Reactor for bulk production of photosynthetic microorganisms

Abstract

An algae production reactor system according to the invention comprises a reactor vessel which is provided with: one or more liquid inlets and one or more liquid outlets; one or more gas inlets at the bottom, said gas inlets being connected with a source of carbon dioxide, and one or more gas outlets at the top of the vessel; vertically interspaced and joined pairs of double glass plates which are at least partially submerged in the reactor liquid, said double glass plates having a layer of light-scattering particles in between and having a flat side being exposed to a light source; and means for vertically circulating reactor liquid.

Claims

1. A set of two or more rectangular double glass plates having a layer of light-scattering non-uniformities or light-scattering particles between single glass plates, the single glass plates having a thickness from 5 to 50 mm, a length between 1 and 4 m, and a width between 0.5 and 2.5 m, the two or more double glass plates being mounted in parallel at a distance between 10 and 200 mm, the distance being provided by glass strips having essentially the same length as the rectangular double glass plates and being arranged along and fixed to only the long sides of the double glass plates.

2. The set of double glass plates according to claim 1, wherein the light-scattering non-uniformities or particles have an average size between 0.2-1.2 m.

3. The set of double glass plates according to claim 1, wherein the light-scattering particles are facetted particles having an average size between 10 m to 500 m, acting as geometric scatterers.

4. The set of double glass plates according to claim 1, wherein the two or more double glass plates are mounted at a distance of between 20 and 150 mm.

5. The set of double glass plates according to claim 1, wherein the glass has an iron content below 0.04 wt. % (as Fe.sub.2O.sub.3).

6. A rack in which a plurality of equidistant sets of double glass plates having a layer of light-scattering non-uniformities or light-scattering particles between single glass plates are mounted, the single glass plates having a thickness from 5 to 50 mm, a length between 1 and 4 m, and a width between 0.5 and 2.5 m, the two or more double glass plates being mounted in parallel at a distance between 10 and 200 mm, the distance being provided by glass strips having essentially the same length as the rectangular double glass plates and being arranged along and fixed to only the long sides of the double glass plates, and the rack having guide strips allowing the multiple arrays to be stacked in a reactor vessel.

7. The rack according to claim 6, wherein the plurality is 2-20 sets of double glass plates.

8. The rack according to claim 6, wherein the guide strips are supported by carrier strips.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 schematically shows a section in the vertical plane of the reactor showing the principal parts thereof. A reactor vessel (1) is used for growing the algae. It has an up-flow channel (2) and a down-flow channel (3), which can alternate by switching the feeds (4) and (5) of the gas mixing flow (6). The up-flow and down-flow are separated by a vertical plate (7), the water level in the vessel is indicated with (8). To make this reactor suitable for algae growth, vertical glass plates (9) are installed in the up-flow and in the down-flow channels. Foam-like objects (10) move upward in the up-flow zone for cleaning the glass plates.

(2) FIG. 2 shows a section in the horizontal plane of the reactor with the light mirror system. The vertical pairs of glass plates (9) in the up-flow zone (2) and down-flow zone (3) are shown. The front parts (11) of these plates are protruding from the reactor wall (12) into the light source (13). These glass plates (9) are used to transfer light into the reactor which is necessary for growth of the algae (14) inside the reactor (1). The glass plate consists of 2 layers (15) and (16) with a coating (17) in between, in which small metal parts are mixed that function as mirror facets to scatter the light in such a way that the light can enter the water.

(3) A set of mirrors (18) is mounted on a sun-tracking system (19) to reflect the sunlight during the day under a constant angle on the exposed part of the glass plates sticking in the gas-lift-loop channels of the reactor. To reduce the heating effect of the sunlight, the mirrors (18) are provided with a coating (20) in such a way that only the wavelengths between 400 and 700 nm, necessary for algal growth, are reflected to the reactor.

(4) FIG. 3 shows a set of double glass plates in more detail. The set of glass plates (21) is composed of two double glass plates (9). The set of glass plates contains 4 glass plates (15,16 twice) with layers (17) of scattering particles in between. Two glass strips (22,23) are positioned and sealed between the inner glass plates.

(5) FIG. 4 shows a rack containing an array of double glass plates as a horizontal section (or top view). Sets of double glass plates (21) are mounted in a rack having side walls (33) and front and back walls comprising spacing strips (34) between the sets of glass plates.

(6) FIG. 5 shows the rack in perspective. The rack (30) comprises side walls (33) and strips (34) for spacing the glass plates as front and back walls. The rack has an upper part (31) and a lower part (32), for supporting the glass plates, and for allowing the racks to be stacked. A detachable device (35) for hoisting the rack into and out of the reactor vessel is mounted at the top of the rack.

(7) FIG. 6 shows a stacked reactor (40) containing eight racks (30) as depicted in FIG. 5. The stacked reactor has a bottom part (41) containing gas distributors driving the airlift loop (not shown) fed by gas pipes (42) connected to a gas supply (43), liquid/product lines and a liquid/product exit (not shown), and a top part (46) containing liquid inlets (not shown) and a gas exit (47). A three-way valve (44) between gas supply (43) and gas lines (42) allows to change the gas flow from one compartment to the other thus changing the riser part to downer part and vice versa. Guiding strips (45) supported by carrier strips (48) allow the racks (30) to be slid out of and into the stacked reactor assembly in case of e.g. maintenance or replacement.

(8) The glass plates in the modules are stacked in such a way that they form continuous vertical channels from top to bottom of the stacked reactor. The separation baffle (7) between riser and downer parts runs over the height of the glass modules, so that the space over the glass modules and under is open. As a result, the reactor content (water and algae mixture) can circulate from riser to downer at the top, and from downer to riser in the bottom to create a closed loop.

(9) While FIG. 6 shows two stacks of single racks, one serving as a riser and one as a downer part, more than two racks are equally feasible. For example, the reactor assembly may comprise three stacks, one as a riser, one as a downer, and the third one which can be switched off for maintenance or the like; in this case the valve (44) is a multi-way valve which ca be switched to either of the three or more stacks.

(10) CO.sub.2 can be injected in the air or gas mixture which drives the circulation loop and ensures the stripping of oxygen produced in the reactor. There is a level control in the reactor (not shown) and all water lost by harvesting of the algae and due to evaporation is pumped into the reactor at any point (total mixed system). Nutrients are fed into the reactor together with the make-up water.