SU754291A1 - Liquid volumetric resistance indicator - Google Patents

Description

The invention relates to instruments for measuring (signaling) the volume resistance of liquids and can be used, for example, in water treatment systems of power plants, water deionization systems in the electronics industry, ⁵ while monitoring the condition of the refrigerant in REA cooling systems.

Known meter (alarm)

contact resistance

PA, for example, a concentratometer containing a bridge circuit and a sensor consisting of two immersed electrodes.

However, it is not accurate enough in measurement.

The closest technical solution to the proposed device is a contact meter bulk resistance, comprising a pipeline with a nipple, inside which is placed a HA _m ruzhny electrode with slits is rigidly connected with the internal electrode, wherein the thermistor is integrated, and electron-bridge circuit [2].

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The disadvantages of this device are large errors when working on gas streams associated with the creation of air bubbles in the interelectrode space, and temperature

, the error associated with low intensity of heat transfer between the medium being measured and the thermal compensator embedded in the internal electrode.

The purpose of the invention is to improve the measurement accuracy on gas streams with varying temperature.

This goal is achieved by the fact that the outer electrode of the detector is flexibly connected to the nozzle, has symmetrical straight cuts at an angle of ± 70 100 to the direction of flow, and its axis is displaced with respect to the axis of the internal electrode, and the nozzle on the immersion part has a protrusion G forming a narrowing for flow.

FIG. 1 shows the device, a general view; in fig. 2 shows section A-A in FIG. one.

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754291

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The warning device is a single structure consisting of the housing 1 of the warning device, inside which the electronic-bridge circuit 2 is located and the power supply and signaling connector 3 is installed. The body of the detector is rigidly connected to the carrier fitting 4, which has submersible figured projections 5. Inside the fitting, with the aid of a bellows 6, an outer electrode 7 is fixed, having

areas of midal section (at an angle

70-100 °) symmetrically arranged to the axis of the Flow straight slots 8.

Inside the outer electrode on the insulating sleeve 9 is fixed the inner electrode 10, the axis of which is offset relative to the axis of the outer electrode (along the flow).

Inside the internal electrode 10 there is a compensating thermoresisor 20 tor 11. With the help of switching wires 12 through a sealed connector 13, the electrodes and the thermistor are connected to an electronic-bridge circuit. With the help of the carrier fitting 4 and the boss 14, the signaling unit 25 is mounted on the pipeline 15, in which the measured flow has direction 16.

The location of the details of the detector inside the pipeline 15 is shown in FIG. 2, where 17 - the vortices formed during the flow around the flow of the outer electrode 7.

The detector works as follows.

When a flow 16 appears in the pipeline 15, the latter is compressed by means of shaped protrusions 5, which creates an increased local flow rate in the gap between the projections and the outer electrode 7. When the electrode flows around the back, eddies 17 are set, alternately detached from the electrode in the areas of the slots eight.

Since in the region of the vortex in the liquid creates a zone of reduced pressure, the flow pushes the electrode in the direction of the vortex. After the breakdown of the vortex on one side of the electrode, Exactly such a vortex forms at its other side (at the other slit) and the electrode is pushed back by the flow.

When the vortex breaks off alternately, the electrode oscillates and if its parameters are chosen for resonance, its oscillations have a significant amplitude, especially since the flexible mounting of the electrode 6 in the choke 4 by means of the bellows 6 ensures that such a resonance occurs easily.

In addition, a pulsating flow with a frequency equal to the oscillation frequency of the electrode arises as a result of the breakdown of the vortices and alternate change of the zones of low and normal pressure in the gap between the electrodes. Since the axes of the electrodes are offset relative to each other, the resistances of the channels between the electrodes from the slot to the slot (along the large and small arc around the internal electrode) are equal and in the areas of the interelectrode space, the velocity of the pulsating flow is high and there are no stagnant zones. It is obvious that the intensive oscillation of the electrode system provides, firstly, the detachment from the electrodes of the bubbles deposited on them before the flow and their ejection from between the electrode space, pushing away the bubbles transferred by the flow from the outer electrode and excluding their entry into the interelectrode space, and secondly, the pulsating flow in the interelectrode space b creates an intensive heat exchange between the internal electrode

(in which there is a compensating thermistor) and the flow, which eliminates errors due to the inertia of the compensating circuit of the detector.

The volume resistance signal from the electrodes 7 and 10 and the temperature compensation signal from the thermistor 11 with the help of switching wires through the sealed connector 13 are fed to the electronic bridge circuit 2, and the output signal from the electronic circuit through the power connector 3 is fed to the automation circuit to signal the volume level resistance in a flowing stream 16.

The proposed detector provides high measurement accuracy on gas streams and streams with rapidly changing temperature through the use of vibrational oscillations of the electrode system and due to the presence of a pulsating flow in the interelectrode space, provided by the kinetic forces of the flowing stream.

Claims (1)

Claim Bulk resistance detector liquids containing pipeline with fitting, inside which is placed the outer electrode with slots, rigidly associated with the internal electrode, in 754291 An electromotor incorporates a thermistor resistor, and a Ron-bridge circuit, which is designed so that, in order to improve the accuracy of measurement, the outer electrode is flexibly connected to the nozzle and provided with symmetrical straight slots at an angle of 70-100 ° to the direction flow, and its axis is offset with respect to the axis of the internal electrode, and the coupling on the immersed part has protrusions that form a constriction for the flow. ten