SU891128A1 - Sprinkling apparatus - Google Patents

Description

The invention relates to apparatus used for the absorption of gases, in particular to irrigation columns of desiccant columns, which are used in absorption plants as in the case of. receiving any products, and when catching harmful emissions into the atmosphere.

The main condition for the efficiency of the packed columns is the full wetness of the entire nozzle and the uniform distribution of gas and liquid in each cross-section of the nozzle.

For uniform irrigation of packed columns, distribution plates are used, the action of which is based on low-pressure outflow of fluid, carried out simultaneously with the passage of gas through the nozzles of the bottom of the irrigator. The main conditions for the effective operation of the irrigation plates are to ensure full wetting of the cross section of the nozzle loaded in the apparatus already in its upper layers, the absence of entrainment of splashes by the gas flow passing through the irrigator, and low hydraulic resistance.

Irrigation states are known with short nozzles protruding above the surface of the bottom of the slab, on the upper cut of which there are vertical slots. The gas in these sprinklers passes through the nozzles, and the liquid, overflowing through the slots, also passes through the same nozzles l j.

These sprinklers evenly distribute the gas and liquid streams, they & are small hydraulic resistance, but are characterized by a large sprinkler.

Irrigation devices are also known, consisting of elongated nozzles, sealed with caps on top, and an immersion side openings for introducing liquid, with the nozzles fastened in. distribution plate and immersed in a layer of nozzles L2 J.

Claims (4)

This design allows the liquid to be distributed fairly evenly and has a small bristle fillet, but the gas, especially near the irrigator, is not evenly distributed, which leads to an increase in the material capacity of the column. Also known is the irrigator design, consisting of short pipes reinforced in the distribution plate, with located at the upper cut-off section of the slits for the introduction of fluid, fixed stationary in each nozzle, coaxially, with a gap of insulating gas nozzles for the passage of gas, and about between the short and the gas pipes from above plugged 3j. This sprinkler, evenly distributed gas and liquid streams and having a small hydraulic resistance in gas, is characterized by a large spray ablation. In addition, when the space between the short and gas nozzles is clogged, their inspection and repair is quite complicated and requires dismantling the irrigator from the apparatus. The purpose of the invention is to increase the efficiency of the device by reducing the sprinkling and improving service and repair. This goal is achieved by the fact that the gas nozzle is fitted with a cap mounted on the upper end of its coaxial to the fluid nozzle, while the lower section of the cap is located below the nozzles of the nozzle. The gas connection pipe is installed vertically. The lower sections of the gas nozzle and cap are flared. The gas pipe is equipped with a ballast weight. Due to the installation of a cap of the proposed configuration on each gas patron with its lower section located below the overflow slots, a fluid trap is created, which guarantees that there is no overshoot Iaaa in the space between the nozzles where the fluid is moving. This significantly reduces the sprigunos compared with the known device, while retaining its advantages in the uniform distribution of gas-liquid flows over the nozzle section. Free installation of a gas pipe with a half-pack that can move vertically relative to the Slot nozzle simplifies repair and maintenance of the sprinkler and reduces the sprinkler. Flanging of the lower section of each gas nozzle also reduces the spray bar I distribute the liquid more evenly on the nozzle. The installation of a ballast weight on each gas pipe allows us to avoid an increase in the splash guards, both when using light materials and when the load on the gas fluctuates abruptly. The implementation in each cap of the lower edge of the flanged improves the uniformity of the distribution of the liquid on the nozzle. The drawing shows an irrigation device for absorbing gases. It consists of liquid nozzles 1 with slots 2 located on their upper cut, yKpeiochennyh in the distribution plate 3. In each fluid nozzle is installed on top, freely, coaxially, with a gap a gas nozzle 4. Each gas nozzle is supported by its lower bead end on the nozzle 5. At the upper end of each gas pipe, from the outside, coaxially, with a gap in relation to the livestock pipe, a cap 6 formed by a L-shaped plate is reinforced. The latter is installed in such a way that About its lower flanging slice is located below the overflow slots by an amount equal to the hydraulic power of the device on gas. Each gas pipe with a cap relative to the liquid pipes is centered with a pin of $ 1 to 7. In addition, each gas pipe is equipped with a ballast weight 8, which can be installed on the hood. The device works as follows. The irrigating liquid located on the plate 3 passes under the cap 6 and overflows through the slots 2 in the liquid nozzle 1, gets onto the outer surface of the gas nozzle 4 and flows down the film onto the nozzle 5. Inside the gas pipe from the bottom up, gas is isolated from the liquid. With fluctuations in gas and liquid consumption, the ballast weight 8 prevents the gas nozzles with caps from bouncing. When locally lowering the nozzle or the non-rigidity of the distribution plate, the gas nozzles with caps independently Slide each other into the centering pins 7, all the while resting on the nozzle. When inspecting, cleaning and repairing, gas pipes with caps are freely and individually removed from the irrigation device. The coaxial arrangement of the gadic pipes 4 and liquid pipes 1 58 ensures an even distribution of gas and liquid streams over the cross section of the apparatus immediately after the irrigation device. Due to the fact that the cap creates a gas trap, in the space between the gas nozzles and the liquid, the fluid moves in complete isolation from the gas moving in the gas nozzle. This achieves a significant reduction in the splash hole when the nozzle is irrigated with this irrigation device in comparison with the known one. A water shutter is created due to the fact that the lower section of the cap is located below the overflow slots by an amount equal to the hydraulic resistance of the device in terms of gas. This value is taken from the condition of gas leakage through the water trap. When calculating the hydraulic resistance according to the known dependences, the gas velocity in the nozzle should be taken in view of the fluctuation of the gas load and the distribution of the gas across the apparatus. In order to completely prevent the spatter through the space between the coaxially arranged gas and liquid nozzles, the calculated gas velocity in the nozzle 4 should be taken as high as possible for this apparatus operating in this mode. In addition, due to the installation on each gas nozzle of the cap, the liquid on the irrigation device is more evenly distributed among the nozzles, which improves the uniformity of the nozzle irrigation. This is due to the effect of smoothing the waves of the liquid on its surface with a cap. Flanging the lower section of each gas pumping unit pipe also reduces the spray ratio, because the liquid flowing down the external surface of the gas pipe in the upper layers of the nozzle falls vertically, picked up partially by the gas flow and is carried away by Hivi through the mounting device. The flare deflects the flowing film of liquid away, which reduces the splash from the upper nozzle as the liquid moves along the walls of the nozzle rather than in its volume, and more evenly distributes the liquid along the nozzle in the space between the insulating nozzles. The free, vertically adjustable, installation of a gas nozzle with a cap in the liquid nozzle allows each gas nozzle independently of each other to be supported by its lower cut on the nozzle, which reduces the splash hole, since the gap between the lower cut of the gas nozzle and the nozzle is reduced. which skipped gas. Kroye order free. the installation of nozzles improves the maintenance and repair of the irrigation device, since for cleaning from contamination of the space between coaxially arranged nozzles, gas nozzles with caps are freely removed from above, cleaned and repaired outside the column, the plate with liquid patches remains inside the column. The latter circumstance greatly simplifies the fabrication of the irrigator, its installation and inspection. In a number of cases, for example, in the manufacture of gas pipes and caps made of light materials (vinyl plastic, plexiglas etc.), as well as in case of sharp fluctuations in gas loads, they can be lifted, bounced, carried away by gas flow, which increases. danger of sprigunous. Installing ballast weight eliminates this possibility. Making the lower section of the beaded cap allows the liquid to approach the overflow slits with less turbulence, which increases the uniformity of fluid outflow through the slits and creates a more uniform irrigation of the nozzle. Claim 1. Gas-absorbing device for absorbing gas, including a distribution plate and fluid pipes fixed in it with slots in the upper part and located coaxially inside. They have gas pipes, characterized in that, in order to increase the efficiency of the device by reducing splash guards, improving service and repair, the gas pipe is equipped with a coaxial-liquid pipe with a hood installed at the upper end, and the lower section of the bell is located below the slits of the liquid pipe. 2. A device according to claim 1, characterized in that the gas port is mounted for movement in the vertical direction. 891128 3, the Device in PP. 1 and 2, characterized in that the lower sections of the gas pipe and cap you polished with flared. 4. Popp device 2, characterized in that the gas cutting rod is provided with a ballast weight. Sources of information taken into consideration during examination eight 1. Golovachevsky Yu. A. Irrigators and nozzles of scrubbers of the joupling industry, M., Mashinostroenie, 1974. p. 13. .  2, USSR Author's Certificate No. 281436, cl. С О1 В 17 / 8О, 12.24.70. 3. Works NIUIf. Issue 23O, 1977, p. 124-126. S