DE2807041A1 - Liq. dosing system delivering given weight of liq. - uses dynamometer cell subjected to small loading stroke by engaging immersed body - Google Patents

Abstract

A certain weight of a liquid is delivered from a container by using a body (2) of known weight larger than that of the liquid displaced by it. The body is immersed in the container (1) so deep that the level of the liquid forms a plane with the upper horizontal face (7) of the body. The dynamometer element (9) is used to determine the weight of the body before extraction of liquid and to fix its weight corresponding to its depth of immersion after extraction of liquid. The weight of the extracted liquid is calculated.

Description

Method for the delivery of a load cell loaded by means of a load cell

correct weight of a liquid.

The invention relates to a method for dispensing a means a load cell of certain weight of a liquid It is z. B. from the DAS 23 19 421 a consumption measuring device known in which the scales a two-armed Has a balance beam, one arm of which is the vessel and the other arm of which is counterweights to compensate for the weight of the measuring vessel and the oil weight of the liquid at the beginning of the measurement.

This consumption measuring device is required to record the measured values Light sources, photo receivers and extensive electronic equipment - the disadvantage This known Einrichturlg consists in the fact that your balance beam is both the measuring vessel with content as well as having to carry the counterweights. The balance beam must therefore accordingly be stably constructed, and its load-bearing capacity must be with the size of the weight the liquid to be extracted grow. The well-known device is thus all the more unsuitable and unsuitable, the greater the weight of the liquid to be withdrawn will.

The invention is based on the object of a method of the above mentioned type to indicate which the disadvantages of the mentioned, known constructions avoids and, on the other hand, enables the use of arrangements that are in spite of extremely high accuracy due to simplicity, light weight and therefore easy transportability and high, almost unlimited use.

The solution to this problem results from claim 1, while the subclaims describe useful developments.

The method according to the invention results in its Implementation of the necessary facilities compared to the known consumption measuring devices a significantly reduced structural effort and therefore also significantly lower Manufacturing costs. But also the design of the process according to the invention required facilities compared to the becanner consumption measuring devices decisive advantages, namely a special simplicity and the resulting one extremely light operability. The method according to the invention has The know: n advantage that it not only offers the possibility of additional volume the liquid dispensed from the dispensing container, but also the weight and the volume of the liquid in the tank from which the dispensing container is filled, / determine.

The use of a gyroscope as a load cell for weighing the in di <body immersed in liquid does not guarantee measurement results superior accuracy.

Afterwards, the invention is based on the exemplary embodiments of will be explained in more detail in the attached drawings.

In the embodiment of FIG. 1, the container 1 has a its entire length has a constant cross-section Q. Into the liquid in container 1 A body 2 engaging at the force introduction 18 of the load cell 9 emerges from Over its entire length ho constant cross-section q and of greater weight than GL the fluid it displaced. About the vertical length of the body 2 substantially, becomes essential for the lower part 17 of the body 2 higher density than that of the upper part of the body 2 is considered particularly useful. For the same reason, the lower end face 6 of the body 2 can move with it a preferably extremely flat body of considerably higher density than the body 2 can be connected. Also a tension spring with adjustable train that z. B. by means of Universal joints on the one hand with the end face 6 of the body 2 and on the other hand with the base 10 of the container 1 or the base of a recess in the container 1 serves the same purpose. The level of the liquid in the container 1 arf at most so high that the end face 7 of the body 2 nit the liquid level forms a plane. This requirement is taken into account by the fact that impulses which are triggered when the load cell 9 for the immersed Body 2 displayed weight value no longer changes, the shut-off device 13, over which the container 1 is filled from a storage tank, not shown, close and / or an overflow at the level of the horizontal end face 7, which the liquid can flow back to the storage tank, which is possibly located above this overflow 20. The withdrawal takes place by means of the shut-off device -icwltung (e.g. solenoid valve) 14 and the outlet 16, which is so large that the liquid can drain off, until its mirror forms a plane with the end face 6. The shut-off device 14 can also be controlled by impulses that are triggered when the The display value of the load cell 9 corresponds to the weight value G of the amount of liquid to be dispensed approaches e and has reached @. The residual liquid between the end face 6 and the. The container base area 10 can be left over the shut-off valve 15 if necessary.

The cutting edge 3 of the force introduction 18, on which the body 2 hangs, rurt on the arm 4a of the lever 4 stored on the support blade 5 The pedestal 12 mounted on the container 1 carries lever 4 on its arm 4b the tare weight 11 to compensate for the weight GL of the body 2 in air. At the Embodiment engages through the body 2 over the cutting edge. 3 on the lever 4 force exerted via the suspension cutting edge 8 at the end 19 that does not precede with it the rotatable about the vertical axis suspension of the top 9 on its (not shown) lever. The use of a gyroscope as a load cell for weighing of the body 2 is given preference because the circles are the only load cell where the load does not cause any lift at all. The introduction of force but could also at any load cell with little, the measurement result do not attack the falsifying stroke caused by the load, e.g. B. at a load cell. Instead of the top. could also load cells with always the same Equilibrium or zero position could be used, e.g. B. the lever 4 a two-armed beam scales belong to the arm 4a of the body 2 over the load cutter 3 attacks, while the other arm 4b with the necessary for compensation Running weights is provided. With the microfine regulation 21, if necessary a certain distance between the base 10 of the container 1 and the end face 6 of the body 2.

Fig. 2 shows an embodiment in which the container 1 and the tank 25 are connected to one another by the line 22, - that they are communicating Form vessels. If the shut-off valve 23 in the line 22 is open, the liquid @@ keit in both vessels (1 and 25) the same height. The vessels 1 @ and 25 are in such a way to each other arranged that the liquid @n them never higher than dic through the horizontal Front surface I is determined @; plane is. The rest of the parts are the same as those of the Arrangement of Fig. 1, e is therefore dispensed with their repeated application. The particular advantage of this arrangement is that with knowledge of the dimensions (Length and cross-section) of the tank 25 is only used to determine the weight G @ the required values of the FJ liquid quantity dispensed from the container 1 needed to be there. Weight GT d @ r in the tank 25 above that through the horizontal Front surface 6 of the body 2 certain level standing liquid based on the relationship: V GT = (G - Gh). T to determine q.h in what C @ @@ s weight of the body 2 in Air, Gh its weight corresponding to the immersion depth ii, q its cross-section, h is the immersion depth and VT is the volume of the area determined by the end face 6 Are level standing liquid.

The distance between the base 24 of the tank 25 and the through the forehead surface 6 certain level is kept so low that the consideration the weight of the liquid in between when specifying the weight G of the 5 total liquid in the tank 25 is unnecessary. However, should be taken into account the weight of the between the face 6 and the base 24 of the Tanks 25 located liquid when specifying the weight G5 of the total liquid be required in the tank 25, this is done by the GT. v relationship: Gs = GT +, where GT is the weight of the plane determined by the face 6 above the VT standing liquid, the volume of which and v the volume between the base surface 24 These are tanks 25 and the plane defined by the end face 6.

The volume of the liquid standing in the tank through the end face 6 of the body 2 is simplified to VT QT h and the weight of this Q liquid for tanks whose cross-sectional area - as in the tank 25 - is constant at least over the length ho of the body 2 becomes GT = <GL - Gh), T On the other hand, q for the tanks whose cross-sectional area changes with the filling level, the volume of the liquid above the plane determined by the end face 6 is given by the relation: where k is a constant of the respective tank, f (hx) is a function for the cross-sectional area that changes with the variable hx, which is dependent on the immersion depth h, hx1 is the immersion depth h before and hx2 is the immersion depth h 'after the liquid is dispensed derived.

The following are the equations for some known tank shapes for the volume of the plane above the plane determined by the end face 6 Liquids specified.

So z. B. for a tank in the form of a sphere of radius r and for a lying circular cylinder of length L and radius r and for a horizontal cylinder of length L and elliptical cross-section In these equations (GL - Gh) hx = h - (r - s) = ho # - (r - s) (GL - G @) for the ball and the circular cylinder and for the cylinder with an elliptical cross-section becomes: (GL - Gh) hx = h - (a - s) = ho # - (a - (GL - G @) where h @ is the length of the body 2, GL its weight in air, G the weight of the completely in the liquid body 2 immersed in-0, Gh is the weight of the body 2 immersed to immersion depth h, r is the radius of the sphere or

of the circular cylinder, a is the major axis of the elliptical cross-section of the cylinder, s is the distance between the plane defined by the end face 6 and the base area of the tank.

The determination of the weight Ge of the dispensed from the container 1 The amount of liquid takes place, for example, in the following way: With the gyro 9 is the weight Gh of the immersed in the liquid in the container 1 to the immersion depth h Body 2 detected and saved. However, the liquid must not exceed this stand high that their mirror with the upper, horizontal face 7 of the body 2 forms a plane. For this special case, the immersion depth h corresponds to the length h of the body 2 and the corresponding weight Gh is the weight G0 of the complete body immersed in the liquid 2. The determination of the weight G0 becomes expediently repeated in particular after changing the temperature of the liquid. For this purpose, the body 2 is z. B.

by means of the microfine regulation 21 or by adding liquid from the storage tank at least to its end face 7 with the liquid level forms a plane, immersed and then with the top 9 the weight G0 of the body 2 determined. Before determining the first to determine the weight G of the delivered Fluid required e value Gh, it must be ensured that the body 2 at most so deeply immersed in the liquid that its end face 7 with the Liquid level forms a plane. Well - after at the Embodiment of FIG. 2 the cock 23 of the line 22 is closed - z. B. by opening the shut-off device 14 in the line 16 liquid is released. The weight determined and also stored by the gyro 9 after this delivery Gh corresponds to an immersion depth h 'of the body measured from the end face 6 2. The delivery of liquid can be gradual or without interruption up to the immersion depth h = 0, i.e. H. until the end face 6 forms a plane with the liquid level, take place. After each liquid dispensing, the weight value displayed by the gyro 9 is GhV, which corresponds to the immersion depth h 'achieved by this delivery, is stored.

The weight G of the dispensed liquid is equal to that of the e gyroscope 9 weight Gh determined before delivery and the weight determined after delivery Gh, based on the relationship: V - q. (h - h ') Ge = (Ghw - Gh) q. (h - h ') determined, where V is the volume of the container 1 between (GL - Gh) (GL - Gh,) the immersion depth h = ho # or h '= ho # (GL - Go) (GL - Go) Gh and Gh, the - these immersion depths h and h 'corresponding weights of the immersing body 2 of cross section q and the length ho, G0 the weight of the fully immersed body 2, and GL its weight in air.

For a container whose cross-sectional area Q reduced by the cross-sectional area q of the body 2 is constant over its entire length h, the volume of the container between the two immersion depths h and hs becomes: V = Q. (h - h ') and the weight Ge of the dispensed liquid is simplified to: Q - q Ge = (Gh, - Gh) q For a container 1 with a cross-sectional area that is variable depending on the immersion depth h of the body 2 where k is a constant of the container 1 and f (hx) is a function for the cross-sectional area, which changes with the variable h dependent on the immersion depth h, hxi is determined by the x immersion depth h before and hx2 from the immersion depth h 'after the liquid is dispensed derived.

The weight of the dispensed liquid is given by the relationship: given.

Use this relationship for the weight Ge of the dispensed liquid or the volume V of this liquid, these quantities can easily be calculated. The calculation can also be carried out using a computer or microprocessor, which first the constants determined by the container 1 and then that of the Gyroscope 9 determined the weight Gh before the liquid was dispensed and the weight Gh after be forwarded to this levy.

The relationships for the weight G and the volume V e are based on Gh, resolved, the result is the weight value Ghi indicated by the load cell 9 must, so that the dispensed liquid has the weight Ge or the volume V. That Approaching the load cell 9 to the display value Gh can be used to control the dispensing of liquid and for their final interruption when the value Gh is reached.

Claims (3)

Claims method for the delivery of a load cell by means of a load cell a certain weight of a liquid from a container, characterized in that that one at the force introduction (28) of a load cell (9) with as little as possible Stroke caused by the load or always the same equilibrium or zero position attacking body (2) of known weight (GL) greater than that of the body it displaced Liquid and of constant cross-section (q) over its entire length (ho) so deeply immersed in the liquid in the container (1) that its level with the upper, horizontal end face (7) of the body (2) forms a plane, so then with the load cell (9) the weight (Gh) of the up to the horizontal End face (6) measured height (h) immersing body (2) in front of and its Immersion depth (h ') corresponding weight (Gh,) determined after the liquid has been removed, which, however, only forms a plane with the liquid level up to the forehead surface (6), takes place, then the weight (Ge) of the withdrawn liquid is given by the relation: V - q <h - h ') Ge = (Gh, Gh) q. (h - h '), where V is the volume of the container (1) between the immersion depths h and h ', Gh and Gh, which correspond to the GL - Gh GL - GhI L @ L immersion depths (h = ho #) or (h '= ho # @ @ @ @ 0 corresponding Weights of the immersed body (2) of cross section (q). 2) Method according to claim 1, characterized in that the container (1) is connected in a communicating manner to a vessel (25) filled with liquid and that - after the liquid level in the two vessels (1 and 25) in one not higher than determined by the horizontal end face (7) of the body (2) Level - before the one that only takes place after the communicating connection has been interrupted Delivery of liquid from the container (f) determined by the load cell (9) Weight (Gh) of the measured from the lower, horizontal face (6) Height (h) immersed body (2) to determine the weight (GT) in the tank (25) above the liquid standing through the end face (6) of the body (2) the relation: VT GT = (GL - Gh) # q. h is used, where q is the cross section of the body (2), GL is its weight in air, Gh is its weight at the immersion depth (h = ho GL - Gh) ulld VT is the volume associated with the immersion depth (h) GL - G0 T of the tank (25). 3) Device for performing the method according to one of the claims 1-2, characterized in that the load cell (9) used to determine the weight of the body (2) a gyro is used.