LT6005B - Method and device for sum-frquency generation of light pulses. - Google Patents

Abstract

This invention relates to the field of laser technology and more particularly concerns to the sum-frequency generation method, where laser pulses are combined by adding their optical frequencies in a second-order nonlinear medium. In order to increase energy of generated sum-frequency pulses or to generate shorter sum-frequency pulses than initial light pulses, the initial light pulses are directed to the input side of the second-order nonlinear medium in pairs or one by one. First light pulse of a pair or first part of the single light pulse, passes through the nonlinear medium without taking part in a nonlinear interaction and then it is returned and directed to the input side of the same second-order nonlinear medium. Propagating for the second time though the second-order nonlinear medium first light pulse of a pair or first part of the single light pulse overlaps with second light pulse of the pair or second part of the single light pulse, respectively, propagating through the second-order nonlinear medium for the first time, and satisfying the phase-matching conditions, the effective nonlinear interaction takes place between overlapping light pulses or parts of the single light pulse, respectively, propagating for the first and second time through the nonlinear medium, where they are combined to a sum-frequency light pulse.

Description

The invention relates to a method for measuring the level of an electrically conductive liquid and to a device where the level measurement is based on the measurement of the conductivity of the liquid to the electric current.

There are many methods and devices known for their function and design for measuring the level of a fluid. One of the groups of liquid level gauges is when the measurement is based on the conductivity of the liquid being measured.

One group of this type of gauge only determines whether the water level is higher or lower than the set, i.e. acts only as a discrete transducer for two (or more) positions (CN2485633, TVV390983).

Devices that measure the water level in a tank and give a result in percent or height units often use three or four electrodes, one or two of which is called an excitation voltage (can be constant or alternating) and reads from the other or other electrodes. voltage resulting from water conductivity (resistance) that is proportional to the water level (CN101025371, US7343798). These devices have a sophisticated circuitry required to convert scanned signals into a signal proportional to the water level.

JP6317449 (A) discloses a fluid level meter having a fluid level detection portion consisting of three submerged electrodes, one electrode being a high-voltage signal electrode, the second electrode being a reference electrode, and the third electrode being a fluid level electrode. setting electrode. Said signal and support electrodes are immersed in the measuring liquid at all times during the measurement, and their lower ends are located in the lower part of the liquid to be measured, and the lower end of the liquid level measuring electrode is located in the upper part of the liquid to be measured. The high-frequency voltage is fed to the signal electrode, and the detected voltage on the reference and fluid level electrodes is fed through respective matching circuits to the respective inputs of the voltage comparator, the output of which is proportional to the level of the liquid being measured in the vessel.

A known meter requires three electrodes, a high-frequency voltage source, and an analog circuitry to amplify, detect, and convert the measured signal to the measured liquid level, which makes the meter complicated and expensive.

The present invention aims to simplify the method and apparatus for measuring the level of an electrically conductive fluid, and to improve the accuracy of measurement.

In the method of measuring the level of an electrically conductive fluid according to the present invention, wherein the fluid level is determined by the conductivity of the liquid to be measured by means of a dip electrode, one being a reference electrode and the other a detection electrode, and the immersion of all of the immersed liquid in contact with said liquid to be measured and the detection electrode immersed in said liquid such that the contact area of said liquid changes with the level of liquid in said vessel, and one cycle of measuring the level of electrically conductive liquid in the vessel the following sequence of operations:

- rapidly charging the first capacitor to a voltage U1 from a constant voltage power supply, then slowly discharging said first capacitor to a set voltage U2 through a reference electrode and a liquid in the vessel, further the measuring circuit calculates the first capacitor discharge time T1 from voltage U1 to voltage U2; prepares capacitor C1 for the next measuring cycle by discharging it to zero voltage, then rapidly charging a second capacitor to voltage U1 from a constant voltage power supply, slowly discharging said second capacitor to a specified voltage U2 through the detection electrode and the liquid in the vessel; capacitor discharge time T2 from voltage U1 to voltage U2, and capacitor C2 prepares for the next measurement cycle by discharging it to zero voltage, then calculates the respective capacitors discharge times T1 and T2 in the measuring circuit the measured conductivity of the liquid to be measured is S1 and S2 and, having evaluated their ratio, determines the level of the electrically conductive liquid to be measured in the vessel.

The measuring fluid may be distilled water. The liquid level in said vessel may be calculated by a measuring circuit according to the formula Lx = L0 + LA * S2 / S1, where L0 is the distance from the lower end of said electrodes to the bottom of the vessel using uniform rod-shaped electrodes with lower ends spaced LO the length of the bottom electrode of said vessel, LA, immersed in the liquid to be measured. The said first and second capacitors charge in about a few microseconds and discharge in about 0.1 to 100 milliseconds, depending on the conductivity of the fluid being measured.

To achieve the object of the present invention, there is provided an embodiment of the present invention, wherein an electrically conductive liquid level gauge comprising reference and detection electrodes immersed in a vessel with the level to be measured and a measuring circuit that determines the level of the liquid in the vessel according to the conductivity of said liquid. for the electric current, the reference electrode is completely immersed in said liquid to be measured and does not change its surface area in contact with the liquid to be measured and the second electrode is soaked in said liquid that the surface area in contact with said liquid changes with electrically conductive material and is grounded while said reference and detection electrodes are respectively connected to the first and second capacitors of the first electrodes, the second electrodes of which are grounded, said capacitors are connected to a direct voltage U1 a device for loading them through a control device designed to control the charging and discharging of said capacitors by first charging the first capacitor to voltage U1 and then discharging it through the support electrode and the measuring fluid in the vessel to voltage U2 and then charging the second capacitor to voltage U1 and discharge it through the detection electrode and the measuring fluid in the vessel to voltage U2 where the measuring circuit is constructed:

- comparing the voltage on said first or second capacitor electrodes with a set reference voltage U2 which, when reached, would emit a signal terminating the discharge of the respective first or second capacitor,

- calculate the discharge times T1 and T2 of the first and second capacitors from voltage U1 to voltage U2

- calculate the conductivity S1 and S2 of the liquid to be measured, and determine the level of the electrically conductive liquid to be measured in the ratios, based on the time periods T1 and T2, respectively, of said discharge and detection electrodes and the measuring fluid, respectively.

Preference is given to an embodiment of the present invention, wherein the first and second electrodes are equal bars of small thickness, the lower ends of which are spaced equally from the bottom of the vessel.

The proposed method of measuring the level of electrically conductive fluid and the meter are characterized by measuring accuracy and simplicity of construction. The measurement of the electrical conductivity of a liquid by reference and detection electrodes is performed at different times and therefore does not introduce additional errors due to interactions between the electrodes during measurement. In addition, the liquid level is determined by evaluating the ratio of the measured conductances, so the accuracy of the measurement is not affected by the absolute conductivity of the liquid, which depends on the temperature and the amount of impurities dissolved. The measurement requires only two electrodes and a constant voltage power supply, making the meter simple to construct,

A further embodiment of the present invention will be explained in more detail in the drawings, wherein

Fig. 1 is a block diagram of a proposed electrically conductive liquid level gauge.

FIG. 2 illustrates the voltage variation on any of the capacitors during charging and discharging.

Fig. 1 shows a gauge of an electrically conductive liquid 1 contained in a vessel 2, having two parallel electrodes, a support electrode 3, and a detection electrode 4, which are immersed in the liquid during operation. The upper part 5 of the support electrode 3 is insulated and the lower one is uninsulated. part 6 of length LA is immersed in liquid 1 during operation and does not change its surface area during contact with liquid 1 during measurement. The reference electrode is used to measure the conductivity of fluid 1. The detection electrode 4 is immersed in the liquid so that its surface area in contact with the liquid 1 varies with the fluid level in the vessel 2 and is used to measure the fluid level. The vessel 2 is made of electrically conductive material and is earthed. The electrode 3 is connected to a single electrode of the capacitor 7, the other electrode of which is grounded. The electrode 4 is connected to a capacitor 8 with one electrode, the other electrode of which is grounded. The meter has a measuring circuit 9 comprising integrated control units 10, comparators 11 and 12, counters 13 and 14 and a computer data processing unit 15. Capacitors 7 and 8 are connected to a constant voltage U1 power supply 16 via control unit 10. consisting of two pairs of transistors, namely 17 and 18 and 19 and 20. wherein one transistor of the same pair is connected to a constant voltage U1 power supply and the other to a zero voltage supply. Said transistors are controlled by a data processing device 15. The reference electrode 3 coupled to the capacitor 7 is connected to one of the inputs of the comparator 11, the other input of which is supplied with a reference voltage U2. The detection electrode 4 is connected to a capacitor 8 and connected to a single input of comparator 12, the other input of which is supplied with a reference voltage U2. The outputs of the comparators 11 and 12 are connected to respective counters 13 and 14 for calculating the discharge times T1 and T2 of the capacitors 7 and 8, the outputs of which are connected to a computer data processing unit 15 for calculating the conductivity and level of the liquid in vessel 2. The measured fluid may be distilled water.

One cycle of measuring the water level according to the present invention comprises the following sequence of operations. The data processing device 15 opens the transistor 17 through which the capacitor 7 is quickly charged from the DC voltage source 16 to the voltage U1 within a few microseconds. The transistor 17 is then closed and the counter 13. The capacitor 7 is slowly discharged through the support electrode 3 and the liquid 1 in the vessel, depending on the conductivity of the fluid, over a period of about 0.1 to 100 milliseconds, its voltage being transmitted to the comparator 11, and counter 13 counts the discharge time of capacitor 7. When the voltage on the capacitor 7 equals the reference voltage U2, the output signal of the comparator closes the counter 13 and its calculated discharge time T1 of the capacitor 7 from the voltage U1 to U2 is transmitted to the data processing unit 15. The transistor 18 is opened. voltage. The transistor 19 is then opened through which, from a constant voltage source 16, the capacitor 8 is rapidly charged analogously to a capacitor 7 to a voltage U1. The transistor 19 is then closed and the counter 14 is energized. The capacitor 8 slowly discharges through the support detection electrode 4 and the liquid 1 in the vessel, the voltage on the capacitor 8 is transferred to the comparator 12, and the counter 14 counts the discharge time of the capacitor 8. When the voltage on the capacitor 8 equals the reference voltage U2, the output signal of the comparator 12 closes the counter 14 and calculates the discharge time T2 of the capacitor 8 from the voltage U1 to U2 to the data processing device 15. The transistor 20 is opened. . The computer data processing unit 15 calculates the conductances S1 and S2 of the liquid, respectively, based on the calculated discharge times T1 and T2 of the capacitors 7 and 8 and determines the ratio of the water level in the vessel 2 at that time. The water level Lx can be calculated by the formula Lx = L0 + LA * S2 / S1, where L0 is the distance from the lower end of said electrodes to the bottom of the vessel using uniform rod-shaped electrodes with the lower ends spaced from the bottom of said vessel , LA is the length of the reference electrode 3 immersed in the liquid to be measured.

The measuring cycle described may be repeated analogously at any desired time. Since the contact surface of the reference electrode 3 with the liquid is constant i.e. is independent of the level of the liquid in the vessel, the calculated conductivity S1 will also be constant at any other measurement cycle. Meanwhile, the contacting surface of the detection electrode 4 with the liquid varies with the level of the liquid in the vessel, thus changing the impedance circuit impedance of condenser 8 and its conductivity S2, calculated from capacitor 8 discharge time T2 and directly proportional to the liquid level.

Claims (6)

DEFINITION OF INVENTION 1. A method of measuring the level of an electrically conductive fluid, the fluid being determined by the conductivity of the liquid to be measured by means of a dip electrode, one of which is a reference electrode and the other a detection electrode and calculated by a measuring circuit the immersion electrode is immersed in said liquid so that upon contact with said liquid the surface area changes with the change of the liquid level in said vessel and the measurement of the level of the electrically conductive liquid in the vessel one cycle covers the following sequence of operations: - from constant voltage power supply fast, charges first capacitor to voltage U1, then - slowly discharging said first capacitor to a set voltage U2 through a reference electrode and said liquid in the vessel, - the measuring circuit calculates the discharge time T1 of the first capacitor from voltage U1 to voltage U2 and prepares capacitor C1 for the next measuring cycle by discharging it to zero voltage, - then rapidly charging the second capacitor from the DC voltage supply to U1, - slowly discharging said second capacitor to a set voltage U2 through the detection electrode and the liquid in the vessel, - the measuring circuit calculates the discharge time T2 of the second capacitor from voltage U1 to voltage U2 and prepares capacitor C2 for the next measuring cycle by discharging it to zero voltage, - the measuring circuit calculates, according to the discharge times T1 and T2 of said first and second capacitors, the respective conductances S1 and S2 of the liquid to be measured and determines the ratio thereof to determine the level of the conductive liquid to be measured in the vessel. 2. A method for measuring the level of an electrically conductive liquid according to claim 1, wherein the measuring fluid is distilled water. 3. A method for measuring the level of an electrically conductive liquid according to claim 1 or 2, characterized in that said first and second capacitors charge in about a few microseconds and discharge in about 0.1 to 100 milliseconds depending on the conductivity of the fluid being measured. 4. A method for measuring the level of an electrically conductive fluid according to any one of claims 1 to 3, wherein the level of the fluid in said vessel is calculated by a measuring circuit of the formula Lx = L0 + LA * S2 / S1, wherein L0 is the distance from the lower end of said electrodes the length of the bottom using uniform rod-shaped electrodes, the lower ends of which are at a distance LO from the bottom of said vessel, the length of the LA reference electrode immersed in the liquid to be measured. 5. An electrically conductive liquid level meter comprising a parallel array of reference and detection electrodes immersed in a receptacle containing the liquid to be measured, a power supply and a measuring circuit which determines the level of the liquid to be measured in the vessel by the conductivity of said measuring fluid; that the reference electrode is completely immersed in said liquid to be measured and does not change its surface area during contact with said liquid and that the detection electrode is immersed in said liquid such that when contacted with said liquid changes in the level of the liquid in said vessel and grounded, and said reference and detection electrodes are respectively connected to the first and second capacitors of the first electrodes, the second electrodes of which are grounded, and said capacitors are connected to a direct voltage U1 power supply for run through a control device designed to control the loading and unloading of said capacitors by first loading the first capacitor and discharging it through the reference electrode and the measuring fluid in the vessel, and then loading the second capacitor and discharging it through the detection electrode and the measuring fluid in the vessel; the circuit is constructed - comparing the voltage on said first or second capacitor electrodes with a set reference voltage U2 which, when reached, emits a signal terminating the discharge of the respective first or second capacitor, - calculate the discharge times T1 and T2 of the first and second capacitors from voltage U1 to voltage U2 - based on the calculated times of the above discharge times T1 and T2, calculate the conductivity S1 and S2 of the liquid to be measured through the reference and detection electrodes and the liquid respectively and determine the level of the electrically conductive liquid to be measured in the vessel. 6. An electrically conductive liquid level gauge according to claim 5, wherein said reference and detection electrodes are rods of the same configuration, the lower ends of which are spaced from the bottom of the vessel.