Having a proper tool design review and check list can and will save time to market. Here at Oakley, we have an internal tool design team that works across functions by performing design for manufacturability (DFM) throughout the entire process, from sketch and design engineering through CAD. This means when final product CAD is released to our tool design team, there is little to no request for iterations to enable a robust tool design.
The next step of tool design is designated to one person who takes that CAD and wraps a tool around it. The general design direction has already been determined by several CAD reviews and discussions with team members, so this person is responsible for managing cost, manufacturing difficulties and ensuring the design stays within the confines of the desired press size. If executed correctly, this task can save time in the manufacturing of the tooling, as well as initial tool start-up time and qualification. With typical tool designs taking 3 to 6 weeks to execute, high level decisions and innovations are implemented quickly – extra care must be taken to ensure that smaller details are not overlooked. Tool design is like a soup. The designer has insured that the movements required by part geometry are designed in (the meat) and the part has a gate to fill the part (the vegetables), and the tool fits in the press (the broth). Then the cavity and core blocks need the proper number of screw holes to retain it in the base (the soup bowl).
A tool design check list can be reviewed by the tool designer as he/she works through the design. It can be documented and reviewed with cross functional manufacturing teams prior to final tool design release to the build shop. These teams should include, but not be limited to, process engineering, automation, tool maintenance, PMO (post mold operation) teams, including representation from assembly and secondary teams such as paint and or decoration teams. All team members should have knowledge of desired end product needs and review the tooling for their individual needs (for example, does the tool design allow for end-of-arm to be used to remove a part from tool via a picker feature or does the tool incorporate a feature for the paint team to handle the part in their line?). We have asked for no fly zones and design needs from each of these teams and incorporated them into our tool design standards. This has decreased the time spent at tool start-up and product launch. Below is an example of what we have implemented into our design check list:
Does the tool fit in desired press?
Is the base material proper for class of tool ordered?
Are mold components made of proper material?
Will the part stay on the proper side of the tool for ejection?
Have mold inserts been reviewed for manufacturability?
Are runners proper size? Is the gate size and location correct?
Is the sprue puller correct? Does the Z puller pin have a ring vent?
Are runner shutoffs needed?
Are cooling lines/heater rods sufficient and appropriate to the material?
Is a thermocouple required?
Are insulator sheets needed?
Are water/oil fittings size and style correct?
Are parting line side locks or taper locks necessary and protect shutoffs?
Are there enough ejector pins, blades, ejection sleeves?
Are there adequate support pillars and stop pads? Is guided ejection needed?
Is ejection stroke sufficient and clears the part from tool?
Is positive spring ejection return needed?
Does tool need to be tied into ejection unit?
Is thin switch needed to verify ejection back?
Is an air blast and/or other ejection assist needed to clear part from tool?
Is slide and/or lifter travel enough to clear when part is ejected?
Are slides held in open position effectively? Are cavity and part identifications and date codes needed and in proper size and location?
Has venting been addressed?
Is there proper mold base relief?
Are mold components poka yoked and/or keyed for proper assembly and timing?
Are moving components checked for collision, clearance and orientation?
Is a quick change mold system used in-press to be utilized and will tool fit?
Are clamp slots or machine mounting holes correct and sufficient to hang tool in press?
Are there enough and correct eyebolt holes?
Is mold safety strap in proper location?
Is the locating ring diameter, sprue busing orifice and radius correct?
Are knock out locations and size correct?
Is mold identification and weight shown correctly and in proper location?
Are there enough pry bar slots?
Are leader pins taller than any other mold components above parting line?
Is surface finish defined in tool design drawings?
Is proper tolerance defined in detail drawings for dynamic and static fits?
Further Steps to Take Before Beginning to Design
Not necessarily part of the tool design review, but rather part of the DFM, are a few items to be considered before a tool design is started. Is there adequate draft for desired texture and part geometry? Is part geometry considered when developing parting line in part? Is the part influenced to stick in the correct side of the tool considering which side of the part can or cannot have ejector pin marks? Another constraint that should be looked at is the press tonnage sourced. As a quick check to ensure the press size can be utilized, I have found this rule of thumb helpful: take the square inch area of the part by taking a measurement of the extreme length and width of the part size as projected on parting line and multiply by the following values to calculate required clamp tonnage, using the higher value for thinner walled parts and the lower value for thicker, more even part geometry (see matrix below). This is usually dictated by the customer via press capacity and scheduling demands.
Smart moldmakers use a mold-design checklist to help ensure they don’t overlook anything. Most checklists that I have seen include details such as pry slots, insulator plates, steel types, safety straps, interlocks, etc. They all relate to the mold construction, but not the molding process.
Very few checklists are geared towards preventing mold-design problems that arise at the initial mold sampling. I’m talking about problems that cause the cycle time to be extended, the machine size to be larger, the labor requirements to be increased—or even prevent the mold from running in full auto mode. They don’t include any “what if” questions. What can be done if this or that happens during the initial mold trial? I call this a “Proactive Mold Design Checklist.” Merriam-Webster aptly defines proactive as “acting in anticipation of future problems, needs, or changes”.
The automotive and medical industries (as well as the military) insist on using all sorts of comprehensive checklists, with acronyms such as APQP (Advanced Product Quality Planning), PPAP (Production Part Approval Process), FMEA (Failure Mode and Effects Analysis), DOE (Design of Experiments), IQ/OQ/PQ (Installation Qualification/Operational Qualification/Process Qualification) and Mil Spec (Military Specification). Most of these checklists address the function of the part, or the repeatability of the mold and machine to make the part.
Reviewing the design of a mold is often a lengthy and complex process, and at times important elements can be overlooked amidst the morass of detail, created a mold design review form, based on experience in the company’s mold design review meetings, attended by mold designers, part designers and others involved in the project.