SU1126330A1 - Liquid spraying device - Google Patents

Abstract

1. A DEVICE FOR DISINFECTING A LIQUID, containing a water distribution collector connected via taps to horizontal pipes below it, in the upper part of which a perforation is made along their length and reflective shields mounted on racks, characterized in that in order to ensure even and stable spraying fluid when its pressure changes, the water distribution manifold is provided with perpendicularly disposed pipes, the number of which is equal to the number of racks, and each u p is set free in sootvetstvunidem her pipe. 2. The device according to claim 1, which is distinguished by the fact that each strut is made at the end entering the (L. branch pipe, with thickening. 3. The device according to claim 1, about tl. Is. Perch that each branch pipe on the end facing the reflector, it is made with an inner collar that overlaps the size of the stand thickening. 4. The device according to claim 1, differs from 8 so that the working 00 surface of the shield is roughened.

Description

11 The invention relates to a device for spraying liquids and can be used in the energy, chemical, food and other industrial sectors. A device for spraying a liquid is known, which contains a collector for supplying liquid, on which nozzles with channels for discharge of liquid CO are installed. However, this device is characterized by uneven irrigation of packed columns with fluctuations in the pressure of the liquid in the collector. The closest to the proposed technical essence and the achieved effect is a device for splashing liquid containing a water distribution collector connected through taps with horizontal pipes located below it, in the upper part of which along their length there are perforations and L2J reflectors mounted on racks . A disadvantage of the known device is the deterioration of splashing fluid when its pressure in the pipes changes due to fluctuations in the supply voltage and disturbances causing turbulization of the flow. When the pressure in the pipes decreases, the liquid spreads poorly along the lower surface of the shield, as a result of which the irrigation area of the nozzle decreases. With an increase in the pressure of the liquid, the spray formation appears when the jet strikes the shield, which contributes to the dripwood and uneven irrigation of the nozzle. The purpose of the invention is to ensure uniform and stable sprinkling of the backbone when its pressure changes. This goal is achieved by the fact that in a device for spraying a liquid containing a water distribution manifold, connected via taps to horizontally arranged pipes beneath, in the upper part of which perforations are made along their length, and reflector panels mounted on racks, the water distribution manifold is perpendicularly arranged pipes pipes, the number of which is equal to the number of racks, and each rack is installed freely in the corresponding pipe. 0 In addition, each rack is made at the end, which enters the nozzle with a thickening. Each nozzle at the end facing the reflector is made with an inner collar overlapping the size of the stand thickening. In this case, the working surface of the shield is made rough. FIG. 1 shows a device for spraying a liquid, an obshcheid, FIG. 2 shows a section A-A in FIG. . The device for spraying liquid contains a water distribution collector 1 connected via taps (not shown) with pipes 2 horizontally located with it, in the upper part of which perforations 3 are made along their length and reflector plates 5 are mounted on racks 4. The distribution manifold 1 is provided with a perpendicular The pipes 6 are arranged with pipes 6, the number of KOTopbix is equal to the number of racks 4. Each rack 4 is installed freely in its corresponding pipe 6 and is made at the end of the pipe 6 with thickening 7. Each nozzle 6 at the end facing the reflector 5 is made with an inner collar 8 that overlaps the size of the thickening 7 of the pole 4. The working surface of the flap 5 is roughened. The device works as follows. Water is supplied to the pipes 2, from where through the perforation 3 it flows out in the form of streams to the outside and falls on the reflective surface 5. Spread out on the lower surface of the shield 5, the liquid wets it and then drains onto the irrigated surface, creating a longitudinal wetting zone on it. Depending on the pressure of the liquid, the reflective shield 5 can be raised or lowered due to the mobility of the pillars 4 installed in the nozzles 6. To limit the mobility of the racks 4, the nozzles 6 attached to the manifold 1) are equipped with shoulder 8 and the pillars 4 It is necessary to eliminate the dependence of the quality of water distribution on the flow rate of a liquid. The greater the flow rate of water, the higher the flap 5 rises. In the equilibrium state j, when the impact force of the jet is equal to the weight of the flap 5, the latter stops. Thus, the spreading of the fluid over the surface of the shield 5 ceases to depend on its consumption. The water pressure influences the force of its impact against the shield 5. The mobility of the shield 5 provides the same force of impact of the jet at various flow rates and thus avoids increased splash formation with increasing flow rates. The distribution of fluid in the prototype over the irrigated zone in the case of smooth flaps 5 reflects the advantageous flow of fluid from the flap of the flap. In the proposed device, the surface of the shield 5 is roughened, since irregularities (roughness) of the surface of the shield 5 serve as sources for the formation of liquid droplets, and the uniform distribution of roughness contributes to uniform surface irrigation. . The invention can be used in many areas of industry, in particular in the energy industry in Sepax. For efficient operation of the economizer, it is very important to evenly distribute the water over the cross section of the contact chamber and completely wet the entire surface of the nozzle, which ensures a rational design of the water distributor. The proposed water distribution device allows to increase the wettability coefficient of the nozzle, which is equal to the ratio of the wetted surface to the full geometrical one, and in turn it determines the necessary volume of the contact chamber. . where er is the calculated amount of heat, Zr, K., is the volume coefficient of heatwatt. exchange; ui is the average temperature head, K. g As can be seen from (1), an increase in the coefficient 4f leads to a decrease in the volume of the contact chamber or a decrease in size and material consumption, and consequently, to a resistance of the contact economizer, i.e. to lower capital and operating costs. Even with an increase in the wettability coefficient всего of only 10%, the volume of the contact chamber decreases by 0.1%. According to the characteristics of the most common types of LZZ nozzles, the heat exchange surface in contact economizers is relatively large to about 90 for randomly lying Raschig rings of 50x50x5 mm and about 200 for Raschig rings of 25x25x3 mm with similar piling. Thus, the heat transfer surface is reduced for the Rings 50x50x5 mm, most often used in the contact chamber, by 9 V (m), and 1 m of the heat exchange of the contact economizer costs 10 rubles. For the most common economizer, the production capacity of the necessary contact chamber object is 23 m. Under the condition of an increase in wettability by 10%, the heat exchange surface will be reduced in this case by m, i.e. the cost of the heat exchange surface will decrease by 2070 rubles. If we consider that not one, but - economizers are installed at a large station, the economy will be: E 2070.p., rub. A decrease in the volume of the contact chamber B leads to a decrease in operating costs by reducing the resistance of the contact economizer. When calculating economizers installed at TPPs, operating costs are reduced by a factor of h.

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Claims (4)

1. A LIQUID SPRAYING DEVICE, comprising a water distribution manifold connected through pipes to horizontally arranged pipes, perforated along the length of the pipes, and reflective shields mounted on racks, characterized in that, in order to ensure uniform and stable spraying of liquid when its pressure changes, the water distribution manifold is equipped with pipes, perpendicular to the pipes, the number of which is equal to the number of racks, and each rack has set free in the corresponding pipe. 2. The device according to p. 1, characterized in that each rack is made at the end included in the pipe, with a thickening. 3. The device according to claim 1, about t l. characterized in that each pipe at the end facing the reflector is made with an inner flange overlying the size of the thickening of the rack. '' 4. The device pop. 1, characterized in that the working surface of the shield is made rough. „1126330 1 1126330