SU1366478A1 - Device for hydrogen sulfide desorption - Google Patents

Description

(21) 3918997 / 23-26

(22) 07/01/85

(46) 01/15/88. Bksh. № 2

(72) V.P. Gorshkov, A.P. Salyuk

and S.M. Tymchuk

(53) 628.543 (088.8)

(56) USSR Author's Certificate No. 981234, cl. C 02 F 1/00, 1981..

(54) DEVICE FOR HYDROGEN DISPOSITION

(57) The invention relates to devices for purifying hydrogen sulphide-containing water by electrochemical methods, as well as for purifying drinking water and wastewater, and allows increasing the degree of hydrogen sulphide desorption, simplifying the design and reducing the size of the device. The device comprises a housing divided into annular ducts for moving fluid.

which are formed by three metal flat ring electrodes dividing the body into two identical annular spaces. A metal rod-electrode is installed on the end wall opposite to the gas outlet pipe between the metallic rings-electrodes, the length of which does not reach the gas output nozzle, and two adjacent rings between which the input tangential channel is located are connected to a low-voltage current source and form a uniform electric field, and the middle ring electrode and the metal rod are connected to a high-voltage current source in such a way that the positive pole of the current source is connected to the meta cyclically rod. 1 hp f-ly, 1 ill., 1 tab.

cl

with a

05

N

00

The invention relates to devices for purifying hydrogen sulphide-containing waters by electrochemical methods and can be applied in the field of purification of drinking water from waste waters of mining and chemical enterprises, in particular in the production of sulfur, oil-producing, and purification of water saturated with gases, such as geothermal, used directly for heat supply.

The purpose of the invention is to increase the degree of desorption of hydrogen sulfide, simplify the design and reduce the size of the device.

The drawing shows the proposed device, the cut.

The device consists of a housing 1 made of a dielectric material, equipped with tangentially connected inlet 2 and outlet 3 liquid nozzles, divided into two annular spaces by three flat metal rings-electrodes 4, 5 and 6. In housing 1 is mounted on one end wall .also along the axis of the metal rod-electrode 7, and on the other end wall - the nozzle 8 for the output of the desorbed gas. Electrodes 4 and 6 are connected to a low-voltage current source, and electrodes 4 and 7 are connected to a high-voltage current source.

The formation of annular spaces with three metal flat annular electrodes with tangentially connected inlet and outlet nozzles makes it possible to create a spiral motion of fluid from the periphery to the center in one annular space and from the center to the periphery and the outlet nozzle in another annular space. Connecting to a low-voltage source, the current of the electrodes, between which the inlet is located, leads to the electrolysis of part of the water, the formation of gas bubbles, their coalescence and contributing to the removal of dissolved gas. When switching the current source to another plate, you can change the purpose of the pipes.

The device is supplied with a metallic rod located along the axis of the apparatus case between the metal rings-electrodes, and a connection to a high-voltage current source, a positive pole to the rod and

the middle ring electrode to the negative pole allows the creation of a non-uniform electric field, which promotes the ascent of gas bubbles to the surface of the liquid and the introduction of gas into the region of the metal rod.

The execution of the rod electrode,

the length not reaching the gas outlet nozzle is due to the need for the desorbed gas to pass from the electrode space of the rod - electrode to the outlet nozzle,

d The distance between the inner diameter of the metal rings and the outer diameter of the metal rod, equal to not less than the distance between two adjacent electrode disks,

Q is due to the need to create a channel for the passage of water from one channel to another and the need to have an air gap only to create a non-uniform electric field in the absence of current.

The device works as follows.

When applying voltage from current sources A and B to electrodes 6.4 or.

0, 4.5 and 4.7. To the inside of the housing 1, made of an insulating material, a process liquid is fed through the inlet 2, which begins to twist. The velocity of the fluid increases and the pressure decreases, as the fluid moves towards the center, the velocity increases further, the pressure decreases and the liquid boils. . To increase the gas content of the liquid and increase the yield of dissolved gases, an electric current is passed through electrodes 6 and 4 or (and) 6 and 5. When this happens partially electrolysis

g of water with the formation of electrolysis gases and their subsequent coalescence both between themselves and with the dissolved gas. Gas bubbles under the action of Archimedean forces and forces

the electric field formed by electrodes 4 and 7 is collected in the region of the central rod of the electrode 7 and is outputted through the pipe 8. The waste liquid, continuing to move, enters the channel between the ring electrodes 4 and 5 and further to the outlet pipe 3.

Example. At the entrance of the device was fed water containing 20 5

ten

15

, 3t3 7 "

70 MG / L of hydrogen sulfide, which is in molecular form, with a temperature of 40 ° C in a volume of 1.5; the current density flowing between electrodes 6 and 4 varied in the range of 3-4 A / dm; the voltage on these electrodes is 4-6 V, and on the electrodes 4-7 600 V; the ratio of the input velocity to the output velocity, i.e. in the interelectrode space, 3. The cleaning efficiency was determined by the amount of hydrogen sulfide remaining in purified water.

The efficiency of water purification at various concentrations of hydrogen sulfide in the source water and the amount of electricity consumed required for desorption is given in the table.

Claims (1)

1. Device for desorption of hydrogen sulfide from water, containing cyl. body connected to the tangentially inlet and outflow water inlets, gas outlet inlet on the body cover along its body and an annular partition, which, in turn, increases the degree of desorption of the core, simplifies the design and clears the device dimensions , the core is made of dielectric material, the partition is made of electrophore, the case is additionally supplied with electrodes made in the form of disks with central holes located on the lid and bottom, and a rod electrode, scattered at the bottom of the device for its height K is less than the height, and the disk electrons and the partition are connected to a low-voltage current source, and the perpendicular and rod electrode are connected to a voltage source in such a way that 2, Device no.n.l, in that the spacing between the electrode discs and the surface of the rod is not less than the distance between the bulkhead and the discs of the electrodes. 20  one Note. The current on the electrodes 4 and 7 was within 17-25 tA. ten 15 - 25 neva electr is an anode, 366478 a chassis, tangentially connected water inlet and outlet nozzles, a gas outlet nozzle placed on the housing cover along its axis, and an annular partition, characterized in that the body is designed to increase the degree of hydrogen sulphide desorption, simplify the design and reduce the overall dimensions of the device made of dielectric material, the partition is made of electrically conductive, the case is additionally equipped with electrodes made in the form of discs with central openings located on the lid and bottom of the device, and a rod electr ode placed at the bottom of the apparatus along its axis, the height of which is less than the height of the device; the disk electrodes and the partition are connected to the low-voltage current source, and the partition and the rod electrode to the high-voltage so that the rod 20 one the neva electrode is the anode, 2, Device no. N. L., Characterized in that the distance between the electrode discs and the surface of the rod is not less than the distance between the partition and the electrode discs. / /