EP3538637A1 - System for lighting a device, in particular a decorative element, a façade of a building or a street furniture item by bioluminescence - Google Patents

Abstract

The present invention relates to a system for lighting a device, in particular a decorative element, a façade of a building or a street furniture item by bioluminescence, including a bioreactor (1) provided with an intake for a culture medium and at least one means for collecting a portion of the biomass, as well as tappings for connecting a circuit (5) for circulating a culture medium which carries bioluminescent microorganisms, said circulation circuit (5) comprising a set of at least partially transparent ducts and at least one circulation pump (6) and one air pump (13), said system including a circuit (11) for controlling the supply of culture medium, the addition of biomass and the removal of biomass, and at least one sensor of the biological status of the circulating microorganisms.

Description

 SYSTEM FOR ILLUMINATION OF A DEVICE, IN PARTICULAR A DECORATIVE ELEMENT, A FACADE OF A BUILDING OR AN ELEMENT OF

 URBAN FURNITURE BY BIOLUMINESCENCE

Field of the invention

The present invention relates to the field of bioluminescence illumination of a device, in particular a decorative element, a facade of a building or a piece of street furniture.

 Bioluminescence is a chemical reaction governed by a gene that allows certain living organisms to produce light, including marine organisms, algae, jellyfish, squid, fish, or shrimp.

 Such genes coding for bioluminescence, for example, in symbiotic squid bacteria can be inserted into common, non-pathogenic and nontoxic bacteria, encapsulated in a container, with a nutrient solution comprising everything they need to live and produce their light.

 This phenomenon has been analyzed for scientific research purposes and is starting to find industrial applications, to produce bioluminescent equipment emitting for relatively short periods of light, of low intensity.

State of the art

Patent Application US2013045531 describes a lighting assembly comprising a submergible bioreactor and an optical waveguide having a cylindrical structure with a refractive index known to cause the propagation of light longitudinally through a length of the guide. optical wave at an angle of reflection. A bioreactor medium having a refractive index different from the known refractive index produces light in the optical waveguide to diffuse the diffusing structure through the inner surface of the optical waveguide and into the medium to another angle of incidence.

The prior art is known in particular from the international patent application WO2012125953 describing light emitting systems from algae. By preparing the algae and applying an appropriate electromagnetic wave, the algae emit light. The prepared luminescent algae can also be incorporated into luminescent panels, which can then be integrated in a variety of applications. In some embodiments, these luminescent panels can be controlled individually and remotely, allowing ease of use and installation. In addition, these luminescent panels also consume a relatively small amount of energy compared to conventional light sources, creating the potential to save significant amounts of energy and energy costs.

 US patent US5554035 relates to an apparatus for visualizing the luminescence of dinoflagellate algae, incorporated in an aqueous solution contained in a container shaped translucent light bulb.

Disadvantages of prior art

The solutions of the prior art have several disadvantages. They are suitable for ephemeral applications, producing bioluminescent lighting for a period of minutes to a few hours. Biomass is not stable because of the growth of bioluminescent microorganisms, and the evolution of density and aging of microorganisms leads more or less rapidly to the death of the majority of microorganisms and therefore the arrest of bioluminescence.

 Furthermore, the bioluminescence activity results in the solutions of the state of the art of a stress which disturbs the survival of the microorganisms, due to the agitation of the biomass observed in the solutions of the prior art.

 In particular, these solutions are not suitable for illuminating large surfaces exposed to the weather, including facades.

Solution provided by the invention

In order to overcome these drawbacks, the present invention relates to an illumination system of a device, in particular a decorative element, a facade of a building, or a piece of street furniture produced by bioluminescence, characterized in that it includes a bioreactor comprising an arrival of a culture medium and at least one means for sampling a portion of the biomass, as well as connections for connecting a circulation circuit of a medium of culture loaded with bioluminescent microorganisms (that is to say a medium in which the microorganisms evolve), said circulation circuit comprising a set of at least partially transparent conduits and at least one circulation pump and a pump to air, said system comprising a control circuit of the supply of culture medium, the contribution of biomass and removal of biomass and at least one sensor of the biological state of the circulating microorganisms. Advantageously, said system comprises other sensors making it possible to intervene in an optimized manner on the biomass culture conditions, such as a biomass oxygenation level sensor, a temperature sensor, a turbidity sensor of the medium. and a biomass irradiance sensor.

Detailed description of the invention

The present invention will be better understood on reading the description which follows, with reference to the accompanying drawings relating to a nonlimiting example of embodiment in which:

 - Figure 1 shows a schematic view of a system according to the invention.

The plant comprises a reaction vessel (or bioreactor) (1) containing the biomass and the culture medium and an agitator.

 The reaction vessel (1) receives biomass supplements from a reservoir (2) and liquid culture medium from a reservoir (3).

 The reaction vessel comprises intermittently stirred and oxygenated means, for example with an activation / deactivation time ratio of less than 10% so as to limit the stress of the microorganisms as well as the electrical consumption.

The removal of excess biomass in the reaction vessel (1) is transferred to an auxiliary container (4). The biomass contained in said container (4) can be recovered for the production of biomaterials, energy or heat. This container may be equipment for treating biomass, for example by incineration. Moreover, the system may include means for recovering molecules of interest. This recovery step may relate to proteins and / or monoclonal antibodies secreted by the microorganisms, and separated from the biomass by filtration.

 The reaction vessel (1) may have tappings for connecting a circulation circuit (5) of the liquid culture medium containing the biomass.

 The circulation circuit (5) is transparent in the illumination zone. A circulation pump (6) provides the flow of biomass in the circulation circuit (5).

 In the exemplary implementation of the invention as shown in Figure 1, this circuit is formed by a tubular assembly. The diameter of such a tubular system can be adapted to the type of device. The section may for example be between 10 and 100 millimeters, but may be smaller, for example 5 millimeters or larger, for example 150, 300, 500 millimeters or more. The circulation circuit can also take other forms. The conduit may have a circular, rectangular, triangular or any other shape of its choice. In addition, the circulation circuit may consist of two closed plates at their ends between which circulates the solution containing the biomass. Thus, within the meaning of the invention, the term "conduit" means a set of partitions delimiting the passage of the solution containing the biomass regardless of the form (pipe, pipe, passage between two plates ...)

The circulation circuit (5) is fluid tight and can be gas permeable. It comprises an air pump (13) to ensure the oxygenation of the culture medium. The supply of oxygen is indeed essential for the emission of bioluminescence by microorganisms. Oxygen supply may be intermittent or continuous during biomass growth phases but must be continuous during periods during which bioluminescence emission is required.

In a particular embodiment, said circulation circuit is fluid-tight and gas-permeable, at least partially, to allow CO ₂ exchanges with the ambient air. In this embodiment, the biomass is preferably composed of cyanobacteria, so as to capture the ambient CO 2. An electronic circuit (also called control system) (11) controls the operation of:

 the valve (7) controlling the flow rate in the circulation circuit (5),

 the valve (8) controlling the addition to the reaction vessel (1) of culture medium from the reservoir (3),

 the valve (9) controlling the addition in the reaction vessel (1) of biomass coming from the tank (2),

 the valve (10) controlling the evacuation of biomass from the reaction vessel (1),

 the valve (14) controlling the air flow.

The control system (11) may further be configured to automatically control at least one variable of the process. For example, the control system (11) may be configured to automatically control at least one parameter among the temperature within the bioreactor, the pressure in the bioreactor, the pH level, the nutrient flow rate, the culture of the medium flow, gas flow, carbon dioxide gas flow, oxygen gas flow, light supply, etc. To ensure good management of these different parameters, the system can be equipped with sensors to monitor different parameters.

This control system (11) notably receives signals coming from an optical density sensor (12) arranged on the circulation circuit (5) and / or physicochemical sensors.

 A major advantage of the bioreactor according to the invention lies in the fact that it allows a continuous or semi-continuous culture. The good management of the culture in the long term is advantageously ensured thanks to different sensors.

 A culture of bioluminescent bacteria in "batch" mode has no effluent, resulting in an exponential accumulation of bacteria in the reactor until the nutrients are depleted. The bacteria then reach a stationary growth phase which is accompanied by metabolic changes preventing the expression of the proteins of interest (in particular bioluminescent proteins). There is also accumulation of metabolic products secreted by bacteria; these products modify the medium and may prevent the bioluminescence reaction.

 On the contrary, in a "continuous" or "semi-continuous" culture, there are inputs / outputs: fresh medium can be added and withdrawn from the "used" medium continuously or at given intervals depending the state of the system. This configuration makes it possible to ensure the constant availability of nutrients and the stability of the chemical composition of the culture medium in the reactor. By adjusting the rate of dilution (through a pump and valve system) to the growth rate of the bacteria, one can keep the turbidity of the medium at a constant level. In other words, it is possible to maintain a constant number of bacteria in the reactor and to keep the population of the biomass in a certain metabolic state (stable exponential phase). In this case, the preferred state is one in which the level of bioluminescence is maximal.

For a good management of the culture inside the bioreactor, one can follow the growth of the microorganisms, the pH, the temperature, the quantity of dissolved oxygen, etc. If the reactor does not have a sensor, the user must make Manual withdrawals punctually to extract information of interest. This practice poses risks and has considerable disadvantages. Indeed, at each sampling there is a risk of contamination of the crop, modification of the total volume of the crop and monitoring is very time-consuming. On the other hand, if the reactor has sensors, the user no longer needs to take samples during the experiment and some aspects of the bioprocess can be automated with the help of a control system and some actuators.

Thus, in a preferred embodiment, different sensors may be associated with the bioreactor of the illumination system according to the invention in order to control the biomass and ensure a good quality of luminescence, among which: a biomass oxygenation level sensor . Depending on the level of oxygenation of the medium, the aeration can be activated or interrupted. The interruption of the aeration can, for example, be obtained via a pinch valve which can be provided with a solenoid which makes it possible to cut off the aeration by putting pressure on the air hose.

 - a temperature sensor. It may be an external sensor to monitor the ambient temperature outside the reactor and anticipate its impact on the indoor temperature to maintain an appropriate temperature inside the bioreactor. It is also possible to immerse a temperature sensor in the crop with a special probe.

- A medium turbidity sensor (or optical density as described above). It may be a set of photodiodes consisting of a transmitter and a receiver, both at 940 nm. This type of sensor makes it possible to evaluate the growth of the biomass by using the infrared light coming from the transmitter. The more microorganisms there are, the more the medium becomes murky and less infrared light can pass through the medium to the receptor. With an initial calibration, we can have a relationship between the value obtained with this sensor and the value obtained using a conventional spectrophotometer to calculate the number of bacteria in the medium. an irradiance sensor (or luminescence sensor). This sensor may be of the light-frequency converter type. It is used to measure the bioluminescence that passes through the bioreactor. The sensor emits a frequency that is directly proportional to the intensity of the light that hits the detector. This frequency (Hz) can be translated into irradiance radiometric units (μνΐ / απι ² ) using the sensor's technical specifications.

In an automated system, the sensors can be connected to an interface for displaying the data. These sensors are connected to a control system as described above, which controls the different valves and pumps of the bioreactor in real time.

In a preferred embodiment, the illumination system according to the invention comprises a set of sensors, namely a biomass oxygenation level sensor, a temperature sensor, a turbidity sensor of the medium and a sensor. irradiance. In this system, the sensors can be connected to the control system for automated control of the various valves and pumps of the control circuit.

For optimized operation of the bioreactor, care must be taken to ensure proper placement of the sensors. The temperature sensor should be placed away from heat sources to avoid false reading. Infrared LED photodiodes must be placed perfectly in front of each other and the pipes inside the reactor must not block the path between the LEDs. The irradiance sensor should be placed in a suitable location where the light produced by the reactor can reach the detector. Finally, the design of a base that allows the fixing of the location of the sensors is recommended, because it is absolutely not necessary to move the turbidity and irradiance sensors once the system is calibrated. Thus, the system according to the invention makes it possible to generate a bioluminescence which is stable over time and of good quality. While the luminescence time in a batch system is approximately 24 hours, the bioreactor system according to the invention makes it possible to maintain the bioluminescence for a duration greater than 2 weeks and more generally an unlimited duration. The sensors play a major role in this system since they allow optimized management of the biomass by permanently maintaining optimal conditions for the growth of microorganisms and bioluminescence.

Bioluminescent biomass is a naturally bioluminescent biomass or, preferably, biomass genetically modified to produce bioluminescence, such as:

 photosynthetic organisms (algae, microalgae, cyanobacteria)

 - microorganisms (bacteria, ...)

 - cellular organisms (yeasts, ...)

 - biological active substances

 a combination composed of several of the examples cited above (co-culture).

 The culture medium is constituted by way of non-limiting example of a composition comprising:

500 ml of modified pH7 culture medium containing 10 g / l of glucose, 13.6 g / L of KH 2 PO 4,

 - 0.02g / L of CACL2,

 0.2 g / L of MgSO7H20,

 2 g / L of (NH 4) 2 SO 4,

 - medium LB.

 The culture media may be freshwater, estuarine or brackish type media or specific marine bacterial species, plankton or algae and / or other microorganisms. Culture media may include salts such as sodium chloride and / or magnesium sulfate, macronutrients such as nitrogen and phosphorus-containing compounds, trace elements such as trace metals, e.g. iron and compounds containing molybdenum and / or vitamins such as vitamin B. sub.12. Culture media can be modified to accommodate different species and / or to optimize the different characteristics of the crop species, such as growth rate, protein production, lipid production and carbohydrate production. . Those skilled in the art will be able to choose a culture medium adapted to the microorganism (s) constituting the biomass.

In a particular embodiment, the biomass consists of cyanobacteria. These microorganisms have the particularity of capturing C0 ₂ and emitting 0 ₂ , and to clean up some dirty water. Thus, in addition to the bioluminescent effect, the device can have a depolluting action.

Optionally, the system comprises optically active dopants of the photoluminescent type. These dopants are, according to a first variant, constituted by microbeads incorporated in the biomass.

These materials consist of a polymeric matrix in which are incorporated one or more types of luminescent organic compounds. In the case of combining two types of luminescent organic compounds, the compounds exhibit an absorption spectrum and an emission spectrum respectively, and the emission spectrum of one of two types of luminescent organic compounds overlaps the spectrum of absorption of the other luminescent organic compound. The two spectra, corresponding to two curves of intensity of a radiation as a function of the wavelength, have a surface of recovery.

 The micro-beads consist for example of nanoparticles of an optically active compound encapsulated in a silicone polymer matrix, ethylene-vinyl acetate (EVA), polyolefins polymethyl methacrylate (PMMA) elastomer, polyurethane, polyamide, ethylene tetrafluoroethylene ( ETFE), polytetrafluoroethylene (PTFE).

 The nanoparticles are, for example, silica nanoparticles, or luminescent organic compounds incorporated inside porous silica, either grafted onto the surface of the nanoparticles.

 According to an alternative, the optically active materials are incorporated in a polymer matrix of the biomass circulation conduit.

 Additionally, the conduit and / or the biomass may comprise a diffusing filler, for example silica powder.

 According to another variant, at least one of the faces of the ducts is reflective, for example by depositing a metallized coating; it may be the back side of the ducts.

Claims

 claims

1 - System for illuminating a device, in particular a decorative element, a facade of a building or an element of street furniture by bioluminescence characterized in that it comprises a bioreactor (1) comprising a arrival of a culture medium and at least one means of sampling a portion of the biomass, as well as connections for connecting a circulation circuit (5) of the culture medium in which bioluminescent microorganisms evolve , said circulation circuit (5) comprising a set of at least partially transparent conduits and at least one circulation pump (6) and an air pump (13), said system comprising a control circuit (11) of the supply in the culture medium, biomass supply and biomass removal and at least one sensor of the biological state of the circulating microorganisms.

2 - illumination system according to claim 1 characterized in that said circulation circuit (5) is fluid-tight and gas-permeable, at least partially.

3 - illumination system according to one of the preceding claims characterized in that it comprises an electronic circuit (11) controls the operation of:

 the valve (7) controlling the flow rate in the circulation circuit (5),

 the valve (8) controlling the addition to the reaction vessel (1) of culture medium from the reservoir (3)

 the valve (9) controlling the addition in the reaction vessel (1) of biomass coming from the reservoir (2)

the valve (10) controlling the evacuation of biomass from the reaction vessel (1). 4 - illumination system according to one of the preceding claims characterized in that it comprises a control system configured to automatically control at least one parameter among the temperature within the bioreactor, the pressure in the bioreactor, the level pH, nutrient flow, medium flow culture, gas flow, carbon dioxide gas flow, oxygen gas flow rate, light delivery. 5 - illumination system according to one of the preceding claims which further comprises a biomass oxygenation level sensor, a temperature sensor, a turbidity sensor of the medium and an irradiance sensor.

6 - illumination system according to one of the preceding claims characterized in that the biomass consists of microorganisms genetically modified to emit bioluminescence.

7 - illumination system according to claim 6 characterized in that said microorganisms are cyanobacteria. 8 - illumination system according to one of the preceding claims characterized in that the biomass in excess in the reaction vessel (1) is transferred into an annex container (4) for processing. 9 - illumination system according to one of the preceding claims characterized in that it comprises means for recovering molecules of interest. 10 - illumination system according to one of the preceding claims characterized in that it comprises optically active dopants. 11 - Illumination system according to the claim

Characterized in that said optically active dopants are incorporated into the biomass.

12 - illumination system according to claim 10 characterized in that said optically active dopants are incorporated in the envelope of said conduit.

13 - illumination system according to one of claims 1 to 11 characterized in that at least one of the faces of the ducts is reflective.