GB2354476A

GB2354476A - A mould tool for resin transfer moulding

Info

Publication number: GB2354476A
Application number: GB9915505A
Authority: GB
Inventors: Alan Roger Harper; Steven Leonard Williams
Original assignee: Individual
Current assignee: Individual
Priority date: 1999-07-03
Filing date: 1999-07-03
Publication date: 2001-03-28
Also published as: GB9915505D0; WO2001002146A1; EP1198332A1

Abstract

A mould tool for resin transfer moulding and a method of using the mould tool are disclosed; the mould tool 10 having first and second members defining the face 30 and contra 11 mould surfaces which when in a juxtaposed relationship the members define a mould region R, wherein at least one of the members is provided with a channel (13 of Fig 1) opening into the interior of the mould region R, an elastomeric member 18 being located in the channel (13 of Fig 1) which defines a flexible wall 22 for the region R; the elastomeric member 18 being pressurisible by a duct 17 extending through the elastomeric member 18 so that the flexible wall 22 may be varied from a first position where the wall 22 forms a runner channel 24 for the mould surface 12 and a second position where the flexible wall 22 is flush with the mould surface 12.

Description

2354476 IMPROVED LIQUID POLYMER FLOW

This invention relates to improved liquid polymer flow. It is particularly concerned with improved liquid polymer flow in the field of resin transfer moulding ('RTM').

RTM is a method of moulding composite parts of polymer and fibre which is now being adopted widely by moulders throughout the world as a cleaner and more efficient manufacturing method over traditional open moulding techniques such as hand lay-up or spray deposition. The RTM method is now a preferred route for the manufacture of composite moulded parts both large and small. It is applicable to a wide spectrum of products ranging from general industrial mouldings to advanced composite aerospace mouldings.

Significant development has taken place to optimise the RTM process in reducing production cycle times. One major area of optimisation involves the actual speed of mixed resin flow into the fibre pack which is held within a closed RTM mould. The main method of increasing resin flow is to increase the injection pressure. However this has major disadvantages which include the following. a) The RTM process is regarded as a low pressure process (that is to say below 7 bar). Conventionally RTM mould tools are made from cost effective reinforced composite materials rather than block metal, alurninium/ steel. Increasing polymer input pressures beyond the normally accepted low maximum level causes composite moulds to deflect with the consequent production of inaccurately moulded parts. b) Higher injection pressures result in faster polymer injection speeds and higher velocity at the injection point. This can give rise to fibre pack movement or washing' at or around the injection point and increase the likelihood of product rejection.

The purpose of this invention is to enable the combination of higher injection flow, rates without the disadvantages outlined above and provides an improvement on traditional methods currently employed.

2 Traditionally the accepted method of providing for increased flow of liquid polymer into a closed mould within which the dry fibre pack awaits infusion is to provide a fresin runner' in one half of the mould faces. This is a recess in the surface of the mould having a cross section into which compacted dry fibre will not readily fit so ensuring that the channel remains open throughout the injection process to provide a clear path for flowing injected polymer. By positioning the mould injection point to communicate with this open channel the injected resin, upon first entering the mould sees an open, high permeability, flow path in which to flow and from which to permeate into and around the fibre pack. In mould design such a resin flow channel is sometimes termed a'mould sprue runner'.

A flow channel design has geometric limitations within the overall mould tool geometry so that a flowing resin front must eventually be forced to pass through a lower permeable fibre pack without finding a shortcut to the mould cavity final fill points. This can result in some of the fibre pack being left dry or only partially impregnated.

A conventional flow channel shape incorporated in a mould surface will result in a moulded part, on removal after cure from the mould, having a resin rich moulded line upon its surface. For many products this is unacceptable.

The present invention serves to provide a low permeable channel within the mould surface while avoiding the generation of resin rich moulded line.

According to the present invention there is provided a mould tool for resin transfer moulding having a first member defining a face mould surface and a second member defining a contra mould surface whereby, when in a juxtaposed working relationship, the first and second members form a mould region; wherein there is provided in at least one of members for the mould surface defined by the member; a channel with a first cross section including a region opening into the interior of the mould region; and 3 an elastomeric member located in and by the channel defining in part a flexible wall for the region; a pressurisible duct extending through the elastomeric member; a passage extending from the interior of the duct to a location outside the mould member whereby the pressure within the duct can be varied to cause displacement of the flexible wall between a first position wherein the wall is drawn inwardly to define and maintain a runner channel in the mould surface of the member; and a second position wherein the wall is released from forming the channel and serves to provide a wall for the mould surface of the member conforming substantially to that of the mould surface adjacent the channel. Typically the channel has opening into it in a location not occupied by the elastomeric member an injection port whereby liquid resin can be injected into the mould.

An exemplary embodiment of the invention will now be described with reference to the accompanying drawings of a part of a moulding machine used for resin transfer moulding of which; Figure 1 shows a sectional elevation of a first member defining a mould surface; Figure 2 shows a sectional elevation of another part of the first member; and Figure 3 shows the assembly of Figure 3 in use in combination with a second member defining a mould surface.

FIGURES 1 AND 2 Mould 10 includes a contra mould member 11 in surface 12 of which is located a channel 13 which is of rectangular section recess with flat walls 14, 15, 15 and an open periphery 17. The channel 13 extends for a major part of the length of the contra mould member 11. The channel 13 helps to facilitate the ready distribution of liquid polymer during its injection into the mould 10 as will be described hereafter with reference to Figure 3.

An elastomeric member 18 is located in and by the channel 13. The elastomeric member 18 has side walls 19, 20, 21 which seat on and are located by, respectively, 4 walls 14, 15, 15 of the channel 13. Side wall 22 of the member 18 serves as a flexible wall closing open periphery 17of the channel 13.

The member 18 incorporates a duct 17 extending the length of the member but with either end of the duct 17 closed so that the duct 17 can serve as a chamber whose volume can be varied by varying the pressure of fluid within the duct 17. To this end there is provided (Figure 1) a passage 23 through member 11 to the interior of the duct 17 from a location outside the mould member 11 where means are provided to pressurise the duct 17 to cause displacement of the flexible wall 22 between a first position (as shown in Figure 2) wherein the wall 22 is drawn inwardly to define and maintain a runner channel 24 in the mould surface of the member 11; and a second position (as shown in Figure 1) wherein the wall 22 is caused to revert to a form a wall conforming substantially to that of the mould surface 12 in the vicinity of the channel 13.

The elastomeric member 18 can be manufactured in unlimited lengths. A closed mould matching set is readily designed and fabricated to accept the member in the mould face and the path of the or each channel can be selected to provide for an optimised path for polymer flow into the mould.

The member 18 is glued to the three walls 19, 20, 21 of the channel 13 so as to secure the member 18 firmly into position with the exposed face 22 flush with the surrounding mould surface 12. A suitable mould resin injection port is designed and positioned either at one end of channel 13 or some way along its length with separate elastomeric members corresponding to member 18 in the channel on either side of the injection port.

FIGuRE 3 In operation the mould 10 is closed and contra mould 11 is clamped shut with face mould 30 to form a mould region R. clamped together over a fibre pack F.

A vacuum is connected to the duct 17 as described in connection with Figure 1 in order to deform the member 18 to provide a flow channeOl 24 over the fibre pack F. An injection matrix is made to enter the mould 10 by way of one or more injection ports similar to that described in connection with Figures 1 and 2. The provision of the channel 24, and any available similar channels enables the incoming liquid resin to flow more readily above the fibre pack. Matrix injection continues in this way until the mould region R is full with the fibre pack F fully wetted and impregnated.

Once filling of mould region R is complete the vacuum maintaining the channel 24 is removed and replaced with gas at atmospheric or above atmospheric pressure. As a result the member 18 reverts to the form shown in Figure 2 with wall 22 conforming in level to the adjacent form of the surface 12 and the disappearance of the channel 24. As a result no channel space is left for polymer rich material to occupy[y and harden in.

In the case of the exemplary embodiment the channel 13 to receive the elastorneric member 18 is of rectangular cross section. However any convenient cross section can be used together with an elastomeric member of complementary cross section. of a) The face of the wall 22 of the elastomeric member 18 can be fabricated to give a slight outward bow so that its natural position when not subject to positive or negative pressure whilst positioned against the fibre pack F after injection is slightly positive. This is to prevent negative buckling or deformation under the residual pressure of either the liquid matrix or the fibre pack F.

The use and application of vacuum in duct 17 may not be required as the matrix injection pressure may be sufficient to deflect the member 18 to establish a sufficient size of channel providing easy priority flow of liquid matrix along the created 6 flow channel.

The invention provides a method of manufacturing a moulded article by providing in one or more of mould face surfaces in a mould a channel for a resilient member. A part of the resilient member can be displaced from a position flush with the surrounding surface of the mould face to a position retracted from the surrounding surface to provide a flow channel enabling liquid resin to readily flow across the face of, for example, a preformed fibre pack located in the mould. Prior to polymerisation the resilient member is caused to revert to its flush state so as to ensure the resulting moulding arises from a mould from which the flow channel has effectively been removed.

Claims

CLAIMS 1 A mould tool for resin. transfer moulding having a first member defining a face mould surface and a. second member defining a- contra mould surface whereby, when in a juxtaposed working relationship, the first and. second members form a mould region;'wherein there is provided in at least one of members for the mould surface defined by the member; a channel with a first cross section including a region opening into the interior of the mould region; and an elastomeric member located in and by -the channel defining in part a flexible wall for the region; a pressurisible duct extending through th.e elastomeric member; a passage extending from the interior of the duct to a location outside the mould member whereby the pressure within the duct can be varied to cause displacement of the flexible wall between. a first position wherein the wall is drawn. inwardly to define and maintain a runner channel in the mould surface of the member; and a second position wherein the wall is released from forming the channel and serves to provide a wall for the mould surface of the member conforming substantially to that of the mould surface adjacent the channel.

1

2 A. mould tool as claimed in Claim 1 wherein the channel has opening into it in a location. not occupied by the elastomeric member forming an injection port whereby Rquid resin can be injected into the mould.

3 A mould tool, as hereinbefore described with reference to the accompanying drawings.

4 A method of resin transfer moulding utilising a mould comprising a first Received 30-Jun-00 17: 09 From-01855882786 To-THE PATENT OFFICE page11 member defining a face mould surface and a second member defining a contra mould surface whereby, when in. a. juxtaposed working relationship, the members serve to bound a mould region comprising the steps of: providing in the first member defining the face mould surface or the second member defining the contra mould surface or in each a channel incorporath-ig EaL elastorneric member (which is hollow so as to provide an intemal duct) the elastomeric member extending over a path in the or each surface with a face of the elastomeric member directed towards the mould region; providing f or the face of the elastomeric member to be moved rel-ative to the channel betweena first state where the face is in a first configuration conforming to the surrounding region of the mould surface adjacent the channel; and a second state where the face is in a second configuration retracted from the first into the channel so as to increasc the volume of the mould region and thereby providing a channel through which mobile material (such as liquid resin) in the vicinity of the elastameric member can flow.

A method of resin transfer moulding as clairnedin. Claim 4 wherein the step of providing for the face to move from the first state to the second state is caused by applying a vacuum to the internal duct. 6 A method of resin transfer moulding as claimed in Claim 4 or 5 wherein -the step of providing for the face to move from the second state to the first state is caused by applying an overpressure to the internal duct. 7 A moulded article produced by means of a mould tool as claimed. in Claim I or Claim 2. 8 A moulded article produced''by means of a method as claimed in Claims 3,4,5 or 6.

Received 30-Jun-00 17: 09 From-OISSS882790 To-THE PATENT OFF ICE Page12