DE102017101725A1 - Photo bioreactor for the cultivation of aquatic microorganisms - Google Patents

Abstract

The invention relates to a photobioreactor for the cultivation of aquatic microorganisms, for example microalgae or cyanobacteria, formed from a plurality of stacked plate modules (1), whose respective bottom plate (8) consists of a light-conducting material. The bottom plate (8) has a light-scattering microstructure on at least one of its top surfaces or a light-scattering interior engraving. The photobioreactor is particularly effective in its yield due to the homogeneous illumination of the culture medium.

Description

The invention relates to a photobioreactor with a plurality of staggered plate modules for the cultivation of aquatic microorganisms, in particular of microalgae or cyanobacteria, for use in the recovery of valuable materials and biomass, for the treatment of waste water, in the laboratory and in hobby.

Microalgae as well as cyanobacteria belong to the aquatic microorganisms, which are able to build up biomass by photosynthesis from water and carbon dioxide - with a much higher efficiency than terrestrial plants. The cultivation of such organisms in artificial plants is a promising resource in food and feed production, in the pharmaceutical and cosmetics sectors or in energy production.

Various methods are known for the controlled rearing of aquatic microorganisms, whereby the systems for carrying out the methods are distinguished into open and closed systems whose operation is possible continuously or in batch mode.

Closed systems are characterized by higher productivity, better controllability of processes and lower risk of contamination of the culture medium compared to the open ones. Here, a distinction is generally made in tube, flat plate and boiler reactors, with a particularly high density of microorganisms with the design of the flat plate reactor can be achieved.

A closed system for the cultivation of microalgae is known US 8 713 850 B2 , Accordingly, several flat plate reactors in the form of transparent drawers within a cabinet offset from each other are arranged. The culture medium flows during operation from a drawer to the underlying each, so that results in a meandering flow through the system as a result of the offset. The lighting is provided by separate bulbs, which are positioned in levels between the drawers. Disadvantages are the large space required for the lamps between the drawers and the heating of the culture medium by the bulbs.

In WO 2015/102529 A1 is also disclosed a closed photobioreactor, which is composed of plate reactors, which are flowed through meandering. By means of a pump driven return flow system, the culture medium is circulated. The system is designed for outdoor use under sunlight. The disadvantage is that the efficiency of the photosynthesis in the individual plate modules decreases due to mutual shadowing.

To improve the introduction of light into the plate reactors, the illumination by optical fibers is known. In US Pat. No. 6,603,069 B1 A photobioreactor for culturing cyanobacteria is described in which optical fibers are guided within the culture medium between the walls of the plate modules. The illumination by means of the laterally radiating optical fibers ensures lossless introduction of the light into the culture medium. The disadvantage is that introduced into the culture medium optical fibers are mechanically sensitive, which z. B. hinders the purification of the plate reactor.

WO 2008/145719 A1 discloses a photobioreactor with illuminants, wherein LED luminous bodies are included as radiation sources in a plastic matrix, which are arranged in the interior of the photobioreactor. Because of this positioning of the bulbs in the interior of the photobioreactor, there is an increased risk of damage to the bulbs here, for example, in the necessary cleaning work due to contamination of the LED plastic moldings.

The object of the invention is to provide a robustly constructed photobioreactor for the cultivation of aquatic microorganisms within a culture medium, which can be operated in a continuous mode, wherein the photobioreactor is constructed of flat plate reactors, which operate with high surface yield density.

The object is achieved by a photo bioreactor with the characterizing features of claim 1; expedient developments of the invention are described in the subclaims 2 to 10.

According to the invention, the photo-bioreactor has a plurality of stacked plate modules whose respective bottom plate consists of a light-conducting material.

In the disk module stack a meandering channel is formed by the composition of the plate modules, which flows through the culture medium during operation. The bottom plates of the plate modules are each to the adjacent, d. H. the above or below the disk module, staggered. The plate modules are preferably box-shaped.

For decoupling light into the culture medium flowing over the bottom plate in operation, the bottom plate has a light-scattering microstructure on at least one of its top surfaces or one, z. B. generated by laser, light scattering interior engraving.

The photobioreactor further has a return duct, which fluidly connects the uppermost with the lowermost disk module, so that a circulation channel is formed in the bioreactor. The return shaft can be decoupled from the disk module stack.

During operation of the photobioreactor, the culture medium flows cascade from the uppermost plate module of the plate module stack, following the meandering channel, into the respectively underlying plate module until it finally reaches the lowermost plate module of the plate module stack. From the return shaft connected to the lowermost disk module, the culture medium is conveyed by means of a flow generator, for example a pump or an air outlet, back to the uppermost disk module. In this way, the culture medium flows through the photo bioreactor in the circulation.

The culture medium is an aqueous solution adjusted to the respective optimum living conditions of the microorganisms. During operation of the photobioreactor, carbon dioxide and water are regularly added as starting materials of the photosynthesis reaction and, if appropriate, nutrients and trace elements. The photosynthesis and the construction of biomass by the microorganisms take place primarily in the illuminated plate modules, with their illumination via the photoconductive base plate. By using transparent materials for the walls of the plate modules and the return shaft, the ambient light for photosynthesis is additionally usable. Alternatively, in the same way as the bottom plate, the walls may be made of photoconductive material having a light scattering microstructure on at least one of their top surfaces or a light scattering interior engraving.

According to the invention, illuminants, for example light emitting diodes, for coupling light into the photoconductive base plate are mounted on at least one side surface of the base plate. As light bulbs and optical fiber cable can be used, which initiate targeted sunlight from a collector or laser light in the side surfaces of the bottom plate.

The lighting means are adjustable with respect to their illuminance, so that the introduction of the amount of light can be adapted to the microorganism density in the culture medium. In addition, the bulbs are removable from the side surfaces of the bottom plate, allowing easy replacement with defective bulbs is possible. It can be provided that the bulbs in a passive heat sink, for. As metal foam, are embedded.

Suitable light-conducting material for the bottom plate are plastics, such as polycarbonate or polymethylmethacrylate, or glasses. The light-scattering microstructure arises as a surface structuring, for example, by a specific roughening of the top surface or by structuring the top surface with a fine pattern. Such patterns are for example grooves or waves, which are preferably oriented in the flow direction of the flow. The light-scattering microstructure may alternatively be incorporated inside the bottom plate by an internal engraving, also known as vitrography, for example by means of a laser.

During operation of the photobioreactor, the light is introduced into the bottom plate via the side surfaces and coupled out via the light-scattering microstructure. As a result, the plate module is illuminated with the culture medium therein evenly diffused over the entire top surface of the bottom plate.

An advantage of the invention is that the culture medium is illuminated directly and very evenly in the plate modules operating as flat-plate reactors. Thus, a highly efficient photosynthesis is possible. There are no unlit positions in the respective disk module; neither does shadowing effects occur between individual plate modules, which can be stacked at the desired height. The shading-free intermediate illumination by means of the light-conducting bottom plates in the plate module stack leads to the high surface yield density of the plate modules.

In addition, the photo bioreactor is characterized by a robust, space-saving design, since the bottom plate according to the invention simultaneously acts as a structural and functional component.

Consequently, in contrast to the prior art, it is not necessary to position light-generating bulbs or sensitive light fibers inside the photobioreactor (ie in the region of the culture medium). As a result, the risk of contamination of the culture medium or the damage of the lamps or their electrical connections is excluded because the light is supplied exclusively by externally introduced light.

In one embodiment of the invention, the light-scattering microstructure is a surface structuring in a plurality of delimited areas on the top surface of the bottom plate, ie, the top surface alternately has areas with surface structuring and without. Such a surface structuring is, for example, by roughening the Surface can be produced by means of abrasive blasting. Particularly suitable are microstructures having an average roughness Ra in the range of 0.2 to 0.9 microns.

Advantageously, each of the plate modules with its plate module module adjacent stack plate modules by positive engagement gas and liquid tight connected. The fit can be realized by accurately fitting, geometrically corresponding design of the connection or joints between adjacent plate modules, for example with secure plug-in connections. The top and bottom plate module of the disk module stack is connected by means of connecting pieces in each case with the return shaft gas and liquid-tight.

An advantage of this embodiment of the invention is that contamination of the photobioreactor with foreign organisms or its contamination is virtually eliminated. In particular, the risks of operating the photobioreactor with sensitive aquatic microorganisms are reduced.

In the connecting pieces between the top or bottom plate module of the disk module stack and the return shaft, a slide for opening and closing the fittings can be introduced, which makes it possible to perform cleaning or revision work on the return shaft without having to drain the culture medium in the disk module stack.

Advantageously, the photobioreactor has a transfer line on one or more of the plate modules. The transfer lines are preferably arranged on the side of the photobioreactor facing away from the return shaft. By means of the transfer lines during operation, the addition of water, carbon dioxide and / or nutrients for the microorganisms, but also the removal of samples of the culture medium. Further transfer lines, devices for exchanging water and for filtration, for example membranes, can be arranged in the return shaft.

In one embodiment of the photobioreactor, in the bottom region of the return duct, an outflow device, which is oriented towards the ceiling region, is arranged, which serves to supply a sterile gas to the culture medium. For example, sterile air can be used as the sterile gas. Likewise, the introduction of carbon dioxide through the vent is possible. In operation, the upward flow is initiated or maintained by the incoming gas in the return duct according to the Lufthebe- or Airliftprinzip. Thus, the vent also acts as a flow generator. Generating the circulation flow in the photo bioreactor by means of this airlift flow generator is particularly gentle compared to mechanical piston pumps, centrifugal pumps or flow generators with propellers for the microorganisms. In addition, the risk of contamination or clogging of moving mechanical components is avoided.

In one embodiment of the invention, each plate module is box-shaped, wherein the two along the longitudinal extension extending, opposite side walls at their respective inner side, d. H. have on the side facing the culture medium, a guide rail. The guide rails are bent or kinked in such a way that the position and orientation of the guide rails in the connection region of adjacent plate modules coincide so that an uninterrupted guide rail system follows the meandering channel in the plate module stack. The guide rails close continuously at the joints between plate modules, d. H. without jumps or heels, against each other.

The guide rail system is used to guide additional equipment, such as cleaning equipment, static mixers, flow guide or sample vessels.

The guide rail system makes it possible to clean the photo bioreactor during operation, for example, by a brush suspended in the guide rails along the meandering channel is moved therethrough, and this frees the inner surfaces of the plate modules of deposits. Static mixers or flow directors may be temporarily or permanently introduced into the photobioreactor to affect the dynamics of the flow of the culture medium (for example, to swirl deliberately or to avoid dead water areas in the flow). In addition, it is possible to introduce sample vessels on the guide rail system for taking samples for testing purposes or for adding chemicals.

Advantageously, all plate modules of the photobioreactor in the plate module stack are identical in their geometric dimensions. As a result, the plate modules can be stacked as needed, so that photo bioreactors a desired height of the plate module stack can be realized. For maintenance or repair single plate modules are easily interchangeable.

In one embodiment of the invention, the meandering channel in the plate module stack at each position on the same cross-section with respect to the direction of flow through the culture medium, for which, for example, the transitions of the bottom plate to the frontal walls are rounded so that the corner radius equal to the distance Floor panels is. As a result, in addition to a uniform flow through the culture medium, the effective cleaning of all inner surfaces along the meandering channel is made possible by means of cleaning devices.

The photobioreactor can have connecting lines for fluidic coupling with another, identical photobioreactor. The connecting lines preferably connect the lowermost plate module of one photobioreactor to the return shaft of the other photobioreactor. The connection lines can be illuminated. The coupling of photobioreactors serves to increase the system volume, whereby the homogeneity of the culture medium is ensured.

In one embodiment of the photobioreactor, the latter has a harvesting container, via which microorganisms can be diverted from the photobioreactor for further use during continuous operation, without interrupting the circulation process. The harvesting container designed as a skimmer is preferably arranged in the upper region of the return shaft.

It is also possible that inside the plate modules along the longitudinal direction extending partitions are installed, so that when compiled the disk modules to the disk module stack, forming a plurality of parallel meandering channels. In the separate parallel channels different microorganisms can be cultivated.

It can be provided that an exhaust pipe is connected to the crop container with the vent. This makes it possible to recycle the reactor gas and enrich it with carbon dioxide as needed. In addition, the closed loop management of the reactor gas reduces the risk of contamination.

• 1: den Fotobioreaktor im perspektivischen Längsschnitt, und
• 2: ein Plattenmodul in der perspektivischen Ansicht.

The invention is explained in more detail below with reference to an embodiment with reference to the schematic drawings. Show this

• 1 : the photo-bioreactor in perspective longitudinal section, and
• 2 : a disk module in perspective view.

In the photo bioreactor according to 1 form ten identically constructed box-shaped, vertically stacked and each horizontally oriented plate modules 1 the disk module stack with the return shaft 4 made of transparent plastic. The arrows illustrate the flow 2 of the culture medium through the meandering channel 18 in the disk module stack. Together with the return shaft 4 forms the meandering channel 18 the circulation channel in the photo bioreactor off. The meandering channel 18 in the plate module stack is free of heels or projections in the region of the joints of adjacent plate modules 1 , The return shaft 4 towers above the plate module stack in height.

In operation, through the vent 3 sterile air into the return shaft 4 blown. The initiation or the maintenance of the flow 2 in the circulation channel takes place after Lufthebe- or Airlift principle. The culture medium is in the return shaft 4 promoted upward and gets into the top plate module 1 , The photobioreactor is so far filled with culture medium that its liquid level 13 in the return shaft 4 above the top plate module 1 forms the disk module stack. The culture medium flows from the top plate module 1 horizontally downwards meandering along the meandering channel 18 to the bottom plate module 1 and finally back to the return shaft 4 ,

In the disk modules 1 is the photoactive zone for the cultivation of aquatic microorganisms. In the return shaft 4 the water and gas exchange takes place. By flotation, the microorganisms pass continuously into the designed as a skimmer crop container 5 at the upper end of the return shaft 4 , The continuous removal of microorganisms from the circulation process via the harvest line 6 , At the harvest container 5 is still the exhaust pipe 7 appropriate. Due to the arrangement of the harvest container 5 above the disk module stack, ie above the top disk module 1 , Reactor gases, for example, the resulting oxygen as a result of the photosynthesis reaction can be removed.

One of the disk modules 1 as reflected in the photo bioreactor 1 are installed in the 2 played. It shows the bottom plate 8th , two side walls 10 , the front wall 12 and the back wall 11 on. The bottom plate 8th consists of the photoconductive material polymethylmethacrylate. It has on the upper and lower top surface a microstructure produced by abrasive blasting with an average roughness Ra of 0.5 microns. On the side surface of the bottom plate 8th are the bulbs 9 in the form of light-emitting diodes mounted so that the light emitted by the light-emitting diodes in the light-conducting material of the bottom plate 8th initiated or coupled. The side walls 10 as well as the front wall 12 and the back wall 11 consist of transparent plastic.

In the back wall 11 is the transfer line 16 attached, through which the photo bioreactor water, Carbon dioxide or nutrients supplied to the microorganisms or alternatively microorganisms, for example, for testing purposes, are removed.

During operation, the culture medium flows from a disk module (not shown) above it 1 from the top into the inlet area 14 , flows through the disk module 1 and flows out of the outlet opening 15 into a disk module (not shown) underneath 1 ,

On the insides of the side walls 10 is the guide rail 17 attached, wherein the concealed in the perspective view guide rail 17 on the front side wall 10 represented by the dotted line. The guardrail 17 on the back sidewall 10 in 3 is shown as a solid line in the field of view.

LIST OF REFERENCE NUMBERS

1

board module

2

flow

3

Outlet, supply for sterile gas

4

Feedback shaft

5

harvest container

6

harvest line

7

exhaust pipe

8th

Base plate of the plate module

9

Lamp

10

Side wall of the plate module

11

Rear wall of the plate module

12

Front wall of the disk module

13

Liquid level of the culture medium

14

Inlet area of the plate module

15

Outlet opening of the plate module

16

transfer line

17

Guardrail

18

meandering channel

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 8713850 B2 [0005]
• WO 2015/102529 A1 [0006]
• US 6603069 B1 [0007]
• WO 2008/145719 A1 [0008]

Claims (10)

A photo bioreactor for cultivating aquatic microorganisms comprising a plurality of plate modules (1) stacked into a plate module stack forming a meandering channel (18) in the plate module stack, and at least one return well (4) co-located with the meandering channel (18) in the plate module stack Circulation channel for the flow (2) of a culture medium through the photobioreactor forms, characterized in that - the bottom plate (8) of each plate module (1) consists of a photoconductive material, - wherein at least one side surface of the bottom plate (8) lighting means (9) for Coupling light into the bottom plate (8), and - wherein the bottom plate (8) has a light-scattering microstructure on at least one of its top surfaces or a light-diffusing internal engraving. Photo bioreactor behind Claim 1 , characterized in that the light-diffusing microstructure is a surface structure consisting of several demarcated areas on the top surface of the bottom plate (8). Photo bioreactor behind Claim 1 or 2 , characterized in that each of the plate modules (1) with its in the plate module stack adjacent plate modules (1) gas-tight and liquid-tight manner is connected and the top and bottom plate module (1) of the plate module stack by means of fittings each with the return shaft (4) gas- and are connected liquid-tight. Photo bioreactor after one of the Claims 1 to 3 , characterized in that one or more of the plate modules (1) each have at least one transfer line (16) for adding water, carbon dioxide and / or nutrients or for taking samples of the culture medium. Photo bioreactor after one of the Claims 1 to 4 , characterized in that in the bottom region of the return shaft (4) is arranged to the ceiling region outwardly aligned vent (3) for supplying a sterile gas in the culture medium. Photo bioreactor after one of the Claims 1 to 5 characterized in that each of the plate modules (1) is box-shaped, the inner sides of two opposite side walls having guide rails (17) whose position and orientation in the connection area of adjacent plate modules (1) coincide, whereby a meandering channel (18) in the plate module stack the following, continuous guide rail system for guiding ancillary equipment with regard to cleaning the channel (18), turbulence or flow line of the culture medium and / or sampling is formed. Photo bioreactor after one of the Claims 1 to 6 , characterized in that it comprises means for controlling the illuminance of the illuminant (9) attached to the bottom plate (8), which are detachably connected to the bottom plate (8). Photo bioreactor after one of the Claims 1 to 7 , characterized in that the meandering channel (18) in the plate module stack at each position has the same cross section transverse to the direction of flow (2) of the culture medium. Photo bioreactor after one of the Claims 1 to 8th , characterized in that the photo bioreactor connecting lines for fluidic coupling with another, identical photo bioreactor has. Photo bioreactor after one of the Claims 1 to 9 , characterized in that the photo-bioreactor has a harvesting container (5) in the upper region of the return shaft (4).

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