Patent Description:
Wind turbine blades are commonly made from fiber-reinforced resin. To facilitate manufacture, individual blade components are often pre-manufactured and connected with each other afterwards. For example, a pressure side and a suction side shell of a blade are manufactured separately and are then connected with each other at the leading and trailing edges. Further, for example, a shear web is manufactured separately and is then connected to a pressure side and a suction side shell of a blade. Known methods of connecting pre-manufactured blade components with each other include adhesive processes as well as infusion of a dry fiber lay-up in a connection region with resin. Further, <CIT> and <CIT> disclose thermal welding for joining blade components.

It is one object of the present invention to provide an improved wind turbine blade and an improved method for manufacturing a wind turbine blade.

Accordingly, a wind turbine blade is provided. The wind turbine blade comprises:.

Connecting the first and second blade components by thermal welding provides a faster connection method compared to a laminate joint because curing of an epoxy resin is not required. Further, an advantage of thermal welding compared to a glue joint is that an adhesive which adds significant weight to the blade can be avoided.

Further, the resistive element which was used for the welding process and is left in the blade as a remnant of the welding process can be integrated into the lightning protection system of the blade. By connecting the resistive element at its first and second terminals to the lightning conductor, flashovers during lightning between the resistive element and the lightning conductor can be prevented. In particular, in the case of high voltages at the lightning conductor caused by a lightning strike of the blade, the surge protection device opens a pathway for the lightning current to flow via the resistive element. Hence, large voltage differences between the resistive element and the lightning conductor are prevented. Thus, uncontrolled current flows such as flashovers and arcing between the resistive element and the lightning conductor are avoided.

The wind turbine blade is part of a rotor of a wind turbine. The wind turbine is an apparatus to convert the wind's kinetic energy into electrical energy. The wind turbine comprises, for example, a rotor having one or more of the blades connected each to a hub, a nacelle including a generator, and a tower holding, at its top end, the nacelle. The tower of the wind turbine may be connected via a transition piece to a foundation of the wind turbine, such as a monopile in the seabed or a concrete foundation.

The wind turbine blade, e.g., its root section, is fixedly or rotatably connected to the hub. Apart from a (cylindrical) root section, the wind turbine blade is formed aerodynamically. The wind turbine blade comprises, for example, a pressure side (upwind side) and a suction side (downwind side). The pressure side and the suction side are connected with each other at a leading edge and a trailing edge. The pressure and suction sides and the leading and trailing edges define an airfoil of the wind turbine blade.

The wind turbine blade has a shell made, for example, from a fiber-reinforced resin. The blade shell is, for example, manufactured by arranging fiber lay-up in a mold, infusing the fiber lay-up with resin, and curing the resin. The blade shell surrounds, for example, an interior cavity of the blade. The wind turbine blade further comprises, for example, one or more shear webs connecting the blade shells of the pressure side and the suction side in the interior cavity of the blade. The shear web provides shear strength to the blade.

A pressure side shell, suction side shell, the one or more shear webs and/or other blade components may be pre-manufactured separately. Then, the pre-manufactured blade components (e.g., a first and a second blade component) may be joined with each other, for example, by thermal welding.

Thermal welding includes, for example, thermal resin welding of weldable resin such as thermoplastic resin or weldable thermoset resin. Thermal welding is, for example, thermoplastic welding.

The resistive element is, in particular, an electrically conductive element. The resistive element can produce heat by means of a current that is applied to the resistive element and that is flowing between the first and second terminals of the resistive element. The resistive element is, in particular, a heating element. The heat produced by the resistive element depends on the electrical resistance of the resistive element and the amount of current and/or voltage applied to the resistive element.

The resistive element can be made of a metal. For example, the resistive element is made of copper. Alternatively, the resistive element can be made of carbon fibers.

The resistive element is arranged between the blade components such that it is sandwiched between the blade components in the overlap region.

The overlap region is a region in which a portion of the first blade component overlaps with a portion of the second blade component. The overlap region is a joining region of the first and second blade components.

During manufacture, a thermoplastic resin or weldable thermoset resin may be placed between the first and second blade components in the overlap region, e.g., in contact with a surface of the first and/or second blade component and/or the resistive element. When the resistive element is heated up by applying an electrical current through the resistive element, the thermoplastic resin or weldable thermoset resin melts and/or softens and joins the blade components.

The lightning conductor is a down conductor of a lightning protection system of the blade. The lightning conductor is, for example, arranged parallel to a longitudinal direction of the blade. In the manufactured state of the wind turbine, the lightning conductor is, for example, electrically connected at a first end thereof with a ground potential and is connected at a second end thereof with one or more air termination elements of the lightning protection system.

One of the first and second terminals being electrically connected with the lightning conductor via the surge protection device means that only one of the first and second terminals is electrically connected with the lightning conductor via the surge protection device. The other one of the first and second terminals is electrically connected with the lightning conductor without an intercalated surge protection device.

The first terminal of the resistive element is, in particular, electrically connected with a first connection portion of the lightning conductor. Further, the second terminal of the resistive element is electrically connected with a second connection portion of the lightning conductor, the first and second connection portions being separated from each other.

According to an embodiment, the surge protection device is configured to:.

Thus, during manufacture of the blade, the electrical connection of the resistive element with the lightning conductor for lightning protection can be already established, in particular before the thermal welding process. Nevertheless, the resistive element can still be used during manufacture as a heating element for the thermal welding process.

A voltage applied to the surge protection device during a lightning strike usually exceeds the threshold voltage such that the surge protection device acts as electrical connector.

Further, a voltage applied to the surge protection device during the thermal welding process is usually much lower than the threshold voltage such that the surge protection device acts as electrical isolator.

The lightning conductor is, for example, arranged in the interior cavity of the blade shell. The lightning conductor is, for example, arranged at the first and/or second blade component and/or at a shear web of the blade.

According to a further embodiment, only one of the first and second terminals is connected to the lightning conductor via a surge protection device and the other one of the first and second terminals is connected to the lightning conductor by an electrical wire.

In particular, the other one of the first and second terminals is connected to the lightning conductor by only an electrical wire, i.e. without an intercalated surge protection device.

According to a further embodiment, the resistive element is an elongated element extending in a longitudinal direction and having a first and a second end with respect to its longitudinal direction, and the first terminal is arranged at the first end and the second terminal is arranged at the second end.

Having an elongated resistive element (i.e. an elongated conductive element) in the blade bears the risk of large voltage difference between the first and second ends of the resistive element during lightning conditions. By connecting the first and second ends of the elongated resistive element with the lightning conductor, flashovers between the resistive element and the lightning conductor can be better prevented.

A length of the resistive element in the longitudinal direction is, for example, <NUM> meter or more, <NUM> meter or more, <NUM> meter or more and/or <NUM> meter or more.

According to a further embodiment, the overlap region of the first and second blade components is an elongated region arranged (i.e. extending) parallel to a longitudinal direction of the blade and/or the resistive element is an elongated element arranged (i.e. extending) parallel to the longitudinal direction of the blade.

The elongated resistive element is, for example, arranged such that it is extending parallel to the lightning conductor.

According to a further embodiment, the wind turbine blade comprises two or more of the resistive elements electrically connected to each other in series at their respective first and/or second terminals.

By using more than one resistive element, a joint between the first and second blade components over a large bonding line can be realized by thermal welding. Further, by using more than one resistive element, the voltage required for heating a respective one of resistive elements can be kept small (e.g., at or below <NUM> V and/or <NUM> V).

The wind turbine blade may also comprise more than one surge protection device.

According to a further embodiment, each of two neighboring ones of the two or more resistive elements are electrically connected with each other at their neighboring terminals, and the neighboring terminals are electrically connected with the lightning conductor by a common conductive wire and/or by a common surge protection device.

Thus, the number of conductive wires, conductive connections and/or surge protection devices can be reduced.

According to a further embodiment, the wind turbine blade comprises an even number n of the resistive elements and a number p of the surge protection devices, wherein p is an even number fulfilling the equation p = (n / <NUM>) or p is an odd number fulfilling the equation p = (n / <NUM>) + <NUM>.

Preferably, p is fulfilling the equation p = (n / <NUM>) because in this case a smaller number of surge protection devices is necessary.

According to a further embodiment, the wind turbine blade comprises an odd number m of the resistive elements and a number q of the surge protection devices, wherein q is an even number fulfilling the equation q = [(m - <NUM>) / <NUM>] + <NUM>.

According to a further embodiment, the first blade component and/or the second blade component comprises a blade half shell, a lower blade shell, an upper blade shell, a pressure side shell, a suction side shell, a structural element, a reinforcement beam, a web and/or a shear web.

According to a further embodiment, the threshold voltage is <NUM> kV or larger, <NUM> kV or larger, <NUM> kV or larger, <NUM> kV or larger, <NUM> kV or larger and/or <NUM> kV or larger.

According to a further aspect, a method for manufacturing a wind turbine blade is provided. The method comprises the steps of:.

In step a), a weldable resin such as thermoplastic or weldable thermoset resin may be arranged between the first and second blade components.

According to an embodiment of the further aspect, a voltage applied at the surge protection device in step b) is at or below a threshold voltage such that:.

According to a further embodiment of the further aspect, each of the first and second terminals are electrically connected in step b) with a power source for supplying the electrical current between the first and second terminals.

According to a further embodiment of the further aspect, the method comprises the step of removing after step b) the electrical connection between each of the first and second terminals and the power source.

The embodiments and features described with reference to the wind turbine blade of the present invention apply mutatis mutandis to the method of the present invention.

<FIG> shows a wind turbine <NUM> according to an embodiment. The wind turbine <NUM> comprises a rotor <NUM> having one or more blades <NUM> connected to a hub <NUM>. The hub <NUM> is connected to a generator (not shown) arranged inside a nacelle <NUM>. During operation of the wind turbine <NUM>, the blades <NUM> are driven by wind to rotate and the wind's kinetic energy is converted into electrical energy by the generator in the nacelle <NUM>. The nacelle <NUM> is arranged at the upper end of a tower <NUM> of the wind turbine <NUM>. The tower <NUM> is erected on a foundation <NUM> such as a monopile or concrete foundation. The foundation <NUM> is connected to and/or driven into the ground or seabed.

<FIG> shows a cross-section view of a wind turbine blade <NUM> of the wind turbine <NUM> of <FIG>.

The blade <NUM> comprises a blade shell <NUM> including a lower blade shell <NUM> and an upper blade shell <NUM>. The lower and upper blade shells <NUM>, <NUM> are lower and upper blade shells with respect to a manufacturing position. The lower blade shell <NUM> is, for example, a pressure side shell and the upper blade shell <NUM> is, for example, a suction side shell or vice versa. The blade shell <NUM> surrounds an interior cavity <NUM> of the blade <NUM>.

The blade <NUM> further comprises one or more structural elements <NUM> running in a longitudinal direction L1 of the blade <NUM>. The longitudinal direction L1 of the blade <NUM> is, for example, pointing from a root of the blade <NUM> to a tip of the blade <NUM>. The structural element <NUM> preferably comprises fiber composite material, in particular glass fiber mats. The structural element <NUM> can be a shear web, a spar cap or the like. In <FIG>, a shear web <NUM> is shown as an example for a structural element <NUM>. Although not shown in the figures, the blade <NUM> can also comprise more than one shear web <NUM>. The shear web <NUM> is connecting the blade shells <NUM>, <NUM> of the pressure side and the suction side in the interior cavity <NUM> of the blade <NUM> and is providing shear strength to the blade <NUM>. The shear web <NUM> comprises two flanges <NUM>, <NUM> that are attached to inner surfaces <NUM>, <NUM> of the shells <NUM>, <NUM>, respectively.

The blade <NUM> is, for example, assembled from several pre-manufactured blade components such as the lower blade shell <NUM>, the upper blade shell <NUM>, the structural element <NUM> and/or the shear web <NUM>. Such pre-manufactured blade components may, for example, be connected to each other at joints <NUM>, <NUM>, <NUM>, <NUM> by thermal welding. For example, the lower blade shell <NUM> is connected to the upper blade shell <NUM> in a first and a second joint <NUM>, <NUM> by thermal welding. The first and second connection regions <NUM>, <NUM> are, in particular, arranged at a leading edge <NUM> and a trailing edge <NUM> of the blade <NUM>. Furthermore, the structural element <NUM> such as the shear web <NUM> is connected to the lower blade shell <NUM> in a third joint <NUM> by thermal welding and/or is connected to the upper blade shell <NUM> in a fourth joint <NUM> by thermal welding.

In the following, exemplarily, the fourth joint <NUM> between the shear web <NUM> and the upper blade shell <NUM> by thermal welding is described. However, the following description may also be applied to one, more or all of the other joints <NUM>, <NUM>, <NUM>.

<FIG> shows a detail view of portion III of <FIG>. Visible in <FIG> is a portion of the shear web <NUM> including its upper flange <NUM> and a portion of the upper blade shell <NUM>. The shear web <NUM> is an example of a first blade component. Further, the upper blade shell <NUM> is an example of a second blade component. The shear web <NUM> and the upper blade shell <NUM> are connected with each other in an overlap region <NUM> by thermal welding. For providing the necessary heat for thermal welding, the blade <NUM> comprises a resistive element <NUM>. The resistive element <NUM> is arranged between the shear web <NUM> (in particular the upper flange <NUM> of the shear web <NUM>) and the upper blade shell <NUM> in the overlap region <NUM> during manufacture. Further, as can be seen in <FIG>, the resistive element <NUM> remains after the manufacturing process in the blade <NUM>. Further indicated in <FIG> is that during the manufacturing process a weldable resin <NUM> is arranged between the shear web <NUM> (in particular the upper flange <NUM> of the shear web <NUM>) and the upper blade shell <NUM> in the overlap region <NUM>.

The resistive element <NUM> which is used as a heating element for the welding process during manufacture is left in the blade <NUM> as a remnant of the welding process. Further, the resistive element <NUM> is electrically connected (reference sign <NUM>) to a lightning conductor <NUM> and is, thus, integrated into a lightning protection system (not shown) of the blade <NUM>.

<FIG> illustrates electrical connections of the resistive element <NUM> during thermal welding of blade components, i.e. of the shear web <NUM> and the upper blade shell <NUM>. <FIG> shows a cross-section along line A-A in <FIG>.

The resistive element <NUM> is an elongated element extending in a longitudinal direction L2 and parallel to the longitudinal direction L1 of the blade <NUM>. The resistive element <NUM> has a first end <NUM> and a second end <NUM> with respect to the longitudinal directions L1, L2.

Further, the resistive element <NUM> has first and second terminals <NUM>, <NUM> for electrical connection. In particular, the first terminal <NUM> is arranged at the first end <NUM> of the resistive element <NUM>. Further, the second terminal <NUM> is arranged at the second end <NUM> of the resistive element <NUM>.

In order to prevent flashovers during operation of the wind turbine <NUM> between the resistive element <NUM> remaining in the blade <NUM> after manufacture and the lightning conductor <NUM>, the first and second terminals <NUM>, <NUM> of the resistive element <NUM> are electrically connected to the lightning conductor <NUM>. In particular, one of the first and second terminals <NUM>, <NUM> of the resistive element <NUM> is electrically connected to the lightning conductor <NUM> by an electrical wire <NUM>. Further, the other one of the first and second terminals <NUM>, <NUM> of the resistive element <NUM> is electrically connected to the lightning conductor <NUM> via a surge protection device <NUM> and a further electrical wire <NUM>. In the example of <FIG>, the first terminal <NUM> is electrically connected to the lightning conductor <NUM> by the electrical wire <NUM>, and the second terminal <NUM> is electrically connected to the lightning conductor <NUM> via the surge protection device <NUM>.

The surge protection device <NUM> is configured to provide a closed electrical connection between the second terminal <NUM> of the resistive element <NUM> and the lightning conductor <NUM> when a voltage V applied to the surge protection device <NUM> exceeds a threshold voltage Vth. Since a voltage V applied to the surge protection device <NUM> during a lightning strike usually exceeds the threshold voltage Vth, the surge protection device <NUM> acts as electrical connector in this case.

Further, the surge protection device <NUM> is configured to provide an electrical isolation between the second terminal <NUM> of the resistive element <NUM> and the lightning conductor <NUM> when the applied voltage V is at or below the threshold voltage Vth.

In this manner, during manufacture of the blade <NUM>, the electrical connection (<NUM>, <NUM>, <NUM>) of the resistive element <NUM> with the lightning conductor <NUM> for lightning protection can be already established (in particular before the thermal welding process). Nevertheless, the resistive element <NUM> can still be used during manufacture as a heating element for the thermal welding process.

<FIG> shows the electrical connections of the resistive element <NUM> during the welding process. Each of the first and second terminals <NUM>, <NUM> is electrically connected with a power source <NUM> for supplying electrical current I between the first and second terminals <NUM>, <NUM> for heating the resistive element <NUM>. In particular, the first terminal <NUM> is electrically connected by means of the electrical wire <NUM> to the lightning conductor <NUM> and the lightning conductor <NUM> is electrically connected by means of a further electrical wire <NUM> to the power source <NUM>. Further, the second terminal <NUM> is electrically connected by means of a further electrical wire <NUM> to the power source <NUM>. Since the voltage V applied to the surge protection device <NUM> during the thermal welding process is lower than the threshold voltage Vth, the surge protection device <NUM> acts as an electrical isolator in this case.

After the thermal welding process, the electrical connection between each of the first and second terminals <NUM>, <NUM> and the power source <NUM> are removed. For example, the electrical wires <NUM> and <NUM> are disconnected from the first and second terminals <NUM>, <NUM>, respectively.

The blade <NUM> may also comprise two or more of the resistive elements <NUM> electrically connected to each other in series, as shown in <FIG>. Using more than one resistive element <NUM> allows an easier heating of the resistive element even when the thermal welding process is carried out for a long bondline. Specially, since a length of the blade <NUM> can be as large as <NUM> meter and more, using several resistive elements <NUM> is advantageous.

As shown in <FIG>, different electrical connections of the resistive element <NUM> are possible depending on the number n, m of resistive elements <NUM> connected in series and the number p, q of applied surge protection devices <NUM>.

<FIG> show examples with an even number n of resistive elements <NUM>. <FIG> show examples with an odd number m of resistive elements <NUM>.

<FIG> shows an example of two resistive elements 125a, 125b connected with each other in series at their neighboring terminals 132a, 131b.

For lightning protection during operation of the wind turbine <NUM>, a first resistive element 125a is electrically connected at its first terminal 131a via an electrical wire 133a to the lightning conductor <NUM>. Further, the neighboring terminals 132a, 131b of the first and second resistive elements 125a, 125b (i.e. the second terminal 132a of the first resistive element 125a and the first terminal 131b of the second resistive element 125b) are electrically connected via a common surge protection device <NUM> to the lightning conductor <NUM>. Furthermore, the second resistive element 125b is electrically connected at its second terminal 132b via an electrical wire 133b to the lightning conductor <NUM>. These electrical connections are, in particular, established before the thermal welding process.

For thermal welding, additionally, the lightning conductor <NUM> is electrically connected by means of an electrical wire <NUM> to the power source <NUM>. Further, the neighboring terminals 132a, 131b of the first and second resistive elements 125a, 125b are connected by a common electrical wire <NUM> to the power source <NUM>.

The surge protection device <NUM> acts as isolator for the voltage applied by the power source <NUM> (e.g., less than <NUM> V). Hence, an electrical current I is flowing from the power source <NUM> via the electrical wire <NUM>, the lightning conductor <NUM>, the electrical wire 133a, the first resistive element 125a and the electrical wire <NUM> back to the power source <NUM>. Thereby, the first resistive element 125a is heated.

Furthermore, an electrical current I is flowing from the power source <NUM> via the electrical wire <NUM>, the lightning conductor <NUM>, the electrical wire 133b, the second resistive element 125b and the electrical wire <NUM> back to the power source <NUM>. Thereby, the second resistive element 125b is heated.

Advantageously, for two resistive elements 125a, 125b only one surge protection device <NUM> is required.

<FIG> shows an example of four resistive elements 225a, 225b, 225c, 225d connected with each other in series at their respective terminals. In this case two surge protection devices 234a, 234b and three electrical wires 233a, 233b, 233c are used for electrically connecting the resistive elements 225a, 225b, 225c, 225d to the lightning conductor <NUM>.

Advantageously, for four resistive elements 225a, 225b, 225c, 225d only two surge protection devices 234a, 234b are required.

In particular, in the examples of <FIG>, the number of resistive elements 125a, 125b, 225a-225d is even and the number p of required surge protection devices <NUM>, 234a, 234b fulfills the equation p = (n / <NUM>).

<FIG> show examples for an even number n of resistive elements 325a, 325b, 425a-425d for which the number p of required surge protection devices 334a, 334b, 434a-434c is an odd number fulfilling the equation p = (n / <NUM>) + <NUM>.

In the example of <FIG>, for lightning protection during operation of the wind turbine <NUM>, a first resistive element 325a is electrically connected at its first terminal 331a via a surge protection device 334a to the lightning conductor <NUM>. Further, the neighboring terminals 332a, 331b of the first and second resistive elements 325a, 325b are electrically connected via a common electrical wire <NUM> to the lightning conductor <NUM>. Furthermore, the second resistive element 325b is electrically connected at its second terminal 332b via another surge protection device 334b to the lightning conductor <NUM>. These electrical connections are, in particular, established before the thermal welding process.

For thermal welding, additionally, the power source <NUM> is connected by means of an electrical wire <NUM> to the lightning conductor <NUM>. Further, the first terminal 331a of the first resistive element 325a is electrically connected by means of an electrical wire 338a to the power source <NUM>. Furthermore, the second terminal 332b of the second resistive element 325b is connected by an electrical wire 338b to the power source <NUM>.

In comparison to the case of <FIG>, for the electrical connection of <FIG> two surge protection devices 334a, 334b are required for two resistive elements 325a, 325b.

<FIG> shows an example of four resistive elements 425a, 425b, 425c, 425d connected in series for which three surge protection devices 434a, 434b, 434c and two electrical wires 433a, 433b are used for electrically connecting the resistive elements 425a, 425b, 425c, 425d with the lightning conductor <NUM>.

<FIG> show examples with an odd number m of resistive elements 525a-525c and 625a-625c. In this case, the number q of required surge protection devices is an even number fulfilling the equation q = [(m - <NUM>) / <NUM>] + <NUM>.

In the example of <FIG>, for lightning protection, three resistive elements 525a, 525b, 525c are electrically connected to the lightning conductor <NUM> using two surge protection devices 534a, 534b and two electrical wires 533a, 533b.

Furthermore, for thermal welding in addition three electrical wires <NUM>, 538a, 538b are used as illustrated in <FIG>.

The example of <FIG> is a variant of the example of <FIG> with a different arrangement of the surge protection devise 634a, 634b. However, the number of used resistive elements 625a, 625b, 625c and the number of used surge protection devise 634a, 634b is the same as for <FIG>.

To conclude, the resistive elements which were used for the welding process and are left in the blade <NUM> as a remnant of the welding process are integrated into the lightning protection system of the blade <NUM>. Hence, flashovers during lightning between the resistive elements and the lightning conductor <NUM> can be prevented. In particular, in the case of high voltages at the lightning conductor <NUM> caused by a lightning strike of the blade <NUM>, the surge protection devices each open a pathway for the lightning current to flow via the resistive elements. Hence, large voltage differences between the resistive elements and the lightning conductor <NUM> are prevented.

Moreover, as the electrical connection between the resistive elements and the lightning conductor <NUM> are advantageously installed before the welding process for joining the blade components, they can be easier installed.

In the following, a method for manufacturing a wind turbine blade is described with reference to <FIG>.

In a first step S1 of the method a first and a second blade component (for example, the shear web <NUM> and the upper shell <NUM>, <FIG>) are arranged such that they overlap with each other in an overlap region <NUM> (<FIG>). Further, a resistive element <NUM> is arranged between the first and second blade components <NUM>, <NUM> in the overlap region <NUM>. The resistive element <NUM> has a first and a second terminal <NUM>, <NUM> (<FIG>). Furthermore, a lightning conductor <NUM> is arranged such that it is electrically connected with each of the first and second terminals <NUM>, <NUM>, wherein the lightning conductor <NUM> is electrically connected to one of the first and second terminals <NUM>, <NUM> via a surge protection device <NUM>.

In a second step S2 of the method, the first and second blade components <NUM>, <NUM> are connected to each other by thermal welding. Thermal welding includes supplying an electrical current I between the first and second terminals <NUM>, <NUM> of the resistive element <NUM> for heating the resistive element <NUM>.

In particular, each of the first and second terminals <NUM>, <NUM> is electrically connected with a power source <NUM> for supplying the electrical current I between the first and second terminals <NUM>, <NUM>. Further, a voltage applied by the power supply (e.g., <NUM> V or less) is at or below a threshold voltage Vth of the surge protection device <NUM> (e.g., <NUM> kV or more). Hence, the surge protection device <NUM> provides an electrical isolation between the one of the first and second terminals <NUM>, <NUM> of the resistive element <NUM> and the lightning conductor <NUM>. In addition, the electrical current I for heating the resistive element <NUM> is supplied through the electrical connection between the other one of the first and second terminals <NUM>, <NUM> of the resistive element <NUM> and the lightning conductor <NUM>.

In a third step S3 of the method, the electrical connection between each of the first and second terminals <NUM>, <NUM> and the power source <NUM> is removed.

Claim 1:
A wind turbine blade (<NUM>), comprising:
a first and a second blade component (<NUM>, <NUM>) connected with each other in an overlap region (<NUM>) by thermal welding,
a resistive element (<NUM>) arranged between the first and second blade components (<NUM>, <NUM>) in the overlap region (<NUM>) as a remnant of the thermal welding, characterized by the resistive element (<NUM>) having a first and a second terminal (<NUM>, <NUM>),
a lightning conductor (<NUM>) electrically connected with each of the first and second terminals (<NUM>, <NUM>), and
a surge protection device (<NUM>), wherein one of the first and second terminals (<NUM>, <NUM>) is electrically connected with the lightning conductor (<NUM>) via the surge protection device (<NUM>) .