The following information defines the minimum requirements for Upmold injection molds produced by Upmold Engineering. Alternatives that will contribute to improved tool life, minimum wear, ease of molding, and ease of Manufacturing will be considered within the confines of the original quotation and Customer supplied mold design and build standards. The Engineering Manager must approve any deviations from the Upmold standards, and any deviations must be documented and approved by the Customer.
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Contents:
a) Upmold injection Mold Standard Description
b) Mold Series Description
c) Common mold steels and applications for Upmold molds
d) Drawing format and standards
e) Solid Model Geometry format, construction, and standards
A)Upmold injection Mold Standard Description
*Upmold:
Cycles: 50000 to 250000 Save
*Built for medium production. Upmold molds are not recommended for abrasive or corrosive materials without written customer approval, and appropriate plating of all part related items.
*All mold plates must be a minimum of SAE steel. AISI steel is commonly used due to price and availability of SAE steel.
*Core and Cavity blocks (In-solid designs), Core and cavity inserts, sub-inserts, and other non-moveable items are to be constructed with a minimum of P-20 steel.
*Slides, lifters, bar ejectors, and similar actions can be constructed of P-20 steel also, but must have a minimum of 3-degrees shut-off on all seal surfaces. Nitriding is required otherwise, as in the case of straight wall lifter designs. Hardened S-7 steel should be considered for all lifter designs.
*Slides must have lamina bronze wear plates with grease grooves.
*Ejector plates must be guided with two guide pins and ejector guide bushings minimum. The amount will be determined based on the mold size and number of ejector plate activated actions.
*Integral parting line locks must have lamina bronze wear plates if the interlock angle is less than 10-degrees. Standard inserted hardened interlocks are acceptable as the part design permits. All interlock designs must protect internal shut-offs.
*Cooling is required in all part-related features insofar as possible, and in mold plates as required for specific temperature control, such as in plates encompassing hot runners, valve gate actuators, etc.
B) Mold Series Description
C) Common mold steels and applications for Upmold molds
Defines the common steel types and their applications.
Examples given are the most common types as used by Upmold. The Customer will specify the general steel types.
HRS Hot rolled steel SAE : Ejector housing plates, clamping plates, back-up plates, support pillars, mold feet (NOTE: Due to the limited availability of HRS, all mold plates can be / (#2) steel.)
/ (#2 Steel) Prehardened 30-36 RcC : General mold base plates
P-20 Prehardened 30-36 RcC : High grade base plates, large cores and cavities, core and cavity inserts, slides, sub-inserts
420M (Prehardened 420 stainless steel) Prehardened 30-35 RcC : large cores, cavities, inserts, slides
S-7 Air hardening 54-56 RcC Cavities, Cores, inserts, lifters, stripper rings, slides
420 SS Stainless 50-52 RcC Cavities, cores, slides, inserts
FP-100 Lamina Bronze Wear plates Must provide grease grooves.
O-1 Oil hardening 58-62 RcC Gibs, slide guides, wear plates
Ampco-18 Gibs, slide guides, and wear plates
D) Drawing format and standards
Defines the Upmold 2-D drawing layout and standard drafting aids for the Block-out, Preliminary, and final design drawings.
Final drawing 2-D Mold Layout to include:
E) Solid Model Geometry format, construction, and standards
Defines the Unigraphics Solid Modeling requirements, Upmold data layering specifications, Upmold construction techniques, general mold functionality fit and function standards, and Upmold design for manufacturability requirements.
Final 3-D Mold Data to Include:
Spruesrunners, and gates fulfill the function of conveying the plastics melt from the nozzle of the injection unit to the individual cavities.
While it is true that those plastic materials may be reused in the form of regrind, their presence nevertheless means a reduction in the performance of the injection molding machine since they must be plasticized in the barrel.
With smaller partsthey may account for 50 % or more of the actual shot weight.
plastic mold feed systemSprue
The sprue may be considered the continuation of the mold to the nozzle of the injection machine.
Single-cavity molds where the sprue links directly to the molded part are said to have direct sprue gating.
Very often, the performance of a single-cavity injection mold is determined by the cooling time of this sprue.
In addition to providing adequate cooling of the sprue bushing, the diameter of the smallest opening in the sprue bushing should be kept as small as possible and permitted by proper filling of the cavity.
No universally applicable rules can be given heresince filling the cavity depends on many factors.
The sprue should have a 1.5° draft.
A greater draft may simplify removal from the sprue bushing, but a function of the length of the runnersince it may be assumed that the pressure loss in a runner increases at least proportionally with the length.
In all likelihood, it will probably increase more than proportionally since the cross-section is reduced by solidification of the melt along the wallsand the more so, the greater the distance from the sprue.
Because the sprue and runner system represent lost material and lost plasticating capacity, the runners should be designed to be as short as possible and with the smallest possible cross-section.
The length of the runners is determined by the number of cavities in the mold and the geometrical arrangement of the individual cavities.
Runners follow channels cut into the parting line instead of sprues, which deliver material into the center of the mold plate. Their design affects part quality and molding efficiency.
Thicker runners can make filling pressures too high and cause unwanted long cycle times. Conversely, thick runners can cause unnecessary lengthening of cycle time and increases in costs associated with regrinding. The optimal runner design must strike a balance between mould feasibility and filling pressures.
During mold filling, freezing occurs as the heat of the melt is transferred to the mold. The result is less melting material flowing through the runner and a large pressure drop. The round runners create the smallest cross-sectional area of the frozen wall.
A trapezoid runner can be an alternative more effective than round runners because it only requires machining in one mold half. Round runners require the matching and low flow restriction of two mold halves.
The runner system in an injection mold is responsible for distributing the molten material from the injection point to the various cavities in the mold. The cross-section of the runner system refers to the shape and configuration of the channels and passages that make up the runner system.
More than 35% of the pressure required to fill the mold is often attributed to the runner system. To eliminate this additional pressure drop, optimize the route to each gate. For example, substitute diagonal paths or reorient the cavity to shorten the runner.
Factors such as runner thickness, packing density, and runner volume directly impact filling pressure and cycle time. To determine the optimum runner diameter, many factors have to be considered. These involve parts volume, filling velocity, filling pressure, runner length, and material viscosity.
Runners for multi-cavity molds are particularly important. A runner must be designed well so that each part is filled simultaneously during a single shot in a family mold.
By adjusting gate locations and/or runner section lengths and diameters, you can achieve balanced flow to each cavity while reducing over-packing and flash in the cavities that fill first.
In addition to providing balanced flow between each cavity, molds producing multiples of the same part should also ensure an equal distance between the injection machine nozzle and gate on each cavity.
The spoked runner is normally a choice. However, a spoked runner may not be very efficient as the number of cavities increases due to cavity spacing or cavities size increases.
When possible, it is preferable to arrange cavities in rows rather than circles. Runners are typically divided into rows consisting of main feed channels and sub feed channels at the ends of the flowing path.
Generally, the diameter of the runner increases as the increase in a number of cavities on that runner segment, since the flow path to each cavity must be of equal length and make the same number.
If the mold feed rate is constant, the flow-front velocity between each cavity will remain constant. If the press cannot maintain an adequate flow-front velocity, the number of cavities that can simultaneously be molded may be limited.
An artificially balanced runner can produce an evenly filled runner, thereby reducing the volume of the runner. These runners may have segments of varying diameters adjusted to compensate for the length differences of the runners segments.
A ladder runner, one of the most commonly used artificially balanced runner designs, contains two rows of cavities in a primary runner that equal-length secondary runners feed.
Typically, the sub runners of these cavities are made progressively smaller for the flows with the shortest distance between the sub runners. These designs require sufficient sub runners to balance the flow using reasonable sub-runner diameters.
A runner for three-plate molds burrows through the middle plate perpendicularly to the cavity parting line after conveying material along the runner-split parting line.
Projecting from the main runner, tapered drops are usually set on the part surface via pinpoint gates.
The drops in the mold reduce in size as they go toward the gate at a rate of approximately 0.5 inches per foot. Avoid the use of long drops since the taper can cause excessive thickness at the runner junction.
It is pretty common for three-plate plastic mold to be constructed with a stripper plate and sucker pins or some other device. Make sure these features do not hinder the flow of material.
The gate is a narrow intersection between the main runner and the mould cavity, and the intersection is also the shortest part of the whole mold.
Its function is to make the molten plastic enter into the mould cavity quickly, which is beneficial to the rapid filling of the cavity.
After filling, the gate is condensed first to block the cavity, prevent the melted plastic from falling and avoid the pressure drop of the cavity too fast.
Insufficient backup pressure would produce shrinkage holes or dent parts on the workpiece.
The edge gate side gaterepresents the simplest of gate designs; it is easy to make, and usually, a milling cutter can finish this job.
Although it is easy to produce, edge gates are severely restricted due to poor filling.
In this case, the overall strength of the plastic product obtained is poor, and the surface finish is also not good. The edge gate is usually used for plastic part quality requirements that are not very high or products without the appearance requirements.
In addition, it needs to cut off the gate later, which will lead to ugly scars.
Side gates are suitable for most injection molded products and many plastics (such as rigid PVC, PE, PP, PC, PS, PA, POM, AS, ABS, PMMA, etc.), especially for molds with multiple cavities.
It is important to note that small changes in the depth of the side gate can cause large changes in the flow of the plastic melt.
Therefore, the size of the side gate has a great influence on the quality and production efficiency.
1 easy to separate from the molded article;
2 shorter sun-runner;
3 easy processing and easy trim.
1. The limited location, the long distance from the gate to the cavity sometimes, and the large pressure loss;
2. short shot for poorly fluid plastics (such as PC) molding;
3. flat or large-sized molded articles are easy to be found bubbles or flow marks on the surface due to the small size of the gate;
4. hard gate trim and obvious traces.
The shape of the fan gate is gradually enlarged from the sub-runner to the cavity, like a fan.
It is suitable for flat, shell or box products. The flow pattern and orientation stress can be reduced.
The shape of the product determines the angle.
The gate cross-section cannot be larger than the runner cross-section.
This type of gate can be used for many plastics such as PP, POM, and ABS.
1. Evenly filling to prevent warpage of the product.
2. Reduce internal stress and deformation.
3. A molded article with a good appearance and almost no bad phenomenon.
1.Hard trim.
Design:thickness H = 0. 25~1.5 mm; Width =L/4, it should be greater than 8mm
In fact, the fan gate is an extended design of the side gate. It is used for the plastic part of a large area.
The fan gate is designed to reduce the warping of the product and improve the finish of the products surface.
To achieve a better surface, the contact area cannot exceed the cross-section of the sub-runner.
Due to the large size of the gate, it is difficult to trim, and the trace left is not small.
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The Diaphragm gate can be regarded as a special form of the annular gate and is mainly used when the center of the product has a larger diameter than the main channel. Suitable for PS, PA, AS, ABS injection molding.
1. prevent the flow marks.
2 runner machining effective.
3 same as the function of direct gate, less pressure loss.
1. Hard gate remove.
2. One time, just one part.
3.The center of the hole of the product must align with the main runner.
Diaphragm or disc gating can be used for cylindrical or hollow components when concentricity and weld strength is needed.
To balance mould fillinga minimum gate land length of 0.5 to 1.0mm is generally recommended.
The subsequent removal of the gate disc from the moulding tends to leave a sharply jagged edge about the rim of the component.
The positioning of the gate inside the moulding serves to reduce post-mold finishing operations.
Ring gates are commonly employed on cylindrical moldings when internal dimensions are more crucial than external.
A runner gutter is machined about the mould cavity and subsequently mirrored about the coreand land is machined connecting the gutter to the cavity wall.
Gate land depth is usually determined due to mould trials; shallow lands detract from the packing control of the mouldingwhereas over-thick lands create degating problems and lead to increased costs.
Spoke gates could be employed on mouldings that are often too large to diaphragm or ring gate.
They allow a larger volume of polymer to flow through them than either of the latter two designs.
In this case, component accuracy and weld strength are reduced in favor of volumetric throughput and packing control.
This design of the gate is suitable for thicker section cylindrically shaped mouldings with high shot weights.
The large gate remains usually require a machining operation to remove them after moulding.
Tunnel gating permits the automatic degating of the moulding from the feed system.
The gate is sheared off the component during the ejection cycle of the moulding process.
Tunnel gate diameters vary from 0.5-0.8 mm for unreinforced plastics to larger diameters of 2 mm plus for reinforced materials.
Due to the buried design of the gate, gas trapping and the resultant burning of the moulding surface can prove a problem in use.
Bearing this in mindadequate venting must be added to a mould that incorporates a tunnel gating design.
A gate scar is left on the molding surface, which subsequently increases in size as the gate shear land wears.
Pinpoint gates for three-plate moulds vary in size from diameters of 0.8 mm-2 mm for unloaded materials to 2.5-3 mm for loaded grades.
This design of the gate also permits the automatic degating of the mouldings during use.
The gate land is usually reduced in size to enable a clean break to occur upon separation from the moulded component.
Gate breakage is achieved by pulling the runner from behindusually by sucker or puller pins buried in the runners back.
As a result of reduced gate land thickness, pinpoint gates are easily damaged and tend to suffer from wear if loaded materials arc processed regularly.
The side-filling effect of the tab gate format reduces the likelihood of jetting or worming occurring when the melt flow exits the gate.
Tab gates are frequently employed to gate large decorative mouldings such as housings or instrument cases for aesthetic reasons.
The even fill pattern produced about the tab feature reduces the effects of stress-induced distortion or warpage once the moulding has solidified.
Tab features are expensive to remove from mouldings and should, therefore, be positioned in locations where they can be left on the component or have a useful function, e.g., as holding tabs for paint spraying or similar finishing purposes.
In essence, the flash gate is an extension of the fan gate.
They can all be used on flat or large-area parts. The warping of these parts is to be avoided as much as possible.
But flash gate subsequent processing will be very troublesome. Be careful when using it.
(1) The gate position should be selected on the parting surface as much as possible for easy removal and mold machining, so it is necessary to adopt the side gate instead of the pinpoint gate.
(2) The distance to the gate is as equal as possible from each cavity, and make the shortest flow path so that the melt can fill all the cavities simultaneously in the shortest time.
(3) The position of the gate should be selected at the wide and thick-walled section of the part, which is convenient for melt feeding and shrinkage.
This gate location does not lead to defects such as bubbles and shrinkage depressions.
When the melt enters the thick-walled section from the thin-walled section, re-injection occurs.
It will cause the melt speed and temperature to drop suddenly.
(4) Avoid the gate near the long and thin core to prevent the flow directly impacting the core to cause deformation or bending.
High temperature, high pressure and frequent impact on the weak insert make it bent or even broken.
The melt temperature is high, the pressure is high, and the frequency of impact on the insert is large.
If the insert is weak, it must be bent or even broken.
(5) if the injection molding requirements meet, the smaller the number of gates is, the better it is. It would reduce the weld marks.
If unavoidable, the weld marks should be designed on the products unimportant surface and non-weak parts.
However, multi-gates are recommended for large or flat products to prevent warpage and short shot.
(6) The gate should be beneficial to the mold venting.
After the melt enters the cavity, the venting groove (on the parting surface) cannot be blocked first.
Otherwise, the gas in the cavity cannot be discharged, which will affect the melt flow and cause defects such as bubbles, weld lines or short shots.
See Figure: If feeding from (a), the melt will first block the parting surface, which will cause (b) to be trapped.
(7) The gate location does not affect the appearance and function of the product.
As mentioned earlier, any gate will leave traces on the surface of the product.
To not affect the appearance of the product, the gate should be placed in the concealed section of the product.
However, due to the shape of the plastic parts, the gate must be externally set.
To do this, the gate should be made beautiful, and the situation should be told to the customer in advance.
(8) The gate should neither be too large nor too small.
If it is too large, the melt temperature will NOT rise when passing through the gate, and it wont be easy to prevent back-flow;
If it is too small, the resistance will be large, and defects such as jetting, cloudy spots, and the short shot will occur.
The size of the gate is determined by the size, geometry and type of plastic product. The small gate size should be taken first and then correct according to the trial result in the design.
(9) In a multi-cavity mold with a large filling bulk difference, the feeding balance can be achieved by adjusting the gate width dimension instead of the depth.
(10) The cross-section of the gate is 3%~9% of the cross-section of the sub- runner, and the cross-sectional shape of the gate is circular (point gate) or rectangular (side gate), and the gate length is 0.5~2. 0 mm, the surface roughness is not less than 0.4 um
(11) In the side gate mold, gating on the shut-offs should be avoided because the melt de-course sharply causes loss of the temperature and pressure.
When it is impossible to avoid, it is necessary to make a slope at the feed position of the shut-off to reduce the melt flow resistance.
(12)The number of gates: The number of gates depends on the ratio of melt flow L to the thickness of the products wall thickness T. Generally, each gate should be controlled at L/T = 50~80.
In any case, the L/T value must not be over 100.
In actual design, the number of gates must be adjusted according to the products shape, the viscosity of the melting plastic and other factors.
(13) The weld line caused by the position of the gate can be judged by experience or mold flow analysis, whether it will affect the appearance and strength of the product.
If it is, a cold slug well can be added to solve the problem.
(14) A cold slug well should be set near the gate (especially the sub-gate), and the puller should be set to facilitate the runner de-molding.
(15) The gate must be designed to have a rapid, uniform and unidirectional mold filling pattern.
(16)The position of the gate must be such that the air in the cavity can escape during injection molding. Otherwise, it will cause short shots or burn marks.
(17) If the gate location creates the weld lines, the lines should be designed to a suitable position.
(18) The position and size of the gate should avoid jet flow.
The gate can be enlarged to remove the jet flow, or the position can be changed to make the melt impact the mold wall.
(19)The condensing time of the gate is the maximum effective holding time of the cavity.
If the gate is properly designed, the backflow of the injected material can be avoided.
(20) The gate should be designed as short as possible to reduce the pressure drop across the gate.
(21)The normal gate thickness is 50 to 80 percent of the finished wall thickness.
The manual removal gate thickness is sometimes the same as the finished part wall thickness.
The automatic removal gate thickness is generally less than 80% of the wall thickness to avoid deformation when the gate is broken.
Pinpoint gates and sub-gate ends diameter typically is from 1 mm to 3 mm.
(22) Fiber-filled materials require larger gates to reduce fiber breakage as the material passes through the gate. Smaller gates, such as sub-gates or pinpoint gates, may cause fiber damage during filling.
(23) The gate should be designed a small size at the design beginning, so the size can be enlarged later if necessary (because it is difficult to reduce the size of the gate).
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