SU1230660A1 - Rotary apparatus - Google Patents

Description

2. The apparatus according to claim 1, wherein the length of the blades is periodically increased by an amount A.

3. The apparatus according to claim 1, is different from a-u y and i in that the length of the blades is periodically reduced by the value of Af.

4. The apparatus according to claim 1, characterized in that the length of the blades increases periodically and then decreases by the value of q (.

5. The device according to claim 1, which differs from and so that the length of the blades periodically varies by

8e u8 sinx,

where & t is a constant value for changing the length of the blades, X is an arbitrary variable value.

6. The apparatus according to claim 1, wherein the stator blades have a periodically varying length.

7. Apparat popp. 1 and 6, differing from the fact that the length of the blades is periodically increased by the value of l t

The invention relates to a mixing technique and can be used in the chemical industry for carrying out processes of dispersion, homogenization, stirring, etc. in flowable media, in particular in the production of photographic materials.

The aim of the invention is to intensify the process of dispersing and mixing multicomponent systems by creating a broadband acoustic field.

FIG. 1 shows a mixer, longitudinal section: (the arrows indicate the direction of rotation of the rotor, the direction of movement of the liquid medium being processed) fig. 2 — section AA in FIG. 1, a variant with an increase in the length of the blades i in FIG. 3 - the same, option with decreasing 8. The device for pn. 1 and 6, oo l in order that the length of the blades is periodically reduced by the value of d L.

9. The device on PP. 1 and 6, characterized in that the length of the blades increases periodically and then decreases by the value of l L.

10. The device on PP. 1 and 6, characterized in that the length of the blades is periodically changed by

, -Sinx,

where uL is the constant value of the change in the length of the blades.

11.Appa | Al on PP. 1, 6 and 9, about the fact that d e

 Hi .... 12. The device according to paragraphs. 1, 6, and 9, in that the rotor blades and stator blades are installed in two stages, while the length of the rotor blades in one stage is longer than the length of the stator blades of the same stage, and the other stage is less than the length of the stator vanes of the same same steps.

spanning on the kt length of the blades} on (| I1G. 4 - option with increasing and decreasing by d value of the blade length in Fig. 5 - option with varying by 8 & 6 Sinx i in Fig. 6 - option c the length of the stator vanes i increases by the value of AL in Fig. 7 is a variant with the length of the stator blades decreasing by the value of & L in Fig. 8 is a variant with the length of the stator blades increasing and decreasing by the value of L, Fig. 9 is a variant with the length of the blades, changed to a value of 81 "iL-Stn x; .Y section BB in Fig. 1, a variant with the location of the blades and the blades the current is in two stages, with the blades of one stage longer than the blades of the other stage (the arrow shows the direction of rotation of the rotor); in Fig. 11 - section A-A. in Fig. 1, with different variants of changing the lengths of the blades and blades. -11 by a dash-dotted line, envelopes of blades and blades are drawn, and various channels are formed.

The mixer includes a housing 1 with concentrically placed stators 2 and rotors 3. Between each rotor 3 and stator 2, chambers of displacement 4 are formed, divided by partitions 5. In each stator 2 circumferentially, elastic blades 6 and 7 are installed in two stages, having periodically changed length. On the rotor 3 resilient blades 8 and 9 are placed, having a periodically varying length. In case 1 there are component connections 10-17. Displacement chambers 4 are interconnected by means of a radial gap 18 located between the baffles 5 and the rotor 3. The housing 1 is provided with an outlet 19. In the stators 2 there are cavities 20 for supplying heat carrier to them. In addition, the apparatus can be equipped with temperature sensors in each mixing chamber 4. The rotor blades 8 and 9 have a periodically varying length.

It is known that the natural frequency of the plates (blades, blades) is determined from the expression:

where Р „

  - plate oscillation frequency, dimensionless coefficient depending on the oscillation shape and closure condition (Plate insertion (L, 15.4, L 50, o; - L, 104.0) i plate length and elastic modulus of the plate material / I - moment of inertia cross section

tina

h is the mass per unit length of the plate.

From the expression it can be seen that the oscillation frequency of the plates largely depends on its length t, and a slight change in the length of the blades and blades leads to significant changes in the frequencies of their natural oscillations.

The execution of rotor blades with periodically varying length dependencies, as well as

HER

five

5 0 5 0

five

0

five

0 5

The introduction into each mixing chamber of blades of various lengths, installed on the stator around the circumference, the length of which also varies periodically according to different dependencies, leads to the fact that each blade and blade in the mixing chambers have their own oscillation frequency, determined from the above expression, consequently, in each mixing chamber, a broadband acoustic field takes place, intensely affecting the treated medium.

The lengths of the blades 8 and 9 and the blades 6 and 7 can periodically increase by the value of LE, in this case, when the blades and blades flow around the liquid medium, each of them is affected by a fluid, exerting a pressure proportional to pV (where p is the density of the fluid, V is the velocity of the fluid ). Behind the last longest blade, a zone of vortex breakdown is formed. Cavitation takes place in this zone, pressure pulsations and the following blades (blades) are located in it. Thus, the blades (blades) have a pulsating fluid flow, causing each of them to oscillate with a maximum amplitude in the frequency range close to the natural frequency of the oscillations.

The length of the blades 8 and 9 and the blades 6 and 7 may periodically decrease by the value of l. In this case, the first blade (blade) has the most dynamic impact on the incident flow of fluid. Behind this blade, a zone of vortex breakdown is formed, as in the previous case. Breaking vortices are formed behind each blade (blade). It also contributes to increased pulsation in the area of the blade group installation, which, in turn, intensifies acoustic effects in the apparatus.

The length of the blades 8 and 9 and the blades 6 and 7 may periodically increase and then decrease. In this case, the effect is the same as in the two previous versions.

The lengths of the blades 8 and 9 and the blades 6 and 7 may periodically vary respectively by the value of B ATsJn X and Si d1 31px (where (1 and aL are constant values of changing the length of the blades and blades, X is an arbitrary variable). In this case, the natural frequency of oscillations of the blades and blades changes smoothly.

In the apparatus may l j 4L. When this frequency of the rotor blades

and stator blades are not identical, which expands the acoustic spectrum of the apparatus.

Installing the blades and blades in each chamber in two stages, where the length of the blades in one stage is greater than the length of the blades in this stage, and the length of the blades of the second stage is less than the length of the blades in the same stage, when the rotor blades move with respect to the blades, in the meltz gaps, they experience significant shear stresses in the liquid and pulsating phenomena, which intensify the processes of dispersion and mixing.

The number of steps. Elastic blades 6 and 7 and elastic blades 8 and 9 in each mixing chamber 4, as well as changing the lengths of the blades and blades, their combination and arrangement in groups can be any of the following options: e. It depends on the properties of 4 flowing products introduced into the mixing chambers.

The device operates as follows.

The flowable fluid flows into the housing through the inlet nozzles tO-17. In the mixing chamber 4, when the rotor 3 rotates, it is exposed to elastic blades 8 and 9 fixed to the rotor 3, as well as from the elastic blades 6 and 7 fixed to the stator 2. In this case, the fluid is effectively mixed in the mixing chambers 4, since the elastic blades 6 and 7, fixed in the stator 2, prevent its twist,

When the rotor 3 moves with blades 8 and 9 mounted on it in two stages (the lengths of the blades vary according to the above dependencies), there is a relative movement of the liquid medium both with respect to the blades 8 and 9 of the rotor 3 and with respect to the blades 6 and 7 stator 2. For the longest blades mi

and blades form zones of high-frequency swirl vortices in which pressure, velocity, etc. pulses. which causes the elastic blades and vanes to oscillate. Frequency

The spectrum of acoustic oscillations in such zones is quite wide. It causes intense oscillations of the blades and blades, and an increase in the amplitude of their oscillations occurs when the frequencies of the natural oscillations of the blades and blades in groups coincide with the frequencies of disturbances. Thus, there is a more complete use of the energy of the acoustic oscillations of the blades and blades, since it is possible to achieve such a mode of breaking the vortices (by selecting the rotation frequency, the material of the blades and blades, the length, the law of their change) that all blades and blades in groups will perform intensive (with maximum amplitude) oscillations.

The vibrations of the blades and blades intensively affect the fluidized multicomponent medium flowing in the channels between them. In this medium there are particles of various sizes, the range of which is considerable. Moving in the mixing chambers 4, the particles of the dispersed phase of various sizes occur on different blades and vanes. In this case, only those particles of the dispersed phase that are most easily destroyed under the action of a given frequency (the frequency with which the blablets of this blade) are subjected to destruction (dispersion) under this blade or blade. .

It is known that the diameter of dispersed particles subjected to destruction (division) in the acoustic field is in the range of 0.25-0.1 standing wavelength of oscillating blades and blades. The other blade (blade), which oscillates with a different frequency, will cause destruction (crushing) of particles of the dispersed phase, which have a different size. 1 Thus, the dispersion process in the apparatus in the mixing chambers will proceed under optimal conditions for particles of the dispersed phase of various sizes.

When changing the length of the blades and blades by the values of it and & L, the frequencies of their natural oscillations will change accordingly in proportion to the values

(e, ye) (u «+ iLf

where k is the number of blades in a group of blades that change the length in one period,

and - the number of blades in a group of blades that change the length in one period.

The step of changing the oscillation frequency depends on the step of changing the length of the blades and blades LU and bL. To reduce the difference in the natural frequencies of oscillations of two adjacent blades and blades (it is advisable to change the step of changing the length of the blades and blades in proportion to the sine function. In this case, when the malps change the sinus function, the length of the blades and blades changes by an insignificant 58 LU s s n X and 81 uL sin X, and the natural frequencies of such blades and blades will be proportional to the values

R .

 (e.rae Sinxi

. R

 (L aL Sinx) V

With such a smooth change often the natural oscillations of the blades and blades will have a more dense a: bushy frequency spectrum in the apparatus. The greater density of the acoustic field increases the dispersion intensity of fluid systems.

When the fluid moves in the axial direction of the apparatus, it falls into the gap between the two stages of the blades and the blades. Since these blades and blades overlap each other in length, in this area of the mixing chamber A, there are high velocity gradients, accelerations, etc., caused not only by the rotation of the rotor blades relative to the stator blades, but also by the intense oscillations of the latter. The mutual arrangement of the blades and blades, their groups in this area will be cyclical and vary, which, in turn, will lead to mutual

0 s 0 5

0

five

five

0

influence of the blades on the blades of the Sleep, the nature of their vibrations) and vice versa. High gradients of velocities, accelerations, complex acoustic (varying with time) obstanovka in this area intensify the processes of dispersion, dissolution, i.e. intensify the processing of fluid systems.

The processed liquid from one mixing chamber to another flows through the radial gaps 18 between the partitions 5 and the rotor 3. Passing through the entire apparatus, the liquid through the outlet 19 goes out of it.

When the length of the blades of the rotor and stator blades and the sinusoidal length of the blades and blades vary, a broadband acoustic field is created in the device, intensifying dispersion processes in liquid heterogeneous media, due to the selective effect of different wavelengths on particles of a certain size range. When the rotor blades move relative to the stator blades, due to the movement in the same direction of the liquid in the mixing chambers, the latter moves in a variable cross-section channel with a sharp contraction or expansion. It is known that in such channels a high-frequency breakdown of whirlwind occurs, cavitation, which leads to hydraulic shocks, and this contributes to the process of dispersion of the dispersed phase in the dispersed system. The arrangement of blades and blades in the chambers of mixing in two stages leads to the appearance of large gradients of acceleration velocities, etc., arising in a liquid medium under the action of rotating and oscillating blades of the rotor and oscillating and stationary vanes of the stator in the region of transition from one level to another. It also intensifies the dispersion process in the apparatus.

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JrA

A j

AFig, in

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FIG. ten

Editor K. Voloshchuk

Compiled by N. Fedorov

Tehred G.Gerber Proofreader M.Samborska

Order 2476/10

Circulation 578 Subscription

VNIIPI USSR State Committee

for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab, 4/5

Production and printing company, Uzhgorod, Projecto st., 4

11

Claims (12)

1. A ROTARY APPARATUS containing a rotor with elastic blades located around the circumference and a stator concentric to it with elastic blades located around the circumference, characterized in that, in order to intensify the processes of dispersion and mixing due to the creation of a broadband acoustic field, the rotor blades have a periodically changing length . 2. The apparatus by π. 1, characterized in that the length of the blades periodically increases by the value of A t. * 3. The apparatus by π. 1, with the fact that the length of the blades periodically decreases by the value of d I. 4. The device pop. 1, characterized in that the length of the blades periodically increases, and then decreases by an amount. 5. The apparatus according to claim 1, characterized in that the length of the blades periodically changes by the value where At is the constant value of the change in the length of the blades *, X is an arbitrary variable. 6. The device pop. 1, due to the fact that the stator vanes have a periodically changing length. 7. The device popp. 1 and 6, characterized in that the length of the blades periodically increases by the value of l 1 8. The apparatus of the CPU. 1 and 6, which implies that the length of the blade current periodically decreases by the value of l L. 9. The apparatus according to claims 1 and 6, characterized in that the length of the blades periodically increases, and then decreases by an amount to L. 10. The apparatus according to claims. 1 and 6, characterized in that the length of the blades periodically changes by the value? L = 4Lstnx, - '’· · where aL is a constant value of the change in the length of the blades. 11. The apparatus according to claims. 1, 6 and 9, characterized in that / / ab. 12. The apparatus according to claims 1, 6 and 9, characterized in that the rotor blades and the stator vanes are installed in two stages, while the length of the rotor blades in one stage is longer than the length of the stator blades of the same stage, and the length of the rotor blades in the other stage is less than the length of the stator blades of the same steps.