NL1032779C2 - Greenhouse operating method with enriched carbon dioxide atmosphere, involves cooling greenhouse or dehumidifying greenhouse air and supplying ambient air at given rate - Google Patents

Abstract

In a first situation where there is excess heat inside the greenhouse, ambient air is supplied from the outside atmosphere to the greenhouse at a maximum rate of 25 m3>/h/m2> greenhouse surface area, air from the greenhouse is dehumidified by mechanically cooling, and a mixture of ambient air and air from the greenhouse is delivered to the plants. In a second situation where there is more excess heat inside the greenhouse compared with the first situation, the greenhouse is mechanically cooled at 75% or more of the maximum cooling capacity, ambient air is supplied to the greenhouse at a rate which is at least 5 m3>/h/m2> greenhouse surface area greater than the rate in the first situation, and a mixture of ambient air and air from the greenhouse is delivered to the plants. An independent claim is also included for an air conditioning box comprising a casing with an inlet for air from a greenhouse, a first heat exchanger for cooling air supplied via the inlet, a second heat exchanger for heating the air, a fan, and an outlet for the air. A sealable second inlet for ambient air is located between the first heat exchanger and fan.

Description

Method for operating a greenhouse, as well as an air treatment cabinet

The present invention relates to a method for operating a greenhouse, wherein an increased CO2 concentration is maintained in the greenhouse.

Such a method is generally known in the art. The CO 2 may come from, for example, a combined heat and power plant. In such a case, the CO2 released during the combustion of, for example, natural gas and which CO2 would otherwise be released into the atmosphere, is used to increase the yield of the crop grown in the greenhouse. When an open greenhouse is used, that is to say a greenhouse in which removal of the surplus of heat and / or moisture takes place purely by means of ventilation, the CO2 supplied quickly disappears via the ventilation openings of the greenhouse. The CO2 supply capacity is already maximally utilized in practice, as a result of which the desired CO2 level cannot be achieved under conditions with a large heat surplus, and as a result of which CO2 thus escapes quickly through the ventilation openings.

The present invention has for its object to provide a method of the type mentioned in the preamble, with which the greenhouse can be operated as economically as possible under a variety of conditions that vary throughout the year.

The invention relates in particular to a method for operating a greenhouse, wherein an increased CO2 concentration is maintained in the greenhouse, wherein - under first circumstances with a surplus of heat in the greenhouse outside air with an outside air flow rate of a maximum of 25 m3 outside air / h per m2 of greenhouse area is supplied to the greenhouse, air from the greenhouse 30 is dehumidified by mechanical cooling, and air which is a mixture of outside air and air from the greenhouse is brought to the crop, and - under second conditions, where compared to the first circumstances greater heat surplus in the greenhouse is such that mechanical cooling is carried out with a capacity of at least 75% of the maximum mechanical cooling capacity, outside air with an outside air flow that is at least 5 m3 outside air / h per m2 of greenhouse area greater than that used under in the first circumstances, the greenhouse is supplied with 1032770¾ 2, and air which is a mixture of outside air and air u it the greenhouse is brought to the crop.

The set goal is thus achieved to a large extent by providing optimum growth conditions at the lowest possible costs. A closed greenhouse is a greenhouse in which at least part of the cooling and / or dehumidification is achieved by means of mechanical cooling. As a result, a higher CO2 content can be maintained in the greenhouse, but the problems with regard to excess heat and / or air humidity are greater. The surplus heat in a closed greenhouse is at least partly removed by mechanical cooling and / or dehumidification. In the present application, mechanical cooling means any form of cooling using a heat exchanger. In the context of the present invention, the term "heat exchanger" means any system with which heat is exchanged by conduction. This therefore also comprises, for example, a heat exchanger in which a cold medium flows over a surface and the cold medium is in direct contact with the air to be cooled and / or dehumidified. An important disadvantage of a closed greenhouse that uses an aquifer for mechanical cooling is that the aquifer area is so large that third parties are hindered in their possibilities to use the aquifer. In other words, the aquifer surface can be considerably larger than that of the greenhouse. It is an important object of the present invention to substantially reduce or even eliminate this disadvantage. It has been found that with the aid of the method according to the invention the required aquifer area (i.e. the annual capacity) can be reduced by as much as 60% or even 75%. A further object of the present invention is to reduce costs in comparison to a closed greenhouse at all times. F. A considerable saving appears to be possible on the peak capacity of the mechanical cooling, and thus on the number of required wells of the aquifer and / or their size. According to the present invention, the greenhouse can in fact be operated for most of the time with the majority of the advantages of a closed greenhouse, that is to say with a CO2 concentration increased at a low cost, and optimum temperature for the crop in question and humidity level. The investment costs are higher in comparison with an open greenhouse, but this is more than offset by the higher yield. The term "increased CO2 concentration" is understood to mean that even under the second conditions a CO2 content of at least 475 ppm can be maintained with an available CO2 supply of 125 kg / ha per hour, something that so far only with a (more expensive) ) closed greenhouse was feasible. The present invention makes it possible to achieve a CO 2 content of at least 575 ppm in an economical manner, wherein the supplied CO 2 benefits the plants to a greater extent. Under the first circumstances, the air that is brought to the crop as a mixture of outside air and air from the greenhouse, is preferably a mixture of outside air and dehumidified air. This also applies to the second circumstances.

The greenhouse is preferably a greenhouse in which air distribution channels are present for supplying air to a crop grown in the greenhouse with a controlled temperature and air humidity and the air which is a mixture of outside air and air from the greenhouse via the air distribution channels at the crop brought.

A method is thus provided with which both the climate in the greenhouse can be accurately controlled and a cost saving on cooling of the greenhouse can be achieved through a far-reaching integration of both functions. The air distribution channels are, for example, air distribution hoses, as is well known in the art.

A preferred embodiment is characterized in that during the second conditions in the air comprising outside air, water is sprayed for lowering its temperature, which thus moistened and temperature-reduced air is brought to the crop via the air hoses 25.

Thus, the cooling requirement and thus the need for ventilation for removing heat and / or moisture from the greenhouse is reduced, further reducing the loss of CO2.

According to an important embodiment, for mechanical cooling, an air treatment cabinet is used with an inlet opening for air from the greenhouse, a cooling block for dehumidifying the air supplied via the inlet opening, an inlet opening for outside air placed after the cooling block, and a fan placed after the inlet opening for outside air for discharging air treated in the air treatment cabinet via an outlet opening, the outlet opening being connected to an air distribution channel.

Such a use of such a special air treatment cabinet is particularly favorable, since under circumstances where outside air must be supplied / the supply of air from the greenhouse is automatically limited, and thus moisture is effectively expelled from the greenhouse. Furthermore, the reduction of the flow resistance can cause the fan in the air treatment cabinet to move a larger flow of air, whereby even more efficient moisture (and therefore latent heat) is expelled from the greenhouse. Even if the outside air that is introduced into the greenhouse is warmer than the air in the greenhouse, net heat can be removed. The supplied air is almost always drier, and by evaporating water the plant can easily keep itself cool, even in the supplied warm air. However, in practice it will be preferable not to expose the plant to large temperature changes. This can be done by atomizing water in the supplied warm and dry outside air (whether or not already mixed with or without dehumidified air from the greenhouse). As a result, the temperature of the air drops and the plant does not have to evaporate extra water. The outside air is sucked in through the air treatment cabinet and distributed over the crop via the air distribution channels and the greenhouse air is discharged through an opening (window) in the greenhouse cover, advantageously in the vicinity of the facade, preferably an opening in the facade itself.

Preferably, the CO 2 is supplied after the cooling block of the air treatment cabinet.

Thus, the air from the greenhouse to be dehumidified is not unnecessarily diluted, which would complicate the removal of moisture from the air from the greenhouse and would require a cooling block of greater capacity.

Preferably, under the first conditions, a maximum of 15, such as a maximum of 12 and more preferably a maximum of 10, such as a maximum of 7 m3 of outside air per hour per m2 of greenhouse area is supplied.

Thus, as little CO2 as possible is wasted while still dehumidification takes place through removal. This gives a saving on the cooling capacity so that the aquifer can be smaller.

Preferably, under the second conditions, a minimum of 5, in particular a minimum of 15 and preferably a minimum of 30 m3 of outside air is supplied per hour per m2 of greenhouse area.

Thus, under these circumstances that occur rarely, it is prevented that a large attack would otherwise be made on the cooling capacity. This would otherwise either increase the cost of an aquifer (more wells; larger - usually unused - pumping capacity) or increase the (energy) costs for cooling by means of heat pumps and the like. Preferably no more than 70 m 3 outside air per hour per m2 greenhouse area is supplied, more preferably no more than 55 m 3 outside air per hour per m2 greenhouse area, and most preferably no more than 45 mJ outside air per m 2 greenhouse area. This is achieved by choosing the maximum mechanical cooling capacity so large that this condition is met.

A further optimization is characterized by the fact that under conditions where there is a heat shortage and the relative humidity is too high, mechanical cooling is dispensed with and instead, outside air is supplied with a maximum of 25 m3 per hour per m2 of greenhouse surface via an inlet opening of an air treatment cabinet which inlet opening for outside air is located in front of a heat block, the outside air is heated by the heat block and supplied to the air distribution channel, and excess moisture is expelled by means of the air thus supplied.

Thus, the total of the periods that cooling is required for dehumidification under conditions is substantially reduced. Preferably, under the first conditions, a maximum of 15, such as a maximum of 12 and more preferably a maximum of 10, such as a maximum of 7 m3 of outside air per hour per m2 of greenhouse area is supplied.

Finally, the invention relates to an air treatment cabinet.

In general, it concerns an air treatment cabinet which comprises a housing with an inlet for admitting air from a greenhouse, a first heat exchanger for cooling air supplied via the inlet, - a second heat exchanger for heating air and a fan for supplying air via the inlet, and an outlet for discharging air supplied by the fan, wherein a closable second inlet opening for outside air is provided between the first heat exchanger and the fan.

The second inlet opening is preferably a controllable, lockable second inlet opening.

The greenhouse can thus be kept closed as much as possible, and an optimum adjustment of the air circulation for the crop in the greenhouse is made possible.

6

More specifically, it concerns an air treatment cabinet which comprises a housing with a first inlet opening for admitting air, a heat exchanger for cooling air supplied via the first inlet opening, and a fan for supplying air via the first inlet opening, and an outlet for discharging air supplied by the fan from the housing, wherein a closable second inlet opening for air is provided between the heat exchanger and the fan.

Such an air treatment cabinet is suitable in particular for the method according to the invention, since under circumstances where outside air must be supplied via the second inlet opening, the supply of air from the greenhouse is automatically limited, and thus moisture is effectively expelled from the greenhouse. Furthermore, the reduction of the flow resistance causes (as a result of the opening of the closable second inlet opening) that the fan in the air treatment cabinet displaces a larger flow of air, as a result of which even more efficient moisture is expelled from the greenhouse, as already explained above.

A preferred embodiment is characterized in that the air treatment cabinet comprises a housing with a first inlet opening for dehumidified air, a heat exchanger for dehumidifying the air supplied via the first inlet opening, a second inlet opening provided after the heat exchanger for non-dehumidified air, and a fan disposed after the second inlet opening for discharging air treated in the air treatment cabinet via an outlet opening, and the air treatment cabinet furthermore has a passage opening provided with lamellae, the heat exchanger being at a first angle with the vertical, the passage opening below a second angle with the vertical, the slats are placed under the heat exchanger and above an outside air flow path that is located between the second inlet opening and the fan, and the slats are provided with gutters for discharging during dehumidification of air conde condensed water falling from the heat exchanger.

Condensed water can thus be collected and discharged on the slats without any noticeable increase in air resistance in the air treatment cabinet.

7

For easy drainage of water, the gutters advantageously open onto a collection gutter.

For optimizing the air to be introduced into the greenhouse, preferably via the air distribution channels, the air treatment cabinet 5 preferably comprises a second heat exchanger for heating air.

This second heat exchanger is preferably located after the second opening.

The second inlet opening is preferably a controllable, lockable second inlet opening.

The greenhouse can thus be kept closed as much as possible, and an optimum adjustment of the air circulation for the crop in the greenhouse is made possible.

A preferred embodiment is characterized in that the slats are controllable slats with which the flow through the first inlet opening can be controlled.

The controllable slats thus fulfill a double role, and condensed water can be collected and discharged in the air treatment cabinet without any noticeable increase in air resistance. The invention also relates to a greenhouse provided with an air treatment cabinet according to the invention. The greenhouse is preferably connected to an aquifer.

The present invention will now be elucidated with reference to the drawing, in which Fig. 1 shows a sectional view of a greenhouse wall with an air treatment cabinet; and Fig. 2 shows an air handling unit in detail.

FIG. 1 shows an air treatment cabinet 1, a wall A of a greenhouse and a perforated air distribution hose B connected to the air treatment cabinet 1. The air treatment cabinet 1 has a first inlet 2 for air from the greenhouse, a second inlet 3 for outside air and an outlet 4 which opens out in the lumen of the perforated air distribution hose B. For passing air through the air treatment cabinet 1, it has an electrically driven fan 5. Air from the greenhouse can be cooled by means of a cooling block 6 (this cooling block is referred to as a heat exchanger in the foregoing description) . In addition, the air is also dehumidified. The cooling block 6 is, for example, a heat exchanger through which cold water is passed, for example from an aquifer and / or day buffer as known from WO 00/76296. The cooled and possibly dehumidified air can be mixed with outside air that is supplied via the second inlet 3.

In colder periods, the air, whether or not mixed with outside air, can then be passed through a heat block 7. This heat block 7 is, for example, a heat exchanger through which hot water is passed. The treated air then enters the air distribution hose B via fan 5 and into the greenhouse again.

For access to the present invention, the method according to the invention will be explained, as will be applied on a hot day. A 1-hectare greenhouse is provided with 80 air handling units (LBKs) with the structure shown diagrammatically in Fig. 1. Each LBK serves 125 m2 / greenhouse by means of an air hose (length 80 meters; diameter 80 cm), which is provided with holes through which the air supplied via the air distribution hose is distributed among the plant rows.

The cooling blocks of the AHUs used here have the following specifications:

Specification cooling block_High flow_Low flow 20 Aspirated greenhouse air: 8750 m3 / h 4375 m3 / h

Temperature 26 "C 26" C

Relative Humidity 85% 85%

Conditions after the cooling block

Temperature 20.7'C 16.9'C

25 Relative humidity 100% 100%

Cooling capacity 37.6 kW 37.6 kW

Water treatment g

30 Temperature of cooling water in 11 * C 11 "C

Cooling water temperature from 23.9 * C 23 ° C

Flow rate 2.5 m3 / h 2.7 m3 / h

Typical use of the proposed system on a hot day 35 can be explained as follows. The method makes it possible to work as much as possible with a high CO2 content in the greenhouse. With very small heat surpluses, for example at the start of the day, this surplus can be removed purely by supplying outside air (and removing greenhouse air). However, the CO2 loss will soon lead to a need for mechanical cooling in the event of a slightly higher heat surplus. These are the first circumstances. Mechanical cooling makes it possible to reduce or maintain the outside air flow. The outside air flow rate is preferably a maximum of 10 m3 / m2 greenhouse area per hour. With increasing heat surplus, the heat surplus and the dehumidification are increasingly realized by means of mechanical cooling, as a result of which the CO2 loss remains limited. As soon as the maximum cooling capacity is insufficient (or already from 75% thereof if a greater saving in the cooling water is desired), the second circumstances arise, in which the supply of outside air is increased at the expense of the CO2 concentration.

The maximum cooling capacity of the cooling block is achieved when the water flow through the cooling block is maximum (with pump used in this exemplary embodiment 2.7 m 3 / h). The maximum cooling capacity of the cooling block depends on the prevailing conditions, but can be determined in a conventional manner. The cooling capacity depends, for example, on the then available cooling water temperature and cooling water temperature.

The maximum cold capacity can then be determined by determining the air flow (in kg / s) that flows through the cooling block, and multiplying this by the difference of the incoming and outgoing enthalpy of the air.

The air flow through the cooling block can be determined with the aid of an anemometer, taking into account any differences over the flowed-through surface. The temperature and the Relative Humidity of the 1st number are determined on both sides of the cooling block. The enthalpy of the air is determined using a Mollier diagram for moist air, or equivalent tables, using the measured temperature and RH, as is known to those skilled in the art.

If the heat surplus increases to such an extent that mechanical cooling is insufficient - or a saving on the use of cooling water is desired and it is decided to take measures earlier (at least 75% of the maximum cooling capacity) (ie to reduce the outside air flow rate) to protect the crop in the greenhouse against the effects of the heat surplus - there are 10 second circumstances. At the transition from the first to the second conditions, the power of the cooling block is maintained at a value that is 75% or more of the maximum cooling power that can be achieved under these conditions. By increasing the outside air flow rate, this extra heat / moisture surplus is discharged to the outside, whereby it is accepted that the CO2 content falls because priority is given to saving on cooling water consumption. Under these second circumstances, the outside air flow rate can be increased to more than 4375 m3 / h, with another 4375 m3 / h flowing over the cooling block. The total air flow rate is then higher than 8750 m3 / h. By using LBKs as described in the method according to the invention, use is made for the cooling water saving measure of the usual installation (fan, air distribution hoses so that the crop is directly protected), while further benefiting from the fact that the flow weather position experienced by the fan drops.

In the event of a decreasing heat / moisture surplus, the system switches back in the reverse order.

A variant of the air treatment cabinet (Fig. 2) is provided with controllable slats 8 which are placed immediately after the cooling block 6. In the closed state, with a resistance mainly determined by the heat block 7, outside air is supplied to the greenhouse, whereby air can be expelled from the greenhouse. This is favorable in the case of exceptional situations (such a high temperature and / or humidity level in the greenhouse that the cooling block 6 can no longer cope with this, and the loss of supplied CO2 is preferable to the higher costs for a cooling installation with greater capacity and a larger required aquifer area).

For those situations in which air from the greenhouse is led through the cooling block fi, it is undesirable for condensed water to fall down on the cooling block 6 and can be sucked in by the fan 5 and re-enter the greenhouse. This makes it more difficult to reliably control the humidity level in the greenhouse. According to the invention, the slats 8 are preferably provided with gutters 9 along which the condensed water can be discharged. A collection gutter may be present which is connected to a drain pipe for the water (not shown). The controllable slats 8 thus fulfill a dual role: on the one hand for controlling the amount of air 11 from the greenhouse which is guided along the cooling block 6, and on the other hand for discharging water condensed on the cooling block 6.

Slats 10 can also be present for closing the second inlet opening 3. These slats 10 (this also applies to slats 5) preferably can be controlled remotely, and can be controlled (i.e., wholly or partially) opened and closed.

1032779

Claims (17)

1. Method for operating a greenhouse, whereby an increased CO2 concentration is maintained in the greenhouse, wherein - under initial conditions with a surplus of heat in the greenhouse outside air with an outside air flow rate of a maximum of 25 m3 outside air / h per m2 of greenhouse surface area at the greenhouse is supplied, air from the greenhouse is dehumidified by mechanical cooling, and air which is a mixture of outside air and air from the greenhouse is brought to the crop, and - under second conditions, whereby there is a greater heat surplus compared to the first conditions in the greenhouse is such that it is mechanically cooled with a capacity of at least 75% of the maximum mechanical cooling capacity, outside air with an outside air flow that is at least 5 m3 outside air / h per m2 greenhouse area greater than that used under the first conditions at the greenhouse is supplied, and air which is a mixture of outside air and air from the greenhouse is brought to the crop. 20 Method according to claim 1, wherein the air which is a mixture of outside air and air from the greenhouse is brought to the crop via the air distribution channels. 3. A method according to claim 2, wherein during the second conditions in the air comprising outside air water is sprayed for lowering its temperature, which air thus wetted and temperature-reduced is supplied via the air hoses to the crop. «V» + · 30 4. Method as claimed in claims 2 or 3, wherein for mechanical cooling an air treatment cabinet is used with an inlet opening for air from the greenhouse, a cooling block for dehumidifying the air supplied via the inlet opening, and a place after the cooling block. outside air inlet opening, and a fan placed after the outside air inlet opening for discharging air treated in the air treatment cabinet via an outlet opening, the outlet opening being connected to an air distribution duct, and a mixture of outside air and dehumidified air from the air greenhouse is brought to the crop via the air distribution channels. 5. Method as claimed in claim 4, wherein CO2 is supplied after the cooling block of the air treatment cabinet. 6. A method according to any one of the preceding claims, wherein under the first circumstances a maximum of 15, such as a maximum of 12 and more preferably a maximum of 10, such as a maximum of 7 m3 outside air per hour per m2 of greenhouse area is supplied. 7. Method as claimed in any of the foregoing claims, wherein at least 5, in particular at least 15 and preferably at least 30 m3 outside air per hour per m2 greenhouse area is supplied under the second circumstances. 8. Method as claimed in any of the foregoing claims, wherein under conditions where there is a heat shortage and the relative humidity is too high, mechanical cooling is dispensed with and instead of that outside air is supplied with a maximum of 25 m3 per hour per m2 of greenhouse area via an inlet opening of an air treatment cabinet, which inlet opening for outside air is located in front of a heat block, the outside air is heated by the heat block and supplied to the air distribution channel, and excess moisture is expelled by means of the air thus supplied. 9. Air treatment cabinet comprising a housing with an inlet for admitting air from a greenhouse, a first heat exchanger for cooling air supplied via the inlet, a second heat exchanger for heating air and a fan for passing through the inlet supplying air, and an outlet for discharging air supplied by the fan, wherein a closable second inlet opening for outside air is provided between the first heat exchanger and the fan. 35 The air treatment cabinet of claim 9, wherein the second inlet port is an adjustable controllable lockable second inlet port. 11. Air treatment cabinet, which comprises a housing with a first inlet opening for admitting air, a heat exchanger for cooling air supplied via the first inlet opening, and a fan for supplying air via the first inlet opening, and an outlet for discharging air supplied by the fan from the housing, wherein a closable second inlet opening for air is provided between the heat exchanger and the fan. 10 12. Air treatment cabinet as claimed in claim 11, which comprises a housing with a first inlet opening for dehumidified air, a heat exchanger for dehumidifying the air supplied via the first inlet opening, a second inlet opening provided after the heat exchanger for non-dehumidified air, and a fan disposed after the second inlet opening for discharging air treated in the air treatment cabinet via an outlet opening, and the air treatment cabinet furthermore has a passage opening provided with lamellae, the heat exchanger being at a first angle with the vertical, the passage opening below a second angle with the vertical, the slats are placed under the heat exchanger and above an outside air flow path located between the second supply opening and the fan, and the slats are provided with gutters for discharging air condensed during dehumidification 25 water that comes from the heat changer falls. An air treatment cabinet according to claim 11 or 12, wherein the troughs open onto a collection trough. The air treatment cabinet according to any of claims 11 to 13, wherein it comprises a second heat exchanger for heating air. 15. Air treatment cabinet according to claim 14, wherein the second heat exchanger is located after the second inlet opening. 4 The air treatment cabinet according to any of claims 11 to 15, wherein the second inlet port is an adjustable controllable lockable second inlet port. The air treatment cabinet according to any of claims 11 to 16, wherein the slats are controllable slats with which the flow through the first inlet opening can be controlled. 1032779