DE2259152A1 - ARRANGEMENT FOR MEASURING FLOW RATES - Google Patents

Description

Arrangement for measuring flow rates The invention relates to a Arrangement for measuring the flow of flowing media, especially liquids through closed pipelines.

The object of the invention is to create such an arrangement, with which small flow rates can also be measured, which has a large measuring range and with which a quantity display for different reference bases is possible, for example the display of flow rates per unit of time and per unit of travel.

This object is achieved according to the invention by a measuring cylinder with a should dividing the measuring cylinder into two cylinder spaces, at both ends of the measuring cylinder arranged limit switches and connections for the to be measured Medium, further through a solenoid-operated reversing valve for the alternating connection the connections with the inlet and the outlet, switching means for the solenoid-operated Reversing valve Depending on the response of the limit switches, a reference base emitting pulses, a counting device for the pulses emitted by the reference base, a memory arrangement, in which the respective counter reading depends on the response of the limit switch the counting device is transferable and by means of processing and display of the counter reading taken over into the memory as a function of the measuring volume of the measuring cylinder The reference base can be a time base if the flow should be measured per unit of time. The reference base can, however, also be a path base if the flow is to be measured over the path. As a limit switch you can It is advisable to use electronic switches, preferably field plate limit switches.

The switching means for the reversing valve is preferably a bistable one electronic switch provided. This switch can be controlled with means the transfer of the counter reading into the memory. It can do that too Means can be provided with which the counting device after taking over the counter reading can be reset to zero in the memory.

The invention is illustrated in the drawing in an exemplary embodiment and described in detail below with reference to the drawing.

Fig. 1 shows schematically a device for measuring the flow of a flowing medium through a closed pipeline.

2 shows the circuit of the control and display device in a block diagram.

The arrangement shown in Fig. 1 has a measuring cylinder 2, by means of a piston arranged so that it can be pushed back and forth in the measuring cylinder 4 is divided into two cylinder spaces 6 and 8. The Mizylinder is on both of them Ends closed by floors 10 and 12, which are releasably connected to the cylinder jacket are. Connections 14 and 16 are provided at both ends of the measuring cylinder. There is also a limit switch 18 or

20 arranged. This limit switch works with the leading one Edge on the face of the piston 4 together, which acts here as a control edge.

The device also has a solenoid-operated reversing valve 22 on. Via this reversing valve 22, the measuring cylinder 2 is shown schematically in a Pipeline connected in series. A 4/2-way valve can be used as the switching valve 22 solenoid actuation on both sides can be used. The inlet is at port P. 24 of the pipeline to be measured: the liquid is connected while connected to the connection R of the continuing section 26 of the pipeline is. The connection A of the valve is connected to the connection 14 of the measuring cylinder and the Port B of the valve is connected to port 16 of the measuring cylinder.

In the illustrated switching position I of the reversing valve 22 flows the liquid through the connection 16 into the cylinder space 8 of the measuring cylinder, thereby the piston 4 is moved to the left until it reaches the one shown in dashed lines on the left End position reached. In this end position, the limit switch 18 emits a switching pulse from who about the a circuit to be described below Reversal of valve 22 into switching position II carries out.

The pressurized liquid arrives in this switch position into the connection 14 of the measuring cylinder 2 and displaces the piston 4 to the right until this reaches the right end position shown in dashed lines in the limit switch 20 in turn a switching pulse is triggered, via which the valve 22 again in the Switching position I is switched.

While from the line 24 each pressurized liquid into one of the two cylinder chambers 6 or

8 flows in, from this liquid via the piston 4 the liquid, which is located in the opposite cylinder space, via valve 22 in the power 26 displaced. It follows that the pressure of the inflowing liquid must be so great that the force exerted on the face of the piston 4 is greater than the piston friction in the measuring cylinder plus the force that is required in order to achieve the pressure specified there in line 26.

The limit switches 18 and 20 are limit switches that respond with high accuracy. This condition applies to field plate limit switches met with differential field plates. Here the achievable accuracy is 0.001 mm. However, other limit switches can also be used that are inductive or are capacitively effective.

A photo-optical arrangement can also be used as a limit switch, Hall generators can also be used as limit switches. Finally come changeover switches with mechanical actuation are also in question.

From the measuring cylinder, a quantity of liquid is in the with each stroke line 26 delivered, which corresponds to the stroke volume. For fine adjustment of this volume the distance between the control edges can be adjustable on the piston 4. This adjustment can expediently be filtered out through the end caps 10 and 12.

Carrying out the reversal of the solenoid-operated switching valve 22 and the display of the flow rate is shown below using the block diagram explained according to FIG.

The pulses emitted by the limit switches 18 and 20 are, if necessary given into a bistable switch 32 after amplification in amplifiers 28 and 30. This switch is preferably a bistable electronic switch. In the respective switching position is via this switch 32 in each case one of the two Solenoid coils 34, 36 are energized while the other solenoid is de-energized.

The reversing valve is reversed via the bistable switch 22nd

When one of the two limit switches 18 and 20 is triggered, over the bistable switch 32 or a pulse is given directly to a pulse control 38.

The circuit shown further comprises a reference base 40, which for example, can be designed as a time base or path base and accordingly either emits frequency-dependent or distance-dependent pulses. These impulses are possibly after Conversion in a frequency converter 42 given in a counter 44. The state of the Counter 44 can be transferred to a storage unit 46. This transfer is over the pulse control 38 effects. The counter 44 can be continuous or work discontinuously. In the case of discontinuous work, after each transmission of the counter reading in the storage unit 46 is a reset of the Counter 44 to zero. This reset takes place via one of the impulse controls 38 control pulse, which is followed by the transfer of the counter reading to the The impulse that triggers the storage unit is subsequently emitted with a time delay will.

The counter reading taken over is related in the storage unit 46 to the constant volume that take over from the Neßylinder 2 between two of Meter readings have been submitted and the result is displayed.

If a flow rate per unit of time is to be measured, is used as Reference base 40 uses a pulse generator operating at a constant frequency.

The pulse frequency of the generator 40 is used as a frequency divider trained frequency converter 42 is reduced to a frequency that is sufficient high resolution, i.e. in the present case a sufficiently high resolution Division of the time that the piston 4 in the measuring cylinder 2 at the lowest flow rate required for the path between its two end positions.

The liquid measurement is carried out as a continuous individual measurement of the liquid dispensed each time the piston travels back and forth. When responding of the limit switch 18, the magnet 34 is actuated via the bistable switch 32 and thus the valve 22 in the switching position II reversed. In order to the movement of the piston 4 from the left end position to the right end position initiated towards. The pulse control receives 38 simultaneously with the reversal a control pulse. The counter reading of the counter is then transmitted via the pulse control 38 44 taken over into the memory 46 and then the counter 44 is set to zero posed. The counter 44 then counts the over the frequency divider 42 into the Counter fed pulses until the piston 4 reaches its right end position has and via the limit switch 20 a pulse to switch the bistable switch 32 is given and at the same time a new control pulse in the pulse control 38 is given. It is then again the counter reading of the payment mechanism 44 in the memory 46 taken over and the counter itself then reset to zero. To Reversal of the switching valve 23 via the magnet 36 in the switching position The piston is then moved to the left again and the counter 44 counts again the pulses from the frequency divider 42 until another pulse from the limit switch 18 is delivered.

The frequency divider 42 can be designed so that the output Pulses are fractions, preferably decimal fractions, of seconds. Then got there when the counter reading is transferred from the counter 44 to the storage unit 46 the real time required for the specified amount of liquid to flow through has been. This time can then be directly expressed as time per amount of liquid, if necessary after multiplication or division on a liquid unit for display will. By inverting this value you get a display volume per Time unit. This display signal is because the Time summed up digitally as a digital signal that enables digital display. About a Digital / analog converter, an analog signal can be derived from the digital signal, this is then displayed in analog form via a pointer instrument or via a flow recorder can be registered. Let both the digital signals and the analog signals Of course, they can also be registered using magnetic recording media.

For the immediate display of average flow values, the a summation of the piston strokes and the individual times can be made. To do this Not having to use too extensive payment mechanisms could be part of the impulse control 38, a pulse counter may be provided, which the limit switches 18 and 20 emitted pulses are added. This counter could then be a separate one Be assigned time counter, count the further subdivided frequency impulses and in connection with the total volume. Via shift register the flow rate could be continuously recorded at a time preceding the reading time display a predetermined time unit.

On a zero position of the counter 44 at the beginning of each measuring stroke can be omitted if necessary, i.e. the counter 44 can continuously over the Count the counting area. In this case, the actual payment status was used are transferred to the storage unit 46. Since in the Speichen7erk 46 the previous Counter reading is saved, the actually required for the fleßhub Determine the time by subtracting it in the storage unit.

Above that suggested for the averaging of the flow The counter for the switchover pulses can be used simultaneously for mean value display or display the total flow in volume units without the mean value display. The device can thus be used at the same time for absolute volume measurement.

If a distance-dependent volume measurement is to be carried out, a travel-dependent pulse generator is used as the reference base. With path-dependent flow measurements of wheeled vehicles can use the existing Arrangement for the path recording the path-dependent working encoder for the speed measurement and distance measurement can be used. In many cases this will be achievable Pulse division is not sufficient to provide a sufficiently accurate indication. Man it is therefore advisable to connect a frequency multiplier downstream as a frequency converter. This can be designed in such a way that the pulses entered into the counter 44 are each decimal fractions of a distance unit. In this case it can be analogous the foregoing is the flow rate or consumption as a path per unit volume or volume show per distance unit. An averaging can also be carried out here and a total volume measurement. This total volume measurement could be in a motor vehicle can then be used at the same time as a reliable indicator of the tank volume.

If the device is installed in vehicles, the installation should be carried out as far as possible in such a way that accelerations of the vehicle have as little influence as possible have on the piston 4. A horizontal installation is transverse to the vehicle's longitudinal axis therefore recommended.

Instead of a reversing valve with solenoid actuation on both sides, a valve with one-sided solenoid actuation and return spring can also be used.

Claims (10)

Claims 1. Arrangement for measuring the flow of flowing media, in particular Liquids, through closed pipelines, characterized by a measuring cylinder (2) with a piston (4) dividing the measuring cylinder into two cylinder spaces, on both Ends of the Neßzyiinder arranged limit switches (18,20) and connections (14,16) for the medium to be measured, further through a solenoid-operated reversing valve (22) for the alternating connection of the connections with the inlet (24) and the outlet (26), switching means (52) for switching over the solenoid-operated reversing valve Depending on the response of the limit switches, a reference base emitting pulses (40), a payment device (44) for the pulses emitted by the reference base, a memory arrangement (46) in which, depending on the response of the limit switches the respective count of the counting device can be transmitted and by means for Processing and display of the counter reading transferred to the memory depending on the measuring volume of the measuring cylinder. 2. Arrangement according to claim 1, characterized in that as a reference base (40) a time base is provided. 3. Arrangement according to claim 1, characterized in that as a reference base (40) a path base is provided. 4. Arrangement according to claim 1, characterized in that as a limit switch (18,20) a non-contact electronic limit switch is provided. 5. Arrangement according to claim 4, characterized in that as a limit switch a field plate limit switch (18, 20) is provided. 6. Arrangement according to claim 1, characterized in that as switching means a bistable electronic switch (32) is provided for the reversing valve (22) is. 7. Arrangement according to claim 6, characterized in that the switch (32) with means (38) for controlling the transfer of the counter reading (44) into the Memory (46) is provided. 8. Arrangement according to claim 1, characterized in that means (38) are provided with which the counting device (44) after taking over the counter reading can be reset to zero in the memory (46). 9. Arrangement according to claim 1, characterized in that a counting device is provided for the pulses emitted by the end shell ': rn (18,20). 10. Arrangement according to claim 9, characterized in that means for counting detection pulses emitted from the reference base (40) for a plurality of the limit switches (18,20) emitted pulses are provided and that further MitteS are provided with which the pulses are displayed depending on one another to be brought.