This application claims priority to Netherlands Patent Application No. 2020176, filed Dec. 22, 2017, which is incorporated by reference in its entirety.
The invention is directed to a greenhouse comprised of transparent walls and a structure comprising of one or more ridge beams as part of a roof of the greenhouse. The invention is also directed to a novel ridge beam. The invention is also directed to a method to condition the air within a greenhouse.
DE8426219 describes a building with a ventilating ridge beam. The beam construction is provide with two elongated flaps which can simultaneously open and close thereby providing a ventilation opening.
DE1454648 describes a greenhouse provided with a window near the ridge beam allowing air to escape the greenhouse.
Such a greenhouse is described in WO17176114. In FIGS. 1 and 2 a schematic representation of a greenhouse with a saddle roof is shown. In the roof ventilating windows are present to discharge excess air from the interior of the greenhouse to the exterior of the greenhouse. Such ventilating windows are typically present in every saddle roof at a regular interval. A disadvantage of such ventilating windows is that the frames and controls to operate the window take away light and thus negatively affect the efficiency of the greenhouse to grow plants. Furthermore, local pressure differences and temperature differences may result from the internal gas flows towards these windows.
The object of the present invention is to provide a greenhouse which has a higher efficiency of the available sun light and avoids the local pressure differences and temperature differences.
This is achieved by the following greenhouse. Greenhouse comprised of transparent walls and a structure comprising of one or more ridge beams as part of a roof of the greenhouse, wherein the ridge beam extends some distance above the roof defining two elongated side zones present above the roof and at either side of the ridge beam, wherein the ridge beam is comprised of one or more elongated hollow spaces, wherein the ridge beam is provided with one or more closable openings in both side zones which openings fluidly connect the exterior of the greenhouse with the one or more elongated hollow spaces of the ridge beam, and wherein the ridge beam is provided with one or more openings at its lower end fluidly connecting the interior of the greenhouse with the one or more elongated hollow spaces of the ridge beam.
The greenhouse according to the invention will have less light blocking parts near the roof of the greenhouse than the prior art greenhouse. Furthermore, a more even discharge of air from within the greenhouse to its exterior via the roof is possible. This will decrease the local pressure and temperature differences within the greenhouse. Further advantages will be discussed when describing the preferred embodiments of the invention.
The ridge beam may suitable be provided with an elongated valve to direct air from within the greenhouse to one side of the ridge beam. This is advantageous because the operator or computer operating the greenhouse can open de openings in the ridge beam at the leeward side or windward side in case a wind is blowing over the greenhouse. Openings at the leeward side is preferred when air is to be discharged from the greenhouse to its exterior and openings at the windward side is preferred when air is to enter the greenhouse from its exterior. Preferably the openings in the ridge beam are used to discharge air from the greenhouse to its exterior. In a prior art greenhouse the ventilating windows are typically positioned at the leeward side of a roof for the locally most predominant wind direction. The greenhouse according to this invention enables one to discharge air via a leeward opening independent of the wind direction. In a prior art greenhouse the ventilating windows would have to be shut when the wind blow from the wrong direction at a certain high wind speed. By wrong direction is here for example meant that the wind blows into the openings of the ventilating windows. This mandatory closing of the windows is not preferred because it limits the possibilities for conditioning the air within the greenhouse. In the greenhouse having the ridge beam as here described such safety shutting of the ventilation openings is not required because one can always use the openings in the ridge beam at its leeward side.
The valve has at least a first position wherein the one or more openings in a first elongated side zone fluidly connect the exterior of the greenhouse with the one or more elongated hollow spaces of the ridge beam and wherein the one or more openings in the opposite and second elongated side zone are closed, a second position wherein the one or more openings in the second elongated side zone fluidly connect the exterior of the greenhouse with the one or more elongated hollow spaces of the ridge beam and wherein the one or more openings in the first elongated side zone are closed. By closed is here also meant substantially closed. There may be gas passages from the hollow space of the ridge beam to the closed openings as illustrated in
Preferably the valve has a third position which results in that the interior of the greenhouse is not fluidly connected to the exterior of the greenhouse via the openings of the ridge beam. This may be by enclosing the openings in the two elongated side zones and/or by enclosing the one or more openings at its lower end of the ridge beam. Preferably the valve has intermediate positions wherein the size of the one or more opening in one of the two elongated side zones and/or the size of the opening at the lower end of the ridge beam can be varied while the one or more openings of the other elongated side zone are closed. This is advantageous because one can then fully close the greenhouse and control the volume of air being discharged from the interior of the greenhouse to its exterior.
The valve may be one or more screens which can move in the elongated direction of the ridge beam and close or open the openings at either of the elongated size zones depending on its position relative to the two elongated zones. For example the openings in the two elongated zones may be openings in an upwardly extending wall which is covered by an elongated and moveable top having at either elongated side a downwardly directed screen also provided with openings. The screen may run within the two upwardly extending walls or preferably outside the two upwardly extending walls. The openings in the screen may or may not align with the openings in the upwardly extending walls depending on the position of the moveable top. The openings may be alternatingly positioned in the two screens when viewed along the length of the screens or alternatingly positioned in the upwardly extending walls when viewed along the length of the walls. The top may be moved by well known techniques.
Instead of the top with screens the longitudinal moveable valve may also be a tube placed within a hollow space of the ridge beam having a tubular shape. The tubular valve is then co-axially moveable within this tubular hollow space.
The valve preferably changes from one position to another position by rotation along an axis running parallel with the ridge beam. The valve may also rotate along more than one axis running parallel with the ridge beam. The valve is suitably connected to a means to rotate the valve in case the valve changes position by rotation along one axis. Such a means may be a tubular motor. The valve is suitable rotatably connected to a motor positioned below the ridge beam via a transmission, for example a bevel gear. Although this motor may block some light it is not as much as would be by the prior art means to open and close the ventilating windows. The valve is suitably connected to a means to tilt the valve in case the valve changes position by rotation along more than one parallel axis.
The valve may have any design which makes it suitable to achieve one or more of the above described positions. In one preferred design the hollow space of the ridge beam has a tubular shape and wherein the valve is rotatably positioned within this tubular hollow space. Suitably this valve is a tube provided with two parallel rows of openings. The tube further has an elongated surface separating the inner tubular space of the valve into an elongated space fluidly connected to the two rows of openings and a remaining space. This remaining is suitably an elongated enclosed space defined by the elongated surface and part of the tubular wall. In order to avoid that the tube-shaped valve gets jammed within the tubular hollow space sliding surfaces are preferably provided. Such surfaces may be part of the stationary ridge beam or part of the rotating valve. Such surfaces may for example be made of messing, Teflon or engineering plastics such as polyamide, for example Nylon. The ridge beam and the tubular shaped valve may be made of aluminium, steel or alloys comprising these metals.
In another preferred embodiment the valve is an elongated rotating cap valve as here described. The upper end part of the ridge beam is an elongated cap valve which can rotate along an axis running parallel with the ridge beam and which axis runs within the hollow space of the ridge beam. The cap valve is shaped such that in a first rotatable position one or more openings in the first elongated side zone are present which fluidly connect the exterior of the greenhouse with the elongated hollow space of the ridge beam and wherein the second elongated side zone is closed by the cap valve and in a second rotatable position one or more openings in the second elongated side zone are present which fluidly connect the exterior of the greenhouse with the elongated hollow space of the ridge beam and wherein the first elongated side zone is closed by the cap valve.
In another preferred embodiment the valve is comprised of a first wall part as one elongated side zone and a second wall part as the opposite elongated side zone, wherein the wall parts are rotatably connected to the fixed part of the ridge beam at their lower ends. The wall parts are further both rotatably connected to an elongated bridging part at their upper ends. The axis of rotation of all four rotatable connections run parallel with the elongated ridge beam. This structure enables that the bridging part can tilt in different positions, wherein in at least one position the bridging part closed the openings in one wall part and provides a fluid connection between the exterior of the greenhouse and the hollow spaces via the openings of the other wall part, and wherein in at least another position the bridging part closes the openings of first and second wall part.
The area of openings in the ridge beam per axial length of the ridge beam is preferably between 0.01 and 0.1 m2/m and more preferably between 0.01 and 0.04 m2/m. The ridge beam is suitably not a wide construction. The external width is preferably below 0.11 m. such to avoid that the ridge beam itself blocks too much sunlight. The openings are here defined as the maximum allowable opening. Thus expressly not the sum of open and closed openings.
The ridge beam running along the length of the roof of a greenhouse may be provided in sections, wherein each section is provided with a valve which can be independently operated from the remaining valves. This allows one to vary the volume of air which is discharged along the length of the ridge beam.
The roof of the greenhouse may have the shape of a number of parallel oriented saddle roofs each provided with the ridge beam. Such a greenhouse may have any type of transparent walls, suitably glass or polycarbonate. Such transparent walls are suitably fixed in a frame work. The ridge beam is suitably part of such a frame work providing the structure of the greenhouse itself. The greenhouse may also be of the tunnel type and wherein the transparent walls are transparent polymer sheets. At the upper end of the tunnel the ridge beam is provided running in the same direction as the elongated tunnel. More than one tunnel may be positioned in parallel forming one space.
The greenhouse is suitably a so-called semi-closed greenhouse. Such a greenhouse is suitably provided with means to take in air from the exterior of the greenhouse, an air conditioning mixing zone suited to mix air from the exterior of the greenhouse with air from within the greenhouse and means to distribute air from the air conditioning zone to the interior of the greenhouse via a multitude of ventilation ducts fluidly connected to the air conditioning mixing zone.
Such a greenhouse will be typically operated with a small over pressure resulting in that the flow direction in the openings of the ridge beam will be from the interior to the exterior of the greenhouse. This avoids that insects can enter the greenhouse and may avoid additional measures such as netting and the like. The pressure within the greenhouse may be between 0 and 100 Pa higher and preferably between 10 and 20 Pa higher than the pressure exterior of the greenhouse.
The greenhouse may be operated by only recirculating air from within the greenhouse to the air conditioning zone and back to the interior of the greenhouse. In this mode no external air is let in and the openings in the ridge beam may suitably be closed or only opened if the pressure within the greenhouse has to be decreased. In another mode of operation air from the exterior of the greenhouse is let into the air conditioning zone only and discharged via the openings in the ridge beam. No recirculation of the air from within the greenhouse via the air conditioning zone takes place. This mode may be omitted because it has been found that a minimal recirculation is favourable. In the third and most used mode of operation air from the exterior of the greenhouse is mixed with air from within the greenhouse in the air conditioning zone and fed to the interior of the greenhouse via the ventilation ducts. The net excess air entering the greenhouse will be discharged via the openings in the ridged beam in order to avoid that the pressure within the greenhouse exceeds its safe limits. Optionally additional openings may be present to discharge the excess air.
The ventilating ducts may be any device which provides a substantially even distribution of the air into the greenhouse. Preferably the air is discharged from these ducts in the greenhouse at a position below the cultivation. Examples of such ventilating conduits are for example described in EP1464219, WO0076296, NL1038219 and in US2010/0126062.
The air conditioning zone is suitably provided with means to cool, heat, humidify or dehumidify the air before it is distributed into the greenhouse. Such means are well known and for example described in WO2004032606, WO0076296, WO2015/012698 and WO2008002686.
The invention is also directed to the ridge beam as described above and further illustrated in the Figures.
The invention is also directed to a process to condition the air within a greenhouse comprising of transparent walls and a structure comprising of one or more ridge beams as part of a roof of the greenhouse by maintaining a pressure difference between the average pressure within the greenhouse and the pressure exterior to the greenhouse, taking in air from the exterior of the greenhouse and mixing this air with air taken from the interior of the greenhouse to obtain conditioned air, distributing the conditioned air via a forced flow to the interior of the greenhouse, and discharging a volume of air from the interior of the greenhouse via openings present in the one or more ridge beams such to maintain the pressure difference.
The area of openings in the ridge beam per axial length of the ridge beam is preferably between 0.01 and 0.1 m2/m and more preferably between 0.01 and 0.04 m2/m.
The discharge of air via the openings of the ridge beam is suitably controlled such that the pressure within the greenhouse is between 0 and 100 Pa higher and preferably between 10 and 20 Pa higher than the pressure exterior of the greenhouse.
Preferably the volume of air discharged via the openings in the ridge beam is performed via openings at the leeward side of the ridge beam in a situation that a flow of external air flows over the ridge beam under an angle thereby defining a leeward and windward side of the ridge beam. This is advantageous for the reasons earlier discussed.
Preferably the discharge of air via the openings in the ridge beam is performed via openings which direct the air in a side ways direction relative to the ridge beam. For this process a rotatable valve rotating over an axis parallel to the ridge beam is used to either direct the majority of the air to one side or to the other side. More preferably the process is performed in the greenhouse according to the invention.
The invention will be illustrated by means of the following non-limiting Figures.
In this figure the opening 9 at side zone 7 aligns with opening 22a of valve 18 and fluidly connects the exterior 10 of the greenhouse 1 with the elongated hollow space 8 of the ridge beam 4. An opening 11 at the lower end 12 of the ridge beam 4 aligns with opening 22b of valve 18 and fluidly connects the interior 13 of the greenhouse 1 with the elongated hollow space 8. By consequence the interior 13 of the greenhouse 1 is fluidly connected via opening 9 at side 7 with the exterior 10 of the greenhouse 1. By rotating valve 18 clock wise the size of opening 9 at side 7 and the size of opening 11 shall become smaller. In this manner it is possible to vary the flow of air leaving the greenhouse 1 and to control the pressure difference between the interior 13 and the exterior 10 of the greenhouse. By rotating the valve 18 even further opening 9 at side 7 may be fully closed and opening 9 at side 6 will align with opening 22b of valve 18 and opening 11 will align with opening 22a. In this position the interior 13 of the greenhouse 1 is fluidly connected via opening 9 at side 6 with the exterior 10 of the greenhouse 1. This illustrates that the ridge beam having a valve 18 is able to open at either side of the ridge beam and close at its opposite side. The ridge beam 4 having a valve 18 shall be further illustrated in
Hinges 52,53,54,55 enable that the bridging part can tilt in different positions and at least from the positions shown in
The ridge beam as illustrated in
Number | Date | Country | Kind |
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2020176 | Dec 2017 | NL | national |
This application is a national stage entry of International Patent Application No. PCT/NL2018/050876, filed Dec. 21, 2018, which is incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 16955918 | Jun 2020 | US |
Child | 18107061 | US |