LOAD CELL AND WEIGHING FOOT

Abstract

The invention relates to a load cell comprises a spring body formed rotationally symmetrically about a center axis, having an outer support ring, an upwardly projecting inner force introduction element, and an annular deformation section that is formed as an annular membrane and via which the support ring and the force introduction element are fixedly connected to one another; and a plurality pf strain gauges arranged on a lower side of the membrane for detecting a stretching and/or compressive deformation of the spring body, wherein the strain gauges are electrically connected to a Wheatstone bridge or as a part thereof, with at least one first strain gauge. The mean thickness of the annular membrane in the region of the first strain gauge or gauges is larger than the mean thickness in the region of a second strain gauge or gauges.

Claims

1. A load cell comprising a spring body formed rotationally symmetrically about a center axis and having an outer support ring, having an upwardly projecting inner force introduction element, and having an annular deformation section that is formed as an annular membrane and via which the support ring and the force introduction element are fixedly connected to one another; and a plurality of strain gauges arranged on a lower side of the membrane for detecting a stretching and/or compressive deformation of the spring body, with the strain gauges being electrically connected to form a Wheatstone bridge or as a part thereof, wherein at least one first strain gauge is disposed on a first circle having a first radius about the center axis of the spring body and at least one second strain gauge is disposed on a second circle having a second radius that is greater than the first radius about the center axis of the spring body, wherein the mean thickness of the annular membrane in the region of the at least one first strain gauge is larger than the mean thickness in the region of the at least one second strain gauge.

2. The load cell in accordance with claim 1, wherein two first strain gauges are disposed on the first circle.

3. The load cell in accordance with claim 1, wherein two second strain gauges are disposed on the second circle.

4. The load cell in accordance with claim 1, wherein the annular membrane is formed as planar at its lower side.

5. The load cell in accordance with claim 1, wherein the annular membrane has a rounded extent at its upper side in at least one of its transition region to the outer support ring and its transition region to the inner force introduction element.

6. The load cell in accordance with claim 1, wherein the force introduction element has an undercut at its lower end.

7. The load cell in accordance with claim 1, wherein the thickness of the membrane monotonously decreases from the inside to the outside.

8. The load cell in accordance with claim 1, wherein the thickness of the membrane decreases from the inside to the outside in the region of the at least one first strain gauge and increases from the inside to the outside in the region of the at least one second strain gauge.

9. The load cell in accordance with claim 1, wherein the at least one first strain gauge has the inner force introduction element and the at least one second strain gauge has the outer support ring are arranged overlapping.

10. The load cell in accordance with claim 1, wherein the plurality of strain gauges each have a measurement grid oriented in the radial direction.

11. The load cell in accordance with claim 1, wherein one said first strain gauge and one said second strain gauge are respectively arranged on two mutually oppositely disposed sides of the force introduction element.

12. The load cell in accordance with claim 11, wherein the four strain gauges are arranged along a common line through the center axis of the spring body.

13. The load cell in accordance with claim 1, wherein two first strain gauges are arranged along a first line through the center axis of the spring body and two second strain gauges are arranged along a second line through the center axis of the spring body, with the two lines being rotated with respect to one another by an angle from 5 to 20.

14. The load cell in accordance with claim 1, wherein the membrane is provided in a central region with a peripheral annular web at the upper side.

15. The load cell in accordance with claim 1, wherein the load cell comprises an evaluation circuit that is electrically connected to the plurality of strain gauges and that is configured to generate an output signal corresponding to a weight acting on the force introduction element.

16. The load cell in accordance with claim 15, wherein an external interface is provided that is electrically connected to the evaluation circuit and that is configured to output the output signal generated by the evaluation circuit to external.

17. The load cell in accordance with claim 1, wherein the force introduction element is configured as a force introduction pipe; and/or wherein the spring body is configured in monolithic form.

18. A weighing foot having a load cell, the load cell comprising a spring body formed rotationally symmetrically about a center axis and having an outer support ring, having an upwardly projecting inner force introduction element, and having an annular deformation section that is formed as an annular membrane and via which the support ring and the force introduction element are fixedly connected to one another; and a plurality of strain gauges arranged on a lower side of the membrane for detecting a stretching and/or compressive deformation of the spring body, with the strain gauges being electrically connected to form a Wheatstone bridge or as a part thereof, wherein at least one first strain gauge is disposed on a first circle having a first radius about the center axis of the spring body and at least one second strain gauge is disposed on a second circle having a second radius that is greater than the first radius about the center axis of the spring body, wherein the mean thickness of the annular membrane in the region of the at least one first strain gauge is larger than the mean thickness in the region of the at least one second strain gauge.

19. The weighing foot in accordance with claim 18, wherein the force introduction element has an external thread at its upper end.

20. The weighing foot in accordance with claim 18, wherein the weighing foot comprises a lower part on which the outer support ring of the load cell is supported.

21. A weighing system having a plurality of weighing feet, and having a load carrier supported on the plurality of weighing feet, each weighing foot having a load cell, the respective load cell comprising a spring body formed rotationally symmetrically about a center axis and having an outer support ring, having an upwardly projecting inner force introduction element, and having an annular deformation section that is formed as an annular membrane and via which the support ring and the force introduction element are fixedly connected to one another; and a plurality of strain gauges arranged on a lower side of the membrane for detecting a stretching and/or compressive deformation of the spring body, with the strain gauges being electrically connected to form a Wheatstone bridge or as a part thereof, wherein at least one first strain gauge is disposed on a first circle having a first radius about the center axis of the spring body and at least one second strain gauge is disposed on a second circle having a second radius that is greater than the first radius about the center axis of the spring body, wherein the mean thickness of the annular membrane in the region of the at least one first strain gauge is larger than the mean thickness in the region of the at least one second strain gauge.

Description

[0024] The invention will be described in the following by way of example with reference to the drawing. There are shown

[0025] FIG. 1 a weighing foot in accordance with the invention in a perspective view;

[0026] FIG. 2 a spring body in cross-section;

[0027] FIG. 3 a part view of the spring body of FIG. 2 under the action of a weight load;

[0028] FIG. 4 the spring body of FIG. 2 with strain gauges attached to the lower side;

[0029] FIG. 5A a view from below of the spring body in accordance with FIG. 4, with the strain gauges having a first arrangement;

[0030] FIG. 5B the spring body of FIG. 2, but with the strain gauges having a second arrangement;

[0031] FIG. 6 the spring body of FIG. 2 that is additionally provided with a peripheral annular web at the upper side;

[0032] FIG. 7 a spring body in accordance with a further embodiment in cross-section;

[0033] FIG. 8 a load weighing system in accordance with the invention; and

[0034] FIG. 9 a further weighing system in accordance with the invention.

[0035] The weighing foot 11 in accordance with the invention shown in FIG. 1 comprises a load cell 13 in accordance with the invention and a lower part 15 that has the shape of a spherical segment, is configured as a solid body, and on which the load cell 13 is supported. The load cell 13 comprises a spring body 17 that is formed as monolithic and is rotationally symmetrical about a center axis A (cf. FIG. 2). The spring body 17 comprises an outer support ring 19 and an upwardly projecting inner force introduction element 21. The outer support ring 19 and the inner force introduction element 21 are fixedly connected to one another via an annular deformation section 23. The connection between the load cell 13 and the lower part 15 is such that the load cell 13 is supported on the lower part 15 via the outer support ring 19 and the deformation section 23 is downwardly hermetically tightly sealed by the lower part 15.

[0036] The annular deformation section 23 is formed as an annular membrane 23. The inner force introduction element 21 is formed as a vertically oriented force introduction pipe 21 at whose upper end an external thread is provided via which the weighing foot 11 an be screwed into a load carrier from below.

[0037] If a weight force acts on the spring body 17 via the force introduction pipe 21, the force introduction pipe 21 moves, in particular relative to the stationary outer support ring 19, slightly vertically downwardly, with the membrane 23 of the spring body 17 deforming in the manner shown in FIG. 3. In the lower half of FIG. 3, a diagram is shown that the shows the strain distribution of the spring body 17, i.e. the strain of the spring body 17 in dependence on the respective radial position. As in particular results from this diagram with reference to the shown maximum or minimum of the curve representing the strain distribution, the lower side of the spring body 17 undergoes a stretching (positive strain) on a load in the region of the transition to the force introduction pipe 21 and a compression (negative strain) in the region of the transition to the outer support ring 19. The curve shown has a zero point between the maximum and the minimum.

[0038] This deformation of the spring body 17 can be detected via four strain gauges 27 that are attached to the planar lower side of the membrane 28, that are in particular arranged in the two aforesaid regions, and whose electrical resistance changes in dependence on the strain (cf. FIG. 4), with two respective strain gauges 27 being arranged at two mutually oppositely disposed sides of the force introduction pipe 21. As results from a comparison with FIG. 3, the two inwardly disposed strain gauges 27 are strain gauges subject to tension that detect a stretching of the membrane 23 and the two outwardly disposed strain gauges 27 are strain gauges subject to compression that detect a compression of the membrane 27.

[0039] As shown in more detail in FIG. 5A, the four strain gauges 27 are electrically connected via bond wires 57 (of which only one is provided with a reference numeral for reasons of clarity) to form a Wheatstone full bridge, with the measurement grids of the strain gauges 27 each being oriented in a radial direction, i.e. the measurement direction of the strain gauges 27 is in a radial direction in each case. The two inner strain gauges 27 subjected to tension are disposed on a first circle 53 having a first radius R1 and the two outer strain gauges 27 subjected to compression are disposed on a second circle 55 having a larger second radius R2. The four strain gauges 27 are here arranged along a common line through the center axis A of the spring body 17. The production tolerance can be increased by the linear arrangement of the strain gauges 27 and the symmetry associated therewith since then at least specific production deviations can mutually compensate one another.

[0040] It can be seen from FIG. 5B that the strain gauges 27 can also be positioned slightly differently from the linear arrangement in accordance with FIG. 5A, in particular such that the two inner strain gauges 27 are arranged along a first line and the two outer strain gauges 27 are arranged along a second line through the center axis A of the spring body 17, with the two lines being slightly rotated with respect to one another. It is hereby made possible to reduce the radial spacing of the two strain gauges 27 arranged next to one another on one side such that a spring body 17 having a smaller diameter can be selected, whereby the load cell 13 can be designed in more compact form. The advantage of higher production tolerance stated in connection with the linear arrangement in accordance with FIG. 5A is retained here, i.e. is largely maintained with a slightly deviating positioning.

[0041] As can in particular be recognized from FIG. 2, the mean thickness D of the annular membrane 23 is larger in the region of the smaller first radius R1, i.e. with the two inner strain gauges 27, that in the region of the second radius R2, i.e. with the two outer strain gauges 27. It is hereby made possible that the same or at least similar strains are obtained in amount in both regions so that the resistance/load characteristics of the two inner strain gauges 27, on the one hand, and the resistance/load characteristics of the two outer strain gauge 27, on the other hand, at least substantially correspond to one another in amountdespite different radii. The evaluation of the bridge voltage of the bridge circuit is hereby facilitated and the accuracy of the load cell 13 is increased.

[0042] The greater thickness of the membrane 23 further inwardly in comparison with further outwardly can be due to the ratios of moment of inertia of an area and the spacing of the respective region to the force introduction. Formulated in illustrative or simplified form, a small thickness is required in the region of the larger second radius R2 due to the larger periphery to arrive at the same material volume and thus at an analog strain behavior as in the region of the smaller first radius R2 having the smaller periphery.

[0043] In accordance with the embodiment shown, the thickness of the membrane 23 decreases monotonously, in particular linearly, from the inside to the outside. Such a membrane 23 can be manufactured in a particularly simple manner. However, other transitions from the larger inner thickness to the smaller outer thickness are generally conceivable, for example a step-like reduction.

[0044] At its upper side, the annular membrane 23 respectively has a rounded extent in its transition region to the outer support ring 19 and in its transition region to the inner force introduction element 21. The inner force introduction element 21 furthermore has an undercut 59 at its lower end such that the force introduction takes place as closely as possible to the center axis A of the spring body 17. The accuracy of the load cell 13 can hereby be considerably further improved in each case.

[0045] The strain gauges 27 are electrically connected to an evaluation circuit 41 (cf. FIG. 4) that calculates in a manner known per se the weight respectively acting on the load cell 13 from the bridge voltage of the strain gauges 27 connected to form the full bridge and generates a corresponding output signal. The evaluation circuit 41 is here arranged within the force introduction pipe 21.

[0046] As is shown in FIG. 4, the output signal of the evaluation circuit 41 can, for example, be output to external, in particular to a load carrier such as is described above and below, via a plug 43 that is electrically connected to the evaluation circuit 41. The plug 43 is here arranged within the force introduction pipe 21. If the weighing foot 11 is screwed via the force introduction pipe 21 or via its external thread from below into a load carrier, this has the advantage that the output signal can be output directly and over the shortest path to the load carrier or to a weighing terminal of the load carrier and can be displayed there without external cables or the like additionally being required for this purpose, as would be the case if the output signal were output to external at the support ring side. Other external interfaces, in particular contactless means such as a transmitter that can, for example, be based on the NFC standard, can in another respect also be considered as further means for the external output of the output signal.

[0047] Provision can in particular be made with a contactless configuration of the interface between the weighing foot 11 and the load carrier that an internal electrical energy store 45 such as a battery is provided to form the load cell 13 or the weighing foot 11 independently, i.e. autonomously, of an external energy supply. The electrical energy store 45 is then preferably likewise arranged within the force introduction pipe 21.

[0048] A further embodiment of a spring body 17 is shown in FIG. 6. In contrast with the spring body 17 in accordance with FIGS. 1 to 4, the membrane 23 of the spring body 17 in accordance with FIG. 6 is provided at its upper side with a peripheral annular web 29 that is arranged at least substantially centrally of the membrane 23 in the radial direction. It has been found that the width of the maximum and the width of the minimum of the strain distribution of the spring body 17 shown in FIG. 3 can hereby be increased. The production tolerance can thereby be increased. It has furthermore been found that it can in particular be advantageous on a presence of the annular web 29 if the two inner strain gauges 27 are arranged overlapping with the inner force introduction pipe 21 and if the two outer strain gauges 27 are arranged overlapping with the outer support ring 19 to obtain dependencies of the relative resistance changes on the strain that are as linear as possible to increase the accuracy of the load cell 13.

[0049] A further spring body 17 is shown in a slightly different embodiment in FIG. 7. The spring body 17 in accordance with FIG. 7 differs from the spring body 17 in accordance with FIG. 2 in that the thickness of the membrane 23 in the region of the two inner strain gauges 27 decreases from the inside to the outside and increases from the inside to the outside in the region of the two outer strain gauges 27. The mean thickness D of the membrane 23 in the region of the two inner strain gauges 27 is here, however, stilland thus in accordance with the inventionlarger than the mean thickness D of the membrane 23 in the region of the two outer strain gauges 27. The peripheral annular web 29 is furthermore less high, unlike in the embodiment in accordance with FIG. 6.

[0050] FIGS. 8 and 9 show two different applications of the weighing foot 11 in accordance with the invention. In FIG. 8, a supermarket shelf 31 is shown having by way of example two shelf racks 33 that are each set on a shelf bottom 35 via e.g. four weighing feet 11. The total weight of the respective shelf rack 33, including the products located therein, for example bread, can be determined by a respective monitoring device 37 that is connected to all the weighing feet 11 of the respective shelf rack 33. The filling level of the shelf rack 33 can hereby be monitored. If the total weight of the shelf rack 33 falls below a predefined value, i.e. a display integrated in the monitoring device 37 or separate therefrom can, for example, light up to indicate this state. A plurality of platforms 39, for example pallets such as can be present in a warehouse, are shown in FIG. 9. The platforms 39 are each supported on four weighing feet 11 to determine the total weight of the respective platform 39 including the products arranged thereon. If the same products are stacked on all the platforms 39, the total weights of all the platforms can be combined in a wired or wireless manner, e.g. by wireless LAN, whereby a permanent inventory of the respective product is possible.

Reference Numeral List

[0051] 11 weighing foot

[0052] 13 load cell

[0053] 15 lower part

[0054] 17 spring body

[0055] 19 support ring

[0056] 21 force introduction pipe

[0057] 23 membrane

[0058] 27 strain gauge

[0059] 29 annular web

[0060] 31 shelf

[0061] 33 shelf rack

[0062] 35 shelf bottom

[0063] 37 monitoring device

[0064] 39 platform

[0065] 41 evaluation circuit

[0066] 43 plug

[0067] 45 electrical energy store

[0068] 53 first circle

[0069] 55 second circle

[0070] 57 bond wire

[0071] 59 undercut

[0072] A center axis

[0073] D thickness

[0074] R1 first radius

[0075] R2 second radius