RO106868B1 - Implements for caustic soda granulation - Google Patents

Abstract

The invention relates to a machine for granulation, by pearling, for granulating the soda caustic, obtained by a chemical process or electrochemistry. The machine is characterized by that but is made up of a prescribed tubular beam with cylindrical casing (1), two tubular bundles (2) in which are fixed to some pipes (3), a central pipe (4) having a smaller diameter than the other pipes, a bunch (8) at the top of the beam tubular, for caustic soda feed, sub shaped bulge, a reservoir (11) at the side bottom of the tubular soda bead caustic, in melt phases, with a mantle of heating (12) having at the bottom a plate (15) with one or more rows of nozzles (16) in which enters the conical teeth of the device electromagnetic, droplet generation, format from a rod (24) fixed to the central pipe (4), a fork (25) with conical teeth (26), an electromagnet (27) what creates an ascending-descending movement a the rod (24), thereby forming droplets and o conveyor belt (18) mounted in a housing (17) through which nitrogen is the role of solidification and cooling of droplets.

Description

The invention relates to a machine for granulating by pearl, intended for granulation of caustic soda, obtained by a chemical or electrochemical process.

There are known machines for obtaining solid caustic soda, called drum crystallizers, of granulated caustic soda, by solidifying in cooling towers with gases or inert liquids, which have a disadvantage of a complicated construction, large dimensions, especially for gas-cooled granulators. and a high energy consumption necessary for the transport of the cooling agent.

The apparatus according to the invention removes the above disadvantages in that it consists of a soda melt, consisting of a hopper, a tubular bundle with a mantle and a reservoir for molten soda, an electromagnetic device for generating drops and a covered conveyor belt. with a housing circulating the cooling agent (nitrogen); The soda in the form of lumps enters from the bunker into the pipes (which are heated outside with flue gas), where the melting takes place, the resulting liquid enters the reservoir and flows in the form of drops, through nozzles (as a large operating device for generating droplets) on a conveyor belt over which a stream of nitrogen flows to cool the soda granules.

The following is an example of embodiment of the invention, in connection with FIG. 4, which represents:

- fig.l, longitudinal section along the axis of the conveyor belt:

- Fig. 2, top view of the machine;

- Fig. 3, longitudinal section, perpendicular to the axis of the conveyor belt;

- Fig. 4, cross section in the tubular bundle area.

The equipment for granulating caustic soda, according to the invention, consists of a cylindrical casing 1, having welded at the ends two tubular plates 2, provided with holes in which pipes are fixed 3. The pipes are arranged in a beam, on concentric hexagons or concentric circles and they have a diameter of 50 ... 100 mm and a length of 1000 ... 2000 mm. The pipe in the center of beam 4 is smaller in diameter than the other pipes and is longer in length. In the intertubular space there are fixed transverse shocks 5, to intensify the heat transfer from the flue gases to the soda inside the pipes.

On the casing of the tubular beam there are two connections 6 and 7, respectively for the inlet and outlet of the flue gases.

at the upper surface of the pipe bundle is fixed, by means of flanges and screws, a hopper 8 for the supply of bulky caustic soda. The bunker has a flat lid, provided with a socket 9 for feeding and a central hole in which the central tube of the tubular bundle is fixed.

At the bottom of the tubular bundle are fixed, through screw flanges, a stainless steel sieve 10 and a reservoir 11, for collecting molten caustic soda. In order to maintain a certain value of the caustic soda melt fluidity, the reservoir 11 is covered, on the outside, with a mantle 12 through which flue gases circulate. Two connections for the inlet 13 and the exhaust gas outlet 14 are fixed to the casing.

Under the tank, a plate 15 with one or more rows of nozzles 16, located at equal distances, is fixed by welding or flanges. At the bottom, the tank is fixed by a housing, of approximately parallelepipedal shape 17, in which a conveyor belt consisting of an endless belt 18, made of a stainless steel screen, is mounted; with very small meshes, supported on two rollers 19 and 20. One of the rollers is driven by an electric motor mounted externally, which is not shown in the drawings. The housing of the conveyor belt is provided with a connection 21. for cooling agent entry, a connection 22, for cooling agent outlet and a connection 23. for evacuating deodacic granules, at a temperature that allows them to be directly packed.

The electromagnetic device, for generating the drops, is made up of a rod 24 mounted in the central tube of the tubular beam, which ends at the bottom with a fork 25 with more teeth, of conical shape 26. The teeth enter the nozzles 16. At the side from above. the rod is fastened to an electromagnet 27, which is powered by AC power. A timing relay, which is not shown in the drawings, determines an oscillating movement of the rod in an ascending descending direction with a certain amplitude and frequency, which can be adjusted.

The Bulgarian caustic soda is introduced through the connection 9 in the feed hopper 8 and enters the pipes, where the melting takes place on account of the heat given off by the combustion gases obtained from a furnace, by burning a fuel. The combustion gases enter through the connection 6 into the intertubular space of the beam, provided with baffles 5, and circulate perpendicularly on the pipes and exit through the connection 7, then being introduced through the connection 13 In the casing of the tank 11. Here, the combustion gases ensure the maintenance of the Topir at the temperature. desired. in order to ensure optimum fluidity for drop formation with a certain size.

By actuating the device for generating the droplets, the rod 24 will move, alternatively, in an upward and downward direction, with a certain frequency and amplitude, determining the formation of the droplets. Under the action of gravity the droplets detach from the base of the nozzles and fall on an endless band 18 which moves with a speed that is correlated with the frequency of droplet generation. In the opposite direction of the movement of the band 18, a stream of nitrogen is sent through the space above the band to cool and solidify the droplets. Nitrogen circulates at a speed that is a function of the granule flow rate. Next, the nitrogen exiting through the connection 22 is passed to a heat exchanger for cooling and then reintroduced into the circuit The cooled caustic soda granules, at a temperature of 40 ... 50 ° C, exit through the connection 23 and fall into the a bunker, which is not represented in the drawings.

The equipment for granulation of caustic soda has the following advantages:

- reduced energy consumption for the transport of the cooling agent;

- simple construction;

- allows the automatic adjustment of the technological parameters;

- high safety in operation.

Claims (1)

Claim Equipment for granulation of caustic soda, characterized in that it consists of a tubular bundle provided with a cylindrical shell (1), two tubular plates (2) in which are fixed some pipes (3), a central pipe (4) having the diameter smaller than the other pipes, a hopper (8) at the top of the tubular bundle for feeding with Bulgarian caustic soda, a reservoir (11) at the bottom of the melting bundle, provided with a heating jacket (12), at the side lower a plate (15) with one or more rows of nozzles (16) in which the tapered teeth of the electromagnetic drop generating device formed by a rod (24) fixed to the central pipe (4), a fork (25) with conical teeth (26), an electromagnet (27) which creates an upward movement106868 downstream of the rod (24), thus forming the droplets and a conveyor belt (18) mounted in a housing (17), through which nitrogen circulates c has the role of difficult and cooling droplets.