This specification is based upon and claims the benefit of priority from UK Patent Application Number 1819769.9 filed on Dec. 4, 2018, the entire contents of which are incorporated herein by reference.
The present disclosure concerns apparatus and methods for reinforcing composite materials by insertion of reinforcement pins.
Insertion of reinforcement pins, commonly known as z-pins, is a way of reinforcing composite laminates to reduce the risk of delamination by adding through-thickness strength. Insertion of a reinforcement pin commonly involves a three-step process using a machine of the type illustrated in
According to a first aspect there is provided an apparatus for reinforcing a composite preform, comprising:
a carriage for introducing reinforcement pins into the composite preform, the carriage comprising a drill module, a pin feeder module and a tamper module, the carriage being translatable relative to the composite preform,
wherein the drill module and pin feeder module are exchangeable between a common actuation position on the carriage.
The apparatus may further comprise a workpiece holder for holding the composite preform. In some examples, however, a workpiece holder may not be required, for example when introducing reinforcement pins into a large composite preform, in which case the apparatus may be positioned relative to the composite preform without the need for additional support. In other cases the composite preform may just need to be held in place to resist the forces applied by the drill, pin feed and tamper modules to prevent the composite preform from moving.
Exchanging the modules between a common actuation position allows for a smaller footprint for the carriage in relation to the composite preform, enabling the apparatus to introduce reinforcement pins into more complex geometries.
The carriage may comprise a nozzle.
The drill module, pin feeder module and tamper module may each be configured to actuate along a common axis through the nozzle.
At least the drill module and the pin feeder module may be movable relative to the carriage to align with the nozzle.
The nozzle may be stationary with respect to the carriage.
The carriage may be translatable relative to the composite preform in three orthogonal directions and rotatable relative to the composite preform about a first axis orthogonal to the common axis. Rotating the carriage relative to the composite preform allows pins to be inserted into the composite preform at an angle, enabling pins to be inserted in more complex geometries as well as being able to insert pins at different angles to improve the overall reinforcement capability of the pins.
The carriage may also be rotatable relative to the composite preform about a second axis orthogonal to the first axis and the common axis. Being able to rotate about two axes allows for additional freedom to direct pins in different directions into the preform.
In some examples the tamper module comprises a tamping rod actuatable through the nozzle along the common axis. In other examples the tamper module comprises a compressed air line connected to the nozzle.
In some examples the drill module and pin feeder module are linearly translatable relative to the common actuation position. In other examples the carriage comprises a rotatable carousel configured to exchange the drill module and pin feeder module between the common actuation position.
The carriage may be mounted for rotation on a support structure that is translatable along at least two orthogonal directions relative to the composite preform.
In accordance with a second aspect there is provided a method of reinforcing a composite preform using the apparatus according to the first aspect, the method comprising the steps of:
i) drilling a hole through the composite preform using the drill module at the common actuation position;
ii) exchanging the drill module for the pin feeder module;
iii) inserting a reinforcement pin through the hole using the pin feeder module at the common actuation position; and
iv) tamping the reinforcement pin in the hole using the tamper module at the common actuation position.
The method may further comprise the step of holding the composite preform on a workpiece holder prior to the step of drilling a hole.
In some examples step iii) may be carried out by linearly translating the drill module and pin feeder module. In other examples step iii) is carried out by rotating the drill module and pin feeder module.
In accordance with a further aspect, there is provided an apparatus for reinforcing a composite preform featuring an external surface, the apparatus comprising:
a carriage for introducing reinforcement pins into the composite preform through the external surface, the carriage comprising a drill module, a pin feeder module, a tamper module, and a nozzle, the carriage being rotatable relative to the composite preform,
wherein the drill module and pin feeder module are exchangeable between a common actuation position on the carriage.
In some examples the carriage may be rotatable to position the nozzle at an angle to a perpendicular of the external surface of the composite preform. In other words, the carriage may rotate to position the nozzle not perpendicularly to the external surface of the composite preform.
The nozzle may have an actuation axis, and the drill module and pin feeder module each may be configured to actuate along the actuation axis.
The carriage may be rotated to position the actuation axis not perpendicularly to the external surface of the composite preform.
In some examples, the carriage may be rotatable to position the nozzle such that the actuation axis is arranged not perpendicular to the external surface of the composite preform. In such examples, the drill module and pin feeder module each may actuate, along the actuation axis, not perpendicularly to the external surface of the composite preform.
The nozzle may be arranged in correspondence of the common actuation position.
The carriage may be translatable relative to the composite preform.
The skilled person will appreciate that, except where mutually exclusive, a feature described in relation to any one of the above aspects may be applied mutatis mutandis to any other aspect. Furthermore, except where mutually exclusive, any feature described herein may be applied to any aspect and/or combined with any other feature described herein.
Embodiments will now be described by way of example only, with reference to the Figures, in which:
In a first step, the drill module 103 is positioned relative to the laminate 101 and a hole is drilled through the laminate 101. The drill module 103 then withdraws from the laminate and the apparatus 100 translates relative to the laminate 101 to align the pin feeder module 104 with the hole in the laminate 101. This translation may occur by moving the apparatus 100 relative to a stationary workpiece holder 102 or alternatively may involve the workpiece holder 102 moving relative to a stationary apparatus 100. In a second step, the pin feeder module 104 feeds a length of rod or wire 106 into the hole. Before withdrawing from the laminate 101, a cutter 107 cuts the rod 106 to leave a predetermined length of rod in the hole to form a pin. The apparatus 100 then translates again in the x-y plane to align the tamper module 105 with the pin in the hole. In a third step, the tamper module actuates a tamper 108 to drive the pin further into the hole. The process then moves on to insert a further z-pin reinforcement in the laminate 101. In a typical laminate, a large number of pins may be inserted in this way, depending on the degree of reinforcement required. A typical required pin areal density would be around 2%, based on a physical spacing of pins of around 1.75 mm, requiring many hundreds or thousands of pins to be inserted into a panel of a typical size.
In the example apparatus 100 of
As well as being translatable relative to the laminate 201 and workpiece holder 202 in the x, y and z directions, the carriage 211 is also rotatable about an axis that is parallel to the x-y plane. This allows the apparatus 200 to insert z-pins into the laminate 201 through the external surface 201a at an angle to the perpendicular, rather than only along the z direction. The carriage 211 contains the drill module 203, pin feeder module 204 and tamper module 205, which are interchangeable between a common actuation position, so that each module can access the laminate 201 via a common nozzle 212 along an actuation axis 214. This arrangement allows pins to be delivered through a common location with the smaller footprint that allows for rotation of the carriage relative to the laminate 201. The laminate may additionally or alternatively rotate relative to the carriage 211 to align the actuation axis 214 at an angle relative to the laminate 201.
In the example shown, the nozzle 212 is translatable and rotatable relative to the laminate 201 along with the carriage 211. As the carriage 211 translates and/or rotates, the nozzle 212 and the actuation axis 214 translate in the three orthogonal x, y and z directions and/or rotate about the axis that is parallel to the x-y plane, accordingly.
The nozzle 212 may comprise a chamfered end to allow delivery of a pin at an angle while maintaining proximity to the laminate surface, allowing closer access to portions of the laminate 201 having an internal radius.
A mechanism in the carriage 211 allows the modules 203, 204, 205 to be moved to and from the common actuation position either by translation or rotation. In the example shown in
Following insertion of the feedstock rod 106 into the hole 302, the rod 106 is cut to leave a predetermined length of rod in the hole 302, forming a pin 303. The pin feeder module 204 is withdrawn and interchanged with the tamper module 205. As shown in
The tamping rod 304 preferably has an end that has a concave shaped recess 401 in an end that contacts the pin 303, which serves to locate the pin 303 on the end of the tamping rod 304, as shown in cross-section in
In an alternative example, illustrated schematically in
In the examples described above, a tamper module with a tamper rod is provided, which is interchangeable with the drill module and pin feeder module. In alternative examples, the tamper module may be provided instead by a compressed air line acting through the nozzle, as shown in schematic cross-section in
In the examples where a separate tamper module is provided, an additional step between steps 804 and 805 may be added to exchange the pin feeder module for the tamper module. In alternative examples, the tamper module may be provided by a compressed air line and an exchange is therefore not required.
It will be understood that the invention is not limited to the embodiments above-described and various modifications and improvements can be made without departing from the concepts herein. Except where mutually exclusive, any of the features may be employed separately or in combination with any other features and the disclosure extends to and includes all combinations and sub-combinations of one or more features described herein.
Number | Date | Country | Kind |
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1819769 | Dec 2018 | GB | national |
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Entry |
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Great Britain search report dated May 20, 2019, issued in GB Patent Application No. 1819769.9. |
European search report dated Apr. 17, 2020, issued in EP Patent Application No. 19207995. |
Response to Extended European Search Report from counterpart EP Application No. 19207995.2 dated April 28, 2020, filed Jun. 18, 2020, 28 pgs. |
Number | Date | Country | |
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20200171757 A1 | Jun 2020 | US |