DE102010055287B4 - Method and device for cultivating and transporting aquatic plants - Google Patents

Abstract

The invention relates to a method for cultivating and transporting living aquatic plants, which are continuously multiplied in a cultivation reactor and transported from there to a utilization point for the biomass produced, according to the preamble of claim 1. In order to improve the CO2 balance of the biomass transport considerably It is proposed according to the invention that the aquatic plants are transported via a biomass pipeline which is at least partially exposed to light by means of slowly moving culture water, in such a way that the said plants reproduce again on the transport route.

Description

The invention relates to a method for cultivating and transporting live aquatic plants, which is continuously propagated in a cultivation reactor and transported from there to a recovery point of the biomass produced, according to the preamble of claim 1.

From the DE 10 2008 012 154 A1 is a biomass conveyor indicated that promotes the biomass through a pipe by screw conveyor.

This only considers the biomass transport of biomass in general. If, for example, land plants such as corn, etc. are harvested, this biomass is pretreated accordingly for the biogas plant and the prepared biomass is then conveyed into the fermenter.

When using aquatic plants as biomass, for example, there is no need for any customary mixing up with a fermentation triturate, but rather the aquatic biomass provides sufficient moisture.

The transport of maize or terrestrial plants as biomass, however, represents a negative contribution to the CO ₂ balance of this energetically regenerative concept.

Therefore, the object of the invention is to significantly improve the biomass transport in its CO2 balance.

The object is achieved according to the invention in a method of the generic type by the characterizing features of claim 1.

Further advantageous embodiments are specified in the dependent claims 2 to 10.

According to the invention, the object is achieved by the characterizing features of claim 11.

Further relevant advantageous embodiments are given in the remaining dependent claims.

The core of the process according to the invention is that the aquatic plants are transported via a biomass pipeline, which is at least partially exposed to light, by means of slowly agitated culture water, such that the said plants reproduce again on the transport path.

In contrast to biomass transport or plant transport of land plants or maize, here the aquatic plants are transported alive, even so that they are transported by means of their culture water on or in which they swim. In particular, Lemnacea multiply in double within 1 to 3 days. It should also be noted that Lemnacea cultures prefer still water. The movement is so slow that it means quiescent water for the Lemnacea. In this way, the transport phase of the living biomass is again final multiplication phase by the DOUBLE, or more.

Thus, the transport phase is included in the culture phase of the plants and this in the very special way mentioned.

This is on the one hand with no other biomass plant achievable, and thus the transport is again for mass propagation. This creates absolute CO ₂ neutrality, including the transport process. This is unique. Thus, the living biomass is transported directly from the culture reactor to the biogas plant or to the fermenter, or else to other plant utilization facilities.

In this case, not only is propagation on the transport route alone advantageous, but there is a further logistical homogenization of the provision of biomass for the various utilization processes.

So biomass is available in a controllable continuity.

In a further advantageous embodiment, it is stated that the biomass pipeline is hermetically closed and additionally gassed with CO ₂ . Thus, the biomass pipeline receives the same conditions as in biomass reactor d. Cultivation reactor itself, namely the hermetic conclusion and the enormously growth-demanding CO ₂ gassing.

In order to give the aquatic plants the condition of quasi-still waters, and not to disturb the propagation dynamics based on them, it is arranged that the mean flow velocity of the culture water is less than 1 meter per minute. In this way, a conveying distance of about 1.4 kilometers per day becomes possible.

There are also conveyor lines of several kilometers are possible if the increase in mass is taken into account accordingly, for example by width dimensioning of the pipeline, or by juxtaposition of several water transport routes, similar to the floor system of the cultivation reactor.

Furthermore, it is advantageous that nutrients are supplied to the culture water of the biomass pipeline at discrete locations / entry points. This leads to the fact that the aquatic plants can ripen in terms of content during the conveying section.

For this purpose, it is further configured that as nutrients trace elements and / or minerals and / or sugars and / or waste from sugar production, and / or molasses, and / or anthropogenic wastewater, and / or waste water from animal husbandry and / or from food production and / or from chemical production processes and / or yeasts.

Also or alternatively, the waste water from the recycled waste water of biogas plants or bioethanol plants can be at least partially mixed with the culture water of the biomass pipeline.

A particularly advantageous embodiment is that at the end of the biomass pipeline culture water is withdrawn at least as partially clarified / partially purified water.

Thus, the biomass pipeline even becomes a sewage treatment or sewage treatment plant.

In particular, but not exclusively in the use of the device as a kind of sewage treatment plant, it is important to supply the slowly flowing culture water oxygen, or oxygen-rich air, for example, to suppress bacteriological processes either or positively influence.

For this purpose, it is quite considerably advantageous that the water quality (pH value, nitrate value, specific pollutant values, suspended solids content) is measured in situ at at least one point in the biomass pipeline along the conveyor line and from this the flow rate and / or the amount of culture water or wastewater at the Entry into the biomass pipeline is controlled.

It is also important that to maintain a steady flow velocity, the biomass pipeline is disposed along a slope, and that are arranged to further influence the flow velocity flow elements far below the culture water surface, that the flow rate can be influenced without hindering the floating aquatic crops thereon the flow rate within the biomass pipeline is constantly monitored. So accounts for completely energy-consuming screw conveyors or the like.

It is particularly advantageous that readily separable highly mobile varieties of Lemnacea and / or Azolla be used as aquatic plants, with which a maintenance of a steady slow flow rate is possible.

With respect to one device, the essence of the invention is that the aquatic plants are transported via a biomass pipeline, which is at least partially exposed to light, by means of slowly agitated culture water such that the said plants reproduce again on the transport route. The exposure to light is limited to low light in Lemnacea, for example in the order of a few hundred to a few thousand lux.

In a further advantageous embodiment, it is stated that the biomass pipeline is provided with at least a partially translucent, hermetically sealed, CO ₂ -gassable envelope, in which the flowing culture water surface is arranged on at least one plane.

Furthermore, it is advantageously configured that the biomass pipeline has sensors for automatic culture water rapid analysis, and that the addition of culture water and / or wastewater takes place via a control device, in which the sensory detectable culture water rapid analysis takes place.

A further advantageous embodiment is that the biomass pipeline consists essentially of a hermetically sealed, connected to the main bioreactor at least partially light-transmitting film tunnel or tube.

The drawing contains an embodiment of the invention.

The picture shows a major biomass production reactor 1 (Cultivation reactor), in which aquatic cultivated areas are created in a floor system and aquatic plants are cultivated in it self-multiplying. In the main reactor 1 is a high rack density of, for example, 4 floors per meter height, created at a total height of 12 to 20 meters. There, the aquatic plants are then partially harvested daily and the so-called post-reactor 2 fed. This has a small rack density and distributed for the post-treatment phase, the light on less floors. From there, the aquatic plants are then in the at least partially translucent biomass pipeline 3 rinsed. This is arranged along a gradient. In it, the living biomass is then moved slowly as described above. So slowly that the lemnacea, for example, do not experience any disturbance and are transported on a quasi-silent cultivated area and thereby continue to multiply.

At the end of the biomass pipeline 3 finds a partial drying depending on further application 4 the biomass. Condensate is returned to the system, or supplied to the withdrawn at the end of the pipeline, at least partially clarified water mixing, and withdrawn as clarified water.

Afterwards the biomass becomes the fermeter of the biogas plant 5 fed. Leachate and / or fermentation residues from the fermenter are returned to the biomass reactor as a valuable raw material.

At the end of the pipeline, however, other utilizations and processes can also be connected.

Claims (14)

A method for cultivating and transporting live aquatic plants, which propagates steadily in a cultivation reactor and is transported from there to a recovery point of the biomass produced, characterized in that the aquatic plants are transported via a biomass pipeline at least partially exposed to light by means of slowly agitated culture water in that said plants multiply again during transport. A method according to claim 1, characterized in that the biomass pipeline is hermetically closed and additionally gassed with CO ₂ . A method according to claim 1 or 2, characterized in that the average flow rate of the culture water is less than 1 meter per minute. A method according to claim 1, characterized in that nutrients are supplied to the culture water of the biomass pipeline at discrete sites / entry points. A method according to claim 4, characterized in that as nutrients trace elements and / or minerals and / or sugars and / or waste from sugar production, and / or molasses, and / or anthropogenic wastewater, and / or waste water from animal husbandry and / or the food production and / or from chemical production processes and / or yeasts are fed. Method according to one of the preceding claims, characterized in that the culture water of the biomass pipeline wastewater from recycled waste water from biogas plants or bioethanol plants is at least partially mixed. Method according to one of the preceding claims, characterized in that at the end of the biomass pipeline culture water is withdrawn at least as partially clarified / partially purified water. Method according to one of the preceding claims, characterized in that measured at least one point in the biomass pipeline along the conveyor line, the water quality such as pH, nitrate value, specific pollutant values and suspended solids in situ and from the flow rate and / or Zusuduerungsmenge of culture water or Wastewater is controlled at the entrance to the biomass pipeline. Method according to one of the preceding claims, characterized in that to maintain a steady flow velocity, the biomass pipeline is arranged along a slope, and that for further influencing the flow velocity flow elements are arranged so far below the culture water surface, that the flow rate can be influenced without the floating thereon obstructing aquatic crops, while constantly monitoring the flow rate within the biomass pipeline. Method according to one of the preceding claims, characterized in that as aquatic plants easily isolatable highly mobile varieties of Lemnacea and / or Azolla are used, with which a maintenance of a steady slow flow rate is possible. Device for cultivating and transporting live aquatic plants, which is continuously propagated in a cultivation reactor and transported from there to a utilization point of the biomass produced, characterized in that the aquatic plants are transported by means of a slowly agitated culture water via an at least partially exposed biomass pipeline, in such a way that said plants reproduce again on the transport route. Device according to claim 11, characterized in that the biomass pipeline is provided at least with a partially translucent hermetically sealed, can be gassed with CO ₂ enclosure, in which the flowing culture water surface is arranged on at least one plane. Device according to claim 11 or 12, characterized in that the biomass pipeline sensors for automatic Has rapid culture analysis, and that the addition of culture water and / or wastewater via a control device, in which there is also the sensory detectable culture water rapid analysis. Device according to one of the preceding claims 11 to 13, characterized in that the biomass pipeline consists essentially of a hermetically sealed, and connected to the main bioreactor at least partial light-transmitting film tunnel or tube.

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