DE4331383A1 - (Pressure) electrolyser of modular construction - Google Patents

Abstract

(Pressure) electrolyser of modular construction for the electrolysis of water to produce hydrogen and oxygen. The (pressure) electrolyser comprises at least two (pressure) electrolyser modules (A, B, ...) arranged in series, each (pressure) electrolyser module in turn comprising a pressure vessel (1) within which the cell block(s) (2) accommodating the individual electrolytic cells is/are arranged, and each pressure vessel (1) being equipped with a flanged joint on at least one of the end faces. Those (pressure) electrolyser modules (A, B, ...) which are equipped with a flanged joint on only one of the end faces of their pressure vessel (1) are sealed at the opposite end face by means of a domed bottom (3). The number of cells within a cell block (2) is from 10 to 300, preferably from 50 to 180, in particular from 100 to 150. <IMAGE>

Description

The invention relates to a (pressure) electrolyzer in modular design for the electrolysis of Water for the production of hydrogen and oxygen.

The electrolytic decomposition of water to produce hydrogen and Oxygen has been known for a long time. At the beginning of industrial application of this However, the gases obtained could only decompose under one Overpressure of maximum 50 mbar can be delivered. However, since this pressure in the in most cases for industrial processes that require hydrogen or oxygen was sufficient, the development went in the direction of pressure electrolysis. It also played the realization that the useless energy-consuming surge in the cells decreasing with increasing pressure left a not insignificant role. With the Processes of pressure electrolysis can be used to generate the gases water and oxygen dispense with a pressure of about 30 bar. This print is for a variety of people Hydrogen and / or oxygen consuming industrial applications sufficient.

It has been shown in practice that when planning and installing a (Pressure) electrolyzers often a possible extension within the next few years is not taken into account. In these cases it is then necessary to either next to the to set up existing (pressure) electrolysers further (pressure) electrolysers or one instead of the (pressure) electrolyser used initially to put bigger ones.

The aim and object of the invention is to overcome the disadvantages of the prior art avoid.

This is achieved according to the invention in that the (pressure) electrolyzer at least has two (pressure) electrolyzer modules arranged one behind the other, each of which (Pressure) electrolyser module in turn has a pressure vessel within which the cell block (s) accommodating the individual electrolytic cells is arranged  is / are and with each pressure vessel at least on one of the end faces Has flange connection.

The (pressure) modular electrolyzer according to the invention now enables one gradual expansion of an existing (pressure) electrolyser to the simplest Wise. Because each of the (pressure) electrolyzer modules are of essentially identical dimensions has, the production of these modules can be simplified and ultimately lower the price of the modules. Any transportation problems between the Production and the final location of the (pressure) electrolyser modules avoided because the maximum dimensions of each module are chosen so that a normal transportation, e.g. B. by truck or train overland, is possible. Next to the simple expansion of the (pressure) electrolyzer according to the invention by adding additional modules, can also repair individual, damaged modules relatively easy to do. To do this, the damaged module Module assembly removed and reinserted after repair. Conceivable would also be a temporary insertion of a replacement module. In the latter A trap could avoid a longer interruption of H₂ and O₂ production become.

An embodiment of the invention is characterized in that those (Pressure) electrolyser modules that are only on one of the end faces of their pressure vessel have a flange connection on the opposite end face by means of a arched bottom are closed.

The modules provided as so-called end modules are usually on one of the End faces closed by means of a curved bottom. The so-called intermediate modules the modules provided, on the other hand, have a flange connection on both ends on. However, it is also conceivable that, in the case of an existing module association, who intends to expand it on both sides, initially only so-called Intermediate modules are used, to which additional modules are added can.

Further developing the invention it is proposed that the number of cells within a Cell block is 10 to 300, preferably 50 to 180, in particular 100 to 150.

The invention and further refinements thereof are explained in more detail with reference to FIGS. 1 to 3. The same device features have identical reference numerals.

Fig. 1 shows a module A of the (pressure) electrolyzer according to the invention in modular design. The module A is constructed from a pressure vessel 1 , in which the cell block 2, which accommodates the individual electrolytic cells, is located. The pressure vessel 1 is closed on one of its end faces by means of a curved base 3 and can be closed on the opposite end face by means of a cover 4 . Module A presented in FIG. 1 is a so-called end module.

In FIG. 2, however, is a so-called. Intermediate module, in which the pressure container 1 on both end sides by means of a lid 4 can be closed, is shown.

Fig. 3 shows the (pressure) electrolyser according to the invention in a modular design, consisting of two modules A and B, where the so-called. Intermediate module B now contains two individual cell blocks 2. Following module B, another module is drawn to the right in dashed lines, which is intended to indicate that the (pressure) electrolyser according to the invention can be expanded as desired in a modular design.

Each of the (pressure) electrolysers shown in FIGS. 1 to 3 is supplied via line 5 with an electrically non-conductive fluid, preferably purified feed water required for the decomposition. This flows around the cell blocks 2 within the pressure vessel 1 and is subsequently discharged from the pressure vessels 1 via line 6 . Via lines 7 , 7 'and 7 '', the individual cell blocks 2 are supplied with a mixture of alkali and the fluid to be decomposed in the electrolysis, while the gas / alkali mixtures are discharged via lines 8 , 8 ' and 8 '' . The lines 8 , 8 'and 8 ''stand for two individual lines, of course, since a hydrogen / alkali mixture is discharged from each cell block via one line and an oxygen / alkali mixture is discharged via a further line.

For clarity, in FIGS. 1 to 3 no further internals such. B. lye heat exchanger, cooling water supply, heating, etc., as they can be provided within the pressure vessel 1 , shown.

The pressure vessels 1 of the so-called end and intermediate modules as well as the internals of the pressure vessels 1 can now be mass-produced on one production line each. Depending on the power requirement, the so-called end and intermediate modules are then assembled at the factory, transported to the installation site and assembled there to form an electrolyser. The modular design thus makes it possible to achieve cost-effective factory series production and optimal assembly of large electrolysers at the respective installation site.

If the (pressure) electrolyser consists of several modules, either everyone can Cell block individually or several cell blocks connected in series supplied with direct current become. If and if so, how many of the cell blocks are connected in series will depend essentially on the number of cells per cell block. The The number of cells within a cell block is 10 to 300, preferably 50 to 180, especially 100 to 150.

The following table shows the possible expansion stages for one Megawatt high-performance electrolyzer shown in modular design. In this case end modules are designed for 2.5 MW and intermediate modules for 5 MW, which then each can be put together according to performance requirements. It is for the professional it goes without saying that, beyond this example, further gradations are possible.

Claims (3)

1. (Pressure) electrolyser in modular design for the electrolysis of water for the production of hydrogen and oxygen, characterized in that the (pressure) electrolyzer has at least two (pressure) electrolyzer modules (A, B,...) Arranged one behind the other, wherein each (pressure) electrolyser module in turn has a pressure vessel ( 1 ), within which the cell block (s) ( 2 ) accommodating the individual electrolysis cells is / are arranged, and each pressure vessel ( 1 ) at least on one of the end faces has a flange connection. 2. (pressure) electrolyser in modular design according to claim 1, characterized in that those (pressure) electrolyzer modules (A, B,...) Which have a flange connection on only one of the end faces of their pressure vessel ( 1 ) opposite end face are closed by means of a curved bottom ( 3 ). 3. (pressure) electrolyser in modular design according to claim 1 or 2, characterized in that the number of cells within a cell block ( 2 ) is 10 to 300, preferably 50 to 180, in particular 100 to 150.