DE2919527A1 - Electrolysis of dilute sodium chloride solns. - to produce dilute hypochlorite solns. having series of horizontal chambers in cell with vertically mounted intermeshed electrode plates - Google Patents

Abstract

Electrolytic cell to produce sodium hypochlorite from a dil. soln. of common salt (NaCl) or sea water. It has a row of bi- or mono-polar cell elements arranged as horizontal chambers with vertical electrode plates. The electrolyte flows along the horizontal passages created by these plates. The electrodes intermesh such that the electrode faces are vertical while the flow passages are horizontal. The electrodes are rectangular plates made from Ti attached to a horizontal plate. Alternate horizontal plates are connected to the opposite poles of a d.c. source and the electrodes project up and down from the horizontal plates. To produce dil. hypochlorite solns. for disinfection, cooling water treatment and effluent treatment. Does not require circulation of the electrolyte liquor nor intermediate removal of the H2 generated.

Description

Electrolyser for the production of sodium hypochlorite

The invention relates to an electrolyser for the production of sodium hypochlorite by electrolysis of dilute saline or sea water.

Sodium hypochlorite solutions have gained great importance e.g.

for disinfection purposes, for cleaning waste water and in particular for cooling water chlorination. Up to a maximum concentration of around lo g / l Active chlorine can be used to produce hypochlorite solutions directly by electrolysis of dilute sodium chloride solutions getting produced. The sodium chloride solution is made by dissolving salt in water obtained, but you can also use seawater, provided it has a sufficient chloride content (US Pat. Nos. 3,849,281, 3,893,902, 3 974 051 and DE-OS 28 06 441).

If the sodium chloride solution is obtained by dissolving solid salt, for economic reasons, implementation of the in the sodium chloride contained in the solution is desirable. On the other hand, the solution must be so the electrolysis proceeds with an acceptable current yield, a certain minimum content contain chloride. So one will strive to find solutions with the highest possible Produce active chlorine content. If you increase the active chlorine content too much, it decreases the current efficiency, since the generated hypochlorite is further oxidized. To anyway To achieve an optimal power output, it is important to find the solution in one-off To give passage through the cell, i.e. not to recirculate. So becomes the effective Current yield is the mean value between the high current yield at the inlet and the low current yield at the outlet.

For a given current density, there is an increase in the hypochlorite content in the solution proportional to the length of the electrode in the direction of flow and vice versa proportional to the flow velocity. A large increase in the hypochlorite content To get it in one pass, one therefore either requires a large electrode length in the direction of flow or a low flow velocity.

Low flow velocities have the disadvantage that they too Crusting and clogging of the cell result, though the sodium chloride solution, as is usually the case, is not completely free of calcium and magnesium salts. In addition, a pure plug flow can hardly be achieved without backmixing.

If the flow rate is increased, the length of the electrode increases in the direction of flow of the electrolyte so large that it is reasonable to adhere to it geometrical dimensions the electrode must subdivide. With the most common Upward flow of the electrolyte must be made at the top of the electrolysis chamber ensure the separation of the hydrogen developed during electrolysis before the electrolyte is allowed to enter the next chamber. An intermediate separation The gas is not required if you are running the electrolyte at very high speed can flow in an annular gap, the walls of which form the electrodes, as e.g.

is the case with the electrolyzers disclosed in US Pat. No. 3,873,438.

At such high speeds, however, a large number of elements have to be used connected in series in order to achieve higher active chlorine levels. Also is the pressure loss is high and the pump energy to be applied is considerable.

In seawater electrolysis, there are particularly high levels of active chlorine for the purpose of utilizing the sodium chloride content as much as possible, it is not necessary, because the raw material costs practically nothing. Even so, there is a higher hypochlorite content particularly Desired with regard to the intermediate storage of the hypochlorite solution.

It is mainly used for the smooth running of the electrolysis but it is important that the electrolyte passes through the electrode gap at high speed flows, otherwise the space between the electrodes grows quickly with deposits that fail in the strongly alkaline cathode boundary layer.

With the required high speeds even medium ones are Active chlorine content generally only through series connection on the flow side to achieve several cell elements or by recirculation. For recirculation a circulation pump must be installed, which requires additional investment costs, requires a certain amount of maintenance, and the overall energy requirement of the system is not insignificant elevated. When several electrolysers are connected in series on the flow side again, as already mentioned, most electrolysers have the disadvantage that one must ensure an intermediate separation of the hydrogen.

The invention is based on the object of providing an electrolyser according to to create of the type mentioned, with which the disadvantages mentioned can be avoided are. This object is achieved according to the invention in that a number of bipolar or monopolar superposed, between two pressure plates tense Cell elements through which the electrolyte flows one after the other, wherein the elements are designed so that their electrode surfaces are vertical, the The direction of flow of the electrolyte is horizontal.

The invention will now be described with reference to the drawings. In the latter are: FIG. 1 a longitudinal section of the electrolyzer according to the invention in FIG the enlargement in single-flow execution.

FIG. 2 is an enlarged cross section of the electrolyzer according to FIG. 1.

3 shows a longitudinal section of the electrolyser according to the invention in the case of a double-flow Embodiment and FIG. 4 shows a further embodiment of the electrolyzer according to the invention.

In the preferred embodiment of the invention according to FIGS.

1 and 2, the electrolyser consists of a number of one above the other arranged cell chambers 1. The side wall of the chamber forms a frame 2 electrically insulating material, the top and bottom partitions 3 from one Metal that is corrosion-resistant to the conditions of electrolysis is, preferably titanium. The sheets are provided with lamellar electrodes 4, that interlock. They are preferably also made of titanium and are with electrically conductively connected to the base plates in a suitable manner. On the website, which should act as an anode, are the lamellas with a suitable coating, e.g. platinum, platinum-iridium or mixed oxide, the cathode consists of uncoated Titanium or other suitable metal. The upper partition plate 3 forms at the same time the lower end for the chamber above, the lower partition 3 the upper closure for the chamber below. The dividers are therefore on both sides provided with electrode lamellae 4. In the preferred bipolar form, the sheets have on one side anode lamellas, on the other cathode lamellae. At the same time possible monopolar circuit are alternately sheets, which are on both sides with anode lamellas, and those that are equipped with cathode lamellas on both sides are installed.

For sealing to the outside there are between the frame and partition walls Seals 5. The elements are clamped together between two pressure plates 6.

The electrolyte flows horizontally through the gaps between the electrodes. Hydrogen deposited at the cathode is mostly used by the flowing Electrolytes flushed with it. At low flow velocities and high gas Liquid ratio Part of the gas also rises up the lamellae and collects as a gas film in the gap under the upper partition, where it does not significantly hinder the electrolysis.

The electrolyzers can be built with a single or multiple flow.

In the single-flow version (Fig. 1) the partition walls are each closed at one end, provided at the other end with an opening 7, which the Establishes connection to the neighboring chamber. The electrolyte usually leaks through the opening in the lower divider into the chamber through the one on the other Side arranged opening in the upper partition into the upper chamber. The direction of flow but can also be reversed. Assuming a certain minimum speed, can even under load the electrolyte the plate elements in reverse order flow through from top to bottom. That makes it easier to keep the cell clean, there in this way particles that are in aerodynamically disadvantaged places have fixed, flushed out when the direction of flow is reversed and downwards be discharged from the electrolyser.

In the double-flow design according to FIG. 3, there are two chambers in each case connected in parallel on the liquid side.

If it is necessary to cool the electrolyte in between, can this after flowing through a certain number of elements according to FIG. 4 from the Electrolyser are led out. The partition wall 8 is given at the relevant point no opening, the adjacent plastic frames with inlet and outlet nozzles are used instead for connecting the cooler 9.

The number of electrode chambers can be varied and so can the electrolyser can be optimally adapted to the special requirements.

Example: Hypochlorite solution should be used for cooling water chlorination Electrolysis can be obtained from sea water. With consideration for the interim storage The active chlorine content of the solution for shock chlorination should be at least 2.4 g / l. The flow velocity of the electrolyte should be 0.6 m / s to avoid deposits to avoid on the cathodes.

The current density and the gap between the electrodes are specified.

The length of the electrodes in the chambers should be approx. 80 cm.

From this data, for example, an increase in the active chlorine content can be calculated when flowing through a chamber of 0.2 g / l. For an active chlorine content of 2.4 g / l 12 12 12 chambers o, 2 are to be connected in series with a single passage of the solution.

Claims (9)

Claims 1. Electrolyser for the production of sodium hypochlorite characterized by electrolysis of dilute saline or sea water by a series of bipolar or monopolar superposed, between two pressure plates (6) tensioned cell elements (1), one after the other by the electrolyte are flowed through, the elements (1) are designed so that their electrode surfaces (4) Stand vertically, but the direction of flow of the electrolyte is horizontal. 2. Electrolyser according to claim 1, characterized in that the Elements (1) made of rectangular, two horizontally arranged metal sheets (3) and a frame (2) formed from electrically insulating material, to the outside sealed chambers exist in which vertically standing lamellar electrodes (4) are arranged according to their polarity with the upper or the lower Sheet metal (3) are electrically connected and interlock so that they form a number of narrow vertical gaps in which the cathode and anode are located and through which the electrolyte flows horizontally. 3. Electrolyzer according to claim 1 and 2, characterized in that the metal sheets (3) of the elements (1) in the middle elements (l) the partition (8) to form the neighboring chambers and also on the other side with electrode lamellas (4) are provided. 4. Electrolyser according to claims 1 to 3, characterized in that that the metal sheets (3) of the elements in the preferred bipolar circuit the one side are provided with anode lamellae, preferably made of titanium with a suitable anodic coating such as platinum, platinum-irdium or mixed oxide the other side with cathode lamellas made of a suitable material, e.g. from uncoated titanium. 5. Electrolyser according to claims 1 to 3, characterized in that that the metal sheets (3) for monopolar switching laterally over the plastic frame protrude to the outside for the purpose of connecting the power supply and either on both sides are provided with anode or cathode elements. 6. Electrolyser according to claims l to 3, characterized in that that the electrolyte through an opening (7) in the lower partition (8) on a Side from the underlying element (1) enters the chamber, this in the longitudinal direction the Electrode lamellae (4) flows through and them on the other side through an opening (7) in the upper partition wall (8) leaves. 7. Electrolyser according to claims 1, 2, 3 and 6, characterized in that that the openings (7) in the partitions (8) are provided so that a single flow through the electrolyzer results. 8. Electrolyser according to claims 1, 2, 3 and 6, characterized in that that the openings (7) in the partitions (8) are provided so that a Two or more flow through the electrolyzer results. 9. Electrolyser according to claims 1 and 3, characterized in that that individual partitions (8) are provided without an opening (7) and the adjoining chambers be equipped with inlet and outlet connections for connecting an intercooler.