The invention relates to a pallet container with a thin-walled, rigid inner container constructed of a thermoplastic material for storing and transporting liquid or pourable contents, with a trellis tube support casing tightly enclosing the plastic container, and with a base pallet, on which the plastic container rests and to which the support casing is rigidly connected. The trellis tube support casing (outer container) of the pallet container is constructed of vertical and horizontal tubes that are welded to each other, wherein the peripheral horizontal tubes are rigidly connected to each other. In order to obtain a closed outer container, the peripheral horizontal tubes are connected to each other at least one location.
Such pallet containers with a welded trellis tube support casing are generally known, for example from EP 0 734 967 A. The trellis tube support casing of the top container disclosed therein is constructed from a round tube profile which is severely compressed at the welded intersecting locations. DE 297 19 830 U1 discloses a different pallet container having trellis rods with a tube profile other than a circular cross section, which is explicitly designed to have a uniform cross-section along its entire length without any indentations or depressions that would reduce the cross-section. Another pallet container with a trellis tube support casing made of open profile rods is disclosed in DE 196 42 242 A. In addition, various other containers with a square trellis rod cross-section are disclosed in the state-of-the-art. The trellis tube support casing is typically attached to the base pallet, which can be implemented as a flat pallet made of plastic, wood, sheet-metal or parts thereof with a tubular steel frame (composite pallet), by way of fastening means, such as screws, clips, clams or claws, that grip over or through the lower horizontal trellis frame tube. The fastening means are nailed, attached with pins, screwed or welded on the top plate or the upper outer edge of the pallet. With steel pallets, the trellis tube casing is directly welded. For industrial applications or applications of the pallet containers in the chemically industry, the pallet containers must go though a regulatory permit process and meet various quality criteria. For example, interior pressure tests as well as drop tests with filled pallet containers from different heights are performed. Pallet containers or combination IBC's (IBC=Intermediate Bulk Container) of the aforedescribed type—in lightweight construction without massive corner support posts having a tare weight of about 62 to 80 kg for a 1000 liter IBC, depending on the type of pallet—are preferably employed for transporting liquids. In particular when transporting filled combination IBC's by truck, the liquid contents is exposed to strong acoustic vibrations due to the bumps during transport and the movement of the transport vehicle—in particular under poor road conditions—, which produces continuously changing pressure forces on the walls of the inner container, which in turn causes radial oscillations of the trellis tube support casing with rectangular pallet containers (permanent dynamic oscillation load). Depending on the design of the trellis tube support casing, the stress during longer transport on bad roads becomes so large that the welds in the intersecting regions and even individual rods of the trellis can fatigue and break.
The peripheral tube connections of the horizontal tubes of the trellis tube support casing represent in particular under transport stress and during certification tests (vibration test oval one hour with subsequent inner pressure test of about 100 kPa for 10 minutes) a particular location where fatigue fractures or even tube fractures may preferably occur. The horizontal and vertical tubular rods of the presently most widely used combination IBC's have a circular or square tube cross-section.
With the horizontal tube connections, one side of a tube is made smaller and inserted into the other open tube end to a depth of about 50 mm, whereafter the joint is finish-processed in different ways. With the known pallet containers with circular cross section of the trellis rods (U.S. Pat. No. 5,678,688) finish-processing is performed horizontally from the inside; the tube connection is radially compressed from the inside so that the rear tube half makes flush contact with the inside of the front tube half upon insertion. Holding tongues/holes are punched into the fourfold wall of this tube connection from the outside.
In another conventional pallet container with a square tube cross-section (U.S. Pat. No. 5,645,185), after insertion of the inner tube end, the outer tube end is provided with several peripheral chamfers which are pressed into the angled corner regions of the tube cross-section. In addition, with the most highly stressed tube connections, fastening screws are employed for reinforcement.
In another conventional pallet container with square cross-section (U.S. Pat. No. 6,244,453) the outer half of the tube connection is compressed along a predetermined length in the vertical direction and clinched against each other in an undulating pattern. The inner half of the tube connection hereby retains its shape. In order to withstand tensional stress, for example during the internal pressure test, the clinching engagement must be implemented comparatively deeper and/or with sharp edges, so that there may be a risk of excess material stress at this exterior location under typical stress situations. All conventional tube connections are typically centered in a line on top of one another in the trellis wall of the trellis tube support casing, in which the withdrawal fitting for the liquid contents is disposed at the center in the bottom region of the plastic inner container.
It is an object of the present invention to obviate the disadvantages of the prior art and to provide an improved tube connection without additional fastening means, such as screws, wherein the tube connection has improved resistance, in particular against dynamic vibration stress (e.g., vibration test with subsequent interior pressure test) and longer vibration stress with simultaneous stacking stress (e.g., transport stress).
The object is solved in that the connection of the horizontal tubes is made with a positive clinched joint arranged on the inside of the horizontal tubes, wherein the outside of the horizontal tubes is free from any kind of deformation. The clinched joint is implemented only on the inner half of the horizontal tubes in form of a meshing, undulating, positive connection in form of a vertical indentation from above and below produced with corresponding pressing dies. By arranging the positive clinched joint of the horizontal tubes according to the invention in the connecting region on the inside, only the inner half of the tube ends is deformed, whereas the other half of the horizontal tubes with a square tube cross-section is free from any kind of deformation. Because any cold forming, such as a clinched joint, causes an increase in the rigidity of the material structure, this also implies a simultaneous decrease of the previous elasticity. The material accumulation establishing the positive joint and mutual support of the upper and lower sides of the tube (double tube) also stiffens the tube.
In a vibration test, all side walls of the trellis frame oscillate elastically, alternatingly inwardly and outwardly from their normal planar position, due to the movement of the liquid contents. The elastic deformation of the side walls is greatest in the center region, where the outward “bulging” is about twice as large as the inward “bulging.” As a result, the outside of the horizontal rods is subjected during an outward deformation to approximately twice the tension force than the inside of the horizontal rods during an inward deformation. Tension forces are, unlike compression forces, in particular with dynamically changing pressure loads, extremely critical and can damage the material when they exceed a defined magnitude. They cause cracks mostly at the transition points where the cross-section of the tubes changes. Advantageously, with the tube connection constructed according to the invention, the undeformed outer half of the horizontal tubes is in a region of greater bending (outwardly) with higher tension forces, whereas the inner half of the horizontal rods with positively clinched joints (and higher stiffness with lower elasticity) is in a region with smaller rod bending (inwardly) with lower tension forces.
In this way, a supporting connection is produced which does not require additional components, such as screws, and which has a significantly higher stability under load and resistance against alternating bending stress and in particular against long-term dynamic vibration-induced stress.
Additional modified embodiments according to the invention are as follows:
In a modified embodiment of the invention, the arrangement of the tube connection with a clinched joint of the horizontal tubes of the trellis tube support casing may have alternatingly different insertion directions at the same peripheral position. With a horizontal rod, the tube end on the right side is made smaller and inserted into the tube end on the left side, whereas for the next horizontal rod, the tube end on the left side is made smaller and inserted into the tube end on the right side, etc. In this way, the connecting region can be made uniform, without having a preferred insertion direction.
In another embodiment of the invention, the tube connection of the horizontal trellis tubes can be arranged off-center and superpositioned along a line in a side wall of the trellis tube support casing. Because the greatest deformation occurs in the center of the trellis walls, this advantageous approach moves the clinched joints of the tubes to regions with lower peak stress.
In another embodiment of the invention, the tube connection of the horizontal trellis tubes may be arranged off-center and superpositioned alternatingly in a side wall of the trellis tube support casing. Because the clinched joint of the horizontal tubes in the connecting region always increases the stiffness at this location, this modified embodiment results in more uniform elastic properties of the entire side wall with the connecting region compared to the other side walls of the trellis frame without the connecting regions of the horizontal rods.
In one embodiment of the invention, the clinched joints are no longer arranged in the central region of a side wall (=the region with the greatest bending), but instead in an off-center region of the side wall. Moving the tube connections to off-center regions of the side walls of the trellis tube support casing has the significant advantage in that the side walls bend less at that location and have lower peak values of alternating tension/compression stresses.
The outer or outside cross-sectional regions of the horizontal rods (with the highest tension stress) are preferably not deformed in the outer tubes (which are pushed over the inserted other tube end in the connecting region) by the clinched joints, and the outside of the inner tube is deformed only in the longitudinal direction, so that the inner tube regions (with the clinched deformation) are predominantly subjected to harmless compression stress.
The invention will now be described in more detail with reference to exemplary embodiments schematically shown in the drawings, where:
The connecting region of the horizontal tubes 18 are—as is customary—located at the center of one of the two shorter side walls of the pallet container 10 exactly above the withdrawal fitting 22 which is connected at the center in the base region of the inner container 12. In the present example, the arrow tips shown in the horizontal tubes 18 and pointing to the left indicate that the tube end on the right is made smaller and inserted into the unchanged tube end on the left. The clinched joint of the horizontal tubes is implemented on the inside and is therefore not visible from the outside.
To reduce the cross-section of one tube end for insertion into the other tube end, the previously undeformed, mutually parallel pairs of side walls of the square cross section of the tube end to be inserted are pressed inwardly along a length of about 50 mm, producing an approximately X-shaped tube cross-section, wherein the corners of the X-shaped tube cross-section are pulled slightly inwardly, so that they can be pushed into the undeformed square tube cross-section of the other tube end.
To explain the elastic bending characteristic of side walls of a pallet container 10 during transport stresses,
Similarly,
Lastly,
Number | Date | Country | Kind |
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20 2008 013 055 U | Oct 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/007052 | 10/1/2009 | WO | 00 | 4/1/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/037546 | 4/8/2010 | WO | A |
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Number | Date | Country | |
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Number | Date | Country | |
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61102119 | Oct 2008 | US |