BE406624A - - Google Patents

Description

       

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  '. Weighing and weighing process for mixtures of materials.



   The invention relates to a weighing process and a b cule particularly suitable for this use, for effecting mixtures as they have been practiced hitherto, by e ple in the metallurgical industry and in mills, in the past. complicated mixing scales. The invention makes it possible to erase mixtures of a given ratio on the basis of a variety of freely chosen particular quantity of the desired mixture, for example starting from a given final weight of the mixture to be rered, without having to determine the other particular absolute values, for example the individual weights of elements of the mixture.



   This result is obtained, according to the invention, owing to the fact that the dosing graduation lines of a scale provided with a dosing scale are, before the weighings relating to the mixture of materials, set vis-à-vis the absolute value chosen as the starting value in each particular case, in the comparison corresponding to the desired mix. For example, in the case of

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 scale provided with a scale of ratios, such as a scale of percentages, it is possible to start from the final weight of the mixture in such a way that the scale is loaded with the final weight and then brought, for example, to the graduation line for the value ratio 1, therefore 100%. All other special absolute values are then set automatically and can be measured on a special scale as required.



   A scale particularly capable of being adapted to the most diverse mixing purposes is obtained when, in addition to a device indicating the ratios, there is also a device indicating the absolute values of the mixture, such as the weights, and this device is coupled to the gear indicator device by an adjustable transmission, in a manner analogous to what takes place in price calculating scales.

   Besides the weights, other values such as the albumin or starch content or the amount of calories can still be recorded on scales and put in an adjustable ratio with the indications of a scale of ratios, so that the dosage of the mixing can also be based on values of this nature or that these can be observed at the same time as the weighing takes place for the whole mixture or for elements of this mixture in the same operation.



     The various indicating devices may be coupled in such a way that the load first directly influences a indicating needle on a circular scale and the transmission to each additional indicating device is derived from the shaft of that needle. Transmission is simplified by the use of adjustable optical projections. Instead of a second needle, according to the invention, there may be arranged a common needle for various scales and the various readings combined with each other can be made because the additional scales are, of their own accord. side, also movable under the needle moved by the load or with respect to an index finger.

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  The movable scale can then move in its entirety, so that the reading under the needle refers to the immobile scale; but it is also possible to may the entire movable scale and over its entire length in conjunction with the fixed scale, for a focus which shell, when according to the invention, the scale is movable in it- even while the zero point remains stationary, so that, for example in mixing scales with a weight scale and a ratio scale, the value ratio line J (100%) always indicates, on the fixed weight scale , the total weight of a mixture whose weight on the ba cule forms the ratio found under the needle.

   can also provide various hands moving on a cadi provided with various circular scales and coupled together like the large and small hand of the clock. Such a well-adjustable arrangement is obtained when a friction plate is placed on the needle shaft and, along a spiral guide extending from the needle shaft to approximately the periphery of the plate, a frict wheel in engagement with the plate slides on its shaft arranged so as to be able to move around the needle shaft and pendularly to it, The needle shaft and the shaft of the friction wheel can then be coupled together by a fixed gear, so that the friction plate 1 itself rotates at the same time as the needle shaft and can be a movable scale,

   or else the friction plate is on the needle shaft an additional needle is called from the friction plate. The movable scales wind, in each case, be covered and be visible t towards a reading window provided in the cover, or e be provided with several reading windows which can be covered as desired and thus contribute to the elimination of these of errors.

   The preparation of any quantities of e-mail

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 Frequent repre- sentation can be facilitated by prescription cards serving as a scale for the mixture in question; on these cards are only inscribed, according to the invention, the ratios unrelated to determined weights Conversely, in the case of proven mixtures, the mixing ratio can be seen in a simple manner by means of the rocker when, in flip-flops optically focusing the transmission, the optics are at the same time used for the indication on the scale; the readings can then be photo-graphed, in scale form, on a light-sensitive prescription card.



     Mixture weighings according to the invention can also be carried out without the materials being mixed directly. For example, a forage for a day, for which specific ingredients are prescribed in a determined ratio of the total quantity, can be dosed according to the prescribed composition, while the elements are left separate and are consumed, in the current of the day, in particular quantities and mixtures of any kind; naturally, there can be no leftovers at the end of the day.



   The accompanying drawings show various exemplary embodiments of the invention, which are for the most part designed as a mixing scale with kilogram scale and ratio scale and generally have circular scales.



   Fig. 1 shows a load cell type scale with moving weight on a weight lever and decimal scale aprons to receive the load.



   Figs. 2, 3 and 4 show details of fig.l.



   Figs. 5 and 6 show an anal ogue scale-scale with divided scale weight and a special focusing device, in which, alongside complete scales, prescription scales can be used.



   Fig. 7 shows a reading device with a scale

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 the mobile whose zero points do not change position
Fig. 8 shows the arrangement of the references corresponds) to fig. 7.



   Figs.9 and 10 show, in rear view and in vt side, an arrangement with adjustable friction coupling be the two indicating devices.



   Figs. 11 and 12 show various examples of an optical adjustment of the transmission ratio and the possibility of photographic recording of the values of the ratios.



   Fig. 13 shows a particular reading device suitable for prescription cards.



   Figs.14 and 15 show a wheel arrangement with three hidden scales on the front face of the friction and, accordingly; three reading windows in the cover.



   Figs. 16 and 17 show a drum scale ma @ comprising three different scales and, in number corresponding to the number of scales, reading windows that can be specially developed.



   Fig.18 and 19 show, according to different views, a spring balance corresponding to the invention.



     Fig. 20 is a section on a larger scale, in detail: Figs. 18 and 20.



     Figs. 21 and 22 represent realizations of changeable quantifiable scales.



   Fig. 23 represents a scale of the type of that of fié and 12, with variable graduation figures, and special realization card.



   Fig. 24 finally represents a prescription card with variable rates,
The embodiment according to fig.l comprises two tables with charges 1 and he and a fixed circular scale 12 marked in percentages, on which the needle 13 moves. The aprons are connected upwards, by 3 'tie rods, at 1

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 intermediate 2 and from this leaves a traction tape 3 which goes upwards to the part with guide curve 4 (fig. 2) which attacks the shaft 5.

   To the shaft 5 is rigidly connected a pair of guide rods 6 in which is guided a weight 7 carried by a threaded rod 6 '. The weight 7 can, from a crank 14 (fig.l on the right) and via a shaft 15 and a pair of bevel wheels 16-17, be raised and lowered by means of the rod threaded 6 '. To compensate for the self-weight of parts 6 and 6 ', a weight 8 is placed. Opposite the curved guide part 4, the frame 6 carries a toothed wheel 9 with which a rack 10 engages.

   This rack 10 has another toothing 11 at its upper end to mesh with the toothed wheel 18 of the other 19 which thus rotates under the influence of the load on the apron 1 and moves on it. the scale needle 13 mounted rigidly on said shaft.



  When the weight 7 is adjusted by means of the crank 14, an index 20 moves on the shaft 15. This index indicates, on a scale 21 located under a transparent window 24 of the hermetic envelope 25, for which load of the rocker the needle 13 is, for the position given to the weight 7, on 100%. Internally on the scale of the percentages is placed a circular scale of the prescriptions, which indicates the composition of the mixture to be prepared in such a way that it is indicated at the periphery of the card, in arcs which are linked to each other, what percentage of each element or raw material must contain the mixture, the total of the percentages of raw materials being 100.

   The apron 1 can now be successively loaded with the various raw materials, which are designated by 1, II, III and VI on the prescription card shown by way of example, and this each time until the needle 13 has reached the end of the arc corresponding to the raw material in question. The actual mixing of materials can be done on the bottom apron -

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 cule itself, so that the needle 13 is 100 at the end of the weighing and the prescription card oc goes to its position; but it is also possible to remove from the rocker c the raw material which has been weighed and to carry out the mixing the gap of the scale.

   The prescription card must then, after each weighing, be moved angularly along a raw material arc and be set to 0% by the end of the new arc. To facilitate exact focusing, the b of the card is, in the example shown, provided at the end of each arc with a notch forming a stopper and, correspondingly, there is arranged a pawl of stop 22 at the end of the 0% line. In order to avoid, even in the case of separate weighing of raw materials, any manual adjustment of the scale and the sources of error that it involves, the arcs of raw materials can be worn;

   on the map in reverse succession, therefore in an arrangement symmetrical to the example repeated, while the direction of the stop teeth remains the same if it is then made so that the needle shaft enters the As the tipping load increases, but can reverse empty, the amount of each new raw material is, when it comes to weighing it, automatically ready to go.



   In the example shown, a second ta 1 'is arranged. This is used to note after the fact, for the angel weighings carried out, the mixture contribution, for this, it is necessary to weigh exactly the quantity prepared for each first mother and to take only from this quantity the partial quantities used to prepare. mixing, in order to observe the mixing ratio afterwards, it is then necessary to weigh the entire quantity of the mixture carried out, then, on the scale 21, put the index 20 for this total weight observed, by means of a crank14.

   The apron 1 is then loaded with the weight of the div quantities of raw materials which have been prepared and 1 '

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 place each time on the apron the unused remainder of the raw material in question, on the needle 13 then acts the weight of the quantity used, and the corresponding percentage can be read. The various positions of the needle can be recorded successively on a blank circular prescription card, for example by hand or photographically, and thus be retained for subsequent weighings of the mixture to be carried out as described above. In all cases, the apron 1 'is found as a compensation weight vis-à-vis the apron 1.

   If mixing controls do not come into play in the manner described, it suffices, in order to compensate for the weight of the apron 1, to place a mobile weight 23 on the intermediate lever as indicated in dotted lines in fig.l .



  The weight of containers that may be used can also be compensated by a corresponding load placed on the apron 1 'or, instead, by a movable taring weight.



   Indirect weighings of the kind described can be carried out without an additional apron, when the elements can be separated from the mixture, at least in part. To this end, in all the embodiments of the invention, a coupling acting unilaterally can be arranged, for example a coupling which engages immediately or any coupling which can be engaged and disengaged. The arrangement of the coupling can be such that, when weighing the total weight, the ratio indicator is set to 100%, after which, during particular weighing of raw materials, a corresponding reading of the ratios is obtained. , while the concordance between the 100% ratio line and the total weight remains maintained.



   In the example according to figs.5 and 6, the weight is distributed between two load cell levers 6 'and 6 "moved in opposite directions, which are influenced by a common tie rod 3" by means of traction bands. 3a and 3b and jointly determine the

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 position of a needle 13 'according to their inclination and thus ind, on the scale 12', the ratio in the mixture.

   The scale of the weights for setting the desired total weight is here placed externally around the gear scale, and a tune-up guide 20 moves on this last scale. The tune-up takes place again by means of crank, but the focusing shaft 15 'is controlled by the intermediary of a transmission by straight toothed wheels, and it acts the threaded rods 6' of the weights 7 'and 7 "by the intermediary of two pairs of bevel gears K and K 'acting in opposite directions. The bevel gears K' are mounted idle on the shaft 15 "controlling the threaded rods 6 'through the bevel gears 16', 17 '(fig.6) and are coupled to this bre by drive discs M wedged on it. The dragging is operated by drive slats Mn are hole on the discs and the drive pins Ks are tro on the bevel wheels K '.

   If the drive discs and drive jaws occupy the position shown in the figure, the threaded rods 6 'with the weights 7 "can oscillate to an extent corresponding to the load from the bottom. Next to the crank 14', it is for example, there is an indicator device which allows this driving position to be recognized and corrected externally at all times.

   The indicating device consists of a star disc st fixed on 1 ber of the crank and of a casing drum G which can be driven freely and is braked externally to the shaft: the casing drum is provided with stops z directed in inside the stops z and the star-shaped protrusions v of the star disc, so arranged in equal number and distributed uniformly over the perry, and this in number such that the intermediate arc corresponds each time to the spacing of the drive pins on wheels conical K '.

   In the example shown, each wheel c @ that K 'has two drive pins, and the ratio

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 transmission between bevel gears and crank 14 'is 1: 4; consequently, the indicating device has eight star protrusions and eight z-stops. When the crank 14 'is turned for the adjustment of the total weight, there will soon be, at the same time, drive of the envelope G and, inside the scale, M.

   If we then turn the crank in the opposite direction at any time, the discs M remain stationary, and at the same time the casing G because it is braked, and, subsequently, the parts of the indicating device and the drive coupling K'-M, in both directions, will re-engage at the same time. Thus, the position of the star projections relative to the stops!, Always corresponds reliably to that of the drive pins Ks relative to the drive jaws Mn. The most favorable position for carrying out the weighings can therefore be noted on the indicating device, as is done, in the example shown, by recesses W of the envelope G.

   If, after setting the total weight, the star protrusions v are located under the recesses w, so that they are visible through the said recesses as shown in fig. 5, the load cell levers with the weight can move freely. In addition to the known independence of the scale vis-à-vis an exactly horizontal position, the arrangement of two weighing levers here has this particular advantage that the total weight of the mixture can be brought into focus during the weighing operation. without disturbing the weighing, because all the forces deriving from the focus are balanced in the mechanism of the seesaw, for small additions to the mixture whose order of magnitude differs considerably from that of the other elements,

   a special latch more sensitive accordingly can be provided so that the two latch are coupled to a common focusing device.



   In fig. 5, on the left, a prescription card is shown.

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 tion of format smaller than the scales of the seesaw. P @ reduction of the format, on the one hand, a prescriptic needle is connected to the needle shaft of the scale with the mc of a reduction transmission, the centers of rotatic needles being able, because of the smaller deviation , is eccentrically, and, on the other hand, the arcs of matter take only, on the map, an arc corresponding to 100 divided into partial arcs s, and there is arranged a star of several prescription needles, one of which is always finds the beginning of the partial arc when the previous one leaves the arc. In the example drawn, two prescription needles Rz are provided.



   In the example according to Figs. 7-10 and others, the scales which can be adjusted in relation to each other for the various kinds of readings are brought together on a dial. According to fies. 7 and 8, there is also a common guill e for the various readings, and the transmission ratio can be adjusted by changing at least one of the scales. In the example shown, the percenta scale is movable and variable in itself. To each graduating line of the percentage scale belongs a special sector 26, and each sector is mounted idle on the needle shaft and is coupled, via the countershaft co.



  27 and a proper transmission referral 28-29, to the other s teurs. The sectors 26 are, in the zero position, exactly superimposed and open in a fan during the mid-point until, in the terminal position, the line 100% corresponds to the last graduation line of the ltechell of kilograms.

   In this way, during all the time of the age, each line of graduation of the percentages always indicates what ratio in percent there is between the weights being given precisely opposite him and the weight being: indicated opposite line 1 00%. Focusing takes place from a

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 case to another by hand, a certain automaticity of the focusing can be obtained by the arrangement of a transmission, not shown here, between the needle shaft and the idler shaft.



   The example according to Figures 7 and 8 is also suitable for using, for small percentages, the entire weighing capacity of the scale. If, for example, we bring the 100% graduation line, from the zero position, beyond the end of the scale of the weights and we make it do, for the second time, the full turn of the dial, it happens to coincide with the 50% line. The weight graduation line, next to which both 5Q% and 100% lines are now located, indicates 50% of a total weight which no longer belongs to the scope of the scale, but is purely fictitious , for this position of the scales, any mixture weighing can be carried out in which no element is greater than 50% of the total weight.

   The individual weighings then extend over a weighing range twice as large as if the end of the percentage scale had not been brought beyond the end of the scale of weights. . As a result, the precision of the weighings for the mixture in question is doubled, if a mixture does not contain any 33% element, the 100% line can, from zero, be conducted three times around the dial. , and the precision of the weighing is then tripled, while, on the other hand, the weighing capacity of the scale is 66 2/3% of a fictitious total weight lying outside it when the 100% mark was only brought one-half turn of the dial past the end of the weight scale.



  In figures 21-24 are shown other forms of execution of scales which also allow to combine the dosage line for the element having the highest relation with the end of the graduation of the weights. at least approximately, so that the weight which would correspond to the terminal line of the weight scale is then outside the range of

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 wise of the seesaw.

   The change in the scale ratio is equal to the ratio between the element most strongly represented 1 at the weighing range of the rocker can, for example, in the case of a rocker according to fig. 5, take place due to the fact that to the graduation lines, instead of numbers, of the reading tres 130 and that it is disposed behind them, movable discs 131 with various series of c corresponding to each other, as shown in figs. 21, 22 and 23 In the example according to fig.21, c laying in fig.5, the disc is rotated by the handle
The example according to figs. 90 and 10 are intended exclusively for pre-setting, for example, a desired weight of the mixture.

   Focusing is done by means of a movable i 31 on the outer edge of the kilog scale 30. The index 31 is connected to a friction wheel shaft 32 their a friction wheel 33, and the shaft of the wheel of f: is coupled by means of a pair of tooth wheels @ 34, with an invariable transmission ratio, to the guillotine shaft 19. The friction wheel is engaged with a friction plate 35 mounted mad on the needle shaft, and this friction plate is rigidly connected to a special 36 sE needle moving on a fixed scale of percentages. The percentage scale is found here internally on the 1 gram scale. The friction wheel 33 can move axially its shaft 52, and its position is determined by a guide sp 37.

   The guide starts at the needle shaft 19 and extends to the outer edge of the kilogram scale. In the ple represented, it embraces an arc of 360. The position of the friction wheel on its shaft 32, determined by the guide together with the angular position of the friction wheel shaft, in turn determines the transmission ratio between the kilogram needle 21 and the needle. of percentages 36 and causes the percent digits to mount.

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 by this last hand refer to the kilogram figures shown by the focus index 31.

   In the example according to Figures 14 and 15, scales are arranged on the friction plate and reading windows are provided in the cover disc placed in front of the friction plate.



  These scales do not contain figures of percentages, but for example values relating to the absolute content of the quantity of material on the scale in albumin, starch and nutritional value expressed in calories, by index 31, we regulate now, not a desired weight, but the ratios relative to the material to be weighed: content in percent albumin or starch, or nutritional value in calories per kilogram. For values of the same denomination, for example percent contents, a common scale can also be arranged which, averaging different corresponding settings of the index 31, is read for the various percentages sought. Figs, 16 and 17 show a drum ladder 40 serving the same purpose and can be used anywhere.

   Instead of the continuous focusing by the needle 13, it has been chosen here an adjustment by degrees for the various contents or the values in calories per kilogram, which takes place by means of rings 41 of which each has three reading windows. Above the set of rings, there is a sleeve 42 having a single reading slot which extends over all of the rings; for illustration, in fig. 16, the sleeve covers only part of the rings and, on the left, the last rings have been omitted to show the scale of the drum. The drum is rotated by the rocker under the influence of the load, and after the ring has been tuned for the ratio in question, the reading slot of the drum can be seen in the window of the ring under which the sought absolute value appears.



   On fige.la, 19 and 20 is shown an example of a spring lever in which the transmission ratio between

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 the indicating device of the weights and the indicating device of the reports is modified by the connection of the latter, will, at various places of the spring.



   In order to be able to "cue ill ir" easily the movement of the spell, it is not suspended from a ring, as has been done so far, but is screwed into a corresponding thread of 135. (fig. 20). At the lower end, the spring is the same way, screwed into a sleeve 136. This also gives this advantage that the length of the spring coils can be adjusted and rectified. Thanks to the spring connection 138 with the point of attack of the load and by con quent with the indicator device from the weight, the latter can also be brought into focus.



   Into the spring or each of the springs 138 penetrates a sheet metal liner 139 serving to guide the picking device. This guide cylinder has, for guiding the picking, two long slots, opposite in axial direction 140. One of these slots is crossed by the picker. 137 which engages the coil of the spring. At the upper end, the guide cylinder 139 carries a toothed wheel 141 by means of which the header can, by rotation of the cylinder 139, be screwed one along the coils of the spring .

   So that the indicating device of the reports 12 remains at rest during the displacement of the cue their 137, this one can also be raised and lowered on the chain 10 which controls the indicating device, and this by @ of a spring serving only of screw 142, whose pitch conco: with that of the spring 138. To obtain an exact match between the two screw pitches, also taking into account the initial exten to which the spring 138 undergoes under the action of the weight of the rocker parts which are suspended there, the spring serving threaded rod 142 can be focused exactly on the rack ti 10 'by means of a screw 143. Likewise, the spring coil 144 connected to the spring and serving as a nut can be re

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 glued by a small threaded screw on the left and right.

   The spring 142 located on the rack rod 10 'is protected against rotation relative to the rod, and the rod is, for its part, protected against rotation by a cross member 146 guided by two pins 147. Likewise , the weighing springs are protected against rotation, as a pair of weighing springs 138 are generally employed, the drive wheels 148 which rotate the guide cylinder 139 through the gear wheels 141 are placed on a common shaft 149 which at the same time controls a special needle 150 indicating for which final weight there is agreement between the indicating devices. The indicator device for the ratios can also be constituted by the indicator device shown in FIG. 13.

   Focusing can be done using the crank 151.



   Figs. 11 and 12 show examples of the optical transmission between the two indicating devices; in both examples, the optic is at the same time a means of indication. In both cases, a circular kilogram scale with needle 52 is provided for the momentary load, and a focus index 51 for the desired total weight is provided at the outer edge. The scales of the ratios are, in both cases, prescription cards R which are movable under a reading ruler 53. The indication serves an index 54 with rectilinear movement and a light source 55 which projects along the reading ruler, on the prescription card, the shadow of the movements of the index finger.

   The prescription card shows the various lengths corresponding to the various quantities of raw materials, in a rectilinear direction, in accordance with the rectilinear movement of the index 54, and, in the example shown, they are are parallel below each other with zero points in a straight line below each other, in order to obtain a favorable map format. As on the circular prescription card, the various

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 light source, 1st ray passing through the tip of the index 54 as reflected by the reflective screen drawn in solid lines and falls on the map at the 32.5% graduation line, and also the ray which , by the same reflection path, reaches the end of the map at the 50% line.

   The diaphragm 57 covers the window 58 to such an extent that there is shadow to the right of the line 50 Ie. The same illumination range is obtained when the light source occupies the upper position indicated and the reflector also the upper position drawn in straight dotted lines. But the indicated marginal radius reaching the 50% line is much closer to the left end of the window than in the lower position of the reflector and light source.

   The index 54 would therefore have, for its displacement, only a much shorter path, and the readings would consequently lose their precision. The purpose of the diaphragm 57 is to indicate which is the most favorable displacement path that can be obtained for the various total weights and, for this, the diaphragm is connected in conjugal movements, by the toothed wheel 60, to the focusing index 51 for the total weight of the mixture to be prepared.



   In fig. 12, an example is illustrated in which the light source and the diaphragm 57 are automatically tuned together with the adjustment of the total weight by the index 51. The left side of the circular kilogram scale has been omitted for clarity, and only its dotted outlines are shown. The focusing index 51 is connected to a toothed ring 60, and the rotation of this toothed ring causes a, b, c and 62a and b to move, by means of a transmission gear 61 66, the rack 63 upwards and downwards, which rack carries the light source 55. The light source is placed on a screen 65a provided with a foot 65 and resting freely by its foot on a foot 64 of the rack 63.

   When the index 51 rotates, the foot

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 64 forming a platform necessarily moves up and down, driving the screen 65a. The transmission shaft 66 is extended beyond the transmission wheels 61 as a threaded rod and causes, in its rotation, conductive blocks 67 for the diaphragms 57, which are each connected by bars 68 to a particular conductive block, taking first as an example the diaphragm 57a with the block 67a and the bar 68a. The diaphragm moves at the same time as the focusing of the index 51 and the light source 55 takes place, under the influence of the threaded rod and the conductor block.

   It is thus obtained that, during the focusing of the index 51, the light source and the diaphragm are at the same time in focus automatically so that the correct length of the scale is illuminated at a favorable angle of reflection on the scale. reflective screen 59; if necessary, one pet using the crank 69, operate a fine focus by raising or lowering 1 reflector screen.



   The various diaphragms 57a, b and c with complete conduction device are assigned to the most diverse graduation ratios of the scale found on the reading ruler, namely: the diaphragm 57a belongs to the largest graduation ratio, and the diaphragm 57c to the smallest. for the passage another scale ratio, there is also arranged a focusing device which, in reciprocal dependence, puts at the same time the reading rule under the screen 53 ', the light source and the corresponding diaphragm 57a, b or c, after which one can again, by raising or lowering the reflector 59, make a fine adjustment.

   The adjustment of the scale graduation ratio with coarse focusing of the optic is done using a crank located on a shaft 71.



  The shaft has a worm 72 which engages with a toothed SI tor 73. This forms one arm of a two-armed lever having its center of rotation at 75, and the other arm of this lever is connected to the reading rule 53 with longitudinal movement

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 Dosage lengths of raw materials are designated p I, II, III etc. and give, in total, 100%, as indicated at the right edge of each card. The index of the reports is coupled to the shaft of the needle 52 by means of toothed wheel 56, and the reading range is limited by phragn, es 57 which more or less cover a window 58.

   Above the window is a reflective screen 59 which reflects the rays of the light source 55 onto the description card and the reading ruler 53. As the index 54 moves over the window 58, its shadow falls. moves along the reading ruler 53, so that its position on the prescription card placed below or also, as shown in fig. 12, on a scale placed on the reading ruler, can be read at the place of that shadow.

     The light source and the projector screen 59 are movable *, * the closer they are to the window 58, the wider the angle of reflection, the smaller the measurement range for a given length of the reading range, therefore for example with respect to the 1 on of the reading rule, to obtain a reading as early as possible, the proportion of the raw material most frequently represented in the mixture is brought approximately to the entire width of the card. prescription;

   in the exe according to fig. 11, 42% is foreseen for the raw material and, consequently, we have chosen as the scale for the entire width of the map 50%. one obtains a precision two times greater with a double scale by first carrying 25% all the width of the card and the remainder, that is to say 17%, in then we weigh the same material according to the two indications. instead, one can also only graphically represent the remaining quantity and indicate that it is necessary, moreover, to weigh or several times over the entire width of the map. For scales in which prescript cards with different graduation ratios are used, it is shown, on

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 fig. 12, a variable-scale reading ruler.

   There is indicated here, next to each graduation line, four values which, for the penultimate line on the right, are for example the numbers juxtaposed 10, 25.50 and 100; in front of the ruler, there is a reading diaphragm 53 'which bears the grading lines and under the reading windows of which one can, depending on the position of the movable ruler 53, simultaneously see the numbers corresponding to the ratio of graduation employee.

   A color is usefully provided for each graduation ratio which is used both for the digits of the scale corresponding to this graduation ratio and for the inscriptions on the prescription cards, n can also be used various ratios of. graduation on the same prescription card, for example a larger scale for small additions, particularly when these are particularly valuable or need to be measured with caution, such as drugs.



  There is then no need for a special scale for these additions as indicated in the example shown in fig. 5.



   The mode of action of this embodiment is, according to the example of fig.ll, the following: When the latch is loaded, the needle 52 moves on the circular scale while driving, at the means of the toothed wheel 56, the index 54 in a horizontal movement, and this all the more far as the rocker is more loaded. The reflection lamb on the reflective screen 59 should be smaller the larger the greater deviation of the index finger, so that, for using the entire width of the map, the shadow of the index 54 reaches almost to the right edge of this map, and this is achieved by increasing the distance between the light source and the reflecting screen 59.

   In fig. 11, two different positions of the light source and of the reflective screen have been indicated and the course of three light rays is represented. We have shown in interrupted lines, starting from the lower position of the

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 At the other end, the shaft 71 carries a toothed wheel 76, the latter meshes with the small internal toothed arc 77 from one to one arm 78 which, for its part, acts by a large toothed arc on a rod 80 can be raised and lowered.

   Sorting: 80 engages, by a foot 81 forming a platform, under the pie which determines the height position of the light source <On the middle part of the shaft 71 are wedged three exceni cs 82a ,, b and c , which influence separately, through levers 83a, b and c and connecting rods 84a, b and c, dial mes 57a, b and c. The connecting rods undergo the spring action; pushing them upwards and are each coupled to a right-angled link 58 'of a conducting bar 68. Above, 1 connecting rods have heads 85' which, in the example, forms the shape of a square branch , and to these heads face, a shaft 87, eccentrics 86a, b and c which, in the event of reaction of the shaft 87 operated by means of an operating button, push all the connecting rods 84 simultaneously downwards cc the spring action 85.

   Moreover, the height position of the connecting rods is determined in a forced manner by the levers 83 the springs 85. During the raising and lowering of the islands, the conductive bars 68 of the diaphragms rotate as a result of the upward oscillation and down the angled beams 58 'and the diaphragms 57a, b and c connected to c bars are lifted separately, so that they lie parallel between the light rays or are bent towards light rays, and their shadow limits thus the modification of the reading rule. The diaphragms can (the phrase 57a below) be folded over the tiles of a roof. In the drawing, only the lower diaphragm is folded back, and the diaphragms 57b and c are found d as it is drawn in dotted lines.

   The threaded rod is 66 in. Of a particular thread pitch for each of the blocks con their 67a, b and c, and all the diaphragms receive accordingly.

 <Desc / Clms Page number 22>

 from the focus of the index 51, next to the window 58, the position in which they give, in the folded state, the darkening, with respect to the scale which is appropriate for the total weight for which the latch is in focus.

   If, with the aid of the crank 70, a new scale graduation ratio is developed, there will then be, when changing to a higher scale ratio, at least that of the connecting rods rise. 84 lowered which is the furthest to the right, in the example shown the connecting rod 84b; the upward movement takes place, under the pressure of the corresponding spring 85 when the geometric center of the eccentric 82b descends during the rotation of the shaft 71. If these are larger scale ratio changes, several connecting rods will be raised successively due to the fact that the shaft 71 receives an all the greater rotation.



  During the elevation of each connecting rod 84, there is then obscured sown from a new part of the window 58, because the corresponding diaphragm 57 sits like a roof tile on the diaphragms already folded down, If, conversely, it is necessary to switch to a smaller scale ratio, the connecting rods in the upper position are lowered by a reverse rotation of the shaft 71, starting from the left, so that the The corresponding eccentrics 82 draw in turn downwards, by means of the corresponding lever 83 and against the action of the spring 85, the lower end of the connecting rods. When lowering each connecting rod,

   the corresponding diaphragm straightens up and releases part of the window 58 to let the light pass from the light source 55 to the reflector 59.



     Vis-à-vis the focusing index bl, there is disposed, on the toothed ring 60, a crank 51a. When you want to use the tilt, it is therefore necessary, using this crank, to set the desired total weight of the mixture, then to check whether the scale is illuminated to the correct width and, at need,

 <Desc / Clms Page number 23>

 perform a fine adjustment using the crank 69. The b cule is then ready for use, if it is necessary to change the graduation ratio of the scale, the crank 70 is rotated by a suitable small angle and, if necessary, correct the scale illumination control by means of the crank 69. all the diaphragms must be put out of action, on to the maneuver button 88.

   If the entire length of the gearbox is 100%, the mixing of the weighed quantities of mast can also be done on the scale as desired. In the case of a partial scale as shown, the o of index 54 must, at each passage to a new first material, be set to zero; this is done automatically: that each weighed quantity is removed from the scale and that the change takes place outside the scale; but the index may have for this purpose, be capable of focusing independently of the mechanism of the rocker.



   Fig. 13 shows an indicating device for prescription cards, which is suitable for all forms of operation of the scale, on a closed tape 90, placed on two pulleys: and 91 ', are arranged at regular intervals, inc The threaded pulleys are screwed onto threaded rods 9 92 ', and one of them is controlled in such a way as to weigh, usefully from the shaft of a needle or pulling from a rocker of the type load cell. The prescription card is, at the start of the weighing, slipped under the tape 90, so that the indexes 90 'are led by the tape above the card.

   The scales of the card are of equal length to the spacing of the indexes 90 'and, as far as they are related to the same raw material, arranged one above the other at a distance equal to the path of movement of the po 91 on the threaded rods in the time during which an i 90 'travels once the entire width of the scale is on the board.

   In this way, each index moves diagonally

 <Desc / Clms Page number 24>

 a low rectangle of the scale and, when an index finger leaves the scale at one end, the next index begins in the same way, opposite it and at the same height on the other edge of the scale, its course along the ladder. In the example shown, the reading is made particularly simple owing to the fact that it is chosen, as the scale graduation ratio, 10% for the width of said scale.

   To advance the prescription card under the indicating device, when switching to a new raw material, by a quantity equal to the distance of the corresponding scales, an advancement device can be provided in a manner analogous to the arrangements used in similar purposes in typewriters.



   The wire, - ,. 23 shows a rocker according to figs, ll and 12 with variable scale figures. In this example, the edge of the dial 131 is toothed on a part (above in the drawing) and in the toothed sector a small toothed wheel 101 engages. This toothed wheel and therefore also the dial are controlled by a small shaft 103 which carries at its anterior end a rotation button 102 and, at the other end, another small toothed wheel 104. The small posterior toothed wheel meshes with a small rack 105 which, in turn, acts by means of a lever 106 on a number cylinder 107 of the percentage scale and moves the latter accordingly.



  As a result, as in the example of a rocker according to fig. 5, there is a combined focus, on the weight scale, of the figures of the scale of the percentages and at the same time of the figures of fictitious weights which correspond to them in each particular case. In the example shown, there is also a special reading window 108 in which one can always read the relationship between the actual weighing capacity of the scale and the fictitious final weight which, for the particular adjustment of the scale. scale of the reports, would correspond to the terminal line 100% of the latter.

   This ratio (10% in the example shown) indicates in

 <Desc / Clms Page number 25>

 at the same time, the ratio between each real weight located s switches and the fictitious weight in the corresponding window. fig. 23, the actual weights are entered on the p scale as fixed inscriptions, in accordance with the ind ratio of 10% between the real weighing capacity and the final weight tif. On the number holder 107 located behind the reading unit 53 near the prescription card R, are available in addition to the various sets of figures for the indications depicting the weighing range of the. switches, the sets of figures which in accordance with fig. 12, assigned to the various settings of the pc of the light source.

   The various series of digits are carried along two coordinates, and the displacement of the digit port107 takes place, depending on the nature of the focus to along one or the other of the two coordinates. In the example shown the number holder is established in the form of ur linder, and the figures for the different focus of the light source within the limits of the actual weighing capacity follow each other in the axial direction, the figures pc the fictitious scope, on the other hand, in the periphery direction
 EMI25.1
 This, indeed, we move the cylinder lengthwise for the displacement of the light source, and we rotate it to change the fictitious weighing capacity.



   For ease of reading, the figure cylinder can be set up as a light tube, or the same use, analogously, a film can be used.



     Fig. 24 also shows an example of a pressure card with variable scale digits. The card is established @ double folding card; the upper side 110 carries the scale divi and reading windows 111, inside is the flat number holder 112, and the lower cover of the folding card can receive inscriptions. In the card is arranged a retaining means 114 for the poi numbers 112, and it can also be provided several card holders.

 <Desc / Clms Page number 26>

 interchangeable frescoes for the card, which are usefully linked together and. are folded like a folding book.



  The retaining means 114 may be a string or a wire stirrup. Fig. 24 offers a particularly good guarantee against unwanted reciprocal displacement of the holder of the prescription card. In the example drawn, the folding card also contains a window 115 for the indication of the fictitious weighing door or the ratio between the real and fictitious weighing ranges, a report whose reading must always agree with that of the corresponding window. the weight scale,
The scales which are arranged on the prescription cards according to figs. 23 and 24 are scales of values relating to the albumin or starch content or for example also to the calorie value of the elements of the mixture. , or also mixtures themselves.

   The placement of these scales allows, by means of a simple transmission between the gear indicator device and the weight indicating device, to read at the same time 1 weight, the mixing ratio and the content of the element being precisely on the rocking. The placement of the scales themselves as well as the interchangeability of the figures each avoid a degree of transmission or a parallel transmission.

   Above the scales can move an indicator mark 116 coupled to the index 51 for focusing the total weight. This indicator mark can be a line on a fairly wide transparent tape It? under which the scales of values and ratios can be found, This transparent tape moves on two rollers 118 and 118 'and its two ends are joined to a chain 119 which, for its part, moves on a toothed wheel 120 rigidly relief at the focus index 51. Slitting the movement of the index 51, there is therefore a combined movement and this always in the given ratio, of the line located on the transparent tape.


    

Claims (1)

CLAIMS. 1. Method of mixing materials by successive weighing of various materials to be mixed on the same wise device, characterized in that the graduation lines of the metering scale are, before the weights relating to the mixture to be prepared, set vis- with respect to a given absolute value of desired mixing advance, for example a weight, in the ratio which corresponds to that mixture. 2. Basculepour the realization of mixes after weight ratios, according to claim 1, characterized in that it is arranged between a ratio indicator device and an indicator device of absolute values con in the case of a weight scale , in the known manner pc the balances with several scales, an adjustable transmission Rocker for carrying out the method according to claim 1, and rocker according to claim 2, because scales capable of being developed with respect to each other, for the various kinds of reading, are combined in the form. dial (figures 7-10, 14 and 15). 4. Rocker according to claim 3, characterized by a guide curve for a friction wheel, which co extends, embracing an arc of 360, to the edge of a friction pole, laid in the manner known on a needle shaft, a friction transmission mechanism provided between two indicating devices. 5. Rocker according to claim 3 or 4, characterized in that the friction wheel shaft (32) is coupled to the needle with an invariable transmission ratio, and in that the friction plate provided with less than one ladder always concentrically to the needle shaft. 6. A seesaw according to claim 3, characterized in that at least one of the mobile scales is variable in itself <Desc / Clms Page number 28> uniformly, the zero point remaining at rest (figs. 7 and 8). 7. Rocker according to claim 3 or 6, characterized in that the movable scale consists of sectors (26) each having a graduation line, which are mounted one by one on the needle shaft and are coupled. each, through the intermediary of a reference with its own transmission ratio (28, 29), to the needle shaft (fig.8). 8. Scale with movable load cell weight and indicating device coupled to this weight for carrying out the method according to claim 1, and rocker according to claim 2, characterized in that the focusing device of the weight is engaged with the weight whatever the position of the lever, and in that one can always read on the indicating device the value which, for the position given to the load cell weight in each particular case, corresponds to the line of terminal scale which is located on an indicating device (12) operating continuously under the action of the load (fig.l). 9. Scale for mixtures of materials according to claim 8, with load cell weight divided on two load cell levers shifting in opposite directions, characterized by a drive connection between each partial weight and the device. common focus and by an external indicator device for indicating the reciprocal position of the active drive members (Mn, Ks) located inside the rocker (fig.5). 10. Indicator device for tilt according to claim 8, characterized by a star (st) wedged on the shaft of the hand crank and by a drum (G) mounted idle and braked externally to the shaft, with projections (v) and stops (z) respectively, distributed over the periphery in a manner corresponding to the spacing of the internal coaches (Mn, Ks), and the same number of recesses (w) uniformly distributed over the tam - bour (G) to indicate the most favorable service position out of the star (v) under the drum-envelop- <Desc / Clms Page number 29> pe (figs. 5, 6). 11. Toggles with indication by shadow reflected the lo of a reading rule for carrying out the method of apr claim 1, and toggle according to claim 2, because. rised by a shadow projector index. (54) moved in a straight line by the needle shaft of a circular scale through a light beam with variable dispersion angle, and by a movable phrase (57) which always allows recognition : displacement range of 1 index (54) and its shadow for total weight developed in each particular case. 12. Rocker for mixtures of materials according to reve cation il, characterized in that the light source (55) disposed on the side of the index (54) facing the rule of the and in that it is placed, in front of this light source screen projector (59) which reflects towards the light reading ruler of the light source with the shadow of the index finger and 1 limiter of the diaphragm (57). 13. Rocker for mixtures of materials according to reve cation 11 or 12, characterized in that the setting index (51) is connected with combined movements to a toothed arc (60) q on its side, turns a shaft (66) to raise and lower the light source and move the diaphragm (57) at the same time that it is arranged in a special manual way (69) the correction of the focusing of the projector screen (59) 14. Scale for mixtures of materials according to one of vendications 1-13, characterized in that it is arranged, for the scale of the reading rule, various sets of designating interchangeable values, and in that it is provided, for one of them, a particular diaphragm (57a, b, c) constantly produced by the shaft (66), the diaphragms being able to be folded down side by side in the light beam or be raised in a position parallel to the light rays (fig. 12). <Desc / Clms Page number 30> 15. Scale for mixtures of materials according to claim 14, characterized by a shaft with a hand crank (70, 71) and control members for simultaneously and dependent on each other the values of the scale as well as the scale. light source (55) and, in addition, fold or raise one by one and in turn the diaphragms (57a, b, c). 16. Rocker for mixtures of materials according to claims 13 and 15, characterized in that the light source rests by a support foot (65), according to the development of the rocker and of the scale, on a support foot (64) depending on the focusing index (51) or on another support foot (81) depending on the focus of the scale on the reading ruler, while the diaphragms are controlled separately by the different pitch threaded parts of the drive shaft (66) which raises and lowers at the same time, depending on the focus index (51) one ( 64) of the two support feet which determine the height position of the light source. 17. Scale for mixtures of materials according to claim 15 or 16, characterized in that it is placed on the control shaft (71) for the digits of the scale, 1 a light source and the diaphragms (57a, b, c), to serve to control the latter, for each an eccentric (82) which is coupled to its diaphragm in conjugate movement, and in that there is arranged a setting device at the direct point (86,87,88) also coupled to the diaphragms with conjugated movements. 18. Scale according to one of claims 1-17, characterized by interchangeable prescription scales, known per se, for specific mixtures, on which, against known prescription scales, are displayed, in whole lengths, the ratios, not relating to a determined weight, for the various elements of the mixture. 19. Prescription scale according to claim 18, characterized in that the various lengths of reports are <Desc / Clms Page number 31> arranged one below the other, and in that the width of the scale of the map is determined by the greater of these lengths of ratios (figs. 12, R). 20. Prescription scale for scales according to claim 18, characterized in that the width of the prescription card. is determined by a partial length nor le (corresponding for example to 10%) (fig. 13). 21. Indicator device for scales with prescription scales according to claim 20, characterized by several indexes following each other regularly at a distance equal to the normal partial slowness of the prescription scale (freeze and 13). 22. Indicator device according to claim 21, characterized in that the multiple indexes are arranged on a closed ban moving on two pulleys placed on fi téesimmobile rods. 23. Light sensitive prescription scale according to one of claims 18-20. 24. Indicator device for tilt according to one of claims 1-17, characterized by a drum carrying vs their absolute, which rotates, under the influence of the load, vis-à-vis a series of movable rings. reading windows which are assigned to specific ratios (figs. 16, 17). 25. Bascule according to one desrevendications 1 -24, camisole made by two loading aprons balancing each other at (fig.l). 26. A rocker according to claim 2, characterized in that, in the case of a spring rocker, one of the indicator dispositj can be, over the turns of the spring, race of the choice at various locations of the spring (figs. 18-20). 27. Rocker according to claim 6, characterized st that it is added to the graduations of fixed scales games @ figures which can be changed position, including one in each <Desc / Clms Page number 32> case, is visible on the scale. 28. Method according to claim 1, characterized in that, in the case of a rocker according to claim 6, 7, 26 or 27, the metering end line of the element whose ratio is the most high is approximated with the end of the weight scale, so that the weight corresponding to the value ratio line 1 (100%) is then outside the weighing range of the scale. 29. Rocker according to claim 27, characterized in that, in the case of rockers according to one of claims 11-18, two sets of scale values are arranged on the movable number carrier behind the reading rule. placed along two coordinates, so that when moving the number carrier in one direction, you can see under the reading windows of the ruler, the values relating to the real weighing capacity of the scale for various ratios of transmission of indication and, when moving in the other direction, the series of values composed according to claim 28, according to the development of the number carrier. 30. Prescription card, characterized by value scales relating, for example, to the albumin or calorie content. 31. Prescription card, characterized in that it is provided with reading windows and is established as a double folding card, while it is provided, in the fold, m with a retaining means for a number holder d ' scale inserted in the card in a movable way (fig. 24). 32. rocker according to claims 11, 27 and 29, characterized in that it is coupled to the displacement device for the number holder located behind the reading rule, another number holder which shows below the weight scale, in an isolated window, the ratio between the actual weighing capacity of the scale and the filial weight <Desc / Clms Page number 33> tif developed in accordance with claim 28, and in time, under a series of reading windows located at fixed weight figures, the weight lines which have ave the actual weight of each case, the ratio visible in the iron isolated reading. At the same time, a mobi indicator mark above the prescription card is coupled to the focusing india (51) (fig. 23).