MICROWAVE ABSORBING COMPOSITE FOR TURBINE BLADE APPLICATIONS

Abstract

The invention provides a composite laminate comprising an outer, an intermediate and an inner section comprising, respectively, first layers of composite material and one or more functional layers having a printed circuit for absorbing the electromagnetic radiation incident on the composite laminate; second layers of composite material; a conducting layer contiguous to the intermediate section and third layers of composite material. The values of the resistivity of the functional layer and the thickness of the intermediate section are comprised in predefined ranges for the attenuation of the reflection of electromagnetic radiation of the composite laminate in the S or X bands up to a peak of 20 dB. The invention also refers to manufacturing methods of the composite laminate (11) and to wind turbine blades including the composite laminate.

Claims

1. A composite laminate (11) comprising: an outer section (15) comprising first layers (21) of composite material and one or more functional layers (31) having a printed circuit for absorbing the electromagnetic radiation incident on the composite laminate (11); an intermediate section (17) comprising second layers (23) of composite material; an inner section (19) comprising a conducting layer (41) contiguous to the intermediate section (17) and third layers (25) of composite material; wherein the values of the resistivity of the functional layer (31) and the thickness of the intermediate section (17) are comprised in predefined ranges for the attenuation of the reflection of electromagnetic radiation of the composite laminate (11) in the S or X bands up to a peak of 20 dB.

2. The composite laminate (11) of claim 1, wherein: the resin of the composite material of the first, second and third layers (21, 23, 25) is a polymer or an epoxy material; the resistivity of the functional layer (31) is comprised between 40-60 /sq and the thickness of the intermediate section (17) is comprised between 9-11 mm.

3. The composite laminate (11) of claim 2, wherein the thickness of the intermediate section (17) is comprised between 10-11 mm.

4. The composite laminate (11) of claim 3, wherein the fibers of the composite material of the first, second and third layers (21, 23, 25) are glass fibers or carbon fibers.

5. The composite laminate (11) of claim 2, wherein the intermediate section (17) comprises ceramic particles (29) incorporated within it.

6. The composite laminate of claim 5, wherein the ceramic particles (29) are silica particles of sizes ranging between 20-500 nm.

7. A manufacturing method of a composite laminate (11) comprising: an outer section (15) comprising first layers (21) of composite material and one or more functional layers (31) having a printed circuit for absorbing the electromagnetic radiation incident on the composite laminate (11); an intermediate section (17) comprising a plurality of second layers (23) of composite material; an inner section (19) comprising a conducting layer (41) contiguous to the intermediate section (17) and one or more third layers (25) of composite material; wherein the values of the resistivity of the functional layer (31) and the thickness of the intermediate section (17) are comprised in predefined ranges for the attenuation of the reflection of electromagnetic radiation of the composite laminate (11) in the S or X band up to a peak of 20 dB; the method comprising the steps of: providing said first, second and third layers (21, 23, 25) as pre-peg layers; subjecting the ensemble of the outer, intermediate and inner sections (15, 17, 19) to a cycle of pressure and temperature to consolidate the composite laminate (11).

8. A manufacturing method of a composite laminate (11) comprising: an outer section (15) comprising first layers (21) of composite material and one or more functional layers (31) having a printed circuit for absorbing the electromagnetic radiation incident on the composite laminate (11); an intermediate section (17) comprising a plurality of second layers (23) of composite material; an inner section (19) comprising a conducting layer (41) contiguous to the intermediate section (17) and one or more third layers (25) of composite material; wherein the values of the resistivity of the functional layer (31) and the thickness of the intermediate section (17) are comprised in predefined ranges for the attenuation of the reflection of electromagnetic radiation of the composite laminate (11) in the S or X band up to a peak of 20 dB. the method comprising the steps of: providing said first, second and third layers (21, 23, 25) as dry layers; infusing resin; subjecting the ensemble of the outer, intermediate and inner sections (15, 17, 19) to a cycle of pressure and temperature to consolidate the composite laminate (11).

9. Wind turbine blade having at least one component being made with a composite laminate (11) comprising: an outer section (15) comprising first layers (21) of composite material and one or more functional layers (31) having a printed circuit for absorbing the electromagnetic radiation incident on the composite laminate (11); an intermediate section (17) comprising second layers (23) of composite material; an inner section (19) comprising a conducting layer (41) contiguous to the intermediate section (17) and third layers (25) of composite material; wherein the values of the resistivity of the functional layer (31) and the thickness of the intermediate section (17) are comprised in predefined ranges for the attenuation of the reflection of electromagnetic radiation of the composite laminate (11) in the S or X bands up to a peak of 20 dB.

10. The wind turbine blade of claim 9, wherein: the resin of the composite material of the first, second and third layers (21, 23, 25) is a polymer or an epoxy material; the resistivity of the functional layer (31) is comprised between 40-60 /sq and the thickness of the intermediate section (17) is comprised between 9-11 mm.

11. The wind turbine blade of claim 10, wherein the thickness of the intermediate section (17) is comprised between 10-11 mm.

12. The wind turbine blade of claim 11, wherein the fibers of the composite material of the first, second and third layers (21, 23, 25) are glass fibers or carbon fibers.

13. The wind turbine blade of claim 10, wherein the intermediate section (17) comprises ceramic particles (29) incorporated within it.

14. The wind turbine blade of claim 13, wherein the ceramic particles (29) are silica particles of sizes ranging between 20-500 nm.

15. The wind turbine blade of claim 9 wherein said component is a shell of the blade.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0010] FIGS. 1, 2 and 3 are schematic sectional views of embodiments of a composite laminate with enhanced microwave absorption according to the invention.

[0011] FIG. 4 shows photos of two samples of a composite laminate with enhanced microwave absorption.

[0012] FIG. 5 shows diagrams Absorption (dB) vs Frequency (GHz) for samples #1 and #2 of a composite laminate with enhanced microwave absorption.

[0013] FIG. 6 shows diagrams Absorption (dB) vs Frequency (GHz) for samples #3 and #4 of a composite laminate with enhanced microwave absorption.

DETAILED DESCRIPTION OF THE INVENTION

[0014] The invention mainly refers to a laminate which is to be used, for example, as the outer part of the whole laminatewhether a monolithic laminate or a sandwich laminateof a component of a wind turbine blade.

[0015] In reference to FIG. 1, the basic structure of an embodiment of a laminate 11 developed to absorb the microwave radiation in S and X band comprises: an outer section 15 formed by composite layers 21 and one or more functional layers 31; an intermediate section 17 formed by composite layers 23; and an inner section 19 formed by at least one electrically conducting layer 41 and composite layers 25.

[0016] Composite layers 21, 23, 25 are made up of resin materials and fibers with high mechanical properties that form hard sheets attached to each other after curing providing the required mechanical strength (hardness, tensile strength, etc.). The composite layers 21, 23, 25 may comprise glass fiber or carbon fiber cloths and epoxy or polymeric resin. They may also comprise other fibers such as aramids, basaltic fibers or boron fibers as well as polymeric resins such as polyesters or vinyl esters.

[0017] The functional layer 31 is made up of glass fibers and conducting ink (carbon based) and is placed between the composite layers 21, 23. [0018] The electrically conducting layer 41a sheet, mesh or foil made up of, for example, aluminum, copper or carbonis placed between the composite layers 23, 25.

[0019] Additional Features of the Laminate 11

[0020] a) To obtain the attenuation over broad spectrum of frequencies, functional grading of the conducting pattern is employed as shown in FIG. 2. Two functional layers 31 with different functionality, i.e. different pattern or different resistivity values, are employed at more than one location in the laminate. Such incorporation creates more than one capacitance value leading to broad band attenuation.

[0021] b) Broad band attenuation is critically important for the practical applications of the laminates of the invention to wind turbine blades. The size of the blade may be higher than 80 m (in length). From the manufacturing point of view above said layers are to be joined together for form a component of a large blade (for example a shell). During this process the variation in the separation, distance, resistivity, flatness and smoothness of the functional layer 31 would affect the attenuation results. Design shown in FIG. 2 is forgiving to the errors and variations in manufacturing process.

[0022] c) FIG. 3 shows the incorporation of ceramic nanoparticles (with suitable permittivity values) within the laminate 11 that has two main effects on the properties of the laminate. First it results in increase of the permittivity values, which reduces the distance between the functional layer 31 and the conducting layer 41 allowing flexibility in the manufacturing process, particularly at the complex shapes such as curves of leading edge where the separation distance is more difficult to control due to the limitations of the manufacturing process of highly curved composite laminates. Secondly, addition of specific ceramic particles, such as silica nanoparticles, improves the compression toughness/strength of the laminate 11 and may also led to reduced number of layers of carbon fibers, saving the cost and weight. The location of the ceramic particles could be anywhere within the laminate 11. Typically, SiO.sub.2 nanoparticles of sizes ranging from 20-500 nm are employed as fillers. Further, the quantity of ceramic fillers may vary from 0 to 20% by weight.

[0023] Manufacturing Method of the Laminate 11

[0024] In an embodiment, the manufacturing method comprises the following steps:

[0025] a) The composite layers 21, 23, 25provided as pre-peg layers, the functional layer 31 and the conducting layer 41 are arranged in the manner shown in FIG. 1. It is ensured that the layers are made completely flat without wrinkles and air gaps. The functional layer 31 is prepared printing a conducting pattern with an ink with an appropriate resistivity on a fiber glass cloth using a semi-automatic screen printer. The printed patter is characterized by 4-point resistivity measurement.

[0026] b) The arrangement of layers 21, 31, 23, 41, 25 is enclosed in a vacuum bag and a vacuum of 0.9 ATM is maintained with the help of a compressor.

[0027] c) The whole arrangement is kept in an oven and the temperature is set at 900 with the maximum ramping rate the oven possesses from the room temperature (25).

[0028] d) After two hours of heating the vacuum pump is switched off and the temperature of the oven is set at 25.

[0029] e) The laminate is taken out from the oven and the air cools it to room temperature.

[0030] The laminate 11 can also be manufactured using infusion techniques providing the first, second and third layers 21, 23, 25 as dry layers, infusing resin and subjecting the ensemble of the outer, intermediate and inner sections 15, 17, 19 to a cycle of pressure and temperature to consolidate the composite laminate 11.

[0031] Microwave Absorption of the Laminate

[0032] Experimental tests carried out with samples of the laminate (see FIG. 4) have shown that the critical parameters on the absorption of the S and X bands are on the one hand the resistivity of the functional layer 31 and on the other hand the separation between the functional layer 31 and the conducting layer 41.

[0033] The effect of the variation of the resistivity of the functional layer is shown in FIG. 5 for samples #1, #2 having functional layers 31 with a resistivity of, respectively, 47.74 and 57.53 /sq: an increase in the resistivity of the functional layer 31 shifts the absorption towards higher frequencies and lowers the degree of attenuation. The resistivity of the functional layer 31 can be changed by the amount of ink deposited on the glass fiber cloth.

[0034] The effect of the separation between the functional layer 31 and the conducting layer 41 is shown in FIG. 6 for samples #3, #4 having a separation of, respectively, 11.46 mm and 9.43 mm: an increase in separation between the functional layer 31 and the conducting layer 41 shifts the absorption towards the lower frequencies and improves the degree of attenuation. Said separation is controlled by the number of layers 23.

[0035] From the experimental work carried out it can be concluded that the absorption of wavelength in S and X bands requires a specific pair of values of the separation between the functional layer 31 and the conducting layer 41 and the resistivity of the functional layer 31 comprised in, respectively, the following ranges: 9.0-11.0 mm (preferably 10.0:11.0 mm); 40-60 /sq.

Advantages

[0036] The weight added by the functional layer 31 and the conducting layer 41 to a wind turbine blade is minimal compared with the weight of a radar absorbing coating. [0037] The laminate of the invention is specifically addressed to the absorption of the S and X bands which are the critical bands for wind turbines. [0038] The laminate of the invention allows attenuation in reflection as well as transmission up to a peak of 20 dB. [0039] The laminate of the invention is highly robust and forgiving to the manufacturing errors and variations. [0040] The laminate of the invention can be manufactured with 3D features and therefore can be adapted to the shape of a wind turbine blade which is critically important to its performance.

[0041] 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.