NL1037137C2 - BREEDING BED FOR MUSHROOMS, AND A DEVICE AND METHOD FOR PRODUCING MUSHROOMS. - Google Patents

Description

Brief description: Cultivation bed for mushrooms, and apparatus and method for growing mushrooms.

DESCRIPTION

According to a first aspect, the present invention relates to a cultivation bed for mushrooms comprising a permanent support surface and a temporary support surface which is displaceable relative to the permanent support surface, on which a temporary breeding ground for mushroom cultivation is present when applied.

Such a culture bed is known. The known culture bed is part of a scaffold with uprights that support a number of culture beds that are located above one another and that extend horizontally. The known culture bed has a grid as permanent support surface, over which as a temporary support surface a cloth has been drawn on which the nutrient medium of compost with brood and supplementary food for mushrooms to be grown is located. A layer of heat-insulating material is located under the permanent support surface to prevent heat being released to the environment from the bottom of the culture bed of the culture bed. The culture medium is usually covered with casing soil. A known cultivation bed for growing mushrooms is filled with approximately 90 kg / m2 of nutrient medium and approximately 40 l / m2 of soil. Mushrooms are grown and harvested from the culture medium for a few weeks. After a while, the activity of the culture medium is insufficient for an operationally efficient culture and the cloth with the culture medium and the soil on it is pulled from the permanent support surface. Subsequently, the cloth is moved over the permanent bearing surface as a conveyor belt, wherein the nutrient medium is discharged and a new nutrient medium is then deposited on the fabric.

A drawback of the known culture bed is that the activity of the culture medium diminishes relatively quickly and must already be replaced relatively quickly, as a result of which only a limited part of the culture capacity present in the culture medium can be utilized before the culture medium has to be replaced in order to operate efficiently. able to grow mushrooms.

The present invention therefore has for its object, according to the first aspect, to provide a cultivation bed according to the introduction, with which a larger part of the capacity of the culture medium can be utilized for the operating efficiency of growing mushrooms. This object is achieved according to the present invention in that temperature control means are present under the temporary nutrient medium present in use for being able to control the temperature of the nutrient medium, wherein the temperature control means are at least partially surrounded by insulating material. With the temperature control means, the temperature of the culture medium can be controlled such that more mushrooms can be grown per kilo of culture medium. It has been found that with the use of such a temperature control less, in advantageous cases about half less, nutrient medium is required in comparison with a known culture bed without the use of such temperature control means. Moreover, the culture medium need be replaced less quickly compared to the known culture bed. As a result of the temperature control, active substances present in the culture medium can be activated to a sufficient extent for longer than in the known culture bed. In other words, even at a relatively low concentration of brood and supplementary food, mushrooms can be grown in the compost in an operationally efficient manner. The insulation means ensure efficient heat supply and removal. It is thus possible to leave the temperature control means free where effective heat transfer between temperature control means and the culture medium can be realized, i.e. between insulation material and a culture medium located above it. Other parts of the temperature control means may be surrounded as far as possible by insulating material to limit heat transfer between the temperature control means and the environment. The object of the present invention has thus been achieved.

Heating means are already present in mushroom growing rooms. However, it concerns air heating in which the temperature of a culture bed is kept fairly constant by the warm ambient air, which has a much lesser effect and with relatively great delay has an effect on the temperature 30 'of the culture medium. Moreover, the ambient air is only suitable to a limited extent for influencing the temperature of the culture medium, because requirements are also imposed on the ambient air in which the mushrooms grow, such as a limited suitable temperature range and a minimum of air displacement. The heating device for heating the air may not be regarded as a temperature control device because of said moderate influence and the delay occurring. In any case, that air heating device does not extend below the temporary nutrient medium present at use.

In a preferred embodiment according to the present invention the insulating material comprises a plate-shaped insulating element, in which temperature control means are at least partially included. For example, fluid lines may extend at the top of the plate-shaped insulating element, the top of the fluid lines being released for releasing and / or absorbing heat to or from the nutrient medium, respectively. This is a simple solution with good insulation to prevent heat transfer between the temperature control means (fluid lines) and the air in the grow room.

Alternatively, the temperature control means comprise temperature control means, wherein individual temperature control means are partially surrounded by separate insulation elements. For example, fluid lines as temperature control members can extend below the nutrient medium and be partially surrounded by insulating material, not a C-shaped cross-section, the opening being at the top, at least facing the nutrient medium. Less insulation material is thus required for furnishing a growing space.

For a good heat transfer between the temperature control means and the nutrient medium, it is preferred that the temporary support surface is connected to the temperature control means. This connection can be direct or indirect, for example via the permanent support surface.

It is preferred that the temperature control means are located at least in part between the permanent bearing surface and the insulating material. The nutrient medium can thus be heated or cooled via the support surface by the temperature control means. When the permanent support surface is provided with air passages, in particular when the permanent support surface is a grid, a highly efficient and direct heat transfer can take place between the temperature control means and the nutrient medium. The insulating material can thereby prevent heat from being transferred in a different direction or from a different direction.

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In a preferred embodiment according to the present invention, the temperature control means comprise a fluid line which extends at least partly under the temporarily present nutrient medium. Below the temporary nutrient medium there is a (empty) space where the fluid line can extend. When insulating material is provided under the fluid conduit, radiation heat from the fluid conduit is prevented from influencing the temperature in a lower culture bed.

In order to be able to properly control the temperature of the culture medium, it is preferred that the temperature control means are suitable for transferring heat to and for absorbing heat from the culture medium. Because the culture medium for mushroom cultivation can start to breed, it is not only important that the culture medium can be heated, but it must also be possible to cool the culture medium.

In order to be able to adjust the temperature control means properly, it is preferred that temperature sensors are provided for monitoring the temperature of the culture medium. The temperature in the culture medium can be influenced by factors that are not, or hardly, at all, controlled. Temperature sensors can support a rapid response by the temperature control means to temperature changes in the culture medium below * 20.

When using the cultivation bed according to the present invention, it is preferred that for growing mushrooms, a maximum of 65 kg, furthermore preferably a maximum of 55 kg, of nutrient medium per square meter of permanent support is present in the culture bed. Because at relatively favorable temperature, relatively high yields can be realized in the culture bed mutatis mutandis, with 40 to 50 kg culture medium per square meter the yield of the previously discussed known culture bed can equal or even exceed.

The temporary bearing surface preferably comprises a cloth. A cloth, for example a nylon cloth, provides a suitable support surface for the culture medium and is furthermore suitable for a favorable heat transfer between the temperature control means present under the cloth and the culture medium.

According to a second aspect, the present invention relates to a cultivating device for cultivating mushrooms, comprising at least one closable space with at least one shelf with a permanent support surface and means for arranging a temporary support surface with a temporary breeding ground for mushroom cultivation.

Such a culture device is known and comprises a culture bed of the previously discussed known type. The present invention has for its object, according to the second aspect, to provide a cultivation device with which a larger part of the capacity of the culture medium can be utilized for the efficient cultivation of mushrooms. This object is achieved according to the present invention in that temperature control means are present under the temporary nutrient medium present in use for controlling the temperature of the nutrient medium. The advantages of such a device correspond to the advantages discussed in the first aspect of the present invention.

It is thereby preferred that a culture device a culture bed according to the first aspect of the present invention is used.

It is furthermore preferred here that the temperature control means comprise a fluid line which extends at least partly under the temporary nutrient medium.

The temperature control means preferably comprise a heat source and a cold source, wherein a heat exchanger is provided between the heat source and / or the cold source on the one hand and the fluid line on the other. Thus, heat extracted from the culture bed via the temperature control means can be stored via a heat exchanger. Conversely, stored heat can thus be applied via the heat exchanger for heating the nutrient medium.

According to a third aspect, the present invention relates to a method for cultivating mushrooms, comprising the steps of: a) providing a closable space with at least one permanent support surface; b) arranging a temporary support surface with a nutrient medium for mushrooms over the at least one permanent support surface; c) growing 6 mushrooms in the room under controlled conditions; d) harvesting mushrooms; and e) removing the temporary support surface and the nutrient medium thereon when the activity of the nutrient medium. In this case step c) is a continuous process which in principle takes place continuously between step b) and step e). During step c), step d) is generally carried out several times.

Such a method is known, but has the disadvantage that the temperature in the culture medium can only be controlled to a limited extent. In fact, this mainly occurs indirectly as a result of the climate control in the relevant space that compensates for temperature fluctuations in the culture medium due to the extent to which it is brewing. The present invention thus has for its object to provide such a method, wherein the temperature control in the culture medium is improved compared to the temperature control in the known device. This object is achieved by the present invention in that in step c) the temperature of the culture medium is controlled with the aid of temperature control means which are located below the temporary support surface. The advantages of such a method have already been discussed with regard to the above-mentioned devices according to the first and second aspect of the present invention.

It is preferred that a culture bed according to the first aspect of the present invention is used. The advantages of this, too, have already been discussed, as have those of a preferred method in which the temperature of the culture medium is heated or cooled with the aid of fluid flowing through pipes extending at least partially under the culture medium.

The present invention will be explained in more detail below with reference to the accompanying figures, in which:

Figure 1 shows a longitudinal sectional view of a culture bed according to the present invention; and Figure 2 is a schematic representation of a temperature control system for a culture device according to the present invention.

Figure 1 shows a cultivation bed 1 for mushrooms. The culture bed 1 comprises a number of uprights 2 between which longitudinal beams 3 extend. Inverted U-shaped transverse sections 4 extend between the longitudinal girders 3 under a layer of 7 insulation material 5 at the top where recesses 6 are provided through which water pipes 7 extend in the width direction that two pipes extending in the longitudinal direction (not shown) extend connect the two sides of the culture bed 1 to each other. A grid 8 extends above the insulating material 5 and the conduits 7 and is fixed to the uprights 2. A nylon cloth 9 has been drawn over the grid 8 on which there is a layer of compost 10 with the soil 11 on it, in which mushrooms 12 grow. Edge boards 13 extend between the uprights 2 both in the longitudinal direction and in the width direction of the culture bed 1.

Figure 2 provides a schematic overview of a heating / cooling installation 21 according to the present invention with a heat source 22 and a cold source 23 with respective supply lines 24, 25 and return lines 26, 27 to or from heat exchanger 28. The supply lines 24, 25 are provided of thermostatic valves 29, 30. The return lines 26, 27 are provided with immersion sensors 31 and 32. On the heat exchanger 28 there is a circulation line 33 for the heating / cooling system for the culture beds (not shown in Figure 1). The circulation line 33 is in communication with an expansion vessel 34 and breather 35 and is connected to a circulation pump 36 which pumps fluid from circulation line 33 via distributor 37 and ball valves 38 to lines 39 through 20 respective culture beds (not shown). The heating or cooling water flows via control valves 40 to collector 41 and then via circulation line 33 back to heat exchanger 28. Distributor 37 is provided with an overflow valve 42 and collector 41 is provided with fill and drain valve 43.

Now looking at Figure 1, nylon cloth 9 is supported as a temporary carrier for a temporary nutrient medium from compost 10 and soil earth 11 by grid 8. When the nutrient medium cannot be activated sufficiently or yields insufficiently for the profitable cultivation of mushrooms 12, that is, if the culture medium contains (too) little incubation and / or supplementary nutrients, the nylon cloth 9 with the culture medium and any remaining mushrooms 12 is pulled from the grid 8 of the culture bed 1. Subsequently, a new nylon cloth 9 filled with compost 10 and cover soil 11 is drawn over grid 8. The activity of the culture medium depends on the concentration of enzymes in the compost 10 and the temperature of the compost 10. The culture bed 1 is usually located in a sealed, conditioned room, but δ because compost 10 tends to heat up of compost 10 a factor that is difficult to control without sufficient control. To this end, after the nylon cloth has been filled, resistance sensors 14 are inserted into the compost 10, which send temperature information to the control device via (not shown) wiring. The control device determines on the basis of the temperature information of the resistance sensors 14 whether the temperature in the nutrient medium must be adjusted upwards or downwards. The desired temperature of the water then determines which must be passed through pipes 7 (39 in Figure 2). Hot water will release heat from the pipe 7 upwards and this heat will be absorbed by the compost 10. Although the pipes 7 in Figure 1 are drawn at a distance from the grid 8, for a good heat transfer it is preferred that the pipes 7 make direct contact with the grid 7. When the compost 10 is (too) hot, a cooler liquid is just passed through pipes 7, wherein water flowing through pipes 7 will absorb heat and cool the compost 10. The temperature control can be supported by temperature information of water supplied to the culture bed 1 and water discharged from the culture bed. Moreover, it is possible to suspend infrared cameras above the culture bed 1 for measuring the surface temperature of the culture bed 1. This information can also be fed back to the control device for determining or adjusting the desired temperature of the temperature below the culture bed. 1 water to be supplied.

The control device can be set to control the temperature of an entire culture bed, but it is also possible for the culture bed 25 to be divided into compartments, so that the temperature of the culture bed can be controlled per compartment. The influence of incubation of the compost on the temperature can differ locally in a culture bed.

The temperature of the compost 10 is thus controlled for the optimum cultivation of mushrooms 12. Thereby, it is not always necessary to strive for the optimum temperature for mushroom cultivation. It is also possible to control temperature such that it can be determined in advance that the mushrooms 12 are ready for harvesting at a certain moment. Logistical advantages can thus be achieved by actively controlling the degree of growth using the heating / cooling installation. Furthermore, from a comparable amount of compost, 10 more yield can be realized than with a known system in which the temperature is not controlled, because the compost can be used for longer than in known culture beds.

The heating * / cooling installation from figure 2 speaks for itself and requires no further explanation.

The foregoing has described a preferred embodiment of the present invention by way of example only. It will be clear that various variants, whether or not obvious to those skilled in the art, are conceivable within the scope of the present invention which is defined by the following claims. For example, the description focuses on the cultivation of mushrooms, but it is of course also possible to cultivate other types of mushrooms in a similar cultivation bed. A different type of compost or a different ratio between compost and casing earth can be applied to the nylon cloth. Currently, nylon cloth is frequently used for mushroom growing beds, but it should be clear that cloths of other materials can also be used. The growing bed of a growing device can also be designed differently, for example as a permanent support on which crates with culture medium are placed, which are taken from the permanent support for harvesting mushrooms or for refreshing the culture medium. The conduits extending under the culture bed need not be included in recesses of insulating material. The advantage of fluid lines under the lattice on which the nylon cloth rests is that the fluid lines cannot easily be damaged when changing the nylon cloth and the culture medium. This document describes as an example a hot / cold water pipe for transporting heat / cold. Another suitable fluid can be used instead of water. It is even possible to transport heat and cold in a different way than through fluid lines to and from the culture bed, for example by radiant heat.

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Claims (17)

Cultivation bed for mushrooms comprising a permanent support surface and a temporary support surface which is displaceable relative to the permanent support surface, on which a temporary breeding ground for mushroom cultivation is present when applied, characterized in that temperature control means are present under the temporary breeding ground present during use for being able to control of the temperature of the culture medium, which temperature control means are at least partially surrounded by insulating material. A culture bed according to claim 1, characterized in that the insulating material comprises a plate-shaped insulating element, in which temperature control means are at least partially included. 3. Culture bed according to claim 1, characterized in that the temperature control means comprise temperature control means, wherein individual temperature control means are partially surrounded by separate insulation elements. 4. Culture bed according to one or more of the preceding claims, characterized in that the temporary interface is in communication with the temperature control means. 5. Culture bed as claimed in one or more of the claims, characterized in that the temperature control means are at least substantially between the permanent support surface and the insulating material. 6. Culture bed according to one or more of the preceding claims, characterized in that the temperature control means comprise a fluid conduit which extends at least partly under the temporarily present nutrient medium. 7. Culture bed according to one or more of the preceding claims, characterized in that the temperature control means are suitable for transferring heat to and for absorbing heat from the culture medium. 8. Culture bed according to one or more of the preceding claims, characterized in that temperature sensors are provided for detecting the temperature of the culture medium. Culture bed according to one or more of the preceding claims, characterized in that a maximum of 65 kg of nutrient medium per m2 of permanent support is present in the culture bed for the cultivation of mushrooms. Culture bed according to one or more of the preceding claims, characterized in that the temporary bearing surface comprises a cloth. 11. Cultivation device for cultivating mushrooms, comprising at least one closable space with at least one shelf with a permanent support surface and means for arranging a temporary support surface over the permanent support surface with thereon a temporary breeding ground for mushroom cultivation, characterized in that there are temperature control means for controlling the temperature of the culture medium, which temperature control means are at least partially surrounded by insulating material below the temporary culture medium present in use. 12. Culture device according to claim 11, characterized in that the culture device comprises a culture bed according to one or more of claims 1 to 8. A culture device as claimed in claim 11 or 12, characterized in that the temperature control means comprise a fluid line which extends at least partly under the temporary nutrient medium. 14. Growing device according to claim 13, characterized in that the temperature control means comprise a heat source and a cold source, wherein a heat exchanger is provided between the heat source and the cold source on the one hand and the fluid line on the other. 15. Method for cultivating mushrooms, comprising the steps of: a) providing a closable space with at least one permanent support surface; b) arranging a temporary support surface with a nutrient medium for mushrooms over the at least one permanent support surface; c) growing mushrooms under space under controlled conditions; d) harvesting mushrooms; and e) removing the temporary support surface and the nutrient medium located thereon when the activity of the nutrient medium, characterized in that in step c) the temperature of the nutrient medium is controlled with the aid of temperature control means located below the temporary support surface, which temperature control means are at least partially surrounded by insulating material. Method according to claim 15, characterized in that a culture bed according to one or more of claims 1 to 10 is used. 17. Method as claimed in claim 15 or 16, characterized in that the temperature of the culture medium is heated or cooled with the aid of fluid flowing through pipes extending at least partially under the culture medium. 1 03 7 137