DE2128750A1 - METHOD AND DEVICE FOR MEASURING THE FLOW OF LIQUID MEDIA - Google Patents

Description

Description of the patent application of Regarding method and device for flow measurement of liquid media.

The present invention relates to a flow measurement method for liquid media and facilities for its implementation.

Eo flow measurement methods for liquid media are known that are based on the change in the nature of a swimmer in a stream of control fluid are based.

In the known method, the position of the swimmer is changed determined by inductive coupling between the float and a recorder.

There are facilities for flow measurement of liquid medium known who realize the said method These bodies contain a rotametric tube with a float, the location of which is a function from a flow rate of the liquid flowing through the rotametric tube Control medium changes.

In the case of the above-mentioned facility which implements the above-mentioned method are on the rotametric tube three with each other inductively coupled and in a measuring bridge circuit with a contact wire lying coils set, wherein the latter with the help of a phase-sensitive device with an electric motor is automatically matched.

The ones in the edge coils when an alternating current flows over the middle one Coil induced electromotive force is proportional to the coupling factor of the coils, its size depends on the position of the made of a ferromagnetic material Depends on the float.

This leads to the establishment of the above-mentioned method the necessity of making one resistant by a counter-aggressive media Protected float cover made of ferromagnetic material to increase weight of the float and to limit the range of the flow rates to be measured, while the need to manufacture the rotametric ear from a non-magnetic one Material defines the area of application for the flow measurement methods mentioned considerably restricted by liquid media.

In addition, these facilities have to implement the aforementioned Process a small range of flow rates to be measured because of the location of the swimmer is only registered if he is within the effective range the coil fields is located. Here it is impossible for the swimmer to jump after a jump Change in flow rate automatically in the zone of the magnetic field Start the bobbins.

The purpose of the present invention is to overcome the aforementioned shortcomings.

The invention is based on the object of a flow measurement method for liquid media to develop a remote transmission of the position of the float secures in a stream of the liquid control medium, and means for performing of the process mentioned, the construction of which enables the location of the float in the rotametric tube.

This task is solved in that one on the change of the position of the float in a flow measurement method which constitutes a stream of the liquid control medium for liquid media according to the invention in the direction of the swimmer an acoustic Signal sent, an acoustic signal reflected by this received and after the time interval between the broadcast and, which characterizes the position of the swimmer the flow rate upon receipt of the acoustic signal of the to be controlled liquid medium is determined.

In a device for measuring the flow of liquid media, at which the said method is implemented, and which has a rotametric tube Contains a float, whose position is dependent on the one determined by the rotametric Tube changing flow rate of the liquid control medium is according to the invention provides an electroakastscher converter on one of the end faces the rotametric tube is arranged and periodically emits an acoustic signal and receives an acoustic signal reflected from the swimmer and one with the electroacoustic transducer electrically coupled electronic unit that has a Contains pulse generator and a time interval measuring device, the two with the electroacoustic transducer are electrically coupled, as well as one with these electrically coupled synchronizer for electrical signals, the.

Pulse generator at the moment of emitting an acoustic Signal controls through the electroacoustic transducer and the time distance measuring device triggers before an acoustic signal reflected by the swimmer on the electroacoustic transducer Signal has arrived.

To ensure reliability, durability and low In terms of size of the device, it is expedient to use the pulse generator in the form of a transistor from% uffahr, at its collector - base - Ubergallg the electroacoustic converter and the storage capacity are connected in series, while on the emitter-base transition via your adjustment stage the synchronizer for electrical signals is connected.

The time interval measuring device can be implemented in the form of a transistor be, at the emitter - base - junction one to the base of the transistor from electroacoustic transducers normalizing signals to the front and duration Tunnel diode and its emitter-collector junction via a matching transformer one of the inputs of a flip-flop is connected, the other input is electrically coupled to the electrical signal synchronizer.

Thanks to the flow measurement method according to the invention for liquid media and its constructive solution it is possible to use the float and the rotametric Tube made of both magnetic and non-magnetic material with a Remote display of the position of the float regardless of its position in the rotametric Manufacture tube, thereby increasing the range of the flow rate to be controlled by liquid media and a continuous automatic measurement of the flow rate of liquid media in the event of sudden changes in the flow velocity will.

The invention is intended below with reference to the description of a concrete one Embodiment and the accompanying drawings are explained in more detail. It Fig. 1 shows the overall scheme of the proposed method realizing Device for measuring the flow of liquid media; 2 shows the basic circuit diagram a pulse generator of the proposed device for flow measurement of liquid media; 3 shows the basic circuit diagram of a time interval measuring device the same device, and FIG. 4 shows the principle circuit diagram of a synchronizer for electrical signals from the same facility.

The device according to the invention for measuring the flow of liquids Media that use the proposed method for measuring the flow of liquid media realized, contains a rotametric tube 1 (Fig. 1) made of glass with one from stainless steel made float 2, the position of which is a function of the flow rate of the fluid control medium passing through the rotametric Tube 1 ström @. The rotametric tube 1 and the float 2 can both ausd a magnetic material rather than a non-magnetic material.

The device contains one on one of the end faces 5 of the rotametric Tube 1 arranged electroacoustic transducer 4 and one coupled to the transducer 4 electronic unit 6 In the embodiment shown, the electroacoustic Converter 4 on the lower face 5 and sends or receives a reflected by the swimmer 2 acoustic signal.

The electronic unit 6 includes a pulse generator 7, a Time distance measuring device 8 and a synchronizer electrically coupled to this 9 for electrical signals.

The pulse generator 7 and the time interval measuring device 8 are on the electroacoustic transducer 4 is connected directly. The synchronizer 9 controls the pulse generator 7 at the moment of emission of the acoustic Signal through the electroacoustic transducer 4 and triggers the time distance measuring device 8 off until an acoustic signal reflected by the float 2 is transmitted to the electroacoustic Converter 4 has arrived.

The pulse generator 7 (Fig. 2) is designed in the form of a transistor 10, at the collector-base junction of the electroacoustic transducer 4 with a Inductor 11 and a storage capacitor 42 are connected in series while to the emitter-base junction via a resistor 14 and via a capacitance 15, which form a differentiating circuit, an adaptation stage 13 is connected. The resistor 16 represents a collector load of the transistor 10.

The matching stage 13 contains a transistor 17, a matching transformer 18 and one from a resistor 19 and a separation capacitance 20 existing emitter - base circle.

The terminal 21 is used to connect the synchronizer 9 for electrical Signals and the terminal 22 for the connection of the time distance measuring device 8.

The time interval measuring device 8 (Fig. 3) is in the form of a transistor 23 executed, at the emitter - base junction one to the base of the transistor 23 from the electroacoustic transducer 4 signals coming from the front and duration normalizing Tunnel diode 24 and its emitter-collector junction over a matching transformer 25 with a bypass diode 26 and an isolating capacitance 27 of one of the inputs a flip-flop 28 is connected, the other input by means of a terminal 29 is electrically coupled to the synchronizer -9 for electrical signals.

The resistor 30 together with the secondary winding of the transformer 25 represents a KJllektorload the transistor 23 is.

The resistors 31 to 33 are used to supply and regulate voltage at the tunnel diode 24, the inductance 34 is used to form a current pulse in the circle of the tunnel diode 24. The resistor 35 represents a decoupling circuit between the electroacoustic transducer 4 and the tunnel diode 24.

The flip-flop 28 is made up of transistors 36 and 37 with symmetrical Coupling circuits made up of resistors 38, 39 and capacitors 40, 41 and with bias circuits from resistance 42 to 46 together. The capacity 47 bridged the resistance 46.

The synchronizer 9 (Fig. 4) includes a transformer 4d, whose Primary winding to an alternating current network and its secondary winding to diodes 49 and 50 and connected to a voltage divider consisting of resistors 51 to 53 is.

Diodes 49 and 50 and the center tap of resistor 52 are to one in the form of a four-layer diode 54 te uncontrolled diode with the by a resistor 56 bridged primary winding of the transformer 55 as Load connected.

The secondary winding of the transformer 55 is via an isolating capacitance 57 connected to a blocking oscillator 58.

The blocking oscillator 58 has a transistor 59, on the emitter of which - Base - transition an isolating capacitance 57 and one from the primary winding of a transformer 60, a capacitance 61 and a resistor 62 existing forming circuit connected are, while to the collector, the secondary winding of the transformer 60 with a connected to it diode 63 is coupled. The third dedication of the transformer 60 is connected to a voltage divider consisting of resistors 64 and 65.

To terminal 21 between the third winding of the transformer 60 and the opponent 64 is the adjustment stage 13 of the pulse generator 7 and to the terminal 29 between the resistors 64 and 65 one of the inputs of the Flip-flops 28 of the time interval measuring device 8 are connected.

The device realizing the flow metering process for liquid media works as follows: The one arranged on the lower end face 5 of the rotametric tube 1 Elektroakustiscbe transducer 4 (Fig. 1) sends periodically and receives a from the float 2 reflected acoustic signal that is reflected in the through the rotametric tube 1 (in the direction of arrows A and B) propagating liquid medium flowing, a the electroacoustic transducer 4 triggering electrical signal comes from the electronic Unit 6 and egg triggered by the acoustic signal reflected by the swimmer 2 electrical signal from the electroacoustic transducer 4 comes into the electronic Unit 6.

The electrical triggering the electroacoustic transducer 4 (FIG. 2) Signal is generated by the pulse generator 7, in which the collector - base --Transition of the transistor 10 and via the electroacoustic transducer 4 with him adjoining inductance 11, the discharge of the storage capacity 12 takes place.

The storage capacity 12 is from the supply source via the resistor 16 charged and after switching through the transistor 10 by one of the synchronizer 9 via the adaptation stage 13 discharging the incoming impulse.

The electrical signal from the electroacoustic transducer 4 occurs the time interval measuring device 8 (Fig. 3) via the terminal 22, where it is to the front and duration normalized with the aid of the tunnel diode 24 with the inductance 34 and is amplified by the transistor 23 with the matching transformer 25, of which the signal via the isolating capacitance 27 to one of the inputs of the flip-flop 28 got.

The synchronizer 9 (Fig. 1) converts the sinusoidal voltage into the pulse generator 7 and the Zeitabstgldsmeßeinrichtung controlling electrical pulses around. The sinusoidal voltage from transformer 48 (Fig.4), its primary winding is connected to an alternating current network, is transformed and comes from the Secondary winding to which the alternating voltage in a four-layer diode 54 triggers pulsating single-phase voltage converting diodes 49 and 50.

The amplitude of the voltage coming across diodes 49 and 50 becomes balanced with the help of resistors 51 to 53. The pulse comes from the four-layer diode 54 via the transformer 55 bridged by the resistor 56 and the isolating capacitance 57 to the blocking transducer 58.

Ier blocking oscillator 58 generates normalized electrical signals that via terminal 21 to the pulse generator 7 and via terminal 29 to the time distance measuring device 8 meet.

The pulse of the synchronizer 9 (Fig. 1) controls the pulse generator 7th at the moment when an acoustic signal is emitted by the electroacoustic one Converter 4 and at the same time displaces the flip-flop 28 (FIG. 3) of the time interval measuring device 8 into one of the stable states, in which it remains until the electroacoustic Transducer 4 receives an acoustic signal reflected by float 2, according to the time interval between the swimmer, which characterizes the position of the swimmer Sending and receiving an acoustic signal the flow rate of the liquid Control medium is calculated.

Those realizing the proposed flow measurement method for liquid media The device ensures remote transmission of the swimmer's position indicator in the rotametric tube, all measuring properties being retained and can be used in an automatic flow control system be used. The automatic control works reliably in the event of severe disruptions the flow of the control liquid medium.

The transistorized electronic unit of this device secures a high reliability of the present device, so that it extends over several Runs continuously for months.

Claims

Claims (4)

Claims 1. Durchflußmeßverfahren for liquid media, the on changing the position of a float in a stream of the control fluid medium is based on the fact that the swimmer is in the exercise of the swimmer an acoustic signal is sent, an acoustic signal reflected by this received and in accordance with the 7: elapsed time that characterizes the position of the swimmer the flow rate between the transmission and the reception of the acoustic signal of the liquid control medium is determined. 2. Device for performing the method according to claim 1, with a rotametric ear with a swimmer, whose position is dependent on the flow rate of the control liquid medium flowing through the rotametric tube changes, d u r c h e k e n n n z e i c.h n e t, that they are with one at one of the End faces (5) of the rotametric tube (1) arranged and periodically an acoustic Emitting signal and an acoustic signal reflected by the float (2) receiving electroacoustic transducer (4) with one with the electroacoustic Converter (4) electrically coupled electronic unit (6) containing a pulse generator (7) and a time distance measuring device (8), each with the electroacoustic Converter (4) are electrically coupled, as well as with one electrically coupled to these Synchronisttor (9) is provided for electrical signals, the Pulse generator (7) at the moment when an acoustic signal is emitted by the electroacoustic signal Converter (4) controls and the time distance measuring device (8) triggers before the electroacoustic Transducer (4) received an acoustic signal reflected by the float (2) is. 3, device according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that the pulse generator (7) is designed in the form of a transistor (10) is, at the collector-base junction of the electroacoustic transducer (4) and a storage capacity (12) connected in series while connected to the emitter - Basis - transition via an adaptation stage (13) der.Synchronizer (9) for electrical Signals is connected. 4. Device according to claim 2 and 3, d a d u r c h g e -k e n n z e i c h n e t that the time distance measuring device (8) is in the form of a transistor (23) is designed, at the emitter - base junction of a to the base of the Transistors (23) from the electroacoustic transducer (4) signals coming to the front and duration normalizing tunnel diode (24) and at its emitter-collector junction Via a matching transformer (25) one of the inputs of a flip-flop (28) is connected, the other input to the synchronizer (9) for electrical Signals is electrically coupled. L e r s e i t e