Nowadays, growing apples and pears presents farmers with new challenges due to adverse and unpredictable weather conditions, new pests that alter fruit quality, and increasingly competitive market conditions.
In such a scenario, it is important to set up the orchard in the best possible way to obtain an abundant, high-quality harvest and protect it from all environmental threats, ensuring that farmers receive fair remuneration for their work.
When you choose Valente, you find a partner whose experience, professionalism, and top-quality products enable you to achieve your goals.
To improve the yield of our customers' crops and protect them from weather and environmental threats, every type of complete Valente system can be equipped with various covering systems, which can also be combined with each other, called ValenteProtect© .
For example, the Valente system can be equipped with a combination of polyethylene film, polyethylene film with a UV filter, and polyethylene film with a UV filter and UV protection.
These are MULTIFUNCTIONAL covers, capable of performing several functions at the same time, but each with its own distinctive feature that makes it particularly effective and therefore suitable for special areas of use.
Hail is one of the most serious threats to the cultivation of apples and pears, particularly during the fruit growth and ripening stages.
Designed to effectively counter hail damage, the ValenteProtect© Hail system consists of a tensile structure made of pre-stressed reinforced concrete poles connected by steel wires and ropes, tensioned by special ground anchors..
Anti-hail netting is installed on this structure to fully cover orchard rows, protecting them and withstanding even severe weather.
The ValenteProtect© Hail system offers multiple benefits:
protects crops from hail damage
reduces direct solar radiation
mitigates wind intensity, protecting crops and structures
limits the entry of harmful insects into protected areas
This system uses protective anti-hail netting designed to shield orchards from severe weather.
The nets are fixed to the ridge wire using plates positioned in the center along the central selvedge which, in addition to having the function of stabilizing the system, serves to support the net and the weight of the deposited hail.
Used to cover very tall plants (up to 5 meters) with large volumes.
While the above system remains the standard for hail protection, increasingly intense weather events due to climate change are challenging the safety and durability of such structures.
Wind is a critical variable for netting systems, and absorbing strong stress without compromising structural integrity is a top priority for producers and installers.
At Valente, we continuously seek new design and production methods to address these challenges, aiming to improve system safety and ease the work of installers and farmers.
This led to the development of the KONNET system, which redesigns key aspects of the current standard.
Let’s start from the idea that this system is structurally identical to the classic anti-hail system, but with a new installation method for the anti-hail net. In this new method, the nets will no longer be very wide and installed “across” the ridge wire, but will consist of two half-sheets installed one on the right and one on the left of the row, which will always be installed using plates on the ridge wire and plates in the centre of the row.
In practice, the nets are laid out on the ground and then lifted with one of the two selvedges along the ridge line. Subsequently, using specific Valente plates, the net is fixed along the ridge line. Each row will therefore have a right-hand net and a left-hand net that overlap along the ridge line, closing any possible gaps and preventing hail from passing through. The ridge plates will no longer be 1.5 meters apart as in the previous system, but will be spaced 50 cm apart.
This new installation method, which has already been extensively tested in the field, offers numerous advantages:
Insects are one of the main threats to apple and pear cultivation, both because of the direct damage they cause to fruit and vegetation, and because of their role in transmitting diseases, which can seriously compromise the yield, quality, and marketability of the crop.
The ValenteProtect© Insect system was designed with the aim of effectively combating this problem and represents an addition to the superior coverage systems offered by Valente.
It involves the addition of perimeter insect nets, both front and side, which allow the system to be completely closed. In this way, in addition to the protection from above provided by the hail or shade cover, effective defense against insects is also achieved on the sides, ensuring total protection for crops.
The Monobloc system can be applied to all systems with Valente covers. It involves closing off the entire perimeter of the plot, including the headlands, using a specific insect net or the same net used for the top cover. This allows vehicles to transit within the plot and turns the system into a closed and efficient structure, capable of protecting crops from both insects and adverse weather conditions.
Access to the site is guaranteed by special doors, which are closed again once the vehicles have passed through to prevent unwanted insects from entering.
There are various types of closures that involve stretching an insect net from the top of the poles and laying it directly on the anchor ropes.
In the case of the simple front closure, it is fixed at the bottom to the anchors using plates and can be opened and closed at any time. Simple and very affordable, the closure is operated manually and one or two rows can be opened at a time. In the case of the Roller Tube, however, the lower net is rolled up on a transverse tube that serves as a roller for the net itself during the opening and closing phases.
Movement is ensured by a crank handle which rotates the tube and therefore the net attached to it and it is provided by a power multiplier mechanism operated by an electric screwdriver. This solution can open up to eighty meters of net in a single operation.
Unlike the Monobloc solution, the Single-row cover cannot be applied to orchard cover systems, as it can only be installed as their alternative.
This covering system involves the complete sealing of each individual row, offering the best guarantees of protection against small and medium-sized insects, while ensuring that the plant has adequate space for plant growth by means of a system of elastic spacers that keep the net stretched over the top of the plants.
The single-row system is designed to minimize damage caused by insects, particularly the codling moth and the Asian bug. This solution also acts as hail protection, offering additional protection to crops against extreme weather events.
The ValenteProtect© Sun system is designed to protect orchards and plants from the dangers of excessive solar radiation.
The structure is made of pre-stressed reinforced concrete poles, placed at a maximum height of 5 metres above ground and at a maximum distance of 8 metres between them.
The maximum recommended distance between rows is 5 metres.
The structure is connected longitudinally and transversally with steel wires and ropes firmly anchored along the perimeter to ensure stability and safety.
The shade net is sized so that the space between the net and the ground does not exceed the width of the rows, ensuring complete and effective sunlight coverage.
One of the most interesting applications of the system is its use for Melannurca Campana PGI, a unique variety of apple in the Italian fruit and vegetable sector, known for its ripening process called “reddening”.
Apples are harvested unripe and placed on straw beds, covered with shade netting for about 15 days to protect the fruit from sunburn while allowing the light necessary for reddening to pass through.
The material used to make the net is high-density polyethylene (HDPE), a plastic known for its high mechanical strength, durability and good chemical stability.
The thread that makes up the net is produced by extrusion, a process during which the polyethylene is melted and passed through perforated grids (extruders), thus obtaining threads of the desired section. After extrusion, the thread undergoes a thermostabilisation treatment, i.e. it is heated to reduce all shrinkage (dimensional contraction) that normally occurs in plastic material exposed to even modest sources of heat.
The shade net is then made by processing the monofilament using a special technique called flat weaving. In this process, the monofilament is woven according to an orderly pattern of weft and warp, obtaining a mesh (depending on the desired degree of shading) that is non-deformable, i.e. stable even when subjected to the loads of hail or wind.
The permeability of shade nets varies from 30% to 90%, and the choice should be made based on the final desired outcome.
Now let's talk about the colour of the net.
The polyethylene used to make the net has always been black, thanks to the carbon black additive that is added during the extrusion of the monofilament. This material remains the best choice today, as it combines the benefits of coverage with excellent durability over time, thus keeping costs down.
Its lifespan varies from 10 to over 20 years in ideal conditions.
The average shading of black netting is 15%, and it is suitable for all types of fruit.
Two alternative options are white netting and black + white netting, ideal for fruit with particular ripening and colouring difficulties:
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This system was developed almost fifteen years ago by a group of Dutch farmers with the aim of streamlining a series of agricultural procedures, particularly with a view to reducing labour costs.
At that time, a Dutch company had just developed a specific machine that, by means of two arms wide enough to span two rows of trees, could spray the necessary treatments on three rows at the same time, saving about a third of the time required to perform a very frequent operation, carried out several times a year.
The idea was implemented fairly quickly, greatly benefiting the farmers who used it; however, it was necessary to adapt traditional anti-hail systems by making some substantial changes.
There was a need to create a system that had two low rows and, at the same time, one that was high enough to support the net, so that the enormous machine could do its job without getting tangled up in it.
Many issues had to be addressed: the considerable width of the rows (at least nine metres) and the consequent lowering of the net with the resulting height of the posts, just to mention the most relevant and difficult to solve, without obviously considering the stability and safety of the entire system.
The final result is essentially that of creating two systems in one.
The tall structure supporting the net is made of poles with a distance between rows of up to nine metres and three metres along the row, thus ensuring the strength and robustness of a system that must be five metres above the ground. The net does not increase in width as usual, so it sags less and lies on top of the entire upper framework, thus avoiding entanglement. However, this requires a few “tricks” to prevent it from literally blowing away or accidentally opening.
Low rows are essentially those of a normal uncovered orchard, with rows installed at the standard distance of three metres.
The idea, revolutionary in the Netherlands, was then exported to other countries, particularly New Zealand.
In Italy, the 3-row concept is usually applied with the idea of an inverted anti-hail system: a system with a distance of nine metres between rows and a distance of three metres along the rows, without the short rows in the centre. This may be the best solution for covering vegetables or nurseries, also meeting the need for large machinery to pass through while ensuring crop safety.
We started over 60 years ago with the production of CAP poles, gradually growing to become one of the few manufacturers on the market able to provide customers with a turnkey system that fully meets their agronomic and business needs.
At Valente, we have a motto: “There is no innovation without tradition.” Since our foundation, we have always followed a dual path, consolidating and perfecting what worked while researching new solutions that would bring real improvements to fruit growing. No leaps into the unknown, but a policy of step-by-step progress that has allowed us to stay ahead without compromising on quality, guaranteeing our customers top-of-the-range products.
In the last year alone, we have created over 2,000 hectares of orchards in Italy and around the world, 80% of which are covered.
Customers rely on us, thus increasing their demand for turnkey solutions, from design to complete system installation. Therefore, even when weather conditions are not ideal, our clients can rest easy.
It is every farmer's dream: to create an orchard with the highest quality standards on the market and guaranteed against all adverse weather conditions. Is this possible? Of course, just combine the Valente system with the Sikuro warranty.
Any damage caused by hail, strong winds, hurricanes, storms, tornadoes, lightning, and snow is covered by the warranty.
Top-quality materials, professional installation, and comprehensive warranty against all adverse conditions: what else could one ask for?
We know from our customers' feedback how much time and, above all, money a quick and easy-to-install system can save farmers. Similarly, regular annual maintenance, which involves re-tensioning wires and ropes, and any other extraordinary maintenance, becomes a breeze if the system has been built with due care and the right accessories.
A Valente system is forever (semi-quote). Well, maybe forever is too long, how about 30 years? We have customers with systems that have far exceeded this milestone, and others who, finding themselves having to convert their fruit production, have kept the same systems built more than 25 years ago, modifying only the electrical connections. We have customers with systems that have far exceeded this milestone, and others who, faced with having to convert their fruit production, have kept the same systems they built over 25 years ago, modifying only a few details necessary for growing new crops. Why? “Because they were still in excellent condition”!
Anti-hail net is manufactured weaving a plastic monofilament and is used to cover and properly protect crops from damages caused by hail.
Net must be installed and fixed on special structures to guarantee total protection from bad weather, still maintaining a minimum elasticity to avoid premature material wear.
Material used to make the net is high-density polyethylene (HDPE). Wire used is made by extrusion, melting and passing raw material through perforated grids (extruders); subsequently it is thermostabilized, that is to say heated to reduce all retractions that plastic material exposed to even modest heat sources normally presents.
Anti-hail net is made manufacturing monofilament with a particular technique called “loom weaving”; obtained mesh has a rectangular 2.8 x 8 mm shape and is non-deformable, meaning dimensions don’t change when subjected to hail load.
Net weaving is “Leno weaving”, so mono-wire is woven into weft and warp threads.
Anti-hail net is certified and guaranteed over the time. Documentation is released at purchasing.
In apple and pear orchards, various insects and fungi can cause significant damage to both the plants and the fruit. Here are the main ones:
Apple tree
Pear Tree
Mushrooms
The most common fungal diseases affecting apples and pears are:
The use of orchard coverings, now common practice for most crops grown using modern farming methods, actually has a fairly recent history. In the 1960s, when our company entered the market with the production of pre-stressed reinforced concrete poles, the idea of covering orchards was certainly not a priority for farmers, but, as is now clear, many things have changed in just over 60 years.
Starting in the 1980s, besides hail protection, other needs emerged such as protection from insects, rain, wind and sun.
Thanks to the experience we've gained over the years, two other new aspects have emerged that are proving to be fundamental.
The first is that these coverings, in addition to fulfilling their specific functions, can actually be multifunctional, i.e. capable of performing multiple tasks and offering different types of protection.
The second is that coverings also guarantee a better microclimate for crops in various ways, creating a more favourable environment for plant growth and increasing fruit productivity and quality.
Scientific literature on this subject is now quite extensive and, although necessary distinctions must be made regarding the type of coverings, cultivation and characteristics of different territories, it agrees on confirming the benefits in relation to the following parameters.
These are vital benefits, especially when we consider that the environmental situation is continuing to evolve and become more complicated, with mild winters and late frosts, concentrated and more intense rainfall, frequent hailstorms, excessive wind and sunlight, and an increase in alien pathogens.
This scenario leads to one conclusion: fruit growing without orchard covering systems is now unimaginable.
Obviously, there are different types of solutions, from traditional anti-hail systems to multifunctional ones complete with insect nets, single-wire or monobloc systems with different levels of automation, but all of them have a positive impact. Despite representing a significant initial investment, they bring long-term benefits in terms of improved quality and quantity of production that more than justify the costs.
Sezione | Lunghezza | Armatura | Peso | Dimensioni |
| 6×6 | Da 2,00 a 3,80 m | 8 fili = 4 trecce 2×2,25 | 8 kg/m |  |
| 7×7 | Da 2,50 a 4,70 m | 8 fili = 4 trecce 2×2,2512 fili = 4 trecce 3×2,25 | 11 kg/m |  |
| 7×8 | Da 2,50 a 5,50 m | 12 fili = 4 trecce 3×2,25 | 12 kg/m |  |
| 8×8 | Da 2,50 a 5,50 m | 12 fili = 4 trecce 3×2,25 | 15 kg/m |  |
| 9×9 | Da 2,50 a 5,50 m | 12 fili = 4 trecce 3×2,2518 fili = 6 trecce 3×2,25 | 19 kg/m |  |
| 8×12 | Da 2,70 a 5,80 m | 18 fili = 6 trecce 3×2,25 | 25 kg/m |  |
| 14×14 | Da 4,20 a 5,80 m | 36 fili = 12 trecce 3×2,25 | 42 kg/m |  |
We realize tensile structures that requires to be anchored to the ground to grant a permanent tension of the system.
We need therefore elements that, once set in the ground, are able to grant an adequate resistance and stability. They are of different shape and size, to suit the different types of structure and soil.
This type of anchorage consists of a rod and a reinforced concrete plate.
It is used when the soil has gravel or rock inside it or in the presence of extremely sandy soils.
The hexagonal anchors are not galvanized because steel thickness and rod diameter are so big to minimize any corrosion damage that might cause product destruction.
This type of anchoring is ideal for the creation of anti-hail, anti-rain or shading covering systems on terrain without gravel or rock.
STRUKTURASTEEL steel wire is made of high-carbon steel (greater than 0.6%) coated with a zinc-aluminum alloy. It is drawn in diameters ranging from 1.60 to 4.00 mm and is used to connect all intermediate posts, providing support for plants and securing branches. It is also used to connect the ends of posts when covering them with a covering material, such as hail netting.
Cables are used to connect pile to anchor in systems with rear anchoring. Furthermore, they are used in anti-hail systems for longitudinal and transversal connection of piles, to stabilize the whole structure.
Cables, formed by intertwining wires, are highly flexible and easily adjustable to anchored parts.
Wires quantity depends on cable intended purpose and, consequently, desired resistance.
ROPSTEEL cable can also be supplied galvanized with a black plastic coating so that surface touching the net is perfectly smooth, avoiding net early wear due to brushing on cable.
A cut-to-size cable with slipknot has been created to ease installation operations and make them quicker and safer.
In small fruit crops such as strawberries, blueberries, blackberries, raspberries and currants, various insects can cause significant damage to both the plant and the fruit. Here are the main ones:
The spotted wing drosophila Drosophila suzukii (Diptera: Drosophilidae), native to Southeast Asia, appeared in Europe in 2008 in Spain and Italy, subsequently spreading throughout the continent. In Italy, D. suzukii spread from north to south and to the islands in just a few years.
The Nematus ribesii is a sawfly belonging to the Tenthredinidae family. It is known as a parasite of gooseberries.
The Anthonomus rubi, known as the strawberry or raspberry weevil, is a small curculionid beetle that causes damage particularly to the flower buds of these species.
The Frankliniella occidentalis affects several species, including strawberries, where it causes brown streaks and deformation of the petals and malformation of the fruit. In the most severe attacks, the flowers may abort and the fruit may show browning and blackening of the achenes.
Aphids on small fruits (strawberries, currants, raspberries, etc.)
The Chaetosiphon fragaefoli sucks the sap from strawberry plants. The leaves and fruits become sticky due to the honeydew secreted, on which sooty moulds grow. It is also an important vector of several viruses that affect strawberries (Crinke virus, Mild yellow-edge virus).
The Yellow currant aphid (Cryptomyzus ribis) causes blistering and false galls on the edges of the leaves, which turn a wine-red colour. This damage spreads rapidly to other plants, hindering the development of the
The Cochineal is a small insect similar to aphids that feeds on the sap of currant plants. The honeydew it secretes spreads disease and dirties the berries, reducing their value.
The whitefly belongs to the order Hemiptera. Whiteflies belong to the Aleurodidae family; they suck sap and vector certain viruses. The sugary liquid excreted by the nymphs promotes the appearance of fungi such as sooty mould (a black fungus that disfigures affected plants) on the leaves.
Leaf-eating moths (Lepidoptera): their larvae can damage leaves and compromise blueberry development. The most common are the blueberry bush moth, whose larvae feed on leaves and shoots, and the blueberry moth, which mainly attacks the fruit.
The presence of defoliating moths can be seen by the remains of buds and flowers hanging from thin silk threads.
Beetles and mining larvae can damage blueberries. Adult beetles, such as the Japanese beetle (Popillia japonica), feed on leaves and flowers, causing damage to blueberry production. Mining larvae dig tunnels inside the leaves, and adults feed on leaves and flowers, affecting production.
La rete anti insetto è realizzata dalla tessitura di monofilo plastico e viene utilizzata per coprire e proteggere adeguatamente le colture dai danni causati dagli insetti, soprattutto la DROSOPHILA SUZUKI, la CARPOCAPSA e la CIMICE ASIATICA.
Il materiale utilizzato per la realizzazione delle reti anti insetto è il polietilene ad alta densità (HDPE). Il filo utilizzato è realizzato per estrusione, fondendo e facendo passare attraverso delle griglie forate (estrusori) la materia prima; successivamente viene termostabilizzato, ovvero viene riscaldato per far diminuire tutte le ritrazioni che normalmente presenta il materiale plastico esposto a fonti di calore anche modeste.
La rete antinsetto è realizzata lavorando il monofilo con una particolare tecnica chiamata tessitura a telaio: la maglia che si ottiene con questo tipo di lavorazione è di forma rettangolare di misura variabile ed è indeformabile, cioè le dimensioni non variano quando il telo anti insetto è sottoposto alle sollecitazioni.
Le reti anti insetto sono disponibili nelle seguenti dimensioni:
Rete ANTI-CARPOCAPSA: H 2,50 – 4,00 – 4,60
Rete ANTI-SUZUKI: H 2,00 – 2,50 – 3,00
Actinidia (kiwi) cultivation can be threatened by various phytophagous insects, some of which cause direct damage to the fruit, while others weaken the plant, making it more vulnerable to disease. Here are the main ones:
Argyrotaenia pulchellana (Eulia) is a polyphagous leaf-rolling moth that feeds on the leaves, flowers and fruit of numerous herbaceous and arboreal plants, both cultivated and wild.
Metcalfa pruinosa is a homopteran insect belonging to the Flatida family. It can attack kiwifruit, sucking sap and producing white waxy secretions, expelling the sugary part as honeydew and causing the development of sooty moulds, which facilitate the growth of harmful fungi that cover the leaves and fruit with a black coating, reducing photosynthesis and growth.
Pseudaulacaspis pentagona (white scale insect) can cause damage by piercing the shoots of actinidia, causing stress and weakening the plant. In the most serious cases, the branches dry out and fruiting is compromised. Affected fruit develop a reddish halo around the follicles, causing serious economic damage, as they cannot be sold or exported.
Empoasca vitis (green leafhopper) pierces the leaves of actinidia, altering lymphatic flow and transpiration and causing yellowing that rapidly spreads from newly formed leaves to older ones. Necrosis begins at the edges of the leaves, which then fall off, causing a reduction in photosynthesis.
Panonychus ulmi (red spider mite) can infest kiwifruit in hot, dry weather conditions. Repeated bites from the mites reduce the functionality of the foliage, causing leaf discolouration, premature leaf fall and general weakening of the affected plants.
Autographa gamma: The larvae of these lepidoptera can cause significant damage to actinidia plants as they feed on leaves and shoots, the loss of which reduces and may affect photosynthetic capacity, leading to a subsequent reduction in fruit production and quality.
Halyomorpha halys is an extremely polyphagous species that also affects actinidia plants. In spring, the adults colonise the plants, feed and lay their eggs. The larvae, which go through several stages of development, also feed on the sap of the plants and fruits, causing them to fall and become deformed, thus compromising their marketability.
MONILIA DISEASE OF THE CHERRY TREE
Monilia is one of the most widespread and easily recognisable diseases affecting cherry trees. It is caused by two different parasites, called Monilia laxa and Monilia fruttigena, which thrive in particularly damp soil and when the plant is not pruned and disinfected correctly.
The most dangerous period is spring, when temperatures begin to rise and irrigation may be more abundant, with a higher risk of liquid accumulation and stagnation, which causes the fungus to proliferate.
It is easy to recognise when the leaves, flowers or fruits suddenly become darker, as if covered with a thick, compact layer of grey mould, which tends to rot them from the outside inwards and cause them to fall off.
The branches appear dry, with cracks that are an indication of the disease, inside which spores proliferate and where other variants of different bacteria can also insidiously develop.
CORINEO DISEASE OF THE CHERRY TREE
Corineo is also commonly referred to as shot -hole disease, precisely to emphasise how the disease manifests itself with small spots that tend to affect every part of the plant, starting with the leaves.
The characteristic colour of these anomalies is a reddish-purple that forms a distinctive halo that spreads across the entire surface, causing the leaf or fruit to fall and die.
The disease can also be recognised by the small holes that form inside the halo, as well as on the branches near the buds, which are unable to blossom and therefore transform.
The cherries also show encrustations that are difficult to remove and prevent the fruit from being edible.
This is another fungal disease that occurs mainly in spring, when the temperature is very humid and the spores find fertile ground for proliferation.
BACTERIA CANCER OF THE CHERRY TREE
The name sounds rather threatening, and indeed this is one of the most dangerous diseases that can affect this variety.
In this case, it is not caused by a fungus but by a bacterium, which likes to nestle in various types of stone fruit and lead to their premature death, first drying out the branches at the ends and then reaching the heart of the tree and its roots.
The symptoms of bacterial cancer are dark spots that appear irregularly on the leaves, with lighter, blurred halos and necrotic parts on woody areas such as branches and the trunk.
THE ROTTEN CHERRY TREE
Rottenness is one of the most common diseases affecting cherry trees and is caused by a number of factors.
The first factor is excessive irrigation of soil that is already very moist, which causes puddles and waterlogging, leading to the deterioration of the roots as they extend upwards.
The second factor is certain types of fungi, which manifest themselves in this way and must therefore be treated with sulphur-based products and other antibacterial and antiseptic agents. One of the fungi that most affects cherry trees in the Vignola area and is already present in Puglia is Armillaria mellea, a fungus that appears on the roots with a whitish colouring that can lead to the death of the plants. This is more prevalent in soils where cherry trees have been cultivated for a long time.
To prevent this phenomenon, it is therefore advisable to pay attention to soil preparation, adjusting watering according to weather conditions and pruning dry and diseased parts tactically to prevent them from damaging the fruit.
LEAF SPOT DISEASE OF THE CHERRY TREE
Also known as leaf blight, this disease tends to occur mainly in summer and is caused not by a lack of water, as one might mistakenly think, but by a fungus called Gnomonia erythrostoma.
This misunderstanding often leads to delayed action, but it is possible to recognise the difference by noticing yellow patches with a red halo around them, which tends to darken when the necrosis is already at an advanced stage.
The dry leaf tends to fall off, leaving the plant bare.
As with any other infection of this kind, the key is to use a sulphur-based product or the classic copper sulphate to stop the spores from spreading, taking care to remove any damaged parts that are beyond repair and will only encourage the disease to spread.
LEAF-RUST DISEASE OF THE CHERRY TREE
Similar to the previous disease in terms of symptoms, this disease manifests itself with brownish spots mainly on the upper side of the leaf, which gradually darkens until it dies and falls off.
The disease then spreads to the branches, preventing the buds from blooming and thus preventing fruit formation.
The white pustules that accompany this condition can be defeated with a copper-based spray, which is disinfectant and antifungal, combined with a sulphur component for a stronger action.
BLACK APHIDS ON THE CHERRY TREE
This is a disease that can be easily recognised, as it develops following infestation by small black insects that are visible to the naked eye.
These insects bite the shoots of cherry trees and other fruit trees, depositing a large number of other young aphids that do the same thing.
The tree will die quickly if immediate action is not taken, resulting in small, deformed and inedible cherries.
The only solution is to use a specific insecticide or have the tree professionally treated by a pest control expert.
In cherry orchards, various insects can compromise the quality and yield of cherries. Here are the main pests to watch out for:
The rainproof film is a raffia fabric plastic-coated on one side and is used to cover and adequately protect crops from damage caused by rain.
Through a patented welding process, reinforced side selvedges (triple layer of fabric) are applied, essential for secure attachment to the structure; the entire film is waterproof, has considerable mechanical strength and tear resistance.
In addition, perforations are made along the edge of the film so that hooks or carabiners can be inserted to secure it to the structure.
The technical characteristics of the rainproof film are as follows:
Valente offers a quick and automatic system that allows rain covers to be opened and closed like an umbrella, for optimal cherry orchard management.
This innovative technology, installed exclusively on the Multishield structure, offers great advantages and represents a complete, effective, flexible and safe solution for farmers to protect their crops.
The particular arrangement of the Multishield system's covers allows the operator to slide them along the frame of the structure, so that they can be opened and closed as needed, with the great advantage of allowing the plants to grow in normal conditions for most of the time, covering them only when necessary, i.e. when there is a real risk of rain, thus promoting the best development.
The Valente system makes this operation quick and effective, allowing a single worker to close or open the cover of a 100-metre row in less than a minute, which means that 20 minutes are needed for one hectare of land.
Peach and apricot orchards are susceptible to various harmful insects that can compromise the quality and quantity of the harvest.
On peach trees, damage is mostly during harvest time; attacks during flowering and fruit set only happen in protected crops, while they are rare for open field crops. The damage is only cosmetic and shows up as discolouration of the skin, mostly on nectarine cultivars, where it can seriously depreciate the product.
Insects
Prestressed Reinforced Concrete poles are made using pre-tensioning technique, which ensures a greater mechanical resistance.
Valente pole has a trapezoidal shape with four smooth sides and no edges, so not to wear hail nets out in orchard installations. Our trademark is on the front: V for Valente!
Valente pre-stressed cement piles are realized with the wize combination of two fundamental components: concrete (natural gravel and sand mixed with PORTLAND 525 cement) and the high carbon content steel braid with low relaxation (made of two or three braided wires with a diameter of 2.25 mm).
The quality of Valente poles are guaranteed by DNV through Product Quality Certificate.
The poles are available in the KLASSIC version in grey or brown and in 9 sections, with heights from 2 m to 5.8 m.
