SU689695A1 - Rotary mass-exchange apparatus - Google Patents

Description

(54) JUTION MASS MEDIA

Claims (3)

The invention relates to rotary apparatuses for mass-heat exchange processes and can be used in the food, chemical and petrochemical industries, as well as in agriculture. A rotary mass-exchange apparatus is known, which includes a housing with a rotor with screw blades and overflow devices arranged in it, made in the form of truncated cones with perforation, made in the form of coil pipes with gaps between turns 1. This apparatus has a relatively small phase contact surface and there is no recycle (pair) on the steps, which makes it unsuitable for operation. A mass-transfer apparatus is also known, including a housing with a jacket, a rotor in the form of a shaft with a distribution disk and radial blades fixed on it, a film forming element made in the form of a truncated cone with radial blades, a fender-cut-off cone 2. This device does not provide degasification of ductness. The closest in technical essence to the proposed rotary apparatus, comprising a case with overflow devices in the form of perforated elements and a rotor, made in V1 more than Archimedes' screws fixed on the shaft, limited by bushings interconnected by a hollow sphere, provided with slots. A perforated partition is attached to the edge of the upper bushing, installed with a gap in relation to the perforated element, and the perforated elements and the partition are made in the form of hemispheres 3. In this rotary mass exchanger, the presence of fixed hemispheres and a hollow sphere with slots reduces the frequency of fluid circulation on the spheres, which reduces productivity, and the introduction of gas (vapor) into the liquid with screws affects the efficiency of the apparatus as a whole. 3 The purpose of the invention is to intensify the process by increasing the rate of circulation of the fluid and ensuring its detailing. This is achieved by the fact that, in the apparatus proposed, the housing is rotatably mounted and provided with a tapered disk in the lower part, and the rotor shaft is hollow and perforated at both ends, with the lower part of the rotor shaft fitted with screws fixed in annular magnetostrictive emitters. It is advisable to provide an apparatus in the upper part of the shaft with a chipper, made in the form of a disk with radially arranged trapezoidal blade ш, and the perforated elements should be made in the form of concave hemispheres arranged one above another. FIG. 1 shows the proposed apparatus, a longitudinal section; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. 1. The rotaciosa mass transfer apparatus contains a cylindrical body 1 mounted rotatably with a conical cap 2, on which is placed an opening 3 with a branch pipe 4, an actuator 5; the lower part of the body engages with the device 6 and the stationary part 7 of the apparatus, equipped with ring-shaped map-emitters 8 and a conical bottom 9 with a branch pipe 10. Inside the housing 1 of the apparatus there are perforated concave hemispheres 11, a conical disk 12 and a hollow perforated 13 and 13 14 shaft 15, baffle - tapered disc 16, having radially {fitted trapezoidal blades 17 below, concave hemispheres 18 and augers 19. Rotary mass transfer apparatus operates as follows. Gas (steam) is fed into the lower part of the housing 1 of the apparatus through the lower hollow with perforation portion 13 of the shaft 15. Through the pipe 4 enters the top of the cone disk 16, where, under the action of centrifugal force, it is thrown into the perforated concave hemisphere I; there, the flowing film intensively contacts with gas entering through the perforations of the hemisphere 11, and hits the rotating perforated concave hemisphere 18 of the shaft 15, where it again contacts the gas (steam) entering through the perforations of the hemisphere 18, etc. This arrangement of the rotating concave perforated the hemispheres of the housing and the rotor shaft directs the gas (vapor) only through their perforated surface, ensures intensive contact of the gas (vapor) with the liquid flowing off the film and accelerates the mass and heat exchange processes. Then the liquid, having passed all the perforated concave hemispheres 11. and 18, from the lower part of the housing 1 flows along a tapered disk 12 to the center of the shaft 15, where it mixes with gas (steam) coming out of the lower hollow perforated part 13 of the shaft 15. Screw 19 the liquid in the form of a film is directed into the space of an annular magnetostrictive radiator 8, where degassing of liquids occurs intensively. After that, the fluid, having passed all magnetostrictive emitters 8, flows down the inner surface of the conical bottom 9 and is removed from the apparatus, through the nozzle 10, and the exhaust gas (steam) is sent by trapezoidal blades 17 of the tapered disk 16 to the upper perforated part 14 of the shaft 15 and leaves apparatus through the upper part of the shaft 15. Claim 1. Rotational mass transfer apparatus, comprising a housing, a rotor in the form of a shaft with perforated elements, nozzles for supplying and discharging gas (vapor) and liquid (material), characterized in that In order to intensify the process by increasing the circulation ratio of the fluid and ensuring its degassing, the housing is rotatably mounted and provided with a conical disk in the lower part, and the rotor shaft is hollow and perforated at both ends, the lower part of the shaft is equipped with screws enclosed in annular magnetostrictive radiators. 2. Rotational mass transfer apparatus according to claim 1, characterized in that nefM | Oriented elements are made in the form of concave hemispheres arranged one above the other, fixed alternately to the body and to the shaft. 3. The rotary mass transfer apparatus according to claim 1, 2, characterized in that the upper part of the shaft is provided with baffles made in the form of a conical disk with trapezoidal blades radially located in its lower part. Sources of information taken into account in the examination 1. The author's certificate of the USSR N 363500, .kl. B 01 D 3/30, 1971. 2. USSR author's certificate N 512772, cl. B 01 D 3/30, 1974. 3. Authors certificate of the USSR N 480424, k. B 01 D 3/30, 1974 (prototype). FIG.