Electrolyzer with horizontal mercury cathode

专利摘要:
Mass transfer to the surface of a substantially horizontal, foraminous gas-evolving electrode, suspended in the electrolyte pool over a co-operating electrode, is improved by inducing a vigorous multiple recirculation motion of the electrolyte to and from the interelectrodic gap through the openings in the foraminous electrode exploiting the gas lift of evolved gas bubbles by means of a multiplicity of baffles, alternatively slanting one way and the opposite with respect to the vertical axis, and defining, with their lower edges, an alternating series of large and small areas over the foraminous electrode surface; electrodes and cells incorporating the hydrodynamic means to effect recirculation are also disclosed.
公开号:SU1364243A3
申请号:SU802914400
申请日:1980-05-02
公开日:1987-12-30
发明作者:Пеллегри Альберто
申请人:Оронцио Де Нора Импианти Элеттрохимичи С.П.А. (Фирма)；
IPC主号:

专利说明:

The invention relates to designs of electrolytic cells with a horizontal mercury cathode.
The aim of the invention is to reduce power consumption.
FIG. t shows an electrolyzer with a horizontal mercury cathode, longitudinal section; in fig. 2 - anodic construction, axonometrics; On fig.d, 3 - part of the anodic structure with inclined partitions;
The electrolyzer consists of a housing 1. Current is supplied to the anode through four conductive copper rods 2, screwed onto titanium sealing rings 3, welded to titanium primary distribution bars 4, Eight titanium secondary distribution bars 5 welded to two primary bars 4, and to the lower edges of the secondary bars 5 welded titanium mesh 6, having an anode electrocatalytic coating and serving as an anode Titanium sleeves 7, welded to titanium sealing rings 3, prevent copper conductive rods from contact with the electrolyte chlorine and chlorine.
The upper edges of the titanium barriers 8 are inclined one to the other, with the angle between the partition and the anode being 45-75 °, and the area of the anode inside these partitions refers to the area of the anode as (2-6): 1 Titanium partitions 8 the form of elongated sheets are welded or fixed with brackets on each secondary distribution bar 5. The lower edges of the partitions 8 form an alternating row of large sections A and small sections B on the surface of the anode grid 6, as a result of the liquid mass into which the anodic assembly It is divided by partitions B into a series of volumes, each of which is bounded by the surfaces of two adjacent partitions. In the electrolyzer there is a mercury cathode 9 passing along the bottom 10 of the electrolyzer.
Bubbles of chlorine gas (Fig. 3), which are released in large areas A, block the path converging at the top of the surface of two adjacent partitions 8.
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bubbles. Chlorine gas bubbles emitted in small areas of the anode rise through the mass of electrolyte enclosed between the surfaces of two adjacent partitions 8 that diverge at the top,
Liquid masses containing electrolyte and chlorine gas bubbles dispersed in the electrolyte and enclosed between two surfaces converging at the top and two surfaces diverging at the top, have a different density, resulting in an upward movement inside the liquid mass enclosed between the converging surfaces and in doing so, a downward movement is established within the fluid mass enclosed between the diverging surfaces.
The movement shown by the arrows in FIG. .3, is effective for transferring concentrated brine over the top of the interelectrode distance and for reducing the high differential in concentration between the brine within the electrode gap and the brine above the anode design due to depletion or depletion of chlorine anions by electrolysis. The movement in the brine countercurrent causes the brine to pass through the anode grid vigorously, whereby the transfer of conventional mass (chlorides) is greatly improved. This effect is almost uniform, while effectively preventing concentration gradients along the surface of the anode.
The table shows the voltage data on the electrolyzer.
. Test conditions: current density 11 kA / m; NaCl brine concentration 240 g / l; temperature 70 C.
As can be seen from the table, the angle of inclination of the partitions is 45-75 °, and the area of the anode inside these partitions refers to the area of the anode between them as (2-6) i1. As this ratio increases, the current output drops.
During the operation of the electrolytic cell, chloride ions are discharged onto the surface of the anodes, resulting in the formation of molecular chlorine, while sodium ions are reduced on the mercury cathode, forming sodium amalgam - mercury, which is continuously released through the outlet. Then
the amalgam passes through decomposition Continued Tablei
fie.z
Editor A.Lezhnina
Compiled by V.Mes Nzhinov
Tehred L. Serdyukov and Proofreader V. Booth ha
6386/58
Circulation 613 Subscription
VNIIPI USSR State Committee
for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5
Production and printing company, Uzhgorod, st. Project, 4

权利要求:
Claims (1)
[1]
Claim
An electrolyzer with a horizontal mercury cathode, comprising a housing, an anode made in the form of a lattice or grid of metal with an electrocatalytic coating with partitions located on the side opposite the mercury cathode, characterized in that, in order to reduce energy consumption, adjacent partitions are tilted one to one the other and the angle between the partition and the anode is 45-75 °, and the area of the anode inside each pair of partitions refers to the area of the anode between each pair as (2-6): 1.
Configuration Tension- Exit subjects cell current electrodes Ki, B % with partitionsAngle Attitudeon the- areasclo- A / Bon the, hail
The proposed cell
40 1,0 4,55 96.5 40 2.0 ' 4,50 96.5 < 45 1,0 4.40 96.5 45 2.0. 4.40 96.5 45 4.0 4.30 96
P birth tables | Configuration Tension- Exit 5 subjects cell current 10 electronic] with lane'' Tilt angle, deg childbirthRelations of areas, A / B Ki, B Z fifteen 45 6.0 4.30 96 60 1,0 4.40 96.5 60 1.4 4.30 96.5 20 60 2,3 4.25 96 60 3,5 4.25 96 25 60 5,0 4.25 96 60 6.0 4.25 96 75 1,0 4.40 96.5 thirty 75 1.3 4.40 96.5 75 2.0 4.35 96.5 35 75 4.0 4.25 96 75 5,0 4.25 96 75 6.0 4.25 96 40 80 1,0 4,55 96.5 80 3.0 4.25 96 45 80 6.0Famous electro leaser 4.25 96 -  - 4.6 96.5
fizz

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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IT22318/79A|IT1165047B|1979-05-03|1979-05-03|PROCEDURE FOR IMPROVING THE TRANSPORT OF MATERIAL TO AN ELECTRODE AND RELATED HYDRODYNAMIC MEDIA|

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