DE7611754U1 - CONTAINER SYSTEM WITH FLEXIBLE STORAGE - Google Patents

Description

Ronald J. Ricciardi, Garfield, New Jersey / USA

Container system with flexible storage

The invention relates to a flexibly mounted container system.

The system according to the invention is particularly useful for this, among other things suitable to be used for weighing the contents of a container, especially when the weight of the material in the Container, for example, is relatively large.

It has already been in a considerable number and variety Used by flexibly mounted container systems in which facilities such as bearings, connecting pins, cutting edges and the like were used, but this was not fully satisfactory due to a lack of sensitivity, especially with regard to the handling of relatively large weights. To avoid these undesirable properties bending pins were used, but these were previously of a complicated structure and expensive to manufacture, bulky and had relatively low load limits in practical use.

The object of the invention is therefore to create a flexibly mounted container system with improved properties,

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in which a novel combination of properties is designed to be an effective solution to the above gives rise to the difficulties mentioned and in which the desired results are achieved. The container system according to the invention should therefore be able to work linearly, cleanly and repeatedly with high sensitivity, should be able to be able to carry a wide range of loads, including very heavy loads on the order of several Tons and should be of simple construction with relatively low manufacturing costs.

The container system according to the invention should be practically smooth Form a system that is not affected by dirt and temperatures within a relatively large working area that is very resistant to corrosion and with very little wear and tear.

This object is achieved by a flexibly mounted container system which is characterized according to the invention through a container, a mounting bracket rigidly attached to the container, a first flange-like element that is attached to the Mounting bracket is rigidly attached, a second flange-like element that is spaced from and parallel to the first flange-like Element is arranged, a rigidly attached to the second flange connecting element, a third flange-like element that is rigid on the connecting element is mounted a fourth flange-like element that is spaced is arranged from and parallel to the third flange-like element, a support frame which is attached to the fourth flange-like Element is rigidly attached, and a plurality of elongated elastic transverse elements, each at right angles extend to the first and second and to the third and fourth flange-like elements and these each with one another

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the connect, with the cross-sectional areas of the cross-learners in any plane parallel to their respective flange-like Elements together symmetrically about a pivot axis are arranged around which extends at right angles to their corresponding flange-like elements.

In the container system according to the invention there is a mounting bracket attached to one side of the container, and a second mounting bracket is on the opposite side of the container attached. A flexure pivot bearing device is attached to the second mounting bracket and is similar to that described above described with the first mounting bracket. In addition, a third mounting bracket is attached to the bottom of the container, and a bending pivot bearing device is attached to this bracket, which is relatively similar to the first and second previously described Schv / enklagereinrichtung, whereby the container is perfectly stored and undesirable lateral movements of the same can be prevented.

In one embodiment of the invention, there are essentially four mutually identical transverse elements are provided which interconnect their respective flanges, and preferably the cross members are made of stainless steel selected from the group consisting of AISI type 410, AISI type 420 and AISI-Type 440, namely annealed, i.e. heat-treated to a hardness between about 42 and about 55 Rockwell C. Preferably the elements are flange-like Made of AISI type 304 stainless steel. The cross members between their corresponding flange-like members are in one embodiment of the invention ribbon-like elements, and each of the elements is spaced from the other transverse elements. According to a further feature of the invention are the transverse elements between corresponding flange-like elements in two planes at right angles to one another

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arranged. The preferred width is the width of each of the elements considerably greater than its thickness and the length of each of the elements is considerably greater than its width.

According to a further feature of the invention, the four transverse elements extend at right angles to their respective flange-like elements / wherein two of the transverse elements are each arranged in a plane and the other two are arranged in a second plane which is perpendicular to the first plane, the four Cross members are symmetrically disposed about a pivot axis that is perpendicular to their corresponding flange-like members, and the cross members are equally spaced from the pivot axis. Preferably, the two elements in a "plane at a distance spaced from each other which is substantially equal to the width of the cross elements. In one embodiment of the invention] are the cross elements band-like elements, and the width

* each element is much larger than its thickness,

and the length of each of the elements is substantially greater than its width. Preferably the width of each of the transverse elements is on the order of about 12.9 times its thickness and the length of each of the transverse members is on the order of about 2.4 ?. times its width.

Only the particularly essential features of the invention have been specified above so that the following detailed description and the contribution made to the technology may be more easily understood. However, the invention still has several properties which are described in detail below. The general concept ₍ on which this description is based can easily be used as a starting point to create other embodiments for solving the object on which the invention is based. The invention therefore also includes this.

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j like equivalent constructions.

Further features and usefulnesses of the invention emerge from the description of exemplary embodiments

;; of the figures. From the figures show:

r Fig. 1 is a perspective view of an embodiment of the

i flexibly mounted according to the invention

f. \ container system;

. Ί Figure 2 is a plan view of the system of FIG. 1;

I. Figure 3 is a side view of the system of Figure 1;

I Fig. 4 is an enlarged perspective [: Detail view to show details

\ the flexible pivot bearing device of the container

^: ; the support frame;

Fig. 5 is a cross-sectional view of the bearing device according to ί Fig. 4 to illustrate the flexible pivot bearing mounting

direction in their normal or neutral position;

FIG. 6 is a cross-sectional view similar to FIG. 5, however

the bending pivot bearing device is shown in its pivoted or rotated position;

FIG. 7 is an enlarged front view of the bearing device of FIG. 4; and

8 is an enlarged perspective view of a flexible pivot bearing the storage facility.

Included in the illustrated embodiment of the invention the flexibly mounted container system, as can best be seen from FIGS. 1 to 3, a container 10 which is capable of

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is to carry a wide range of loads, including very heavy loads of the order of, for example, several tons. A first mounting bracket 12 is on the 14 designated point firmly attached to the container, preferably on the side wall in the area of the upper end. A first The flange-like element 16 is fixedly attached to the first mounting bracket 12. A second flange-like element 18 is in At a distance from and parallel to the first flange-like element 16.

A connecting element 20 is attached to the second flange-like element 18, and a third flange-like element 2 2 is rigidly attached to the connecting element 20. A fourth flange-like element 24 is arranged at a distance from and parallel to the third flange-like element 22. A support frame 26 is rigidly attached to the fourth flange-like element 24, specifically at the point indicated by 28. The base of this support frame is fixed on a base plate 30 intended for these two. A plurality \ ίοτ \ stretched elastic cross members, generally indicated at 32, extending at right angles to, and connects each of the first and second flange-like member 16, 18 and the third and fourth flange-like member 22, 24. The function and the operation of these cross members will be described in detail later.

A second mounting bracket 34 is rigidly attached to the container 10 on the upper side wall opposite the first mounting bracket 12. A fifth flange-like element 36 is attached to the mounting bracket 34, and a sixth, spaced therefrom Splash element 38 is arranged parallel to the fifth flange-like element 36. A connecting element 40 is rigidly attached to the sixth flange-like element 38, and a seventh flange-like element 32 is rigidly attached to the Connecting element 40 attached. An eighth flange-like

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Element 44 is spaced from and parallel to the seventh Flange-like element 42 is arranged, and a support frame 46 is rigidly attached to the eighth flange-like element 44. The support frame 46 is also mounted on the base plate 30. A plurality of elongated elastic transverse elements, which are indicated generally at 4 8, extends at right angles to and connects respectively the fifth and the sixth flange-like element 36, 38 and the seventh and the eighth flange-like element 42, 44. The cross-sectional areas the transverse elements in any plane parallel to their respective flange-like elements are collectively symmetrical aligned about a pivot axis extending at right angles to their respective flange-like elements.

Reference is made further to FIGS. 1, 2 and 3. A third bracket 50 is rigidly attached to the bottom of the container 10, and a ninth flange-like element 52 is rigidly attached to this bracket. A tenth flange-like element 54 is arranged in parallel with the ninth flange-like element 52, and a third connecting element 56 is fixed attached to the tenth flange-like member 54. An eleventh flange-like element 58 is on the connecting element 56 rigidly attached, and a twelfth flange-like element 60 is spaced from and parallel to the eleventh flange-like element Element 58 arranged. A support frame 62 is rigidly attached to the twelfth flange-like element 60. A majority of elongated resilient cross members, indicated generally at 64, extend to and connect respectively the ninth and tenth flange-like elements 52, 54 and the eleventh and twelfth flange-like members 58, 60; the cross-sectional areas the cross members in any plane parallel to their corresponding flange-like members are common arranged symmetrically about a pivot axis that extends

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perpendicular to their respective flange-like elements extends ,,

It goes without saying that the flange-like elements 16, 18, 22, 24, 36, 38, 42 and 44 are preferably identical and that the elongated elastic transverse elements 32 and 48 are also are preferably identical. The flange-like members 52, 54, 58 and 60 are preferably smaller than the flange-like ones Elements 16 and 18, but of the same proportioned shape. The elongated resilient cross members 64 are preferred smaller than the transverse elements 32 and 48, but are also of the same proportioned shape. This is through establishes the fact that the pivot bearing means on the sides of the container account for most of the container weight carries, while the pivot bearing devices at the bottom of the container primarily to prevent undesirable serve lateral movement. To simplify the explanation of the mounting device should only be the flange-like elements 16, 18, 22 and 24 and their corresponding transverse elements 32 in the are individually described below, since the two other pivot bearing devices are constructed similarly and similarly work.

As best seen in Figures 4 through 8, the plurality of elongated resilient transverse members comprises 32 four ribbon-like stretched elastic, essentially like cross members 66, 68, 70 and 72 that are between the two Flanges 16 and 18 are arranged, and their ends are for example welded to the flanges at point 74 or otherwise rigidly attached. How best to figure out 5 shows, the cross members 68 and 72 are arranged in one plane, and the cross members 66 and 70 are in one arranged second plane, which is perpendicular to the first plane.

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The distance, designated by 76, between the transverse elements 6 8 and 72 is substantially equal to the distance 78 between the cross members 66 and 70, and the length of the distances 76 and 78 is substantially equal to the width 80 of each cross member.

The four transverse elements are symmetrical about a pivot axis which is designated by 82 in FIGS. 5, 6 and 8 and extends at right angles to the flange-like elements 16 and 18 and the cross members are equidistant from this pivot axis.

The transverse elements are ribbon-like elements and the width 80 of each element is substantially greater than its thickness shown in FIG FIG. 5 is designated by 84. The length of each of the transverse elements, denoted by 86 in FIG. 7, is substantially greater than its width 80.

The flange-like element 16 is rigidly attached to the bracket 12, and the flange-like element 18 is rigid to the connecting element 20 fastened, for example with screws and nuts 88, 90. If the two flange-like Elements 16 and 18 are in their normal or neutral position, the transverse elements 66, 68, 70 and 72 are in their positions shown in FIG. When a torque is applied to the flange-like element 16 engages, for example by penetration a load in the container, it becomes flange-like Element 18 in relation to the other flange-like element 16 rotated by an angle, which is designated in Figure 6 with 92, whereby the transverse elements 66, 68, 70 and 72 are rotated. The transverse elements are substantially uniform across twisted their length so that the ends are arranged adjacent to the flange 16, as shown in Figure 6 with a continuous Is indicated by a line, and the ends abutting the flange element 18 are in a position which is shown in FIG

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with dashed lines 66 ', 68', 70 'and 72' is. When the previously applied torque ceases, for example when the container is empty, the puddles return to theirs Neutral position back, as shown in Figure 5, due to the elasticity of the transverse elements. At the same time will the flange-like element 2 2 by the same amount in the opposite direction with respect to the flange-like element 24 rotated, whereby the flange-like elements 16 and 24 remain parallel to one another at all times, but the flange-like element 16 differs with respect to the flange-like element Elements 24 moved up and down while the weight in the container is increased or decreased. The relative movement the flanges 16 and 24 in the vertical direction reliably shows that which has been added to or removed from the container 10 Weight linearly. It is particularly important to emphasize that the linearity of the movement is very sensitive, accurate and reproducible although the loads carried by the container can be very heavy, for example on the order of several Metric tons. Thus, the operation can be carried out almost indefinitely with very high precision of the forward movement and backward movement the flanges are repeated. In view of the fact that the four transverse elements are symmetrical about the pivot axis 82 are arranged around, there is a direct linear relationship between the applied torque and the angle of rotation 92

To measure the relative movement of the flanges 16 and 24, thereby indicating the weight added or added to the container 10 has been removed, a sensor arm 96 shown in Figure 3 is provided, one end of which is rigidly mounted on the fastening element 20. The other end of the sensing arm is with a deflection probe 9 8 which may be of any commercially known type, for example a linear variable differential converter (LVDT). The length of the feeler arm 96 is like this

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chosen that there is a reasonable level of gain in the Relative movement of the connecting element 20 results. It is obvious - that in some systems the weight in the container is between For example, other systems can weigh between 0 and 1812 Kp (0 and 4000 pounds) can change. In order to keep the deflection range of the deflection probe 98 practically constant, If a peder element 100 is provided for calibration, one end of which is at the point marked 102 with respect to the sensor ς-irms is rigidly attached and the other end is connected to the feeler arm. So the spring constant of the spring 100 is chosen so that there is a compensation for the load area of the container, whereby a practically constant Deflection range of the deflection probe is maintained, regardless of the weight range of the container.

The cross members can be made of any suitable material, such as stainless steel made of is selected from the group consisting of AISI-Type 410, AISI-Type 420 and AISI Type 440, annealed to a hardness between about 42 and about 55 Rockwell C. Preferably, the angle of rotation extends 92 to about ten degrees. In general, the flange-like members 16, 18, 22 and 24 are made of stainless steel AISI type 304 manufactured. As soon as the transverse elements 66, 68, 70 and 72 are welded to the flanges, those shown in FIG S visible end surfaces 17 and 19 machined so that the suitable dimensions result. Thereupon the entire bending pivot bearing device is heat treated, whereby the two flanges 16 and 18 are annealed and the cross members 66, 68, 70 and 72 to a hardness of about 42-45 Rockwell C. are annealed to form feathers. The transverse elements are hardened due to the heat treatment process.

As an example of a flexure pivot bearing assembly constructed in accordance with the invention, each cross member has a thickness

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j of about 0.234 cm (0.092 inches), width 80 of about

3.02 cm (1.187 in) and a length 94 of about 7.3 cm (2.875 in.) Customs Service). This pivot bearing has a radial movement of three degrees (angle 92) when a torque of about 13.82 kpm (100 ft. Lb) of flange-like member 16 with respect to the other flange-like member 18.

It can be seen that the total cross-sectional area of the transverse elements, ie the thickness 84 and the width 80 as well as the number of transverse elements, are chosen so that the transverse elements withstand the compressive force (or tensile force) occurring at right angles between the structural elements between the complementary flange-like elements are effective as required for the particular system. Pressure forces of up to 10 tons or significantly more are not unusual and can be processed by the flexible pivot bearing device according to the invention. Preferably, the Working temperature range of the flexural pivot bearing device is between about -29 ° C (-20 ⁰ P) and about 71; 2 ° C (+ 160 ⁰ F). Within this temperature range, the flexible pivot bearing device works extremely well and with very little distortion.

It can therefore be seen that the invention provides an improved, flexibly mounted container system is created, which due to its simplicity, working characteristics and accuracy is superior to the prior art.

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Claims (15)

Sqhutz.claims. ' 1. Flexibly mounted container system, characterized by a container (10), a mounting bracket (12) rigidly attached to the container, a first flange-like element (16) which is attached to the mounting bracket is rigidly attached, a second flange-like element (18) spaced jj and parallel to the first flange-like element is, a connecting element rigidly attached to the second flange element (20), a third flange-like element (22) resting on the connecting element (20) is rigidly mounted, a fourth flange-like element (24) which is at a distance of and is arranged parallel to the third flange-like element, a support frame (26) attached to the fourth flange-like Element is rigidly attached, and a plurality of elongated elastic transverse members (32), each extending at right angles to the first and second and to the third and fourth flange-like elements and connecting them to one another, the cross-sectional areas of the transverse elements in any plane parallel to theirs respective flange-like elements are arranged together symmetrically around a pivot axis (82) which is at right angles extends to their respective flange-like elements. 2. Flexibly mounted container system according to claim 1, characterized in that four substantially identical Querele- 7611754 06/12/76 elements are provided that are of ribbon-like shape and where the width of each element is substantially greater than its thickness and the length of each element is substantially greater as its width, and that the transverse elements are respectively between the first and second flange-like elements and between the third and fourth flange-like elements are mounted. 3. Flexibly mounted container system according to claim 1 or 2, characterized in that the first mounting bracket on one Side of the container is arranged and that the system further comprises a second mounting bracket on the opposite Side of the container is rigidly attached, a five-point flange-like element that is rigidly attached to the second mounting bracket is attached, a sixth flange-like element that is parallel is arranged to and at a distance from the fifth flange-like element, a second connecting element which is attached to the sixth flange-like element is rigidly attached, a seventh flange-like element which is attached to the connecting element is rigidly attached, an eighth flange-like element spaced from and parallel to the seventh flange-like element is arranged, a second support frame which is rigidly attached to the eighth flange-like element, and a A plurality of elongated elastic transverse members, each perpendicular to the fifth and sixth and to the seventh and eighth flange-like elements extend and connect them to each other, the cross-sectional areas of the Cross members in any plane parallel to their respective flange-like members symmetrically about a common Pivot axis are arranged around, which extends at right angles to their respective flanschähnltchen Elenenten. 4. Flexibly mounted container system according to claim 3, characterized by a third mounting bracket which is rigidly attached near the bottom of the container, a ninth flange-like one Element that is rigidly attached to the mounting bracket, a tenth, spaced from it, flange-like 7611754 12.0876 Element spaced from and parallel to the ninth
flange-like element is arranged, a third connecting element which is rigidly attached to the tenth flange-like element, an eleventh flange-like element which is rigidly attached to the third connecting element, a twelfth
flange-like element spaced from and parallel to
the eleventh flange-like element is arranged, a third support tube which is rigidly attached to the twelfth flange-like element, and a plurality of elongated elastic transverse elements, which respectively extend at right angles to the ninth and tenth and to the eleventh and twelfth flange-like elements and these respectively connect with each other,
the cross-sectional areas of the transverse elements in any
Plane parallel to their respective flange-like elements
arranged together symmetrically about a pivot axis
extending at right angles to their respective flange-like elements. 5. Flexibly mounted container system according to a r ".er claims 1 to 4, characterized by a sensor arm, one of which
End is rigidly connected to the connecting element, and one
Deflection sensor means connected to the other end of the feeler arm, whereby the deflection sensor means determines the weight contained in the container. 6. Flexibly mounted container system according to claim 5, characterized by a spring device, one end of which is connected to the sensor arm and the other end with respect to the
The sensor arm is rigidly attached, whereby the deflection range of the sensor device is kept essentially close,
regardless of the range of weight carried by the container. 7. Flexibly mounted container system according to one of claims 1 to 6, characterized in that four flange-like egg 7611754 08/12.76 elements are provided, each between the first and second flange-like element and are arranged between the third and fourth flange-like element and the im are essentially parallel to each other. 8. Flexibly mounted container system according to one of claims 1 to 7, characterized in that the first and the fourth flange-like element lie in the same plane and that the second and the third flange-like element in the same Lie level. 9. Flexibly mounted container system according to one of claims 1 to 8, characterized in that the transverse elements are made of stainless Steel made from that of AISI type 410, AISI-Type 420 and AISI-Type 440 existing group selected and is annealed to produce spring elasticity. 10. Flexibly mounted container system according to one of claims 1 to 9, characterized in that the transverse elements between the first and second flange-like elements and between the third and fourth flange-like elements are band-like elements and that each of the transverse elements is spaced from the transverse elements adjacent thereto. 11. Flexibly mounted container system according to one of claims 1 to 10, characterized in that the transverse elements between the first and second flange-like members and between the third and fourth flange-like members, respectively are arranged in at least two mutually perpendicular planes. 12. Flexibly mounted container system according to one of claims 2 to 11, characterized in that two of the transverse elements, between the first and the second flange valve Union element are arranged, are arranged in one plane and the two other transverse elements in a second plane which is perpendicular to the first plane, the four transverse elements are arranged symmetrically about a pivot axis extending perpendicular to the first and second flange-like elements, and that the four transverse elements are arranged at the same distance from the pivot axis. 13. Flexibly mounted container system according to claim 12, characterized characterized in that the two transverse elements lying in one plane are separated from one another by a distance, which is substantially equal to the width of the transverse elements. 14. Flexibly mounted container system according to claim 12 or 13, characterized in that two of the between the third and fourth flange-like element arranged transverse elements lie in one plane and the two other transverse elements lie in a second plane that is perpendicular to the first plane, the four transverse elements are arranged symmetrically about a pivot axis which is perpendicular to their respective flange-like ones Elements extends, and that the four transverse elements are arranged at equal distances from the pivot axis. 15. Flexibly mounted container system according to one of claims 1 to 14, characterized in that the width of each the transverse elements on the order of about 12.9 times theirs Thickness and the length of each of the cross members is on the order of about 2.42 times their width. 7611754 06/12/76