DE1161049B - Measuring device for measuring the weight of a gas flowing through it or a pipe during a certain measuring time - Google Patents

Description

Measuring device for measuring the weight of one by them or one Conduction during a certain measurement time of flowing gas The invention relates relate to a measuring device for measuring the weight of one by them or one Conduction of compressible medium flowing during a given measurement time, d. H. a gas flowing during this period. The aim of the invention is the weight of the volume of gas which flowed through the device during this period of time and without determining any conversions.

Reservoir or nozzle flow meters are known for such measuring purposes; With these measuring devices, the volume of a quantity of gas can be determined flowed through the measuring device during a certain measuring time. On the other hand, at these known devices neither the density nor the weight of the gas without cumbersome Invoices are determined. In particular, determining weight requires a complex process Calculations.

Such calculations are not only time consuming, they must be also be made repeatedly, as the pressures and temperatures of the gas in one Pipeline are changeable in a wide range. Everyone in the natural gas industry has to Supplier or customer many people to calculate and convert the gas quantities that flow through the pipelines because the cost of delivery of the Gas quantities and their accounting on the gas weight, and not on the gas volume, are based.

The invention is therefore primarily intended to provide a measuring device to create that the weight, d. H. determines the mass of the gas and indicates that during a certain measuring time (i.e. between two measuring times) by the Measuring device or an associated line flowed.

Furthermore, a measuring device is to be created according to the invention, which preferably also at any time the gas density and the total weight of the amount of gas allows reading which flowed through the measuring device or the pipeline.

The objects of the invention are achieved in that a the gas density continuously determining measuring device is provided and according to the measured values the position of a control member changed, which these changes in position in an integrating device via which one of its input actuators controls that a speedometer is provided that continuously determines the speed of the gas flow and this in the form of a movement to the other of the input actuators of the integrator controls in this, and that at the output of the integrator a counter for Specification of the weight of the gas volume is connected during the measuring time flowed through the device or the line.

Such a measuring device does not deliver directly to the counter the gas volume, but rather the gas weight of the amount of gas that is between two given measurement times by the device or the line, without that the pressures and temperatures of the gas in the lines need to be determined.

Depending on the initial number of the counter, instead of the weight the amount of gas that flowed between the two measuring times, also the total weight determined or read from an earlier point in time up to Completion of the measurement period flowed through the device.

A practical embodiment of the invention other than the foregoing Determination of the gas weight also the instantaneous value of the at any time Gas density can be read off, according to the invention contains a measuring device for determination the gas density, which consists of the following parts: one the pressure difference and behind a line constriction measuring differential pressure measuring device, which is an electrical Voltage generated, which is the differential pressure and therefore the product of the square of the Flow rate is proportional to the gas density, one from the speedometer powered compound generator that supplies an electrical voltage equal to the square is proportional to the flow velocity, and a quotient measuring device, in which the two voltages are controlled and the one to the quotient, d. H. the gas density proportional size through the position of a display element and / or of the control member reproduces.

A measuring device according to the invention designed in this way can measure the gas density also record in the form of a curve over time and thereby contribute to appropriate calibration of the scale of the quotient measuring device the gas weight in kilograms specify per time unit. The total gas weight for each selected measurement period could then by integrating the recorded curve over time as an area integral be won. In connection with an integrating device and a counter of the aforementioned type, however, this subsequent area integration is also unnecessary.

Another practical embodiment needed in connection with the integrating device the described measuring device and the counter the aforementioned Quotient measuring device not; rather, in this embodiment there is the measuring device from a measuring device continuously determining the gas density, which this density directly supplies and is preferably also a display device that is connected to the output of a Fan or a pump is connected, which is in a gas flowed shunt circuit the gas pipe.

Other advantages will emerge from practicing the invention from the following description and the drawing, namely Fig. 1 shows a diagram of an embodiment of the device, FIG. 2 a scheme of another Embodiment of the device.

The invention is based on the fact that, although no known measuring device itself provides the results required above, there are measuring devices that are exactly different Measure functions of those data that are necessary to e.g. B. the weight of a to determine the gas flowing through a pipeline.

Fig. 1 shows a venturi measuring nozzle. Everything flowing through this measuring device Gas also flows through a speedometer 3. The combination of two of these Measuring equipment provides all the required data about the gas. The Venturi measuring nozzle 1 is used for example as a so-called "first measuring device", but any other measuring nozzle or orifice can be used.

The measuring device 1 has two measuring points in the form of two tubes 2 'and 2 ", one of which is from the gas flow channel upstream of the Venturi nozzle to the second branches off at the narrowest nozzle cross-section.

These two pipes lead to a device2 that controls the pressure difference between the pipes 2 'and 2 ". The device 2 is, for example, a differential pressure conversion device serve, which generates an electrical voltage that is proportional to the pressure difference is. This voltage is denoted by V1. Other similar devices for measuring the pressure difference can be used in place of this particular device.

As is known, the pressure difference PO can be a function of the density J can be expressed: Po = J.k1.v2, where k1 is a device constant and v is the speed represent.

The flow meter can be calibrated in such a way that the Can read gas velocity.

Since between the flow or nozzle cross section of the measuring device 1 and the effective cross section of the measuring device 3 can be a difference, must a suitable constant is introduced in such a way that as a result of the corresponding calibration of the z. B. designed as a vortex wheel rotor of the measuring device 3 by the rotor speed, z. B. on the circumference, the speed of the flow or

Nozzle cross-section can be measured towards continuous gas. These Circulation speed can be expressed in meters per unit of time so that it the velocity v of the flow in the flow or. Corresponds to the nozzle cross-section and this speed v at each instant on the display of the meter 3 is given immediately; on the other hand, however, is now the same as for measuring device 1 above has already been described. the pressure difference multiplied as a function of density with the square of the speed v, namely Po = k1 - v-.

The gas weight W flowing through the measuring device 1 per unit of time be a function in which the flow or nozzle cross-section A is included, and it must (if constants are omitted) be equal to the product of the nozzle cross-section A (in m2), speed v (in meters per unit of time) and density J (e.g. in kgimj), d. H.

W = A-v-J.

Since AJv2 is equal to PO multiplied by the constant A, it's just still required to multiply Po by A and divide by v to get for each Instant to get the gas weight that per unit of time through the pipeline flows.

The differential pressure converter 2 generates under the influence the pressure difference in its output line, which it can be controlled with a potentiometer z. B. Weston type, executed quotient measuring device 4 connects. an electric Voltage V1. This tension is a unique function of Jv2.

If a generator 3 'were to be driven by the measuring device 3, it would its output line leading to the quotient measuring device 4 has a second output line to this device 4 Apply voltage V. A scale with pointer 4 'of the quotient measuring device could then be calibrated so that it gives the gas weight in kilograms per unit of time. aside from that a pen could be attached which moves together with the pointer 4 ' and draws a line on a clockwork-driven strip of paper. That Total weight for each chosen time period would then be calculated as that between the The baseline and the area lying on the display line are measured. These measures would still require the integration of the curve as an area integral in order to achieve the desired Get results without calculating.

Instead of only one generator 3 'of the aforementioned embodiment is now still, as Fig. 1 shows, a second generator 3 "connected in such a way that he delivers a voltage V, which is now not the speed v, but its Square v2 is proportional. The pointer 4 'then does not give the current one Weight W, but a display proportional to the instantaneous value of density J. From the Namely, differential pressure conversion device 2 is obtained Voltage Vl, which expresses Jv2, and from generator 3 "one obtains a voltage V2, which expresses v2: If one then divides Vl by V2 or JV2 by v2, one obtains J, the density or the specific weight.

The quotient measuring device 4 then actuates a one via a member 5 Carriage moving bumper 6 'of an integrator 6.

As above for the z. B. as a vortex flow meter working speed meter 3, the speed of the rotor of this measuring device, e.g. B. be calibrated on its circumference as the instantaneous speed v; instead of this can just as well, since the cross-section is constant, through appropriate calibration the absolute number of rotor revolutions as a time-independent volume variable can be reproduced (as the product of the number of revolutions and cross-section equal to the volume).

A synchronous torque converter or amplifier is used for this purpose 7 provided by the speed measuring device 3 from a Selsyn or rotary field encoder 8 and a Selsyn or rotary field receiver 8 'is fed and the shaft 6 ″ of the integrator 6 in a speed ratio of 1: 1 (or another selected speed ratio). The integrator multiplies therefore the density J, as indicated by the member 5 of the quotient measuring device 4 in it is controlled, with the indicated by the speedometer 3 and volume amount forwarded by means of the synchronous torque converter.

The result is given by the absolute number of revolutions of the integrator shaft 9, to which a counter 10 is connected for this number of revolutions is. This counter can be scaled down so that the number displayed on the scale gives the total weight of the gas in the desired appropriate units that flowed through the pipeline.

F i g. 2 shows another embodiment of the device in which a density meter 11 is used in place of the measuring device 1. This densimeter 11 measures by the difference between that pressure exerted by a centrifugal fan or a pump 12 is generated, and the one connected to the suction side of the pump Pipeline pressure, the density J of the gas by means of a differential device 13. The scale together with pointer 14 of this device is, as with pointer 4 'in Fig. 1, calibrated in density units. The densitometer 11 moves a link 5 'in the same Way, as the link 5 in F i g. 1 is controlled. The rest of the device according to FIG. 2 is the same as in FIG. 1.

Thus, the invention creates a simple and effective measuring device, the bills superfluous makes and an immediate weight display of the amount of gas supplies that flowed through the pipeline.

It can also be seen that the measuring device according to the invention by means of an additional device supplies measurement results or displays that the sequence of Reproduce the gas flow in the pipeline and allow it to be recorded and recorded.

Claims (3)

Claims: 1. Measuring device for measuring the weight of a gas flowing through it or a line during a certain measuring time, d a -characterized in that a measuring device continuously determining the gas density J is provided and changes the position of a control element (5) according to the measured values, this changes in position in an integrating device (6), over which one of his Input actuators (6 ', 6 ") controls that a speed measuring device (3) is provided is that continuously determines the speed v of the gas flow and this in Form of movement of the other (6 ") of the input actuators (6 ', 6") of the integrator controls in this, and that at the output of the integrating device a counter (10) to indicate the weight of the gas volume that is connected during the measuring time flowed through the device or line. 2. Measuring device according to claim 1, characterized in that the The measuring device determining the gas density J consists of the following parts: one the pressure difference Differential pressure measuring device (1, 2) measuring upstream and downstream of a line constriction, that generates an electrical voltage V1 that the differential pressure PO and thus the Product of the square of the flow velocity v times the gas density J proportional is, a by the speed measuring device (3) driven composite generator (3 ', 3 "), which supplies an electrical voltage V2, which is the square of the flow velocity is proportional, and a quotient measuring device (4), in which the two voltages V3 and V2 are controlled and one of the quotient Vl-, d. H. the gas-2 density J proportional size due to the position of an ancillary link (4 ') and / or the control link (5) reproduces. 3. Measuring device according to claim 1, characterized in that the A measuring device continuously determining the gas density is a measuring device which directly supplies this density J and preferably also indicating device (13) having the output of a fan or a pump (12) is connected, which is in a gas-carrying bypass circuit the gas pipe.