Cross corrugated media or fill has been a standard product in the cooling tower and trickling filter markets for decades and may also be utilized in oil/water separation, bio-towers, nitrification towers, demisters and related systems and markets. The cross corrugated media product has undergone few changes to the general configuration since its earliest configurations and has become a commodity for these markets. Basic changes such as limited microstructure features and dedicated glue bonds are relatively recent, minor changes to the cross corrugated media product. The cross corrugated media product is not differentiated by manufacturers in these markets nor is its design typically modified for these different applications, such as oil/water separation, bio-towers, nitrification towers, demisters.
Specific to the cooling tower industry, it would be advantageous to differentiate the cross corrugated media product based on the ability to retrofit a new product that meets the application requirements, improves existing tower performance capacity, and reduces the size of new cooling tower designs based on improved tower performance. One of the ways that a cooling tower performance can be characterized is by comparing the amount of fan horsepower required to meet its intended operating conditions. An improvement to overall performance of the cooling tower by replacing original, traditional cross corrugated media with replacement cross corrugated media that improves performance would be advantageous to fill manufacturers and the tower owner. In addition, improving overall performance of the cooling tower by designing and installing a tower that is smaller and has the same or improved performance when compared to the existing tower would be advantageous to fill manufacturers and tower owners.
The typical design of a cross corrugated fill includes a simple cross corrugated trapezoidal flute geometry with linear sidewalls in the trapezoid. These fill products have features or “microstructure” that are designed to increase the surface area of the fill and to mix the water film flowing over the surface of the microstructure in the fill. The increased surface area exposes a greater amount of the water film to the airflow in the film. Since fill thermal performance is dependent upon having increased mass transfer rates of water into the air stream, changes to microstructure may provide a benefit; however, any changes to the microstructure that result in pressure drop across the assembled fill products may reduce overall tower performance.
An aspect in design performance of a cross corrugated fill is to promote full distribution of water on the surface of the fill sheets. Full distribution of water on the surface increases the effective surface area of the water in contact with the air and enables higher mass transfer efficiencies. The tradeoff of full water distribution is typically the pressure drop generated by the changes to the surface and, in practice, the overall performance does not change significantly as the higher thermal performance is offset by the increased horsepower to overcome the change in pressure drop or a reduced airflow for the same horsepower is realized.
The capacity of the cooling tower is dependent on the amount of air passing though the fill. It would be advantageous to further reduce the pressure drop for a particular fill so that the existing horsepower fan provides more mass flowrate of air through the fill. This increased air flow through the tower typically enables the unit to achieve colder outlet water temperature or to cool a larger mass of water for a given set of operating conditions.
It would be advantageous to design, construct and deploy a cross corrugated media or fill that maintains a lower pressure drop with an increase in thermal performance over known fill products. The preferred embodiment of the cross corrugated media and fill packs address the disadvantages of the prior art media and fill by balancing pressure drop with increased surface area of the microstructure for particular operating conditions and applications.
Briefly stated, the preferred invention is directed to a cross corrugated fill pack assembly for cooling a fluid flowing through the pack with a gas flowing through the pack in a substantially opposing direction. The cross corrugated fill pack assembly includes a first sheet and a second sheet. The first sheet defines a longitudinal axis and has a first end, a second end and a first plurality of flutes extending from the first end toward the second end. A first microstructure is defined on the first sheet including first top flat strips, first bottom flat strips and first conduit sides connecting the first top flat strips to the first bottom flat strips. A plurality of first radii connect the first top flat strips to the first conduit sides and the first bottom flat strips to the first conduit sides. The first plurality of flutes extends at a first flute angle relative to the longitudinal axis. The first flute angle is approximately zero to forty-five degrees. The second sheet has a second plurality of flutes. A second microstructure is defined on the second sheet including second top flat strips, second bottom flat strips and second conduit sides connecting the second top flat strips to the second bottom flat strips. The first and second microstructure is generally arcuate or wavy in both longitudinal and lateral directions of the fill pack assembly or preferably forming sinusoidal-like waves along nearly any cross-section taken of the microstructure. In addition, the macrostructure or flutes that carry the microstructure 12 are also preferably angularly shaped in their cross-section defining a substantially sinusoidal-like wave taken along a line substantially perpendicular to the longitudinal direction of the flutes, as is shown in
In another aspect, the preferred invention is directed to a cross corrugated fill pack assembly for cooling a fluid flowing through the pack with a gas flowing through the pack in a substantially opposing direction. The cross corrugated fill pack assembly includes a first sheet and a second sheet. The first sheet defines a longitudinal axis and has a first end, a second end and a first plurality of flutes extending from the first end toward the second end. A first microstructure is defined on the first sheet including first top flat strips, first bottom flat strips and first conduit sides connecting the first top flat strips to the first bottom flat strips. A plurality of first radii connect the first top flat strips to the first conduit sides and the first bottom flat strips to the first conduit sides. The first plurality of flutes extends at a first flute angle relative to the longitudinal axis. The first flute angle is approximately zero to forty-five degrees. The second sheet has a second plurality of flutes. A second microstructure is defined on the second sheet including second top flat strips, second bottom flat strips and second conduit sides connecting the second top flat strips to the second bottom flat strips. A plurality of second radii connect the second top flat strips to the second conduit sides and second bottom flat strips to the second conduit sides. The first sheet is connected to the second sheet in an assembled configuration with the first plurality of flutes extending to an opposite side of the longitudinal axis relative to the second plurality of flutes in the assembled configuration.
In yet another aspect, the preferred invention is directed to a fill sheet for assembly into a fill pack for cooling a cooling medium in a cooling tower. The fill sheet includes a first end and a second end extending substantially parallel to the first end and generally perpendicularly relative to a longitudinal axis. The first and second ends extend substantially parallel to a lateral axis of the fill sheet. A plurality of flutes extends from the first end toward the second end at a first flute angle. Microstructure is defined on the plurality of flutes. The microstructure includes first top flat strips, first bottom flat strips and first conduit sides connecting the first top flat strips to the first bottom flat strips. A plurality of first radii connect the first top flat strips to the first conduit sides and the first bottom flat strips to the first conduit sides.
The foregoing summary, as well as the following detailed description of the preferred invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there are shown in the drawings embodiments which are presently preferred. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown. In the drawings:
Certain terminology is used in the following description for convenience only and is not limiting. Unless specifically set forth herein, the terms “a”, “an” and “the” are not limited to one element but instead should be read as meaning “at least one”. The words “right,” “left,” “lower,” and “upper” designate directions in the drawings to which reference is made. The words “inwardly” or “distally” and “outwardly” or “proximally” refer to directions toward and away from, respectively, the geometric center of the fill pack and related parts thereof. The terminology includes the above-listed words, derivatives thereof and words of similar import.
It should also be understood that the terms “about,” “approximately,” “generally,” “substantially” and like terms, used herein when referring to a dimension or characteristic of a component of the invention, indicate that the described dimension/characteristic is not a strict boundary or parameter and does not exclude minor variations therefrom that are functionally the same or similar, as would be understood by one having ordinary skill in the art. At a minimum, such references that include a numerical parameter would include variations that, using mathematical and industrial principles accepted in the art (e.g., rounding, measurement or other systematic errors, manufacturing tolerances, etc.), would not vary the least significant digit.
Referring to
Each of the sheets 10 has a flute height Hf of approximately nineteen millimeters (19 mm) in the preferred embodiment, but is not so limited and may have smaller or greater flute heights Hf depending on design parameters and preferences. The flute height Hf may, for example, be in a range of approximately five to thirty millimeters (5-30 mm) for various configurations and applications. A first sheet 10a of the sheets 10 is shown as a representative example of the sheets 10 in
Each sheet 10 of the preferred cross corrugated media or fill 100 includes a first portion 22 and a second portion 24. The first portion 22 extends between a central row of connectors 18c and the first end 11a and the lower portion 24 extends between the central row of connectors 18c and the second end 11b. The sheets 10 are not limited to including the first and second portions 22, 24 and may be comprised of a single portion, such as the first portion 22, which is the upper portion of the first sheet 10a, or the second portion 24, which is the lower portion on the first sheet 10a, or may include additional portions connected or integrally formed with the first and second portions 22, 24, depending on designer preferences, preferred functions, size limitations or other factors. In the preferred embodiment, the plurality of flutes 20 includes a first plurality of flutes 20 on the first portion 22 and a second plurality of flutes 20 on the second portion 24, wherein the first plurality of flutes 20 extend at a first flute angle Δf1 and the second plurality of flutes 20 extend at a second flute angle Af2. The first portion 22 is preferably separated from the second portion 24 by the central row of connectors 18c that extends generally parallel to the lateral axis 16. The flute angle Δf is generically identified by reference character Δf, although the flutes 20 extend substantially at the same flute angle Δf in the preferred embodiment, with the flutes 20 of the second portion 24 extending at an opposite side of the longitudinal axis 14 relative to the flutes 20 of the first portion 22, thereby defining the cross corrugated configuration of the preferred fill pack 100, as is described in further detail herein.
In the preferred embodiment, the sheets 10 include flutes or corrugations 20 that guide airflow through the first and second portions 22, 24 and between the first and second ends 11a, 11b in an airflow direction 28. The flutes 20 define a first flute angle Δf1 in the first portion 22 and a second flute angle Af2 in the second portion 24. The first and second flute angles Δf1, Af2 are approximately the same twenty degrees (20°) in the preferred embodiment, compared to a typical thirty degree (30°) flute angle for prior art cross corrugated media or fill, to reduce the fill pressure drop created by the flute macro-geometry as the air flows between the first end 11a and the second end 11b in the airflow direction 28. This reduced first and second flute angles Δf1, Δf2, as well as the arcuate and undulating shape of the microstructure 12, reduces pressure drop from the macrostructure flute geometry and enables more pressure drop to be attributed to the microstructure 12 of the cross corrugated media or fill pack 100 to improve thermal performance of the fill pack 100 over typical media or fill, for example, a Brentwood Industries CF1900 cross-fluted film fill. The CF1900 fill has limited microstructure which is defined by features that are physically cut into a mold to produces the CF1900. The features are cut into the mold with a ball mill to a relatively shallow depth and the sheets of the CF1900 fill pack take on the shapes milled into the mold during production. The microstructure of the CF1900 is also discrete and spaced relatively widely apart on the surface of the CF1900 corrugated fill sheet. The flutes 20 in the first portion 22 of the sheets 10 preferably extend in a first direction relative to the longitudinal axis 14 and the flutes 20 in the second portion 24 preferably extend in a second opposite direction relative to the longitudinal axis 14, but are not so limited and may be comprised of different angles and extend in substantially the same direction relative to the longitudinal axis 14 or may be otherwise configured based on designer preferences, functional purposes or based on other factors. The first microstructure 20 of the first sheet 10a and the remaining microstructure 20 of each of the sheets 10, defines generally arcuate surfaces between the first top flat strips 12bt and the first bottom flat strips 12bb along which the fluid flows during operation between the first and second ends 11a, 11b in the water flow direction 26.
The sheets 10 are preferably connected to each other along the rows of connectors 18 to define the assembled fill 10. The rows of connectors 18, which are generically identified by reference number 18, preferably include a first end row 18a proximate the first end 11a, a second end row 18b proximate the second end 11b, the central row 18c preferably centrally located between the first and second ends 11a, 11b and two intermediate rows 18d positioned between the first end 11a and the central row 18c and between the second end 11b and the central row 18c, respectively. The connectors 18, including the first end row 18a, the second end row 18b, the central row 18c and the intermediate rows 18d, are not limited to being positioned at the described locations or having the configurations shown in the attached drawings, but preferably are designed and configured to align and connect the sheets 10 into the fill pack 100, such as by crush locking, fastening, clamping, adhesive bonding or other connecting mechanisms or approaches. In the preferred embodiment, the first sheet 10a is connected to the second sheet 10b in an assembled configuration with the first plurality of flutes 20 of the first sheet 10a extending to an opposite side of the longitudinal axis 14 relative to the second plurality of flutes 20 of the second sheet 10b in the assembled configuration and the first end 11a of the first sheet 10a is positioned proximate the second end 11b of the second sheet 10b. In addition, the third sheet 10c is preferably connected to the second sheet 10b with the third plurality of flutes 20 of the third sheet 10c extending to an opposite side of the longitudinal axis 14 relative to the second plurality of flutes 20 of the second sheet 10b. Likewise, the remaining fourth, fifth, sixth, seventh, eighth, ninth, tenth, eleventh, twelfth, thirteenth, fourteenth, fifteenth and sixteenth sheets 10d, 10e, 10f, 10g, 10h, 10i, 10j, 10k, 10l, 10m, 10n, 10o, 10p are preferably connected to their adjacent sheets 10d, 10e, 10f, 10g, 10h, 10i, 10j, 10k, 10l, 10m, 10n, 10o, 10p such that the flutes 20 extend to an opposite side of the longitudinal axis 14, respectively. The fill pack 100 is not limited to such arrangements, for example, the flutes 20 may extend generally parallel to the longitudinal axis 14, offsets (not shown) may be utilized or other methods may be utilized to configure the adjacent sheets 10. The offsets, particularly if designed to have no contact between corrugations or flutes 20 along their lengths as they extend from the first end 11a toward the second end 11b in the assembled configuration at the flute angle Δf, also reduce pressure drop, by eliminating a complete block to airflow created when portions of the flutes 20 of adjacent sheets 10 in the fill pack 100 contact each other along their length.
The microstructure 12 of each sheet 10 of the preferred cross corrugated media or fill 100 includes relatively deep, undulating, and continuous structure. The microstructure 12 preferably extends substantially parallel to the lateral axis 16 and the first and second ends 11a, 11b, but is not so limited and may extend at an angle relative to the lateral axis 16 or may be configured in a Chevron-like shape. The preferred microstructure 12 allows water to spread across the width or across the lateral axis 16 and along the length or along the longitudinal axis 14 of the sheets 10 during use for improved distribution of water on the fill sheets 10. The relatively deep, arcuate and continuous horizontal microstructure 12 facilitates use of substantially all surface area of the sheets 10 as heat transfer surfaces within the fill pack 100. As the water flows down the assembled fill sheets 10, the microstructure 12 constantly redirects the water if channeling or pooling occurs to promote a consistent film of water across the width of the sheets 10. The microstructure 12 comprises essentially the entire surface of the fill sheets 10, with the exception of rows of connectors 18, 18a, 18b, 18c, 18d that extend substantially parallel to the lateral axis 16. The sheets 10 are not limited to including each of the first end, second end, central and intermediate rows of connectors 18a, 18b, 18c, 18d, but preferably include the first and second end rows 18a, 18b that extend along the first and second ends 11a, 11b. The connectors 18 are preferably configured to secure the sheets 10 together in the fill pack 100 and may include any number of connectors 18 at nearly any desired location on the sheets 10 to facilitate connection of the sheets 10 into the fill pack 100. The connectors 18 are preferably designed, depending on the particular application and designer preferences, to facilitate secure engagement of the sheets 10 in the packs 100. With the arcuate undulating microstructure 12 of the preferred embodiment, the obstruction to vertical water flow generally along the longitudinal axis 14 from the first end 11a to the second end 11b may create a thicker film on top of the horizontal microstructure 12 and facilitates distribution of the water film laterally fully across the width of the sheets 10 in the fill pack 100, thereby enabling consistent water film distribution and flow of water in a water flow direction 26.
Performance of the cross corrugated fill described in German Patent Application No. DE 41 27 245, filed Aug. 17, 1991 and titled, “Heat Exchanger for Cooling Tower — has Elements with Zigzag Grooved for Flow of Water in Opposite Direction to Flow of Gat” (“245-APP”) was tested and compared to the CF1900. The fill sheets constructed in accordance with the 245-APP have sharp-edged transitions between conduit sides and flat strips of the microstructure of the surface elements or sheets 1. The 245-APP states, “this fine profile extends to the direction of the channel profile at an angle which corresponds approximately to the angle of inclination of the channels to the main flow direction of gas and liquid. The resulting, approximately horizontal run of the fine profiling in the installed state causes the liquid is held on the edge of the channels within the respective flow channel and despite the oblique channel course does not leave the channel edge.” As a result of the sharp transitions, turbulence is produced in the film of liquid at a transition from a profile peak to a profile trough, or from a profile trough to a profile peak, which promotes heat exchange and mass transfer. The pressure drop of a pack of sheets constructed in accordance with the 245-APP was higher than that of the CF1900, even though the flute angle was reduced, although the thermal performance also increases. The overall performance of the fill constructed in accordance with the 245-APP was lower than the existing CF1900, due to the significant increase in pressure drop which was not offset by the increased thermal performance.
In the preferred cross corrugated fill packs 100, the fill sheets 10 include fillets or radii 12a added to the microstructure 12 to provide arcuate structures where, in contrast, sharp corners are present on the horizontal microstructure of the sheets constructed in accordance with the 245-APP. As is shown in
The first sheet 10a includes a first microstructure 12 including first top flat strips 12bt, first bottom flat strips 12bb and first conduit sides 12c connecting the first top flat strips 12bt to the first bottom flat strips 12bb. The first sheet 10a also includes a plurality of first radii 12a connecting the first top flat strips 12bt to the first conduit sides 12c and the first bottom flat strips 12bb to the first conduit sides 12c. The first plurality of flutes 20 extend at the first flute angle Δf1 relative to the longitudinal axis 14. The first flute angle Δf1 is approximately zero to forty-five degrees, but is not so limited and may be fifteen to thirty degrees (15-30°) and twenty degrees (20°) in the preferred embodiment.
The second sheet 10b a second plurality of flutes 20 and a second microstructure 12 defined on the second sheet 10b. The additional sheets 10 also include flutes 20 and microstructure 12 and are designed and configured substantially the same as the first and second sheets 10a, 10b. The microstructure 12 of the second sheet 10b includes second top flat strips 12bt, second bottom flat strips 12bb and second conduit sides 12c connecting the second top flat strips 12bt to the second bottom flat strips 12bb. A plurality of second radii 12a connect the second top flat strips 12bt to the second conduit sides 12c and the second bottom flat strips 12bb to the second conduit sides 12c. The first sheet 10a is connected to the second sheet 10b in an assembled configuration with the first plurality of flutes 20 extending to an opposite side of the longitudinal axis 14 relative to the second plurality of flutes 20 in the assembled configuration. The first sheet 10a is preferably connected to the second sheet 10b in the fill pack 100 such that the first end 11a of the first sheet 10a is positioned proximate the second end 11b of the second sheet 10b so that the flutes 20 are in a cross corrugated configuration with the second sheet 10b rotated approximately one hundred eighty degrees relative to the first sheet 10a. In the preferred embodiment, the first sheet 10a includes a first end row of connectors 18a extending along the first end 11a and a second row of connectors 18b extending along the second end 11b. The second sheet 10b also includes a first end row of connectors 18a at the first end and a second end row of connectors 18b extending along the second end such that the first end row of connectors 18a of the first sheet 10a are connected to the second end row of connectors 18b of the second sheet 10b and the second end row of connectors 18b of the first sheet 10a are connected to the first end row of connectors 18a of the second sheet 10b in the assembled configuration of the fill pack 100. The central row of connectors 18c of the first and second sheets 10a, 10b and the aligned intermediate rows of connectors 18d of the first and second sheets 10a, 10b are also attached in the fill pack 100. In the preferred embodiment, the first and second end rows of connectors 18a, 18b, the central row of connectors 18c and the intermediate rows of connectors 18d are comprised of a plurality of connector tabs.
Referring to Table 1, the fan horsepower was determined to achieve the same cold water temperature during testing of each of the CF1900 cross corrugated fill, the cross corrugated fill constructed in accordance with the 245-APP and the preferred cross corrugated fill pack 100. The density and height of the microstructure were increased over the baseline CF1900 and for the packs constructed in accordance with the 245-APP with the sharp microstructures, but the product configuration of the preferred fill pack 100 was substantially the same except for the fillets 12a included between the flat strips 12b and the conduit sides 12c, which are substantially comprised of an inflection line between the adjacent fillets 12a of the preferred sheets 10. Because of the higher thermal performance or efficiency of the preferred cross corrugated fill pack 100, the required airflow was reduced also lending itself to lower required fan horsepower and higher overall tower performance. As is shown below in Table 1, in each of the scenarios, the preferred cross corrugated fill packs 100 function at a lower fan power percentage than the CF-1900 fill packs and the 245-APP fill packs to achieve the same cold water temperature, functioning at between seven and seven tenths to thirty-five and eight tenths percent (7.7-35.8%) less fan power than the fill packs constructed in accordance with the teachings of the 245-APP.
When both the packs constructed in accordance with the 245-APP and the preferred cross corrugated fill pack 10 are compared to the CF1900 fill, it must be noted that the flute angle was reduced from thirty degrees (30°) to twenty degrees (20°) for the packs constructed in accordance with the 245-APP and the preferred cross corrugated fill pack 100. Based on the results in Table 1, the CF1900 had lower pressure drop for the same thermal performance when compared to the packs constructed in accordance with the 245-APP.
The shape of the microstructure 12 of the sheets 10 of the preferred cross corrugated packs 100 impacts the shape of the water surface at the air-water interface during operation. The sharp microstructure of the packs constructed in accordance with the 245-APP creates a Weir effect upstream from the flow of the water film. This effect significantly increases the thickness of the water film (also called water hold-up). The thickness of this fluid film at the ‘Weir’ of the fill constructed in accordance with the 245-APP sometimes can be much larger than the actual height of the microstructure depending on the water application rate. This increase in fluid film thickness impedes air flow in the fill constructed in accordance with the 245-APP by reducing the cross-sectional area through which the air is allowed to flow between assembled fill sheets. Soft microstructure does not hold up water as it adheres to the surface and, therefore, the air-water interface more closely follows the shape of the microstructure. The artifact of this phenomena is that the thinner more distributed layers of water on the preferred sheets 10 within the fill pack 100 do not generate the thick formation of pockets of water seen on the surface of the sheets of the fill pack constructed in accordance with the 245-APP, thereby creating water holdup. The impedance to airflow is therefore reduced with the softer and arcuate microstructure 12 of the preferred sheets 10 within the fill pack 100, thereby reducing pressure drop of air flowing in the airflow direction 28 through the fill pack 100.
The water application rate onto the preferred cross corrugated fill packs 100, as well as onto the packs constructed in accordance with the 245-APP, impacts the thickness of the water on the surface of the fill packs 100 and the fill pack constructed in accordance with the 245-APP and contributes to differences in thermal performance and pressure drop under differing water loads. The proximity of the adjacent microstructure surfaces (i.e., space between successive horizontal ribs or top ribs) drives the ability of the water to bridge or adhere to both surfaces (inherent in design) and fill in (not inherent in design) on the microstructure. Larger distances break the surface tension of the water and allow for the surfaces of the microstructure 12 to dominate the effective surface area driving a thinner more distributed film and improved mixing within the film based on interface friction with the air and fill surface. The filleted design or relatively smooth and arcuate radii 12a of the microstructure 12 of the preferred sheets 10 does not support the bridging of water across the surfaces of the microstructure 12, including the radii 12a, the flat strips 12b and the conduit sides 12c.
Structured sheet fill products, including the preferred cross corrugated fill pack 100, are configured to handle the structural loads applied during installation and while in operation. Typically, the compressive strength of the fill pack 100 in the gauge selected for the application is sufficient based on the configuration of the geometry of the flutes 20 and the microstructure 12. The addition of structural ribs (not shown) in the sheets 10 may be preferred, depending upon the structural performance of the product design, whereas focusing on thermal performance and pressure drop is subject to the application of the product. These structural ribs essentially cut through the microstructure 12 where they may also provide a drain for water to flow directly through the fill pack 100, thereby limiting the water’s exposure to the airflow. A small change in thermal performance is expected if structural ribs are incorporated into the preferred sheets 10 for structural integrity for varying fill gauges.
The first and second flute angles Δf1, Δf2 of the preferred corrugated fill sheets 10 range from zero to forty-five degrees (0-45°) from a vertical position or relative to the longitudinal axis 14. A microstructure depth A of the microstructure 12 ranges from approximately eight hundredths to twelve hundredths inches (0.08 - 0.12″) or two to three millimeters (2-3 mm). A microstructure height B of the microstructure 12 ranges from approximately two tenths to three tenths inches (0.2-0.3″) or five to seven and six tenths millimeters (5-7.6 mm). A microstructure radius D, E of the fillet or radii 12a as a percentage of the microstructure depth A ranges from seventy to one hundred percent (70-100%) and generally is not necessarily consistent throughout the sheet 10. The microstructure radius D, E is, therefore, approximately fifty-six thousands of an inch to twelve hundredths inches (0.056-0.12″) or one and four tenths to three millimeters (1.4-3 mm) in the preferred embodiment. In addition, a microstructure spacing C between peaks of the microstructure 12 is approximately twice the microstructure height B or approximately four tenths inches to six tenths inches (0.4-0.6″) or ten to fifteen millimeters (10-15 mm) in the preferred embodiment. The microstructure depth A, the microstructure height B, the microstructure spacing C and the microstructure radius D, E are not limited to the above-listed dimensions and ranges and may be designed and configured to have different sizes and dimensions based on design requirements, designer preferences and design characteristics, as long as the sheets 10 are able to take on the general preferred configuration, withstand the normal operating conditions and perform the preferred functions described herein.
Referring to
For these reasons, the design of the preferred cross corrugated media or fill sheets 10 and assembled fill pack 100 is novel, inventive, and has significant commercial value over the existing commodity product offered in the market.
It will be appreciated by those skilled in the art that changes could be made to the preferred embodiment described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiment disclosed, but it is intended to cover modifications within the spirit and scope of the present invention as defined by the present disclosure.
The present application claims the benefit of U.S. Provisional Pat. Application No. 62/736,135, filed on Sep. 25, 2018 and titled “Cross Corrugated Media and Related Method” the entire contents of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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62736135 | Sep 2018 | US |
Number | Date | Country | |
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Parent | 17261218 | Jan 2021 | US |
Child | 18143727 | US |