DE202017007355U1 - Espalier fruit plant and heating arrangement for heating a planting area - Google Patents

Abstract

Planting plant, in particular espalier fruit plant, in particular viticulture plant, for fruit plants (20) placed in a row, which can be fastened to a fastening wire (32), preferably a wire frame structure (30),
wherein the fastening wire (32) is stretched between posts (31) and wherein a heating device is provided,
characterized,
that the heating device has a heating cable (10) which is guided in a hollow profile (40) and is fastened to the fastening wire (32) via this,
and that the heating cable (10) has an electrically conductive heating conductor (16) and an electrically conductive PTC thermistor (17), both the heating conductor (16) and the PTC thermistor (17) being surrounded by a common jacket (11).

Description

The invention relates to a planting plant, in particular a trellis fruit plant, in particular a wine-growing plant, for fruit plants placed in a row, which can be fastened to a fastening wire, preferably a wire frame, the fastening wire being stretched between posts, and a heating device being provided,

The invention also relates to a heating arrangement for heating a plantation, in particular a trellis fruit plant, particularly preferably a vineyard, with a heating cable.

In the commercial production of fruit, frost is a problem in particular when the fruit plants begin to sprout in spring. The young shoots are particularly susceptible to temperatures below 0 ° C. If it is exposed to frost for a long time, the shoot dies and the fruit plant can no longer develop any fruit here. Especially in espalier fruit orchards, in which a large number of plants are planted in one place, there are massive crop failures when a frosty night is approaching.

1. 1. den Einsatz von Heizungen
2. 2. den Einsatz von Windmaschinen oder Hubschraubern
3. 3. den Einsatz von Sprinklern
4. 4. Oberflächenbewässerung
5. 5. Raucherzeuger

This problem has been known for a long time and various active protection methods are used to protect espalier fruit plants, especially on frosty nights. These methods include:

1. 1. the use of heaters
2. 2. the use of wind machines or helicopters
3. 3. the use of sprinklers
4. 4. Surface irrigation
5. 5. Smoke generator

The above methods have proven to be more or less effective. When heating is used, large combustion units are used, in which part of the heat is captured by the parts of the plant via radiation. Another part of the heat is transported via convection. Regardless of the fact that this method requires the intensive use of fuel, it is also likely to have a strong impact on the environment. Furthermore, this method can only be used when there is little or no wind.

Using wind machines or helicopters, attempts are made to mix warm air layers with cold air layers close to the ground. In the recent past it has been shown that the inversion position required for mixing layers of air is not available, especially on cloudless and clear nights. Therefore, these methods can only be used if there are corresponding inversions.

When using sprinklers or the method of surface irrigation, the enthalpy of evaporation of the water is used to achieve a local temperature increase in the vicinity of the plants. It must be reliably ensured that the water does not freeze on the shoots and form an impermissibly thick layer of ice there. This would damage the shoots

Smoke generators are often used in vineyards. These smoke generators create a layer of smoke over the planting area. This layer of smoke is supposed to absorb heat radiation coming from the ground and prevent excessive radiation. It has been shown that the smoke layer reduces the radiation in the visible wavelength range of light, but has little influence on the transmission of boring radiation. In this respect, the upwardly directed thermal radiation passes through the smoke layer unhindered, especially during the night. This method therefore cannot effectively prevent the orchard from cooling down, especially on cold nights. In addition, the strong smoke development is environmentally harmful.

It is also known to lay electrical heating cables on plants in order to deposit the thermal energy generated by the heating cable in the vicinity of the plants. The heating cable is carefully fixed to the plant to ensure heat transfer to the plant. Only then can sufficient heat input into the plant be guaranteed and the heat can be transported to the shoots with the sap flow of the plant. The use of such heating cables is limited to individual plants, however, since the effort required to fix the heating cable is very complex and cannot be carried out in orchards with reasonable assembly costs. In addition, the heating system must be dismantled again when the frost period is over, which incurs new costs. It is important to ensure that the young shoots are not damaged. In the case of commercial fruit production, care must also be taken that the heating cable is not damaged when the fruit plants are pruned with scissors.

It is the object of the invention to equip a trellis fruit plant of the type mentioned at the beginning with a heating device in such a way that it is possible to effectively combat frost with a reasonable amount of assembly and energy.

This object of the invention is achieved in that the heating device has a heating cable which is guided in and over a hollow profile is attached to the fastening wire, and that the heating cable has an electrically conductive heating conductor and an electrically conductive PTC thermistor, both the heating conductor and the PTC thermistor being surrounded by a common jacket.

The object of the invention is also achieved with a heating device for a planting plant, in particular a trellis fruit plant, in particular a wine-growing plant, with fruit plants placed in a row, the heating device having a heating cable that is guided in a hollow profile, and that the heating cable has an electrically conductive heating conductor and has an electrically conductive PTC thermistor, both the heating conductor and the PTC thermistor being surrounded by a common jacket.

According to the invention, therefore, the heating cable is now fastened to the fastening wire of the wire frame, which is also used to fasten the fruit plant, by means of the hollow profile. Accordingly, the fruit plant is already in contact with the fastening wire. The heating cable can transfer its thermal energy to the hollow profile. The thermal energy is then transferred from the hollow profile to the fastening wire. In the event that the plant is also fixed to the hollow profile, a direct heat input into the plant can take place. This type of heating has advantages especially in viticulture systems. It is the case that the vines are pruned in autumn, with stretchers in the form of flat arches, pendulum arches or round arches being fixed to the fastening wire in the case of trellis systems. In spring the young shoots sprout on the extensor. Since the stretchers are already fixed to the fastening wires, they are therefore also arranged in the immediate vicinity of the heating cable guided in the hollow profile. Thanks to the good thermal conductivity of the hollow profile and the fastening wire, the heat from the heating cable can be transported directly to the wood of the stretcher. From there, the heat can be transported via the juice stream. Furthermore, the thermal output can be entered in direct spatial allocation to the young shoot. In this way, the young shoots are effectively protected. Laying the heating cable in the hollow profile also has the advantage that it offers effective cut protection. This is reliably guaranteed in particular when the hollow profile is made of aluminum or another metal material. This hollow profile is then extremely resistant to the cutting forces that can be generated with conventional scissor tools. According to the invention, the heating cable is designed such that both the heating conductor and the PTC thermistor, which is not designed for heating purposes and leading back to the power source, are routed in a common cable assembly. The heating conductor has a sufficiently high ohmic resistance to be able to guarantee the required heat generation. In contrast, the PTC thermistor has a very small ohmic resistance for the most loss-free current flow possible. Because the two conductors, namely the heating conductor and the PTC thermistor, are routed in a cable network, they can be laid together in the profile in a simple manner. In the case of trellis fruit plants placed in rows, a heating cable in particular can then be laid along a row of the trellised fruit plant. At the end of the row the heating cable can then be uniformly contacted and connected to a power supply. No digging work is required when laying the heating cable, which is a clear installation advantage.

Fixing the hollow profile on the fastening wire also has the advantage that the heating device can remain in the orchard. In particular, it does not have to be dismantled. In particular, the hollow profile is arranged along the fastening wire at a point on the plant that is not excessively stressed even when using, for example, mechanical harvesting machines, so that damage is prevented. Accordingly, the hollow profile does not have to be dismantled after the end of the frost period, which saves assembly costs. It can then remain in the orchard for many years.

According to a preferred variant of the invention, it can be provided that the heating conductor is electrically conductively connected to the PTC thermistor in the region of one end of the heating cable, and that the other end of the heating conductor and the PTC thermistor are led to an electrical junction box and contacted there, the junction box preferably is attached to a support post of the wire frame structure. In this way, a closed circuit can be formed simply by using the heating cable, so that the laying of the heating cable is easy. At the end of the heating cable, the heating cable can be contacted at the junction box. The fruit grower can then, for example, lay a cable harness in the frost-critical time and connect it to the junction boxes using suitable plugs. A power supply can be connected via the wiring harness. As soon as the frost-critical period is over, the wiring harness can be dismantled again. It is particularly advantageous here if it is provided that the connection box has a connection terminal made of temperature-resistant material, in particular a ceramic connection terminal, on which both the heating conductor and the PTC thermistor are in direct contact. The heating conductor can therefore be connected directly to the connection terminal, so that there is no need for a complex transfer of the heating conductor to a cold connection end. This makes it possible to use a particularly inexpensive heating cable.

It can particularly preferably be provided that the support post or posts has a hook-shaped wire holder on which the tensioned fastening wire can be hooked and unhooked, and that the hollow profile is wrapped around the fastening wire. Such support posts are typical in particular in vineyards. To install the heating device, the hollow profile can be twisted around the fastening wire. In the area of the support post, the fastening wire can be unhooked and the hollow profile can be wrapped around the fastening wire past the support post. The fastening wire can then be attached to the hook-shaped wire holder again. In this way, an intimate connection between the fastening wire and the hollow profile is achieved, with the two components being braced against one another. A development of the hollow profile with respect to the fastening wire is simply prevented by the fact that the fastening wire is hooked into the hook-shaped wire holder. The installation of the heating devices is therefore extremely simple and effective.

According to the invention, it can also be provided that the hollow profile has one or more bulges, and that a receptacle is formed between the bulge and the fastening wire, which is suitable for receiving a branch, in particular an extensor of a vine. In this way, the hollow profile can also be used to fix the branch to the fastening wire. The branch only needs to be bent and inserted into the receptacle between the bulge and the fastening wire. Due to its internal tension, the branch then holds by itself. An additional fixation with a fastening wire, as is customary in viticulture, for example, can then be dispensed with.

A further variant of the invention can be such that the hollow profile has a bend by means of which it is bent away from the fastening wire, that the hollow profile is attached to a branch, in particular a stretcher of a vine, after the bend, and that the hollow profile is then attached via another The bend is bent back in the direction of the fastening wire and attached to it. Accordingly, the hollow profile can be guided along the branch in an existing orchard. In this way an optimal heat supply for this part of the plant is guaranteed. The secure assignment of the hollow profile to the wire frame takes place again via the fastening wire.

According to the invention, it can also be provided that the heating conductor and the PTC thermistor are twisted with one another in the longitudinal direction of the cable. This twist does not result in an extended alignment of the heating conductor or the PTC thermistor in the longitudinal direction of the heating cable. Rather, these cables run helically. In this way, the heating cable has the possibility of elongation in the event of thermal fluctuations. This simple measure reliably prevents damage to the heating cable in the event of normal temperature fluctuations.

In espalier orchards, long rows of fruit plants are usually formed, which are connected to one another via a wire frame. Accordingly, the heating cable can extend a considerable length along the row. When laying the heating cable, it must be pulled into the hollow profile. In order to prevent damage when pulling in the heating cable, a variant of the invention provides that the heating conductor, the PTC thermistor and an extension, preferably in the form of a thread or fiber, made of high tensile strength material, for example glass fiber or metal, are twisted together in the longitudinal direction of the cable. The tensile forces can be absorbed via the extension.

A heating cable, which is particularly suitable for installation in orchards and at the same time also inexpensive, is such that the heating conductor, each surrounded by an insulating sleeve, and the PTC thermistor are wrapped in a protective film, and that an electrically conductive grounding ( 13th ) is led around, which is then covered by another slide ( 12 ) is wrapped. Finally, an insulating jacket can be placed around the further film.

The object of the invention is also achieved with a heating device for a trellis fruit plant, in particular a wine-growing plant, with fruit plants placed in series, the heating device having a heating cable which is guided in at least two hollow profiles lined up, the two hollow profiles being in the area of one of their longitudinal sides Opposite ends in a joint area, a sleeve being pushed over the two hollow profiles in this joint area, and the two hollow profiles being connected to the sleeve. With regard to the advantages of the heating device, reference is made to the statements above. In the case of long rows of plants in espalier fruit orchards, hollow profiles that are not continuous cannot be used. Rather, sections of hollow profiles are to be attached to the wire frame. To connect the hollow profiles, the sleeve proposed according to the invention is used, which is pushed over the two ends of the hollow profiles lined up next to one another. The inner diameter of the sleeve is dimensioned such that it can be pushed over the outer diameter of the hollow profiles. This results in a particularly simple and effective connection option for the hollow profiles.

If it is provided that the sleeve is at least partially surrounded by a shrink tube and that the shrink tube has end sections on one or both sides following the sleeve, which are at least partially guided over the adjoining hollow profiles, then a simple type of connection is achieved. This type of connection is also characterized by elastic properties. In particular, the shrink tube has, within certain limits, the possibility of taking up a longitudinal expansion or an offset of the hollow profiles in the longitudinal direction. Such a longitudinal expansion can occur, for example, as a result of temperature due to temperature differences along the row of plants of the planting system. In addition, the longitudinal end sections of the shrink tubing form a watertight connection, so that penetration of water into the space which is enclosed by the hollow profiles is reliably prevented. The assembly of the sleeve with the shrink tube can be done easily in the orchard, for which only a heating element, for example a Bunsen burner, has to be used. Of course, it is also conceivable that a short piece of shrink tubing is used at each of the two ends of the sleeve, which is then passed on one side over the connected hollow profile.

Provision is particularly preferably made for an adhesive connection, preferably consisting of hot melt or hot melt adhesive, to be arranged between the shrink tube and the outside of the hollow profile or profiles and the outside of the sleeve, at least in some areas. In this way, a high-strength connection between the sleeve and the connected hollow profile is achieved.

• • Polyamide
• • Polyethylen
• • amorphe Polyalphaolefine
• • EVAC (Ethylenvinylacetat-Copolymere)

The hot melt or hot melt adhesive can consist of a polymer material. The following materials can preferably be used as base polymers

• • polyamides
• • polyethylene
• • amorphous polyalphaolefins
• • EVAC (ethylene vinyl acetate copolymers)

These base polymers are sufficiently temperature resistant for the chosen application.

• • Kolophonium
• • Terpene
• • Kohlenwasserstoffharze

The following materials can be added to the aforementioned base polymers as resin:

• • rosin
• • terpenes
• • hydrocarbon resins

Furthermore, stabilizers in the form of antioxidants can be added, for example phenols or peroxide decomposers. The use of UV-resistant light protection agents has also proven to be advantageous for use in orchards. Natural or synthetic waxes can also be used

• 1 in schematischer Seitenansicht ein Drahtgerüst einer Obstanlage in Seitenansicht,
• 2 ein Detail der Obstanlage mit einem Abschnitt einer Heizeinrichtung gemäß 1,
• 3 eine Muffenverbindung für Hohlprofile der Heizeinrichtung gemäß 2 in Seitenansicht und
• 4 in perspektivischer Darstellung ein Heizkabel.

The invention is explained in more detail below with reference to an embodiment shown in the drawings. Show it:

• 1 a schematic side view of a wire frame of an orchard in side view,
• 2 a detail of the orchard with a portion of a heating device according to 1 ,
• 3 a socket connection for hollow profiles of the heating device according to 2 in side view and
• 4th a heating cable in a perspective view.

1 shows a plant as it is used in viticulture. It is an educational facility for grapevines 20th . There are support posts for this plantation 31 placed at a distance from one another along the terrain profile. The support posts 31 are forming a wire frame structure 30th connected by wires. A fastening wire comes with it 32 for use, the over the support post 31 is led away. Above and at a distance from the fastening wire is a bending wire 33 arranged. Above the bending wire 33 three wire pairs are arranged, which are movable and in the vertical extension of the support posts 31 can be adjusted to a limited extent. The fruit plants 20th extend with their trunk into the area of the fastening wire 32 . Turned away from the ground, the trunk forms stretchers 21st attached to the mounting wire 32 can be attached. In the drawing, two typical types of education are shown as examples. By the two grapevines on the right 20th a horizontal education is shown, with the extensor 21st along the fastening wire 32 are guided and attached. The left two vines 20th represent a so-called pendulum arch training. Here are the stretchers 21st starting from the trunk to the bending wire 33 guided and fixed there. From the bending wire 33 become the stretchers 21st back again towards the fastening wire 32 bent and fastened there. From the stretchers 21st go shoots 22nd from. These urges 22nd can then on the bending wire 33 or the wire pairs 34 to 36 attached.

In the present embodiment, it is along the fastening wire 32 relocated a heater. This heating device has a hollow profile 40 on that on the mounting wire 32 is fixed.

As 2 reveals is the fastening wire 32 on hook-shaped wire holders 31.1 the support post is attached. The hollow profile 40 is laid twisted around the fastening wire so that the hollow profile is closely related 40 to the fastening wire 32 results. If necessary, binding wires can also be used 37 be used with which the hollow profile 40 on the fastening wire 32 is fixed. Inside the hollow profile 40 is a heating cable 10 out that later with reference to 4th is explained in more detail. The hollow profile 40 can like this 2 further shows a bulge 41 exhibit. This is generated in such a way that a bend is generated from the hollow profile, the hollow profile 40 first from the binding wire 32 away and then back towards the binding wire 32 is bent back, taking a recording 42 arises. In this recording 42 can the straightener 21st the neighboring fruit plant, so that an easy fixation is possible. In particular, the extensor must 21st only in the recording 22nd be inserted. An additional fastening of the extensor by means of a fastening wire 37 is then no longer necessary. As 3 shows can run along the fastening wire 32 several hollow profiles 40 be laid and connected to one another at their longitudinal pipe ends. To connect the hollow profiles 40 is a sleeve 50 used. The sleeve 50 can be designed as a pipe section. Where is the inside diameter of the sleeve 50 on the outer diameter of the hollow profiles 40 Voted. In this way the sleeve 50 over the pipe ends 43 be pushed. Around the sleeve 50 is a shrink tube 60 placed. The shrink tube 60 has end sections 61 in the assembled state around the areas of the pipe ends 43 are led around following the sleeve 50 form. The shrink tube is preferably on its sleeve 50 and / or the hollow profiles 40 facing inner contour coated with a hot melt adhesive. If now the one over the sleeve 50 and the hollow profiles 40 put shrink tubing 60 is heated, it shrinks onto the outer wall of the sleeve 50 and the hollow profiles 40 on. This takes place with the introduction of thermal energy, for example with a Bunsen burner. This heat input also heats the hot melt adhesive. When shrinking the shrink tube 60 consequently, the shrink tube is glued to the sleeve at the same time 50 or the pipe ends 43 . This creates a high-strength connection for the hollow profiles that are lined up 40 generated. This connection is also waterproof as the heat shrink tubing 60 in the transition of the sleeve 50 to the hollow profiles 40 with the end sections 61 forms a tight connection.

In 4th is the heating cable 10 shown. As this illustration shows, the heating cable 10 a heating conductor 16 on. This is designed in such a way that it has a resistance at a voltage of 220 V, so that heating outputs in the range between 10 and 25 W / meter can be generated. This way, common orchards can be safely protected against frost. The heating cable can preferably generate a heating power in the range between 12 to 20 W / meter. This is ideal for use in vineyards. The heating conductor 16 is from an insulating sleeve 15th surround. There is also a PTC thermistor 17th used, which can be designed for example in the form of a copper braid with a very low resistance. For example, a resistance in the range of 0.035 ohms / meter can be realized. Also the PTC thermistor 17th is from an insulating sleeve 18th surround. The heating conductor 16 and the PTC thermistor 17th are at a slow pace 19th twisted, i.e. in the longitudinal extension of the heating cable 10 helically wrapped around each other. The Beilauf 19th can be made of fiberglass. Around the heating conductor 16 , the PTC thermistor 17th and the drain 19th a protection made of polyester is arranged around it. This protection can, for example, be a protective film 14th be formed around the heating conductor 16 , the PTC thermistor 17th and the drain 17th is wrapped around. Between an aluminum-laminated foil 12 and the protective film 14th is a ground 13th guided. This can be formed, for example, from a tinned copper wire or a tinned copper wire mesh. The heating cable 10 is finished with an outer jacket made of polyethylene, which is attached to the foil 12 is extruded on.

As 1 shows is the heating cable 10 in the hollow profile 40 , or the hollow profiles 40 guided. At one end is the heating cable 10 to a junction box 70 connected. The junction box 70 has a connection terminal made of ceramic material that is temperature resistant. In this way the heating cable can be connected to the heating conductor 16 and the PTC thermistor 17th directly to the connection terminal of the junction box 70 connected. The junction box 70 is preferably on the last support post 31 of the wire frame attached. Here you can then use a connecting cable 71 and one on the connecting cable 71 attached to the junction box 70 matched plug a connection to a power supply 72 respectively. The junction box 70 the heating cable is turned away 10 designed at the end so that the heating conductor 16 with the PTC thermistor 17th connected to complete the circuit.

Once the power supply 72 to the heating cable 40 connected, the heating conductor heats up 16 . The thermal energy of the heating conductor 16 is on the hollow profile 40 or the hollow profiles 40 transfer. The heat energy is from the hollow profiles 40 then in the fastening wire 32 brought in. In the case of the 1 The right training method shown is then the thermal energy via the fastening wire 32 or via the hollow profile 40 in the stretchers 21st introduced so that they are effectively protected from frost. At the in 1 The pendulum arch training shown on the left is the hollow profile 40 along the pendulum arches (Strecker 21st ) bent, so that a direct heat input into the stretchers 21st can be done. When the hollow profile 40 is formed from an aluminum material, it can be simply molded onto the straightener 21st success.

So-called self-regulating heating cables can also be used within the scope of the invention. Self-regulating heating tapes have two parallel supply conductors, namely a heating conductor and a returning PTC thermistor. These supply conductors are embedded in a cross-linked plastic heating element doped with carbon particles. If the temperature rises during operation, the plastic expands through molecular expansion and the distances between the carbon particles increase. The resistance of the conductive plastic increases and the performance decreases. When it cools down, this process is reversed and performance increases. Such self-regulating heating cables do not have to be manufactured in a ready-made size. Rather, they can be cut to length as required, with a constant heat output per meter.

Claims (14)

Planting plant, in particular espalier fruit plant, in particular wine growing plant, for fruit plants (20) placed in a row, which can be fastened to a fastening wire (32), preferably a wire frame structure (30), the fastening wire (32) being stretched between posts (31) and a heating device being provided is, characterized in that the heating device has a heating cable (10) which is guided in a hollow profile (40) and fastened to the fastening wire (32) via this, and that the heating cable (10) has an electrically conductive heating conductor (16) and has an electrically conductive PTC thermistor (17), both the heating conductor (16) and the PTC thermistor (17) being surrounded by a common jacket (11). Espalier fruit plant after Claim 1 , characterized in that the heating conductor (16) is electrically connected to the PTC thermistor (17) in the region of one end of the heating cable (10), and that the other end of the heating conductor (16) and the PTC thermistor (17) lead to an electrical connection box and are contacted there, wherein the junction box is preferably attached to a support post (31) of the wire frame structure (30). Espalier fruit plant after Claim 2 , characterized in that the junction box has a connection terminal made of temperature-resistant material, in particular a ceramic connection terminal, on which both the heating conductor (16) and the PTC thermistor (17) are in direct contact. Espalier fruit plant according to one of the Claims 1 to 3 , characterized in that the hollow profile (40) is wound around the fastening wire (32), and that the support post or posts (31) preferably has a hook-shaped wire holder (31.1) on which the tensioned fastening wire (32) can be suspended and removed .. Espalier fruit plant according to one of the Claims 1 to 4th , characterized in that the hollow profile (40) has one or more bulges (41), and that a receptacle (42) is formed between the bulge (41) and the fastening wire (32), which is suitable for a branch, in particular a straightener (21) to take up a vine. Espalier fruit plant according to one of the Claims 1 to 5 , characterized in that the hollow profile (40) has a bend, by means of which it is bent away from the fastening wire (32), that the hollow profile (40) is attached to a branch, in particular a stretcher (21) of a vine, following the bend , and that the hollow profile (40) is then bent back over a further bend in the direction of the fastening wire (32) and is fastened to it. Heating devices for a plantation, in particular a trellis fruit plant, in particular a wine-growing plant, with fruit plants (20) placed in a row, characterized in that the heating device has a heating cable (10) which is guided in a hollow profile (40), and that the heating cable (10) has an electrically conductive heating conductor (16) and an electrically conductive PTC thermistor (17), both the heating conductor (16) and the PTC thermistor (17) being surrounded by a common jacket (11). Heating device after Claim 7 , characterized in that the heating conductor (16) and the PTC thermistor (17) are twisted together in the longitudinal direction of the cable. Heating device after Claim 7 or 8th , characterized in that the heating conductor (16), the PTC thermistor (17) and a shim (19), preferably in thread form or fiber form, made of tensile material, for example glass fiber or metal, are twisted together in the longitudinal direction of the cable. Heating devices according to one of the Claims 8 to 9 , characterized in that the heating conductor (16) and each surrounded by an insulating sleeve (15, 18). the PTC thermistor (17) are jointly wrapped in a protective film (14), and that an electrically conductive earth (13) is routed around the protective film (14), which is then wrapped in a further film (12). Heating devices for a trellis fruit plant, in particular a wine-growing plant, with fruit plants (20) placed in a row, characterized in that the heating device has a heating cable (10) which is guided in at least two concatenated hollow profiles (40) so that the two hollow profiles (40) are in Area of one of their longitudinal ends in a joint area opposite that a sleeve (50) is pushed over the two hollow profiles (40) in this joint area, and that the two hollow profiles (40) are connected to the sleeve (50). Heating device after Claim 11 , characterized in that the sleeve (50) is at least partially surrounded by a shrink tube (60), and that the shrink tube (60) has end sections (61) on one or both sides following the sleeve (50) which at least partially extend over the subsequent hollow profiles (40) are performed. Heating device after Claim 12 , characterized in that between the shrink tube (60) and the outside of the or the hollow profile (40) and the outside of the sleeve (50) at least regionally an adhesive connection, preferably consisting of hot glue is arranged. Heating device according to one of the Claims 11 to 13th , indicated by one of the Claims 7 to 10 , or use of a heating device according to one of the Claims 11 to 13th in a trellis fruit plant according to one of the Claims 1 to 6th , preferably with a heating device according to one of the Claims 7 to 10 .

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