FR2540990A1 - Weighing apparatus using deformation gauges, in particular for bathroom scales - Google Patents

Abstract

The apparatus, comprising a single sensitive bar or element 1 which is solidly attached at its ends respectively to a load receiving plate and to a support seat, and which is fitted with at least three deformation gauge assemblies fixed to the said bar, is characterised in that it comprises: a first deformation gauge assembly 12 which is essentially sensitive to the bending of the bar under the effect of the load applied; a second deformation gauge assembly 15 which is essentially sensitive to the torsion of the bar under the effect of the load applied and is situated preferably in the same axial zone of the bar as the first assembly; a third deformation gauge assembly 17 which is essentially sensitive to the torsion of the bar under the effect of the load applied and to its shear due to the transverse force; and a circuit of the bridge type for processing the signals emitted by the three assemblies, comprising means for combining the said signals so as to eliminate from the output signal any component other than that resulting from the shear due to the transverse force.

Description

 The invention relates to weighing devices of the type with strain gauges, and it applies in particular to scales.

 It aims to provide a device of this type which, while being of simple design and structure, therefore at low cost, is nevertheless reliable and precise.

To this end, the invention proposes to provide a weighing device of the bar or single sensitive element type, one end of which is secured to a load receiving plate and the other end of which is secured to a support seat, the bar carrying at least one strain gauge assembly sensitive to the strains of the bar under the effect of the load
These single bar devices have a decisive economic advantage which is linked to the uniqueness of the bar.
But, because the point of application of the load on the plate is variable, the bar is subjected, in a random manner, to deformations in bending, in torsion and in shearing dia with the shearing force
The applicants have proposed, in their French patent application No. 82 20040 of November 30, 1982, a solution consisting of providing several sets of strain gauges arranged geometrically on the bar and electrically mounted in a measuring bridge so as to obtain at output a signal representative of the only bending
This solution gives full satisfaction, both in manufacturing as in sensitivity and fidelity, but it requires the measurement of the bending at two points spaced from the bar.
In some cases, in particular for overall dimensions and / or placement, it is difficult to measure the flexion at two spaced points; moreover, this bending, by its moment, varies along the bar whereas the torsion remains constant whatever the area of the bar considered
The present invention proposes to provide a
apparatus in which it is no longer bending, but the
shear due to shear which is isolated on
the outgoing signal
To this end, the apparatus according to the invention comprising,
in known manner, a single bar or sensitive element
which is secured at its ends respectively with
a load receiving tray and with a seat of
support, and which is equipped with at least three sets to
deformation gauge fixed on said bar, is characterized
laughed at by the fact that it includes: a first set to
strain gauge, sensitive mainly to bending
of the bar under the effect of the applied load; a second
th essentially sensitive strain gauge assembly
when the bar is twisted under the effect of the applied load
and preferably located in the same axial zone of the bar
than the first set; a third gauge set
deformation sensitive essentially to the torsion of the bar under the effect of the applied load and to its shear-
due to the cutting force; and a type circuit
bridge for processing signals from the three
assemblies, comprising means for combining said assemblies
signals so as to eliminate in the outgoing signal any
component other than that resulting from the shearing of the
with sharp effort.

Preferably, the three sets are in the same
axial sone of the bar which can then be short.

The bar can be of variable cross-section and / or composition, in particular at its fixing ends or in
the reception areas of the deformation gauge assemblies
Preferably, however, the bar is of section
constant, for example polygonal (square, rectangular,
...) or curved (round, elliptical, ....) or profiled
(T, U, I, H, C, L, O, -).

The bar can be full or tubular
According to a preferred embodiment each set
ble has a selue gauge, the gauge of all sen
flexural being parallel to the general direction of the bar and the gauges of the other two sets being inclined in this direction, for example 450
In practice, each of the three strain gauge assemblies is in fact sensitive to bending, torsion and shear, but for different parts, the correction being made by eliminating the components, other than that shear due to shearing force, in the outgoing signal.

The invention will be clearly understood on reading the description which follows, with reference to the appended drawings in which:
Fig 1 is a vertical section of an apparatus according to the invention, this section being made by the axis of the bar;
Fig 2 is a plan view of the apparatus of Fig 19
Fig 3 shows, in perspective, an example of arrangement of gauges, according to the basic embodiment of the invention;
Fig 4 and 5 show two strain gauges formed with the gauges of Fig 3,
Fig 6 is a view similar to Fig 3 and relating to a variant; and
Fig 7 shows the extensometric bridge formed with the gauges of fig 5.

The weighing device, in particular a scale, shown in FIGS. 1 and 2, comprises a sensitive element 1 constituted by a single cylindrical bar, that is to say of constant section; preferably, as shown, the bar 1 is of rectangular section, but this section could be of another curved shape, for example elliptical or circular, or of another curved shape, for example square, or even profiled (T, H, I, U, C, L, O
At one end 2, the bar n is secured, for example by clamping using screws 3 and a clamping clamp 4, with a plate 5 of load support constituted by a plate proper 6 and by a structure support 7 in the form of an H, or frame, to which the plate 6 is fixed and which is immobilized directly on the end 2.

At its end 3, the bar n is secured, by
example also by clamping using screws 8 and a flange 9, with a base 10 by which the device rests
on its support, for example the ground. The base can receive a side covering 11 whose upper edge is covered by the side skirt / of the plate 6. The base 10 is
also in H, C or frame shape to provide stable support.

The plate 6 and the covering 11 have been removed at the
fig 2 for clarity of the drawing.

The bar 1 is generally horizontal, as is
structure 7 and base 10.

The bar 1 can extend parallel to one side of
the device 9 for example along a median axis, or, as the case
if necessary, along a diagonal or even a diameter if the device is circular.

When a load to be weighed is placed on the plate 6, it subjects the bar 1 to bending stresses,
torsion and shear due to shearing force, and this, randomly depending on the position of the can of load application on the plate.

To measure these constraints, the bar 1 is fixed,
usually by bonding, at least three gauge assemblies
deformation and, we combine the signals emitted by these gauges
to keep only the component in the outgoing signal
health representative of the shear da at the tran effort
song, the other components, that is to say those of tor
sion and bending, being eliminated.

For this (Fig 3) one of these sets is constituted by a longitudinal strain gauge 12 sensitive es
sentiently to the bending of the bar; this gauge is
preferably located, for the axial zone chosen, in a part with maximum deformation, for example, as shown, along the longitudinal axis 13 of the upper face 14
of the bar which is perpendicular to the direction of the
this F exerted by the load.

The second set consists of a 15 sen gauge
sible mainly to the torsion of the bar due to the for
this F when the latter is not located in the vertical median plane of the bar. This gauge 15, in known manner, has the greatest sensitivity to torsion when it is inclined at 450 on the longitudinal axis 16 of the bar, a position for which it admits the maximum torsional deformation but does not induce signal due to bending The gauge is also bonded to the upper face 14 of the bar, preferably in the same axial area of the bar as the gauge 12, for reasons which will appear later.

 The third set is constituted by a gauge 17 sensitive essentially to the torsion of the bar, but also to the shear due to the shearing force parallel to the direction of the force F. The torsion is constant at all points of the bar: preferably, the gauge 17 is planed in the same axial area as gauges 12 and 15.

 This gauge 17 is placed on a vertical lateral face 18 of the bar, parallel to the directlom. of force F.

For the same reason as above, it is glued to the face 18 to 45 on the longitudinal axis 19 of this face and oriented so as to provide the same torsional measurement as the gauge 15.

Theoretically, the gauge 15 is sensitive only to torsion. Indeed, its inclination at 450 on the axis 13 makes it in principle insensitive to bending and, because it is located on a face perpendicular to the direction of the force F, it is insensitive to shearing due to the ef-
very sharp, parallel to this direction. Theoretically still, the gauge 17 is sensitive to torsion and shear due to shearing force, but it is insensitive to bending. Finally, gauge 12 is theoretically insensitive to torsion and shear due to shearing force.

 In practice, however, one is not afraid to be satisfied with one or two gauges 15, 17, because for construction and / or mounting reasons, they induce parasitic measurements, in particular of bending, which are eliminated thanks to the use of the longitudinal gauge 12. Besides, this can also induce a parasitic measurement, which must be eliminated.

 For this, the gauges 12, 15 and 17 are mounted in a strain gauge bridge arranged as shown in fig 4 or 5.

 In FIG. 4, at the terminals of the power source 8 is mounted a first series branch constituted by the gauge 17 and a balancing resistor 20, a second series branch constituted by two resistors 21 22, a third series branch constituted by the gauge 12 and a balancing resistance 24, and a fourth branch constituted by the gauge 15 and a balancing resistance 23. As can be seen in FIG. 4, owing to the fact that the gauges 15, 17 are sensitive to the torsion in the same direction and that the gauge 12 works in flexion, the gauges 12, 15 17, have a common terminal connected to the same pole of the source S, the other pole of the source being connected to the common terminal of the resistors 20, 22, 23, 24.

 On each of the intermediate points s of the branches containing the gauges 12 and 15 is mounted a terminal of an attenuation or correction resistance 25, 26 of which the other terminal C, D is connected to the intermediate point A, B of the urn OR the other of the branches containing the resistor 21 and the gauge 17. These connections are made, once and for all, when the bridge is assembled and when it is balanced.

 The bridge variant of fig 5 differs from have of fig 4 by the permutation of the series branches 15, 23 -21, 22, the resistor 26 being connected to the common point of the resistors 21 and 22 and the terminal A being taken on the common point of the gauge 15 and of the resistance 23. For the rest, the bridge of fig 5 is @dentic to that of fig 4, the description of which we can refer. As in fig 4, the terminal C, D of each attenuation resistor 25, 26 is connected, once and for all, during mounting lu pon @ and i or balancing, on one or the other of the terminals A , B.

 In both bridges, the measurement of the outgoing signal @@ makes @ntre @ e @ terminals A and B.

l @ if necessary, a correction resistor (not shown) can be mounted in series or in parallel with at least one gauge 12, 15, 17
With such bridge arrangements, the components due to torsion and bending are eliminated from the outgoing signal taken from terminals A, B, this signal comprising only the component corresponding to the shear due to the cutting force measured by the 17 gauge.

 FIG. 6 shows a variant installation of gauges and, in FIG. 7, the corresponding strain gauge bridge.

 In this arrangement, there are the base gauges 12, 15, 17 arranged on the bar in the same manner as above. These gauges are supplemented by gauges which increase the number of measurements carried out and make the whole more precise. A first gauge 27 is placed on the upper face 14, perpendicular to the gauge 15, a second gauge 28 is placed axially on the lower face 29 of the bar; a third gauge 30 is placed on the other vertical lateral face 31 of the bar, parallel to the gauge 17; a fourth gauge 32 is placed on the lateral face 18, perpendicular to the gauge 17, and a fifth gauge 33 is placed on the lateral face 319 parallel to the gauge 32.

These five complementary gauges are preferably located in the same axial zone as the gauges 12, 15, 17. Theoretically, the gauge 27 is only sensitive to torsion, the gauge 28 is only sensitive to bending and the gauges 30, 32 and 33 are only sensitive to torsion and to shear due to sharp effort; but in practice for the reasons indicated above, they induce spurious signals which must be eliminated
The bridge circuit comprising the gauges of fig 5 is shown in fig 7. It is deduced from that of fig 4 by replacing the balancing resistors 20, 21, 22, 23 and 24 respectively by the gauges 32, 33, 30, 27 and 28.

For the rest, the two bridges are identical; the description will therefore not be repeated.

One could also, with the geOmetric arrangement of the gauges of fig 6, establish a bridge obtained from that of fig 5 by replacing in it the balancing resistors 20, 21, 22, 23, 24 by the corresponding gauges
The decculating advantage of the placement of the flexion gauge (s) 12, 28 in the same axial zone as the torsion and shear gauges due to the tran singing force resides in that, the flexion being variable along the bar, we do not have to compensate for the axial offset, and in that we can have a short bar, or even very short.

 Of course, the invention is not limited to the mode of application, nor to the embodiments which have been described. One could, on the contrary, conceive other applications in the weighing field, give the bar another form, for example of circular section, and conceive other arrangements of gauges on the bar and / or other bridge circuits. .

Claims (7)

 1. Measuring device with strain gauges, in particular bathroom scales, comprising a single bar or sensitive element (l) which is secured at its ends respectively with a load receiving plate (59 6, 7) and with a seat of support (10), and which is equipped with at least three sets with strain gauge fixed to said bar, characterized in that it comprises o a first set (12, 28) with strain gauge, essentially sensitive to the bending of the bar under the effect of the applied load; a second assembly (159 27) with a strain gauge sensitive essentially to the torsion of the bar under the effect of the applied load and preferably situated in the same axial zone of the bar as the first assembly 9 a third assembly (17, 30, 32, 33) with a strain gauge sensitive essentially to the torsion of the bar under the effect of the applied load and to its shear due to the shearing force 9 and a bridge type circuit for processing the signals emitted by the three assemblies, comprising means for combining said signals so as to eliminate in the outgoing signal any component other than that resulting from the shear due to the shear force  2. Apparatus according to claim 1, characterized in that the three assemblies are located in the same axial zone  3. Apparatus according to one of claims 1 and 2, characterized in that the second assembly is placed in an area (14) perpendicular to the direction of the force (F).  4. Apparatus according to one of claims 1a 3, characterized in that the third assembly is placed in an area (18) parallel to the direction of the force (F).  5. Apparatus according to one of claims 1 to 4, characterized in that the bar (l) is of constant section, for example polygonal (square, rectangular, ...) or curved (circular, elliptical ...) or profiled (T, H, I, U, C, L, O ....), the bar being full or hollow.  6. Apparatus according to one of claims 1 to 5, characterized in that each assembly has a Single gauge, the gauge (12) of the first set being parallel to the general direction of the bar and the gauges (159 17) of the second and third sets being inclined at 450 on this direction.  7. Apparatus according to claim 6, characterized in that the circuit for processing the signals emitted by the gauges (12, 15, 17) comprises, mounted in parallel at the terminals of a source (S) 9 a first series branch comprising the third Gauge (17) and a balancing resistance (20), a second series branch comprising two balancing resistors (21, 22), a third branch comprising the first gauge (12) and a balancing resistance ( 24), and a fourth series branch comprising the second gauge (15) and a balance resistance @ braking (23), the measurement being made between the intermediate points (A, B) These first and second branches series, and the intermediate points of the third and fourth series branches both connected, by respective attenuation resistors (25, 26) to one and / or the other of the measurement terminals (A, B).  E. Apparatus according to claim 6, characterized in that the circuit for processing the signals emitted by the gauges (12, 15, 17) comprises, mounted in parallel across the terminals of a source (S), a first series branch comprising the third gauge (17) and a balancing resistance (20), a second series branch comprising the second gauge (15) and a balancing resistance (23), a third series branch comprising the first gauge (12) and a balancing resistor (24), and a fourth sari branch comprising two balancing resistors (21,  2), the measurement being made between the intermediate points (A, B) of @ first and second series branches, and the intermediate points of the third and fourth series branches being connected, by respective attenuation resistors (25, 26) to one and / or the other of the measurement terminals (A, B).  9. Apparatus according to one of claims 1 to 5, characterized in that the first set comprises two gauges (12, 28) sensitive to bending and placed in the same axial area, that the second set comprises two gauges (159 27) inclined at 450 on the general direction (16) of the bar and perpendicular to each other, and that the third set comprises four gauges (17-9 32, 30 33) distributed in pairs of crossed gauges perpendicular and inclined each at 450 on the general direction (16) of the bar.  10. Apparatus according to claim 9, characterized in that the circuit for processing the signals emitted by the gauges comprises, mounted in parallel at the terminals of a source (S), a first series branch comprising the two crossed gauges (17, 32) of one of the pairs of the third set, a second series branch comprising the two crossed gauges (30, 33) of the other pair of the third assembly, a third series branch comprising the two gauges of the first set, and a fourth series branch comprising the two gauges (15, 27) of the second set, the measurement being made between the intermediate points (A, B) of the first and second series branches, the intermediate points of the third and fourth series branches being connected, by respective attenuation resistors (25 26), at one and / or the other of the measurement terminals (A, B).