The present technology relates to the field of assemblies for joining walls, and more specifically to parts assemblies, panels, and tanks.
Large storage structures, such as field-erected tanks, leaching tanks, or cisterns, are often constructed from many metal panels bolted and/or welded together, directly at the structure's desired location. Overall costs of such field-erected structures include not only material costs, but also the time necessary to assemble the structure.
In order to prevent leakage of materials, especially liquids, through the panels assembled together, the edges of the panels are welded together. Large welds passing through the thickness of the wall are necessary to hold and seal the panels together, using, for example, forge welding or butt welding. While generally effective for providing structural strength for the assembly and for sealing the joint between the walls, these types of welding are highly time consuming and specialized work. Each additional joint to weld is therefore a significant increase of costs for the overall structure. Further, time on-site spent welding panels together cannot generally be reduced by pre-welding panels together, as such structures generally must be assembled and welded on-site due to their large size.
Some such structures use flanges that abut each other to bolt together adjacent panels, those flanges being thick enough to support highly tightened bolts. Thick flanges increase material costs, and the joints will generally still require extensive welding.
There is therefore a desire for structures that can be assembled and sealed in a time and cost efficient manner.
It is an object of the present technology to ameliorate at least some of the inconveniences present in the prior art.
According to a first broad aspect of the present technology, there is provided a parts assembly including a first wall; a second wall, a first edge of the first wall facing a second edge of the second wall; a first flange connected to and extending outward from the first wall; a second flange connected to and extending outward from the second wall, the second flange being spaced from and disposed opposite the first flange; at least one fastener extending through and connecting the first flange and the second flange, the at least one fastener being pre-tensioned; and at least one rigid spacing member disposed between the first flange and the second flange, the at least one rigid spacing member being spaced from the at least one fastener, the at least one rigid spacing member being in contact with the first and second flanges, the at least one fastener being disposed between the at least one rigid spacing member and the first and second walls.
In some embodiments of the present technology, the first edge of the first wall abuts the second edge of the second wall.
In some embodiments of the present technology, the first flange is offset from the first edge; the second flange is offset from the second edge; and the first edge and the second edge are aligned with a space between the first flange and the second flange.
In some embodiments of the present technology, the first flange and the second flange are disposed equidistant from a corresponding one of the first edge and the second edge.
In some embodiments of the present technology, the at least one rigid spacing member is a rigid shim connected to one of the first flange and the second flange.
In some embodiments of the present technology, the rigid shim is welded to the first flange.
In some embodiments of the present technology, the at least one rigid spacing member is disposed between a first outward end of the first flange and a second outward end of the second flange, the first outward end and the second outward end being ends of the first and second flanges opposite the first wall and the second wall.
In some embodiments of the present technology, the at least one rigid spacing member is a single rigid spacing member extending along an entire height of the first flange and the second flange.
In some embodiments of the present technology, the first flange is welded to the first wall; and the second flange is welded to the second wall.
In some embodiments of the present technology, the parts assembly further includes at least one sealing member disposed between the first edge of the first wall and the second edge of the second wall, the first edge and the second edge abutting the at least one sealing member.
According to another broad aspect of the present technology, there is provided a parts assembly including a first wall; a second wall; a first flange connected to and extending outward from the first wall; a second flange connected to and extending outward from the second wall, the second flange being spaced from and disposed opposite the first flange; at least one rigid spacing member disposed between the first flange and the second flange, the at least one rigid spacing member being in contact with the first and second flanges, the first wall, the second wall, the first flange, the second flange, and the at least one rigid spacing member forming a closed perimeter defining a space; and at least one fastener extending through the first flange, the space, and the second flange and connecting the first flange to the second flange, the at least one fastener being pre-tensioned, the at least one fastener being spaced from the at least one rigid spacing member.
According to another broad aspect of the present technology, there is provided a parts assembly including a first wall; a second wall, a first edge of the first wall facing a second edge of the second wall; a first flange connected to and extending outward from the first wall; a second flange connected to and extending outward from the second wall, the second flange being spaced from and disposed opposite the first flange; at least one fastener extending through and connecting the first flange and the second flange, the at least one fastener being pre-tensioned; and at least one rigid spacing member disposed between the first flange and the second flange, the at least one rigid spacing member being spaced from the at least one fastener, the at least one rigid spacing member being in contact with the first and second flanges, the at least one rigid spacing member being disposed at at least one of: above the at least one fastener, and below the at least one fastener.
According to yet another broad aspect of the present technology, there is provided a tank including a first curved wall including a first edge extending vertically along the first curved wall; a second curved wall including a second edge extending vertically along the second curved wall, the first edge facing the second edge; a first flange connected to and extending vertically and radially outward from the first curved wall; a second flange connected to and extending vertically and radially outward from the second curved wall, the second flange being spaced from the first flange; at least one fastener extending horizontally through and connecting the first flange and the second flange, the at least one fastener being pre-tensioned; and at least one rigid spacing member disposed between the first flange and the second flange, the at least one rigid spacing member being spaced radially outward from the at least one fastener, the at least one rigid spacing member being in contact with the first and second flanges, the at least one fastener being disposed radially between the at least one rigid spacing member and the first and second walls.
In some embodiments of the present technology, the first edge abuts the second edge.
In some embodiments of the present technology, the first flange is offset from the first edge; the second flange is offset from the second edge; and the first edge and the second edge are aligned with a space between the first flange and the second flange.
In some embodiments of the present technology, the first flange and the second flange are disposed equidistant from a corresponding one of the first edge and the second edge.
In some embodiments of the present technology, the at least one rigid spacing member is a rigid shim connected to one of the first flange and the second flange.
In some embodiments of the present technology, the rigid shim is welded to the first flange.
In some embodiments of the present technology, the at least one rigid spacing member is disposed between a first outward end of the first flange and a second outward end of the second flange, the first outward end and the second outward end being ends of the first and second flanges radially outward of the first wall and the second wall.
In some embodiments of the present technology, the at least one rigid spacing member is a single rigid spacing member extending along an entire vertical height of the first flange and the second flange.
In some embodiments of the present technology, the first flange is welded to the first wall; and the second flange is welded to the second wall.
In some embodiments of the present technology, at least the first curved wall and the second curved wall form a first cylindrical wall assembly.
In some embodiments of the present technology, the first cylindrical wall assembly includes a first horizontal flange extending outward from a top edge of the first curved wall and a second horizontal flange extending outward from a top edge of the second curved wall, the first horizontal flange and the second horizontal flange defining a first circumferential flange of the first cylindrical wall assembly; and further including a second cylindrical wall assembly, the second cylindrical wall assembly including a second circumferential flange extending outward from a bottom edge of the second cylindrical wall, the second cylindrical wall assembly being disposed on top of the first cylindrical wall assembly, the first circumferential flange abutting and being fastened to the second circumferential flange.
In some embodiments of the present technology, the at least one fastener is a plurality of fasteners spaced vertically through the first flange and the second flange.
In some embodiments of the present technology, the tank further includes at least one sealing member disposed between the first edge and the second edge, the first edge and the second edge abutting the at least one sealing member.
According to yet another broad aspect of the present technology, there is provided a panel including a wall; a first flange having a first end connected to a first end portion of the wall, the first flange being offset from a first side edge of the first end portion, the first flange defining a first plurality of apertures for receiving fasteners therethrough; at least one rigid spacing member connected to a second end of the first flange, the second end of the first flange being opposite the first end of the first flange; a second flange having a first end connected to a second end portion of the wall, the second end portion being disposed opposite the first end portion, the second flange being offset from a second side edge of the second end portion, the second flange defining a second plurality of apertures for receiving the fasteners therethrough, the first plurality of apertures being defined between the first end portion of the wall and the at least one rigid spacing member; and at least one third flange connected to at least one of a top edge and a bottom edge of the wall, the first flange, the second flange, and the third flange extending in a same direction away from the wall.
In some embodiments of the present technology, the at least one third flange includes: a top flange connected to the top edge of the wall; and a bottom flange connected to the bottom edge of the wall.
In some embodiments of the present technology, the at least one rigid spacing member is a single rigid spacing member extending along an entire vertical height of the first flange.
In some embodiments of the present technology, the first flange is welded to the first end portion of the wall; the second flange is welded to the second end portion of the wall; and the at least one rigid spacing member is welded to the first flange.
For purposes of this application, terms related to spatial orientation are defined with respect to the standard operational orientation of the tank. Specifically, vertical is meant to represent a direction generally orthogonal to the ground upon which the tank rests when oriented in its standard operational orientation.
For purposes of this application, the term “tank” refers to any number of structures which includes, but is not limited to: a field-erected tank, a leaching tank, a cistern, a reservoir, a silo, a bin, a standpipe, a pumpbox, and a receptacle.
Embodiments of the present technology each have at least one of the above-mentioned object and/or aspects, but do not necessarily have all of them. It should be understood that some aspects of the present technology that have resulted from attempting to attain the above-mentioned object may not satisfy this object and/or may satisfy other objects not specifically recited herein.
Additional and/or alternative features, aspects and advantages of embodiments of the present technology will become apparent from the following description, the accompanying drawings and the appended claims.
For a better understanding of the present technology, as well as other aspects and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:
It should be noted that the Figures may not be drawn to scale.
The present detailed description is intended to be only a description of illustrative examples of the present technology. The following description relates to ways of manufacturing and designing a tank, a panel for a tank, and a parts assembly for joining two walls. Other ways of manufacturing and designing the tank, the panel, and the assembly are contemplated and this technology would encompass these other known ways and designs.
A tank 100 according to an embodiment of the present technology is illustrated in
The tank 100 is built from three cylindrical wall assemblies 110, each one being built from multiple panels 200. The bottommost cylindrical wall assembly 110 includes a door panel 130, which allows access to an interior of the tank 100 during assembly or maintenance. The door panel 130 is connected to the panels 200 of the bottommost cylindrical wall assembly 110 in the same manner as the panels 200 are connected together. The panels 200 will be described in more detail below.
The wall assemblies 110 are vertically stacked and fastened together, as will be described below. A roof 120 is also fastened to a topmost cylindrical wall assembly 110. A floor (not shown) is further fastened to a bottom-most cylindrical wall assembly 110. In some embodiments, the tank 100 could be built from more or fewer cylindrical wall assemblies 110. Some embodiments of the tank 100 may not include the roof 120 and/or the floor. In some embodiments without the roof 120, the tank 100 could include a bridge connected to and extending over a top side of the tank 100.
The upper two cylindrical wall assemblies 110 are built from three panels 200 fastened together, while the bottom most cylindrical wall assembly 110 is formed from four panels 200. Depending on the specific embodiment, the cylindrical wall assemblies 110 could be formed from more or fewer panels 200. Connecting the panels 200 together to form the wall assembly 110 will be described in more detail below. Some of the panels 200 have pipes 107 or other fixtures 109 extending therethrough.
Each cylindrical wall assembly 110 includes a top circumferential flange 112 and a bottom circumferential flange 114. Both the top flange 112 and the bottom flange 114 define a plurality of through-holes. During assembly of the tank 100, one cylindrical wall portion 110 is stacked on top of another cylindrical wall portion 110. Fasteners are then inserted and fastened through the apertures of the bottom circumferential flange 114 of the wall assembly 110 on top and the apertures of the top circumferential flange 112 of the wall assembly 110 disposed below. It is contemplated that the bottom flange 114 of the bottommost cylindrical wall assembly 110 could be omitted in some embodiments. Similarly, it is contemplated that the top flange 112 of the topmost cylindrical wall assembly 110 could be omitted in some embodiments.
With reference to
The panel 200 includes a curved wall 202. In the cross-section of
It is contemplated that the panel 200 could be more or less curved, depending on the embodiment. The panel 200 is shaped to form a part of the circumference of the final tank 100, and the curve and length of the wall 202 will depend on variables such as the desired circumference and radius of curvature of the tank 100, as well as the number of panels 200 to be connected to form a given cylindrical wall assembly 110. In such applications, it is contemplated that the wall 202 could be planar or nearly planar, for example when implementing the panels 200 for construction of a slurry pumpbox.
In the illustrated embodiment of the field-erected leaching tank 100, the panels 200 are formed from carbon steel. The materials used to form the panels 200, or even the components (described below) of the panels could vary depending on the specific application. The panels 200, or the panel components, could be made from materials including, but not limited to: industrial grade plastic, hardened steel, aluminum, and stainless steel. Some of the panels 200 also include two reinforcing ribs 216, but it is contemplated that the panels 200 could include more or fewer ribs 216. The panels 200 of the bottommost cylindrical wall assembly 110, for instance, do not include reinforcing ribs 216.
The panel 200 includes a top horizontal flange 212 extending radially outward along and welded to a top edge of the wall 202. The panel 200 also includes a bottom horizontal flange 214 extending radially outward along and welded to a bottom edge of the wall 202. When the three (or four) panels 200 are connected to form one of the cylindrical wall assemblies 110, the three top horizontal flanges 212 form the top circumferential flange 112 and the three bottom horizontal flanges 214 form the bottom circumferential flange 114. Both the top horizontal flange 212 and the bottom horizontal flange 214 define a plurality of through-holes for receiving the fasteners for fastening one cylindrical wall assembly 110 to another, as described above.
The wall 202 has a right side end portion 204, as viewed from an exterior side of the tank 100, with a vertical edge 206. At an opposite end of the wall 202, the panel 200 also has a left side end portion 208 with a vertical edge 210. Each edge 206, 210 is beveled to form a v-shaped groove when two panels 200 abut, as will be described in more detail below.
It is contemplated that the edges 206, 210 could be differently shaped, for example to form a u-shaped groove when two panels 200 abut. It is also contemplated that the edges 206, 210 could be flat such that no groove is formed when two panels 200 abut.
The panel 200 includes a right flange 220 welded to an exterior side of the right side portion 204 by inner and outer welds 205. The flange 220 is offset from the edge 206 and extends along the vertical length of the wall 202. The flange 220 defines a plurality of apertures 222 for receiving fasteners therethrough, as will be described in more detail below.
The panel 200 further includes a left flange 230 welded to the left side portion 208 by inner and outer welds 209. The flange 230 is offset from the edge 210 and extends along the vertical length of the wall 202. The flange 230 defines a plurality of apertures 232 for receiving fasteners therethrough, as will be described in more detail below.
In the present embodiment, the flanges 212, 214, 220, 230 all extend in a same direction away from the wall 202, specifically in the radial direction outward, away from the wall 202. While the flanges 212, 214, 220, 230 are welded to the wall 202, it is contemplated that the flanges 212, 214, 220, 230 could be connected to the wall 202 in any one of many different manners depending on the application. Methods of connecting one or more of the flanges 212, 214, 220, 230 to the wall 202 could include, but are not limited to: fastening, gluing, epoxying, and soldering.
In the illustrated embodiment, the flanges 220, 230 are offset from their respective edges 206, 210 by an equal distance. In some embodiments, the flange 220 could be disposed nearer to or farther from the edge 206 than the flange 230 is disposed to the edge 210. In some embodiments, one of the flanges 220, 230 could be integrally formed with the wall 202, as will be described below with regards to
The panel 200 includes a rigid spacing member 250 connected to an outward end of the right flange 220. The rigid spacing member 250 is spaced from the apertures 222, and as such is spaced from fasteners received therethrough when the flange 220 is connected to another panel 200 (described below). In some embodiments, it is contemplated that the rigid spacer 250 could be connected to the left flange 230. It is also contemplated that the rigid spacer 250 could be integral to one of the flanges 220, 230. As will be described further below, it is also contemplated that the rigid spacing member 250 could be provided separately from the panel 200, such that the rigid spacing member 250 is disposed between adjacent panels 200 only upon assembly of the cylindrical wall assembly 110 or the tank 100.
In the illustrated embodiment, the rigid spacing member 250 is a carbon steel shim 250 welded to a right side of the right flange 220 by a weld 251. It is contemplated that the rigid spacing member 250 could take various forms depending on specifics of a given embodiment, including but not limited to: stainless steel, aluminum, hardened plastic, and various other metals. The rigid spacing member 250 extends vertically along an entire height of the flange 220. In some embodiments, however, the rigid spacing member 250 could extend only along portions of the flange 220.
It is contemplated that the rigid spacing member 250 could be a series of rigid spacing members 250 disposed along the height of the flange 220. It is also contemplated that some of the panels 200 may include one rigid spacing member 250 connected to each of the flanges 220, 230. In such an embodiment, neighboring panels 200 may omit the rigid spacing member 250 completely, assuming that the assembly 110 of such an embodiment contains an even number of panels 200. In other such embodiments, all the panels 200 may include the two rigid spacing members 250, where the walls 202 and the flanges 220, 230 of each panel 200 are adapted such that the rigid spacing member 250 of one panel 200 abuts the corresponding rigid spacing member 250 of the neighboring panel 200.
Having described the various components of one panel 200, connection between two adjacent panels 200 will now be described with regard to
When the panels 200a, 200b are assembled together, the edge 206a and the edge 210b come together and face each other. In the present embodiment, the edges 206a, 210b are directly abutting. With the edges 206a, 210b brought together, the rigid spacing member 250a contacts the flange 230b, such that the rigid spacing member 250a is disposed between and in contact with both flanges 220a, 230b. As can be seen in at least
As can also be seen in
To connect the panels 200a, 200b together, a plurality of fasteners 260 are inserted through the apertures 222a in the flange 220a and the apertures 232b in the flange 230b. The fasteners 260 extend through the flange 220a, the space 258, and the flange 230b, connecting the flange 220a to the flange 230b. In the present embodiment, the fasteners 260 are bolts and nuts 260 extending horizontally through the apertures 222a, 232b to connect the flanges 220a, 230b. The bolts 260, when installed in the flanges 220a, 230b, are disposed radially between the walls 202a, 202b and the rigid spacing member 250a. The bolts 260, when installed, are aligned with each other and are spaced vertically through the flanges 220a, 230b. It is contemplated that different kinds of fasteners could be used to connect the flanges 220a, 230b, including but not limited to: rivets and dowel pins.
To aid in forming a dust- or liquid-proof seal between the panels 200, such that the material stored in the tank 100 generally cannot leak out between the edges 206a, 210b, the bolts 260 are pre-tensioned. Specifically, the bolts 260 are tightened to a pre-determined torque, which forces the flanges 220a, 230b, and thus the connected walls 202a, 202b, toward each other. It is contemplated that in some cases the edges 206a, 210b may not necessarily form a dust- or liquid-proof seal, for example where the tank 100 is destined to store larger rocks, etc.
In the present technology, the necessary pre-tensioning is based on determination of adequate fasteners properties as well as flange and walls properties. Adjustable fastener properties could include, but are not limited to: number of fasteners 260, material of the fasteners 260 and fastener size. Properties to be determined for the wall 202 and the flanges 220, 230 could include, but are not limited to: thickness, width of each flange 220, 230, material of the wall 202, and material of each flange 220, 230. Properties are selected such that the resulting assembly 299 produces an adequate contact between the walls 202 and/or the spacing member 250 and the flange 220 to withstand usage for the specific application considered.
With an adequate design determined, the fasteners 260 having been pre-tensioned, the resulting assembly will generally maintain contact without shifting or relative movement between panels 200, whether the tank 100 is under pressure, has been filled, or is empty. By pre-tensioning the fasteners 260, disposed radially between two contact areas (the edges 206, 210 and the flange 220 and the spacing member 250), the forces on the panels 200 are distributed toward the contact areas and thus over a larger area. In some prior systems, the tension forces may tend to be concentrated near the fasteners 260 and thus the forces holding the panels 200 together are distributed over a smaller area. This can lead to a greater likelihood of relative movement or shifting between panels 200 when the tank 100 sees an increase in pressure (i.e. when the tank 100 is being filled). In some embodiments, sealing the walls 202 by pre-tensioning the fasteners 260 may also produce a decrease in the field work necessary during assembly of the tank 100.
In embodiments where the rigid spacing member 250a is not connected to one of the flanges 220a, 230b, the rigid spacing member 250a is inserted between the flanges 220a, 230b before the bolts 260 are pre-tensioned.
While tightening the bolts 260 through such spaced flanges 220a, 230b would generally otherwise cause a flaring or separation of the edges 206a, 210b, the rigid spacing member 250a aids in keeping the edges 206a, 210b in contact. The rigid spacing member 250a contacts the flanges 220a, 230b on exterior portions of the flanges 220a, 230b, on a side of the bolts 260 opposite the edges 206a, 210b. As such, the exterior portions of the flanges 220a, 230b cannot move toward each other, thereby keeping inward and outward ends of the flanges 220a, 230b approximately equidistant. In this way, the edges 206a, 210b are similarly forced together and remain in contact.
To further secure the connection between the panels 200a, 200b, a 3 mm groove weld is performed along the edges 206a, 210b, specifically on an interior side of the walls 202a, 202b where the edges 206a, 210b form a beveled v-shaped groove. It is contemplated that different types of welds may be performed on the interior side of the walls 202a, 202b, but need not be the time-consuming welding method of the prior art. In some embodiments, the pre-tensioning of the bolts 260 is sufficient to cause a plasticisation of the two edges 206a, 210b to further aid in preventing materials from passing between the edges 206a, 210b. It is also contemplated that different preparations could be applied to the edges 206a, 210b before, during, or after assembly, including for example, epoxies or sealants.
In some embodiments, other sealing methods could be included, either in place or in addition to the weld described above. For example, a sealant material could be applied between the edges 206a, 210b: either to one of the edges 206a, 210b or both of the edges 206a, 210b. In some embodiments, a bonding material, such as a glue or epoxy, could be applied between the edges 206a, 210b: either to one of the edges 206a, 210b or both of the edges 206a, 210b. It is also contemplated that a sealant or polymer could be applied to any of the interior side of the edges 206a, 210b, an interior side of the panels 200 or the tank 100, or in the vicinity of the edges 206a, 210b.
The assembly made up of the walls 202a, 202b, the flanges 220a, 230b, the rigid spacing member 250, and the fasteners 260 is also referred to herein as a parts assembly 299. While the connection of the panels 200a, 200b is described herein relative to their use in constructing the tank 100, it should be noted that the parts assembly 299 could apply to creating secure connections between different types of walls. For example, the parts assembly 299, as well as the different embodiments of parts assemblies described herein below, could be utilized to secure the walls of many different apparatuses. These could include, but are not limited to, reservoirs, silos, bins, standpipes, receptacles, cisterns, pumpboxes, pipes and plumbing installations, and plateworks. In embodiments such as pipes and plumbing installations, the flange assembly 299 could be generally annular, wrapping around the circumference of the pipe rather than extending along its length.
With reference to
The parts assembly 399 includes a flange 320a extending outward from the wall 202a of the left panel 300a and a flange 330b extending outward from the wall 202b of the right panel 300b.
The flange 320a defines a plurality of staggered apertures 322a and 324a. The apertures 322a and 324a extend vertically along the flange 320a, with all of the apertures 322a being radially aligned with one another and all of the apertures 324a being radially aligned with one another. The apertures 322a are horizontally closer to the wall 202a than the apertures 324a. Similarly, the flange 330b defines a plurality of corresponding staggered apertures 332b and 334b, with all of the apertures 332a being radially aligned with one another and all of the apertures 334a being radially aligned with one another. The apertures 332a are horizontally closer to the wall 202a than the apertures 334a.
With reference to
The parts assembly 499 includes a sealing member 480 for aiding in creating a seal between the edges 206a, 210b of the walls 202a, 202b. Rather than abutting directly, the edges 206a and 210b each abut and compress the sealing member 480. The bolts 260 are pre-tensioned as described above, and the sealing member 480 simply aids in further sealing the edges 206a, 210b.
In the present embodiment, the sealing member 480 is a rubber gasket 480, but it is contemplated that the sealing member 480 could take various forms, including but not limited to: a plastic gasket, polyurethane member, epoxy, and any of various elastomer members. While illustrated as extending only slightly past the walls 202a, 220b, it is contemplated that the sealing member 480 could extend farther into the space between the flanges 220a, 230b. It is contemplated that the sealing member 480 may be received in a recess defined on an interior side of the wall 202 or the flanges 220a, 230b.
The parts assembly 499 also includes a rigid spacing member 450a connected to the flange 220a. It is contemplated that the rigid spacing member 450a could be connected to the flange 230b, or could simply be disposed between the flanges 220a, 230b. Similarly to the member 250, the rigid spacing member 450a is a metal shim 450a welded to the flange 220a. In the illustrated embodiment, however, the shim 450 is welded to a more central portion of the flange 220a and is not welded to the exterior edge of the flange 220a, although still disposed between the bolts 260 and the exterior edge of the flanges 220a, 230b.
With reference to
The parts assembly 599 includes a plurality of radially extending rigid spacing members 550 connected to the flange 220a. The rigid spacing members 550 are metal shim spacers 550 in the present embodiment, but this is just one non-limiting example as before. There is one spacer 550 disposed below (or above) each bolt 260. It is contemplated that fewer spacers 550 may be utilized, for example, one spacer 550 being disposed in alternating spaces vertically between the bolts 260. The spacers 550 extend radially outward of the bolts 260. It is contemplated that the spacers 550 could be longer or shorter than the illustrated embodiment, depending on the specific application.
The shims 550 are welded to the right flange 220a, but it is contemplated that the shims 550 could be welded or otherwise connected to the flange 230b in some embodiments.
It is also contemplated that some of the shims 550 could be connected to the flange 220a, while the remaining shims 550 could be connected to the flange 230b. It is also contemplated that the shims 550 could be inserted between the flanges 220a, 230b during assembly of the parts assembly 599. In some embodiments, it is contemplated that the shims 550 could be included with the parts assembly 299, where the shims 550 could be inserted between 2 or more bolts 260, in addition to the rigid spacing member 250.
With reference to
The parts assembly 699 includes a rigid spacing member 650a connected to the flange 220a and a rigid spacing member 650b connected to the flange 230b. The rigid spacing members 650a, b are metal shim spacers 650a, b in the present embodiment, but this is just one non-limiting example as before. The rigid spacing member 650a abuts the rigid spacing member 650b when the panels 600a, b are connected together as describe above for the panels 200.
Another non-limiting embodiment of a tank 700 according to the present technology is illustrated in
The tank 700 is made from six vertically extending panels 750. In contrast to the panels 200, the panels 750 extend vertically to the full height of the tank 700. As such, the tank 700 is not composed of the multiple cylindrical wall assemblies 110 of the tank 100, but is rather directly formed by the panels 750. Depending on the specific embodiment, it is contemplated that the tank 700 could be made from more or fewer panels 750.
With reference to
The parts assembly 899 includes a flange 820a extending outward from the wall 202a of the left panel 800a and a flange 830b extending outward from the wall 202b of the right panel 800b.
The flange 820a defines a plurality of horizontally aligned apertures 822a and 824a. The apertures 822a and 824a extend vertically along the flange 820a, with all of the apertures 822a being radially aligned with one another and all of the apertures 824a being radially aligned with one another and each aperture 822a having a corresponding aperture 824a vertically aligned with it. The apertures 822a are horizontally closer to the wall 202a than the apertures 824a. Similarly, the flange 830b defines a plurality of corresponding horizontally aligned apertures 832b and 834b, with all of the apertures 832a being radially aligned with one another and all of the apertures 834a being radially aligned with one another and each aperture 832a having a corresponding aperture 834a vertically aligned with it. The apertures 832a are horizontally closer to the wall 202a than the apertures 834a.
With reference to
The right side end portion 204a of a panel 900a has a right flange 920 integrally formed with the wall 202a. The flange 920a is aligned with the edge 206a and extends along the vertical length of the wall 202a. The flange 920 defines the plurality of apertures 222a for receiving fasteners therethrough, as was described in relation to the flange 220 above. The panel 900b further includes the left flange 230b, as is shown in
With reference to
The side end portion 204a of the panel 1000a has a flange 1020a connected to and abutting the edge 206a of the wall 202a. The flange 1020a is welded directly to the edge 206a by an inner weld 1005a. As such, the edge 210b abuts the flange 1020a when panels 1000a and 1000b are connected, rather than abutting the edge 206a. The side end portion 208b of a panel 1000b has a flange 1030 connected to the wall 202b by inner and outer welds 1009b, offset from the edge 210b. The flange 1030 has a rectangular cross section, such that both welds 1009b are disposed toward an exterior of the panel 1000b. The rigid spacing member 250 is welded to the flange 1030 in the illustrated embodiment.
A modified version of the panel assembly 1099, identified as panel assembly 1099′, is illustrated in
Modifications and improvements to the above-described embodiments of the present technology may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present technology is therefore intended to be limited solely by the scope of the appended claims.
The present application is a divisional application of U.S. patent application Ser. No. 16/957,945, entitled “Parts Assembly, Panel, and Tank”, filed Jun. 25, 2020, which is a National Phase Entry of International Patent Application No. PCT/CA2019/1050341, filed Mar. 20, 2019, which claims priority to U.S. Provisional Application No. 62/646,666, entitled “Parts Assembly, Panel, and Tank”, filed Mar. 22, 2018, the entirety of each of which is incorporated herein by reference.
Number | Date | Country | |
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62646666 | Mar 2018 | US |
Number | Date | Country | |
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Parent | 16957945 | Jun 2020 | US |
Child | 17519977 | US |