Patent Application
20230347601
The present invention relates to a method of assembling a bicycle rim, in particular a bicycle rim of composite material. The invention further relates to a bicycle rim obtainable by such a method.
Performance bicycle rims need to be light weight, have an inherent stiffness, be durable and well balanced so that these can be used on the road, on race tracks and in off-road applications.
Composite bicycle rims are well known as light weight rims. Unfortunately, the method of manufacture of such rims leads to deficient inter-laminar shear strengths, non-ideal wall thickness leading to rims having less than the desired stiffness and strength and also rims that are comparatively unbalanced.
It should also be noted that such bicycle rims are manufactured by hand in a very time-consuming manner. Typically, it takes between 7 to 8 hours to produce one rim per hand.
For this reason, it is an object of the invention to provide an improved method and bicycle rim in which the durability and stiffness of the bicycle rim is increased and the degree of unbalance is reliably reduced. It is yet a further object of the invention to reduce the time of manufacture of such bicycle rims and to provide an at least semi-automated method of manufacture of such bicycle rims.
This object is satisfied by a method having the features of claim 1.
Such a method of assembling a bicycle rim comprises the steps of:
By using a removable mold in the form of a pattern of removable material the layers forming the bicycle rim can be ideally pressed together during the formation of the rim, so that rims can be formed with a pre-definable uniform thickness of the sidewalls of the rim. Moreover, through the use of two molds pressing the material of the rim between one another a bond between the layers of webs of fiber material can be enhanced leading to more durable and stable rims. A further benefit obtained by such a method is that the internal surface of internal spaces of the rim can be formed with a reduced desired surface roughness, this leads to a more homogenous rim, to a rim having the desired stiffness and to a rim having an improved inter-laminar shear strength.
Using composite materials, a lightweight rim can be formed for high-performance applications, said rim having the desired characteristics. By way of the method described herein the time of manufacture of the rim can typically be reduced from 7 hours to 7 to 25 minutes depending on the type of resin used to form the composite material and its time of curing. This decrease in time of manufacture is complemented by an increase in the quality of the rim obtained using the presently described method.
It should also be noted that the first temperature range is preferably a temperature range of ±3° centered about the desired first temperature. The first temperature is preferably selected between 30 and 60° C., especially between 40 and 55° C.
In this connection it should be noted that the webs of fiber material may a layer of fabric made from woven fibers that are made by interlacing two or more tows of fibers at right angles to one another. Additionally or alternatively the web of fiber material may be formed by a tow of fibers. In this connection a tow of fibers is a bunch of fibers like a yarn.
The first temperature may be used for at least one of heating the mold to aid introduction of resin into the mold, heating said mold for curing the material of said rim, and removal of the removable material of the pattern, such as a wax.
In this connection it should be noted that the one or more patterns may be used as part of a mold for a so-called resin transfer molding (RTM) process. In this case, the pattern, i.e. wax mold, may then be covered with roving following which it may be inserted into a further mold for the addition of resin and heat treatment to form the final device of composite material in a manner known per se.
At least one of the one or more patterns may be formed by three, four, five or more pattern segments that are assembled to form the at least one of the one or more patterns. Forming said one or more patterns from a plurality of pattern segments makes the assembly of larger patterns with complex geometries simpler.
Said pattern segments may be covered with one or more layers of webs of fiber material before or after the pattern segments are combined to form said pattern.
At least one of the one or more patterns may comprise one or more first inserts integrally formed therein. The provision of inserts in the pattern means that the patterns can be held in further apparatus and be provided with features providing stability in shape to said patterns of removable material.
At least one of said first inserts may be configured to interact with a support apparatus used to assemble the rim. In this way the pattern can be beneficially held during at least some of the stages of an RTM process.
In this connection it should be noted that at least one of said one or more patterns may be supported at a respective support apparatus. In this way the patterns can all be beneficially held during at least some of the stages of the RTM process.
Said bicycle rim may have one or more internal spaces, with each internal space being formed by first and second patterns, with at least one of the first and second patterns being formed by three, four, five or more pattern segments that are assembled to form the respective pattern of the internal space prior to covering the respective one of the first and second patterns forming the internal space with said one or more layers of webs of fiber material. The use of pattern segments enables the production of complex 3D parts in an expedient and efficient manner.
Said rim may have first and second internal spaces that are formed by respective first and second patterns, with the first pattern being formed in one piece and forming said first internal space and being covered with said one or more layers of webs of fiber material and sequentially assembling said second pattern from respective second pattern segments at said covered first pattern from two, three, four, five or more second pattern segments to form said second pattern covered with one or more further layers of webs of fiber material. In this way a high-performance rim having the desired characteristics can be formed
Said first pattern may also be formed from two, three, four, five or more first pattern segments to form said first pattern. In this way smaller molds for the manufacture of the respective first and second patterns can be used which can simplify the manufacture of the first and second patterns.
Said combined first and second patterns may be additionally covered with one or more layers of webs of fiber material. In this way one can ensure a thorough connection between the covered first and second patterns to form a high strength rim having the desired stiffness and inter-laminar shear strength.
The method of assembling the rim may further comprise the step of heating said mold to a second temperature in a second temperature range. It should also be noted that the second temperature range is preferably a temperature range of ±3° centered about the desired second temperature. The second temperature is preferably selected between 60 and 100° C., preferably between 70 and 95° C.
The second temperature may be used for at least one of heating the mold to heat said mold for curing the material of said rim, and removing said removable material, e.g. melting away said wax.
The method of assembling the rim may further comprise the step of heating said mold to a third temperature in a third temperature range. The third temperature can generally be selected to remove the removable material, e.g. a wax, i.e. to remove said one or more patterns of removable material from said mold. It should also be noted that the third temperature range is preferably a temperature range of ±3° centered about the desired third temperature. The third temperature is preferably selected between 80 and 140° C., preferably between 95 and 120° C.
The reason for these first, second and/or third temperature ranges existing is that the molds may have a temperature gradient across a length and width of the mold which leads to a higher temperature of the mold at one side of the mold in comparison to the temperature at a further side of the mold.
Said first temperature may be lower than said second temperature. Moreover, said second temperature may be lower than said third temperature. In order to produce the rims a resin used to bond the different one or more layers of webs of fiber material one to another may be subjected to temperature and pressure to ensure that the resin flows into all of the spaces between fibers and bonds these one to another. This flow of the resin can be aided if the temperature of the mold is elevated in comparison to room temperature at standard pressures due to a more runny consistency of the resin. The runnier the consistency of the resin is, reduces the number of air pockets obtained in the rim leading to an increased durability and stiffness of said rim due to the decrease in the number of air pockets.
Following the flow of the resin throughout the mold, the resin is cured in order to obtain the rim, this curing can take place either on the application of the second temperature and/or via the application of UV light. Once the material of the rim has cured and the rim will maintain its final shape, the removable material can be removed from the internal spaces of said rim.
The removal may take place by heating the removable material, e.g. a wax, or a special compound that can be liquified on the application of one or more further chemical substances can be used as the removable material.
A vacuum may be applied to said mold during and/or prior to heating said mold to said first temperature, optionally during and/or prior to heating said mold to said second and third temperatures. The application of a vacuum possibly on heating can assist in the flow of a resin in and around one or more layers of fiber material to ensure that as few as possible air pockets result in the rim. It has namely been found that the presence of too many air pockets can significantly reduce the inter laminar shear strength of the rim. Hence a rim having an as high as possible interlaminar shear strength is obtainable by such a method which reduces the amount of air pockets present during the manufacture of said rim in and around said layers of webs of fiber material.
Said vacuum may be selected with a pressure in the range of 0.8 to 10−4 bar. Such vacuums are readily obtainable using a roughing pump either on its own or connected in series with a turbomolecular pump. Moreover, such pressure can achieve the desired flow of the resin through and around the layers of webs of fiber material while reducing the number of air-pockets remaining in a rim.
The method of assembling the rim may further comprise the step of introducing a resin into said mold prior to and/or during said step of heating of said mold to said first temperature.
Through the provision of resin from the outside, a web of fiber material which previously is not coated with a resin, i.e. a prepreg, can be used. Thereby the assembly in a mold can be simplified and an average wall thickness of the final rim can be controlled in an improved manner.
Said resin may be heated to below a curing temperature of said resin on the introduction of said resin into said mold. In this way one does not risk the resin curing prior to removing all of any possibly present air gaps.
Said step of the application of heat may comprise heating said mold to said second temperature and/or heating said resin on introduction into said mold to said second temperature in said second temperature range. In this way one can ensure that the material of the rim can cure at the ideal temperature to make it possible to obtain the desired strength and stiffness of the rim in the shortest possible period of time to expedite the manufacture of the rim.
Said resin may be one of a one-component resin, a two-component resin comprising a hardener, and a multi-component resin comprising one or more hardeners.
The resin may comprise a resin on an epoxy basis, a resin on a polyurethane basis, a resin on a cyanate ester basis or another basis suitable for injection or infusion.
Said one or more patterns may comprise at least one of one or more recesses and projections in an outer surface thereof. Such projections can be used to form e.g. apertures or predefined channels at the rim. The recess can be used to form portions having an increased amount of material to increase a stiffness of a portion of the rim, such as for the formation of ribs e.g. in a sidewall of the rim, to strengthen the radial components of the rim. The projections can be arranged at positions of the rim where spokes and/or the valve are arranged. The spokes and thus the projections are generally arranged symmetrically along the circumference of the rim.
Additionally or alternatively the positions at which spokes and a valve are placed at said rim can be reinforced with elevated portions by providing corresponding recesses in the pattern.
Said one or more patterns of removable material may be made of wax. Wax is a comparatively cheap material that can be used in the bulk manufacture of wax patterns in a reliable manner.
Said one or more patterns of removable material are produced in a 3D printing process, an injection molding process and a wax casting process. These are beneficial ways of producing patterns of removable material.
Said wax casting process may comprise the steps of:
In this way wax patterns can be formed which are generally free off shrinkage effects at an outer surface of the pattern ensuring the manufacture of a rim having the desired wall thickness and wall thickness tolerance.
Said one or more patterns of removable material may have a melting point selected in the temperature range of 80 to 140° C., preferably in the range of 95 to 120° C. Said one or more patterns of removable material remain stable in shape to temperatures selected in the range of 60 to 100° C., preferably in the range of 70 to 95° C. Said one or more patterns of removable material may thus remain stable in shape at temperatures below a melting point of said removable material. This is particularly beneficial to ensure the manufacture of rims having the desired uniform wall thickness.
Said one or more patterns of removable material may remain stable in shape at temperatures below a melting point of said removable material. This means that an outer surface of the one or more patterns does not readily alter its physical state. In this way the one or more patterns can form a part of a mold used in a Resin Transfer Molding Process (RTM process) or a Vacuum Assisted Resin Transfer processes (VARTM process) with which the rim may be formed.
The one or more patterns of removable material that are stable in shape can thus be used to form inner surfaces of enclosed spaces of the rim, with the inner surfaces of the enclosed spaces of the rim having a pre-definable shape and contour.
One or more of the patterns of removable material may be formed by first pattern segments and/or second pattern segments that remain stable in shape at temperatures below a melting point of said removable material. In this way the assembled pattern segments can form patterns that form molds for the one or more internal spaces of the rim.
Said first pattern may be formed by first pattern segments, in particular only formed by first pattern segments and/or wherein said second pattern may be formed by second pattern segments, in particular only formed by second pattern segments.
Said first pattern segments and/or said second pattern segments may be bonded one to another using a pattern material comprising, in particular consisting of said removable material. Using a material comprising said removable material as a bonding agent means that the bonding agent will likewise be removed on removing said pattern. Alternatively the pattern segments can be welded one to another, for example by hot plate welding.
Said first pattern segments and/or said second pattern segments are bonded one to another at respective first and second ends using said pattern material comprising, in particular consisting of said removable material.
First and second ends of said first pattern segments and/or of said second pattern segments may be formed complementary to one another. In this way the first and second ends of respective first and second pattern segments can be bonded one to another in a simple way as these are matching in shape or the like. For this purpose the ends may be chamfered, have features complementary and/or matching in shape and/or the like.
It is particularly preferable to use pattern segments having shapes complementary to one another to assemble the patterns and then to bond these one to another, e.g. by means of a welding technique.
Said first and second pattern segments may have a generally arc-shaped outer shaped viewed in a cross-section thereof. In this way the segments replicate parts forming internal molds for forming the rim, which when assembled form a complete pattern respectively a mold for said rim.
Said one or more patterns have an outer surface, with an average surface roughness Ra below 200 μm, in particular below 150 μm and especially below 100 μm. By providing an internal mold for said rim having such a surface roughness, rims with pre-definable wall thicknesses can be formed.
Two patterns of removable material may be provided, with each pattern of removable material having an outer shape forming a mold for an inner shape of a respective cavity of said rim, with said removable material remaining stable in shape at temperatures below a melting point of said removable material at standard temperatures and pressures, and wherein the same removable material may be used for each of the two patterns of removable material. In this way a mold for a rim may be provided that can be covered with the fiber material prior to insertion into the mold where the rim is subsequently formed.
Said one or more patterns may each have one or more second inserts present therein, with said second inserts being fixedly attached to said rim. The position of the second inserts can correspond to positions in which recesses are present in the pattern to reinforce the portions of the rim where the second inserts are present. The second inserts can also be used to aid in coupling the rim to the further components of a bicycle wheel, such as spokes or a valve of the wheel.
Said second inserts may be provided at positions for spokes of said rim and/or at a position of a valve associated with a wheel formed by said rim. It has hitherto been found that during the production of composite rims, the drilling of the holes for the spokes can lead to a splintering of the material of said rim at the position where it is bored leading to inherent weaknesses in said rim.
In this connection it should be noted that said second inserts may be directly or indirectly attached to said first inserts. In this way the position of the spokes of the bicycle rim can be aligned from the start during the method of assembling the bicycle rim such that a rim with a superior weight distribution can be achieved.
In this connection it should be noted that tows of fibers may be applied at the positions of the inserts to reinforce the position of the inserts in said completed rim, whereas woven fabric can be introduced on areas representing a planar surface of the rim.
Said one or more layers of fiber material are formed by carbon fibers, glass fibers, basalt fibers, wood fibers, hemp fibers, aramid fibers, and polyester fibers, respectively in dry condition or as a prepreg. Such fibers can beneficially be used in the formation of a rim of composite material that is reinforced with fibers. In this connection it should be noted that a prepreg is a layer of fibers which comprise an adhesive.
According to a further aspect the present invention relates to a rim obtainable by a method in accordance with the teaching present herein, said rim being formed of composite material, said rim having one or more internal spaces formed by walls, with a wall thickness of said walls of said rim having a predefinable wall thickness with a tolerance of the wall thickness lying in the range of ±0.5 mm, in particular of ±0.1 mm, especially of ±0.05 mm, for a wall thickness selected in the range of 1 to 4 mm, in particular for a length of material of said rim cut from said rim in the range of 1 to 5 mm and at a width selected in the range of 0.5 to 2.5 cm.
Said rim has a tolerance of the wall thickness lying in the range of ±0.3 mm, especially of ±0.2 mm, for a wall thickness selected in the range of 1 to 4 mm.
Said rim may have a void content of less than 2%, in particular of less than 1.5%. A rim having such a void content has a particularly good inter laminar shear strength. Such shear strengths are ideal for high-performance bicycle rims having the desired durability and stiffness.
In this connection it should be noted that a void is a pore present in a composite material that remains unfilled with polymer and fibers. If less than ideal manufacturing standards are used then voids result which cause a degradation of the mechanical properties and lifespan of the composite material. The void content is represented as a ratio where the volume of voids, solid material and bulk volume are taken into account.
Said rim may have a tolerance of the surface profile of ±0.1 mm, in particular for a length of material cut from said rim selected in the range of 1 to 5 cm and a width selected in the range of 0.5 to 2.5 cm. In this way a rim having particularly smooth surfaces can be achieved by means of the present teaching.
In this connection it should be noted that the tolerance of the surface profile is a standard measurement technique used to define the surface quality of objects. The more uniform the surface is, the lower its tolerance is. The surface profile is defined by a uniform boundary around a surface within which the elements of the surface must lie. The surface profile is a complex tolerance that simultaneously controls a feature's form, size, orientation, and sometimes location. The surface profile is a three-dimensional tolerance that applies in all directions regardless of the drawing view where the tolerance is specified. It is usually used on parts with complex outer shape and a constant cross-section like extrusions.
To measure the tolerance of a surface profile two planes are placed around the surface whose tolerance profile is to be measured and the tolerance is defined by the spacing between the planes that are placed around the surface.
Said rim may have a tolerance of the surface profile of ±0.05 mm, in particular of ±0.03 mm, especially of ±0.01 mm e.g. at the position of e.g. an insert for a spoke or the like.
Said rim may comprise reinforcing ribs, reinforcing beads, stiffening corrugations and/or reinforcing platforms, i.e. elevated portions, formed at at least an inner surface of a sidewall portion of said rim. Such formations in an otherwise uniform surface add strength to the rim and hence improve the durability and strength of a rim comprising such formations.
Said rim may comprise inserts present at positions of said rim corresponding to positions of spokes and/or of a valve associated with a wheel formed by said rim.
Said rim may comprise apertures inherently present in at least one wall of the rim. By providing a rim having such apertures, weak spots of prior rims can be avoided.
Further embodiments of the invention are described in the following description of the Figures. The invention will be explained in the following in detail by means of embodiments and with reference to the drawing in which is shown:
In the following the same reference numerals will be used for parts having the same or equivalent function. Any statements made having regard to the direction of a component are made relative to the position shown in the drawing and can naturally vary in the actual position of application.
The spokes 16 are provided in order to carry the weight of the bicycle as well as its load, e.g. the rider, via the rim 12. The spokes 16 and rim 12 also absorb any irregularities that may be present on the road or track and thereby aid in ensuring the comfort of the rider. Furthermore, the spokes 16 and the rim 12 transmit the acceleration and breaking effort of the rider between the road and the hub and axle assembly 14 and vice versa. Thus, the rim 16 has to be able to cope with the forces transmitted via the spokes 16 and in the wheel 10 in order to ensure an as efficient as possible ride and comfort using said rim 12.
The tire receiving section 22 is separated from the hollow section 24 via a separating wall 26. The separating wall 26 comprises a channel 28 which is configured to accommodate part of an inner tube (not shown) of the wheel 10.
An end of the sidewalls 18 remote from the bottom end 20 comprises projections 30 that can be present in order to increase a clamping force on a tire that can be installed in the tire receiving section 22. As indicated in
Also visible is an aperture 40 via which the spokes can be engaged using a tool in order to balance a wheel 10 by tightening or loosening a spoke 16 as required.
In this connection it should be noted that the apertures 40 could also be formed by inserts 38 present in the patterns 48, 50 of removable material M at positions which later form the apertures or the position of the spokes in order to fixedly and inherently attach said inserts 38 during the manufacture and assembly of said rim.
In this connection it should be noted that inserts 38 and apertures 40 may also be present at a position of the rim 12 where a valve associated with the wheel 10 is inserted into the rim 12.
In this connection it should further be noted that the provision of ribs 34 and/or elevated portions 36 and/or inserts 38 and/or apertures 40 within the internal spaces 22′, 24′ of the rim 12 has hitherto not been possible using prior art techniques of forming rims of composite materials. This is because the prior art methods had no control over the formation of the inner space 22′, 24′ of said rims 12 therefore not making it possible to foresee such structures in the rims 12.
The rim 12 as will be explained in the following is formed by the composite material. A wall thickness of the walls 18, 26 of said rim 12 have a pre-definable wall thickness with a tolerance of the wall thickness lying in the range of ±0.5 mm for a wall thickness selected in the range of 1 to 4 mm.
In order to test the tolerance of the wall thickness a strip of material of a part of the rim 12 is cut from the rim, for example a strip having a length of 1 cm and a width of 0.5 cm, or a strip having a length of 5 cm and a width of 2.5 cm and a variation of the thickness of each strip is measured at 0.1 cm intervals along both the length and the width of the strip of material using e.g. a pair of Vernier calipers or the like. The measured thicknesses are then added and divided by the amount of measurements to obtain an average thickness. This average thickness is then compared to the pre-defined thickness of said part of said rim 12.
Indeed for very high-performance rims 12 manufactured using the method described herein, the rims 12 may have a tolerance of the wall thickness lying in the range of ±0.3 mm, especially of ±0.2 mm, for a wall thickness selected in the range of 1 to 4 mm.
The rim 12 may have an increased inter laminar shear strength due to a comparatively low void content of less than 2%.
Thus, the patterns of removable material M can be used as a mold in resin transfer molding (RTM) processes to form composite bicycle rims.
The removeable material M forming the first pattern 50 is covered completely with layer of webs of fiber material 54. Three sides of the second pattern 48 formed by removable material M are covered with layers of webs of fiber material 52. Once the covered second pattern 48 is brought into contact with the covered first pattern 50, a third layer of webs of fiber material 56 cover both parts of both the first and second patterns 50, 48. Said one or more layers of fiber material 52, 54, 56 can be formed from carbon fibers, glass fibers, wood fibers, hemp fibers, aramid fibers, polyester fibers, a prepreg.
In this connection it should be noted that it is preferred to use pure fibers that are not in prepreg form, as such fibers are still comparatively flexible and have not reached the final thickness obtained on the addition of the resin R. In this way the covered patterns 48, 50 can be placed into the mold 42 in a simpler manner. Leading to a reduction in the time required to assemble the rim 12. Moreover, layers of webs of fiber material 52, 54, 56 to which a resin R is added can be produced having a superior inter-laminar shear force in comparison to layers of pre-pregs.
In order to aid the flow of resin R into a space filled with the layer of webs of fiber material 52, 54, 56 formed between an inner surface 42″ of the mold 42 and an outer surface 48″″ of the pattern 48, respectively of an outer surface 50″″ of the pattern 50, a vacuum and/or heat can be applied. This leads to a more runny consistency of the resin R so that the resin R can be distributed better in the mold 42. Such a runny resin R can be used to reduce the amount of air pockets in said rim 12. Further air pockets can be extracted using said vacuum. The vacuum can be set to a pressure in the range of 0.8 to 10−6 bar.
The vacuum can be applied by sucking air from the internal cavity 42′ using a vacuum pump 47. The vacuum pump 47 is connected to the internal cavity 42′ via a vacuum port 45 and a channel 45′.
The heat can be applied via a heating and/or cooling device 49. This can be configured to heat and/or cool the mold 42 directly and/or the reservoir of the resin R in order to heat the resin R to a first temperature in a first temperature range.
In this connection it should be noted that the resin R can be cured through the application of heat and/or UV light.
If the resin R is cured through the application of heat the mold 42 is heated further to a second temperature in a second temperature range via the heating and/or cooling device 49. In this connection it should be noted that the mold 42 and/or the resin R is/are heated to a temperature below a curing temperature of said resin R on the introduction of said resin R into said mold 42 to ensure that the rim 12 does not prematurely cure during the introduction of the resin R into the mold 42.
Once the material of the rim 12 has cured the removable material M, which is typically a wax, but can also be other kinds of materials, is removed through the application of heat. For this purpose the mold 42 is heated further to a third temperature in a third temperature range.
Thus, said first temperature is lower than said second temperature and the second temperature is lower than said third temperature.
In this connection it should be noted that when the mold is heated to one of the first, second and third temperatures, the heating steps may be carried out gradually in a stepwise manner. For example, the temperature can be increased in steps of 0.5, 1, 1.5, 2, 2.5 or 3° C. over a period of 10 s, 20 s, 30 s, etc., such that the material present in the mold can gradually adapt to the temperature of the mold.
Particularly during RTM processes, it should be noted that the composite of fiber and resin is typically heated in steps to below the glass transition temperature of the resin in order to prevent the device to be formed from becoming soft and thereby obtaining a device with a deformed outer and/or inner surface.
In this connection it should be noted that the mold used in the RTM process and the wax mold may each preferably be formed from a thermally conductive and non-magnetic material, such as aluminum or an aluminum alloy.
The resin R is one of a one-component resin, a two-component resin comprising a hardener, and a multi-component resin comprising one or several hardener.
Moreover, the resin can comprise a resin on an epoxy basis, a resin on a polyurethane basis, a resin R on a cyanate ester basis or another basis suitable for injection or infusion. Such resin can be beneficially used in the formation of composite devices.
Said one or more patterns 48, 50 of removable material M can be produced in a 3D printing process, an injection molding process and a wax casting process. By way of example a wax casting process will now be described in connection with
Each internal space 22′, 24′ is formed by the first and second patterns 50, 48, with each first and second pattern 50, 48 being formed by three, four, five or more pattern segments 50′, 48′ that are assembled to form the pattern 48, 50 of the respective internal space 22′, 24′. For this purpose, first and second ends 48″, 48′″, 50″, 50′″ of the pattern segments 48′, 50′, comprise complementary shaped tongue and groove like features as indicated in
An inner surface 58″ of the respective molds 58 is shaped such that it has the inner shape of the respective rim 12 to be formed by the pattern 48, 50 or pattern segments 48′, 50′ formed in the respective wax mold 58, i.e. the wax mold 58 has an inner space 58′ having a shape corresponding to an outer shape of said pattern 48, 50 or pattern segments 48′, 50′.
The wax, i.e. the removable material M, is introduced into said inner space 58′ of the mold 58 in liquid form from a reservoir 63 via a supply line 63′. Between 40 and 98% of said inner space 58′ of the wax mold 58 is filled with liquid removable material M.
Following this a gas G is introduced into said liquid removable material M present in said wax mold 58 to pressurize said removable material M present in said wax mold 58. The wax M is pressurized with a pressure difference between an outside of said formed wax pattern 48, 50 and a hollow space within said wax pattern 48, 50 selected in the range of 0.02 to 20 bar in comparison to the wax M which is not pressurized.
The wax mold 58 is then moved to completely coat an inner surface 58″ of said wax mold 58 with said liquid removable material M during a cooling of said mold 58. This can take place by cooling the mold 58 while simultaneously rotating the mold 58 about at least one axis and thereby exploiting the centrifugal force to coat the inner surface 58″ of said wax mold, while forming a hollow pattern 48, 50. By pressurizing an interior of the wax pattern, the wax of the pattern can be urged into contact with the inner surface 58″ of the wax mold 58 to form the outer surface 48″″, 50″″ of the pattern 48, 50 or pattern segments 48′, 50′ of wax can be achieved free of defects whose outer surface 48″″, 50″″ is free of shrinkage effects. Such patterns 48, 50 form ideal parts of the mold 42 for forming the inner spaces 22′, 24″ of the rim 12. The removable material M is solidified in said wax mold 58 prior to the removal of the first and/or second pattern 50, 48 respectively the first and second pattern segments 48′, 50′.
Also other methods of making a wax pattern 48, 50 or wax pattern segments 48′, 50′ which avoid shrinkage effects at an outer surface 48′″, 50″″ of the wax pattern 48, 50 or wax pattern segments 48′, 50′ can be employed to form the wax pattern.
The one or more patterns 48, 50 or wax pattern segments 48′, 50′ of removable material M are selected such that they remain stable in shape at temperatures below a melting point of said removable material M, but with said temperature corresponding to a curing temperature of the resin R or said Temperature at which the one or more patterns 48, 50 or wax pattern segments 48′, 50′ of removable material M remain stable in shape is selected higher than a curing temperature of the resin R. The wax can beneficially be selected as one of the following waxes.
The one or more patterns 48, 50 or wax pattern segments 48′, 50′ of removable material M may have a melting point selected in the temperature range of 80 to 140° C., preferably in the range of 95 to 120° C. Moreover, the one or more patterns 48, 50 or wax pattern segments 48′, 50′ of removable material M remain stable in shape to temperatures selected in the range of 60 to 100° C., preferably in the range of 70 to 95° C.
Typically the wax may be selected to be a wax molten at a higher temperature in a range from 60 to 140° C., in particular 70 to 120° C. and to be solid at a lower temperature in a range from 30 to 100° C., in particular 60 to 90° C. The temperature difference between the higher temperature and the lower temperature is preferably selected to be less than 40° C., preferably less than 30° C., in particular less than 20° C. and especially less than 10° C.
The wax may have a viscosity of greater than 2000 mPas for a temperature of less than 85° C. and a viscosity of less than 800 mPas for a temperature greater than 105° C. Such waxes have found to be particularly stable in shape up to their melting point and the transition between the liquid state and the solid state takes place over comparatively small temperature ranges making said waxes more cost effective in their use.
On forming the wax pattern 48, 50 the wax mold may be heated to a temperature below a solidification temperature of the wax, in particular to a temperature selected in the range of 1 to 40° C., in particular 5 to 25° C., below the solidification temperature of the wax. In this way the wax can be solidified in a more controlled manner and the shrinkage effects at the surface of the wax pattern 48, 50 can be reduced as the wax does not automatically solidify on contact with the surface of the mold cavity.
The mold cavity may be evacuated to a pressure selected in the range of 0.02 to 0.95 bar, in particular to a pressure selected in the range of 0.05 to 0.5 bar.
To form the first and second patterns optionally having inserts 38, 38′ placed at one or more predefined positions a vacuum may be applied at said wax mold using a vacuum pump. Once the desired vacuum of e.g. 0.3 bar is achieved in the wax mold, a valve may be closed to maintain the pressure within the cavity. Thereafter a liquid form of the removable material M may be introduced into the wax mold. For example, 80% of the volume of the mold 18 may be filled with liquid material M, e.g. wax W. Thereby the residual air in the mold is compressed through the addition of the wax W in such a way that the pressure in the wax mold may now be in the range of 1.02 to 20 bar depending on the initial vacuum pressure and the amount of wax added.
The wax mold may then be rotated about an axis of rotation, e.g. the axis of the rim while the wax mold is cooled, due to the pressurized gas in the wax mold and the rotation of the mold, the initially liquid wax covers the complete surface of the mold such that a wax pattern can be formed having the outer shape resembling that of the inner shape of the mold used in the RTM process, with the wax pattern having a hollow interior.
If a pattern having a particularly complex outer shape is to be formed, additional gas may be added to the wax mold prior to, during and/or after the addition of the liquid removable material M. Additionally or alternatively more than 80% of the volume of the cavity of the wax mold can be filled with the removable material M.
This additional pressure in the mold can guide the liquid removable material into the complex negative geometries of the mold to ensure that a pattern having an outer surface 48″″, 50″″ substantially free of defects can be formed.
For this purpose, the individual pattern segments 50′ are connected at their ends 50″. Once the pattern segments 50′ have been combined to the first pattern 50, all of the sides of this are completely covered with one or more layers of webs of fiber material 54.
Once the first pattern is completely covered with the one or more layers of webs of material 54, the second pattern segments 48′ are assembled at the covered first pattern 50 as shown in
The covered and combined first and second patterns 50, 48 are subsequently covered with one or more further layers of webs of fiber material 56. Following this the covered patterns 48, 50 are introduced into the mold 42 as shown in
In this connection it should be noted that similar recesses 74 and projections can be present in the first pattern 50.
In this connection it should be further noted that each of the patterns 48, 50 may only comprise either recesses 74 or projections 70.
It should also be noted that simper forms of rims 12 can be formed using the method described in the foregoing namely rims 12 only having one internal space 22′. Such an internal space 22′ could be formed e.g. in a manner similar to the internal space 22′ of the tire receiving section 22, with the spokes then being connected to the rim 12 directly in the channel 28 formed in the separating wall 26. In this case said channel 28 may be formed deeper and/or comprise recesses at positions where the spokes 16 are attached to the rim 12. If such a comparatively simple structure is selected the wax pattern 48 used can be produced as one without the need of combining several wax patterns 48, significantly reducing the cost of manufacture of such a rim.
Thus in the RTM process described in the foregoing at least one layer of roving is provided as a first layer of fiber material 52 optionally also a second layer of fiber material 54 is provided as further roving and/or a third layer of fiber material 56 is provided as further roving. The one or more patterns covered with the roving are then placed into the mold. The mold is then evacuated to create a vacuum in the mold. The resin R is then injected into the mold at a temperature above room temperature but below the ideal hardening temperature of the resin R possibly under pressure. The resin R at elevated temperature and which is possible pressurized is more flowable than unpressurized resin R at room temperature and hence can flow more easily through the roving and the cavity in the mold in order to ensure, if possible, that no air pockets are formed in the composite material of the final device.
The resin R is then permitted to solidify, i.e. harden, at a temperature selected below the melting temperature of the wax pattern, preferably while gradually increasing the temperature of the mold between the boundaries of the second temperature range from the lower temperature to the higher temperature, e.g. from 90° C. to 100° C. If required, openings and/or apertures can be applied at the hardened composite device. Following which the temperature of the mold is gradually increased from e.g. 100° C. to 120° C. during the third heating step in order to melt out the wax patterns.
As is known to the person skilled in the art of RTM processes, the glass transition temperature of the resin can be increased temporally in the mold during the stepwise gradual increase in temperature to above the melting point of the wax to form the device. The liquid wax can then be removed via the openings and/or apertures present at the rim, e.g. at the position of the spokes.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1913552.4 | Sep 2019 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2020/076106 | 9/18/2020 | WO |
