This invention is directed to a sealing mechanism for a steam chest which is used in textile production.
It is known that steam can be used to facilitate the manufacture of textile materials, e.g., fibers, yarns, filaments, tows, and fabrics. See U.S. Pat. Nos. 3,452,132; 4,639,347; 4,704,329; and the other references mentioned below, each of which is incorporated herein by reference. In general, steam treatments are used, for example, to facilitate drawing, annealing, heat setting, and/or relaxing of the textile materials. Steam treatments are also used during application of certain dyes and chemicals to textile materials, as disclosed, for example, in U.S. Pat. Nos. 3,349,578 and 3,889,495. To simplify the discussion here, the textile material described below will be a filament yarn or tow, it being understood that the apparatus and processes, set forth below, can be applied equally to other textile materials, e.g. woven or knit fabrics, which require steam treatment.
Steam treatment is the application of steam to the textile material so that heat from the steam is imparted to the material. (Steam treatment may be used to also impart heat to a dye or other chemical product being applied to a textile material and the apparatus and methods of this invention may be used in such a treatment. However, the present disclosure will focus on the steam treatment of textile material, itself.) This treatment is typically conducted in an enclosure, a steam chest. The chest has a steam inlet and two apertures through which the continuous textile material may pass, i.e. a material inlet and a material outlet. Typically, these apertures are shaped as long, narrow slits to accommodate sheet-like material, with the long dimension (length) of the aperture being in the direction of the width of said sheet-like material and the width of the aperture being in the direction of the thickness of said sheet-like material. Inside the chest, the steam comes in contact with the material and heat is transferred to the material. The heat available for transfer comes, primarily, from the condensation of the steam, and the material will acquire heat until it comes to equilibrium with the condensation temperature of the steam. So, if the process requires the material to be heated to 100° C., then steam at atmospheric pressure may be used. To attain higher temperatures, one may either use superheated steam or pressurize the chest to increase the condensation temperature. The latter is preferred. So, if the process requires a temperature of 150° C., then steam at about 476, kPa (or 54, psig) may be used.
The efficiency of the steam chest is determined by the amount of steam needed to heat the material. In practice, not all the steam entering the chest is used to heat the material because of leakage at the apertures. This leakage becomes greater as the steam pressure (i.e., the condensation temperatures) increases, so efficiency will decrease. One way of reducing leakage would be to decrease the width of the aperture, but the practical limit is that the moving material cannot contact the stationary surfaces of the aperture because of the risk of abrasion or snagging. Moreover, the material undergoes considerable vibration due to turbulence and high velocity steam escaping through the aperture. With a clearance of at least one (1) millimeter above and below the material and a pressure of about 500, kPa one could expect a steam leakage rate in excess of 50, kg of steam per hour per centimeter length of aperture. A typical commercial textile tow processing rate is about 50, kg of tow per hour per centimeter length of aperture. Accordingly, the steam leakage rate is nearly equal to the processing rate. But only about 10% of that steam is needed to heat that material to the steam condensation temperature. Therefore, this process is only about 10% efficient.
Several solutions to this leakage problem have been suggested. These solutions may be grouped into three categories. Those categories include labyrinth seals, nip roll seals, and sonic seals.
Labyrinth seals are set forth in U.S. Pat. Nos. 3,349,578; 4,332,151; 5,287,606; and Japanese Unexamined Patent Publications (Kokais) Nos. 5-33237; 5-44132; 5-339839; 6-93554; 6-57573; and 8-246330. For example, in U.S. Pat. No. 4,332,151, labyrinth seals are illustrated as tubes having a plurality of apertures through which yarn is passed into and out of the steam chest. Also see, Japanese Kokai 6-57573, labyrinth seals enclose nozzles at ends of the steam chest. Yarn may be abraded, snagged, or damaged by contact with elements of this seal, so sufficient clearance must be provided to accommodate the yarn's vibration. In the foregoing example, the clearances lead to high steam losses which can only be prevented with very long seals with a large number of chambers. Such seals are costly and lead to alignment problems.
Nip roll seals are illustrated in U.S. Pat. Nos. 3,808,845; 4,064,582; 4,111,434; 4,087,992; 4,064,713; 4,089,194; 4,184,346; and 4,949,558. For example, in U.S. Pat. No. 4,111,434, a nip roll seal mechanism is installed at the feed and takeout apertures of the steam chest. Rollers are intended to block the escape of steam from a passage which is in communication with the steam chest. The seal is formed by the nip between the rollers through which the tow passes. To minimize steam loss, the nip roll pressure must be higher than the steam pressure, and this can be a source of fiber fusion and damage.
Sonic seals are illustrated in German Patent Specification DE19546783Cl and U.S. patent application Ser. No. 09/334,140, filed Jun. 15, 1999, of Reese and Goodall. In German Patent DE19546783Cl, the device consists of an upstream jet, an injector jet, a treatment channel with no entry and exit seals, but instead three constriction zones. In operation, this arrangement of elements acts to seal the device from steam loss by developing a stationary shock wave that reduces pressure at the aperture. Such seals are useful for small scale, but are not practical for commercial lines because both capital costs and operating costs are high or prohibitive.
In view of the foregoing, there is still a need for a simple, low cost sealing mechanism which will increase efficiency and reduce noise.
The invention is a sealing mechanism for a steam chest used in the manufacture of textile materials. The term “manufacture” is intended here to include both the production of a textile material and the further treatment of a textile material, e.g. with a dye or chemical, to impart a desired characteristic thereto.
A further aspect of this invention is a device for heating continuous textile materials comprising: a steam chest having a steam inlet, a material inlet, and a material outlet. A first seal means is located adjacent to the material inlet. A second seal means is located adjacent to the material outlet. At least one of the seal means comprises a plurality of expansion chambers located along a curvilinear material path.
A still further aspect of the invention is a method for moving a textile material into and/or out of a steam chest via improved seal means.
For the purpose of illustrating the invention, there is shown in the drawings a form which is presently preferred; it being understood, however, that this invention is not limited to the precise arrangements and instrumentalities shown.
Referring to the drawings, wherein like numerals indicate like elements, there is shown in
While the seals are shown at the ends of the steam chest 14 according to the preferred embodiment of
The seals 16 may be outside the body of the steam chest 14. In accordance with this embodiment they may be joined in a sealed union to the steam chest by suitable means, such as flanges and bolts (not shown). Enclosures are thereby formed wherein, respectively, the first and second seals 16 communicate with the steam chest 14 and the material inlet of the steam chest is suitably aligned with a material outlet at the downstream end of the curvilinear material path of the first seal 16 to receive material, e.g. a tow, therefrom and a material inlet at the upstream end of the curvilinear path of the second seal 16 is suitably aligned with the material outlet of the steam chest to receive material therefrom.
In accordance with another embodiment of the invention, a seal 16 may be located within the body of the steam chest 14 at each end thereof. The upstream end (relative to the direction of movement of a textile material therethrough) of the curvilinear material path of the first seal 16 is suitably aligned with the material inlet of the steam chest so that material entering the steam chest can be drawn into and through the first seal and the downstream end of the curvilinear material path of the second seal is suitably aligned with the material outlet of the steam chest for transport of a textile material from the former and through the latter.
Referring to
Lower frame 22 and upper frame 24 are disposed opposite one another and comprise the bottom closure and the top closure, respectively, of seal 16. In addition, each frame comprises parts of the sidewalls of the seal, as shown in
Each of frames 22 and 24 may be comprised of sections which are held together by suitable means, such as bolts, and can be separated for convenience in installing and removing rollers. Three such sections are shown in
The term “Surrounding” as set forth above and hereinafter is not intended to mean that each of rollers 26, 28 and 30 is completely encircled by a plurality of expansion chambers 32. Rather, as shown in
Also, in accordance with the embodiment of the invention shown in
In the embodiment shown in
Each expansion chamber 32 extends parallel to the longitudinal axis of the roller to which it is adjacent and has a length which, preferably, is substantially at least as long as that portion of the total length (end to end) of said roller which is adapted for contact with the textile material to be transported therethrough. Put another way, the length of each expansion chamber is preferably at least as great as the width of the towband or other textile material as transported through the seal 16.
Each first and/or second plurality of expansion chambers 32 may be a separate unit which is attached to frame 24 or 22, respectively. However, it is preferably an integral part of the frame. More preferably, each expansion chamber 32 comprises a groove in the surface of the inner side of a frame 22 or 24, whereby the deepest portions of the grooves comprise the recessed surfaces and the lands between adjacent grooves comprise the non-recessed surfaces of each plurality of expansion chambers.
Each plurality of expansion chambers is disposed along a curve opposite a portion of the surface of a roller adjacent thereto. Preferably, the non-recessed surfaces of which each plurality of expansion chambers is comprised, as described above, is disposed along a segment of a circle which has a slightly larger radius than and is substantially concentric with said roller. More particularly, each first and second plurality of expansion chambers preferably forms a segment of a right circular cylinder which has a slightly larger radius than and is concentric with the adjacent roller. The difference between the radius of said circle or the internal radius of said cylinder and the radius of the adjacent roller constitutes the clearance between the roller surface and the expansion chamber discussed above.
Preferably, each first and second plurality of expansion chambers is opposite a segment of the circumference of the roller to which it is adjacent, which segment is at least about 50°. More preferably, each first and second plurality of expansion chambers which is adjacent to the portion of a roller which is adapted to be in contact with the tow during its passage through the seal 16 is opposite to substantially the entire segment of the surface of said roller with which the tow is in contact at any given instant.
The rollers 26, 28 and 30 are parallel to one another along their longitudinal axes, which axes are preferably disposed generally horizontally within the seal 16. Said longitudinal axes are disposed transversely, particularly perpendicularly, to the direction of transport of the tow from the inlet to the outlet of the seal. Typically, each roller extends substantially from sidewall to sidewall of the frame 22 or 24 by which it is supported, with sufficient spacing between each end of each roller and the respective adjacent sidewall to avoid excessive friction and/or wear without permitting excessive leakage of steam through the seal 16. However, other arrangements are possible, such as that shown in
Because of the sealing effect provided by each combination of a plurality of expansion chambers 32 and the roller 26, 28 or 30 to which it is in closest proximity, it is not necessary that the rollers which are adjacent to one another be in contact with each other, much less in pressure contact as in nip roll seals discussed above. Rather, adjacent rollers may be, and preferably are, spaced from one another as shown in
The seals 16 abut the chest 14 and form a fluid tight seal therebetween. The steam's only escape paths are along the curvilinear paths, those curvilinear paths being defined by the surfaces of rollers 26, 28, 30. While three rollers are preferred, it is understood that as few as two rollers, or more than three rollers could also work, the tradeoffs being cost for efficiency.
In operation, textile material to be treated or which has been treated in a vessel containing a gas, especially steam, under elevated pressure is drawn into or from the vessel through the sealing device (“seal”) of the present invention at the inlet and/or outlet of said vessel. Within the sealing device the material passes in a sinuous path over the surface of a portion of a first roller and then over the surface of a portion of an adjacent second roller through clearances between said surfaces and the plurality of expansion chambers adjacent to the respective roller which forms with that respective roller a curvilinear labyrinth seal. Preferably, each first and second plurality of expansion chambers along a curvilinear path defined by the surface of a roller forms with that roller a curvilinear labyrinth seal.
By supporting the tow on the roller surfaces, the vibration of the tow is substantially reduced or eliminated. As a result, the clearances may be significantly reduced. By making the clearances smaller, the apertures through which steam escapes are made smaller. The loss rate through the seal is directly proportional to the size of the aperture. Therefore, by reducing the aperture size by half one can decrease the loss rate of the seal by half. The curvilinear path also improves the efficiency of the expansion chambers relative to that of a linear labyrinth seal where all the steam apertures are aligned in a straight line. The purpose of each chamber is to permit the forward velocity of the escaping steam to dissipate, so that the kinetic energy from one aperture is not carried into the next. The curvilinear arrangement of apertures prevents the steam escaping from one aperture from impinging directly into the following one. The expansion chambers can preferably be shorter and more numerous than in a linear array, providing more efficiency within a given space. Therefore, the efficiency of the steam chest is increased by the seal.
In
During operation, the tow tends to spread out over the roller surface, and may fall off the surface and into the bearings supporting the rollers. In
In
In
In
In
Finally, another embodiment to lessen or prevent the movement of the tow off the roller surface (not illustrated) involves the fluid pressurization of the space between the lateral side of the roller and the frame. The pressure may be generated from the primary steam supply.
Another feature which has been tried but is not currently preferred is to mount a vertical guidepost for the tow on either side of the outlet on the exterior of the outlet end of the seal.
As discussed above, the apparatus and methods of this invention to other textile materials besides tow, including forms of textile material which may not tend to fall off the roller surface. Accordingly, it is to be understood that the present invention includes embodiments which do not include mechanisms, such as those shown in
While the present disclosure has been directed to the applicability of the present invention to steam treatment, it is believed that it is further applicable to the sealing of vessels containing other fluids besides steam which are under elevated pressure.
The entire disclosure of U.S. patent application Ser. No. 09/712,331, filed Nov. 14, 2000, is incorporated herein by reference.
The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof such as, for example the upper frame 24 and the lower frame 22 could be reversed (frame 22 on top of frame 24), or side-by-side (i.e. left frame 22 and right frame 24, or vice versa), with the other parts of the seal being oriented accordingly. Therefore, reference should be made to the appended claims, rather than to the foregoing specification, as indicating the scope of the invention.
This application is a continuation-in-part of U.S. patent application Ser. No. 09/712,331, filed Nov. 14, 2000 now abandoned.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US01/47519 | 11/14/2001 | WO | 00 | 4/18/2003 |
Publishing Document | Publishing Date | Country | Kind |
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WO02/070808 | 9/12/2002 | WO | A |
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Number | Date | Country | |
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20040000176 A1 | Jan 2004 | US |
Number | Date | Country | |
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Parent | 09712331 | Nov 2000 | US |
Child | 10399727 | US |