GR1008952B - Method for the cultivation of strawberry plants and greenhouse-grown vegetables planted in beds with elevated plantation surface-greenhouse for the achievement of said method - Google Patents

Abstract

Novelty: a method for the cultivation of strawberry plants and greenhouse-grown vegetables planted in beds with elevated plantation surface are disclosed herein. Technical features: the vegetables and strawberry plants are cultivated into longitudinal beds (1) the plantation surface of which is elevated by 50 cm at least from the level where the workers are supposed to circulate and configurated with a rigid framework (3) retaining the soil. Parallel longitudinal corridors (2) interpose between the beds to allow the circulation of the working staff during cultivation and collection of vegetables. A greenhouse into which the beds are manufactured with steady systems destined for the transport and circulation of the produce (e.g. trolleys, (4) or transport means hanging from a ceiling track system (5)). A steady air-flow control system (6) creating optimal climate inside the greenhouse is also provided. The framework of the greenhouse is composed of frames (7.1) able to overlap lengthwise the oneside (8) of the chamber, freeing the entire cultivated surface. Advantages: optimal plant cultivation and growth conditions, comfortable working conditions for the collection of the produce, significantreduction of the operational cost, improvement of the quality of the produce and control and traceability process to be applied to the produce from production to consumption stage.

Description

DESCRIPTION

"METHOD OF STRAWBERRY CULTIVATION AND GREENHOUSE GARDENING IN

BORDER WITH RAISED PLANTING SURFACE AND GREENHOUSE FOR

IMPLEMENTATION OF THE METHOD"

The invention refers to a "method of greenhouse strawberry and horticultural cultivation in flowerbeds with an elevated planting surface" which consists in the fact that the strawberry and horticultural plants are grown in longitudinal flowerbeds in a greenhouse, the planting surface of which is elevated by at least 50 cm from the movement level of the workers, with mechanical lateral containment of the soil, interspersed with parallel longitudinal corridors for the movement of personnel to carry out cultivation and collection operations. It also refers to a "greenhouse for carrying out the method", which is constructed with flower beds with a raised planting surface of more than 50cm and mechanical soil retention, with fixed systems for transporting and handling the products, and with fixed systems and arrangements for the creation of the best possible climate within the space.

Today, strawberry cultivation in greenhouses is mainly done on the ground in longitudinal rows with a slight shaping of the soil in the shape of a slope of small width and small height without mechanical retention of the soil and with intermediate parallel traffic corridors shaped in the form of grooves. The planting surface of the plants is close to the ground, with a slight elevation in relation to the level of the traffic corridors, resulting from the formation without mechanical restraint of the soil. There are also cases, on a limited scale, where mainly horticultural crops are cultivated in flower beds shaped in various dimensions with a slight elevation of the planting surface from the natural ground. The cultivation of strawberries and horticulture with the aforementioned methods is done in greenhouses that are made in various types, forms and dimensions. Especially for the cultivation of strawberries, simple greenhouses are constructed, with rough covering and ventilation arrangements, characterized by a relatively high height that allows the movement of large agricultural machinery, at the end of each growing season or alternatively they are dismantled and re-erected when the basic work is completed preparation for planting with the new

growing season. In addition to these methods, there is also the cultivation of strawberries, which is done "semi-outdoor" by locally covering the rows with plastic film, as an extended "small greenhouse" above each row, until the growth of the plants, which is then removed and recreated with the new growing season.

Some of the most important problems and disadvantages of the methods and ways applied to date for the cultivation of strawberry and greenhouse horticulture are the following:

The harvesting of the strawberry fruit is particularly laborious and tiring mainly due to the fact that the workers are obliged to constantly work bent over, making the work inefficient and excessively increasing the cost of the final product. These conditions are aggravated by the high temperatures inside the greenhouse. Particularly in the cultivation of strawberries, the aforementioned conditions, which require particular physical endurance, are the main cause of the significant difficulty in finding labor for cultivation and collection, with the result that personnel are employed without the possibility of elementary training, organization and control of the work, a fact that it increases costs, degrades quality and makes a complete and reliable end product traceability process impossible.

The shape of the traffic aisles makes it difficult and almost prohibitive to use permanent and modern crate transport systems, which are handled either by hand or by manual carts, also resulting in increased labor costs.

Plant growth takes place close to the ground where adequate drainage is impossible and in the soil we have a high percentage of moisture which favors the development of plant diseases. These conditions are aggravated by leaves and tips of the plant that rot due to moisture and accumulate on the cultivation surface or in the corridors-troughs. The result is reduced performance and degradation of product quality.

It is almost impossible to achieve optimal temperature and ventilation conditions, especially necessary for the growth and performance of strawberry plants, only with natural ventilation from side or frontally opening surfaces of the plastic coating of the greenhouses.

The invention aims to achieve the removal of the aforementioned problems and disadvantages.

The "strawberry and horticultural greenhouse method of cultivation in flower beds with raised planting surface" consists in that the strawberry and horticultural plants are grown in longitudinal flower beds in a greenhouse, which have a raised planting surface at a height of at least 50 cm from the level of movement of the workers. Along and parallel to the flower beds are inserted long corridors for the movement of personnel, of small width, for the execution of cultivation and collection operations. The width of the flower beds is configured so that the worker, moving along the corridor, can easily perform the cultivation tasks that are required to be done manually, such as mainly harvesting. The lateral retention of the soil of the flower beds is done by mechanical support, with frames resting on piles fixed in the ground, so that the lateral surfaces of the flower beds are flat and the cross-section of the corridors constant throughout their length. The work of preparing the soil for cultivation, such as milling, fertilizing, etc., is done by mechanical means with small agricultural machinery that can and does move at the level of the planting surface of the flower beds, while the work that requires manual labor, such as harvesting, is done with workers trafficked in the traffic corridors. For the handling and transport of the products during the harvest, fixed infrastructures are used, such as a handling system of trolleys suspended on light-type rails fixed to the frame of the roof of the greenhouse or light trolleys rolling on the top of the lateral soil retaining frames of the flower beds, the which has an appropriate configuration.

Another object of the invention for the implementation of the above method, is the construction of a greenhouse with flower beds whose planting surface is elevated at least by 50cm from the level of movement of the workers, between which are interposed narrow width circulation corridors. The width of the flower beds is proportionally shaped so that the worker, moving along the corridor, can easily perform the cultivation tasks that are required to be done manually. By mechanical means, the greenhouse space is shaped so that the ground is level throughout the area and the necessary amounts of soil are milled and moved to shape the level of the surface of the circulation corridors. The flower beds and circulation corridors are planned on this ground. In the designed positions, the retaining frames for the soil of the flower beds are made, at the desired height which is greater than 50 cm. The frames are made of rigid materials so that their surface is flat along the entire length. A metal construction of the frames is made with metal stakes fixed at regular intervals along the two side walls of the flower beds. A metal grid is attached to the inner part of the metal piles. The inside of the mesh is covered with a thin soil retention membrane, which folds over the top of the mesh and piles. The panels are reinforced together with buttresses and the frames of the two sides in each parterre, are fixed and assembled together at intervals with metal or wire retaining links. A full-length Π-shaped metal cross-section is attached to the upper part of the frame, ensuring the alignment of the grid and the soil retention membrane. The metal Π of the two opposite side surfaces of the flower beds, which are respectively also side surfaces of the traffic corridor, serve and also function as tracks on which a light trolley-wagon rolls with side wheels on which the crates with strawberries are placed and transported to the exit of the greenhouse, ready to be forwarded to the final inspection and packaging process in the packaging plant. At a suitable height, a system with rails of light cross-section, which are arranged along and in the center of the circulation corridors, is attached to the frame of the greenhouse roof. Light stretchers are hung on these rails, on which crates can also be placed to collect the products and transport them, as above, to the exit of the greenhouse. The suspension of the stretcher is done by a rolling device on the rails, so that its movement is done manually by simple pulling or pushing. A controlled air flow system (dynamic ventilation) is fitted to the front of the greenhouse to create an air current along the flower beds and at the desired height from the planting surface, which consists of one or more devices with an electric fan adapted and powered by photovoltaic elements (panel ), while on the opposite (rear) side, openings with fixed or movable ventilation louvres are fitted. The frame of the greenhouse consists of frames with an arched or gabled roof, supported on two uprights, which are repeated in the longitudinal dimension, creating the chamber of the greenhouse. One of the two uprights is fixed to a device that allows its rotation, while the second is fixed to a fixed base-socket with a detachable joint. Thus, when the base joint is loosened, the entire swivel frame can be moved and "folded" to the longitudinal side of the greenhouse on which the swivel uprights are arranged. In this way, when the plastic coating of the greenhouse and the longitudinal joints of the frames are removed, all the frames can be "folded" to one longitudinal side of the chamber, freeing the entire cultivated area. In cases of construction of a greenhouse with multiple arches (multiple arched greenhouse), by arranging the rotating uprights on the two outer sides for each pair of chambers, by folding the frames the single cultivated surface of these two chambers is free.

The invention, while achieving the removal of the aforementioned disadvantages, presents the following advantages.

Easier and more efficient collection work, due to the more favorable working conditions and the organized way of collecting and moving the products inside the greenhouse.

- Less required number of workers with a significant reduction in collection costs.

Ability to organize and standardize collection work, quality control and above all to implement an integrated product traceability process, with obvious results in improving the quality of the final product and reliable handling and distribution to the consumer public.

Ability to develop a trained workforce Ability to pay workers according to their quantitative and qualitative performance.

- Better conditions for plant growth on the elevated planting surface, where the appropriate percentage of moisture is achieved in the root system of the plants, there is no stagnant water and the leaves with the fruits are in a clean and ventilated environment, so that diseases do not develop.

- Ability to regulate the climate in each chamber of the greenhouse by achieving the best possible conditions of temperature and ventilation of the space, resulting in better plant growth and an increase in their yield.

When it is required to intervene for extensive work in a chamber using large-sized machines, it is easy to release the cultivated area by simply moving and folding the frames of the frame, on one side of the chamber.

The "strawberry and horticultural greenhouse cultivation method in flower beds with an elevated planting surface and the greenhouse for carrying out the method" described above, is illustrated in the drawings, and the brief description thereof constitutes an embodiment of the invention in the form of an example, without being a limitation of the where:

- Figure 1 shows a cross-section of one of its chambers

greenhouse

- Figure 2 shows a top view of a greenhouse chamber

- Figure 3 shows a section along one of its chambers

greenhouse

- Drawing 4 shows a detail of the construction of a flower bed

- Drawing 5 shows a detail of flower beds with a corridor and a product transport trolley

- Figure 6 shows a pair of chambers with an indicative folding of the frames of the frame.

- Figure 7 shows a detail of the seating arrangement and

rotation of one arched frame upright - Figure 8 shows a detail of the fixed base-socket with a detachable joint of the second arched frame upright.

The "method of growing strawberry and horticultural vegetables in a raised bed and the greenhouse for carrying out the method" as described above and illustrated in drawings 1 to 8, consists in the strawberry and horticultural plants being grown in longitudinal beds ( 1) inside a greenhouse, whose planting surface (1.1) is raised at least by 50 cm from the level (2.1) of movement of the workers, with mechanical lateral retention of the soil. Along and parallel to the flower beds (1) are inserted longitudinal corridors (2) for the movement of personnel, of small width, for the execution of cultivation and collection operations. The lateral retention of the soil of the flower beds (1) is done by mechanical support, with frames (3) resting on piles (3.1) fixed in the ground, so that the lateral surfaces of the flower beds (1) are flat and the cross-section of the walkways constant along their entire length. For the handling and transportation of the products during the harvest, fixed infrastructures are used, such as a handling system of stretchers (5.1) suspended on light-type rails (5) fixed to the frame of the roof of the greenhouse and light stretchers (4) rolling on the upper part ( 3.6) of the lateral frames (3) holding the soil of the flower beds (1), which has a suitable configuration.

The "greenhouse for carrying out the method" is constructed with flower beds (1) whose planting surface (1.1) is elevated at least by 50cm from the level (2.1) of movement of the workers. Between the flower beds (1) are interposed circulation corridors (2) of small width. The width of the flower beds is proportionally shaped so that the worker, moving along the corridor (2), can easily carry out the cultivation operations that are required to be done manually. By mechanical means, the greenhouse area is shaped so that the ground is level throughout the area and the necessary amounts of soil are milled and moved to shape the level (2.1) of the surface of the circulation corridors (2). The flower beds (1) and the traffic corridors (2) are designed on this ground. In the designed positions, the frames (3) are made to hold the soil of the flower beds (1), at the desired height which is greater than 50 cm. The frames (3) are made of rigid materials so that their surface is flat along the entire length. A metal construction of the frames (3) is made with metal stakes (3.1) fixed at regular intervals along the two side walls of the flower beds (1). A metal grid (3.2) is attached to the inner part of the metal piles (3.1). The inside of the mesh (3.2) is covered by a thin soil retention membrane (3.3), which is folded over the top of the mesh (3.2) and the stakes (3.1). The stakes (3.1) are reinforced with each other with countersunks (3.4) and the frames (3) of the two sides on each parterre (1), are fixed and assembled with each other at intervals with metal or wire retaining links (3.5). On the upper part of the frame (1) a metal cross-section in the form of Π (3.6) is attached along the entire length, ensuring the alignment of the mesh (3.2) and the soil retention membrane (3.3). The metal Π (3.6) of the two opposite side surfaces of the flower beds (1), which are also side surfaces of the traffic corridor (2), serve and also function as tracks on which a light trolley (4) rolls with side wheels on the which the crates with the strawberries (4.1) are placed and transported to the exit of the greenhouse, ready to be forwarded to the final inspection and packaging process in the packing plant. At a suitable height, a system with rails (5) of light cross-section, which are arranged along and in the center of the circulation corridors (2), is attached to the frame of the greenhouse roof. A light stretcher (5.1) is suspended on these rails, on which crates can also be placed to collect the products and transport them, as above, to the exit of the greenhouse. The carriage (5.1) is suspended by a rolling device on the rails (5), so that it can be moved manually by simple pulling or pushing. A controlled air flow system (6) is fitted to the front of the greenhouse chambers, which consists of an electric fan (6.1) adapted and powered by photovoltaic elements (panel) (6.2), while vents (6.3) are fitted to the opposite (back) side of the chamber. with fixed or movable ventilation louvres. The frame (7) of the greenhouse consists of frames (7.1) with an arc-shaped or aphiricte roof, supported by two uprights (7.2), which are repeated in the longitudinal dimension, creating the chamber of the greenhouse. One of the two uprights (7.2) is fixed to a device consisting of a compacted tube (7.3) into which the lower end of the upright (7.2) is fitted so that it can rotate. The second upright (7.2) is fixed to a fixed base-socket (7.4) with a detachable joint (7.5). Thus, when the joint (7.5) of the base (7.4) is loosened, the entire rotating frame (7.1) can be moved and "folded" to the longitudinal side (8) of the greenhouse on which the rotating uprights (7.3) are arranged. In this way, when the plastic coating of the greenhouse and the longitudinal joints of the frames (7.1) are removed, all the frames (7.1) can be "folded" to one longitudinal side (8) of the chamber, freeing the entire cultivated area. In the cases of building a greenhouse with multiple arches (multiple arched greenhouse), by arranging the rotating uprights (7.3) on the two outer sides (8.1) and (8.2) for each pair of chambers, by folding the frames (7.1) the single cultivated surface is free of these two chambers.

Next, a way of realizing the invention is described: By mechanical means, the greenhouse space is shaped so that the ground is level throughout the area and the necessary amounts of soil are milled and moved to shape the level (2.1) of the surface of the circulation corridors . The flower beds (1) and the traffic corridors (2) are designed on this ground. In the designed positions, the frames (3) holding the soil of the flower beds are made, at the desired height which is greater than 50 cm and the flower beds (1) are filled with soil. At the same time, the support bases (7.3) and (7.4) of the frames (3) of the frame are manufactured. After the construction of the flower beds and bases, the frame of the chamber with the covering is set up and the rails (5) for hanging the stretchers (5.1), the dynamic ventilation system (6.1), (6.2), (6.3) are adjusted.

On the planting surface (1.1) the plants are cultivated with agricultural tools and small-sized machines, and all the necessary water supply systems are installed, etc. To carry out the manual work on the planting surface (1.1), the workers move along the corridors (2) . For the strawberry harvesting operations, the worker moving along the corridor (2) works standing up, collects the ripe strawberries and places them directly in the crate (4.1) which he has already placed on the trolley-wagon (4) or on the suspended trolley (5.1 ). Each crate (4.1) is labeled with a characteristic "traceability" code that uniquely corresponds to the chamber from which the product was collected, the date of collection, the worker who collected the product and the owner. Thus, the possibility of full application of the traceability process from the point of production of the product is achieved. The carriage (4) moves with a simple push rolling on the upper part (3.5) of the frames (3) of the flower beds (1). As soon as the collection of the products in an aisle is completed, the full crates are transported with the trolley (4) to the exit of the chamber for the packing room. Similarly, the suspended stretchers (5.1) are moved by simply pulling or pushing the system with the rails (5). Throughout the period of plant growth and product collection, and especially during the hours of sunshine when high temperatures develop in the room, the electric fan (6.1) operates automatically and at no cost, powered by the photovoltaic cells (6.2). , so that in combination with the blinds (6.3) an air flow is created parallel to the longitudinal arrangement of the flower beds (1) and at the appropriate height from the planting surface (1.1). In this way, through the ventilation, a continuous regulation of the temperature on the planting surface is achieved in order to create the optimal climate for the growth of the plants and at the same time comfortable conditions for the workers in the corridors (2) of the chamber.

At the end of the growing season, soil preparation work for the new season is carried out, such as milling the cultivation surface (1.1) of the flower beds with a tiller and a small tractor, which can be moved to the upper part (1.1) of the flower beds (1) . For larger-scale operations required on an emergency or regular basis after three or four growing seasons, the plastic cover of the chamber is removed and the frames (7.1) are folded to one side (8.1) of the chamber, pivoting on the base (7.3) of the upright (7.2). , after first disconnecting the connector (7.5) of the fixed base (7.4).

In the above way, a stable infrastructure is achieved that ensures the best conditions for cultivation, collection and distribution of the products to the consumer public.

Claims (12)

CLAIMS "METHOD OF GROWING STRAWBERRIES AND GREENHOUSE HORTICULTURE IN A BORDER WITH A RAISED PLANTING SURFACE AND A GREENHOUSE FOR CARRYING OUT THE METHOD" 1. "Strawberry and horticultural greenhouse cultivation method in flower beds with raised planting surface" characterized by the fact that the strawberry and horticultural plants are grown in longitudinal flower beds (1) inside a greenhouse, the planting surface (1.1) of which is elevated by at least 50 cm from the level (2.1) of movement of the workers. 2. "Strawberry and horticultural greenhouse cultivation method in flower beds with a raised planting surface", according to claim 1, characterized by the fact that between the flower beds are interposed parallel longitudinal corridors (2) of small width for the movement of personnel to carry out manual cultivation operations and collection. 3. "Strawberry and horticultural greenhouse cultivation method in flower beds with a raised planting surface", according to claims 1 and 2, characterized in that the lateral retention of the soil of the flower beds is done mechanically, with rigid frames (3) throughout their length. 4. "Strawberry and horticultural greenhouse cultivation method in flower beds with raised planting surface", according to claims 1, 2 and 3, characterized by the fact that for the handling and transport of the products inside the greenhouse during harvesting, fixed infrastructures are used which include system of suspended carriages (5.1) on fixed rails (5) fixed to the roof of the frame (7) and light carriages (4) rolling on the upper part (3.6) of the side frames (3) holding the soil of the flower beds (1). 5. Greenhouse for carrying out the method of claim 1, with a frame (7) formed by frames (7.1) with an arc-shaped or pitched roof, which rests on two uprights (7.2), characterized by the fact that longitudinal flower beds (1) for the cultivation of strawberries and horticulture, with a raised planting surface of at least 50 cm from the level (2.1) of movement of the workers, and whose lateral retention of the soil is done by rigid frames (3) fixed to the ground with stakes ( 3.1). 6. Greenhouse for carrying out the method of claim 1, according to claim 5, characterized by the fact that between the flower beds (1) are interposed parallel traffic corridors (2) of small width. 7. Greenhouse for carrying out the method of claim 1, according to claim 5 and 6, characterized in that the construction of the rigid frames (3) for the lateral retention of the soil of the flower beds (1) is made with metal stakes (3.1) fixed to the ground at regular intervals along the two sides of the flower bed (1). In the inner part of the piles (3.1) a metal mesh (3.2) is fixed, which on the inner side is covered with a thin plastic film (3.3), the upper edge of which folds over the outer side of the mesh (3.2) and the piles (3.1). At the top of the piles (3.1) is attached a metal plate in the form of Π (3.6), aligned along the entire length of the frame. The stakes (3.1) of each frame (3) are reinforced with metal counters (3.4) and the side frames of each flower bed are tied at intervals with metal links (3.5). 8. Greenhouse for carrying out the method of claim 1, according to claim 5, 6 and 7, characterized in that it has carriages (4) rolling on the upper part of the flat metal surface (3.6) of the side frames (3) of the flower beds (1) , for moving the products (4.1) inside the greenhouse. 9. Greenhouse for carrying out the method of claim 1, according to claim 5, 6, 7 and 8, characterized in that it has a system with rails (5) fitted to the frame (7) above the walkways (2) and suspended stretchers (5.1) for moving products, at the height of the planting surface (1.1). 10. Greenhouse for carrying out the method of claim 1, according to claim 5, 6, 7, 8 and 9, characterized by having a ventilation system (6) of controlled air flow parallel to the longitudinal arrangement of the flower beds (1) , which consists of an electric fan (6.1) powered by photovoltaic elements (panel) (6.2) adjusted to the front of the chamber at a suitable height from the planting surface (1.1) and ventilation openings (6.3) with fixed or movable blinds adjusted to the same height on the back of the chamber. 11. Greenhouse for carrying out the method of claim 1, according to claim 5, 6, 7, 8, 9 and 10, characterized in that the uprights (7.2) located along the outer side of the flower bed (1) in one side (8.1) or (8.2) of the chamber, are fixed to a device consisting of a compacted tube (7.3) into which the lower end of the upright (7.2) is fitted so that it can rotate while the respective uprights (7.2) of on the opposite side of the chamber are fixed to a fixed base-socket (7.4) with a detachable connector (7.5). 12. Greenhouse for carrying out the method of claim 1, according to claim 5, 6, 7, 8, 9, 10 and 11, characterized in that it is manufactured in any size and shape required, with one or more chambers so that without restrictions to have any number of shape and dimensions of flower beds (1 ).