Oxidation ovens are commonly used to produce carbon fibers from a precursor (such as an acrylic, pitch, or cellulose fibers). One common processing method involves successively drawing fibrous segments of the precursor material through one or more oxidation ovens.
Each of the oxidation ovens comprises a respective oxidation chamber in which the oxidation of the fiber segments takes place. Each fibrous segment can be drawn into a first oxidation oven at a first end as a carbon fiber precursor and then make multiple passes through each oxidation oven prior to exiting the final oxidation oven as an oxidized fiber segment. Roll stands and tensioners are used to draw the fibrous segments through the oxidation chambers of the ovens. Each oxidation oven heats the segments to a temperature approaching approximately 300° C. by means of a circulating flow of hot gas.
An example of such an oven is the Despatch Carbon Fiber Oxidation Oven, available from Despatch Industries, Minneapolis, Minnesota. A description of such an oven can be found in commonly-assigned U.S. Pat. No. 4,515,561. The oven described in the '561 Patent is a “center-to-ends” oxidation oven. In a center-to-ends oxidation oven, hot gas is supplied to the oxidation chamber of the oven from the center of the chamber and flows toward the ends of the chamber.
Typically, such a center-to-ends oxidation oven employs a single heating system to supply heated gas to the oxidation chamber of that oven. While some processing lines make use of multiple stacked oxidation ovens in a single processing line (where fiber exits one oven and enters the other oven), each of the stacked oxidation ovens uses a single heating system. That is, the heated gas supplied to the oxidation chamber of each stacked oven is supplied from a single heating system.
One embodiment is directed to an oven for heating fibers. The oven comprises a plurality of walls forming a chamber and a supply structure disposed within the chamber between first and second ends of the chamber. The supply structure is in communication with a first heating system and is configured to direct heated gas from the first heating system into a first portion of the chamber. The supply structure is in communication with a second heating system and is configured to direct heated gas from the second heating system into a second portion of the chamber.
Another embodiment is directed to a method of heating fibers using an oven in which a chamber is formed. The method comprises heating gas using a first heating system and heating gas using a second heating system. The method further comprises supplying the heated gas from the first heating system into a first portion of the chamber, and supplying the heated gas from the second heating system into a second portion of the chamber.
One of ordinary skill in the art will recognize that, for the sake of brevity and clarity, various conventional features used in oxidation ovens have been omitted from the figures and the following description. Examples of such features include, without limitation, baffles, ducts, vanes, vents, and the like used to adjust the flow of gas within the oven 100, vestibules and exhaust features to reduce the discharge of undesirable processes gases into the ambient environment, and/or insulation, louvers, and other thermal features to improve the thermal efficiency of the oven 100. It is to be understood that the exemplary oven 100 shown in
In the exemplary embodiment shown in
The oven 100 is configured to use multiple independent heating systems 128. Each heating system 128 is used to supply heated gas into the chamber 102. In this exemplary embodiment, two independent heating systems 128 are used, though it is to be understood that more than two independent heating systems 128 can be used. In the following description, the heating systems 128 are referred to here individually as the “first” and “second” heating systems 128 and are individually referenced using reference numerals 128-1 and 128-2, respectively. Also, in the exemplary embodiment shown in
The oven 100 includes a supply structure 130 disposed within the interior of the chamber 102 between the ends 120 and 122 of the chamber 102. In the exemplary embodiment shown in
In the exemplary embodiment shown in
The supply structure 130 and nozzles 132 can be implemented in various ways. For example, in the embodiment shown in
Each of the heating systems 128 is used to supply heated gas to a respective different subset of the nozzles 132 in the center supply structure 130. That is, in the exemplary embodiment shown in
The first and second supply ducts 134-1 and 134-2 can be appropriately tapered or provided with adjustable slots or other features (not shown) so that the velocity of heated gases exiting the nozzles 132 is substantially uniform.
In the exemplary embodiment shown in
Each of the multiple independent heating systems 128 can be independently controlled (for example, using one or more suitable controllers such as proportional-integral-derivative (PID) controllers). That is, each of the heating systems 128 can be operated to heat gas to a target temperature that differs from the target temperatures at which the other heating systems 128 are operated. This provides additional process variables that can be adjusted in order to further refine the overall oxidation process.
As noted above, the fibers that are heated in the oven 100 make multiple passes through the chamber 102. For each pass though the chamber 102, the fibers enter the chamber 102 via a slot on one side and exit the chamber 102 through a slot on the other side, with, for example, roll stands and tensioners being used to draw the fibers through the chamber 102. In one example, the multiple passes start at the bottom and go from bottom to top (though it is to be understood that other embodiments can be implemented in other ways). In one such example, where the first heating system 128-1 is used to supply heated gas to the upper portion of the chamber 102, where the second heating systems 128-2 is used to supply heated gas to the lower portion of the chamber 102, and where the multiple passes of the fibers through chamber 102 go from bottom to top, the first heating system 128-1 can be operated at target temperature that is slightly higher (for example, 1-5 degrees Celsius) than the target temperature at which the second heating system 128-2 is operated. In this way, a slight temperature difference can be established between the upper and lower portions of the chamber 102. As a consequence, the speed at which the fibrous segments can be run through the oven 100 can be increased since the higher temperature in the upper portion shortens the required residence time. This can be done without using of a physical barrier between the upper and lower portions of the chamber 102 since the fibrous segments that pass between the upper and lower nozzles 132-1 and 132-2 typically provide sufficient thermal isolation between the upper and lower portions of the chamber 102 to maintain different temperatures in the upper and lower portions of the chamber 102. In some common applications, each degree Celsius by which the temperature of the upper portion of the chamber 102 is increased relative to the temperature of the lower portion of the chamber 102 can result in at least a one percent increase in line speed.
The multiple independent heating systems 128 can be operated in other ways.
The heating systems 128 can be implemented in various ways. In the exemplary embodiment shown in
By using multiple heating systems 128 to supply heated gas to the center supply structure 130, it is possible to use components of the heating systems 128 (that is, the heaters 136, blowers 138, and/or motors 140) that are smaller than those that would otherwise be used in an oven employing only a single heating system. This can reduce the cost of the overall oven 100 and/or make it easier to assemble and service the heating systems 128.
Each oven 100 also includes two return structures 142-1 and 142-2 within the oxidation chamber 102. The first return structure 142-1 is positioned near the first end wall 116. The second return structure 142-2 is positioned near the second end wall 118. Each of the return structures 142-1 and 142-2 includes a plurality of return channels (not shown) that are each stacked one above another and that are positioned to generally correspond with the positions of corresponding nozzles 132 of the center supply structure 130. Gaps are provided between the return channels to enable passage of fibrous segments between the return channels.
The return channels of the first return structure 142-1 are configured to receive at least a portion of the gas directed from the center supply structure 130 toward the first end wall 116. That is, the first return structure 142-1 receives gas directed from both the lower and upper nozzles 132-1 and 132-2 of the center supply structure 130 toward the first end wall 116. Similarly, the return channels of the second return structure 142-2 are configured to receive at least a portion of gas directed from the center supply structure 130 toward the second end wall 122. That is, the second return structure 142-2 receives gas directed from both the lower and upper nozzles 132-1 and 132-2 of the center supply structure 130 toward the second end wall 118.
As shown in
In the exemplary embodiment shown in
In the exemplary embodiment shown in
In this exemplary embodiment, each heater 136 is implemented within the corresponding return duct 146. More specifically, each return duct 146 is implemented in two modules. Each return duct 146 includes a respective first module 154 that is connected at one end to the side wall 108 of the chamber 102 and is in fluid communication with a respective one of the return outlets 148. Each such first module 154 is also connected at the other end to an inlet of the corresponding heater 136. Each return duct 146 also includes a respective second module 156 that is connected at one end to the outlet of the corresponding heater 136 and that is connected at the other end to the inlet of a corresponding blower 138.
In this exemplary embodiment, the center module 150 is configured to also house the blowers 138 and supply ducts 134 for both of the heating systems 128. As shown in
By implementing the heaters 136 in the return ducts 146, the same central module 150 (which houses the blowers 138 and supply ducts 134 for both heating systems 128 and to which the motors 140 are mounted) can be used with different heaters 136 and heater configurations by changing or adjusting the heaters 136 and return ducts 146. That is, different heater configurations can be used with the same center module 150.
In the exemplary embodiment shown in
As shown in
As shown in
Method 600 comprises heating gas using a first heating system 128-1 (block 602 shown in
Method 600 further comprises directing the heated gas from the first heating system 128-1 to the center supply structure 130 (block 606) and supplying the heated gas from the center supply structure 130 into a first portion of the interior of the chamber 102 from a location between the first and second ends 120 and 122 of the chamber 102 (block 608). In this exemplary embodiment, the first portion of the interior of the chamber 102 is the upper portion of the chamber 102. Heated gas from the first heating system 128-1 is supplied to the nozzles 132-1 in the center supply structure 130 that are in the upper portion of the chamber 102. The upper nozzles 132-1 supply the heated gas from the center of the chamber 102 towards both the first and second ends 120 and 122 of the chamber 102.
Likewise, method 600 further comprises directing the heated gas from the second heating system 128-2 to the center supply structure 130 (block 610) and supplying the heated gas from the center supply structure 130 into a second portion of the interior of the chamber 102 from a location between the first and second ends 120 and 122 of the chamber 102 (block 612). In this exemplary embodiment, the second portion of the interior of the chamber 102 is the lower portion of the chamber 102. Heated gas from the second heating system 128-2 is supplied to the nozzles 132-1 in the center supply structure 130 that are in the lower portion of the chamber 102. The lower nozzles 132-2 supply the heated gas from the center of the chamber 102 towards both the first and second ends 120 and 122 of the chamber 102.
With method 600, the heated gas that is supplied to the first (upper) portion of the chamber 102 can be heated to a different target temperate than the heated gas that is supplied to the second (lower) portion of the chamber 102. As noted above, this provides additional process variables that can be adjusted in order to further refine the overall oxidation process.
For example, as described above, where the first heating system 128-1 is used to supply heated gas to the upper portion of the chamber 102 and the second heating systems 128-2 is used to supply heated gas to the lower portion of the chamber 102, the first heating system 128-1 can be operated at target temperature that is slightly higher (for example, 1-5 degrees Celsius) than the target temperature at which the second heating system 128-2 is operated. In this way, a slight temperature difference can be established between the upper and lower portions of the chamber 102. As a consequence, the speed at which the fibrous segments can be run through the oven 100 can be increased since the higher temperature in the upper portion shortens the required residence time. This can be done without using of a physical barrier between the upper and lower portions of the chamber 102 since the fibrous segments that pass between the upper and lower nozzles 132-1 and 132-2 typically provide sufficient thermal isolation between the upper and lower portions of the chamber 102 to maintain different temperatures in the upper and lower portions of the chamber 102. As noted above, in some common applications, each degree Celsius by which the temperature of the upper portion of the chamber 102 is increased relative to the temperature of the lower portion of the chamber 102 can result in at least a one percent increase in line speed.
Method 600 further comprises receiving, using a first return structure 142-1 positioned near the first end 120 of the chamber 102, at least a portion of the heated gas directed into the chamber 102 toward the first end 120 (block 614). Method 600 further comprises directing at least a portion of the heated gas received using the first return structure 142-1 to a first return outlet 148-1 formed in a side wall 108 of the chamber 102 (block 616) and receiving, in the first heating system 128-1, at least a portion of the heated gas directed to the first return outlet 148-1 (block 618). In this exemplary embodiment, the gas directed out of the first return outlet 148-1 is directed to the first heating system 128-1 via the first (upper) return duct 146-1. The gas that is returned to the first heating source 128-1 is heated by it and directed to the center supply structure 130 for supplying into the first (upper) portion of the chamber 102 as described above in connection with blocks 602, 606, and 608.
Likewise, method 600 further comprises receiving, using a second return structure 142-2 positioned near the second end 122 of the chamber 102, at least a portion of the heated gas directed into the chamber 102 toward the second end 122 (block 620 shown in
Embodiments of method 600 are suitable for use with modular oxidation ovens of the type described above in connection with
The embodiments described above are merely exemplary and are not intended to be limiting. For example, in the embodiments described above, the nozzles of the center supply structure are supplied from a single side; however, it is to be understood that other types of supply structures can be used (for example, a center supply structure and nozzles that are fed from both sides can be used). Also, in the embodiments described above, the return ducts are implemented outside of the walls of the chamber. However, as noted above, it is to be understood that the return ducts can be implemented in other ways (for example, the return ducts can be implemented at least in part within the walls of the chamber). Furthermore, in the embodiments described above, the heating systems are implemented in a modular manner with the heaters implemented in the return ducts; however, it is to be understood that the heating systems can be implemented in other ways (for example, the heating systems can be implemented in a more conventional non-modular manner).
A number of embodiments have been described. Nevertheless, it will be understood that various modifications to the described embodiments may be made without departing from the spirit and scope of the claimed invention.
Example 1 includes an oven for heating fibers, the oven comprising: a plurality of walls forming a chamber; and a supply structure disposed within the chamber between first and second ends of the chamber; wherein the supply structure is in communication with a first heating system and is configured to direct heated gas from the first heating system into a first portion of the chamber; and wherein the supply structure is in communication with a second heating system and is configured to direct heated gas from the second heating system into a second portion of the chamber.
Example 2 includes the oven of Example 1, wherein the first and second portions of the chamber comprise lower and upper portions of the chamber, respectively.
Example 3 includes the oven of any of the Examples 1-2, wherein each of the first and second heating systems comprises: a respective heater; and a respective blower to draw gas through the respective heater.
Example 4 includes the oven of Example 3, wherein the respective heater of each of the first and second heating systems comprises at least one heating element.
Example 5 includes the oven of any of the Examples 3-4, wherein each of the first and second heating systems further comprises a respective motor.
Example 6 includes the oven of any of the Examples 1-5, wherein the supply structure comprises a plurality of nozzles, wherein a first subset of the nozzles are in fluid communication with the first heating system and are used to supply heated gas from the first heating system to the first portion of the chamber and wherein a second subset of the nozzles are in fluid communication with the second heating system and are used to supply heated gas from the second heating system to the second portion of the chamber.
Example 7 includes the oven of any of the Examples 1-6, wherein first and second return outlets are formed in at least one of the plurality of walls that form the chamber; and wherein the oven further comprises: a first return structure positioned near a first end of the chamber and configured to receive at least a portion of the heated gas directed into the chamber, the first return structure configured to direct at least a portion of the received heated gas to the first return outlet; a second return structure positioned near a second end of the chamber and configured to receive at least a portion of the heated gas directed into the chamber, the second return structure configured to direct at least a portion of the received heated gas to the second return outlet; and a first return duct located external to the plurality of walls that form the chamber, the first return duct providing fluid communication between the first return outlet and the first heating system; and a second return duct located external to the plurality of walls that form the chamber, the second return duct providing fluid communication between the second return outlet and the second heating system; and wherein the first heating system is configured to receive at least a portion of the heated gas directed to the first return outlet; and wherein the second heating system is configured to receive at least a portion of the heated gas directed to the second return outlet.
Example 8 includes the oven of any of the Examples 1-7, wherein the first and second heating systems are independently controllable.
Example 9 includes the oven of any of the Examples 1-8, wherein the first heating system is configured to heat gas to a first target temperature and wherein the second heating system is configured to heat gas to a second target temperature that differs from the first temperature.
Example 10 includes a method of heating fibers using an oven in which a chamber is formed, the method comprising: heating gas using a first heating system; heating gas using a second heating system; supplying the heated gas from the first heating system into a first portion of the chamber; and supplying the heated gas from the second heating system into a second portion of the chamber.
Example 11 includes the method of Example 10, further comprising: directing the heated gas from the first heating system to a supply structure disposed between first and second ends of the chamber, wherein supplying the heated gas from the first heating system into the first portion of the chamber comprises supplying, from the supply structure into the first portion of the chamber, the heated gas from the first heating system; and directing the heated gas from the second heating system to the supply structure, wherein supplying the heated gas from the second heating system into the second portion of the chamber comprises supplying, from the supply structure into the second portion of the chamber, the heated gas from the second heating system.
Example 12 includes the method of any of the Examples 10-11, wherein heating gas using the first heating system comprises heating gas using at least one heating element included in the first heating system; and wherein heating gas using the second heating system comprises heating gas using at least one heating element included in the second heating system.
Example 13 includes the method of any of the Examples 10-12, further comprising: receiving, using a first return structure positioned near the first end of the chamber, at least a portion of the heated gas directed into the chamber; directing at least a portion of the heated gas received using the first return structure to a first return outlet formed in the chamber; receiving, in the first heating system, at least a portion of the heated gas directed to the first return outlet; receiving, using a second return structure positioned near the second end of the chamber, at least a portion of the heated gas directed into the chamber; directing at least a portion of the heated gas received using the second return structure to a second return outlet formed in the chamber; and receiving, in the second heating system, at least a portion of the heated gas directed to the second return outlet.
Example 14 includes the method of any of the Examples 10-13, wherein heating gas using the first heating system comprises heating gas using the first heating system to a first target temperature, and wherein heating gas using the second heating system comprises heating gas using the second heating system to a second target temperature, wherein the first target temperature differs from the second target temperature.
Example 15 includes the method of Example 14, wherein the first target temperature is higher than the second target temperature.
This application claims the benefit of U.S. patent application Ser. No. 14/257,383, filed Apr. 21, 2014, which claims priority to U.S. Provisional Patent Application Ser. No. 61/816,376, filed Apr. 26, 2013. The entireties of U.S. patent application Ser. No. 14/257,383 and U.S. Provisional Patent Application Ser. No. 61/816,376 are incorporated herein by reference.
Number | Date | Country | |
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61816376 | Apr 2013 | US |
Number | Date | Country | |
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Parent | 14257383 | Apr 2014 | US |
Child | 15392257 | US |