DE8706579U1 - Temperature-controlled tank container - Google Patents

Description

DESCRIPTION

A temperature-controlled tank container of the type specified in the preamble of claim 1 is known from DE-C2-2 917 364* In this publication it is emphasized as important that the thermal insulation jacket is arranged on the flat wall surfaces of a cuboid-shaped container frame. There are large triangular flow cross-sections between these flat wall surfaces and the cylindrical tank jacket, which means that a large part of the temperature control medium can flow without contact with the tank jacket, especially since passage openings for the temperature control medium are arranged in support walls arranged transversely to the longitudinal axis relatively far away from the tank jacket.

In the known tank container, the space between the tank shell and the thermal insulation shell is divided by dividers in such a way that the tempering medium flows essentially in the axial direction of the tank, whereby laminar flow can occur over longer distances. Depending on the arrangement of the dividers, a flow path is formed that is only two to four times the length of the tank.

For the reasons mentioned above, the extent to which the temperature control medium used for cooling or heating is used in the known tank container is limited.

Apart from that, the arrangement of the thermal insulation jacket on the flat surfaces of the container frame requires a considerable amount of insulation and covering material and means a corresponding increase in the tare weight of the entire tank container.

Finally, the known tank container requires a box-shaped container frame; if this is missing, the known construction is unsuitable.

The invention is based on the general task of at least partially eliminating disadvantages that occur in comparable tank containers according to the state of the art.

In view of the above-described state of the art, a more specific object of the invention can be seen in specifying a temperature-controlled tank container that can be

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complete container frame and which, with a simple structure and the lowest possible tare weight, allows even flushing of the tank shell with good utilization of the tempering medium.

In the solution to this problem specified in the characterizing part of claim 1, the tempering medium is guided in a uniformly thick layer, which in practice is only a few centimeters, along a helical path around the cylinder circumference in close contact with the tank shell, at least once in both directions. The uniform and small distance of the thermal insulation shell from the tank shell and the helical shape of the flow path cause a constant circulation of the tempering medium, so that the entire flow volume is used for an intensive heat exchange on the surface of the tank shell.

Because of the tight enclosure of the tank shell, a relatively small amount of insulation and covering material is required for the thermal insulation shell, which has a positive effect on the tare weight of the tank container. The helical separating webs are easy to attach and at the same time provide more stable support for the thermal insulation shell than the conventional circumferential rings, as they offer support points at continuously different locations in the axial direction.

In contrast to the known tank container discussed above, a closed box-shaped container frame is not required. Rather, the design according to the invention is preferably suitable for tank containers in which the frame consists only of two end groups connected to the bottoms of a self-supporting tank.

From DE-Ul-I 851 590 it is known to use helically laid wires in a double-walled storage tank in order to keep parts of an outer shell at a distance from an inner shell. Apart from the fact that the outer shell and inner shell of the known storage tank are only partially spaced apart, the wires used there are neither intended nor suitable for continuous and separate wires.

* to form separate channels for the flow of a tempering medium, beyond this difference, the separating webs designed as profile strips in the tank container according to the invention simultaneously serve to reinforce the pressure of the cylindrical tank shell in a similar way to conventional circular reinforcement rings.

Advantageous further developments of the invention are characterized in the subclaims. If the tank according to claim 2 is connected to the respective front frame via end rings, it can be expedient not to interrupt this, but to let at least some of the separating webs end at a distance in front of the front ring. The inner area of the respective base is then not covered by the tempering medium, which, given the good tempering of the rest of the tank surface, is generally not a disadvantage. In a similar way, only a relatively narrow channel can be provided on the front side provided with the inlet and outlet openings for the tempering medium, which leads to the respective opening and is connected to the helical channel via a correspondingly limited opening in the respective front ring. Claims 4 to 6 relate to advantageous designs of the thermal insulation jacket and additional stiffening measures.

Preferred embodiments of the invention are explained in more detail below with reference to the drawings. In the drawings,

Figure 1 is a schematic side view of a temperature-controlled tank container,

Figure 2 is a front view of the tank container, the left half of Figure 2 being a front view of the

Tank container according to Figure 1, seen from the left, and the right half shows a front view from the right.

Figures 3A and 3B are schematic views of the two front sides of a tank container in a different design

form of formation.

According to Figures 1 and 2, the tank shell consists of a cylindrical shell 10 and bottoms attached to both ends

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11, 12, which are connected via end rings 13 to diagonal struts 14 of end frames 15. Such a purely frontal suspension of a cylindrical tank on two end frames is known from DE-C2-3 212 696. In Figure 1, |

the two front frames 15 are additionally connected to each other via lower longitudinal beams 16 '. The right one according to Figure 1
Tank bottom 12 is provided with a manhole 17 and a drain nozzle 18. Near the left tank bottom 11 in Figure 1
is also in the apex line of the cylindrical tank shell
10 a filling connection 19 is shown.

Around the cylindrical shell 10 of the tank shell are two
Dividers 20, 21 are placed along two 180° offset
In Figure 1 it is assumed that each separating web 20, 21 surrounds the tank shell twice, with all four end points of these separating webs in the representation according to Figure |

f 1 lie in a horizontal plane containing the tank axis. The two separating webs 20, 21 can consist of rectangular profile strips of, for example, 8 mm x 30 mm, which are welded to the tank shell with their narrow edge. In order to avoid stress peaks at the end points of the separating webs 20, 21, these are attached to pipe sockets 22, each of which is welded to the tank shell with a closed circular seam ^.

The dividers 20, 21 hold a total of 23

drawn thermal insulation jacket at a distance from the tank shell, whereby this thermal insulation jacket is designed according to the diagram in Figure 1 below
indicated partial section of an inner skin 24, a
Outer skin 25 and insulating compound 26 arranged between them. In areas between the separating webs 20, 21,

the inner skin 24 of the thermal insulation jacket 23 by additional spacers in the form of bead-like or grommet-like formations
27 be supported on the tank shell.

The insulating compound 26 preferably consists of
large polyurethane foam panels, which are pre-protected on the surface facing ^the inner skin \ 24 and thus calibrate to

the required cylindrical shape. |

ti The thermal insulation jacket 23 runs with the through the separating \

webs 20, 21 predetermined cylindrical shape over the entire length *

of the tank container up to the front frame 15 and ends at flat or curved thermal insulation panels 28 inserted into these front frames 15, which can have a similar structure to the thermal insulation jacket 23. The tank is thus insulated on all sides. as can be seen from the left half of the front view according to Figure 2, the left bottom 11 of the tank according to Figure 1 is provided with two openings 31, 32, which are used for connection to a temperature control medium supply system. Such supply systems are particularly common on container ships, where the temperature control medium is in particular cooling air, which is available in large flow quantities with a small pressure difference. Similar supply systems are also present in port container storage facilities.

In such a cooling system, the openings 31, 32 of the tank container are also referred to as "port holes", with the lower opening 31 forming an inlet opening and the upper opening 32 forming an outlet opening. The flow of the cooling medium is caused by an overpressure prevailing at the inlet opening 31 and a corresponding negative pressure acting at the outlet opening 32.

As can also be seen from Figures 1 and 2, the space between the left tank bottom 11, the thermal insulation jacket 23 and the front frame 15 closed with a thermal insulation plate 28 is divided by a partition plate 33 running in the horizontal center plane both inside and outside the front ring 13. The partition plate 33 is attached to the two pipe sockets 22 at which the partition webs 20, 21 end on the two opposite sides of the tank jacket. The front ring 13 is provided with openings 34 both above and below the partition plate 33. Corresponding openings can alternatively or additionally be provided in the flanges of the diagonal struts 14 running in the longitudinal direction of the tank. As a further variant, it is also possible to guide the cooling medium around the diagonal struts 14, provided that a sufficient distance is maintained between them and the thermal insulation plate 28 and the thermal insulation jacket 23.

In this way, a flow channel is formed for the tempering medium, which runs from the lower inlet opening 31

through the lower gaps 34 in the front ring 13, one of the two helical flow channels formed between the two separating webs 20, 21 to the area of the tank bottom 12 on the right according to the figure, from there back through the other of the two helical flow channels and through the openings 34 visible in the front ring 13 to the outlet opening 32. Since the flow channels between the two separating webs 20 have a relatively low, uniform height, the entire tank shell is flowed around by the tempering medium in close contact. The helical shape of the flow channels simultaneously causes a continuous circulation of the tempering medium, which prevents the formation of a laminar flow that is unfavorable for heat exchange.

As can be seen from Figures 1 and 2, the front ring 13 connecting the right tank bottom 12 to the front frame 15 is continuous and only interrupted in the area of the drain nozzle 18. The diagonal struts 14 connecting this front ring 13 to the front frame 15 also have no openings. Instead, the two separating webs 20, 21 end at a distance from the front ring 13 and thus leave space for the passage of the tempering medium. The part of the tank bottom 12 located within the front ring 13 is not covered by the tempering medium in this embodiment. Due to the good flushing, particularly over the entire cylindrical shell, tempering of the inner parts of the tank bottoms 11, 12 can generally be dispensed with. If this part is to be tempered, the separating webs 20, 21 are extended to the right end ring 13 and this or the corresponding diagonal struts 14 are provided with similar openings 34 as indicated in the left part of Figure 1.

While in the embodiment according to Figure 1 only two helical separating webs 20, 21 offset by 180° are provided, in principle four or a larger even number of separating webs can also be present, which result in a correspondingly larger number of helical flow channels in order to extend the entire flow path for the tempering medium over the tank surface.

Figure 3A shows a schematic view of the front side of a tank container provided with the inlet and outlet openings 31, 32, which is provided with four helically applied separating webs 35, 36, 37, 38. Figure 3B shows the opposite front side of the same tank container. On the front side shown in Figure 3A, the separating webs 35 to 38 run up to the front ring 13. Furthermore, each of the two openings 31, 32 opens into a connecting channel 40 formed by two limiting webs 39 running at an acute angle, which is connected via openings in the front ring 13 to the flow channel formed between a pair of separating webs 35, 36 and 37, 38. Outside the connecting channels 40, the front ring 13 is provided with further openings which connect the flow channel formed between the separating webs 36, 37 across the dome area of the base with the opposite flow channel formed between the separating webs 35, 38. On the other end shown in Figure 3B, the separating webs 35, 37 are led up to the front ring 13 provided there, while the two other separating webs 36, 38 end at a distance from it. In this design, the tempering medium takes the path indicated by the arrows A, B, C, D and E from the inlet opening 'J1 to the outlet opening 32, which wraps around the tank in a spiral shape a total of four times.

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Claims (1)

STRSHL' S'SCHÜBEL-HOPF 'GROENING SCHCLZ PATENT ATTORNETS EUROPEAN PATENT ATTORNETS Westerwald Ironworks Gerhard GmbH
DEG-28293 Temperature-controlled tank container PROTECTION CLAIMS 1. Temperature-controlled tank container with a tank mounted between two end frames (15), the shell of which consists of a cylindrical shell (10) and two end bases (11, 12), a thermal insulation jacket (23) enclosing the tank jacket on all sides, on one end face of which two openings (31, 32) for the inlet and outlet of a temperature control medium are arranged one above the other, and separating webs (20, 21) provided between the tank shell and the thermal insulation jacket (23), which force the tempering medium to flow around the tank shell, characterized in that the separating webs (20, 21) are designed as at least two profile strips helically surrounding the cylindrical shell (10) of the tank shell. 2, tank container according to claim 11, characterized in that the tank is connected to the end frames (15) via end rings (13) attached to its bottoms (11, 12) and that the front side not provided with the inlet and outlet openings (31, 32) at least some of the separating webs (20, 21) end at a distance from the front ring (13). 3. Tank container according to claim 2, characterized in that at least some of the separating webs (20, 21) are attached to the front ring (13) on the front side provided with the inlet and outlet openings (31, 32), and that flow channels formed between two separating webs are connected to the openings (31, 32) via openings (34) in the front ring (13) and via connecting channels (40) formed by limiting webs (39) on the tank bottom (11). 4. Tank container according to claim 3, characterized in that the limiting webs (39) leading from each opening (31, 32) to the end ring (13) run towards one another at an acute angle. 5. Tank container according to one of claims 1 to 4, characterized in that the thermal insulation jacket (23) comprises an inner skin (24), an outer skin (25) and insulating mass (26) arranged therebetween. 6. Tank container according to claim 5, characterized in that the inner skin (24) has bead-like or spout-like formations (27) for additional support relative to the tank shell. 7. Tank container according to claim 5 or 6, characterized in that the insulating mass (26) is applied in the form of foam panels which are pre-protected on their surfaces facing the inner skin (24)*