DE3006928A1 - METHOD FOR CHECKING AND CALIBRATING A DEVICE FOR MEASURING AND DISPLAYING THE WEIGHT OF LIQUIDS IN TANKS - Google Patents

Description

Method for checking and calibrating a device for Measurement and display of the weight of liquids in tanks.

The invention relates to a method for checking and calibration of a device for measuring and displaying the weight of liquids in tanks by means of an in the tank guided displacer, the weight of which is greater than that of the liquid displaced by it, and its cross-sectional areas a constant ratio to the corresponding cross-sectional areas of the at least over its entire immersion depth Tanks have, and the weight of the between the plane determined by the lower, horizontal face of the displacer and the liquid level in the tank is displayed, which is the product of the ratio of the cross-sectional areas and corresponds to the buoyancy of the displacer determined by means of a balance.

Devices for measuring and displaying the · "■ · ~ - ht.? S of liquids in containers (e.g. DT-PS" ^r j '\ 1 ... US 3 677 356) are known in which with a balance the buoyancy of a displacer guided in a container is determined, and the buoyancy and the product of this and the ratio of the cross-sectional areas of the displacer to the corresponding cross-sectional areas of the container is displayed.

However, calibration and verification methods for the known arrangements are not known. For their calibration and verification one could either empty the liquid from the container, or bring the displacer outside the container, so that the displacer does not experience any buoyancy and the scales are not actuated because of the dead weight of the displacer is balanced by a counterweight. These two procedures are possible when it comes to is small dimensions of both the container and the displacer. As the size increases, these dimensions take on however, the difficulties for the two procedures increase considerably.

At the size of the currently common tanks with one capacity of several million liters, it is hardly possible to have a second tank to hold the liquid to be emptied

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BATH ORIGINAL

I 3006923

ability to be made available. But also removing the displacer, which at least reaches a height of 10-20 m and more, from the tank, besides a considerable expenditure of time, also entails great difficulties.

The invention is based on the object of creating a method of the type mentioned at the beginning, which has the disadvantages of the above avoids the methods shown, and on the other hand, despite extremely great accuracy, simplicity and inrelation on the size of the dimensions of the tanks and displacers of almost unlimited possibilities of use. The solution to this problem results from patent claim 1, while the subclaims show useful developments.

The inventive method has the advantage that it is his Implementation does not require any structural changes. It continues to stand out for its simplicity, its greatness Accuracy and its almost unlimited, but always possible usability and its extremely easy operability the end.

The invention is explained below with reference to the accompanying drawings, for example.

Fig. 1 shows a simple embodiment and serves essentially to explain the method.

FIG. 2 shows an exemplary embodiment which is to be preferably used in practice.

In FIG. 1, the lever 3 mounted on the cutting edge 3a engages the load cell via the cutting edge 16a and the hanger 16. The use of a gyroscopic load cell as a load cell is preferred because it is the only load cell in which no stroke is caused by the load. B. load cells are used. Load cells with always the same equilibrium or zero position, such as a two-armed beam balance, can also be used as a measuring cell. The shell 7 engages on the lever 3 via the cutting edge 7a, on which the displacer 2 engages via the hanger 18, 18a and the releasable connection 19, which is guided ^{by the link 5 and 5 1.} Instead of the hook connection 19, any other releasable connection z. B. Step edge and pan.

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The displacer 2 is only partially immersed in the liquid 12 in the tank 11. The closer the lower, horizontal face of the Displacer 2 is the bottom of the tank 11, the greater the measuring range of the device. The measuring cell 1 is adjusted so that that at a moment of force of the balance weight 6, which is the difference between the weight G of the displacer 2 and its max. Buoyancy corresponds to the value of the maximum buoyancy. This value corresponds to a zero load on the measuring cell 1 The display of the measuring cell 1 shows not only the value for the buoyancy of the displacer 2 in the liquid 12, but that also z. B. determined by a computer product of buoyancy and the - at least over the entire immersion depth of the displacer 2 constant - ratio of the cross-sectional areas Q of the tank 11 to the corresponding cross-section sf laugh at q of displacer 2. For the purpose of determining the maximum buoyancy of the displacer 2 in the liquid 12 is this completely in this liquid or a liquid of the same spec. Weight submerged and the buoyancy, which the displacer 2 experiences, determined by means of a measuring cell (balance). But it can also with the measuring cell 1, the buoyancy of a the displacer completely immersed in the tank liquid 12, the volume of which is a fraction of the volume of the displacer 2, determined and the maximum lift of the displacer 2 can be calculated from this by multiplication. Also as a product the volume of the displacer 2 and the spec. The weight of the liquid 12 can be used to calculate the maximum buoyancy of the displacer 2 will.

For the purpose of checking and calibrating the device, the Lever 3 from the load caused by the displacer 2 located in or outside the tank liquid 12 by lifting it slightly of the displacer 2 or a slight lowering of the entire arrangement located above the releasable connection 19 is relieved, and then

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a weight 8 is attached to the lever 3 (ζ. B. on the shell 7), which is identical to the difference between the weight of the displacer 2 and its maximum lift is. For balancing, the balance weight 6 is now moved on the lever 3 for as long as until the measuring cell 1 shows the value of the maximum lift. Now one after the other calibrated weights 13, which are preferably Corresponding to fractions (e.g. 1/10 - 10/10) of the maximum lift of the displacer 2 (e.g. by placing on the shell 7) attached to the lever 3. Taking into account their lever arm, the calibration weights 13 can also be attached to any Attack the position to the left of the cutting edge 3a (e.g. on the cutting edge 16a) on the lever 3. The from the measuring cell 1 each for the individual Calibration weights 13 weight values displayed will be identical to the corresponding calibration weights. If this is not the case, the display values of the measuring cell 1 are adjusted by moving the corresponding Corrected calibration weights on lever 3. The calibration curve obtained in this way can also be created using the grading method will. After the lever 3 has been relieved of the weight 8 and all calibration weights 13, its load the zero point of the device is checked with displacer 2. The verification and calibration of the device can So be made away from the tank 11 and after building the Device on the tank 11 and partial immersion of the Displacer 2 in its liquid 12 at any time - also made between measurements of the weight of the tank liquid 12 will.

Fig. 2 shows an embodiment again, which - in particular due to the possibility of its remote control - in Preference is given to practice.

Essentially, the device of FIG. 2 differs from that of FIG. 1 in that there is an additional device over the hanger 15 acting on the lever 3 lever 4, through which a for the Practice-appropriate gear ratio is achieved. Furthermore, through the lifting and lifting devices 10, 10a, 10b for loading and relief of the two levers 3 and 4. The checking and calibration of the device is similar

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Way - as already described with reference to Fig. 1 - made. First of all, the lever 3 is relieved of the stress caused by the itself In or outside of the tank liquid 12 displacer 2 is freed with the lifting device 10. Then by means of of the lifting device 10a, the weight 8, which is identical to the difference between the weight of the displacer 2 and its maximum buoyancy is deposited on the shell 17. The adjustment is then carried out by moving the balance weight 6 on the lever 3. The measuring cell 1 then shows the maximum lift at. Finally, the lever 3 is successively loaded with calibration weights 13 until the entire measuring range, which is preferably corresponds to the maximum buoyancy of the displacer 2 is passed through. This is done by placing calibration weights 13 by means of the lifting device 10a on the shell 17 or / and by depositing calibration weights 13 by means of the lifting device 10b on the tray 9. After this in this way the entire calibration curve is created, the lever 3 is relieved of all weights 8 and 13 and then with the Displacer 2 loaded. The lifting devices 10, 10a, 10b can be done manually e.g. B. can be operated by means of a hand crank or with a motor.

To balance by moving the balance weight on the lever 3, instead of the weight, the difference from the weight of the displacer and its maximum buoyancy is identical, also a weight which is identical to that of the displacer or the displacer outside of the tank fluid will kick itself. The load on the transmission links (e.g. pan and cutting edge) between the counterweights and the lever is the maximum buoyancy of the displacer greater.

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Claims (3)

Claims Method for checking and calibrating a device for measuring and displaying the weight of liquids in tanks by means of a displacer guided in the tank, whose weight is greater than that of the liquid it displaces, and its cross-sectional areas at least A constant ratio to the corresponding cross-sectional areas of the over its entire immersion depth Tanks have, and the weight between that determined by the lower, horizontal face of the displacer The liquid level and the liquid level in the tank is displayed, which is the product of the ratio corresponds to the cross-sectional areas and the buoyancy of the displacer determined by means of a measuring cell, thereby characterized in that initially the lever (3) from the load caused by the inside or outside of the tank liquid (12) located displacer (2) relieved by means of the releasable connection (19) and then in its place on the lever (3) a weight (8) is attached which is identical to the difference between the weight of the displacer (2) and its is maximum buoyancy, then the balance is carried out by moving the balance weight (6) on the lever (3) made until the measuring cell shows the maximum buoyancy, finally the lever (3) in one such a distance from its pivot point (3a) successively loaded with calibration weights (13) that the of the measuring cell (1) the displayed values are identical to the values of the calibration weights causing them, the lever becomes finite (3) relieved of the weights (8 and 13) and through loading the zero point is checked with the displacer (2). 2) Method according to claim 1, characterized in that a gyro measuring cell is used as the measuring cell. 3) Method according to claim 1 or 1, characterized in that the load by the displacer (2) and the weights (8 and 13), as well as the relief of these by means of lifting and lifting devices (10, 10a, 10b). 130037/0130