This application is a 371 OF PCT/DE2003/003431 field Oct. 16, 2003.
The invention relates to an electrolytic device for halogen gas production from aqueous alkali halide solution in several plate-type electrolytic cells stacked and arranged side-by-side and provided with electrical contacts, each of the cells provided with a housing consisting of two half-shells made of electrically conductive material and having external contact strips on at least one housing rear wall, said housing being equipped with devices for feeding electrolytic current and electrolysis reactants and for discharging electrolytic current and products, with anodic and cathodic electrodes that evolve gas during normal operation and with gas outlets.
Electrolytic cells are well known and a typical example of state-of-the-art technology is described in DE 196 41 125 A1. A device of this type ensures adequate gas separation in the upper rear zone by means of a guide plate arranged towards the membrane and which is in addition used for sufficiently wetting the electrolytic membrane during the electrolyser operation. However, difficulties in maintaining such a wetting may arise from interruptions of the electrolyser operation.
In order to protect the standard coatings it is possible to polarise the cell during downtime periods such as start-up, shut-down, service interruptions or failures. This applies whenever the cell must be filled and heated prior to starting operation. When shutting down the electrolyser it is likewise imperative that the polarisation be maintained until the anodic liquid is purged from chlorine and cooled down.
In case the electrolyser membrane is not sufficiently flooded in the upper cell zone, the single element technology as described in DE 195 41 125 A1 provides for a liquid level adjustment in the half-shells via the overfall weir of the standpipe. The polarisation current must not be selected arbitrarily but has to exceed a given threshold.
Depending on the type of material used for the standpipe, such as metal or PTFE, and on its chamfered angle, gas zones more than 20 mm high may be established in the upper part of the cell in the cold state. Investigations revealed that the membrane installed in the electrolytic cell is not gas-tight but presents a diffusion rate that depends on the molecular size, irrespective of the differential pressure between the anodic and cathodic chambers. As hydrogen gas is generated at the cathode and chlorine or oxygen gas are generated at the anode depending on the current density, hydrogen gas diffuses in the anodic chamber on account of its substantially smaller atomic size. The amount of the anodic gas build-up when the polarisation is switched on must be such that the explosion limit of the chlorine/hydrogen mixture or oxygen/hydrogen mixture is assuredly not reached. The production rate of oxygen or chlorine gas to be set is directly proportional to the polarisation current and also depends on the membrane surface area in the gas chamber. An electrolyser as described in DE 196 41 125 A1 requires a polarisation current of approx. 28 A, said device having PTFE standpipes and a gas chamber 20 mm high in the warm state and up to 30 mm high in the cold state of the electrolyser.
The object of the invention, therefore, is to design a device that overcomes the aforementioned difficulties and that requires lower polarisation currents.
The object of the invention is achieved by providing built-in components to be installed in the electrolyser in such a manner that the liquid level is raised so as to minimise the volume of the remaining gas zone and to reduce the minimum current required for polarisation. This method permits the filling of the cell element over the top edge of the membrane so that the minimum current required for polarisation with the element filled, hence in the absence of a hydrogen gas chamber contacting the electrolytic membrane, is achieved even by currentless polarisation.
The invention provides for built-in components to be installed in the appropriate electrolytic chamber and suited for playing a role in the hydraulics and dynamics of the liquid/gas mixture. Said built-in components are characterised in that
In a particular embodiment of the invention, the interspace between the trough and the upper side of the electrolytic chamber is implemented as a gap, preferably of 2 to 3 mm width. In a particularly preferred embodiment such gap is inclined both outwards and upwards with respect to the horizontal plane as seen from the electrolytic membrane. The gap may also have a variable width, the adjacent interfaces being straight, corrugated or arched.
In a further embodiment of the invention, the interspace between the trough and the upper side of the electrolytic chamber is equipped with a perforated plate arranged parallel to the electrolytic membrane or slightly inclined therefrom so that the holes have the function of a perforated diaphragm.
According to a further embodiment of the invention, the interspace between the trough and the upper part of the electrolytic chamber is equipped with a duct bundle, the axes of the ducts lying in the plane of the interspace. The ducts need not be circular but may also be honeycomb-structured. The greater stiffness of this structure constitutes a particular advantage.
A further embodiment of the invention provides for beads, webs, nipples or other spacers to be installed in the interspace between the trough and the upper part of the electrolytic chamber, said spacers being used to geometrically delimit said interspace and to secure the implementation of the defined flow pattern.
According to a further embodiment of the invention, the members which form the trough, inlets, outlets and related supports are at least partly coated to ensure corrosion protection.
A further advantage of the invention is that the lower part of the trough also assumes the function of gas pre-separation which calms down the flow and dampens or even prevents pulsation.
A leak of the trough will not necessarily jeopardise the operation of the electrolytic cell since the cell built-in components are sealed inside the cell, which represents a further advantage.
The device according to the invention can be retrofitted as an assembly into existing plants, which is a further advantage.
The device designed in accordance with the invention, moreover, has a particular advantage in that the anodic and cathodic rear walls need not specific geometric requirements, hence they may be straight, corrugated or inclined.
In the following, the invention will be illustrated by means of an example.
The two half-shells of the electrolytic cell are formed by anode rear wall 1 and cathode rear wall 2 and firmly clamped by means of bolted connection 3. The anodic electrode 4 of louver-type design and the cathodic electrode 5 are arranged approximately in the centre of the electrolyser by means of support and fixing elements not shown in the FIGURE, the electrolytic membrane 6 being located between electrodes 4 and 5.
The anode side shows the trough 7 designed as a folded sheet 8. The chlorine gas that forms at the louver-type anodic electrode 4 and the electrolytic liquid simultaneously enter as a foam the interspace 9 located between sheet 8 delimiting trough 7 and electrode 4. The major part of the foam bubbles collapses underneath trough 7 so that they enter pre-separated into trough 7 via interspace 9 and gap 10.
In the event of a shutdown, the amount of liquid admitted to the cell is such that its level reaches the upper end 11 of gap 10. This method permits to completely wet membrane 6 on the anode side, which reduces the quantity of hydrogen diffusing from the cathode to anode side.
The cathode side shows trough 12 designed as bent sheet 13. The hydrogen gas formed at the flat cathodic electrode 5 and the electrolytic liquid simultaneously enter the interspace 14 located between sheet 13 delimiting trough 12 and electrode 5 as foam bubbles. The major part of the foam bubbles burst underneath trough 12 so that they are pre-separated and enter trough 12 via interspace 14 and gap 15.
In the event of a shutdown, the amount of liquid admitted to the cell is such that its level reaches upper end 16 of gap 15. This method permits wetting of the complete membrane 6 on the cathodic side, which prevents hydrogen diffusion from the cathodic to the anodic side.
Number | Date | Country | Kind |
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102 49 508 | Oct 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE03/03431 | 10/16/2003 | WO | 00 | 5/25/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/040040 | 5/13/2004 | WO | A |
Number | Name | Date | Kind |
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4839012 | Burney, Jr. et al. | Jun 1989 | A |
5194132 | Hartmann et al. | Mar 1993 | A |
6214181 | Iacopetti et al. | Apr 2001 | B1 |
6503377 | Borucinski et al. | Jan 2003 | B1 |
Number | Date | Country |
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197 40 673 | Mar 1999 | DE |
Number | Date | Country | |
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20060006062 A1 | Jan 2006 | US |