The upper half of the flow ducts are formed by equal sided angle sections arranged to form a roof like structure inside the bunker. The angles provide an open bottom and the batch itself forms the bottom half of the flow duct, due to its angle of repose under the roof.
Batch is introduced to the bunker through its open top. The batch is moved downward by gravity, thus providing continuously renewed surfaces in the flow ducts that are exposed to the furnace exhaust gases. Heat is transferred to the batch primarily because of the direct contact with the hot gases.
The flow ducts are arranged in horizontal banks, with the furnace gas divided to flow through the ducts of a given bank in parallel. Multiple banks of flow ducts are provided one above another and internal tunnels are provided to direct the flow successively from the lower banks to the upper banks. The result is to achieve a countercurrent flow of hot gases with the downward moving batch in the bunker.
Batch is fed out of the device through a nozzle as controlled by a conventional device such as a vibratory, screw, or other mechanical type feeder.
Other gaseous pollutants are sometimes present, specifically, HF and HCI acid gases. Many local regulations require reduction of the amounts of these pollutants that are emitted to the atmosphere.
US Patent Specification No. 4 696 690 described a device in which furnace exhaust gases are passed through "flow ducts" inside a batch bunker. The upper half of the flow ducts are formed by equal sided angle sections arranged to form a roof like structure inside the bunker. The angles provide an open bottom and the batch itself forms the bottom half of the flow duct, due to its angle of repose under the roof.
Batch is introduced to the bunker through its open top. The batch is moved downward by gravity, thus providing continuously renewed surfaces in the flow ducts that are exposed to the furnace exhaust gases. Heat is transferred to the batch primarily because of the direct contact with the hot gases.
The flow ducts are arranged in horizontal banks, with the furnace gas divided to flow through the ducts of a given bank in parallel. Multiple banks of flow ducts are provided one above another and internal tunnels are provided to direct the flow successively from the lower banks to the upper banks. The result is to achieve a countercurrent flow of hot gases with the downward moving batch in the bunker.
Batch is fed out of the device through a nozzle as controlled by a conventional device such as a vibratory, screw, or other mechanical type feeder.
Such devices have been successfully and reliably operated, but have found limited applicability in the glass industry. Preheating of batch and reduced fuel consumption of the furnace have been well demonstrated. As well, partial removal of S02, HCI, and HF has been realised. The fundamental limitation of the device is that dust from the batch material is entrained in the furnace gases flowing through the flow ducts.
This entrainment can be minimised by reducing the gas flow velocity in the ducts, but such an approach greatly increases the size and cost of the device. Typically, electrostatic precipitators have been installed downstream of the device, in order to capture the entrained dust and prevent its release to atmosphere. However, such an amalgamation results in an expensive overall installation. The economic benefits of preheating the batch materials cannot justify the full installation cost of the equipment.
What is needed is an improvement to the device to allow it to operate without entrainment of dust. Furthermore, in cases where the glass manufacturing process is faced with governmental legislation to reduce pollutant emissions from the furnace, a device capable of simultaneous particulate matter and S02 removal from the furnace exhaust gases to meet these regulations would eliminate the need for additional pollution control equipment. Then, the process of this invention would result in an overwhelming economic justification for installation. This is the motivation and result of the invention described here.
In view of the foregoing, the following are objectives or benefits of the described embodiment of the present invention:
1. Preheat batch material for use in a glass-melting furnace using heat from the furnace exhaust gases by direct contact with the gases.
2. Eliminate carryover of dust with the gases leaving the direct contact process.
3. Simultaneously remove fine particulate matter from the incoming gases, thus achieving a reduction of a pollution emission.
This entrainment can be minimised by reducing the gas flow velocity in the ducts, but such an approach greatly increases the size and cost of the device. Typically, electrostatic precipitators have been installed downstream of the device, in order to capture the entrained dust and prevent its release to atmosphere. However, such an amalgamation results in an expensive overall installation. The economic benefits of preheating the batch materials cannot justify the full installation cost of the equipment.
What is needed is an improvement to the device to allow it to operate without entrainment of dust. Furthermore, in cases where the glass manufacturing process is faced with governmental legislation to reduce pollutant emissions from the furnace, a device capable of simultaneous particulate matter and S02 removal from the furnace exhaust gases to meet these regulations would eliminate the need for additional pollution control equipment. Then, the process of this invention would result in an overwhelming economic justification for installation. This is the motivation and result of the invention described here.
In view of the foregoing, the following are objectives or benefits of the described embodiment of the present invention:
1. Preheat batch material for use in a glass-melting furnace using heat from the furnace exhaust gases by direct contact with the gases.
2. Eliminate carryover of dust with the gases leaving the direct contact process.
3. Simultaneously remove fine particulate matter from the incoming gases, thus achieving a reduction of a pollution emission.
4. Simultaneously remove gaseous pollutants, which might be components of the incoming gas, from the incoming gases by chemical reaction with a constituent of the batch and formation of a solid reaction product.
5. Optimise efficiency of the process by operating with high gas velocity and countercurrent flow of gas and solids.
One aspect of the invention in which these objectives or benefits can generally be achieved is directed to a method for heating glass batch materials before use in a glass melting furnace, the glass batch material comprising solid particle raw materials or Gullet, or a mixture of the two, the method comprising the steps of:
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a (free) surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material;
and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material Preferably the top portion of the tunnel comprises electrically conducted plates forming a roof within the bulk material and in contact with the batch material.
Preferably also, the roof is arranged so that the bottom portion of the~tunnel comprises batch material residing at its gravitational angel of repose beneath the roof. .
Preferably, unheated batch material can be supplied to the top of the hopper.
Preferably also, heated batch material can be removed from the bottom of the hopper so that the batch material moves through the hopper by action of gravity.
The tunnel is advantageously of cylindrical shape and preferably is generally horizontally disposed within the hopper.
Another aspect of the present invention is directed to an apparatus for carrying out the foregoing method.
In another embodiment of the invention, fine dust pollutants in the gases are removed from the gases by electrostatic precipitation onto the inside of the flow tunnels, including precipitation directly onto the batch surface, and are subsequently removed from the hopper along with the batch material.
In still another embodiment of the invention, gaseous pollutants introduced with the gases are chemically reacted with a constituent of the batch material to form a solid reaction product that is removed from the hopper with the batch material.
In still another embodiment of the invention, a plurality of such tunnels is provided, the gases are first introduced to the tunnels near the bottom of the hopper and are finally removed from tunnels near the top of the hopper. Gases are directed to flow successively through the tunnels, or banks of tunnels, from the bottom to the top of the hopper. The batch is introduced at the top and removed from the bottom of the hopper so that the gas and batch flow in direction generally countercurrent to each other.
One aspect of the invention in which these objectives or benefits can generally be achieved is directed to a method for heating glass batch materials before use in a glass melting furnace, the glass batch material comprising solid particle raw materials or Gullet, or a mixture of the two, the method comprising the steps of:
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a (free) surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material;
and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material Preferably the top portion of the tunnel comprises electrically conducted plates forming a roof within the bulk material and in contact with the batch material.
Preferably also, the roof is arranged so that the bottom portion of the~tunnel comprises batch material residing at its gravitational angel of repose beneath the roof. .
Preferably, unheated batch material can be supplied to the top of the hopper.
Preferably also, heated batch material can be removed from the bottom of the hopper so that the batch material moves through the hopper by action of gravity.
The tunnel is advantageously of cylindrical shape and preferably is generally horizontally disposed within the hopper.
Another aspect of the present invention is directed to an apparatus for carrying out the foregoing method.
In another embodiment of the invention, fine dust pollutants in the gases are removed from the gases by electrostatic precipitation onto the inside of the flow tunnels, including precipitation directly onto the batch surface, and are subsequently removed from the hopper along with the batch material.
In still another embodiment of the invention, gaseous pollutants introduced with the gases are chemically reacted with a constituent of the batch material to form a solid reaction product that is removed from the hopper with the batch material.
In still another embodiment of the invention, a plurality of such tunnels is provided, the gases are first introduced to the tunnels near the bottom of the hopper and are finally removed from tunnels near the top of the hopper. Gases are directed to flow successively through the tunnels, or banks of tunnels, from the bottom to the top of the hopper. The batch is introduced at the top and removed from the bottom of the hopper so that the gas and batch flow in direction generally countercurrent to each other.
The invention can be advantageously used to preheat the batch using heat from the exhaust gases. By preheating these materials before they are introduced to the furnace, the amount of fuel required for heating and melting them in the furnace can be reduced. This fuel reduction can represent a substantial economic benefit to the glass making process and also reduces the emission of the so-called green house gases (such as NOx and C02 ) simply because less fuel is burned. Simultaneous with this preheating, pollutant emissions such as fine dust, S02 , HCI, and HF
can be reduced with high efficiency to satisfy stringent regulations. S02 , HCI, and HF
emissions can be reduced because most glass batch contains substantial amounts of material which is chemically reactive with these acid gases, specifically soda ash (Na2C03) and limestone (CaC03).
Fossil fuel fired glass furnaces are of several different designs. When air is combusted with fuel, the air is typically preheated in regenerative or recuperative heat exchangers, utilising some of the waste heat exiting the furnace. As well, nominally pure oxygen can also be used for combustion, in which case no waste heat recovery equipment is typically involved.
While the invention could be advantageously applied to any of the glass production schemes, its benefits are greatest in the case of oxygen-fuel fired furnaces.
This is because exhaust gas temperatures are higher, thus batch can be preheated to high temperatures, and because reduction in fuel requirements for the furnace is accompanied by a proportional reduction in the oxygen supply (and thus cost) for the furnace.
The above and other aspects of the present invention will now be described in further detail, by way of example only, with reference to the accompanying drawings, in which:
Figure 1 is a cut-away perspective view of a preferred embodiment of a preheater in accordance with the present invention;
Figure 2 is a cross sectional view of the interior of the preferred embodiment;
Figures 3A and 3B are detailed views of the cross section of a single tube showing electrical current flows;
Figures 4A and 4B are detailed cross sectional views of alternate designs for the tubes;
Figure 5 is a detailed cross sectional view showing alternate design of discharge electrode and gas flow pattern; and Figure 6 is a process flow diagram showing application of the preferred embodiment to a glass melting furnace.
An electrostatic batch preheater (or E-batch preheater) in accordance with the invention is depicted in Figure 1, which is a perspective cut-away view of the device:
A bulk quantity of glass batch material (not shown in Figure 1 ) fills a hopper 1. The hopper will generally have a square or rectangular plan view cross section 2.
At the bottom of the hopper, a second pyramid shaped discharge hopper 3 allows for material discharge 24 via feeder 4 to produce a substantially uniform flow of the material in the hopper. Such technology for achieving " mass flow" in hoppers is well known in the art. Batch material is uniformly supplied at 17 across the top of the hopper by conventional silo and material handling means. Generally, the hopper 1 is maintained in a full condition.
Rows 5 of internal flow tunnels 22 are created inside the main hopper by providing specially designed structures that are best understood with additional reference to Figure 2. Figure 2 is a cross sectional view of the interior of hopper 1.
Horizontal open bottom tubes 6 form the open tunnels 22 in the bulk quantity of batch material 20. Batch material fills below the tube at its natural angle of repose to form a surface 7, thus the batch material itself completes the tube circumference. Figure 2 shows a hexagonal tube design, with the batch material forming two flat surfaces 7 at its bottom. The two top 8 and two side 9 surfaces of the hexagon are typically metallic plates. The material angle of repose is typically about 30° from the horizontal, so the use of hexagonal geometry maintains good symmetry of the entire flow tunnel.
The symmetry is important for the uniform generation of corona discharge within the tunnels as will be explained later. Other tube geometries could also be used effectively, such as circular cylindrical.
The tubes are extended to a wall 10 of the main hopper and a suitable hole 11 is cut into the hopper wall to allow communication of each tunnel interior with the outside of the hopper for flow of gases. Both ends of the tubes are so constructed, thus allowing a free passage for gas flow through the entire width of hopper 1.
Many such rows of tubes are typically provided.
Plenum structures 12, 13, and 14 are provided exterior to the hopper and they allow for the desired routing of gas flow through the device. Hot gases 15 from the glass furnace are directed to the inlet plenum 12 via inlet pipe 56. This inlet plenum 12 encloses several rows of the flow tunnels. This assemblage of rows of tunnels is termed a bank of tunnels. The plenum design is made so that the gases divide approximately equally and flow through all the tunnels of a given bank enclosed by the plenum. After the gases flow through this initial bank of tunnels, a.
second plenum 13 is provided to gather the gases and then direct them to another bank of tunnels immediately above the first. After passage through this second bank of tunnels, the gases collect in the outlet plenum 14. Cooled gases 16 are then discharged from the device via outlet duct 57.
Although only two banks of tunnels are shown in Figure 1, in practical use, several such banks of tunnels can be provided at successively higher levels in the hopper.
Additional plenums will direct gases to flow successively through the additional banks of tunnels.
can be reduced with high efficiency to satisfy stringent regulations. S02 , HCI, and HF
emissions can be reduced because most glass batch contains substantial amounts of material which is chemically reactive with these acid gases, specifically soda ash (Na2C03) and limestone (CaC03).
Fossil fuel fired glass furnaces are of several different designs. When air is combusted with fuel, the air is typically preheated in regenerative or recuperative heat exchangers, utilising some of the waste heat exiting the furnace. As well, nominally pure oxygen can also be used for combustion, in which case no waste heat recovery equipment is typically involved.
While the invention could be advantageously applied to any of the glass production schemes, its benefits are greatest in the case of oxygen-fuel fired furnaces.
This is because exhaust gas temperatures are higher, thus batch can be preheated to high temperatures, and because reduction in fuel requirements for the furnace is accompanied by a proportional reduction in the oxygen supply (and thus cost) for the furnace.
The above and other aspects of the present invention will now be described in further detail, by way of example only, with reference to the accompanying drawings, in which:
Figure 1 is a cut-away perspective view of a preferred embodiment of a preheater in accordance with the present invention;
Figure 2 is a cross sectional view of the interior of the preferred embodiment;
Figures 3A and 3B are detailed views of the cross section of a single tube showing electrical current flows;
Figures 4A and 4B are detailed cross sectional views of alternate designs for the tubes;
Figure 5 is a detailed cross sectional view showing alternate design of discharge electrode and gas flow pattern; and Figure 6 is a process flow diagram showing application of the preferred embodiment to a glass melting furnace.
An electrostatic batch preheater (or E-batch preheater) in accordance with the invention is depicted in Figure 1, which is a perspective cut-away view of the device:
A bulk quantity of glass batch material (not shown in Figure 1 ) fills a hopper 1. The hopper will generally have a square or rectangular plan view cross section 2.
At the bottom of the hopper, a second pyramid shaped discharge hopper 3 allows for material discharge 24 via feeder 4 to produce a substantially uniform flow of the material in the hopper. Such technology for achieving " mass flow" in hoppers is well known in the art. Batch material is uniformly supplied at 17 across the top of the hopper by conventional silo and material handling means. Generally, the hopper 1 is maintained in a full condition.
Rows 5 of internal flow tunnels 22 are created inside the main hopper by providing specially designed structures that are best understood with additional reference to Figure 2. Figure 2 is a cross sectional view of the interior of hopper 1.
Horizontal open bottom tubes 6 form the open tunnels 22 in the bulk quantity of batch material 20. Batch material fills below the tube at its natural angle of repose to form a surface 7, thus the batch material itself completes the tube circumference. Figure 2 shows a hexagonal tube design, with the batch material forming two flat surfaces 7 at its bottom. The two top 8 and two side 9 surfaces of the hexagon are typically metallic plates. The material angle of repose is typically about 30° from the horizontal, so the use of hexagonal geometry maintains good symmetry of the entire flow tunnel.
The symmetry is important for the uniform generation of corona discharge within the tunnels as will be explained later. Other tube geometries could also be used effectively, such as circular cylindrical.
The tubes are extended to a wall 10 of the main hopper and a suitable hole 11 is cut into the hopper wall to allow communication of each tunnel interior with the outside of the hopper for flow of gases. Both ends of the tubes are so constructed, thus allowing a free passage for gas flow through the entire width of hopper 1.
Many such rows of tubes are typically provided.
Plenum structures 12, 13, and 14 are provided exterior to the hopper and they allow for the desired routing of gas flow through the device. Hot gases 15 from the glass furnace are directed to the inlet plenum 12 via inlet pipe 56. This inlet plenum 12 encloses several rows of the flow tunnels. This assemblage of rows of tunnels is termed a bank of tunnels. The plenum design is made so that the gases divide approximately equally and flow through all the tunnels of a given bank enclosed by the plenum. After the gases flow through this initial bank of tunnels, a.
second plenum 13 is provided to gather the gases and then direct them to another bank of tunnels immediately above the first. After passage through this second bank of tunnels, the gases collect in the outlet plenum 14. Cooled gases 16 are then discharged from the device via outlet duct 57.
Although only two banks of tunnels are shown in Figure 1, in practical use, several such banks of tunnels can be provided at successively higher levels in the hopper.
Additional plenums will direct gases to flow successively through the additional banks of tunnels.
As batch material 20 is fed out 24 of the bottom of the device via feeder 4, the entire bulk of batch material in the hopper moves 19 in a creeping fashion in the hopper and past the tunnels. This motion results in a continuous renewal of the surface 7 of batch material exposed on the inside of the flow tunnel. If alternate rows of the tunnels are provided with staggered centres, as shown in Figure 2, the complete volume of batch material can be exposed to hot gases as the material flows through the hopper. Heat from the gases is transferred to the batch material by this direct contact. As well, S02, HCI, and HF are chemically reacted, with constituents of the batch material to form solid reaction products. In this way, these gaseous pollutants are removed from the furnace gases.
A fundamental limitation of the prior art is the fact that any batch material supplied to the hopper will contain a certain amount of fine dust. When this fine dust is contacted with the flowing gases in the tunnels, the dust is entrained in gas flow and carried out of the hopper. Gases 16 exiting the device show a substantial loading of dust carried over from the batch in the device. This carryover is not acceptable, as its discharge to atmosphere constitutes a pollution emission.
Furthermore, the heat transfer rate from gas to batch is relatively low, thus necessitating a relatively large device. In order to minimise the above mentioned dust carryover, gas velocities in the tunnel must be kept low. Such low flow velocities exhibit a gas flow pattern with a significant "boundary layer" of very low gas velocity near the surfaces of the tunnel. Essentially, heat must diffuse through this boundary layer of nearly stagnant gas in order to heat the batch. This is the primary limitation on heat transfer rate of the device. This aspect forces the process designer to provide a very large device to achieve the desired batch preheating, thus the cost of the unit is high.
The mass transfer rate of pollutant gases to contact the surface of the batch material is low for similar reasons, thus the removal efficiency of gaseous pollutants is generally less than to achieve outlet levels less than those mandated by governmental authorities.
A fundamental limitation of the prior art is the fact that any batch material supplied to the hopper will contain a certain amount of fine dust. When this fine dust is contacted with the flowing gases in the tunnels, the dust is entrained in gas flow and carried out of the hopper. Gases 16 exiting the device show a substantial loading of dust carried over from the batch in the device. This carryover is not acceptable, as its discharge to atmosphere constitutes a pollution emission.
Furthermore, the heat transfer rate from gas to batch is relatively low, thus necessitating a relatively large device. In order to minimise the above mentioned dust carryover, gas velocities in the tunnel must be kept low. Such low flow velocities exhibit a gas flow pattern with a significant "boundary layer" of very low gas velocity near the surfaces of the tunnel. Essentially, heat must diffuse through this boundary layer of nearly stagnant gas in order to heat the batch. This is the primary limitation on heat transfer rate of the device. This aspect forces the process designer to provide a very large device to achieve the desired batch preheating, thus the cost of the unit is high.
The mass transfer rate of pollutant gases to contact the surface of the batch material is low for similar reasons, thus the removal efficiency of gaseous pollutants is generally less than to achieve outlet levels less than those mandated by governmental authorities.
The inventive aspect of the E-batch preheater is now further described.
Each of the tunnels is provided with a discharge electrode 18 axially aligned and centrally located within the tunnel. A simple wire is shown, but other designs incorporating sharp points for generation of corona may be used. The wires 18 for a given bank of tunnels are connected together at either end by brackets 50 and electrical insulators 51 support the brackets. Such insulators are typically of ceramic construction. Similar brackets (not shown) are provided in plenum 13. The wires and brackets are thus electrically isolated from the plenums 12, 13, 14 and hopper 1.
Such arrangements and designs of brackets and insulators are well known to those skilled in the art of electrostatic precipitation.
A high voltage DC power supply 57 is connected 58 to the brackets via the bracket extension 59 through the support insulator. One power supply can be used for the entire unit, or alternatively, separate power supplies can be supplied for each bank of tunnels. The hopper is electrically grounded 60. The electrically conducive plates 8 and 9 of each tube are connected to the hopper wall 10 and thus are also electrically grounded.
The high voltage DC power supply 57 serves to apply a high voltage to the discharge electrodes 18. Application of high voltage of sufficient magnitude to the discharge electrode 18 will produce a corona discharge 52 inside of the tunnel as depicted in Figure 2. The corona discharge is well known to those skilled in the art, so extensive description of the corona process is not necessary. The corona process produces a flow of gaseous ions from the discharge electrode towards the grounded surfaces surrounding the electrode. The metallic tube is electrically conductive and is grounded, so it provides an easy path for the ions to flow to ground.
It has been found that the corona discharge ion flow can also be directed towards the batch material surfaces 7 of the tunnel. These ions 53 then flow through the bulk of the batch material into the metal tubes and then to ground as depicted in Figure 3A. This can occur provided the batch material is of sufficiently low electrical resistivity, as is the case of Figure 3A. However, if the batch material were of high electrical resistivity, as depicted in Figure 3B, electrical current could not flow through the batch. The ions from the corona would then produce a build up of electrostatic charges 54 on the batch surface. Since a negative corona discharge polarity is normally used in electrostatic precipitation, the example here uses negative polarity. The same operation and analysis would also apply for positive polarity. This charge build-up would then prevent the continued flow of ions to the batch.
In the case of high resistivity, the electrostatic charge build-up 54 would quench the corona discharge, and the flow of corona gaseous ions would stop. This would produce a quiescent region 55 in the tunnel that would be free of corona discharge ion flow. However, corona discharge ion flow would continue in the regions adjacent, to the electrically conductive plates 8 and 9 as depicted in Figure 3B. If the resistivity of batch material were very high, such charge build-up would result in the well-known "back-corona" effect that can plague operation of electrostatic precipitators.
At these very high resistivities, the charge build-up 53 is so great that a secondary corona discharge is generated from the surface of the resistive material, emitting positive ions into the gas. These positive ions will flow back towards electrode 18 and effectively cancel out the normal negative corona discharge ion flow. In such cases, the electrostatic precipitator exhibits tremendously increased spark-over rates at reduced voltages. Precipitation performance is dramatically reduced.
Generally, the limiting bulk electrical resistivity for this phenomenon is about 1 OB S2-meter.
In the case where the electrical resistivity is not too high, gaseous ions 52 from the corona discharge flow through the surface of the batch 7 in the tunnel, the resulting current flow 53 through the material generates an electrical field that is aligned with the current flow. It is well understood that the electric field generated in the batch material is related to the current flow density and the bulk electrical resistivity of the batch material by Ohm's law:
Each of the tunnels is provided with a discharge electrode 18 axially aligned and centrally located within the tunnel. A simple wire is shown, but other designs incorporating sharp points for generation of corona may be used. The wires 18 for a given bank of tunnels are connected together at either end by brackets 50 and electrical insulators 51 support the brackets. Such insulators are typically of ceramic construction. Similar brackets (not shown) are provided in plenum 13. The wires and brackets are thus electrically isolated from the plenums 12, 13, 14 and hopper 1.
Such arrangements and designs of brackets and insulators are well known to those skilled in the art of electrostatic precipitation.
A high voltage DC power supply 57 is connected 58 to the brackets via the bracket extension 59 through the support insulator. One power supply can be used for the entire unit, or alternatively, separate power supplies can be supplied for each bank of tunnels. The hopper is electrically grounded 60. The electrically conducive plates 8 and 9 of each tube are connected to the hopper wall 10 and thus are also electrically grounded.
The high voltage DC power supply 57 serves to apply a high voltage to the discharge electrodes 18. Application of high voltage of sufficient magnitude to the discharge electrode 18 will produce a corona discharge 52 inside of the tunnel as depicted in Figure 2. The corona discharge is well known to those skilled in the art, so extensive description of the corona process is not necessary. The corona process produces a flow of gaseous ions from the discharge electrode towards the grounded surfaces surrounding the electrode. The metallic tube is electrically conductive and is grounded, so it provides an easy path for the ions to flow to ground.
It has been found that the corona discharge ion flow can also be directed towards the batch material surfaces 7 of the tunnel. These ions 53 then flow through the bulk of the batch material into the metal tubes and then to ground as depicted in Figure 3A. This can occur provided the batch material is of sufficiently low electrical resistivity, as is the case of Figure 3A. However, if the batch material were of high electrical resistivity, as depicted in Figure 3B, electrical current could not flow through the batch. The ions from the corona would then produce a build up of electrostatic charges 54 on the batch surface. Since a negative corona discharge polarity is normally used in electrostatic precipitation, the example here uses negative polarity. The same operation and analysis would also apply for positive polarity. This charge build-up would then prevent the continued flow of ions to the batch.
In the case of high resistivity, the electrostatic charge build-up 54 would quench the corona discharge, and the flow of corona gaseous ions would stop. This would produce a quiescent region 55 in the tunnel that would be free of corona discharge ion flow. However, corona discharge ion flow would continue in the regions adjacent, to the electrically conductive plates 8 and 9 as depicted in Figure 3B. If the resistivity of batch material were very high, such charge build-up would result in the well-known "back-corona" effect that can plague operation of electrostatic precipitators.
At these very high resistivities, the charge build-up 53 is so great that a secondary corona discharge is generated from the surface of the resistive material, emitting positive ions into the gas. These positive ions will flow back towards electrode 18 and effectively cancel out the normal negative corona discharge ion flow. In such cases, the electrostatic precipitator exhibits tremendously increased spark-over rates at reduced voltages. Precipitation performance is dramatically reduced.
Generally, the limiting bulk electrical resistivity for this phenomenon is about 1 OB S2-meter.
In the case where the electrical resistivity is not too high, gaseous ions 52 from the corona discharge flow through the surface of the batch 7 in the tunnel, the resulting current flow 53 through the material generates an electrical field that is aligned with the current flow. It is well understood that the electric field generated in the batch material is related to the current flow density and the bulk electrical resistivity of the batch material by Ohm's law:
Eb = Jb -pb Where; Eb = electric field strength (Volts / meter) Jb = electric current density ( Ampere / sq. meter) pb = batch material bulk resistivity ( S2 - meter) Such an electric field in turn produces a compressive force within the material, in effect a cohesive force.
Fb = Eb x Eb2 Where; Fb = cohesive force ( Newton / sq. meter) sb = bulk dielectric constant of batch material ( farads l meter ) By conservation of charge, the electrical current density J; of the gaseous ion flow towards the batch surface must equal the electrical current density Jb through the batch material.
J.=Jb Where: J; = corona current density at batch surface (Ampere / sq. meter) Using Ohm's law, we can express the cohesive force of material on the batch surface in terms of the corona discharge ion current density:
Fb=Ebx(pbxJ~)2 This force 62 is directed perpendicular towards the free surface 7 of batch material and will thus act to defeat the entrainment of dust from the batch into the gas flow.
The equation demonstrates that the cohesive force is strongly dependent upon both the resistivity of the batch material and the corona discharge ion current density.
Fb = Eb x Eb2 Where; Fb = cohesive force ( Newton / sq. meter) sb = bulk dielectric constant of batch material ( farads l meter ) By conservation of charge, the electrical current density J; of the gaseous ion flow towards the batch surface must equal the electrical current density Jb through the batch material.
J.=Jb Where: J; = corona current density at batch surface (Ampere / sq. meter) Using Ohm's law, we can express the cohesive force of material on the batch surface in terms of the corona discharge ion current density:
Fb=Ebx(pbxJ~)2 This force 62 is directed perpendicular towards the free surface 7 of batch material and will thus act to defeat the entrainment of dust from the batch into the gas flow.
The equation demonstrates that the cohesive force is strongly dependent upon both the resistivity of the batch material and the corona discharge ion current density.
Generally it can be said that the batch must have sufficiently low electrical resistivity that corona current flow will pass through material to the grounded tubes.
Generally, we can say that this resistivity must be below 108 S2-meter.
Electrical resistivity of batch is primarily a function of the chemical composition of the batch and the temperature of the batch. Typically, batch is a blend of several ingredients, and the resistivity is also a function of the physical disposition of the various chemical constituents in the blend. The primary means of electrical conductance in batch is ionic conduction through the sodium constituents of the batch which is temperature dependent. At temperatures above about 200°C, soda ash generally provides sufficient electrical conductivity that the resistivity remains below the critical 108 S2-meter. In dry air, the resistivity increases monotonically with decreasing temperature and below about 200°C the resistivity would rise above the critical point.
In the presence of furnace exhaust gases, however, the resistivity curve follows the dry air curve for higher temperatures, but for temperatures below about 200°C the resistivity actually decreases with decreasing temperature. The reason for this is that furnace gases typically contain high amounts of water vapour and trace amounts of acidic gases. Below temperatures of about 200°C, acid will condense onto solid surfaces, the so-called acid dew point. At first, only minute amounts of acid condense on the solid surface, but this minute surface film is enough to provide some electrical conductance. Effectively the electrical conductance mechanism switches over from ionic conduction through the sodium constituent of the batch to surface conduction through the acid film on the surface of the batch particles.
Because the electrical resistivity of batch is below the limit imposed by back-corona, but still high enough to produce strong cohesive forces at the batch surface 7, entrainment of dust from the batch can be eliminated.
Generally, we can say that this resistivity must be below 108 S2-meter.
Electrical resistivity of batch is primarily a function of the chemical composition of the batch and the temperature of the batch. Typically, batch is a blend of several ingredients, and the resistivity is also a function of the physical disposition of the various chemical constituents in the blend. The primary means of electrical conductance in batch is ionic conduction through the sodium constituents of the batch which is temperature dependent. At temperatures above about 200°C, soda ash generally provides sufficient electrical conductivity that the resistivity remains below the critical 108 S2-meter. In dry air, the resistivity increases monotonically with decreasing temperature and below about 200°C the resistivity would rise above the critical point.
In the presence of furnace exhaust gases, however, the resistivity curve follows the dry air curve for higher temperatures, but for temperatures below about 200°C the resistivity actually decreases with decreasing temperature. The reason for this is that furnace gases typically contain high amounts of water vapour and trace amounts of acidic gases. Below temperatures of about 200°C, acid will condense onto solid surfaces, the so-called acid dew point. At first, only minute amounts of acid condense on the solid surface, but this minute surface film is enough to provide some electrical conductance. Effectively the electrical conductance mechanism switches over from ionic conduction through the sodium constituent of the batch to surface conduction through the acid film on the surface of the batch particles.
Because the electrical resistivity of batch is below the limit imposed by back-corona, but still high enough to produce strong cohesive forces at the batch surface 7, entrainment of dust from the batch can be eliminated.
Such a strong cohesive force will prevent the entrainment of dust and other batch particles into the gas flow. This allows the E-batch to be designed with gas flow velocities significantly greater than those of prior art. Higher gas velocity means that a smaller device can be provided to handle the same amount of gas flow and thus solids flow.
As well as providing a cohesive force to the batch material and preventing entrainment of dust into the flowing gases, the corona discharge will provide two other important functions. First, it will electrostatically charge any fine particulate matter in the furnace exhaust gases and then force them towards either the interior surfaces of the metallic tubes 8 and 9, or the surface 7 of the batch material. This is conventional electrostatic precipitator operation. Generally, if enough collection surface area is provided, the fine particulate matter will be precipitated from the furnace gases with high efficiency.
Second, the gaseous ion flow in the corona discharge produces intense fine scale turbulence in the gas. Such turbulence has the effect of improving both heat transfer rates and mass transfer rates from the flowing gases to the batch material surface.
This will have the effect of increasing the preheat temperature of the batch exiting the device and increasing the removal of gaseous pollutants from the furnace gases by chemical reaction with the batch material. As described previously, heat and mass transfer rates are typically limited by the formation of a gas flow "boundary layer" near a solid surface. Gas velocities are low in this boundary layer, and the layer becomes the bottleneck in the heat or mass transfer processes. Heat or mass must then diffuse through the layer at a very slow rate. The corona-induced turbulence is especially effective at significantly reducing the thickness of this boundary layer, thus increasing transfer rates. Thus, compared to prior art, the E-batch process can achieve better batch preheating and better gaseous pollutant removal in a physically smaller device.
As well as providing a cohesive force to the batch material and preventing entrainment of dust into the flowing gases, the corona discharge will provide two other important functions. First, it will electrostatically charge any fine particulate matter in the furnace exhaust gases and then force them towards either the interior surfaces of the metallic tubes 8 and 9, or the surface 7 of the batch material. This is conventional electrostatic precipitator operation. Generally, if enough collection surface area is provided, the fine particulate matter will be precipitated from the furnace gases with high efficiency.
Second, the gaseous ion flow in the corona discharge produces intense fine scale turbulence in the gas. Such turbulence has the effect of improving both heat transfer rates and mass transfer rates from the flowing gases to the batch material surface.
This will have the effect of increasing the preheat temperature of the batch exiting the device and increasing the removal of gaseous pollutants from the furnace gases by chemical reaction with the batch material. As described previously, heat and mass transfer rates are typically limited by the formation of a gas flow "boundary layer" near a solid surface. Gas velocities are low in this boundary layer, and the layer becomes the bottleneck in the heat or mass transfer processes. Heat or mass must then diffuse through the layer at a very slow rate. The corona-induced turbulence is especially effective at significantly reducing the thickness of this boundary layer, thus increasing transfer rates. Thus, compared to prior art, the E-batch process can achieve better batch preheating and better gaseous pollutant removal in a physically smaller device.
This corona-induced turbulence is commonly known as corona wind. It results from the fact that the gaseous ions being electrostatically propelled through the gas actually create a drag on the surrounding gases and set them in motion. This effect can be optimised by suitable electrode design, for cases where still higher heat and mass transfer rates are desired. Reference is made to Figure 5, which shows an improved electrode design to optimise corona-induced turbulence for heat and mass transfer.
The wire is replaced by a bar 66 of large enough diameter that little corona is produced from its surface. For typical applications, the interior cross sectional dimensions of the tube might be 6 to 12 inches. Such a bar then might be of ~/2 to 2 inch diameter. Sharpened needlepoints 67 are affixed to the bar at regular intervals and are pointed towards to the batch surface 7. Spacing between adjacent needlepoints might be in the range of 1 inch to 6 inches. The provision of the needlepoint results in localised generation of corona discharge at the needle tip 67, with the gaseous ion flow 69 being almost entirely toward the batch surface 7.
The other regions 68 of the tunnel are essentially quiescent with respect to gaseous ion flow. Such an arrangement has two benefits.
First, all the corona discharge ion current flow is directed into the batch.
Then the cohesion force at the batch surface 7 will be greater than if the ion current were uniformly distributed around the entire circumference of the tunnel.
Second, the non-uniform corona ion flow will create a corona-induced gas flow pattern 70 inside the tunnel, with gas velocity directed toward the batch surface 7.
Such a gas circulation will carry gases from the entire tunnel cross section towards the batch surface 7. This will greatly improve the desired heat and mass transfer processes.
The wire is replaced by a bar 66 of large enough diameter that little corona is produced from its surface. For typical applications, the interior cross sectional dimensions of the tube might be 6 to 12 inches. Such a bar then might be of ~/2 to 2 inch diameter. Sharpened needlepoints 67 are affixed to the bar at regular intervals and are pointed towards to the batch surface 7. Spacing between adjacent needlepoints might be in the range of 1 inch to 6 inches. The provision of the needlepoint results in localised generation of corona discharge at the needle tip 67, with the gaseous ion flow 69 being almost entirely toward the batch surface 7.
The other regions 68 of the tunnel are essentially quiescent with respect to gaseous ion flow. Such an arrangement has two benefits.
First, all the corona discharge ion current flow is directed into the batch.
Then the cohesion force at the batch surface 7 will be greater than if the ion current were uniformly distributed around the entire circumference of the tunnel.
Second, the non-uniform corona ion flow will create a corona-induced gas flow pattern 70 inside the tunnel, with gas velocity directed toward the batch surface 7.
Such a gas circulation will carry gases from the entire tunnel cross section towards the batch surface 7. This will greatly improve the desired heat and mass transfer processes.
Other geometries can be used for the electrically conductive tube, as depicted in Figure 4A. Here a circular cylinder 96 with a lower section removed is provided.
The size of the opening is chosen so that the batch material surface 7 most nearly completes the circle. This geometry provides the most uniform distribution of corona discharge 52. Other details are the same as for the description of previous geometry.
As well, various types of baffles can be provided to promote good flow of the batch material, as depicted in Figure 4B. Here, steeply sloped baffles 97 immediately above tube 96 eliminate the possibility of stagnant batch material 98 directly on top of tube 96. Such stagnant areas can create large agglomerates of batch that can dislodge and then obstruct proper material flow through the hopper.
The basic objective of the invention is to preheat batch material for use in a glass furnace, with simultaneous reduction of pollution emissions in the exhaust gases. As previously mentioned, the benefits of the E-batch process of the invention are greatest in the case of oxygen-fuel fired furnaces because:
the exhaust gases are at higher temperatures than other types of furnaces, and 2. the preheating of batch reduces the requirements for both fuel and oxygen to the furnace, thus saving the costs associated with both.
The description of preferred application to glass furnaces will therefore be made in the context of oxygen-fuel fired furnaces, but the E-batch process has similar applicability to other furnaces including regenerative or recuperative air-fuel fired glass furnaces.
The size of the opening is chosen so that the batch material surface 7 most nearly completes the circle. This geometry provides the most uniform distribution of corona discharge 52. Other details are the same as for the description of previous geometry.
As well, various types of baffles can be provided to promote good flow of the batch material, as depicted in Figure 4B. Here, steeply sloped baffles 97 immediately above tube 96 eliminate the possibility of stagnant batch material 98 directly on top of tube 96. Such stagnant areas can create large agglomerates of batch that can dislodge and then obstruct proper material flow through the hopper.
The basic objective of the invention is to preheat batch material for use in a glass furnace, with simultaneous reduction of pollution emissions in the exhaust gases. As previously mentioned, the benefits of the E-batch process of the invention are greatest in the case of oxygen-fuel fired furnaces because:
the exhaust gases are at higher temperatures than other types of furnaces, and 2. the preheating of batch reduces the requirements for both fuel and oxygen to the furnace, thus saving the costs associated with both.
The description of preferred application to glass furnaces will therefore be made in the context of oxygen-fuel fired furnaces, but the E-batch process has similar applicability to other furnaces including regenerative or recuperative air-fuel fired glass furnaces.
Glass melting furnaces operate under extreme conditions of temperature while maintaining very precise operating conditions. Exhaust gases are hot and chemically aggressive. The batch material consists of an amalgamation of several components of varying chemical and physical composition that are reactive, abrasive, hygroscopic and prone to dusting. Equipment applied to glass furnaces, especially one handling both the batch material and the exhaust gases, must be simple and reliable. This description is important because the. advantage of the E-batch process, compared to the alternatives, becomes apparent when its full integration with the glass manufacturing process is understood.
Reference is made to Figure 6. The glass furnace 71 is a refractory brick structure enclosing a pool 72 of molten glass and a combustion space 73. Burners 74 are supplied with oxygen and fuel and produce flames inside the combustion space.
Heat from the flames melts the glass 72. Molten glass exits the furnace through ports not shown in this diagram. Batch material is fed into the furnace via charging machine 4. Many types of charging machines are commonly used, including vibratory feeders, screw feeders, reciprocating pushers, etc. Batch material is fed into the furnace at variable rates in order to maintain a constant top 95 level of molten glass 72 in the furnace. As such, feeder 4 must be capable of providing batch to the furnace at variable rates.
The effect of preheating batch is to reduce the firing rate of the burners in the furnace. Preheated batch requires less energy to melt than unheated batch.
Reducing the firing rate of the burners reduces both the amount of oxygen and the amount of fuel required by the burner.
Exhaust gases 75 from the combustion space exit the furnace through port 76 and enter flue channel 77. These exhaust gases 75 are typically at temperatures of 1300°C-1400°C, so the flue channel must also be constructed of refractory brick material.
Reference is made to Figure 6. The glass furnace 71 is a refractory brick structure enclosing a pool 72 of molten glass and a combustion space 73. Burners 74 are supplied with oxygen and fuel and produce flames inside the combustion space.
Heat from the flames melts the glass 72. Molten glass exits the furnace through ports not shown in this diagram. Batch material is fed into the furnace via charging machine 4. Many types of charging machines are commonly used, including vibratory feeders, screw feeders, reciprocating pushers, etc. Batch material is fed into the furnace at variable rates in order to maintain a constant top 95 level of molten glass 72 in the furnace. As such, feeder 4 must be capable of providing batch to the furnace at variable rates.
The effect of preheating batch is to reduce the firing rate of the burners in the furnace. Preheated batch requires less energy to melt than unheated batch.
Reducing the firing rate of the burners reduces both the amount of oxygen and the amount of fuel required by the burner.
Exhaust gases 75 from the combustion space exit the furnace through port 76 and enter flue channel 77. These exhaust gases 75 are typically at temperatures of 1300°C-1400°C, so the flue channel must also be constructed of refractory brick material.
Batch material typically begins to melt at temperature of about 600°C.
If this melting were to occur inside the E-batch preheater, the batch would stick together and to the metal surfaces of the device, which would render the device non-operational.
In order to prevent overheating of the batch, the hot gases from the furnace must be tempered before introduction to the E-batch device.
Tempering air 78 is injected into the flue channel by fan 79 through port 80.
The air 78 mixes with the furnace gases 75 to produce tempered exhaust gases 81 in a lower portion of the flue channel. These tempered gases 81 are typically at about 550°C-600°C. Normally, this temperature is measured and the fan 79 speed controlled to maintain the desired temperature.
Alternatively, cooled gases 87 exiting the E-batch module, can be recirculated 95 to provide the desired gas tempering. In this way, no extra oxygen is introduced to the system and no heat is lost due to the cold air infiltration.
Metallic ducts and flues can now handle these tempered gases. Tempered exhaust gas 81 then flows through stack 82 and duct 83. These ducts and stack will be well insulated to maintain the exhaust gas temperature. Fan 84 is provided to overcome the back pressure developed when gases flow through the E-batch device. The passage of gases through the plurality of tunnels in the E-batch requires a certain amount of pressure, but conventional fans commonly used for this purpose can handle this. The fan speed will be controlled in order to maintain proper pressure inside the combustion space 73 of the furnace. Stable pressure in the combustion space 73 is critical to the glass manufacturing process.
Alternatively, the fan can be located on the downstream side of the E-batch module.
Then it will be handling cooler and cleaner gases.
If this melting were to occur inside the E-batch preheater, the batch would stick together and to the metal surfaces of the device, which would render the device non-operational.
In order to prevent overheating of the batch, the hot gases from the furnace must be tempered before introduction to the E-batch device.
Tempering air 78 is injected into the flue channel by fan 79 through port 80.
The air 78 mixes with the furnace gases 75 to produce tempered exhaust gases 81 in a lower portion of the flue channel. These tempered gases 81 are typically at about 550°C-600°C. Normally, this temperature is measured and the fan 79 speed controlled to maintain the desired temperature.
Alternatively, cooled gases 87 exiting the E-batch module, can be recirculated 95 to provide the desired gas tempering. In this way, no extra oxygen is introduced to the system and no heat is lost due to the cold air infiltration.
Metallic ducts and flues can now handle these tempered gases. Tempered exhaust gas 81 then flows through stack 82 and duct 83. These ducts and stack will be well insulated to maintain the exhaust gas temperature. Fan 84 is provided to overcome the back pressure developed when gases flow through the E-batch device. The passage of gases through the plurality of tunnels in the E-batch requires a certain amount of pressure, but conventional fans commonly used for this purpose can handle this. The fan speed will be controlled in order to maintain proper pressure inside the combustion space 73 of the furnace. Stable pressure in the combustion space 73 is critical to the glass manufacturing process.
Alternatively, the fan can be located on the downstream side of the E-batch module.
Then it will be handling cooler and cleaner gases.
The stack 82 is provided with an emergency vent 85 and valve 86. In the case of malfunction of the E-batch device, or failure of fan 84, the furnace exhaust gases must be quickly diverted to atmosphere. The glass furnace cannot be shut down or allowed to cool down, otherwise severe damage to the furnace will result. Upon a malfunction, the vent 85 quickly opens and valve 86 closes. A controller will then position the flaps of emergency vent 85, in order to maintain furnace operating pressure, since fan 84 will no longer be serving this purpose.
In normal operation, tempered gases 82 will discharge from fan 84 and enter inlet plenum 12 of the E-batch preheater. The E-batch preheater shown in Figure 6 is consistent with the previous descriptions, but with further special aspects.
Several banks of tunnels are provided, in this example a total of eight. Additional intermediate plenums 13 are thus provided. Cleaned and cooled gases 87 exit the E-batch preheater from outlet plenum 14. A stack 89 discharges these gases 87 to atmosphere.
The use of multiple banks of tunnels allows for differing designs of each bank, in order to suit the requirements at that particular point of the process. As gases flow upward through the E-batch preheater, they are cooled. As a result of this cooling, the actual volumetric gas flow decreases. Therefore, it will be desirable for the lower banks to include a greater number of tunnels than the upper banks, in order to provide optimum gas velocity in each bank of tunnels.
As well, the electrical characteristic of gases varies with temperature.
Generally, at higher temperatures, the voltage required to produce adequate corona discharge decreases. Therefore, it will be desirable to provide independent high voltage power supplies 57 to individual banks of tunnels. In general, independent power supplies will be beneficial to operation of the process, since each power supply can be operated at a different voltage level, to produce the optimum operation at that point.
However, it may prove to be cost effective to provide a few banks with a single power supply. The example here shows four power supplies for the eight banks of tunnels.
In normal operation, tempered gases 82 will discharge from fan 84 and enter inlet plenum 12 of the E-batch preheater. The E-batch preheater shown in Figure 6 is consistent with the previous descriptions, but with further special aspects.
Several banks of tunnels are provided, in this example a total of eight. Additional intermediate plenums 13 are thus provided. Cleaned and cooled gases 87 exit the E-batch preheater from outlet plenum 14. A stack 89 discharges these gases 87 to atmosphere.
The use of multiple banks of tunnels allows for differing designs of each bank, in order to suit the requirements at that particular point of the process. As gases flow upward through the E-batch preheater, they are cooled. As a result of this cooling, the actual volumetric gas flow decreases. Therefore, it will be desirable for the lower banks to include a greater number of tunnels than the upper banks, in order to provide optimum gas velocity in each bank of tunnels.
As well, the electrical characteristic of gases varies with temperature.
Generally, at higher temperatures, the voltage required to produce adequate corona discharge decreases. Therefore, it will be desirable to provide independent high voltage power supplies 57 to individual banks of tunnels. In general, independent power supplies will be beneficial to operation of the process, since each power supply can be operated at a different voltage level, to produce the optimum operation at that point.
However, it may prove to be cost effective to provide a few banks with a single power supply. The example here shows four power supplies for the eight banks of tunnels.
The final bank of tunnels 88 is provided with the greatest number of tunnels.
It will be beneficial to reduce the gas velocity in this final bank to assure that virtually no batch dust is entrained in the gases leaving this bank, since these gases are discharged directly to atmosphere. As well, this final bank will be provided with its own high voltage power supply, so that optimum electrostatic operation is maintained at all times.
The E-batch module is provided with a surge hopper 90 that holds batch material above its active sections. It is important that the top level of batch 92 in the surge hopper does not fall below the uppermost tunnel 93 in the E-batch preheater.
Batch material 17 is delivered to the top of the surge hopper by conventional material handling equipment 91, such as bucket elevators and belt conveyors. Typically, this equipment is intermittently operated, so the capacity of reservoir must be adequate to allow for the intervals between batch deliveries. As well, the capacity of the surge hopper must be sufficient to allow for batch to be fed to the furnace by feeder 4 during any period of time required to repair a failure of material handling equipment 91.
Hot batch from the bottom of the E-batch module lower hopper 3 flows to the furnace-charging machine 4 by a gravity chute 94. Hot batch is dry and prone to generate fugitive dust emissions, so handling of this material is to be minimised.
Hopper 3 and chute 94 are sealed in a dust-tight fashion. As well, hopper 3 and chute 94 will be well insulated to maintain temperature of the preheated batch.
It will be beneficial to reduce the gas velocity in this final bank to assure that virtually no batch dust is entrained in the gases leaving this bank, since these gases are discharged directly to atmosphere. As well, this final bank will be provided with its own high voltage power supply, so that optimum electrostatic operation is maintained at all times.
The E-batch module is provided with a surge hopper 90 that holds batch material above its active sections. It is important that the top level of batch 92 in the surge hopper does not fall below the uppermost tunnel 93 in the E-batch preheater.
Batch material 17 is delivered to the top of the surge hopper by conventional material handling equipment 91, such as bucket elevators and belt conveyors. Typically, this equipment is intermittently operated, so the capacity of reservoir must be adequate to allow for the intervals between batch deliveries. As well, the capacity of the surge hopper must be sufficient to allow for batch to be fed to the furnace by feeder 4 during any period of time required to repair a failure of material handling equipment 91.
Hot batch from the bottom of the E-batch module lower hopper 3 flows to the furnace-charging machine 4 by a gravity chute 94. Hot batch is dry and prone to generate fugitive dust emissions, so handling of this material is to be minimised.
Hopper 3 and chute 94 are sealed in a dust-tight fashion. As well, hopper 3 and chute 94 will be well insulated to maintain temperature of the preheated batch.
Claims (32)
1. A method for heating glass batch materials before use in a glass melting furnace, the glass batch material comprising solid particle raw materials or cullet, or a mixture of the two, the method comprising the steps of:
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material; and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
a) providing a bulk quantity of glass batch material in a hopper;
b) providing at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a surface of the batch material;
c) passing glass furnace exhaust gases through the tunnel;
d) providing an electrically conductive electrode within the tunnel;
e) providing an electrically conductive surface in contact with the batch material; and f) applying an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
2. The method of claim 1 wherein the gases flowing through the tunnel are at sufficient velocity so that at least some of the batch material would be entrained in the flowing gases if the electrical potential difference of step f) were not applied.
3. The method of claim 1 or claim 2 wherein the bulk electrical resistivity of the batch material is less than 108 .OMEGA.-metre.
4. The method of any one of claims 1 to 3 including the additional steps of:
a) removing heated batch material from the bottom of so that the batch material moves through the hopper by action of gravity.
b) supplying unheated batch material to the top of the hopper
a) removing heated batch material from the bottom of so that the batch material moves through the hopper by action of gravity.
b) supplying unheated batch material to the top of the hopper
5. The method of claim 4 wherein the batch material motion renewed surfaces of batch material in the tunnel.
6. The method of any one of claims 1 to 5 wherein:
a) the tunnel is of cylindrical shape and is generally horizontally disposed within the hopper;
b) the top portion of the cylindrical tunnel consists of electrically conductive plates forming roofs within the bulk material;
c) the roofs are arranged so that the bottom portion of the cylindrical tunnel consists of batch material residing at its angle of repose beneath the roofs; and d) the roofs of b) comprising the electrically conductive surface of claim 1, step e).
a) the tunnel is of cylindrical shape and is generally horizontally disposed within the hopper;
b) the top portion of the cylindrical tunnel consists of electrically conductive plates forming roofs within the bulk material;
c) the roofs are arranged so that the bottom portion of the cylindrical tunnel consists of batch material residing at its angle of repose beneath the roofs; and d) the roofs of b) comprising the electrically conductive surface of claim 1, step e).
7. The method of claim 6 wherein the cylindrical tunnel is a hexagonal cylinder with an apex of the hexagon directed upward, the electrically conductive plates forming the two top and two side portions of the hexagonal cylinder, and the batch material forming the two bottom portions of the hexagonal cylinder.
8. The method of claim 6 or claim 7 wherein the top portion b) of the cylinder is a circular cylinder with a bottom section removed.
9. The method of any of claims 6 to 8 wherein the discharge electrode consists of a wire, a small radiuses bar, or a bar fitted with small radiused points or edges, the discharge electrode being axially aligned and essentially centrally located within the cylinder.
10. The method of any one of claims 6 to 10 comprising of a plurality of the tunnels, thus forming a bank of the tunnels, the furnace gases being divided to flow through the tunnels in parallel.
11. The method of claim 10 further comprising:
a) a plurality of the banks of tunnels located one above another;
b) the gases being directed to flow first through the bottom-most bank, then successively through each vertically adjacent bank; and c) heated batch material is removed from the bottom of the hopper and unheated batch material is added to the top of the hopper in a substantially continuous fashion, so that the batch material moves through the hopper by action of gravity.
a) a plurality of the banks of tunnels located one above another;
b) the gases being directed to flow first through the bottom-most bank, then successively through each vertically adjacent bank; and c) heated batch material is removed from the bottom of the hopper and unheated batch material is added to the top of the hopper in a substantially continuous fashion, so that the batch material moves through the hopper by action of gravity.
12. The method of any one of claims 1 to 11 wherein the glass furnace exhaust gases contain particulate matter and at least a portion of the particulate matter is electrostatically precipitated from the gases onto the inside surface of the tunnel.
13. The method of any one of claims 1 to 12 wherein the glass furnace exhaust gases contain a gaseous pollutant, the batch material is at least partially comprised of a constituent that is chemically reactive with the pollutant, and at least some of the gaseous pollutant is removed from the furnace exhaust gases by reaction with the batch material constituent.
14. The method of claim 13 wherein the gaseous pollutant is sulphur dioxide and the batch constituent is soda ash or limestone.
15. The method of claim 13 wherein the gaseous pollutant is hydrogen chloride and batch constituent is soda ash or limestone.
16. The method of claim 13 wherein the gaseous pollutant is hydrogen fluoride and batch constituent is soda ash or limestone.
17. An apparatus for heating glass batch materials before use in a glass melting furnace, the glass batch material consisting of solid particle raw materials or cutlet, or a mixture of the two, comprising:
a) a bulk quantity of glass batch material contained in a hopper;
b) at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a free surface of the batch material;
c) means to pass glass furnace exhaust gases through the tunnel;
d) an electrically conductive electrode within the tunnel;
e) an electrically conductive surface in contact with the batch material;
and f) means to apply an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
a) a bulk quantity of glass batch material contained in a hopper;
b) at least one gas flow tunnel through the bulk quantity of batch material, at least a portion of the surface of the tunnel consisting of a free surface of the batch material;
c) means to pass glass furnace exhaust gases through the tunnel;
d) an electrically conductive electrode within the tunnel;
e) an electrically conductive surface in contact with the batch material;
and f) means to apply an electrical potential difference between the electrode of step d) and the surface of step e) of sufficient magnitude to produce corona discharge inside the tunnel, the corona discharge consisting of a flow of gaseous ions through the furnace gases, at least a portion of the gaseous ions flowing into the glass batch material.
18. The apparatus of claim 17 wherein the gases flowing through the tunnel are at sufficient velocity so that at least some of the batch material would be entrained in the flowing gases if the electrical potential difference of step f) were not applied.
19. The apparatus of claim 17 or claim 18 wherein the bulk electrical resistivity of the batch material is less than 108 .OMEGA.-metre.
20. The apparatus of any one of claims 17 to 19 further including:
a) means to remove heated batch material from the bottom of the so that the batch material moves through the hopper by action of gravity; and b) means to add unheated batch material to the top of the hopper.
a) means to remove heated batch material from the bottom of the so that the batch material moves through the hopper by action of gravity; and b) means to add unheated batch material to the top of the hopper.
21. The apparatus of claim 20 wherein the batch material motion provides renewed surfaces of batch material in the tunnel.
22. The apparatus of any one of claims 17 to 21 wherein:
a) the tunnel is of cylindrical shape and is generally horizontally disposed within the hopper;
b) the top portion of the cylindrical tunnel consists of electrically conductive plates forming roofs within the bulk material;
c) the roofs are arranged so that the bottom portion of the cylindrical tunnel consists of batch material residing at its angle of repose beneath the roofs; and d) the roofs of b) comprising the electrically conductive surface of claim 17, item e).
a) the tunnel is of cylindrical shape and is generally horizontally disposed within the hopper;
b) the top portion of the cylindrical tunnel consists of electrically conductive plates forming roofs within the bulk material;
c) the roofs are arranged so that the bottom portion of the cylindrical tunnel consists of batch material residing at its angle of repose beneath the roofs; and d) the roofs of b) comprising the electrically conductive surface of claim 17, item e).
23. The apparatus of claim 22 wherein the cylindrical tunnel is a hexagonal cylinder with an apex of the hexagon directed upward, the electrically conductive plates forming the two top and two side portions of the hexagonal cylinder, and the batch material forming the two bottom portions of the hexagonal cylinder.
24. The apparatus of claim 22 or claim 23 wherein the top portion b) of the cylinder is a circular cylinder with a bottom section removed.
25. The apparatus of any one of claims 22 to 25 wherein the discharge electrode consists of a wire, a small radiused bar, or a bar fitted with small radiused points or edges, the discharge electrode being axially aligned and centrally located within the cylinder.
26. The apparatus of any one of claims 22 to 25 comprising of a plurality of the tunnels, thus forming a bank of the tunnels, the furnace gases being divided to flow through the tunnels in parallel.
27. The apparatus of claim 26 further comprising:
a) a plurality of the banks of tunnels located one above another;
b) means to direct the flow of the gases first through the bottom-most bank, then successively through each vertically adjacent bank;
c) means to remove heated batch material from the bottom of the so that the batch material moves through the hopper by action of gravity;
d) means to supply unheated batch material to the top of the hopper.
a) a plurality of the banks of tunnels located one above another;
b) means to direct the flow of the gases first through the bottom-most bank, then successively through each vertically adjacent bank;
c) means to remove heated batch material from the bottom of the so that the batch material moves through the hopper by action of gravity;
d) means to supply unheated batch material to the top of the hopper.
28. The apparatus of any one of claims 17 to 27 wherein the glass furnace exhaust gases contain particulate matter and at least a portion of the particulate matter is electrostatically precipitated from the gases onto the inside surface of the tunnel.
29. The apparatus of any one of claims 17 to 28 wherein the glass furnace exhaust gases contain a gaseous pollutant, the batch material is at least partially comprised of a constituent that is chemically reactive with the pollutant, and at least some of the gaseous pollutant is removed from the furnace exhaust gases by reaction with the batch material constituent.
30. The method of claim 29 wherein the gaseous pollutant is sulphur dioxide and the batch constituent is soda ash or limestone.
31. The method of claim 29 wherein the gaseous pollutant is hydrogen chloride and batch constituent is soda ash or limestone.
32. The method of claim 29 wherein the gaseous pollutant is hydrogen fluoride and batch constituent is soda ash or limestone.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| GB0000969.6 | 2000-01-18 | ||
| GB0000969A GB2363791B (en) | 2000-01-18 | 2000-01-18 | Electrostatic batch preheater |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA2331165A1 true CA2331165A1 (en) | 2001-07-18 |
Family
ID=9883790
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002331165A Abandoned CA2331165A1 (en) | 2000-01-18 | 2001-01-16 | Electrostatic batch preheater |
Country Status (10)
| Country | Link |
|---|---|
| US (1) | US6615612B2 (en) |
| EP (1) | EP1123903A3 (en) |
| JP (1) | JP2001220148A (en) |
| KR (1) | KR20010076305A (en) |
| CN (1) | CN1310142A (en) |
| AU (1) | AU772030B2 (en) |
| BR (1) | BR0100642A (en) |
| CA (1) | CA2331165A1 (en) |
| GB (1) | GB2363791B (en) |
| TW (1) | TW583148B (en) |
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|---|---|---|---|---|
| GB0221823D0 (en) * | 2002-09-20 | 2002-10-30 | Pilkington Plc | Free flowing glass batch |
| US20080289364A1 (en) | 2007-05-23 | 2008-11-27 | Pinkham Jr Daniel | Method and system for preheating glass batch or ingredient(s) |
| US7886531B2 (en) * | 2007-09-28 | 2011-02-15 | Caterpillar Inc | Exhaust system having outlet-located moisture entrainment device |
| DE102009019454A1 (en) * | 2009-05-04 | 2010-11-11 | Ardagh Glass Gmbh | Apparatus for preheating glass shards |
| DE102009019456A1 (en) * | 2009-05-04 | 2010-11-11 | Ardagh Glass Gmbh | Apparatus for preheating glass shards |
| DE102009043074B3 (en) * | 2009-09-25 | 2011-01-20 | Beteiligungen Sorg Gmbh & Co. Kg | Method for the production of dry and pourable mixture for loading glass melt furnace with particle-like components, comprises mixing quartz, sodium carbonate and calcium carbonate and adding water with the mixture |
| DE102010023018B3 (en) * | 2010-06-08 | 2011-05-19 | Beteiligungen Sorg Gmbh & Co. Kg | Method for charging a preheater with heating elements for charging materials by glass-smelting plant, comprises applying the charging materials through sensors controlled in uniform distribution on an upper heating element |
| DE102010025365B3 (en) | 2010-06-28 | 2011-06-16 | Beteiligungen Sorg Gmbh & Co. Kg | Device for drying and pre-heating particle-shaped charging material for glass melting plant, comprises a vertical stack in which gas conduits are arranged, where the stack is equipped with a gas channel for exhaust gas from the melt plant |
| US8329021B2 (en) * | 2010-10-28 | 2012-12-11 | Palmaz Scientific, Inc. | Method for mass transfer of micro-patterns onto medical devices |
| GB201021480D0 (en) * | 2010-12-17 | 2011-02-02 | Doosan Power Systems Ltd | Control system and method for power plant |
| DE102010055685B3 (en) * | 2010-12-22 | 2012-06-21 | Beteiligungen Sorg Gmbh & Co. Kg | Device for preheating feedstock for glass melting plants |
| AU2012272572A1 (en) * | 2011-06-24 | 2014-02-06 | Jtw, Llc | Advanced nano technology for growing metallic nano-clusters |
| RU2547182C2 (en) * | 2012-06-08 | 2015-04-10 | Общество с ограниченной ответственностью "Эффективные инженерные решения" | Preheating of mix in production of mineral wool fibres from rocks and device to this end |
| CN103121787B (en) * | 2013-02-06 | 2015-04-22 | 中国建材国际工程集团有限公司 | Auger type high-radiation fluid bed for glass batch and working method thereof |
| US9776904B2 (en) | 2014-06-06 | 2017-10-03 | Owens-Brockway Glass Container Inc. | Process and apparatus for refining molten glass |
| RU2595745C1 (en) * | 2015-08-10 | 2016-08-27 | Валерий Вячеславович Ефременков | Method of loading charge and glass scrap in regenerative glass furnace with u-shaped flame direction |
| FR3043995B1 (en) * | 2015-11-19 | 2017-12-22 | Imv Tech | DEVICE FOR FEEDING AND POSITIONING ANIMAL SEED CONDITIONING FLAKES AND TREATMENT PLANT COMPRISING SUCH A DEVICE |
| US10101090B2 (en) * | 2016-07-18 | 2018-10-16 | Owens-Brockway Glass Container Inc. | Duct cleaning and valve device for furnace system |
| US10669183B2 (en) | 2018-01-24 | 2020-06-02 | Owens-Brockway Glass Container Inc. | System for preheating glass melting furnace batch materials |
| US20220063475A1 (en) * | 2020-08-31 | 2022-03-03 | Lawrence HOLMAN | Translocatable slurry-containing hopper |
| US20230040599A1 (en) | 2021-08-06 | 2023-02-09 | Jeffrey C. Alexander | Rotary Batch Preheater |
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| US278356A (en) * | 1883-05-29 | niese | ||
| CH555036A (en) * | 1972-08-24 | 1974-10-15 | Buehler Ag Geb | TUBE COOLER. |
| DE2626939A1 (en) * | 1976-06-16 | 1977-12-29 | Babcock Ag | METHOD AND DEVICE FOR SEPARATING UNWANTED GAS-FORMED COMPONENTS FROM AN EXHAUST GAS |
| US4045197A (en) * | 1976-09-08 | 1977-08-30 | Ppg Industries, Inc. | Glassmaking furnace employing heat pipes for preheating glass batch |
| US4144359A (en) * | 1977-11-22 | 1979-03-13 | Efb Inc. | Apparatus and method for controlling pollutant emissions and for enhancing the manufacture of asphaltic roofing |
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| US4338112A (en) * | 1981-03-19 | 1982-07-06 | Owens-Corning Fiberglas Corporation | Method for controlling particulate emissions from a glass furnace |
| US4410347A (en) * | 1981-03-31 | 1983-10-18 | Ppg Industries, Inc. | Glass melting method using cullet as particulate collection medium |
| US4349367A (en) * | 1981-03-31 | 1982-09-14 | Ppg Industries, Inc. | Method of recovering waste heat from furnace flue gases using a granular heat exchange means |
| US4696690A (en) * | 1984-05-03 | 1987-09-29 | Himly, Holscher Gmbh & Co. | Method and device for preheating raw materials for glass production, particularly a cullet mixture |
| US4582521A (en) * | 1984-06-11 | 1986-04-15 | Owens-Corning Fiberglas Corporation | Melting furnace and method of use |
| DE3605509A1 (en) * | 1986-02-20 | 1987-08-27 | Gruenzweig Hartmann Glasfaser | METHOD FOR MELTING SILICATIC RAW MATERIALS, ESPECIALLY FOR THE PRODUCTION OF MINERAL WOOL, AND DEVICE FOR PREHEATING THE MIXTURE OF RAW MATERIALS AND CLEANING DEVICE FOR THE TUBE EXHAUST GASES THROUGH THE PROCEDURE |
| EP0305584A3 (en) * | 1987-08-29 | 1989-09-20 | Himly, Holscher GmbH & Co. | Process for the treatment, especially for the neutralization of waste gases |
| DE4141625A1 (en) * | 1991-12-17 | 1993-06-24 | Gruenzweig & Hartmann | METHOD FOR MELTING SILICATIC RAW MATERIALS, ESPECIALLY FOR THE PRODUCTION OF MINERAL WOOL, AND DEVICE FOR PREHEATING THE RAW MATERIAL BLOCK |
| ATE162960T1 (en) * | 1992-09-21 | 1998-02-15 | Edmeston Ab | METHOD FOR REDUCING POLLUTION EMISSIONS IN GLASS MELTING FURNACES |
| US5342427A (en) * | 1992-12-29 | 1994-08-30 | Edmeston Ab | Apparatus for cullet preheating and polluting emission reduction in the glass manufacturing process |
| US5855636A (en) * | 1995-12-12 | 1999-01-05 | Edmeston Ab | Method which removes odor and pollutants when preparing cullet for use in an electrostatic bed filter |
| EP0948464A1 (en) * | 1996-12-13 | 1999-10-13 | Sandvik Aktiebolag (publ) | Method and apparatus which removes odor and pollutants when preparing cullet for use in an electrostatic bed filter |
-
2000
- 2000-01-18 GB GB0000969A patent/GB2363791B/en not_active Expired - Fee Related
-
2001
- 2001-01-16 CA CA002331165A patent/CA2331165A1/en not_active Abandoned
- 2001-01-16 AU AU15015/01A patent/AU772030B2/en not_active Ceased
- 2001-01-16 EP EP01300340A patent/EP1123903A3/en not_active Withdrawn
- 2001-01-16 TW TW090100929A patent/TW583148B/en not_active IP Right Cessation
- 2001-01-17 BR BR0100642-8A patent/BR0100642A/en not_active IP Right Cessation
- 2001-01-17 KR KR1020010002592A patent/KR20010076305A/en not_active Application Discontinuation
- 2001-01-18 JP JP2001010021A patent/JP2001220148A/en active Pending
- 2001-01-18 US US09/761,749 patent/US6615612B2/en not_active Expired - Fee Related
- 2001-01-18 CN CN01116292A patent/CN1310142A/en active Pending
Also Published As
| Publication number | Publication date |
|---|---|
| TW583148B (en) | 2004-04-11 |
| EP1123903A2 (en) | 2001-08-16 |
| GB2363791A (en) | 2002-01-09 |
| US20010008076A1 (en) | 2001-07-19 |
| CN1310142A (en) | 2001-08-29 |
| GB0000969D0 (en) | 2000-03-08 |
| AU1501501A (en) | 2001-07-19 |
| AU772030B2 (en) | 2004-04-08 |
| BR0100642A (en) | 2001-09-11 |
| KR20010076305A (en) | 2001-08-11 |
| US6615612B2 (en) | 2003-09-09 |
| JP2001220148A (en) | 2001-08-14 |
| EP1123903A3 (en) | 2001-11-14 |
| GB2363791B (en) | 2002-05-15 |
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Legal Events
| Date | Code | Title | Description |
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| FZDE | Discontinued |