CS212948B1 - Cultivation device with varying gradient of temperature for phototrophous organisms on hard soils - Google Patents

Description

The present invention relates to a variable temperature gradient cultivation apparatus for the cultivation of phototrophic organisms, characterized by the possibility of varying the temperature gradient variations, wherein the temperature gradient can be set in advance or can be varied during the experiment.

The cultivation of phototrophic organisms, for example algae in adjustable temperature gradient devices, is! very profitable and promising. The adjustable temperature gradient device should allow the growth rate or other factors to be monitored, for example the content of photosynthetic dyes in a large number of combinations, temperatures and lights within the desired boundaries within a single experiment. Using large agar plates, continuous temperature gradients can be imitated; light, nutrient and substance content, pH, etc., which are unreachable by suspension culture.

The hitherto known temperature gradient cultivator consists of a thicker aluminum plate, the thickness of which is between 2 and 6 cm. On two opposite sides of the plate, channels for the supply and discharge of the medium are drilled one above the other so that the supply and exhaust of the heat transfer medium is on one side and the cooling medium on the other side.

This creates a temperature gradient on the plate. Both media are connected to thermostats. In the upper area

212 948

212 948 aluminum plates are drilled holes to accommodate petri dishes. Some devices tend to? covered with a hatch with air and COg inlet.

The disadvantage of these cultivation devices is that they do not allow to change the nature of the course of the temperature gradient, which has a constant height, so that it is linear. Metal block is also expensive. As a result, the different temperature conditions for the growth of organisms need to be re-examined only under linear conditions, so that investigating all conditions is lengthy. Furthermore, it is expensive to manufacture a larger metal block. ·

These disadvantages are overcome by the variable temperature gradient cultivation device of the present invention, which consists in that the bed for Petri dishes is formed by an inner vessel placed in a larger vessel, and both vessels are connected by adjusting screws, leaving free space between the bottoms of both vessels. filled with a porous absorbent and one side of the larger vessel has a heating tube and the opposite wall has a cooling tube and at the bottom of the inner vessel is water or gauze saturated with foil under the Petri dishes. holes.

An important advantage of the cultivation device according to the invention is, in particular, the possibility to vary the temperature gradient pattern in any one experiment so that, in a single batch of investigated organisms, which can sometimes be expensive, their reaction to various patterns of temperature changes can be investigated. In addition to linear, other waveforms, such as an exponential temperature gradient, can be achieved on this device. Since the device is made of sheet metal, it is easier to manufacture than thick aluminum plates that are difficult to obtain.

The variation temperature gradient cultivation apparatus of the present invention is shown in the accompanying two drawings, in which Fig. 1 is a side view, with the coolant or heat pipe being shown behind the wall of the larger vessel; and Fig. 3 is a top view.

In an exemplary embodiment, the cultivation device consists of an inner container 1, which may be, for example, 80 x 60 x 10 cm. This inner vessel 2 is located in the larger vessel 2, so that there is a free space 12 between the bottom and the side walls of the two vessels 1,2. The two vessels 1, g are connected by four adjusting screws 11 so that their relative position can be changed. The space between the bottom of the two containers 1, g is filled with water and an absorbent, for example with foam. In the free space on two opposite sides of the larger vessel g, a cooling tube 4 is located on one side and a heating tube 4 on the other side with the possibility of precise temperature control. Water is intensively mixed around the heating and cooling pipe 4 ', while the heat is only transferred by conduction in the absorber 2. In the inner vessel 2, which actually represents the culture space, there is either a thin layer of water or gauze 2 saturated with water at the bottom. This thin layer of water or gauze 2 is covered with a foil 5 with openings 2. for placing the Petri dishes 2. The culture space is covered with a transparent cover

10. in which the supply 13 of the air / G0 ₂ mixture is scored in an optional ratio. Position

Thus, it is possible to vary the thickness of the absorbent material evenly or to create a wedge which on the one hand intensifies the heat supply or dissipation, so that a non-linear temperature gradient can be achieved during the experiment.

The variable temperature gradient culture apparatus of the present invention can be used to grow organisms in cross-over temperature and light gradients, or the temperature gradient can be combined with a pH gradient, nutrient concentration, or individual gradient. The cultivation equipment is used primarily for cultivation on solid soils for algae and oceans, for trophic potentials of water samples, ecophysiological characteristics, seed germination tests and for laboratory models of algal growth rates and whole microfytes communities.

Claims (1)

BEFORE YOUR INVENTION Variable temperature gradient cultivation equipment for phototrophic organisms on solid soils, consisting of a bed for Petri dishes, which is connected on one side to the supply of thermal medium and on the opposite side to the supply of coolant and the cultivation space with Petri dishes is covered with a transparent hatch fed a mixture of air and C0 _2, characterized in that the lože- petri dish (6) is formed by an inner container (1) placed in a large container (2) and both vessels (1, 2) are connected by adjusting the ER, ou (11), wherein the void space between the bottoms of the vessels (1, 2) is filled with a porous absorbent (3) and at one wall of the larger vessel (2) there is a heating tube (4) and at the opposite wall there is a cooling tube (5); at the bottom of the inner container (1), under the Petri dishes (6), water or gauze (7) is saturated with a water-covered foil (8) with openings (9).