Lightning current transmission system for wind turbines

Abstract

A lightning current transmission system in a wind turbine between a metal band located at the root of each blade and a metal ring located at the nacelle through a lightning current transmission element comprising a conductive portion, an insulating portion and a supporting unit to be joined to the rotor hub. The metal band and the metal ring are configured with protruding parts extended towards the lightning current transmission element. The conductive portion of the lightning current transmission element comprises first and second receptors mounted on a base plate at different heights and oriented in a direction pointing, respectively, to the protruding parts of the metal band and the metal ring.

Claims

1. A lightning current transmission system between the blades (10) and a nacelle (13) of a wind turbine, comprising: a metal band (18) located at a root of each blade (10) that receives lightning currents from one or more blade lightning current conductors located inside of each blade (10); a metal ring (12) located at the nacelle (13) that transmits lightning currents to one or more lightning current conductors to drive the lightning currents to earth; a lightning current transmission element (33) for transmitting lightning currents from the metal band (18) of each blade (10) to the metal ring (12), comprising a conductive portion (35), an insulating portion (37), and supporting means (30) to be joined to a rotor hub (21); wherein: the metal band (18) of each blade (10) and the metal ring (12) are configured with protruding parts (61, 63) extended towards the lightning current transmission element (33); the conductive portion (35) of the lightning current transmission element (33) comprises first and second receptors (47, 47) mounted on a base plate (41) at different heights and oriented in a direction pointing, respectively, to the protruding parts (61, 63) of the metal band (18) and the metal ring (12); the base plate (41) comprises a pair of slotted holes (43, 43) disposed separately at different heights on the base plate (41) and a pair of circular holes (45, 45), each circular hole of the pair of circular holes (45, 45) being disposed next to a center of each slotted hole of the pair of slotted holes (43, 43) of the base plate (41); each of the receptors (47, 47) comprises a slotted hole (49, 49); and each of the receptors (47, 47) is mounted on the base plate (41) with a first fastener (51) positioned on each of the circular holes (45, 45) of the base plate (41) and on an end of each of the slotted holes (49, 49) of each of the receptors (47, 47), and with a second fastener (53) positioned on each of the slotted holes (43, 43) of the base plate (41) and on each slotted hole of the slotted holes (49, 49) of the receptors (47, 47).

2. A lightning current transmission system according to claim 1, wherein the metal band (18), the metal ring (12), and the lightning current transmission element (33) are arranged with the first receptor (47) placed at a distance d1 of the protruding part (61) of the metal band (18) comprised between 2-10 mm and with the second receptor (47) placed at a distance d2 of the protruding part (63) of the metal ring (12) comprised between 5-35 mm.

3. A lightning current transmission system according to claim 1, wherein: the base plate (41) has a rectangular shape and a thickness of at least 8 mm; the receptors (47, 47) have a rectangular shape with an area of at least 100 mm.sup.2 and a thickness of at least 3 mm.

4. A lightning current transmission system according to claim 1, wherein the metal band (18) of each blade (10) and the metal ring (12) have an L-shaped configuration being one its branches joined to, respectively, the root of a blade (10) or the nacelle (13) and being the other branch a protruding part (61, 63) extended towards the lightning current transmission element (33).

5. A lightning current transmission system according to claim 3, wherein the protruding parts (61, 63) of the metal band (18) of each blade (10) and the metal ring (12) have a planar configuration.

6. A wind turbine with a lightning current transmission system according to claim 1.

7. A lightning current transmission system according to claim 2, wherein the metal band (18) of each blade (10) and the metal ring (12) have an L-shaped configuration being one its branches joined to, respectively, the root of a blade (10) or the nacelle (13) and being the other branch a protruding part (61, 63) extended towards the lightning current transmission element (33).

8. A lightning current transmission system according to claim 3, wherein the metal band (18) of each blade (10) and the metal ring (12) have an L-shaped configuration being one its branches joined to, respectively, the root of a blade (10) or the nacelle (13) and being the other branch a protruding part (61, 63) extended towards the lightning current transmission element (33).

9. A wind turbine with a lightning current transmission system according to claim 2.

10. A wind turbine with a lightning current transmission system according to claim 3.

11. A wind turbine with a lightning current transmission system according to claim 4.

12. A wind turbine with a lightning current transmission system according to claim 5.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic sectional lateral view of a wind turbine with a lightning current transmission system and

(2) FIG. 2 in an enlarged view of the circled area of FIG. 1.

(3) FIG. 3 is a schematic lateral view of a lightning current transmission element illustrating an embodiment of the invention and

(4) FIGS. 4a and 4b are schematic plan views of the base plate and a receptor of its conductive portion.

(5) FIGS. 5a and 5b are schematic lateral view of alternative configurations of the lightning current transmission element.

(6) FIG. 6 is a schematic perspective view of a lightning current transmission system illustrating an embodiment of the invention.

(7) FIGS. 7a and 7b are schematic views of the equipotential lines along, respectively a flat electrode and an elongated electrode.

(8) FIGS. 8a and 8b are schematic views of the electrical field in a gap of a lightning current transmission system in, respectively, a known system and in an embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

(9) In the embodiment illustrated in the Figures, the lightning current transmission system comprises: A metal band 18 in each blade with a protruding part 61 (preferably with a planar configuration) extended towards the lightning current transmission element 33. A metal ring 12 with a protruding part 63 (preferably with a planar configuration) extended towards the lightning current transmission element 33. A lightning current transmission element 33 having a conductive portion 35, an insulating portion 37 and a supporting portion 39 through which is joined to the rotor hub.

(10) The conductive portion 35 comprises a base plate 41 configured with two slotted holes 43, 43 located in its borders at different sides and heights and two circular holes 45, 45 located in front of the center of the slotted holes 43, 43 and two receptors 47, 47 configured with a slotted hole 49, 49.

(11) The receptors 47, 47 are joined to the base plate 41 by means of first fasteners 51 arranged on the circular holes 45, 45 of the base plate 41 and a cooperating slotted hole 49, 49 of the receptors 47, 47 and second fasteners 53 arranged on cooperating slotted holes 43, 43; 49, 49 of, respectively the base plate 41 and the receptors 47, 47.

(12) That configuration allows that the receptors 47, 47 can be mounted at a different height in the base plate 41 and oriented in different directions to place them in a suitable location to cooperate with the protruding parts 61, 63 of the metal band 18 and the metal ring 12 for the lightning current transmission between them (see, particularly, FIGS. 5a and 5b).

(13) The conductive portion 35 shall be made of a metallic material with a high fusion point such as copper, stainless steel or tungsten and have a minimum thickness of 6 mm by mechanical reasons and assuring a minimum cross-section of 50 mm.sup.2.

(14) The insulating portion 37 shall be made of a material such as nylon or other suitable plastic. In an embodiment it has a length of 200 mm.

(15) The receptors 47, 47 can have a rectangular shape (with, for instance, a width of 20-40 mm and a thickness of 3-10 mm) with a minimum area of 100 mm2 and a minimum thickness of 3 mm.

(16) The first receptor 47 shall be placed at a distance d1 of the protruding part 61 of the metal band 18 comprised between 2-10 mm and the second receptor 47 shall be placed at a distance d2 of the protruding part 63 of the metal ring 12 comprised between 5-35 mm to ensure the flashover.

(17) In the embodiment illustrated in FIG. 6 the metal band 18 and the metal ring 12 have an L-shaped configuration being one of its branches the above-mentioned protruding parts 61, 63 in order to reduce the breakdown voltage in the four electrodes of the lightning current transmission system.

(18) Near the electrodes, the distribution of the equipotential lines of the electric field depends on electrode geometry. If the electrode 55 is flat (see FIG. 7a) the distribution of the equipotential lines is uniform along the entire electrode (the spatial variation of the electric potential V is constant) while if it the electrode 57 is elongated (see FIG. 7b) the spatial variation of the electric potential V is reduced in the area close to the electrode. This makes that the electric field is amplified because E=V/x, being x the variation of the distance in the X axis.

(19) So, comparing the distribution of the equipotential lines of the electric field between an end 59 of the first bar and the metal band 18 in the lightning current transmission system described in ES 2 265 776 B1 (see FIG. 8a) and in the lightning current transmission system of the invention (see FIG. 8b) it can be observed that the electric field is amplified both in the receptor 47 and in the protruding part 61 of the metal band 18 (and similarly in the receptor 47 and in the protruding part 63 of the metal ring 12). Consequently the breakdown voltage is reduced. It is estimated that, keeping the same distances d1, d2 between electrodes, the breakdown voltage can be reduced between 15% and 50%.

(20) Although the present invention has been described in connection with various embodiments, it will be appreciated from the specification that various combinations of elements, variations or improvements therein may be made, and are within the scope of the invention as defined by the appended claims.