Title of Invention	PROCESS AND DEVICE FOR FEEDING BULK MATERIAL IN A ROTARY HEARTH FURNACE
Abstract	The invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace, which has hoods that cover the hearth belt in such a manner as to form a ring. According to the invention, the bulk material is deposited on a transport device at a layer thickness proportionately dependent on the distance to the rotary hearth center. The transport speed of the transport device is set at a certain value; the surface of the bulk material is smoothed; and then the bulk material is distributed at a constant layer height over the entire width of the hearth belt. In addition, the invention relates to a device for implementing this process. Figure 2

Title of Invention

PROCESS AND DEVICE FOR FEEDING BULK MATERIAL IN A ROTARY HEARTH FURNACE

Abstract

The invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace, which has hoods that cover the hearth belt in such a manner as to form a ring. According to the invention, the bulk material is deposited on a transport device at a layer thickness proportionately dependent on the distance to the rotary hearth center. The transport speed of the transport device is set at a certain value; the surface of the bulk material is smoothed; and then the bulk material is distributed at a constant layer height over the entire width of the hearth belt. In addition, the invention relates to a device for implementing this process. Figure 2

Full Text	GOVERNMENT OF INDIA, THE PATENT OFFICE 2nd M.S.O. BUILDING, 234/4, ACHARYA JAGADISH CHANDRA BOSE ROAD KOLKATTA - 700 020. Document No. dated: 23rd August 1996 Application No : 1491/MAS/1996 dated: 23rd August 1996 Acceptance of the complete specification advertised on Index at acceptance --85 C International Classification' -F 27 B 9/38 Title : " PROCESS AND DEVICE FOR FEEDING BULK MATERIAL IN A ROTARY HEARTH FURNACE" Applicant: MANNESMANN AKTIENGESELLSCHAFT, A GERMAN COMPANY, OF MANNESMANNUFER 2, D-40213, DUSSELDORF, GERMANY Inventors: 1. ULRICH POHL 2. HERMAN CEPIN 3. HARTMUT SCHMIEDEN 4. GERDHERRE The following specification particularly describes and ascertains the natures of this invention and the manner in which it is to be preformed:- The invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace that has hoods, which cover the belt in such a manner as to form a ring, as well as a suitable device for this purpose. Furnaces of this type demand an even temperature in the furnace chamber at the lowest possible consumption of energy. The removal device and, especially, the charging device, are of particular importance in this regard. From DE 33 12 467 C2, for example, a furnace for heating material is known that has a transport device in the area of the door opening for the purpose of feeding and removing the material, as well as a plurality of gripping devices that can feed the material to be heated from the transport device through the furnace openings to the contents of the hearth support located in the furnace, or remove the material. This known furnace is a so-called hearth bogie furnace, i.e., one in which material is not transported on a circular conveyor. From EP 0 058 736 B1, a rotary hearth furnace with a heating device to produce a hot zone is known, which has a device that constitutes a feed-in station, via which parts can be introduced into the furnace. Neither of these devices makes it possible to place bulk materials onto the furnace belt. Such a device is known from EP 0 259 510 Bl. In this case, a screw device is used; however, this device is used to carry away the material. Here, too, as is generally the case, the feeding of the bulk material is carried out by means of transport belts or chutes. In the present case, the material is passed onto the hearth belt via a lid (not described further). The object of the invention is to create a process and a corresponding device for covering the belt of a rotary hearth furnace with bulk material at a very low layer thickness relative to the belt width, in a careful and reliable manner. The invention attains this object through the characterizing features of the Process Claim 1 and the Device Claim 5. The other claims contain advantageous further developments of the invention. According to the invention, the feed-in device is constructed in such a manner that material supply is divided up into different steps. The individual steps can be easily monitored and the individual step transitions reliably controlled. In a first step, material is supplied evenly in a constant amount. For example, a movable transport belt is used, the discharge quantity of which is monitored and the discharge position of which is adjustable. The position of the turnover point is controlled in such a way that a material layer, the height of which depends on the structure of the rotary hearth furnace and, here, on the size of the furnace belt is established (Step 2) on a further transport device. The fact that the individual belt positions have different transport speeds depending on their distance to the rotary hearth center is taken into account. The layer height on this transport device Is thus highest at the outside of the furnace belt, which is most distant from the furnace center. All told, the layer height has a cross-sectional area in the form of a quadrangle that narrows conically toward the furnace center. The exact surface form is established by a smoothing device. This transport device is operated at a predeterminable speed. By means of the smoothing device and the constant speed, it is possible to set a fixed transport quantity, which is established directly from its position in the cross-sectional area at the discharge relative to the distance to the furnace center. In the third step, the material is carefully discharged from the aforementioned transport means onto the hearth belt at the discharge point. The speed of the hearth belt relative to the speed of the transport means now determines the layer height; specifically, in a constant fashion over the full width of the furnace belt. By simply maintaining the conical cross-sectional area of the bulk material on the transport belt, it is possible, because of the exclusive dependence of the speeds of the furnace belt and the transport belt, to constantly set the layer height in an especially low and reliable fashion. In practice, layer heights of only 30 mm are demanded on the transport belt for furnace belt widths of up to 7 m. Such high accuracy is attained by the device according to the invention, with layer heights from 200 to 400 mm being provided on the transport belt. The device according to the invention is particularly suitable for large-grain bulk materials. Instead of a movable continuous belt, a swivelling belt can also be used as the first material supplier. Advantageously, a continuous belt is used as the transport unit. This can have edge-shaped elevations directly on its edges, or else a side slat is provided, regardless of the transport belt. Given this side limit, it is possible to place bulk material on the transport belt at exactly the height desired. Depending on the material quality, it is also possible to carefully transport the bulk material by means of a vibrating conveyor that has a fixed strip on the side. The vibrational frequency is set in such a way that the conical cross-sectional area is maintained. For example, if a furnace belt with a width of 6 to 7 m is used for a rotary hearth furnace having a diameter of approximately 35 m, in 6 total segments of a cut-out, for instance, a circular cut-out of approximately 3°, then the sixth and outermost segment is covered by a bulk weight of roughly 36 kg and a total weight of only around 25 kg, corresponding to roughly 70%, is required in the inner segment. Accordingly the present invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace which has hoods that cover the hearth belt so as to form a ring, comprising the steps of: depositing the bulk material on a transport device at a layer thickness proportionately dependent on a distance to a center of the rotary hearth so that a cross-sectional area of the bulk material layer conically tapers to the center of the hearth; setting the transport device to a speed at least three times greater than that of the hearth belt; smoothing the surface of the bulk material on the transport device; and distributing the bulk material on the hearth belt at a constant layer height over the entire width of the hearth belt. The present invention also provides a device for carrying out the process as herein above described, said device comprising: hoods that cover the hearth belt so as to form a ring, the ring formed of hoods having a cutout at a feeding point of the rotary hearth furnace; means for transporting the bulk material arranged above the hearth belt and having a material discharge edge arranged perpendicular to a direction of movement of the hearth belt, the transport means having a transport speed which, relative to the hearth belt speed can be set inversely proportional to layer heights of the bulk material; means arranged in an area of the material discharge edge of the transport device for smoothing a surface of the bulk material, the smoothing means being at an angle relative to a middle of the rotary hearth furnace above the transport device so as to define a constant cross-sectional area of the bulk material; and means arranged in front of the smoothing means in the transport direction, for depositing the bulk material in a cross-section that tapers conically to the hearth center. An example of the invention is shown in the accompanying drawings. The drawings show: Figure I An overview of the rotary hearth furnace. Figure 2 The diagram of the feeding device. Figure 1 shows a rotary hearth furnace 11 with a midpoint M, the material transport belt 13 of which is covered by hoods 14. A hood cut-out 12 is provided for the feeding device. Figure 2 shows a section of the hearth belt 13, which moves at the speed Vp. The hearth belt 13 is covered by bulk material at a height h°. Above the hearth belt 13, there is a continuous belt 21 covered by material, which has a height hiF on the side toward the center of the rotary hearth furnace; a height hmf in the center; and a height h^ in the outer area. The continuous belt 21 moves at the speed vp. The surface of the material is passed under a smoothing roller 31, Below the underside of the smoothing roller 31, there are limits in the form of limit slats 24 in the edge area of the continuous belt 21. On the smoothing roller 31, distributed over its axial length, there are blades 32, which serve to distribute the material on the continuous belt 21. In the transport direction of the continuous belt 21, in front of the smoothing roller 31 and above this continuous belt 21, there is a transport belt 41, which has a drive 42. As the arrows indicate, the transport belt can be moved back and forth. In addition, the transport belt 41 can be swivelled around an axis lying outside of the rotary hearth furnace. This is also indicated in the drawing by a double arrow. This swivelling serves to improve the material supply onto the continuous belt; particularly, to achieve different bulk heights. WE CLAIM: 1. A process for feeding bulk material onto a belt of a rotary hearth furnace which has hoods that cover the hearth belt so as to form a ring, comprising the steps of: depositing the bulk material on a transport device at a layer thickness proportionately dependent on a distance to a center of the rotary hearth so that a cross-sectional area of the bulk material layer conically tapers to the center of the hearth; setting the transport device to a speed at least three times greater than that of the hearth belt; smoothing the surface of the bulk material on the transport device; and distributing the bulk material on the hearth belt at a constant layer height over the entire width of the hearth belt. 2. The process as claimed in claim 1, wherein the bulk material is deposited on the transport device in lines in a form dependent on the layer thickness. 3. The process as claimed in claim 1, wherein the smoothing step is carried out by pushing the bulk material into troughs. 4. The process as claimed in claim 1, wherein the smoothing step is carried out by vibrating the bulk material. 5. A device for feeding bulk material onto a hearth belt of a rotary hearth furnace, comprising: hoods that cover the hearth belt so as to form a ring, the ring formed of hoods having a cutout at a feeding point of the rotary hearth furnace; means for transporting the bulk material arranged above the hearth belt and having a material discharge edge arranged perpendicular to a direction of movement of the hearth belt, the transport means having a transport speed which, relative to the hearth belt speed can be set inversely proportional to layer heights of the bulk material; means arranged in an area of the material discharge edge of the transport device for smoothing a surface of the bulk material, the smoothing means being at an angle relative to a middle of the rotary hearth furnace above the transport device so as to define a constant cross-sectional area of the bulk material; and means arranged in front of the smoothing means in the transport direction, for depositing the bulk material in a cross-section that tapers conically to the hearth center. 6. The device as claimed in claim 5, wherein the transport means has a continuous belt having edges, a limit being provided at the edges at a height corresponding to the bulk material height. 7. The device as claimed in claim 5, wherein the transport means has a vibrating conveyor and limit slats arranged in an edge area of the conveyor at a height corresponding to the bulk material height. 8. The device as claimed in claim 5, wherein the smoothing means has a roller arranged parallel to the material discharge edge and driveable counter to the transport direction of the bulk material. 9. The device as claimed in claim 8, wherein elastic blades are mounted to the outer surface of the smoothing roller. 10. The device as claimed in claim 5, wherein the smoothing means has a strip arranged parallel to the material discharge edge. 11. The device as claimed in claim 5, wherein the bulk material depositing means has a swivelling transport belt having a swivelling drive, the transport belt having an adjustable swivelling angle and swivelling speed. 12. A process for feeding bulk material onto a belt of a rotary hearth fiimace substantially as herein above described with reference to the accompanying drawings. 13. A device for feeding bulk material onto a hearth belt of a rotary hearth furnace substantially as herein above described with reference to the accompanying drawings.

Full Text

GOVERNMENT OF INDIA, THE PATENT OFFICE
2nd M.S.O. BUILDING,
234/4, ACHARYA JAGADISH CHANDRA BOSE ROAD
KOLKATTA - 700 020.
Document No. dated: 23rd August 1996
Application No : 1491/MAS/1996 dated: 23rd August 1996
Acceptance of the complete specification advertised on
Index at acceptance --85 C
International Classification' -F 27 B 9/38
Title : " PROCESS AND DEVICE FOR FEEDING
BULK MATERIAL IN A ROTARY HEARTH FURNACE"
Applicant: MANNESMANN AKTIENGESELLSCHAFT, A GERMAN COMPANY,
OF MANNESMANNUFER 2, D-40213, DUSSELDORF, GERMANY
Inventors: 1. ULRICH POHL
2. HERMAN CEPIN
3. HARTMUT SCHMIEDEN
4. GERDHERRE
The following specification particularly describes
and ascertains the natures of this invention and the manner in
which it is to be preformed:-

The invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace that has hoods, which cover the belt in such a manner as to form a ring, as well as a suitable device for this purpose.
Furnaces of this type demand an even temperature in the furnace chamber at the lowest possible consumption of energy. The removal device and, especially, the charging device, are of particular importance in this regard. From DE 33 12 467 C2, for example, a furnace for heating material is known that has a transport device in the area of the door opening for the purpose of feeding and removing the material, as well as a plurality of gripping devices that can feed the material to be heated from the transport device through the furnace openings to the contents of the hearth support located in the furnace, or remove the material. This known furnace is a so-called hearth bogie furnace, i.e., one in which material is not transported on a circular conveyor.
From EP 0 058 736 B1, a rotary hearth furnace with a heating device to produce a hot zone is known, which has a device that constitutes a feed-in station, via which parts can be introduced into the furnace.
Neither of these devices makes it possible to place bulk materials onto the furnace belt. Such a device is known from EP 0 259 510 Bl. In this case, a screw device is used; however, this device is used to carry away the material.

Here, too, as is generally the case, the feeding of the bulk material is carried out by means of transport belts or chutes. In the present case, the material is passed onto the hearth belt via a lid (not described further).
The object of the invention is to create a process and a corresponding device for covering the belt of a rotary hearth furnace with bulk material at a very low layer thickness relative to the belt width, in a careful and reliable manner.
The invention attains this object through the characterizing features of the Process Claim 1 and the Device Claim 5. The other claims contain advantageous further developments of the invention.
According to the invention, the feed-in device is constructed in such a manner that material supply is divided up into different steps. The individual steps can be easily monitored and the individual step transitions reliably controlled.
In a first step, material is supplied evenly in a constant amount. For example, a movable transport belt is used, the discharge quantity of which is monitored and the discharge position of which is adjustable. The position of the turnover point is controlled in such a way that a material layer, the height of which depends on the structure of the rotary hearth furnace and, here, on the size of the furnace belt is established (Step 2) on a further transport device. The fact that the individual belt positions have different transport speeds depending on their distance to the rotary hearth center is taken into account. The layer height on this transport device Is thus highest at the outside of the furnace belt, which is most distant from the furnace center. All told, the layer height has a cross-sectional area in the form of a quadrangle that narrows conically toward the furnace center.
The exact surface form is established by a smoothing device. This transport device is operated at a predeterminable speed. By means of the smoothing device and the constant speed, it is possible to set a fixed transport quantity, which is established directly from its position in the cross-sectional area at the discharge relative to the distance to the furnace center.

In the third step, the material is carefully discharged from the aforementioned transport means onto the hearth belt at the discharge point. The speed of the hearth belt relative to the speed of the transport means now determines the layer height; specifically, in a constant fashion over the full width of the furnace belt.
By simply maintaining the conical cross-sectional area of the bulk material on the transport belt, it is possible, because of the exclusive dependence of the speeds of the furnace belt and the transport belt, to constantly set the layer height in an especially low and reliable fashion.
In practice, layer heights of only 30 mm are demanded on the transport belt for furnace belt widths of up to 7 m. Such high accuracy is attained by the device according to the invention, with layer heights from 200 to 400 mm being provided on the transport belt. The device according to the invention is particularly suitable for large-grain bulk materials.
Instead of a movable continuous belt, a swivelling belt can also be used as the first material supplier.
Advantageously, a continuous belt is used as the transport unit. This can have edge-shaped elevations directly on its edges, or else a side slat is provided, regardless of the transport belt. Given this side limit, it is possible to place bulk material on the transport belt at exactly the height desired.
Depending on the material quality, it is also possible to carefully transport the bulk material by means of a vibrating conveyor that has a fixed strip on the side. The vibrational frequency is set in such a way that the conical cross-sectional area is maintained.

For example, if a furnace belt with a width of 6 to 7 m is used for a rotary hearth furnace having a diameter of approximately 35 m, in 6 total segments of a cut-out, for instance, a circular cut-out of approximately 3°, then the sixth and outermost segment is covered by a bulk weight of roughly 36 kg and a total weight of only around 25 kg, corresponding to roughly 70%, is required in the inner segment.
Accordingly the present invention relates to a process for feeding bulk material onto a belt of a rotary hearth furnace which has hoods that cover the hearth belt so as to form a ring, comprising the steps of: depositing the bulk material on a transport device at a layer thickness proportionately dependent on a distance to a center of the rotary hearth so that a cross-sectional area of the bulk material layer conically tapers to the center of the hearth; setting the transport device to a speed at least three times greater than that of the hearth belt; smoothing the surface of the bulk material on the transport device; and distributing the bulk material on the hearth belt at a constant layer height over the entire width of the hearth belt.
The present invention also provides a device for carrying out the process as herein above described, said device comprising: hoods that cover the hearth belt so as to form a ring, the ring formed of hoods having a cutout at a feeding point of the rotary hearth furnace; means for transporting the bulk material arranged above the hearth belt and having a material discharge edge arranged perpendicular to a direction of movement of the hearth belt, the transport means having a transport speed which, relative to the hearth belt speed can be set inversely proportional to layer heights of the bulk material; means arranged in an area of the material discharge edge of the transport device for smoothing a surface of the bulk material, the smoothing means being at an angle relative to a middle of the rotary hearth furnace above the transport device so as to define a constant cross-sectional area of the bulk material; and means arranged in front of the smoothing means in the transport direction, for depositing the bulk material in a cross-section that tapers conically to the hearth center.

An example of the invention is shown in the accompanying drawings. The drawings show:
Figure I An overview of the rotary hearth furnace.
Figure 2 The diagram of the feeding device.
Figure 1 shows a rotary hearth furnace 11 with a midpoint M, the material transport belt 13 of which is covered by hoods 14.
A hood cut-out 12 is provided for the feeding device.
Figure 2 shows a section of the hearth belt 13, which moves at the speed Vp. The hearth belt 13 is covered by bulk material at a height h°.
Above the hearth belt 13, there is a continuous belt 21 covered by material, which has a height hiF on the side toward the center of the rotary hearth furnace; a height hmf in the center; and a height h^ in the outer area. The continuous belt 21 moves at the speed vp.
The surface of the material is passed under a smoothing roller 31, Below the underside of the smoothing roller 31, there are limits in the form of limit slats 24 in the edge area of the continuous belt 21. On the smoothing roller 31, distributed over its axial length, there are blades 32, which serve to distribute the material on the continuous belt 21.
In the transport direction of the continuous belt 21, in front of the smoothing roller 31 and above this continuous belt 21, there is a transport belt 41, which has a drive 42. As the arrows indicate, the transport belt can be moved back and forth.

In addition, the transport belt 41 can be swivelled around an axis lying outside of the rotary hearth furnace. This is also indicated in the drawing by a double arrow. This swivelling serves to improve the material supply onto the continuous belt; particularly, to achieve different bulk heights.

WE CLAIM:
1. A process for feeding bulk material onto a belt of a rotary hearth furnace which has hoods that cover the hearth belt so as to form a ring, comprising the steps of: depositing the bulk material on a transport device at a layer thickness proportionately dependent on a distance to a center of the rotary hearth so that a cross-sectional area of the bulk material layer conically tapers to the center of the hearth; setting the transport device to a speed at least three times greater than that of the hearth belt; smoothing the surface of the bulk material on the transport device; and distributing the bulk material on the hearth belt at a constant layer height over the entire width of the hearth belt.
2. The process as claimed in claim 1, wherein the bulk material is deposited on the transport device in lines in a form dependent on the layer thickness.
3. The process as claimed in claim 1, wherein the smoothing step is carried out by pushing the bulk material into troughs.
4. The process as claimed in claim 1, wherein the smoothing step is carried out by vibrating the bulk material.
5. A device for feeding bulk material onto a hearth belt of a rotary hearth furnace, comprising: hoods that cover the hearth belt so as to form a ring, the ring formed of hoods having a cutout at a feeding point of the rotary hearth furnace; means for transporting the bulk material arranged

above the hearth belt and having a material discharge edge arranged perpendicular to a direction of movement of the hearth belt, the transport means having a transport speed which, relative to the hearth belt speed can be set inversely proportional to layer heights of the bulk material; means arranged in an area of the material discharge edge of the transport device for smoothing a surface of the bulk material, the smoothing means being at an angle relative to a middle of the rotary hearth furnace above the transport device so as to define a constant cross-sectional area of the bulk material; and means arranged in front of the smoothing means in the transport direction, for depositing the bulk material in a cross-section that tapers conically to the hearth center.
6. The device as claimed in claim 5, wherein the transport means has a continuous belt having edges, a limit being provided at the edges at a height corresponding to the bulk material height.
7. The device as claimed in claim 5, wherein the transport means has a vibrating conveyor and limit slats arranged in an edge area of the conveyor at a height corresponding to the bulk material height.
8. The device as claimed in claim 5, wherein the smoothing means has a roller arranged parallel to the material discharge edge and driveable counter to the transport direction of the bulk material.
9. The device as claimed in claim 8, wherein elastic blades are mounted to the outer surface of the smoothing roller.

10. The device as claimed in claim 5, wherein the smoothing means
has a strip arranged parallel to the material discharge edge.
11. The device as claimed in claim 5, wherein the bulk material
depositing means has a swivelling transport belt having a swivelling drive,
the transport belt having an adjustable swivelling angle and swivelling
speed.
12. A process for feeding bulk material onto a belt of a rotary
hearth fiimace substantially as herein above described with reference to the
accompanying drawings.
13. A device for feeding bulk material onto a hearth belt of a rotary
hearth furnace substantially as herein above described with reference to the
accompanying drawings.

Documents:

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1491-mas-96 correspondence-others.pdf

1491-mas-96 correspondence-po.pdf

1491-mas-96 description (complete).pdf

1491-mas-96 drawings.pdf

1491-mas-96 form-1.pdf

1491-mas-96 form-26.pdf

1491-mas-96 form-4.pdf

1491-mas-96 petition.pdf

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Patent Number

193761

Indian Patent Application Number

1491/MAS/1996

PG Journal Number

30/2009

Publication Date

24-Jul-2009

Grant Date

Date of Filing

23-Aug-1996

Name of Patentee

MANNESMANN AKTIENGESELLSCHAFT

Applicant Address

MANNESMANNUFER 2, D-40213 DUSSELDORF

Inventors:

#	Inventor's Name	Inventor's Address
1	ULRICH POHL	BUGGENBECK 34, D-45470 MULLHEIM, RUHR
2	HERMAN CEPIN	NEUDORFER MARKT 14, D-47057 DUISBURG
3	HARTMUT SCHMIEDEN	NORDRING 47, D-47661 ISSUM
4	GERD HERRE	HEROLDSTR. 5, D-46119 OBERHAUSEN

PCT International Classification Number

F27B9/38

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA