SU634178A1 - Method and apparatus for determining particulate content of powder-like materials - Google Patents

Description

The invention relates to the field of quality control of powder materials, in particular cements, and can be used in silicate, ceramic, chemical, concentrating and other industries.

The known method for determining the dispersed composition of powdered materials using two or more cyclones of different efficiencies, according to the total dust deposition efficiency, in which the median size of the part and the standard deviation of the particles in the log-normal distribution of particles are calculated.

The disadvantage of this method is the duration of the dispersion of the dispersed composition and the narrow size of the analyzed materials.

The closest and best known is a method for determining the dispersion composition of powdered materials, including the dissipation of a powder sample, the transmission of a light flux.

through the sedimentary suspension and registration of the change in its intensity with time with the subsequent calculation of the dispersed composition 21,

The method is carried out by a device containing a precipitating chamber, a dissipative AND photo-recording device.

The disadvantage of this method is the duration of the determination of the dispersed composition due to the need to obtain the entire sedimentation with the curve.

The aim of the invention is to compare test times.

The delivered pell is achieved by the fact that the dissipation of n-powder powder is carried out by colliding it with a perforated surface.

Taxi method can be carried out by using its coistroke device, which contains a precipitating chamber, a camera and photographic equipment.

Distinguishing the device, which makes it possible to carry out a new method, consists in the fact that the dissipating device is made in the form of a set of grids arranged perpendicular to the axis of the precipitation chamber.

The drawing shows a general view of an apparatus for carrying out the method for determining the dispersion of powdered materials.

The device contains a hopper of the original powder-like material 1, a gesture fixed on the rack 2, a dispenser made in the form of two cylinders of rings 3 and 4 coaxially coinciding with each other and with a portion capacity 5

The cylinder 3 is located in the holder 6 and can be rotated therein, and the base of the cylinder is in contact with the polished surface of the disk 7, from the bottom side of which cylinder 4 is attached. Cylinder 3 and cylinder 4 have the same internal diameter disk 7.

A sliding ring-flange 8 is put on the cylinder 4, the lower part of which is in contact with the ground surface of the upper operative plate 9, which is rigidly connected to the lower support plate U with the supports 11,

On the lower support section 1O, shaft 12 and 9 electric motor 13 are mounted, which are interconnected by gear transmission

In the upper part of the shaft 12 is fixed disk 7.

To the lower support plate 10 attached to the camera 15 n pipe 16, adjacent to the hole 17 in the upper support plate 9.1

In the upper part of the settling chamber 15, which is hermetically sealed to the upper support plate 9, a portioning tank 5 is installed, the bottom of which is a shutter 18, hingedly connected to electromnite 19, and a solenoid valve2O with air-cleaning nipples 21.

Inside the precipitation chamber 15, there is a dissipative device 22, which is designed in the form of two grids with mutually shifted cells rigidly fixed in a cylindrical housing.

The dissipating device 22 can be moved within the collecting chamber 15 in the vertical direction and fixed rigidly.

In the middle part of the precipitation chamber 15 are coaxially located a source of a point stabilized beam of light 23 and a photocell 24 connected to a recording device 25.

To the lower part of the settling chamber 15, which has a square cross-section, is fixed a compensation-storage capacitance 26, having a valve 27 and an opening 28 for supplying the pipeline 16.

In the chamber 15 there is a cut-off plate 29 pivotally connected to the electromagnet 30.

The side window 31, in the chamber 15, is adjacent to the sleeve 32 with the filter 33,

A sleep & keno device with a remote control unit 34 comprising a power supply unit and a switching device.

The device works as follows.

Claims (2)

Include automatic system operation of the device 34, In particular, include the motor 13, while mounted on the shaft 12 of the disk 7 through the gear transmission 14. rotates continuously at one revolution per minute. The two cylinders 4 mounted diametrically on the disk 7 alternately pass under the cylinder 3 with a period of 30 seconds. At the moment of passing of the cylinder 4 under the cylinder 3, it is filled with the powder under test and, with further advancement, it loads the batch tank 5, In turn, the cylinder 3 is continuously filled with powder coming from the hopper 1. Possible excess powder in the cylinder 4 left after filling the fluid containers 5 are discharged into a compensatory accumulation tank 26 through conduit 16 when cylinder 4 passes over hole 17 in the upper support plate 9. After batch tank 5 is filled with powder and cylinder 4 is shifted to the side , via. The electromagnet 19 quickly opens the shutter 18 and a portion of the powder, preserving the shape of the portioning capacity, drops onto dissipative device 22 with acceleration. At the moment of impact, due to the combined effect of the dissipative device and powder recoil on the powder portion, the frac- tional suspension that settles Crosses a thin beam from a stabilized light source 23 directed at a photocell 24. Changing with this, depending on the concentration and particle size, the intensity of light sweat Single Q registers unit 25. The absence of the light intensity of the slurry on a current maximum and Do is a constant for a given value of hydrochloric device. The fractionally precipitating suspension enters the compensation-accumulative capacity 26 and after 10 sec. counting from the moment of opening the slurry of the portioned capacity, using an electromagnet. The filament 30 of the shut-off plate 29 closes the precipitation chamber by opening the sleeve 32 with the filter 33. At this time, the electromagnetic valve 2O passes the compressed air through the brush 21 into the settling chamber 15 and the remaining non-dust particles are removed to the filter 33. After purging the shut-off plate 29 returning to the initial vertical position, closing the window 31. The precipitator on the chamber is cleaned and after the air is quenched, a new cycle begins, by which time the portion tank 5 is filled with a powdery material. The median particle size of 630 standard deviation of the logarithmically normal distribution of particle sizes is determined from the corresponding values of the light flux intensities: measured eight times every second, counting from the beginning of the period of fractional sedimentation of the suspension. Calculation of parameters & gg g characterizing the dispersed composition, produced by empirical equations: BSW -25.1671 + 74.513 (e "3triDSi) - 95.8626 (EntJo-EnSSz 58, (ЕпЭо-КпЭб), + 35.8965, (Yp Zo - g d54.) 22,4657 (ErjDo é USs) - 11.9721 (8pau-2pE5b) 5, O186 (gn DO - EpZW 36.7883 (En o-entJBs bz, 2316 - 2.9586 (En tJQgp 35i) +4.0036 (en3o-er DS2) + 1.8968 (En Зое, П 38э) - 1.8154 (in Зо-Кп354) - 0.2865 {«Зgn35g) + 0.1623 (ЕПЭ- EP354) + 0.1011 (enZo-pEb) 1.3984 (KnDo-enDSe to obtain more detailed information on the dispersed composition, it is characterized by a function of the log-normal mass distribution of the material by particle diameters s le s-EgSsoi e 2or tb. SCH5. or a particle size distribution density function 00 iMilMi5 4 (5) E bbShG 2 pct using the parameters found, 5O 5 to automatically print the result of the analysis to determine the dispersed composition, characterized by one or another specified function, calculating them is carried out with the use of a computer or UVM using the characteristics of the intensity of the luminous flux received from the photo receiver. The use of this method for determining the dispersion composition of powder-like materials and the device for its implementation provides, in comparison with existing methods and devices, a significant reduction in the time for determining the parameters Оg and characterizing the dispersed composition of powdery materials, widening the range of materials being analyzed and increasing the accuracy of the analysis. Claim 1. Method for determining the dispersed composition of powdered materials, including dissipating the powder sample, passing the light flux through the settling suspension and recording the change in its intensity over time with the subsequent calculation of the dispersed composition, characterized in that, in order to reduce the test time, the powder sample was dissipated by impacting it with a perforated surface. 2. A device for carrying out the method of claim 1, comprising a precipitation chamber, a dissipative and photo-registering device, characterized in that the dissipating device is made in the form of a set of grids arranged perpendicular to the axis of the precipitation chamber.