This invention relates generally to tubing utilized in steam generating equipment and, more specifically, to a method of forming internally ribbed boiler tubes. The ribbing provides controlled internal flow disruption within the tubes to prevent stagnation of the steam bubbles that are formed during nucleate boiling; i.e., an operating condition wherein stagnating steam bubbles form an insulating layer which impedes the passage of the heat through the tube wall to the water flowing therein.
A major operating component of any conventional steam generating system is the boiler. The generation of steam is commonly accomplished by passage of water through a multiplicity of tubes, during which passage the water is sufficiently heated so as to cause it to change state; i.e., to change from a liquid to a vapor.
As the water flows through the tube, the water in closest proximity to the inner wall of the tube becomes heated by the heat being transmitted through the tube wall. This outer layer of water changes to steam. During this process of changing to steam, the first change which the outer layer of water undergoes is the formation therein of steam bubbles. The steam bubbles act as an insulating layer. Unless the steam bubbles are made to mix with the water in the tube, they will remain adjacent the tube wall, and take on the attributes of an insulating layer or film, thereby causing localized hot spots to develop along the tube wall. These hot spots, in turn, can cause overheating of the tube, and ultimately lead to tube failure. Additionally, unless they are made to mix, the steam bubbles by virtue of their insulating capability will also function to prevent further heating of the core of water, which is passing rapidly through the center the tube.
Thus, in order to achieve the rapid and efficient transfer of heat through the tube walls to the water flowing therein, a need exists to provide some form of means to break up the laminar flow of water through the tube and to effect the mixing of the outer layer of water and thereby also the steam bubbles entrained therein with the core of water flowing through the central region of the tube. One such means which has been employed in the prior art involves the usage of ribbing (lands or grooves) on the internal surfaces of the boiler tubes.
As regards the nature of the existing prior art relating to methods of making boiler tubes with ribbed inner wall surfaces, reference may be had to U.S. Pat. Nos. 3,088,494; 3,213,525; 3,272,961; 3,289,451 and 3,292,408. U.S. Pat. No. 3,088,494, which issued to P. H. Koch et al., is directed to providing a vapor generating tube that has its interior wall formed with helical lands and grooves, which are proportioned and arranged in a particular predetermined fashion. U.S. Pat. No. 3,213,525, which issued to W. M. Creighton et al., is directed to a method of forming an internal rib in the bore of a tube wherein material is removed from the inner tube wall by means of a cutting operation to form the subject ribbing. A still further example of these prior art teachings can be found in U.S. Pat. No. 3,272,961, which issued to L. A. Maier, Jr. et al., and wherein a method and apparatus are taught for making ribbed vapor generating tubes and in accordance with which a rib is deposited on the inside surface of the tube by means of a welding process. U.S. Pat. No. 3,289,451, which issued to P. H. Koch et al., is directed to a method and apparatus for forming internal helical ribbing in a tube wherein the internal ribbing is formed by means of a cold drawing operation. Finally, U.S. Pat. No. 3,292,408, which issued to J. R. Hill, is directed to a method of forming internally ribbed tubes wherein the tube is provided with an asymmetrical helical groove so as to facilitate removal of the forming tool from the tube.
Notwithstanding the existence of these prior art teachings, there is a need for a new and improved method of providing boiler tubes with a ribbed interior surface. The prior art methods that have been employed for this purpose have notable disadvantages and can be relatively expensive to employ.
One disadvantage in using these prior art methods and apparatus is the difficulty in successfully removing the forming member from the tube following completion of the metal deformation process. Generally, a member having a predetermined external configuration, such as a helical pattern, is inserted into the tube, and thereafter the tube is reduced in diameter such that the helical pattern on the member is formed in the inner wall of the tube. In order to remove this member from the tube it is necessary, because of the fact that the interior surface of the tube has been deformed so as to become essentially an exact complement of the member's external surface, to virtually unscrew the member from the tube to effect the removal of the former from the latter. The degree of difficulty in effecting the removal of the member from the tube depends on the length of the member which has been inserted into the tube, and the relative extent to which the pattern formed on the inner tube wall is a true complement of the pattern formed on the external surface of the aforesaid member.
Current methods of fabricating single lead rib (SLR) boiler tubes and multi-lead rib (MLR) boiler tubes often requires either mechanical or metallurgical deformation processing wherein a smooth tube is drawn over a slotted, rotating mandrel. During this process, the smooth interior surface of the tube is plastically deformed and forced to progressively conform to the slotted mandrel shape, thereby producing helical lead ribs along the tube length. This deformation process is not only difficult and costly but is also inherently limited in its ability to accurately produce rib cross-sectional shapes with the desired geometric detail and with the required dimensional accuracy. The conventional metallurgical processes are limited in their ability to produce optimized rib lead angles of 40° or more.
Further, the production of SLR and MLR tubes from high temperature, high strength, and deformation-resistant materials (such as alloy 800H), is very difficult using conventional deformation processing methods.
One aspect of the present invention is drawn to provide a new and improved method of making boiler tubes wherein the latter are provided with means operative to cause a controlled internal flow disruption to be effected therewithin.
Another aspect of the present invention is drawn to provide a method of making boiler tubes wherein the latter are provided with inner tube surfaces that are ribbed.
Another aspect of the present invention is drawn to a method of making ribbed boiler tubes wherein the ribbed pattern to be formed in the tube inner surface is established by detachably wrapping a wire-like member around the circumference of a spindle.
Yet another aspect of the present invention is drawn to a method of making a ribbed boiler tube wherein the spindle may be removed from the boiler tube leaving the wire-like member attached to the tube inner wall.
Yet still another aspect of the present invention is drawn to a method of making a ribbed boiler tube which is advantageously characterized by the fact that it is relatively inexpensive to utilize, relatively simple to employ, and is extremely flexible insofar as concerns the variety of different patterns of ribbing; i.e., helical, circular, etc. that can be formed therewith in boiler tubes.
Accordingly, the method of the present invention involves fabrication of tubes having a smooth interior surface and a separate fabrication of the wire-like rib members, which are typically formed from a flat, non-circular metal wire. The wire-like rib members are typically trapezoidal in cross-section, but could also be rectangular, square or some other desired geometric shape including circular. The ribs are subsequently inserted and positioned within the smooth tube and braze-bonded to the interior tube surface to permanently affix the position and orientation of the ribs by using a corrosion resistant, nickel-based filler metal.
The SLR and MLR tubes and the wire-like rib members can be produced from a variety of different metal materials, including carbon steel, stainless steel and nickel-base alloys.
The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific benefits attained by its uses, reference is made to the accompanying drawings and descriptive matter in which preferred embodiments of the invention are illustrated.
In the drawings:
Referring to the drawings generally, wherein like reference numerals designate the same or functionally similar elements throughout the several drawings, and more particularly to
In accordance with the invention, a method is provided wherein a spindle 100, a portion of which has been depicted in
The spindle 100 is suitably dimensioned so as to be received within the boiler tube 20. More specifically, the spindle 100 may take the form of any suitable conventional type of metallic, ceramic, natural, or polymeric member that is substantially cylindrical in configuration, and which is capable of being utilized in the manner of a spindle. Alternatively, spindles without channels 2 may be used.
As shown in
The ends 8 of the wire-like member 6 are then temporarily affixed to the ends 4 of the spindle 100 for the purpose of holding the wound, elastically-compressed member 6 within the helical channel 2, or smooth surface is a channel is not used, of the spindle 100.
With the wire-like member 6 having been wound in the channel 2 of the spindle 100, the next step in accordance with the method of the present invention, as shown in
Referring to
Once the wire-like member 6 is conformed to the inner tube wall 22, the next step that is performed in accordance with the present invention is the removal of the spindle 100 from the interior of the boiler tube 20.
After the spindle 100 is removed, the wire-like member 6 is brazed to permanently affix its position and orientation within the tube 20. Brazing of the wire-like member 6 to the inner surface 22 of the tube 20 could be done by heating the tube 20 to the melting temperature of the brazing filler metal 16 in a gas-fired or electric continuous mesh-belt conveyor furnace, a gas-fired or electric roller hearth conveyor furnace, a gas-fired or electric box furnace, induction heating, or any other means of applying heat to the assembly.
Several brazing filler metals are available which could be used to bond the wire-like member to the tube interior surface. However, it should be recognized that the different alloying elements in brazing filler metal BNi-2 (where Ni=82.6%, Cr=7%, Fe=3%, Si=4.5%, B=2.9%) together will depress the melting point of the alloy to 1830° F. (where, for comparison, pure nickel melts at 2551° F.). If the time at brazing temperature with this filler metal is extended to about 1 hour, most of the boron will diffuse out of the braze joint and into the base metal of the tube and wire ribs. This will result in an integral, finished braze joint of Ni—Cr—Si—Fe with high strength, enhanced corrosion resistance and, due to the boron diffusion, a higher melting point (typically about 2300° F.) than the original brazing filler metal. Accordingly, BNi-2 is particularly amenable to bonding the wire ribs to the interior surface of tubes which are intended for operation at elevated temperatures.
After cooling of the tube 20, there is provided in accordance with the method of the present invention a boiler tube 20 that has a helical ribbed pattern formed on the inner wall 22 thereof. Reference may be had to
The cost of making SLR and MLR boiler tubes using the new method described above is competitive with the cost of making conventional SLR and MLR boiler tubing using metal deformation processing techniques. Use of this fabrication method provides greater flexibility in SLR and MLR design since parameters such as rib cross-sectional shapes and rib lead angles are not restricted by limitations in producing integral ribs through metal deformation processing. This greater flexibility enables development of a unique design for SLR and MLR boiler tubes, such as complex cross sections not achievable by the prior art deformation means, that improve performance at decreased production costs. Also, the production of SLR and MLR tubes from high temperature, high strength, deformation-resistant materials (such as alloy 800H) is very difficult using conventional deformation processing methods.
While a specific embodiment of the invention has been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.