Patent Description:
The present disclosure is generally directed to injection molding equipment, and more particularly to side actions or slides for injection molding.

Many injection molded parts require what is commonly referred to as a side action or slide to remove coring geometry from the ejection path of a molded part. A common method of actuating this movement is to utilize what is known to the industry as an angle pin. Other common terms for such parts are cam pin, pecker pin, horn pin, or the like, and the terms depend on the region of manufacture. As the angle pin name suggests, this pin-like component is oriented at an angle relative to the normal axes of motion for the molding plates and slides. The pin installation angle and pin length combine to generate the desired movement or stroke of the slide to clear the ejection path of the now molded article from the cavities.

Referring to <FIG>, a typical side action or slide part, i.e., a slide <NUM> has a body <NUM> with a coring element <NUM> of some geometric form extending therefrom. The coring element <NUM> is used to form a void or desired surface or shape within a molded part. However, the coring element <NUM> lies in the part ejection path from the mold. Thus, the slide <NUM> is movable so that the coring element <NUM> can move toward the mold cavity prior to part formation and can be withdrawn from the mold cavity to permit the part to be ejected from the cavity and the mold. In some examples, the slide <NUM> has a slightly oversized round or circular shaped hole <NUM> in the body <NUM> for receiving an angle pin <NUM>. As shown in <FIG> and <FIG>, a slide <NUM> is similar to the slide <NUM> in that it has a body <NUM> with a coring element <NUM> projecting from the body. However, in some examples, the slide <NUM> has an elongate, non-round, oval, or oblong shaped hole, i.e., a slot <NUM> in the body <NUM>.

<FIG> and <FIG> depict a generic mold construction that incorporates the slide <NUM>. In this example, the mold includes a first mold half <NUM> and a second mold half <NUM> that are movable toward and away from one another in the direction of the arrows MC and MO, respectively, i.e., "Mold Close" (MC) and "Mold Open" (MO). <FIG> shows the mold with the mold halves <NUM>, <NUM> closed and <FIG> shows the mold with the mold halves open. The mold halves <NUM>, <NUM> define a mold cavity <NUM>, which can form a molded part in the closed position of <FIG>, and which can eject the molded part in the open position of <FIG>. The angle pin <NUM> has a proximal end mounted to the mold half <NUM> through an opening <NUM> in the second mold half. A distal or working end <NUM> of the angle pin <NUM> protrudes from the second mold half to engage the slide <NUM>. As shown in <FIG>, with the mold halves <NUM>, <NUM> closed, the coring element <NUM> extends into the mold cavity <NUM> to form a void, space, or other shape in a molded part. The coring element <NUM> must move out of the way to clear the mold cavity <NUM>. The working end <NUM> of the angle pin <NUM> and the hole <NUM> in this example, move the slide <NUM> in a direction perpendicular to the mold open/close directions MO/MC. Thus, the coring element <NUM> is simultaneously moved outward from the cavity <NUM> as the mold halves <NUM>, <NUM> are separated in the direction MO to the open position of <FIG>, allowing for the molded part to be ejected from the cavity <NUM>.

While both the hole <NUM> and the slot <NUM> are cut at an angle that matches the angle pin <NUM> installation angle, the hole <NUM> diameter or slot <NUM> radius are always oversized so that the motion, i.e., the stroke S of the slide <NUM> (or <NUM>) can be achieved, as depicted in <FIG> and <FIG>. This is typically referenced as "fit" or "running fit". In the case of an angle pin <NUM> to hole <NUM> or slot <NUM> geometry, this running fit is very loose by virtually any standard so as not to add additional force requirements to facilitate the mold opening process. This conventional loose fit is depicted in <FIG> and <FIG>. This loose fit also allows for pin deflection without binding and breaking the angle pin <NUM> under load. Again, depending on the region of manufacture, the typical hole size could be <NUM> - <NUM> (i.e. <NUM>/<NUM> inch -<NUM>/<NUM> inch) larger in diameter than the diameter of the angle pin <NUM>.

As mentioned earlier, it is sometimes desirable to machine an elongated slot <NUM> in a slide <NUM> rather than an oversized hole <NUM>, as depicted in <FIG> and <FIG>. The purpose for this slot <NUM> geometry is to add a significant or a predetermined delay, i.e., a lost motion effect, to the transverse motion of the slide <NUM> relative to the separation of the mold halves <NUM>, <NUM> and removal of the coring element <NUM> in relation to the mold opening sequence in the direction MO. Adding this motion delay or lost motion can improve the mold cycle time, as the coring element <NUM> of the slide <NUM> assists the natural shrinkage and adhesion of a cooling molded part by holding the part to the ejection half <NUM> of the mold. The typical slot <NUM> geometry is an oval. The oval width would again be oversized by <NUM> - <NUM> (i.e. <NUM>/<NUM> inch - <NUM>/<NUM> inch) with a full, larger clearance oversized radius at each end of the slot. The slot length is elongate to the desired amount of mold half <NUM>, <NUM> separation prior to angle pin <NUM> engagement, which would then move the slide <NUM>.

It has been established that either the hole <NUM> or the oval slot <NUM> geometry utilized to engage with an angle pin <NUM> has an oversized internal surface geometry that is intentionally designed for simplicity of installation. The hole <NUM> or slot <NUM> is formed using a common drill and ream or milling process. While more sophisticated and accurate methods for installing or forming the angle pin hole geometry are known, the geometry itself is a legacy to machining practices available at the inception of mold tool building. This legacy geometry minimizes the surface contact area between the angle pin <NUM> and the slide hole <NUM> or slot <NUM> during operation. If one were to magnify the contact area between an oversized hole/slot radius relative to a nominal sized pin, as in the case of the angle pin <NUM>, there would only be a tangential line of contact between the angle pin and the slide hole/slot geometry in line with the direction of movement, as depicted in <FIG> and <FIG>. This focuses the load to a minimal amount of surface area.

This minimal surface area that carries the load often generates enough frictional heat that galling of the angle pin <NUM>, the slide <NUM> or <NUM>, or both occurs during use. Additionally, the tangential line of contact will wear. While such wear can distribute the load over a greater surface area, the engineered motion is altered from the design intent as the surface contact is no longer at the engineered specification. Also, as depicted in <FIG>, the angle pin <NUM> and hole <NUM> or slot <NUM> may not be at precisely the same angle relative to one another. This can cause undue loading or stress on the angle pin <NUM> as a result of the contact point being at or near the tip of the pin and not along a wear line over the length of the pin. These issues or problems can lead to increased maintenance and repair, such as replacing worn angle pins, repairing or replacing damaged slides, or replacing an angle pin with a larger diameter pin and revising the mold to accommodate the larger angle pin. Associated costs with repairs, revisions, and production loss can be quite substantial. Depending on the mold size and the repairs or replacement parts necessary, it is not be uncommon for these maintenance costs to be on the order of tens of thousands of dollars.

Due to the performance requirements of molding in general, today's molds or mold parts are mostly fabricated from steel and aluminum alloys. There are a variety of surface treatments that have been tried and applied to both steel and aluminum parts to try and extend their useful life cycle. Invariably, these metallic components require lubrication to assist smooth operation in production. However, adding lubricants to the equation creates another level of potential problems.

It is important to further understand the wide variety of environments in which injection molds are operated. Engineered resins can require mold temperatures of <NUM> (i.e. <NUM> °F) while commodity resins need mold temperatures of only <NUM> (i.e. <NUM> °F). Additionally, clean room molding is a segment of the molding community that is desired or required to mold parts that necessitate certain processes to mold parts for food packaging, medical devices, and other products minimizing potential dust, grease, and other contaminants during production. A clean room is a positive pressure room with air filters to minimize airborne contamination particulates. Prior to entry and for the duration of time spent within the clean room, all persons are required to wear gowns, hair and beard nets, shoe covers, and the like. Currently, food grade grease is used for lubrication in clean room molding operations. Food grade grease has very low performance characteristics with respect to pressure and heat tolerance, both of which can be required in the operation of an injection mold. Due to the precision of the mold and molding process, clearances are minimal and therefore grease is spread to a thickness or thinness that is more typical of how an oil lubricant would be used. Oil is not an option as there is no containment system for the oil that would allow for the necessary mechanical operation of componentry within the mold.

Additionally, the current methodology and the tangential line of contact deposits normal wear particulates in the mold tooling, these particulates are usually trapped within the lubricant or grease where they could cause catastrophic failure of the mold tooling. However, it is also possible that the particulate could migrate elsewhere within the mold tooling or the molded article.

Simply put, both oil and grease, when utilized for injection mold tool operation, flow away over time and contaminate the mold, molded parts, and production facility. While FDA approved grease is edible, grease contamination on food packaging, decorated parts or packaging, or medical device molded parts would render those parts as rejects. Rejected parts set into motion an expensive process that is unique to each part or to the processer's procedures as to the disposition of the rejected parts. Fines may be levied by a customer. Lost production or machine down time may result. Remanufacturing or repackaging of parts may be required. Significant resin loss may be incurred. The list goes on and on of potential repercussions from rejected parts, and none of these repercussions is desirable or inexpensive to remedy. It is known from <CIT>) to provide a mold defining a mold cavity for manufacture of an article. The mold having a plurality of mold side wall members, each of the side wall members being moveable from a closed position and an open position. It is known from <CIT>) to provide a slide clip suitable for molds having at least one cam-actuated slide for pulling a core element outward and inward from a parting line of the mold as the mold is opened and closed.

According to the invention there is provide a mold slide and an angle pin bushing according to the claims.

In one example, according to the teachings of the present disclosure, a mold slide has a slide with a slide body movable along a first direction. The slide body has an angle pin hole formed therein and defines an axis. The angle pin hole has a pocket at one end thereof. An angle pin bushing is seated in the pocket and defines an angle pin bore that is parallel to the axis of the angle pin hole. A mold part is adjacent to the slide part and is movable relative to the slide part along a second direction different from the first direction. An angle pin is carried on the mold part. A portion of the angle pin is positioned in and movable in concert with the mold part relative to the angle pin bore in the angle pin bushing to move the slide part along the first direction.

In one example, the slide part and the mold part can be part of an injection mold tool.

In one example, the second direction can be perpendicular to the first direction.

In one example, the angle pin can be oriented parallel to the axis of the angle pin hole and the axis can be oriented at an angle greater than <NUM> degrees and less than <NUM> degrees relative to the first and second directions.

In one example, the angle pin hole can be nearly a circular cross-section shape, with the body of the angle pin bushing having two limited flat regions on opposed sides of the body.

In one example, the angle pin bore of the angle pin bushing can be a generally circular cross-section shape.

In one example, the angle pin hole can be a slot having a non-round oval or oblong cross-section shape.

In one example, the angle pin bore of the angle pin bushing can be a slot having a non-round oval or oblong cross-section shape.

In one example, the pocket can have a larger width than a remainder of the angle pin hole and can define a shoulder at a terminus of the pocket adjacent the remainder of the angle pin hole. The angle pin bushing can be borne against the shoulder within the pocket.

In one example, the angle pin bushing can have a top face that is flush and parallel with a top surface of the slide part surrounding the angle pin hole.

In one example, the angle pin bushing can have a scalloped region on a portion of an exterior surface thereof. The scalloped region can define a step on the exterior surface.

In one example, a clip recess can be formed adjacent the pocket and can have a depth corresponding to the position of a step formed on an exterior surface of the angle pin bushing. A retention clip can be received and retained within the clip recess and can abut against the step to retain the angle pin bushing within the pocket of the angle pin hole.

In one example, the angle pin bushing can be formed from a fabric/resin composite material.

In one example, the angle pin bushing can have an elongate slit formed along a length of the angle pin bushing and through the angle pin bushing from the exterior surface to the angle pin bore.

In one example, the angle pin bushing can have a flat surface region formed on an exterior surface at each of opposed sides of the angle pin bushing.

In one example, the angle pin bushing can have a lead-in relief section at one end thereof. The lead in relief section can include a chamfer at a bottom surface of the slide body.

In one example, the axis of the angle pin hole, the angle pin bore of the angle pin bushing, and the angle pin can each be oriented concentric with one another.

In one example, a retention clip can be received in a clip recess adjacent the pocket and can abut against a step on the angle pin bushing. A fastener hole can be formed through the retention clip and a fastener bore can be formed in the slide body to receive a fastener that retains the angle pin bushing within the pocket. The fastener hole and fastener bore can also each have an axis that is at least parallel with the axis of the angle pin hole.

In one example according to the teachings of the present disclosure, an angle pin bushing for a mold slide includes a body. The body has an exterior surface extending between a top face and a bottom face. An angle pin bore is formed through the body between the top face and the bottom face. The top face and an axis of the angle pin bore are not perpendicular to one another.

In one example, the body can be formed of a fabric/resin composite material.

In one example, a slit can be formed along a length of the body and through the body from the exterior surface to the angle pin bore.

In one example, the top face can be non-parallel with the bottom face and the angle pin bore can be perpendicular to the bottom face.

The drawings provided herewith illustrate one or more examples or embodiments of the disclosure and therefore should not be considered as limiting the scope of the disclosure. There may be other examples and embodiments that may be equally effective to achieve the objectives and that may fall within the scope of the disclosure. Objects, features, and advantages of the present invention will become apparent upon reading the following description in conjunction with the drawing figures, in which:.

The use of the same reference numbers or characters throughout the description and drawings indicates similar or identical components, aspects, and features of the disclosure.

The disclosed angle pin bushings and mold tool slides solve or improve upon one or more of the aforementioned and/or other problems, deficiencies, and disadvantages with the prior known mold slides and angle pin methodology. The disclosure relates to an angle pin bushing applied to a side action or slide of a mold to improve the functionality of the angle pin. The disclosed angle pin bushings do so by addressing the necessary geometry while increasing the contact surface area with the angle pin exponentially. The disclosed angle pin bushings are in the form of replaceable inserts engineered to saddle the angle pin diameter. The disclosed angle pin bushings can extend the service life of both the angle pin and the slide hole or slot, thereby reducing the preventive maintenance schedule of the slide components and mold tool or components. The disclosed angle pin bushings eliminate the need for using lubricants or grease for the angle pins. These and other objects, features, and advantages of the present disclosure will become apparent to those having ordinary skill on the art upon reading this disclosure.

The saddle geometry of the disclosed angle pin bushings establishes what would be the wear pattern of a slide hole or slot that one would see over an extended life cycle of a mold to the point that additional wear would be negligible. Such minimal wear may be multiples of <NUM> to <NUM> (i.e. millionths of an inch vs. thousandths of an inch), essentially yielding no measurable difference to the slide stroke over time. The saddle geometry then flares to a functional clearance width typical for smooth operation. Again, the geometry of the disclosed angle pin bushings serves to improve the overall function of the mold tooling.

<FIG> illustrate two examples of angle pin bushings <NUM> and <NUM> constructed according to the teachings of the present disclosure. The angle pin bushing <NUM> defines a generally round or circular slide hole shape for a mold slide. The angle pin bushing <NUM> defines an oblong or oval slide slot shape for a mold slide. <FIG> illustrate various view of the angle pin bushing <NUM>, which is described in detail. Other than the oblong or oval shape of the body and slot, the description is equally applicable to the angle pin bushing <NUM>.

With reference to <FIG>, the angle pin bushing <NUM> has a generally cylinder-shaped body <NUM> with an outer or exterior surface <NUM>, a top end or face <NUM>, and a bottom end or face <NUM>. A bore <NUM> extends completely through the body <NUM> in a lengthwise direction and thus opens to both the top face <NUM> and bottom face <NUM>. The bore in this example is generally round or circular, though it may not be precisely circular, as discussed below with regard the saddle geometry shape. The bottom face <NUM> is generally flat or planar and is oriented orthogonal or perpendicular to an axis B of the bore <NUM>. The top face <NUM> is oriented at an angle relative to the axis B such that the top face is not parallel to the bottom face <NUM> and is not perpendicular to the bore axis. A thin or narrow slit <NUM> is formed lengthwise along and through the body <NUM> from the outer surface <NUM> to the bore <NUM>. The slit <NUM> forms a break in the circumference of the body <NUM>.

A low point L of the top face <NUM>, relative to its distance from the bottom face <NUM>, references a front of the angle pin bushing <NUM> (see <FIG>) and a high point H of the top face, relative to its distance from the bottom face, references a back of the angle pin bushing. With these references in mind, opposed sides of the body <NUM> may include relatively narrow, flat, timing surfaces <NUM> extending lengthwise along the angle pin bushing <NUM> between the top and bottom faces <NUM>, <NUM>. These flat surfaces <NUM> can give the body <NUM> a generally circular shape, but slightly oval shape on the exterior surface <NUM>. Also, in this example, the body <NUM> has a scalloped or reduced thickness region <NUM> formed in the outer surface <NUM> on the front of the body <NUM> from the top face <NUM> and terminating partway along the length of the body. The terminus or end of the scalloped region <NUM> defines a step <NUM> on the front of the angle pin bushing <NUM>.

The angle pin bushing <NUM> has substantially the same structure in this example. However, the angle pin bushing <NUM> has a body <NUM> that is substantially oval or oblong in configuration instead of being substantially round. Further, the angle pin bushing <NUM> has a bore <NUM> with an oval or oblong shape as well to create the above-described lost motion delay, if desired. The other features of the angle pin bushing <NUM> are essentially the same as the angle pin bushing <NUM> and thus are depicted using the same reference numbers in the drawings.

As shown in <FIG>, and again with relation to the angle pin bushing <NUM>, a mold and slide arrangement, i.e., a mold slide, is simplistically depicted. The mold again has a first half (not shown) and a second half <NUM>, i.e., a mold part, that carries the angle pin <NUM>. The mold halves are movable relative to one another in the direction of the arrows MC/MO, as described earlier. The mold also has a slide part, i.e., a slide <NUM> having a body <NUM> and a coring element <NUM>. The slide <NUM> further has a hole <NUM> with a generally round or circular cross section shape. The hole <NUM> is formed at an angle through the body <NUM> or in other words is not perpendicular to the top and bottom surfaces <NUM>, <NUM> of the body nor to the movement or slide direction S.

The disclosed angle pin bushing <NUM> is received within the hole <NUM>. In the disclosed example, the angle pin bushing <NUM> is received within a pocket <NUM>, i.e., a larger diameter section of the hole <NUM> at one end of the hole in the slide part. The bottom face <NUM> of the angle pin bushing <NUM> is borne against a shoulder <NUM> or ledge at the depth or terminus of the pocket, i.e., where the larger diameter pocket <NUM> terminates within the hole <NUM>. The shoulder <NUM> stops further insertion of the angle pin bushing <NUM> into the hole and thus properly positions the angle pin bushing at the desired depth within the hole in the slide <NUM>. The angled top face <NUM> is oriented at the same angle relative to the axis B of the bore <NUM> as the angle of the hole <NUM> relative to the orientation of the slide <NUM> and slide direction S. By controlling the angle of the top face <NUM>, the length of the angle pin bushing <NUM>, and the depth of the shoulder <NUM> within the hole <NUM>, the top face <NUM> lies flush with the top surface <NUM> on the body <NUM> of the slide <NUM>.

As used herein, the phrase"saddle geometry generally refers to the contact area between the angle pin and the bushing surfaces. Specifically, the radius at the contact sides of the angle pin bushing bore is essentially the same as the angle pin catalog size. Actual angle pins are about <NUM> (i.e. <NUM> inch) undersized of the catalog size. Thus, the bushing will have a <NUM> (i.e. <NUM>) clearance on the functional radii, i.e. the saddle or pin to bushing contact area. Additionally, this radius is carried about <NUM> degrees (<NUM> degrees in each direction from the mid-plane of the bushing at each contact side. Thus, there is a <NUM> degree sweep of radius that is within <NUM> (i.e. <NUM> inches) of the angle pin diameter. This built or designed in saddle geometry then basically approximates many cycles of wear having occurred in the prior art loose fit arrangement, i.e., comparative to a tangential line of contact worn down over time to more surface area contact between pin and bore and slide material. That wear in the existing slide and angle pin construction would have otherwise deposited particulate into the grease as it wears into the bushing. With the increased surface area provided by the disclosed angle pin bushings, the disclosed bushings will all but eliminate wear particulate. This saddle geometry also ensures that the disclosed composite material bushings will have significant bearing surface against the angle pin. In current designs, the above-described significantly oversized hole or oval slot are used, creating the wear problems.

As shown in <FIG>, the need for a loose fit or running fit required for existing slides and angle pins is reduced or eliminated. The angle pin <NUM> diameter and saddle geometry or shape of the bore <NUM> can be very closely matched to the pin diameter through the angle pin bushing <NUM>. Likewise, as shown in <FIG>, the angle pin bushing <NUM> can have a bore slot width and saddle geometry or shape at each end of the bore <NUM> can also be very closely matched to the pin diameter. Further, the diameter of the hole <NUM> (or slot) in the slide <NUM> below the pocket, as shown in <FIG>, can be larger than the diameter of the angle pin <NUM>. This provides clearance at the tip or distal end of the angle pin <NUM> for reasons discussed further below.

As shown in <FIG> and <FIG>, the angle pin bushing <NUM> can be retained in the body <NUM> of the slide <NUM> by a retention clip <NUM>. A clip recess <NUM> is formed in the body <NUM> in the top surface <NUM> to a depth less than that of the pocket <NUM>. The clip recess <NUM> extends laterally further outward from the pocket <NUM> into the body <NUM> and terminates at a ledge <NUM>. The depth of the ledge is the same as the depth position of the step <NUM> on the angle pin bushing <NUM> and the scalloped or reduced thickness region <NUM> on the body <NUM> coincides with the clip recess <NUM>. The retention clip <NUM> is sized and shaped to fit within a void in the body <NUM> of the slide <NUM> created by the clip recess <NUM> in the body and the scalloped region <NUM> on the angle pin bushing <NUM>. The retention clip <NUM> is borne against both the step <NUM> on the angle pin bushing <NUM> and the ledge 100within the pocket <NUM>. A fastener, such as a screw <NUM>, can be inserted through a hole <NUM> in the retention clip <NUM> and engage a threaded bore <NUM> in the clip recess <NUM> to secure the retention clip <NUM> in place.

Also, the angle pin bushing <NUM> with the slot shaped bore <NUM> can be secured in the same manner but in a slide modified to accommodate the oval or oblong shape of the body <NUM>. The sizes and shapes of the clip recess <NUM> in the slide body <NUM>, the scalloped region <NUM> on the front of the angle pin bushing <NUM> or <NUM>, and the retention clip <NUM> can vary considerably and yet function as intended. However, these components and aspects of the mold tool should be cooperatively shaped to accommodate one another. <FIG> show the angle pin bushings <NUM> and <NUM> installed in corresponding slides. Both the retention clips <NUM> and the angle pin bushings <NUM>, <NUM> can be flush with the top surfaces <NUM> of the slides when the slide is assembled.

The disclosed angle pin bushings <NUM> and <NUM> as shown and described herein provide improvements over conventional angle pin methods. Additionally, the installation and retention of the disclosed angle pin bushings <NUM> and <NUM> are also novel. As noted below, the angle pin bushings <NUM> and <NUM> can be made from different materials and thus the angle pin contact surfaces within the slide bodies are not limited to the material of the slide body, as in the prior art. The material of choice for the angle pin bushing <NUM> and <NUM> can be selected for maximizing the wear properties, cost, durability, friction characteristics, replacement schedule, and the like in view of a given mold application. The disclosed angle pin bushings <NUM> and <NUM> are installed into a matching angled pocket within the hole or slot of the slide component or part. The sizes and shapes of the pockets in the slides and the bushing bodies <NUM> and <NUM> can vary considerably from the disclosed examples, depending on the needs of a given mold application.

The pocket shoulder <NUM> in the slide body <NUM> or <NUM> limits the installation depth of the angle bushings <NUM> and <NUM> into the hole <NUM> or slot of the slide to a predetermined level. The angle pin bushings <NUM> and <NUM> in the disclosed examples have the two flat timing surfaces <NUM> on the opposite sides of the body <NUM> or <NUM>. These surfaces or flats <NUM> orient the angle pin bushing <NUM> or <NUM> about its longitudinal axis so that the bushing geometry will align with the hole <NUM> or slot in the corresponding slide body. Thus, the angle pin bushings <NUM> and <NUM> can be precisely aligned with the mold angle pin <NUM>. The flat surfaces <NUM> and the installation depth of the angle pin bushings <NUM> and <NUM> can be configured so that the bushing top face <NUM> is flush with the top surface <NUM> of a slide <NUM> or the like when installed. The flat surfaces <NUM> may be wider on the angle pin bushing <NUM> because of the oval or oblong shape of the body <NUM>.

Regarding material selection, the angle pin bushings <NUM> and <NUM> as described herein may be fabricated of a highly wear resistant metal, such as bronze, aluminum bronze, or other suitable metal bearing materials. Such bushings could include a coating and/or lubricant at least on the inner surface of the respective bores <NUM> or <NUM> to minimize frictional heat build-up and allow for smooth operation. A product manufactured from these materials would be readily adopted by the industry due to the familiarity the industry has with these types of common materials. However, the disclosed angle pin bushing geometry now broadens the consideration and scope of materials that may be used to fabricate the angle pin bushings <NUM> and <NUM>. A desirable material selection for the angle pin bushings <NUM> and <NUM> would not require any lubrication, would be naturally wear resistant to enhance the unique and novel geometry, and would perform in all current molding environments. In one example, such an alternative material would be a wear resistant fabric/resin composite with a resin system capable of performing within the wide-ranging environments as seen in production manufacturing.

The disclosed angle pin bushings <NUM> and <NUM> are essentially bushings, and some standard bushings are used for other purposes in injection molds. Thus, one should understand that in the mold tool building community, standard bushings are typically designed with an intentional interference press fit into their respective openings. Thus, standard bushings typically require the assistance of a press, typically fitted with a hydraulic cylinder that can produce several tons of pressure, to be fit or inserted. This is necessary, as the standard bushings are intentionally oversized on their outside diameter creating the interference fit with the mating hole geometry in the mold tool. This process is relatively simple in nature, as the bushing and receiving bore are axially vertical relative to the mold tool surfaces and the initial contact between bushing and orifice is parallel to each other.

In contrast, in the case of the disclosed angle pin bushings <NUM> and <NUM>, the installation is not parallel to the surface of installation, as depicted in <FIG>. The need to use a hydraulic press would be impractical, cumbersome, and time consuming to accommodate the angle of installation. This angle α is typically less than <NUM> degrees, and in many examples is between about <NUM> degrees and about <NUM> degrees, depending on the rate of slide desired per rate of mold separation for a given mold tool application. The disclosed angle pin bushings <NUM> and <NUM> may optionally have two geometry features that aid during installation with a slight press fit and no need to implement a hydraulic press to seat the bushing. The first such optional feature is a lead-in relief section <NUM> at the base of the angle pin bushing body <NUM> or <NUM>, i.e., adjacent the bottom face <NUM>. In this example, the relief section <NUM> is tilted and thus not perpendicular to the bottom face <NUM> of the angle pin bushing <NUM> or <NUM>. In one example, the taper angle of the relief section <NUM> can be the same as the angle α of the hole <NUM> or slot in the slide body. The relief section <NUM> can also be slightly chamfered such that the relief section is engineered to readily fit in the hole <NUM> or slot and to maintain a line of surface intersection between the relief section and the axial outer profile of the bushing that is parallel with the receiving angle of the installation pocket <NUM>.

The second such optional feature is the narrow slit <NUM> provided along the length of the angle pin bushings <NUM> and <NUM> and located specifically within one of the two flat timing surfaces <NUM>. The slit <NUM> is engineered to allow the angle pin bushing <NUM> or <NUM> to have a minimal amount of deflection during installation. The placement of the slit <NUM> is intentionally located away from the working surfaces, i.e., the inner front and rear pin contact surfaces, of the angle pin bushings <NUM> and <NUM>. The positioning is such that the bushings can perform as intended while allowing installation without the need for excess force that could damage the bushing during this process.

Regarding the aforementioned fabric/resin composite material, there is almost no limit to the geometries that can be shaped with composites through various manufacturing methods. A very common geometry is that of a cylinder. The angle pin bushing with conventional geometry could be manufactured as a cylinder. However, that would still yield a tangential line of contact between the angle pin bushing and the angle pin. If the novel geometry were to be machined into the cylinder, that too would yield a product with performance deficiencies as the fibers of the fabric/resin composite substrate would not be oriented in a manner that maximizes the fabric/resin composite wear resistance capabilities evidenced by a continuous uninterrupted surface of wear resistant composite. Thus, in one example, the novel geometry of the angle pin bushing <NUM> or <NUM> may be created with unique mandrels, such as a mandrel <NUM> as depicted in <FIG>. The mandrel <NUM> can be precisely shaped to form the internal bushing geometry. The fabric/resin composite material <NUM> can be wrapped around the mandrel to yield a bushing body <NUM> having the desired thickness. The composite material substrate <NUM> can be oriented in a way that mates the functional surface in direct contact with the appropriate size angle pin thereby maximizing the wear resistance properties of the composite. Outer surface features, such as the slit <NUM> and the scalloped region <NUM> and step <NUM> can be machined in the bushing body after the composite material <NUM> is formed to the mandrel <NUM>.

While the disclosed angle pin bushings <NUM> and <NUM> have largely been described as beneficial to the mold processing community (molders of plastic parts), the mold tool building community (machinists who build the tooling) would also benefit from the availability and implementation of the angle pin bushings constructed of either a wear resistant metal alloy or fabric/resin composite. As earlier described, there can be significant force required to move a slide. That force may necessitate the fabrication of the slide parts themselves from what is normally referenced as a tool steel alloy. The angle pin bushing acting as the bearing surface for the force to move the slide allows alternate materials, such as certain stainless steels, aluminum, and others, to be considered for use as a mold tool slide.

Tool steel alloys are more expensive per <NUM> (i.e. per pound), generally require more time to initially machine, and necessitate heat treatment to maximize the alloy properties. While the heat treatment process adds expense and time, the greater expense comes from the secondary machining operations required to form the parts. Further, heat treatment alters the molecular structure of the alloy. This alteration in molecular structure is known to the mold tool building community and is factored in during the initial machining process prior to having the heat treatment service performed. To summarize, tool steel alloys are machined the first time leaving excess steel that allows for warp and dimensional change that occurs during the heat treatment process. Then, once the heat treatment process is finished, the mold tool builder now needs to machine the hardened tool steel component a second time to correct the warp and properly finish the part to the desired precise specifications. Thus, the disclosed angle pin bushings <NUM> and <NUM> broaden the scope of materials to be considered for use as slide body components, not only in the conventional sense with current materials and manufacturing practices, but further to include evolving materials and processes. The mold slides can include 3D printed components and new material combinations that may be developed to enhance molding but may not be well suited for a load bearing surface to interface with an angle pin during mold operation. Again, the heat treatment process adds expense and delay as this is typically a specialty service.

During operation, the mold angle pin <NUM> will engage the disclosed angle pin bushings <NUM> or <NUM> in such a way that the pin will try to extract the bushing from the receiving pocket <NUM> during mold half separation and then reversibly drive the bushing deeper into the pocket as the mold halves close. The shoulder <NUM> on the pocket bottom prevents the angle pin bushing <NUM> or <NUM> from being forcibly pushed through the slide component as the mold halves close. The engineered retention clip <NUM> holds the angle pin bushing <NUM> or <NUM> in place while providing solid support at the top of the bushing as the angle pin exits the bushing. While the retention clip <NUM> could have varying geometries to accomplish this task, the disclosed clip geometry, as in <FIG> and <FIG>, provides support behind the force receiving surface area of the angle pin bushing <NUM> or <NUM>. The disclosed angle pin bushing pocket <NUM> and retention clip recess <NUM> are disposed at matching angles to the hole <NUM> or slot in the slide component, such as the slide <NUM>, so that the pocket and recess depths are easily achieved and so that the pocket surfaces are parallel to the angle of the hole or slot, allowing a single set up regardless of the machine tool being used.

The angle pin bushing location and installation method within the slide parts yields benefits for both the molder and mold builder. For the molder, the location of the angle pin bushing <NUM> or <NUM> ensures that, as the angle pin <NUM> engages the bushing, the necessary force to function the slide motion is nearer to the proximal end of the angle pin, i.e., closer to the mounting opening <NUM> where the angle pin is supported in the second mold half <NUM>. A portion of the working end <NUM> of the angle pin extends through the angle pin bushing <NUM> or <NUM> and into the available clearance space or portion of the hole <NUM> below or beyond the angle pin bushing and the pocket <NUM>. Occasionally, the orientation of the angle pin hole <NUM> or the angle pin mounting opening <NUM> are formed or installed where the angle may vary by seconds or minutes, i.e., a fraction of a degree from the engineered specification. Without the angle pin bushing <NUM> or <NUM>, the tip of the angle pin <NUM> at the working end <NUM> may engage the slide at its tip where it is levered and then deflected, as represented by <FIG>. This may potentially create catastrophic failure of the pin and damage the mold tool.

With respect to the mold builder, in the instance of a large slide, the typical angle pin hole can be quite deep. Angle pin holes are required to be smooth along the entire depth of the hole. Creating a smooth and straight hole through a deep slide is limited to special equipment such as a Gun Drill. Gun Drilling is most often performed by a unique service provider who specializes in the Gun Drilling process. This now requires that the slide be shipped to the service provider, adding significant expense and delay for the mold builder. The disclosed angle pin bushings <NUM> and <NUM> allow for conventional drilling of clearance through a deep slide without concern for the surface finish of the hole through the entirety of the slide angle pin hole geometry. The angle pin bushing <NUM> or <NUM> provide smooth functional surfaces and the necessary machining of the hole <NUM> and the receiving pocket <NUM> in the slide is easily accomplished with conventional machine tool equipment.

Further, as best depicted in <FIG>, the angle pin hole <NUM> (or slot) in the slide <NUM>, the angle pin bushing <NUM> (or <NUM>), and the angle pin bore <NUM> (or <NUM>) are each formed having axes that are at least oriented parallel with one another, if not concentric with one another. The retention clip <NUM> abuts against the step <NUM> on the angle pin bushing <NUM> (or <NUM>) and is thus received in a portion of the pocket <NUM>, as well as the clip recess <NUM>. The retention clip screw hole <NUM>, the threaded bore <NUM> in the slide <NUM>, and the screw <NUM> retain the angle pin bushing <NUM> (or <NUM>) within the hole <NUM> (or slot) and are installed in a direction parallel with the angle pin hole. The retention clip <NUM>, screw hole <NUM>, threaded bore <NUM>, and screw <NUM> also each have axes that are at least parallel with each other and parallel with the axes of the angle pin hole <NUM> (or slot), angle pin bushing <NUM> (or <NUM>), and angle pin bore <NUM> (or <NUM>). In this arrangement, all of these various axes are parallel with the axis of the angle pin hole <NUM> (or slot). Thus, when forming the slide pocket <NUM> in the body of the slide <NUM> for the angle pin bushing <NUM> (or <NUM>) within the angle pin hole <NUM> (or slot), which is done using a milling machine, all the various surfaces and holes can be formed without having to reposition the slide <NUM> to another angle to form the bushing pocket <NUM> and retainer clip recess <NUM>. More specifically, the angle pin hole <NUM> can be drilled, the bushing pocket <NUM> can be formed, the clip recess <NUM> for the retention clip <NUM> can be formed, and the screw hole <NUM> and threaded bore <NUM> for the retention clip <NUM> clip can be drilled, all along the same axis angle, without having to reorient the slide <NUM>. This geometry thus simplifies the fabrication process while still offering the many benefits of utilizing the disclosed angle pin bushings.

The angle pin <NUM> is oriented at a desired angle to create a desired amount of movement of the slide <NUM> in one direction as the second mold part <NUM> is moved in a different direction. In one example, the slide <NUM> may move in a horizontal direction, back and forth, depending on whether the mold is opened or closed. The mold part <NUM> may move in a vertical direction, up and down, perpendicular to the slide movement direction. Other varied relative movement directions are possible as well.

As noted above, the configuration and construction of the disclosed angle pin bushings can vary considerably and yet function as intended. Only a very few of the many possible examples are described below. Referring to <FIG>, one alternative example of an angle pin bushing <NUM> is shown. In this example, the angle pin bushing <NUM> is split into two separate bushing parts 122a and 122b. Each part 122a and 122b has a bearing face <NUM>, which face one another, and which define the saddle geometry of the bushing <NUM>. Each bushing part 122a and 122b has a separate fastener hole <NUM> for securing the angle pin bushing <NUM> in an angled pocket of a slide. The parts 122a and 122b may be tapered in height across the angle pin bushing <NUM> so that an angled pocket, similar to the prior examples, can be used in the slide, leaving the top faces flush with the slide and the bearing surfaces oriented at the angle of the angle pin.

<FIG> show another alternative example of an angle pin bushing <NUM>. In this example, the angle pin bushing <NUM> has a rectangular body <NUM> that includes four fastener holes <NUM> surrounding an angle pin bore <NUM> for securing the angle pin bushing in a rectangular pocket of a slide. The angle pin busing <NUM> may otherwise be similar to the prior described angle pin bushing <NUM>, <NUM> examples.

<FIG> show another alternative example of an angle pin bushing <NUM>. In this example, the angle pin bushing <NUM> again has a rectangular body <NUM>, but instead includes only two fastener holes <NUM> adjacent a front side of an angle pin bore <NUM> for securing the angle pin bushing in a rectangular pocket of a slide. The angle pin bushing <NUM> may otherwise be similar to the prior described angle pin bushing <NUM>, <NUM>, <NUM>, examples.

<FIG> show another alternative example of an angle pin bushing <NUM>. In this example, the angle pin bushing <NUM> again has a rectangular body <NUM> with two fastener holes <NUM> adjacent a front side of an angle pin bore <NUM> for securing the angle pin bushing in a rectangular pocket of a slide. However, in this example, a top face <NUM> and a bottom face <NUM> of the body <NUM> are parallel to one another. Instead, the angle pin bore <NUM> is oriented at the angle of the angle pin relative to the orientation of the top face <NUM>. In this example, and referring to <FIG>, a slide <NUM> is formed having a pocket <NUM> that is orthogonal or perpendicular to the orientation of the top and bottom faces <NUM>, <NUM> of the body <NUM>. An angle pin hole <NUM> is formed from the bottom, i.e., a step <NUM> of the pocket <NUM> and through the remainder of the slide <NUM>. The angle pin hole <NUM> is oriented at the same angle as, and is thus parallel with, the angle pin bore <NUM>. The diameter of the angle pin hole <NUM> is slightly larger than the diameter of the angle pin bore <NUM> to create the clearance space below the angle pin bushing <NUM> for the working end of an angle pin during use, as noted above.

The foregoing alternative examples are constructed according to the teachings of the present disclosure and illustrate that the angle pin bushing size, shape, features, and characteristics can vary from the limited examples shown and described herein. In another example, each of the alternative angle pin bushings <NUM>, <NUM>, <NUM>, and <NUM> eliminates the retention clip, retention screw, and clip recess in favor of using fasteners to directly retain the bodies of the angle pin bushings in the slide pockets.

The mold tool and parts, which incorporate a mold slide with angle pins and the disclosed angle pin bushings can also vary considerably. An injection mold tool is typically separated into two respective mold halves, as described above. These mold halves are commonly known as the"A" side and the"B" side of the mold tool. The mold tool often includes one or more slides located in either the"A" side or the"B" side of the mold. Typically, one half of the mold is the cavity or"A" side of the mold and the other side of the mold is the core side or"B" side of the mold. Leader pins or posts on the"A" side of the mold stand straight up and are aligned with or parallel to the mold open/close direction of the mold. When assembled in the closed position, the leader pins are typically aligned within holes and standard bushings located on the "B" side. The angle pins would then also be on the"A" side of the mold and would align with the holes or slots in the slide parts. The slides may typically move toward one another and as the mold closes. The size and productivity of the mold tool can vary widely, depending on the size and complexity of the parts, and thus the mold cavities. In one example, a mold can be a four-cavity tool with two opposing slides. In another example, the mold can have a dozen or more cavities and numerous complex slides. As noted above, the mold tools can be on the order of hundreds of <NUM>. 45Kgs (i.e. hundreds of pounds) or can be on the order of thousands of <NUM>. 45Kgs (i.e. thousands of pounds). The disclosed angle pin bushings are not intended to be limited to any particular mold type, size, or arrangement.

Claim 1:
A mold slide comprising:
a slide part (<NUM>) having a slide body (<NUM>) movable along a first direction, the slide body (<NUM>) having an angle pin hole (<NUM>) formed therein and defining an axis;
a mold part (<NUM>) adjacent to the slide part (<NUM>) and movable relative to the slide part (<NUM>) along a second direction different from the first direction; and
an angle pin (<NUM>) carried on the mold part (<NUM>);
wherein the first direction and the second direction are each not parallel with the axis of the angle pin hole (<NUM>);
characterized in that:
the angle pin hole (<NUM>) has a pocket (<NUM>) at one end thereof;
wherein an angle pin bushing (<NUM>, <NUM>) is seated in the pocket (<NUM>) and defines an angle pin bore (<NUM>, <NUM>) that is parallel to the axis of the angle pin hole (<NUM>); and
a portion of the angle pin (<NUM>) is positioned in and movable in concert with the mold part (<NUM>) relative to the angle pin bore (<NUM>, <NUM>) in the angle pin bushing (<NUM>, <NUM>) to move the slide part (<NUM>) along the first direction.