DE408144C - Flow meter with an electrical display device - Google Patents

Description

Flow meter with an electrical display device. With electrical Flow rate measuring devices usually act the pressure difference between two points of the flow line on a liquid column of a U-shaped tube a, whereby the resistance of an electrical converter is reduced in such a way that that the current requirement of the latter is proportional to the flow rate. Here, the arrangement can be made in a known manner, (let as the secondary conductor and as the variable resistance of the converter, the variable U-shaped liquid column itself is used. The flow meter is then usable for both direct current and alternating current. In the first case the column of liquid acts as a simple ohmic resistance, in the second hall on the other hand as an inductive resistance. A column of liquid used in this way can therefore be used in a wide variety of circuits to change the total resistance of a current that influences reading instruc- tions can be used.

The invention now relates to such a flow meter and consists essentially in (let by special design of the transformer surrounding liquid space, the cross section of the liquid column serving as a secondary conductor is changed in a suitable manner, whereby it is achieved (let the rashes (nasty 1Teßinstruments (le-ii flow rates are proportional.

The subject of the invention is shown in the drawing in an exemplary embodiment illustrated. FIG. 1 shows a top section of the measuring device and Fig. 2 is a circuit diagram of the same. Fig. 3 is a diagram showing certain Relationships with regard to the effect and setup of the measuring apparatus illustrated. Fig. 4 is a section along the line E-E of Fig. I and Fig. 5 is a section the line F-F of Fig. 4, while Ahb. 6 the circuit diagram of the associated '\' attstun (lenniessers represents.

It denotes an annular base plate in which an annular space i i is provided, which forms one leg of a U-shaped tube. on a cover 13 is fastened to the base plate by means of screws 12, the tube of which 14. forms the other leg of the U-shaped tube. The tube 14 protrudes with his lower end 15 to pretty much the bottom of the plate i o and encloses one through Screws 17 finite the plate io attached plate 16. The plate 16 fills the lower end 15 of the tube 14 completely and is at its outer circumference with Grooves i ig provided, two of which can be seen in the drawing and through which the annular chamber ii with the parts of the tube located above the plate 16 1.4 is related. The two legs of the U-shaped tube, (l. H. Rauin i i and pipe 1.4 are therefore connected to one another by grooves 11. This serves to by the amount of the required operating fluid, e.g. B. mercury, as possible.

The tube 14 is provided with two mutually opposite longitudinal grooves 2o, while a transverse groove 21 is provided in the base plate 16 which opens into the grooves 20 at its ends. An L: rnformerkern 22 is inserted into the grooves 2o, which consists of three legs a, b, c, which in turn are connected at the top and bottom by the connecting pieces d and e. The outer legs a and c are guided in the grooves 2o and (the bottom piece e in the groove 21, so (the core 22 of the converter can be moved up and down in the tube 14. The middle leg 17 of the core 22 is from a primary winding 23 consisting of a number of wire turns insulated from one another, which is enclosed by sleeves 24 and 25 made of insulating material Lid and sleeves are expediently made of the same insulation material and can consist of one piece.

The core 22 consists of thin plates and, in order to allow the primary winding 23 to be easily pushed onto the middle leg of the core, there is a slight play 28 between the outer legs a, c and the inner leg 1). The outer legs of each sheet can then be bent to the side, if the middle leg is pushed into the sleeve 2 ...

The upper part of the core 22 is covered by a washer 2) provided with a bore 30 , which is provided with a pair of wings 31, which in turn are fastened to the lateral legs of the core 22 by screws 32. The head of an adjusting screw 33 is held in its position in the bore 30 by a plate 34 fastened to the plate 29 by bolts 35. The upper end of the tube 14 is closed by a cover plate fastened by bolts 37. In the middle of the cover plate 3G, a sleeve 38 is provided, with the thread 39 of which engages the thread of the adjusting screw 33. The outer end of the screw 33 protrudes through a stuffing box 40 and is provided with a square head 4.1 Screw 33, the core 22 with the primary winding in the tube 14 can be moved up and down, with the head of the adjusting screw 33 rotating in the bore 3. Between the sleeve 25 and (for the wall of the tube i.1, there is an annular chamber I_ provided, which forms the continuation (nasty U-shaped tube.

The wire ends 42 and 43 of the primary wich lui @ g 23 are through holes -.4 and .15 passed through. The wire end 42 is then from one Insulating tube 46 encased and connected to a clamping screw 5o, while the wire end .I3 is connected to the housing by means of a connecting line. At the Cover plate 36, a clamping screw 53 is provided for the ground fault.

A pressure line 54 opens into the chamber, and another pressure line 5j ati (with pipe 1d connected. These lines 54 and 55 are, as can be seen from Fig , which is installed in a line 56 through which a gaseous or liquid medium flows. The pressure difference which is established on both sides of the measuring nozzle changes with the otiadrate of the flow rate flowing through. Mercury, and forms a self-contained secondary winding of the converter. The ends .I2 and .a.3 of the primary winding 23 are -in an alternating current source of constant voltage either directly or, as shown in Fig.2, connected through a converter 6i. Here In the circuit there is a regulating resistor 62, watt-hour meter 63. Ammeter 64., a recording device 65 and an unchangeable resistor 6 6 provided. -In use, an appropriate amount of liquid, e.g. B. mercury, introduced into the Rauin ii and the Umforinerkern 22 adjusted by screw 33 such that the upper surface of the lower part e is at the same level with your level of the liquid, in such a way that the leg of the liquid ring is not completely interrupted and the instruments show no power. This occurs when the amount of agent flowing through line 56 is zero and the pressure is the same in the two legs of the device. In this case, as a result of the excitation and the loss of the core, a weak current will pass through the primary winding and through the liquid in the measuring apparatus. The indicating ammeter 64 and the registering device 65 are set so that they are in the zero position. Also with regard to the wattmeter, the device is made so that it is prevented from rotating in this case. This can e.g. B. can be achieved by switching on a counter coil to the current coil of the wattmeter, the current of this counter coil can be regulated by an adjustable resistor in such a way that da_ #; Wattmeter is prevented from rotating. A circuit diagram relating to this is shown in Fig. 6, where 66 denotes the voltage coil & of the wattmeter, 67 denotes the current coil, 68 denotes the counter coil and 69 denotes the regulating resistor.

When a stream of a liquid or gaseous medium passes through the Line 56 flows through, so there is a pressure difference in front of and behind the nozzle 54 a, which through the lines 54. and 55 the two legs of the U-shaped Rohres is communicated and causes the level of the liquid 58 in the room to drain i i decreases, in the annular chamber L in the pipe 1d: however, increases. When the liquid increases in chamber L, the volume of the enclosed liquid coil increases, which represents the short-circuited secondary coil of the converter and its resistance decreases, so that more Stroin will flow through the primary circuit, which, as already discussed, a function of the amount flowing through conduit 56 Gas or liquid flow should be. Ammeter 64 and chart recorder 65 can be arranged to directly flow through the conduit 56 Expressing sets or specifying functions of them.

With regard to the wattmeter, when determining the amount of gas or liquid flowing through the line 56, it is necessary that a rise in the liquid level in the vertical chamber causes a corresponding change in the current in the primary transformer, expressed in watts, the wattage being proportional to the oti-square root the height of the liquid: eitss <ittle, since the pressure difference created by the nozzle 57 is proportional to the square of the delivery rate flowing through the line 56. Or if the flow rate flowing through the line 56 with TI changes with the square root of the pressure difference H that changes upstream and downstream of the nozzle 57, then the watts II "consumed in the primary transformer must change finitely with the square root H if they are in values h are to be expressed. -in Fig. 3 ("denotes the square root curve, which is obtained by plotting the corresponding values L 'and H. In the same diagram, line.4 was created by plotting the corresponding values of W and H, where the primary circuit has a negligible resistance and the chamber in which the liquid coil, which forms the secondary transformer, rises, is arranged vertically and of constant cross-section. If B is now to be expressed in terms of L ', the line must be changed in this way that it becomes equal to the curve C. This can be achieved by the fact that the chamber in which the fluids Coil moves, has a variable cross-section, so that when the values B and FI are plotted, all points fall within curve C, which expresses that '. with H changes. It has been found, however, that this leads to a substantial change in the shape of the chamber, so that it is more advantageous to coincide the line with curve C at the same time by changing the cross-section of the chamber and introducing a certain resistance into the primary circuit of the transformer bring to.

The current flowing through the primary transformer is passed through the gleiclitin expressed, where F_ is the assumed constant voltage of the primary current, R1 the resistance of the primary circuit and R, the corresponding resistance of the secondary circuit.

If the chamber for the liquid secondary coil is of constant average length and is vertical, then the corresponding resistance R i of the secondary transformer is inversely proportional to the word H, as expressed by the line A. and this introduced into the above equation gives If E and R, are constants in this equation, then line.-1 can be changed to curve B by appropriate selection of the value R1 and by subtracting the values TI 'and H. Curve B does not, however, finitely agree with curve C, but approaches it in all points and can be brought into agreement finitely with it by correspondingly changing the cross section of the chamber L in which the secondary liquid coil moves.

In the present case a resistor (i6 according to Fig. 2 is provided, which added one to the other resistors of the primary circuit The value of Hl shows that curve B is produced.

The size of the liquid chamber L is changed by changing the outer shape of the sleeve 25 changed so that the curve B in accordance with the curve C is brought. By choosing the primary resistance R1 and a corresponding one Shaping of the chamber L is achieved that ff 'changes immediately with H and that the wattmeter 63 can be tuned in such a way that it ranges from sizes to in values expressed by V indicates.

Of course, a different curve B results for each value of Hl can easily be determined by experiment and calculation. For different B curves therefore, corresponding changes to the dimensioning of the chamber L are required, to bring the B curve into line with curve C.

The adjustable resistor 62 is provided for the purpose of by Change in the resistance of the external primary transformer circuit through the compensate the differences caused by the wire connections. After installing the Apparatus can determine the exact primary current resistance R1 by setting the resistance 62 can be set.

Claims (1)

PATENT CLAIM Muzzle flow meter with electrical display device, in which the liquid of the [) -manometer is a short-circuited secondary winding of a Converter is used, characterized in that the liquid space surrounding the transformer has different cross-sections at different heights in a manner known per se, to make the deflections of the measuring instrument proportional to the flow rates are.