DE29706379U1 - Device for carrying out photochemical and photocatalytic reactions and photoinducible processes - Google Patents

Description

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Device for carrying out photochemical and photocatalytic reactions and photoinducible processes

Description

The invention relates to a device for carrying out photochemical and photocatalytic reactions and photoinducible processes, in particular for the cultivation of phototrophic organisms and cell cultures, e.g. microalgae.

Known devices for cultivating phototrophic organisms and cell cultures, such as microarrays, are either designed as open tanks in the open air or are operated exclusively with artificial light, with the culture medium being guided in transparent tubes. Devices with container-shaped reactors are usually also equipped with means for circulating the culture medium to achieve intensive light exposure, whereby the construction effort increases the associated costs.

In open tanks there is always a risk of contamination, so that pure breeding is not possible. The temperature control of such systems is also very difficult under the climatic conditions prevailing here.

US-PS 44 73 970 discloses a device that can be operated with artificial light, in which the culture medium is guided in transparent tubes. The main disadvantages of this device are energy aspects with regard to the pump and light output.

Furthermore, devices are known that consist of container-shaped reactors into which the light is introduced via optical fibers. The light is guided into the culture medium via a Fresnel lens that tracks the sun and/or via an artificial light source via the same optical fibers. Such systems are very costly both to manufacture and to operate.

In US-PS 45 55 864 a device for the cultivation of Chlorella algae is described, in which light guides in a cultivation vessel are directly introduced into the

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culture medium, whereby these are supplied with light energy from above via inclined mirrors. This device is also very costly and complex to construct.

DE 41 34 813 A1 also describes a device for cultivating phototrophic microorganisms, which can be operated using sunlight and/or artificial light and through which a culture medium flows. This device is characterized by any number of webs, each of which is arranged at the same distance from one another between two plane-parallel transparent plates in a liquid-tight manner and forms chambers. At the end of each

Connection openings to the adjacent chamber are provided between the webs, whereby the connection openings of adjacent webs are located at opposite ends, whereby a meandering line-shaped channel is formed, which is tightly sealed at its front sides and has a connection piece for gas exchange at its beginning and end. This device is unsuitable for large-scale use for energy reasons alone, due to the high pump output to be expected to overcome the flow resistance of the meandering line-shaped channels and the high manufacturing costs of a plate provided with such webs.

The present invention is therefore based on the object of improving known devices for carrying out photochemical and photocatalytic reactions and photoinducible processes, in particular for the cultivation of phototrophic organisms and cell cultures, e.g. microalgae, with regard to their energy balance, their production costs and optimal use of the available light energy, so that they are suitable for large-scale use.

According to the invention, this object is achieved by the features of claim 1. Advantageous embodiments of the invention are contained in claims 2 to 6.

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The device presented according to the invention for carrying out photochemical and photocatalytic reactions and photo-inducible processes as well as for cultivating phototrophic organisms and cell cultures under the influence of light can be flowed through by a liquid medium and can be exposed to a gaseous medium and contains means for gas removal. It consists of at least one integrally extruded transparent plate module, which has a large number of continuous channels lying one above the other and running parallel to one another, the inlet and outlet sides of which

&iacgr;&ogr; are connected to a liquid distributor or liquid collector, which has a cross-sectional area that enables a uniform flow profile across all channels.

According to a special feature of the invention, the liquid distributor has a cross-sectional reduction in the flow direction and the liquid collector has a cross-sectional expansion, whereby an optimal flow rate is achieved across all channels.

According to a preferred feature of the invention, pressure equalization plates with perforations are provided between the channels and the liquid collector and/or liquid distributor, wherein the perforations have different cross-sections.

According to a further feature, a preferred embodiment of the invention is described in that on one side of the plate module all channels are supplied with fluid simultaneously via a fluid distributor and on the side opposite this side the fluid flowing out of all channel ends is collected and drained off by a fluid collector.

Another particularly preferred embodiment of the invention includes that the liquid inlet and outlet are located on one side of the plate module, whereby the part of the channels connected to the inlet is supplied with fluid via a liquid distributor and the part connected to the outlet

part of the channels that is in this position flows into a liquid collector. The inlet and outlet of this side are not connected to each other and each have

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opposite flow directions, whereby the channels flowing through the liquid distributor open into a liquid collector on the opposite side, which is connected to another liquid distributor that diverts the liquid and flows into the part of the channels that ends in the liquid collector connected to the drain.

According to a further feature of the invention, several plate modules are connected to one another via connecting pieces and are connected at a distance from one another in parallel and/or one behind the other via a common and/or separate supply and return line.

With the present invention, in all variants of the embodiments comprising this invention, it is achieved with surprisingly simple means that turbulent conditions can be maintained in the culture medium with low flow velocities, which are necessary for optimal utilization of light energy. In addition, the flow resistance can be significantly reduced compared to the known solutions.

Ultimately, this significantly reduces the pumping power required for the device, which improves the energy balance in a particularly beneficial way. The connection of several plate modules also enables the construction of reactors of any size for large-scale use from simple standard components.

The invention will be explained in more detail below using exemplary embodiments.

In the drawings the

Figure 1: the schematic representation of an embodiment variant of the device according to the invention,

Figure 2: a plate module with liquid distributor and collector,
Figure 3: a plate module with pressure compensation plate,

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Figure 4: a plate module with combined liquid distributor/collector,

Figure 5: several plate modules directly connected to each other (series connection).

Figure 1 shows a schematic representation of an embodiment of the device according to the invention for carrying out photochemical and photocatalytic reactions and photoinducible processes, in particular for the cultivation of phototrophic organisms and cell cultures, e.g. microalgae.
This device essentially consists of a plate module system 1 with the individual plate modules 1a....1n, a flow 2 and a return 3 for a

&iacgr;&ogr; liquid 4, in particular a culture liquid 4a, a liquid-gas exchanger 5, an equalizing tank 6, a measuring section 7 and a system pump 8. The plate module system is assigned as peripheral equipment gas supply elements 9a, 9b, 9c, gas discharge elements 10a, 10b, a heat exchanger 11, a flushing device 12 with a drain 13 and a fresh water connection 14. The culture liquid 4a passes from the equalizing tank 6 through the measuring section 7 and the system pump 8 via the

Feed line 2 into the plate module system 1. The individual plate modules 1a 1n

have liquid distributors 15 with liquid inlet 16 arranged on their flow side 17. This liquid distributor is firmly connected to the plate module by means of a connection 18 and has a cross-sectional reduction 19. The connection 18 can be, for example, an adhesive connection 18a. On the return side 20 of the plate modules, a liquid collector 21 with a liquid outlet 23 is arranged, whereby the liquid collector 21 has a cross-sectional expansion 22 (Figure 2). The cross-sectional reduction 19 and cross-sectional expansion 22 ensure a uniform speed of the culture liquid 4a in the channels 24 of the individual plate modules. With the help of connectors 25, the individual plate modules are connected to one another via the liquid outlet 23 or liquid inlet 16 (series connection). The gas supply elements 9a and the gas discharge elements 10a are assigned to the connector 25. After the plate module 1n, the culture liquid 4a passes through the return line 3 and the liquid-gas exchanger 5 into the equalization tank 6.

wherein the liquid-gas exchanger 5 and the compensation tank 6 are directly connected to one another. An overflow 26 ensures a safe return of the culture liquid 4a into the compensation tank 6 with reduced throughput of the liquid-gas exchanger 5. In the liquid-gas exchanger 5 and/or before or in the system pump 8 and/or in the connector 25 on the flow side 17 of every second plate module, the culture liquid 4a is conditioned with a gas 27, preferably a CO2-rich exhaust gas 27a. The oxygen 28 formed in the course of the photobiological processes, which is contained in an oxygen-rich exhaust gas 27b, is discharged via gas discharge elements 10a and/or 10b and/or in the liquid-gas exchanger 5. The conditioning of the _CO2 -rich exhaust gas 27a is carried out depending on the pH, temperature and optical density values of the culture liquid 4a, which are recorded in the measuring section 7 before or after the system pump 8. The measurement, control, regulation and storage of state variables of the culture liquid 4a, the CO2-rich exhaust gas 27a and the oxygen-rich exhaust gas 27b are carried out via a central measuring, control, regulation and storage unit 29. With the help of a bypass 30, a partial volume flow of the culture liquid 4a can be conveyed directly into the liquid-gas exchanger 5 and the conditioning of the gas 27 or the culture liquid 4a can thus be influenced.

According to a further exemplary embodiment of the invention (Figure 3), a pressure compensation element 31, preferably a pressure compensation plate 31a, is arranged in front of the flow side 17 of the plate modules 1a....1n. The pressure compensation plate 31a has perforations 32 with a reduced cross-section in the direction of flow.

According to a further embodiment (Figure 4), the liquid inlet 16 and the liquid outlet 23 are arranged on the side 17 of the plate module, whereby the part of the channels 24 on this side that is connected to the liquid inlet 16 is supplied with flow via the liquid distributor 15 and the part of the channels 24 on this side 17 that is connected to the liquid outlet 23 is supplied with flow via the liquid distributor 15.

the liquid collector 21. The liquid collector 21 and liquid distributor 15 on this side 17 are not connected to one another. The channels 24 flowing through the liquid distributor 15 flow on the side 20 into a liquid collector 21 with a cross-sectional expansion 22. This liquid collector 21 is connected to another liquid distributor 15 with a cross-sectional reduction 19 on this side 20 which diverts the culture liquid 4a and flows to the other part of the channels 24.

In another embodiment of the invention (Figure 5), the plate module system 1 has no connectors 25. A liquid distributor 15 with a cross-sectional reduction 19 (Figures 2, 4) or a pressure compensation element 31 or 31a (Figure 3) is arranged in front of the plate module 1a on the supply side 17, and a liquid collector 21 (Figures 2, 3, 4) is arranged downstream of the plate module 1n on the return side 20.

Claims (6)

Protection claims 1. Device for carrying out photochemical and photocatalytic reactions and photo-inducible processes, as well as for cultivating phototrophic organisms and cell cultures under the influence of light, which can be flowed through by a liquid medium and can be supplied with a gaseous medium and contains means for gas removal,
characterized in that &iacgr;&ogr; these consist of at least one integrally extruded transparent Plate module which has a plurality of continuous channels lying one above the other and running parallel to one another, the inlet and outlet sides of which open into a liquid collector and/or liquid distributor, which have a cross-sectional area which enables a uniform flow profile across all channels. 2. Device according to claim 1,
characterized in that the liquid distributor has a cross-sectional reduction in the flow direction and the liquid collector has a cross-sectional expansion. 3. Device according to one of the above claims,
characterized in that pressure equalization plates with perforations are provided between the channels and the liquid collector and/or liquid distributor, wherein the perforations have different cross-sections. 4. Device according to one of the above claims,
characterized in that on one side of the plate module all channels are supplied with fluid simultaneously via a liquid distributor and on this side On the opposite side, the liquid flowing out of all channel ends is collected and drained by a liquid collector. 5. Device according to one of the above claims,
characterized in that the liquid inlet and outlet are located on one side of the plate module, whereby the part of the channels on this side connected to the inlet is supplied with fluid via a liquid distributor and the part of the channels on this side connected to the outlet is supplied with fluid via a &iacgr;&ogr; liquid collector, whereby these are not connected to each other and each have opposite flow directions, whereby the channels flowing through the liquid distributor open into a liquid collector on the side opposite this side, which is connected to another liquid distributor which diverts the liquid and flows into the part of the channels which ends in the liquid collector connected to the outlet. 6. Device according to one of the above claims,
characterized in that several plate modules are connected to each other via connectors and are connected at a distance from each other in parallel and/or one behind the other via a common and/or separate supply and return line .