RU2358810C2 - Method of determining dust separation efficiency of cyclones - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: proposed method determines the gas separation efficiency of cyclones from known dust separation efficiency of a reference cyclone geometrically identical to the given one reaching the preset operating conditions. It includes also the loss factors allowing for the cyclone diametre, dust particle median diametre and inlet flow dust content. Note that it also includes an additional loss factor allowing for dust density. Mind that all loss factors are calculated allowing for the aforesaid factor.

EFFECT: valid data on dust separation efficiency and possibility to be used in designing cyclones of whatever type.

1 ex

Description

The present invention relates to the field of dust collection and can find application in calculating the dust collection efficiency of the designed cyclone of any type (straight-through, counter-current and with counter-swirling flows).

Known methods for calculating cyclones [1, 2], based on the use of empirical probability functions that describe the parameters of the fractional efficiency of cyclone dust collectors, and the dispersed composition of many industrial dusts, such as the calculation method Shilyaeva MI [2] and a typical methodology for calculating NIIOGAZ [1]. Common disadvantages of analogues are:

- the complexity and complexity of mathematical calculations, often associated with the need to perform calculations in several stages;

- lack of consideration of the effect of dustiness of gas z on the efficiency of dust collection;

- the need to take into account the complex for the experimental determination of the parameters of the function of the fractional degree of dust collection of the cyclone (δ ₅₀ and logσ _η );

- unsuitability for calculating the efficiency of dust collection of cyclones with counter swirling flows;

- a calculation error associated with an inaccuracy in determining the parameters of the fractional degree of dust collection function of the cyclone or with the fact that the integral functions of the mass distribution of particles by the size of some industrial dusts do not satisfy the logarithmically normal distribution law due to the action of several dust generation mechanisms.

Closest to the proposed one is the empirical method selected as a prototype [3], which is based on the assumption of the independent influence of parameters: cyclone diameter (D), median diameter of dust particles by mass (δ _m is the mass-median diameter [2]), the dustiness of the input stream (z) by the value of the relative dust leakage for any type of cyclone (straight-through, counter-current, with oncoming swirling flows).

The advantages of the method include its simplicity, versatility (the method is suitable for all types of cyclones), taking into account parameters (D, δ _m , z) that have a significant effect on the dust collection process of the cyclones, the ability to calculate dust collection efficiency in the absence of knowledge about fractional efficiency, more accurate in comparison with the NIIOGAZ methodology, dust collection efficiency assessment.

However, the possibilities of its use are limited by the lack of consideration of the influence of dust density ρ on the dust collection process.

A common drawback of the known methods is the relatively narrow field of practical application of each of them, due to the complexity of the calculations, for this reason - a decrease in accuracy during large-scale transitions and (or) a change in the method of organizing flows in designed cyclones.

The present invention solves the problem of improving the accuracy and universalization of the calculation of the dust collection efficiency of the designed cyclone of any type according to the known dust collection efficiency (η ₁ ) of a reference cyclone geometrically similar to this, with a large-scale transition to specified operating modes, taking into account the influence of the characteristic geometric and physical process parameters (cyclone diameter D, the mass-median diameter of the dust particles δ _m , the dust content of the input stream z), expressed by the values of the entrainment coefficients (K _i ). The problem is solved in that in calculating the dust collection efficiency dust density (ρ) is taken into account by introducing an additional ablation coefficient (K _ρ ) for this parameter, and all other calculated ablation coefficients (K _i ) are adjusted taking into account the influence of this parameter.

The proposed method is implemented, for example, by the following algorithm:

1. The initial calculated data are the consumption of the purified gas Q, its density ρ _g , input concentration Z and density ρ of dust, its dispersed composition.

2. The dispersion composition of dust determines the mass-median diameter δ _{m by} constructing the particle mass distribution function [1, 2].

3. The value of the conditional speed in the apparatus W ₀ , calculated by the maximum cross-sectional area in the cyclone, is set equal to the optimal speed corresponding to the maximum degree of purification in the apparatus. For direct-flow and vortex devices

W ₀ = 8-12 m / s, for countercurrent levels of conventional speeds below W ₀ = 2 ÷ 4 [m / s].

The gas velocity in the cyclone should not deviate from the optimum by more than 15%, otherwise this may cause a decrease in cleaning efficiency.

4. According to the continuity equation, the diameter of the dust collector is calculated:

The resulting value of D is rounded to the diameter closest to the standard recommended in the literature [1].

5. The actual gas velocity in the cyclone is calculated by the formula:

6. The calculation of new ablation coefficients K _ρ , K _ρ1 , used to calculate the dust collection efficiency and taking into account the influence of dust density ρ, is carried out according to the formula:

the empirical coefficients of which were obtained as a result of our own experiments taking into account the literature data [4-6].

The values of the Fisher criterion for formula (3) F = 27.62, the applicability limits of formula (3) correspond to the values ρ = 1380 ÷ 3032 [kg / m ³ ].

7. The ablation coefficients K _D , K _D1 are calculated, which take into account the influence of the diameter of the apparatus on the cyclone efficiency by the formula:

For formula (4), the value of the Fisher criterion is F = 148.0, the applicability limits of formula (4) correspond to the values of the diameter of the cyclone D = 0.1 ÷ 0.6 [m]. The empirical coefficients included in formula (4) are adjusted for the coefficients

K _ρ , K _ρ1 .

8. Determination of the coefficient K _δm , K _δm1 , taking into account the influence of the mass-median dust diameter δ _m on the cyclone efficiency, according to the formula:

For formula (5), the values of the Fisher criterion F = 134.3, the applicability limits of formula (5) correspond to the values of the mass-median diameter of dust particles δ _m = 9.5 ÷ 50 [μm]. The empirical coefficients included in formula (5) are corrected taking into account the coefficients K _ρ , K _ρ1 .

9. The coefficients K _z , K _z1 are calculated, which take into account the dust content of the input stream, according to the formula:

For the formula (6), the values of the Fisher criterion F = 67.07, the applicability limits of the formula (6) correspond to the dust content of the input stream z = 0.035 ÷ 0.22 [kg / m ³ ]. The empirical coefficients included in formula (6) are corrected taking into account the coefficients K _ρ , K _ρ1 .

10. The calculation of the efficiency of dust collection η _ρ by the formula:

Index 1 in the formula (7) addresses the reference cyclone. When proceeding to the calculation of the dust collection efficiency of the test cyclone, index 1 in the designations of the parameters is omitted.

The proposed method was implemented in an extensive experiment taking into account the large-scale transition, and the calculated cyclone efficiency was compared with the efficiency obtained from the test. The technical result consists in obtaining reliable information about the efficiency of dust collection and the possibility of using the proposed method for calculating cyclones of any type.

EXAMPLE OF CALCULATION OF DESIGNED CYCLONE

As an example, we calculate the predicted value of the separation efficiency of the proposed PCPO dust collector for the consumption of cleaned top gas Q = 3000 m ³ / h. Let the used dust have a median particle diameter of δ = 14 μm, dust density ρ = 1008 kg / m ³ , dust content at the inlet of the cyclone z = 0.015 kg / m ³ .

As the source, we take the experimental data for PCPO with a diameter of D ₁ = 0.12 m, which has a separation efficiency of η ₁ = 92% for dust with a median diameter of δ ₁ = 20 μm, at a dust concentration of z ₁ = 0.11 kg / m ³ bulk density ρ ₁ = 1950 kg / m ³ . The drag coefficient on an un dusty stream is ς ₀₁ = 18 at a speed of W ₀₁ = 12 m / s.

1. By the formula (1) we find the new diameter of the apparatus for the consumption of cleaned air

2. Choose the diameter of the cyclone D = 0,300 m and calculate the actual speed W _0g according to the formula (2):

We make sure that the deviation of the actual speed from the optimum does not exceed the specified limits (1.75% <15%):

, учитывающие влияние плотности пыли:3. We calculate according to the formula (3) the coefficients K _ρ and

taking into account the influence of dust density:

, учитывающие влияние габаритов аппарата:4. We determine by the formula (4) the coefficients K _D and

taking into account the influence of the dimensions of the apparatus:

по формуле (5), учитывающие влияние дисперсного состава пыли:5. We determine the values of the coefficients K _δm and

according to the formula (5), taking into account the effect of the dispersed composition of dust:

, учитывающие влияние запыленности потока:6. We calculate by the formula (6) the coefficients K _z and

taking into account the influence of dusty flow:

7. We calculate the cleaning efficiency for the given operating conditions of the cyclone according to the formula (7)

Thus, the calculated efficiency of PCPO with a diameter of D = 300 mm will be η _p = 93.8% on dust δ _m = 14 μm with a dusty input stream z = 15 g / m ³ .

Comparison of the experimental η _e = 94% with the calculated by the proposed method

η _p = 93.8% show good accuracy of the proposed method: the absolute error was -0.2%.

Information sources

1. A guide to dust and ash collection. / Ed. A.A. Rusanova. - 2nd ed., Revised. and add. // M., Energoatomizdat, 1983, 312 p.

2. Shilyaev M.I., Shilyaev A.M., Grishchenko EP Methods for calculating dust collectors. // Tomsk, Tom. state architect build Univ., 2006, 385 p.

3. Sherstyuk A.N., Aslamova B.C. An empirical method for evaluating the efficiency of cyclone separation. // Thermal Engineering, 1990, N5. - S. 61-62.

4. Platov V.D. Research of a dry dust collector with a direct-flow dust concentrator. / Diss. ... Ph.D., Kiev, 1980, 195 p.

5. Kalmykov A.V., Ignatiev V.I., Tyukanov V.N. Research of direct-flow dust separators on streams of dusty gas. // Aerodynamics, heat and mass transfer in dispersed flows. Sat articles. // M .: Nauka, 1967. - S.90-100.

6. Karpukhovich D.T. The effect of the relative height of the cylindrical cyclone body on its characteristics // Chemical and Petroleum Engineering. - 1986, No. 10. - p. 17-18.

Claims (1)

A method for determining the dust collection efficiency of a cyclone by the known dust collection efficiency of a reference cyclone geometrically similar to this, with a large-scale transition to predetermined operating modes and using values of entrainment coefficients taking into account the diameter of the cyclone (K _D ), median diameter of dust particles (K _δm ), dustiness of the input stream (K _z), characterized in that when calculating the dust collection efficiency using additional entrainment coefficient (K _ρ), taking into account the density of dust, all coefficients entrainment races ityvayut considering this option, and dust collection efficiency is calculated based on

,
where K _D , K _δm , K _z , K _ρ are the ablation coefficients of the cyclone;
K _D1 , K _δm1 , K _z1 , K _ρ1 are the ablation coefficients of the reference cyclone;
η ₁ is the dust collection efficiency of the reference cyclone.