The present invention relates to a downcomer for use in conveying wastewater from an upper level of a marine vessel to a lower level of the marine vessel and, in particular, to a lightweight, rust-resistant downcomer formed of an ultrahigh molecular weight polyolefin.
Downcomers are commonly used to convey a substance, typically wastewater, from an upper level of a marine vessel to a lower level of the marine vessel along the outside of the vessel's hull. The wastewater is preferably conveyed from either the interior of the marine vessel or its deck to the waterline. “Wastewater” refers to both gray water (water from sink and shower drains) and black water (water from toilet drains).
Because of its position on marine vessel 6, downcomer 2 is subject to multiple high-force impacts during harsh docking conditions and collisions with tugboats. When the force of these impacts exceeds the yield strength of downcomer 2, it dents, leaving a permanent deformation. Such deformation must be repaired to maintain a smooth surface and so that wastewater may be efficiently conveyed into the water. Guards 22 are sometimes mounted along the flanks of downcomer 2 to absorb a portion of impacts. Also, guards 22 may protect downcomer 2 from being ripped off of hull 4 during docking of marine vessel 6. However, guards 22 add cost and may not be effective when impact with tugboats or docks occurs above or below guards 22.
Known downcomers are made of steel, presumably due to its high yield strength. However, even steel downcomers can be dented during impact. Repair of a steel downcomer requires that the dented downcomer be removed from the hull and a new undented downcomer be attached in its place. Alternatively, the dented portion of the downcomer can be removed and an undented portion can be rewelded in its place. Both approaches are expensive and time-consuming. Further, downcomers repaired using the second method often experience leaking or an increased incidence of rust or corrosion at the weld.
The outer surface of the downcomer is typically painted so that the downcomer color matches the color of the marine vessel and to delay rust formation. However, maintenance of the painted and/or coated steel downcomers includes regular repainting and general upkeep to prevent rust and corrosion. This regular maintenance is both expensive and time-consuming.
The present inventor has recognized a need for a downcomer that can absorb a substantial amount of energy upon impact without permanently deforming, that is highly resistant to rust and corrosion, that is easily installed and repaired, that is lightweight and hydrodynamic at the water line, and that requires little or no maintenance.
A downcomer for conveying wastewater from an upper level of a marine vessel to a lower level of the marine vessel includes a pair of spaced-apart mounting portions and an elongate impact portion extending between the mounting portions. Each mounting portion is adapted for attachment to the hull of the marine vessel, and the elongate impact portion has a shape that defines a concave space through which the wastewater is conveyed. The mounting portions and the elongate impact portion are preferably integrally formed in a unitary structure by extrusion of a lightweight, rust-resistant ultrahigh molecular weight polyethylene material having a high impact resistance.
In one embodiment, a synthetic elastomeric, high temperature, chemically resistant tube is placed within the concave space, and the wastewater is conveyed from an upper level of the marine vessel toward the waterline through the tube. In another embodiment, the downcomer has a hydrodynamic, wing-shaped profile resulting from the elongate impact portion extending outwardly from the mounting portions. In another embodiment the outer edge of the downcomer is attached to the outside of the marine vessel's hull by steel keys or tabs to prevent spreading of the legs of the downcomer profile. The use of these steel keys or tabs makes the downcomer significantly stronger than the prior art steel downcomers.
Additional aspects and advantages of the invention will be apparent from the following detailed description of preferred embodiments, which proceeds with reference to the accompanying drawings.
Each of mounting portions 32 and 34 includes a rear side 40 that faces toward hull 4, and a front side 42 opposite rear side 40 that faces away from hull 4. Each of mounting portions 32 and 34 preferably includes multiple mounting holes 44 extending through a thickness 48 of mounting portions 32 and 34 and spaced along the length of downcomer 30. Each mounting hole 44 is sized to receive a mounting fastener 46 (shown in
Thickness 48 of mounting portions 32 and 34 will typically be dictated by the size of mounting fastener 46, the thickness of elongate impact portion 36, and the amount of material necessary to securely fasten downcomer 30 to hull 4. However, other considerations such as flexibility, expected loads, durability, and aesthetics may also be considered when determining thickness 48 of mounting portions 32 and 34. Thickness 48 may also vary in differing individual sections 72 of downcomer 30. For example, thickness 48 of the downcomer sections 72 closest to waterline 8 may be thicker than downcomer sections 72 closest to hull 4 because downcomer sections 72 closest to waterline 8 must withstand greater impact strength because the incidence of impact with tugboats or docks is significantly greater at waterline 8. For example, thickness 48 may be in the range of about 1 inch (254 cm) to about 5 inches (12.7 cm) depending on the size of marine vessel 6. At about 1 inch (2.54 cm) thickness, mounting portions 32 and 34 will preferably have a height of about 2.75 inches (5.29 cm). Each of mounting portions 32 and 34 may optionally be backed by a layer of elastomeric material 50 (
Mounting fastener 46 (
Elongate impact portion 36 is bounded by an outer surface 52 and a concave inner surface 54. Thus the shape of elongate impact portion 56 defines concave space 38 between hull 4 and elongate impact portion 36 when downcomer 30 is mounted to hull 4. A preferred elongate impact portion 36 has a U-shaped cross-section. Elongate impact portion 36 absorbs a portion of the energy transferred to downcomer 30 during an impact. The amount of energy absorbed by downcomer 30 will be a function of the shape and thickness of elongate impact portion 36, the structural dimensions of which are selected based on expected impact forces. For example, elongate impact portion 36 may have a thickness 56 (shown in
Mounting portions 32 and 34 and elongate impact portion 36 of downcomer 30 are preferably made of UHMWPE. However, mounting portions 32 and 34 may be formed of an alternative material. A preferred UHMWPE has a low coefficient of sliding friction, high abrasion resistance, and high strength characteristics, particularly modulus of elasticity (Young's modulus), yield strength, and impact strength. An exemplary preferred UHMWPE is a crystalline UHMWPE. A preferred commercially available UHMWPE conforms to ASTM 4020. Favorable physical properties of UHMWPE include a modulus of elasticity (Young's modulus) at room temperature of between about 0.6 GPa and about 0.8 GPa (ASTM D638 and D6712), a tensile yield strength ranging between about 21.0 MPa and about 22.3 MPa, an ultimate tensile strength ranging between about 46.8 MPa and about 53.7 MPa, and an Izod impact strength of between about 70 kJ/m2 and about 220 kJ/m2 (modified ASTM D256, double 15° V-notched; ASTM D6712, depending on the material composition and the fabrication method used). UHMWPE is also highly abrasion-resistant, hydrophobic, and chemically resistant. Also, UHMWPE can be successfully used in temperatures ranging from 200° F. to −160° F. It accepts additives, such as UV stabilizers and fire retardants that are included in the preferred embodiments of downcomer 30. Mixing a pigment with UHMWPE eliminates the need to paint downcomer 30 and permits either matching the color of downcomer 30 to the color of hull 4, or having downcomer 30 and hull 4 have high-contrast colors. Both options result in long-lasting visibility without the expense of painting and repainting downcomer 30. UHMWPE can also be machined using conventional woodworking equipment, for example, drilling mounting holes 44 after the body of downcomer 30 is formed.
Additionally, UHMWPE surfaces can be textured, treated, coated, or imparted with fillers to impart radar-scattering or absorbing properties desirable when downcomer 30 is used in military applications requiring stealth capabilities. For example, the ultrablack surface topology described in U.S. Pat. No. 5,225,933 of Myers et al. could be formed on or applied to an outer surface of downcomer 30. Skilled persons will appreciate that different surface textures that are suitable for manufacture by extrusion may also be used. Although other materials can be used in the manufacture of downcomer 30, UHMWPE has a combination of physical properties, including abrasion resistance, strength, low friction, moldability, and resistance to permanent deformation, that makes it especially desirable.
Although any of a variety of fabrication techniques can be used in the manufacture of downcomer 30, extrusion and hot bending are preferred fabrication techniques. Further, two or more materials can be co-extruded to achieve different mechanical properties at different sections of downcomer 30 while maintaining its integral structure.
As mentioned above, elastomeric material 50 can be interposed between downcomer 30 and hull 4 of marine vessel 6. A preferred elastomer material 50 is UV-stabilized outdoor marine-grade rubber having a hardness of approximately 65 durometer. Elastomeric material 50 is preferably in the form of a washer or strip, as shown in FIG. 5.
As shown in
As shown in
The unique shape and design of the downcomers in accordance with the preferred embodiment, offer numerous advantages over prior art downcomers. In one embodiment, elongate impact portion extends outwardly from mounting portions 32 and 34 a distance of less than diameter 58, and preferably less than half of diameter 58 resulting in a the hydrodynamic wing-shaped profile of downcomer 30. As shown in dashed lines 62 in
Further, the use of UHMWPE facilitates the addition of UV resistant pigments throughout downcomer 30, thus eliminating the time-consuming and expensive need for maintenance in the form of painting and repainting, while simultaneously providing colorfastness throughout the thickness of downcomer 30. Additionally, UHMWPE weighs significantly less than the steel used in prior art downcomers, thereby facilitating installation, maintenance, and repair. Further, downcomer 30 of the present invention does not rust and is generally resistant to the corrosive effects of the wastewater it conveys to the waterline. The use of a UHMWPE material also provides increased resistance to denting and/or puncture of downcomer 30 during impact. Further, any damage to downcomer 30 can be easily and inexpensively repaired by removing the damaged portion and replacing it with a new portion. Finally, the wing-shaped profile of downcomer 30 of the present invention offers improved hydrodynamic qualities that result in better flow at the waterline and more even distribution of the wastewater exiting the downcomer at the waterline. It is anticipated that the thick lower downcomer sections may replace the “elephant ears” that are welded to the hull to protect the steel downcomer from impact with tugs and docks.
It will be obvious to those having skill in the art that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention. The scope of the present invention should, therefore, be determined only by the following claims.
Number | Name | Date | Kind |
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5868514 | Gibson | Feb 1999 | A |
20040103948 | Scheelen et al. | Jun 2004 | A1 |
Number | Date | Country | |
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20040112272 A1 | Jun 2004 | US |