The present invention relates generally to heat exchangers and more particularly to a quench exchanger with improved heat transfer characteristics.
The production of ethylene requires a number of process steps through which any of a variety of hydrocarbon feeds can be refined to generate various products including ethylene. The predominate process for producing ethylene is steam cracking. According to this process, hydrocarbon feed is heated in cracking furnaces and in the presence of steam to high temperatures. It is well known in the industry that shorter residence times within the furnaces results in a desirable selectivity to ethylene.
As such, once the desired conversion of feed has been achieved, the process gas must be rapidly cooled, or quenched, to minimize undesirable continuing reactions that are known to reduce selectivity to ethylene. The vast majority of ethylene furnaces currently in use employ so-called “transfer-line-exchangers” (TLEs), also referred to as “quench exchangers”, for this purpose. These devices are heat exchangers that rapidly cool the process gas by generating steam. The resulting steam is typically generated at high pressures (e.g. 600 to 2000 psig; 4150 to 13800 kpag).
Many of the TLEs in service employ a double pipe or double tube construction with the high temperature cracking furnace effluent introduced into the interior pipe, with a cooling medium such as water being introduced into the annular space between the two tubes. Double pipe exchangers may be configured as bundles or as so-called “linear” units. The advantage of the linear type units is that the adiabatic time between the furnace outlet and the cooling tube inlet can be minimized to allow an enhanced ethylene selectivity. Linear units also benefit from the lack of a tubesheet area which would otherwise be exposed to the hot process gas and are thus subject to various mechanical and erosion concerns. Further, in linear units, the process flow is more evenly distributed among the cooling tubes.
In order to achieve best selectivity to ethylene, it is necessary to minimize both the residence time (“fired time”) and the adiabatic time (“unfired residence time”) within an ethylene furnace. The unfired residence time refers to the amount of time required for the process effluent to pass from the fired zone of the furnace to the entrance of the TLE. One set of existing solutions which have been developed to minimize adiabatic time are typically called “close-coupled” type quench exchangers. According to this design, the quench exchanger tubes are connected directly to the furnace effluent tubes without intermediate manifolding.
Examples of this type of exchanger can be found in FIGS. 15, 16 and 17 of Herrmann and Burghardt, “Latest Developments in Transfer Line Exchanger Design for Ethylene Plants”, prepared for the presentation at AlChE Spring National Meeting, Atlanta, Ga., April 1994. Another close-coupled design is presented in U.S. Pat. No. 4,457,364, which discloses a “Close-Coupled Transfer Line Heat Exchanger Unit.” According to this design, “close-coupling” of the quench exchanger is achieved by using a dividing fitting which connects a radiant outlet tube to two or more quench exchanger tubes using a streamlined fitting. Using this arrangement, the quench exchanger tubes have a smaller inside diameter than the radiant tubes which feed them. Although this arrangement does achieve a low adiabatic residence time and thus has high selectivity to ethylene, it has presented problems in practical operation.
In particular, coke segments that have formed on the inner surface of the radiant tubes, when spalled off the tubes, have proven to not always be able to pass through the smaller diameter quench exchanger tubes. As such, furnaces so equipped must periodically be shut down to remove coke blockages from the quench exchanger inlet upstream of the heat exchanger tubes. As a result, current “close-coupled” quench exchanger designs require the quench exchanger tubes to be larger in diameter than the radiant coil outlet tube. Further, it is preferred to have no dividing fittings between the radiant outlet tube and the quench exchanger tube as in the design of U.S. Pat. No. 4,457,364 because these fittings can also create similar blockage problems.
In single pass radiant coil implementations, such as that shown in FIG. 15 of Herrmann, et al., it is possible to complete all the quench exchanger steam generation in a single pass. However, if two radiant tubes are combined into a single, larger diameter quench exchanger tube (as is geometrically advantageous and which eliminates the blockage problems of the U.S. Pat. No. 4,457,364 design), the quench exchanger length may approach or exceed the limits of commercial fabrication and shipping capabilities which are currently at approximately 60 linear feet (18.3 linear meters).
If a U-tube radiant coil is used, the flow rate per tube and the tube diameter increases and it is therefore not always possible to complete the desired steam generation in a single pass. The Herrmann reference presents two solutions in FIGS. 16 and 17, respectively. In the FIG. 16 embodiment, a two pass quench exchanger is used. In FIG. 17, a single pass quench exchanger is close coupled to the furnace coil and the effluent tubes of the single pass exchanger are manifolded together. Steam generation is completed in a circular TLE. Since the manifolding is performed after the effluent is quenched, there is no loss of selectivity to ethylene.
A similar approach to that shown in FIG. 17 may be undertaken using serpentine coils with 4 to 6 radiant tubes per pass. Such tubes generally have inside diameters in the range of 3 to 4 inches (76 to 100 mm). One drawback of this approach is that the close coupled exchanger must be able to cool the furnace effluent to approximately 1100° F. (590° C.) after the first pass to ensure that no reaction occurs in the higher residence time manifolding required upstream of the circular quench exchanger. As a result, this has effectively prevented the use of single pass, close coupled quench exchangers which include ethylene furnace coils having inside diameters of greater than about five inches (125 mm).
Ethylene furnaces are typically used for the production of a wide variety of products. This includes hydrogen at the light end to steam-cracked tar at the heavy end. As a general matter, the heavier the feedstock, the greater the yield of steam-cracked tar. In naphtha crackers, the effluent composition contains a tar content that is high enough that the heaviest components will commence condensing if cooled to approximately 600° F. (315° C.). As feed stocks get heavier, the tar yield rises and the temperature at which condensation commences also rises. Should condensation of the effluent occur in the quench exchanger, heat transfer is substantially impeded and a sharp increase in effluent outlet temperature results.
Since quench exchangers cool the effluent by generating steam at approximately 2000 psig (13,800 kpag) or less, the quench exchanger wall is generally at approximately 635° F. (335° C.) or less. It is therefore very important to prevent areas of low velocity or recirculation eddies in the quench exchanger tubes. If such areas exist, the effluent can be cooled to at or below its dew point and quench exchanger fouling can result.
In one aspect of the invention, a heat exchanger tube is provided. In this embodiment, the heat exchanger tube has a longitudinal axis, an interior surface defining the flow area of the tube, and an interior circumference in a plane perpendicular to the longitudinal axis; wherein the interior surface comprises a plurality of axially extending grooves aligned with the longitudinal axis; the grooves formed along the length of the tube and formed as a series of alternating concave and convex surfaces along at least a portion of the interior circumference; and wherein the length of the perimeter of the interior surface in the plane is at least about twenty percent longer than the interior perimeter of a circular tube having substantially the same flow area as the heat exchanger tube.
In another aspect of the invention, a transfer line heat exchanger unit connected to a steam cracking furnace is provided. In this embodiment, furnace effluent flows from a furnace outlet into at least one heat exchanger tube for cooling the furnace effluent; wherein the at least one heat exchanger tube has a longitudinal axis, an interior surface defining the furnace effluent flow area of said tube, and an interior circumference in a plane perpendicular to the longitudinal axis; and wherein the interior surface comprises a plurality of axially extending grooves aligned with the longitudinal axis; the grooves formed along the length of said tube and formed as a series of alternating concave and convex surfaces along at least a portion of the interior circumference; and wherein the length of the perimeter of the interior surface in the plane is at least about twenty percent longer than the interior perimeter of a circular tube having substantially the same flow area as the heat exchanger tube.
In another aspect of the invention, the heat exchanger tube is used to cool effluent from a hydrocarbon cracking furnace and is fed by at least one radiant tube associated with the furnace.
In another aspect of the invention, the concave and convex surfaces of the heat exchanger tube form a plurality of convex fins, and wherein the number of convex fins is equal to about 5 to about 7 times the inside diameter of the heat exchanger tube when measured in inches.
In another aspect of the invention, each of the concave surfaces of the heat exchanger tube has a concave nadir and each of said convex surfaces of the heat exchanger tube has a convex pinnacle; and wherein each of the convex pinnacles is located at substantially the same distance from the longitudinal axis and each of the convex nadirs are located at the same distance from the longitudinal axis. And in one embodiment, the convex pinnacles are located from about 0.75 inches (19.0 mm) to about 2.75 inches (69.8 mm) from the longitudinal axis; and each of the concave nadirs are located from about 1.0 inches (25.4 mm) to about 3.0 inches (76.2 mm) from the longitudinal axis.
In another aspect of the invention, the inside diameter of the heat exchanger tube is about 2 to about 3 inches (about 50 to about 76 mm) and the wall thickness of said heat exchanger tube is about 0.3 to about 0.5 inches (about 7.6 to 12.7 mm). And in one embodiment, each of the convex pinnacles are located from about 0.75 inches (19.0 mm) to about 1.4 inches (35.6 mm) from the longitudinal axis; and each of the concave nadirs are located from about 1.0 inches (25.4 mm) to about 1.5 inches (38.1 mm) from the longitudinal axis.
In another aspect of the invention, the length of the heat exchanger tube is from about 15 feet to about 60 feet (about 4.5 meters to about 18 meters).
In another aspect of the invention, the height of each groove is from about 0.1 inches (2.54 mm) to about 0.3 inches (7.62 mm).
In another aspect of the invention, the heat exchanger tube has an inside diameter of about 2 to about 6 inches (about 50 to about 152 mm); a wall thickness of about 0.2 to about 0.6 inches (about 5.1 to 15.2 mm); a groove height from about 0.1 inches (2.54 mm) to about 0.3 inches (7.62 mm); and a length of about 15 feet to about 60 feet (about 4.5 meters to about 18 meters).
The heat exchanger tube disclosed herein provides increased heat transfer efficiency relative to a fixed tube length and at the same time eliminates stagnant and low velocity areas as well as recirculation eddies. These benefits are obtained through the use of a fin profile fabricated with alternating concave and convex surfaces. Additionally, the fins are preferably aligned with the tube center line, or longitudinal axis, as opposed to being twisted or spiraled.
These and other advantages and features are described herein with specificity so as to make the present invention understandable to one of ordinary skill in the art.
The invention is further explained in the description that follows with reference to the drawings illustrating, by way of non-limiting examples, various embodiments of the invention wherein:
The present invention for a novel heat exchanger and related TLE tube is now described in specific terms sufficient to teach one of skill in the practice the invention herein. In the description that follows, numerous specific details are set forth by way of example for the purposes of explanation and in furtherance of teaching one of skill in the art to practice the invention. It will, however, be understood that the invention is not limited to the specific embodiments disclosed and discussed herein and that the invention can be practiced without such specific details and/or substitutes therefor. The present invention is limited only by the appended claims and may include various other embodiments which are not particularly described herein but which remain within the scope and spirit of the present invention.
One of the key aspects of the present invention is the use of a fin profile having alternating concave and convex surfaces on the process side of the TLE tube. Further, it is preferred that the fins are aligned with the center line (longitudinal axis) of the tube as opposed to twisting or spiraling the fins within the interior of the TLE tube. Through the use of the finned process tube of the present invention, various advantages may be obtained. For example, stagnant and low flow zones are reduced and/or eliminated as are recirculation eddies. As such, fouling problems are mitigated. Further, increased heat transfer function is obtained with the desirable result that tubes can be shortened while still meeting the required heat transfer characteristics for the furnace and process.
In one embodiment of the present invention, a heat exchanger tube is provided. The heat exchanger tube has a longitudinal axis, an interior surface defining the flow area of the tube, and an interior circumference in a plane perpendicular to the longitudinal axis; wherein the interior surface comprises a plurality of axially extending grooves aligned with the longitudinal axis; the grooves formed along the length of the tube and formed as a series of alternating concave and convex surfaces along at least a portion of the interior circumference; and wherein the length of the perimeter of the interior surface in the plane is at least about twenty percent longer than the interior perimeter of a circular tube having substantially the same flow area as the heat exchanger tube.
In a preferred embodiment, each of concave 120 and convex 130 surfaces are of similar size and shape to one another such that each of the concave 120 surfaces has a concave nadir 160 and each of said convex 130 surfaces has a convex pinnacle 150, and wherein each of said convex pinnacles 150 are located at substantially the same distance from said longitudinal axis 140 and each of said convex nadirs 160 are located at the same distance from said longitudinal axis 140. In a preferred embodiment, all concave surfaces 120 and convex surfaces 130 have the same radius.
The thickness of the tube wall 170 is determined by the steam pressure in the quench exchanger, which is in turn, determined by the particular application. For example, in one embodiment a typical wall thickness for a tube on the order of about 2 to about 3 inches (about 50 to 76 mm) inside diameter (measured from valley to opposing valley of the fins) may have a wall thickness of about 0.3 to about 0.5 inches (about 7.6 to 12.7 mm). In another embodiment, a typical wall thickness for a tube on the order of about 2 to about 6 inches (about 50 to about 152 mm) inside diameter may have a wall thickness of about 0.2 to about 0.6 inches (about 5.1 to 15.2 mm).
As will be readily skilled in the art, the teachings of the present invention may alternatively be applied to tubes of larger or small diameters and the number of fins per unit of diameter may also be increased or decreased as desired for the particular application. That being said, typical dimensions for the inside diameter of the exchanger tube may be in the range of about 2 inches to about 3 inches (about 50 to about 76 mm) for single pass and U-tube type radiant coil units.
For units which are close coupled to serpentine radiant coils, the corresponding exchanger tube inside diameter (measured from valley to opposing valley of the fins) may lie in the range of about 3 inches to 6 about inches (about 76 to about 152 mm) depending upon the diameter of the radiant coil. When used in connection with shell and tube type exchangers, or double pipe units in a bundle arrangement, the corresponding exchanger tube inner diameter may be in the range of about 1.5 inches to about 2.5 inches (about 38 to about 64 mm). Of course, larger and smaller sizes may also be used without departing from the scope or spirit of the present invention.
With specific reference to
The tube illustrated in
Turning now to
As can be seen from
Turning now to
In the embodiment illustrated by
An example of an application of the teachings of the present invention along with the achieved benefits thereof is now discussed. In this case, an older steam cracking furnace employs a four-pass serpentine radiant coil with each of the four radiant outlet tubes having an inside diameter of about 5.25 inches (133 mm). Prior to employing the teachings of the present invention, the four outlet passes are manifolded together and fed to a circular quench exchanger of the type shown in FIGS. 4 and 5 of the Herrmann paper, discussed above. In this state, the furnace experiences an undesirably long “unfired residence time” due to the time required for manifolding and the time required for the effluent to traverse the inlet chamber of the quench exchanger.
It is desirable to use a close-coupled double-pipe quench exchanger to quench the effluent from each of the four radiant passes. The geometrical constraints imposed by the existing furnace limit the length of the double-pipe quench exchanger to a maximum of thirty feet. Using a conventional, circular quench exchanger tube profile, the predicted outlet temperature from the double pipe exchanger is about 1190° F. (645° C.), which provides insufficient operating margin from the practical upper limit of about 1200 to about 1250° F. (about 650° C. to about 675° C.).
By using an internally finned quench exchanger tube such as the one described in connection with
The tubes and the extended surface feature of the present invention as described above may be incorporated into a variety of quench exchanger types and designs. For example and without limitation, the teachings herein may be applied to double pipe exchangers and shell and tube type exchangers. In the case of double pipe units, the design may be linear arrangements or arrangements with multiple units positioned in a bundle with a common inlet changer and a common outlet chamber. If arranged as a linear unit, the unit may be close coupled to the radiant coil to minimize adiabatic time between leaving the furnace fired zone and entering the quench exchanger.
When used as a linear, close coupled unit, it is preferable that one or more radiant tubes be included with one or more radiant tubes feeding each quench exchanger tube. It is preferable in this case that if the radiant coil is a single pass coil, 2 or 4 radiant tubes feed each quench exchanger tube. Alternatively, if the radiant coil is a two-pass or U-tube coil, it is preferable that one or two radiant coil feeds each quench exchanger tube. Further, if the radiant coil is a serpentine coil, it is preferred that one radiant coil feeds each quench exchanger tube.
In the event that the TLE tube of the present invention is incorporated into a shell and tube type exchanger or a double pipe exchanger with multiple double pipe units mounted together in a bundle with a common inlet chamber, multiple radiant coils can be fed to multiple quench exchanger tubes regardless of the radiant coil type.
The teachings of the present invention have particular application to processes with light feeds such as gas and naphtha cracking applications. Additionally, the TLE tubes and the heat exchanger incorporating said tubes may have application in other processes such as gas-oil and other heavy feed based processes. This includes, by way of example and not limitation, gas-oil cracking applications, other heavy feed applications including atmospheric and vacuum gas-oils as well as virgin and hydro-treated gas-oils (to include both mildly hydro-treated gas-oils and severely hydro-cracked gas-oils). Other feeds may include, for example, crude oil and crude oil fractions from which non-volatile components have been removed. Further, the invention may also have application to feeds comprising field condensates with high final boiling points (e.g. above about 600° F. (315° C.).
The foregoing disclosure of the preferred embodiments of the present invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many variations and modifications of the embodiments described herein will be apparent to one of ordinary skill in the art in light of the above disclosure. The scope of the invention is to be defined only by the claims, and by their equivalents.
This application claims priority to and benefit of Provisional application filed on Sep. 13, 2006, U.S. Ser. No. 60/844,186.
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