SU1267224A1 - Device for analyzing particulate composition of powders - Google Patents

Abstract

The invention relates to the field of measurement technology and is intended to measure the dispersion composition of powders and can be applied in the processes of control and production of powder materials; The aim of the invention is to increase the accuracy of the measurement of the dispersion-composition of the powders. A device for analyzing the dispersion composition of powders contains a powder nebulizer for transferring a sample of anapized powder into an aerosol state, a charging chamber for charging particles, an electrostatic filter for air purification and laminarization of air flow, a decoupling condenser with induction sensors for separating powder particles by fractions and measurements of their charges, blower, switching device, connecting induction sensors in to an electrometric amplifier, a neutralizer for neutralizing static charges in a precipitation capacitor, high-voltage sources for powering the charging chamber and a precipitation capacitor, and a device for stabilizing the current. The charging device consists of (a corona discharge section, equipped with a corona electrode, and a charging section, equipped with a receiving electrode, separated by a grid electrode, and also includes a device for stabilizing the current in the charging section, consisting of a current sensor, current transformer and high voltage transformer: a transformer. Moreover, the current sensor input is connected to the receiving electrode, N9 and the output is connected to the input of a current stabilizer, the output of which is connected to the input 4ib of a high voltage transformer. The transformer is connected to the electrodes of the charging chamber. 1 Cp f-crystals, 2 ill.

Description

The invention relates to measuring equipment and is intended to measure the dispersed composition of powders and can be used in $ processes of control and production of powder materials.

The aim of the invention is to improve the accuracy of measuring the dispersed composition of the powders. Ιθ

In FIG. 1 shows a block diagram of a device for analyzing the dispersed composition of powders; in FIG. 2 charger.

A device for analyzing the dispersed composition of powders contains a powder atomizer 1, intended for converting a sample of the analyzed powder to an aerosol state, a charging chamber 2, designed for charging particles ₂₀ , an electrostatic filter 3 for air purification and lamina- _: non-irrigation of the air flow, precipitation condenser 4 with induction sensors designed for 25 separation of powder particles into fractions, blower. 5, a switching device 6, providing a serial connection of induction sensors to an electrometric amplifier 7, a converter 8 for neutralizing static charges in a settling capacitor 4, high-voltage sources 9 and 10 for supplying a charging chamber 2 and a settling capacitor 4, and a stabilization device 11. current.

The charging device (Fig. 2) consists of a corona discharge section equipped with a corona electrode 12, and a charging section equipped with a receiving electrode 14 separated by a mesh electrode 19, a device for stabilizing the amperage in the charging section, consisting of a sensor 15 for changing the magnitude of the current , a current stabilizer 16 and a high-voltage transformer 17, the input of the sensor 15 being connected to the receiving electrode 14, and the output to the input: a £ 1 stabilizer, the output of which soe-5® is dined to the input of the high-voltage transformer 17. The output is high the voltage transformer 17 is connected to the electrodes 12-14 of the charging chamber 2, which allows you to change the output voltage of the high-voltage transformer 17 depending on changing conditions in the charging chamber 2 and thus provide in the charging section such an ion concentration that, regardless of the conditions in the charging chamber of the particle of the same size will receive the same charges.

The device operates as follows.

A sample of the analyzed powder is poured into the atomizer 1. The atomizer 1 puts the powder into an aerosol state. The aerosol jet coming from the atomizer 1 is fed into the charging section, and a corona discharge arises under the action of a constant high voltage applied to the electrodes 12 and 13 of the corona discharge section. the discharge, the ions formed under the action of an alternating voltage applied to the electrodes 13 and 14 of the charging section penetrate the charging section. Part of the ions, encountering particles of the analyzed powder on their way, interact with them, thus ensuring “charging of the particles, and the charge is determined by their size, proportional to the surface of the particles. A part of the ions that have not settled on the particles reaches the receiving electrode 14 and, settling on it, causes the current to flow through the sensor 15.

When conditions in the charging section change due to a change in the concentration of particles entering the charging section, as well as dusting of the electrodes of the charging section, the number of ions entering the charging section changes, therefore, the charge received by the particles changes. the same size. However, a change in the concentration of ions entering the charging section causes a change in current through the sensor 15. This change through the stabilizer 1Bi and the transformer causes an increase in voltage on the corona electrode 12, which leads to a change in the concentration of ions and compensation of the measurement error.

In this charging chamber, the particles receive unipolar charges proportional to the surface of the particles, with particles of the same size. Regardless of the conditions in the charging chamber, the same charges are obtained, which ensures stable deposition of the same fraction of particles of similar size in a certain area in the precipitation cone3 and significantly increase the accuracy of <. The device for analyzing the dispersed composition of powders. From the 'charging chamber', the Particles enter an electric filter 3, intended for 5 fixing the coordinates of the entrance of charged particles into the settling capacitor 4. The settling capacitor 4 is made in the form of a pipe of rectangular cross section. The electric field in the capacitor 4 10 is created by two electrodes - high voltage and collector. Measuring plates are installed in the center of the collector electrode; their number corresponds to the number of measured fractions 15.

In the precipitation capacitor 4, under the influence of the forces of the electrostatic field, the particles are spatially separated and 20 dimensional groups are deposited in different parts of the collector toroid electrode.

As a result, particles of certain fractions settle over each measuring plate. In the process of deposition and accumulation of charges on the measuring plates, they are disconnected from the measuring circuit and isolated from the base of the device. At the end of fractionation, the measuring plates through the switching device are alternately connected to the input of the electrometric amplifier 7, and the recorded signal is proportional to the total particle charge of the corresponding fraction and, therefore, to the number of particles.

Claims (2)

The invention relates to a measurement technique and is intended to measure the dispersed composition of powders and can be applied in the processes of control and production of powder materials. The aim of the invention is to increase the accuracy of measuring the dispersed composition of powders. Fig. 1 shows a block diagram of a device for analyzing the dispersion composition of powders; in fig. 2 charge yctpoucTBO. A device for analyzing the dispersed composition of powders contains a sprayer 1 of a powder, designed to transfer a sample of the analyzed powder to an aerosol state, a charge chamber 2, designed to charge particles, electrostatic F1-pin 3 for air purification and lamyurization of air flow, 4 s condensing condenser induction sensors for the separation of powder particles into fractions, a blower. 5, a switching device 6, which provides a series connection of induction sensors to an electrometric amplifier 7, neutralizers to neutralize static charges in the collecting capacitor A, high-voltage sources 9 and 10 for powering the charging chamber 2 and a collecting capacitor 4, and a stabilizing device 1I, current . The charging device (Fig. 2) consists of a corona discharge section, equipped with a corona electrode 12, and a charging section, equipped with a receiving electrode 14, separated by a grid electrode 19, a current stabilization device in the charging section, consisting of a sensor 15 changes the magnitude of the current, the current stabilizer 16 and the high-voltage transformer 17, the sensor input 15 is connected to the receiving electrode 14 and the output to the input of the current stabilizer 1 |), the output of which is connected to the input of the high-voltage transformer 17. The output is high Voltage transformer 17 is connected to electrodes 12-14 of charging chamber 2, which allows the output voltage of high-voltage transformer 17 to vary depending on the change in the conditions in the charging chamber 2 and thus ensure the concentration of ions in the charging section regardless of the conditions in the charge chamber. 2 particles of the same size will receive the same charge. The device works as follows. A sample of the powder to be analyzed is entrusted to sprayer 1. Spreader I transfers the powder to the aerosol state. The aerosol jet coming from the sprayer 1 is fed into the charging section, while under the action of a constant high voltage applied to the electrodes 12 and 13 of the corona section, a corona occurs, which forms ions under the action of alternating voltage Applied to the electrodes 13 and 14 of the charging section, penetrate into the charging section. The part of the ions, the particles of the powder being analyzed encounter on their way, interact with them, thus ensuring the charge of the particles, while the charge is determined by their size, which is proportional to the surface of the particles. ions, not settled on the particles, reaches the receiving electrode 14 and, settling on it, causes the current to flow through the sensor 15. When conditions change in the charging section, due to a change in the concentration of particles entering the charging section, as well as dusting of the electrodes charge section, the amount of ions entering the charge section changes, therefore, the charge produced by the particles changes. same size. However, a change in the concentration of ions entering the charge section causes a change in the current through the sensor 15. This change through the stabilizer 1bPi transformer causes the voltage on the corona electrode 12 to increase, which leads to a change in the ion concentration and compensation of the measurement error. In this charge chamber, particles receive unipolar charges proportional to the surface of the particles, while particles of the same size, regardless of the conditions in the charge chamber, receive the same charges, which ensures stable deposition of the same fraction particles of similar size in a certain area in the settling condenser and significantly improve the accuracy of the device for analyzing the dispersed composition of the powders. From the charging chamber. The particles enter the electric filter 3, which is designed to fix the COO1 dinates of the charged particles in the settling capacitor 4. The settling capacitor 4 is made in the form of a rectangular tube. The electric field in the capacitor 4 is created by two electrodes — a high voltage and a collector electrode. Measuring plates are installed in the center of the collector electrode; their number corresponds to the number of measured fractions. In the precipitation condenser 4, under the action of electrostatic field forces, spatial separation of particles occurs and the size groups are deposited at different sites of the collector electrode. As a result, particles of certain fractions are deposited over each measuring plate. In the process of deposition and accumulation of charges on the measuring plates, they are disconnected: from the measuring circuit and isolated from the base of the device. At the end of the fractionation, the measuring plates through the switching device are alternately connected to the input of the electrometric amplifier 7, with 244 of this, the recorded signal is proportional to the total charge of the particles of the corresponding fraction and, therefore, to the number of particles. . Formula of the inventions I. Device DP for analysis of dispersed powder composition containing successively installed powder spreader, charging chamber, precipitation condenser with fraction charge sensors and blower, characterized in that, in order to improve the measurement accuracy, the charge chamber is separated by a grid electrode corona discharge section equipped with a corona electrode, and a charging section equipped with a receiving electrode, the receiving electrode being connected through a current stabilization device to the corona ring m and the grid electrodes, the input of the charging section is connected to the spreader, and the output is connected with a precipitation capacitor. 2. The device according to claim 1, of which is that the device for stabilizing the current is made of a successively connected current sensor, current stabilizer and high-voltage transformer. FIG. Fie.2 - / 2