How Industrial Design Engineering During Production Can Improve Your Final Product

Industrial design engineering being applied during live production


As meticulous as your design teams were during the development and testing of your product, there is still work to be done. Your production team will need to continue monitoring products during the manufacturing process. This is where industrial design engineering can have its greatest impact—helping you to ensure the utmost quality and integrity for your product.

Understanding How Industrial Design Engineering Works

Although on the surface a broad term, industrial design engineering can be broken down into several elements. These will apply to all stages of the product development lifecycle but will do so differently than during the actual production stage. Below are a few examples of what these tasks are, and how they apply to the production stage of a product’s lifecycle.

Industrial design engineering being applied during live production

CAD Tools

The advantage of CAD software is the ability to make design changes whenever necessary. This advantage gains teeth when a product is in the manufacturing stage, as production defects can be quickly redesigned and tested without having to go through the full prototyping process. The finalized changes can then be quickly sent digitally to production management teams.

Quality Control

Defects noticed during and post-production requires the eye of an expert to fully diagnose and make an informed diagnosis of the issue. Having a team of experienced quality design engineers on hand will allow you to quickly make these tough decisions with the necessary confidence and accuracy, minimizing the impact of related manufacturing delays.

Create a Rapid Response Playbook

Otherwise known as quality assurance, this well-defined set of quality and production guidelines will keep your lines moving. The systemic functionality of a comprehensive quality assurance plan minimizes risk through planned auditing tasks that adhere to strict guidelines. This also reduces delays in getting the right people on the right task for faster resolution.

Letting the Industrial Design Team Drive Production

As the above demonstrates, putting your industrial design team on point to drive production is an effective strategy. Having proven quality assurance and control processes in their pockets and the innovative CAD tools at their fingertips, a team of industrial design engineers can efficiently drive production with a minimum of risk.

Validate Trueness to Design

The best way to resolve an issue is to prevent it from ever happening. The industrial design engineer accomplishes this during manufacturing by evaluating all aspects of production, from the proper calibration of production machinery to finely detailed measurement comparisons of final production items and physical prototype models.

Provide Rapid Response Engineering Tasks

When a problem is identified, the last thing you want to do is to hold countless meetings to determine an appropriate response. Placing an industrial design engineer at the head of the table will bring a fully scripted, largely automated response that can appropriately resolve almost any issue that arises during production. This minimizes downtime and ensures consistent product quality.

Supervise the Entirety of the Production

While seemingly outside of the technical expertise of an engineer, it will be these analytical viewpoints that can add better efficiency to production. Giving your design engineering team the ability to monitor all aspects of the manufacturing process will allow them to make proactive changes. For example, they may see that a CNC machine may need to be calibrated more frequently, or recommend that its technician has been given additional training.

Building Brand Identity Through Industrial Design Actions

One of the most understated and often misunderstood attributes of industrial design engineering is its ability to create the brand identity of the product. The industrial design engineer typically is involved from the conceptual design of a product’s features and functionalities right on down to the nuances of appearances and tactile responses. Their high level of involvement throughout the various product design stages is perfect for helping to drive its identity in the marketplace.

The contribution made to the marketability of the final product is fairly simple to describe. The attributes that are integrated into the final design will have stemmed from a noted shortfall or gap in the marketplace. This means that a known potential customer base exists, and the features you are presenting are already geared towards catching the attention of this audience to help them solve a problem.

With the product performance already setting itself up for marketing success, the focus turns towards aesthetics, usability, and support. The most effective industrial design engineer will be able to build a product with all three of these in mind. They must also be able to translate tech-speak into documentation that is easily understood by the product’s audience and general laypeople. It is through these basics that a product’s course and success are largely determined.

Outsourcing An Industrial Design Engineering Team Will Yield Efficiencies

The improvements in efficiency and the promise of lowered risk are enough to convince most product teams that an industrial design engineering team is a necessity. But instead of planning for an increased staffing budget and talent recruitment, turn instead to a manufacturing partner that offers engineers as a part of one-stop product development and manufacturing shop.

Pacific Research Laboratories has a variety of talented and experienced engineers to offer for supplementing your product development team. Our team of experts is well-versed in all areas of the manufacturing process, from design to final production, and we specialize in machining and molding small plastic parts. To learn more about our services, please visit our contact page or call (206) 408-7603.

What is Contract Manufacturing? Definition and Applications for Your Product

Image illustrating the contract Manufacturing definition

The contract manufacturing definition is straightforward: it is when one company hires another to produce a product. What is decidedly less clear is how to apply this to your unique project. As with most things in life, even the simplest definitions can quickly branch out into complexities that threaten to trip you up. However, you can gain a firmer grasp on what contract manufacturing can provide for you by reviewing the answers to some commonly asked questions.

Is Contract Manufacturing Considered a Form of Outsourcing?

Since contract manufacturing involves one party reaching out to a manufacturing company to produce an item to spec, the answer to this is yes. The process starts when a business has created and tested a product to the satisfaction of its internal stakeholders and investors. They then reach out to a manufacturer that offers contract production services, ideally doing so exclusively, using the design specifications to produce the items.

Contract manufacturers can offer many attractive aspects not available to do-it-yourself or on-demand manufacturers. Discounts on materials, the ability to provide rapid prototypes to assist your final testing, and design assistance are all beneficial elements offered by an ideal contract manufacturer. These benefits gain steam when a localized manufacturer is chosen, which makes communications and distribution easier, and adds the “buy local” marketing aspect.

What Additional Attributes Should a Contract Manufacturer Possess?

Image illustrating the contract Manufacturing definition

Signing a contract with a manufacturer makes them an important business partner and a driving element of success for your project. It makes sense then to dive deeper into all that this partner provides to your project—and to understand their demonstrated success with similar projects—before signing. After all, this is a relationship that you will need to continuously monitor and manage to assure your customers and investors that only high-quality versions of your products make it to market.

With that in mind, here are several important items to keep in mind while selecting your manufacturing partner:

  • They should be a stable presence in the marketplace, including a high-value reputation and possessing sound financials.
  • The production facility must be well-managed and organized with an emphasis on safety and cleanliness.
  • Their quality standards must align to ISO certifications.
  • They must have the ability to quickly adapt production runs to align with customer demands.

Additionally, it is important to note the quoted costs by your manufacturing partner and to ensure that overruns or hidden costs cannot be added to the original estimate. This allows you to maintain consistency in the prices you quote customers and limits unexpected financial liabilities down the road.

Why Should I Use Contract Manufacturing for My Project?

The reasons for choosing to utilize the benefits of contract manufacturing will vary from project to project. However, several of the core advantages will be consistent regardless of application. Lowering of expenses is one, due to the competitive nature of manufacturing, and the obvious financial gain of not having to build or operate your own manufacturing facility. This removes much of the financial burden of maintaining ISO certifications or skilled staff.

Contract manufacturing allows your team to remain focused on the evolution of your project and its marketing. The ability to harness a U.S.-based manufacturing partner will limit cost points that international production could lead to, as well as minimize the effects of trade and distribution issues. A U.S.-based partner will present you with a quality assurance that better aligns with the features of your design.

Are There Any Drawbacks to Taking this Route?

There are several examples that can quickly fill the cons column when weighing the advantages of partnering with a contract manufacturer. But instead of listing the most common ones here, take note: the biggest drawbacks of outsourcing production, such as loss of control over quality or volume, can all be mitigated during your search. Refining your search process will instantly re-mediate almost all potential drawbacks, except for one potentially important area: your public relations.

One of the biggest drawbacks to outsourcing manufacturing is the potential of your brand as being perceived as a contributor to job displacement. Avoiding this hot-button topic can be minimized by choosing a local manufacturing partner that has a vested interest in fueling the business success of U.S.-based businesses, as well as those operating in the immediate geographic area. Staying local during your partner selection process will be a marketing point to be proud of.

Can This Contract Manufacturing Definition Suit Your Project?

The most accurate statement to make about the definition of contract manufacturing is that it can be molded and adapted to almost any project. This makes it necessary for you to know exactly what you need to bring your project from the drawing table to the customer. But sometimes filling in all of the gaps can be especially challenging. Thankfully, there is a local contract manufacturer that can lend guidance in each area to help get your project off to a running start.

Pacific Research Laboratories provides a complete team of experts to drive your product to its fullest potential. From the earliest stage of design to completion, our team works with you as a partner. This is because our greatest accomplishment is the success of our customers; successes that drive innovation. To learn more about our services, please visit our contact page or call (206) 408-7603.

Do You Need a Prototype for a Patent?

Product design workflow illustrating the answer to do you need a prototype for a patent?

The ideas you have are already worth solid gold in your mind. With an eye on innovation, you have conducted thorough research to ensure that your vision will succeed in the market. With a well-crafted design model conceived, the logical next step is to protect your intellectual property by obtaining a patent. But is a design and specifications enough to get a patent, or do you need a prototype for a patent application?

The U.S. Patent Office (USPO) states that it does not require applicants to submit a prototype. However, producing a prototype, especially a working prototype, has many advantages. In addition to demonstrating a more authentic representation of your idea, a patent will provide some regulatory and business benefits. These benefits will give you a higher level of legal protections from competitors while expanding the field of potential investors,

Building a Prototype Increases the Chances of Patent Approval

Product design workflow illustrating the answer to do you need a prototype for a patent?

For the sake of time and meeting project deliverables, it will be tempting to skip the project’s prototyping phase and secure a patent faster. This error is common and may elongate the time it takes for your patent to be processed. Without a prototype your design may fail to separate itself from similar patented ideas, forcing you either back to square one or, worse, to watch your plans succeed with a party that better represented the same idea.

The patent process requires you to submit as much detail as possible about the product in question. Patent law requires submitters to ensure that their application is detailed enough so that an industry expert could recreate your product using the details in your patent application. An excellent way to accomplish this with meticulous detail is to submit a working prototype along with any design details and specifications that go into the build.

Submitting a prototype with your patent application will provide proof of concept for your idea and give a patent examiner a concrete way to validate the specifications and functionalities you have provided. A prototype will reduce the financial or competitive risks associated with re-submitting a patent application or providing additional clarifications.

Are There Reasons for Patenting or Not Patenting?

A prototype helps determine whether or not to patent your idea. Using a prototype for patent purposes gives you the ability to perform a self-examination to assess your design’s viability. After evaluating if a patent is deemed a requirement, you will shorten your application process by having an interactive object to submit along with your application.

Some scenarios would qualify the patent process as an inefficient endeavor. For example, if there are already many similar products on the market, pursuing a patent may not be cost-effective. Also, patent filings are a very time-consuming process and, given the current three-year backlog at the U.S. Patent Office, may mean that your idea could be obsolete before it appears before an examiner.

Pursuing a patent for a unique design concept and is intended for distribution to even just a small audience is highly recommended. Protecting your intellectual property is only one piece of the puzzle. Starting the patent process will also protect your design and manufacturing partnerships from business and legal challenges. This insurance will grant your design team and investors peace of mind as your project steps closer to production-ready.

When is The Best Time to Pursue A Patent?

The adage, “timing is everything,” is especially true for patent filings. File too soon, and your application will likely be incomplete. File too late, and you run the risk that another party jumps in front of you with a very similar idea that leads to your application being denied. The balance lies somewhere in between, and there is no concrete answer that fits all cases. To find the right timing, you’ll need to dive a little deeper into your industry to choose the best patent timing.

The best time to pursue a patent should start with the drawing up of a conceptual design. This timing provides a protective measure for your initial idea and gives you space to invest in honing your product’s capabilities. Once your product has further matured in the development process, you can move to file a second application using the new design details in your product. It would be in this second filing that you would submit your prototype of choice.

This form of patent filing, while offering the most protection, will be more expensive. In addition to paying more filing fees, legal fees may contribute to costs. The next best option is to submit a patent application when you have a 3D, CAD-based prototype ready to go. This added definition will give your application more traction with an examiner and ensure that your design was appropriately vetted.

So Do You Need a Prototype for a Patent?

Although submitting a prototype with a patent application is not a requirement, it can improve approval chances. Your prototype can fully demonstrate your product’s capabilities when submitted as a part of a patent application. The expert advice of a manufacturing services provider will give you a prototype that fully expresses your idea and will be ready for the eyes of patent examiners and investors alike. 

Pacific Research Laboratories can work with you on a production-grade prototype for your patent application. Our engineering and design teams are ready to collaborate and facilitate your manufacturing goals from start to finish. To learn more about our services, please visit our contact page or call (206) 408-7603.

Digital Fabrication Process: Tools to Get You to Your Final Product

Showing the CAD portion of the digital fabrication process

Leveraging efficiency gains of the digital fabrication process brings some exciting and game-changing benefits to manufacturing. This computer-driven manufacturing process introduces higher accuracy levels in production and gives businesses a keener eye for quality controls. Products created using digital fabrication use three procedural classifications: additive, formative, and subtractive.

The process that drives your project to completion is consistent regardless of the chosen manufacturing method, meaning tools for each step in the digital fabrication process will also be consistent. The compatibility of tools and procedures allows you to develop a production strategy that can be effectively applied to all of your projects with little or no modification, allowing you to develop and manufacture high-quality items quickly.

Design Tools to Drive Your Digital Fabrication Process

You cannot start the digital fabrication process without first developing inclusive and efficient design procedures. A successful design stage will involve performing several fundamental tasks that must be well-thought-out to ensure the remaining steps’ success. At the core of your design strategy, these tasks must include:

  • Brainstorming design includes all stakeholders, especially engineers, CAD designers, sales teams, and product management teams
  • Encouraging an open forum when it comes to product feedback throughout the design stage
  • Choosing the right tools to create virtual representations and measurements of the product
  • Ensuring those tools can also be used for any future product development projects

The tools required to drive the design activities for digital fabrication revolve around the CAD drafting software you select. The most effective CAD drafting tool will provide the ability to test complex calculations in a virtualized environment, streamlining the next two steps in the digital fabrication process. A powerful CAD drafting toolset will also present you with the ability to create design templates and in-program design management to reduce errors and time.

Showing the CAD portion of the digital fabrication process

Prepare Your Product for Prototyping and Validation

With a precise virtual model of the product completed, you can focus on making a physical representation of your design. Creating a prototype of your design brings digital testing and validation to life. It presents customers with something that can be touched and interacted with to improve their feedback quality. This extra layer of scrutiny in the development process shortens the testing time and lowers overall design costs.

The tools required to accomplish this takes on an additional physical form through the use of necessary machinery and materials to build a rapid prototype. Digital renderings of the product and selection of materials will help your project team determine the most effective way to generate a physical prototype. In digital fabrication, the most common of these options will be through the subtractive CNC machining technique or the additive methodology of 3D-printing.

These options will give the same CAD software used in the first step of the process a new vital role. The ability to send a design directly to the manufacturing output method of choice via CAM data, and with very little need for human interaction, presents you with an almost “set it and forget it” approach when creating a prototype. Blending digital fabrication production tools with CAD technologies will have you ready to move into full-scale production faster.

Using Your Digital Tools to Ramp Up Production

The last stage of the digital fabrication process is suited to outsourcing to an experienced manufacturing partner. Taking this approach helps you avoid the common mistakes of scaling up production before there is a demand for the product or producing too high a volume to allow for in-flight product refinement. With your designs already tucked away in a digital file, transitioning projects to an innovative-minded third party can be efficiently accomplished.

Adding a valued team of engineering and manufacturing consultants to your project is simplified when using a digital fabrication process. In addition to the ability to send projects to your manufacturing partner without location limitations, the consulting team will likely possess a comprehensive digital design library at their fingertips. Such resources will provide an experienced and well-versed set of third eyes analyzing your project designs’ innermost complexities.

Some of the manufacturing options that you will gain when you leverage the skills and flexibility of a manufacturing consultant are:

  • 3D-laser scanning to ensure the utmost in product precision
  • The opportunity to utilize prismatic or non-prismatic geometry
  • Data-driven strictness in surface modeling and shaping
  • The ability to reverse engineer any part or product for reproductions or troubleshooting
  • Easy use of custom models or casts

These options provide a lot of insights into how you can utilize state-of-the-art manufacturing tools without investing in them yourself. You gain the advantages of low overhead costs, maximized flexibility in design and modification turnarounds, and getting your product into the marketplace fast, all without worrying about cutting corners on quality or intended features. It makes sense to consider an engineering and manufacturing partner as the best tool for creating your product.

Pacific Research Laboratories are waiting to bring your great ideas to life through the flexibility and power of digital fabrication. Our engineering and design teams are ready to collaborate with you to produce a product effectively using our ability to facilitate your manufacturing goals from start to finish. To learn more about our services, please visit our contact page or call (206) 408-7603.

What Are The Benefits of Short Run Production?

Graphic illustrating some benefits of short-run production

Long term production runs have been the de facto manufacturing standard for centuries. Once assembly machinery has been set up and configured, the goal has always been to produce a high product volume with no changes for an extended period. While this serves more extensive manufacturing operations, the high volumes and subsequent investment in materials and labor are overkill for smaller companies.

Before examining the benefits of short-run production, it is essential to understand that this does not necessarily refer to time or even specific quantities. The term applies to manufacturing bursts, such as for seasonal products, prototype development, or be used when raw material costs fall to a point where it makes financial sense to produce an item for wider margins rapidly. These, when combined with modern digital technology, have served to make short production runs highly beneficial.

Graphic illustrating some benefits of short-run production

Improved Cost and Inventory Controls

Perhaps the most attractive benefits of short-run production are seen in its ability to lower production costs while blending in precision inventory controls. Budgetary variables in short-run production are controllable and scalable, maximizing flexibility within a product lifecycle from the design phase forward. Many factors contribute to the cost savings in short-run manufacturing, including:

  • Reduction in physical manufacturing capacity
  • Streamlined strategic material purchasing.
  • Drop-in warehousing and storage space requirements
  • Increased flexibility in the design and testing phases of a product life cycle
  • Implement modern digital manufacturing tools, such as 3D printing
  • Time-saving ability to shelve or refresh a product when necessary

These benefits introduce savings in controlling inventory, avoiding overstock and cost overruns, and establishing just-in-time or on-demand manufacturing options without sacrificing quality controls or changes in market response times. Leveraging short-run production to create marketing campaign ramp-ups and a sense of exclusivity for seasonal or special event products will reduce inventory concerns. 

Take a Nimble Approach to Product Lifecycle Management

Product lifecycle management is one of the most challenging aspects of manufacturing and can determine a product’s profitability. In long-run production, you lose the ability to quaintly change gears in the face of market changes or when a customer requests modifications. This loss can potentially leave you with a warehouse full of products that must sell at drastically reduced price points.

Short-run production benefits offer a cost-saving edge for life cycle management, especially with product lines that customers anticipate as frequently changed. With the risk of overproduction and production cycle accessibility removed, your business becomes highly adaptable. Reducing the stress on production and distribution logistics opens the door to a data-driven, nimble product development strategy that makes accommodating present market conditions efficient and successful.

Short-run production places your design and engineering teams in a better position to stay fluid with customer requests and directly respond to evolving market trends. The use of modern CAD software will present you with greater flexibility during the design and testing process, even to the point of allowing customers to participate in feature testing from anywhere. This collaboration makes the customer an integral part of lifecycle management and builds their trust in your processes.

Flexibility with Customer Requests

Shortening your product runs and making them more manageable will allow you to focus more on the customer. The cost savings that naturally occur in a short-run manufacturing environment can quickly be passed down to the customer, as can design and modification flexibility, keeping your products aligned with market fluctuations. But there is more to this approach, especially when you have an eye on providing consistent quality and exceptional customer service.

The manageability of short-run production will make it easier to generate new product variations that can be tested with existing customers without sacrificing valuable manufacturing cycles. The flexibility built into short-run production will allow you to expand into new markets, providing rapid and cost-effective market testing before committing to larger investments of time and money. This enables you to continue to wow your current customers while developing new strategic partnerships to fuel growth.

Presenting your customers with malleable product options provides all parties with new opportunities to develop cutting-edge product enhancements. As discussed earlier, the quick production of seasonal or limited edition variations won’t require any additional financial or time investments. New partnerships can reveal innovative options to produce with your customers and the engineering staff’s co-investment.

Start Seeing the Benefits of Short Run Production

Enacting a short-run production strategy requires you to have all of the organizational pieces in place. From design and production to marketing and support, your project processes must be as flexible and efficient as your manufacturing process. Quality cannot be sacrificed, and neither can your ability to deliver products, with modifications, that your customers expect to have at their convenience.

The most successful use cases of short-run production efforts involve the support and industry prowess of an experienced manufacturing partner. A third party partner will be well versed in the cutting-edge tools and methodologies used to produce and deploy products in a short-run manufacturing scenario.

Pacific Research Laboratories will guide you through the process of moving towards a short-run production model by using all of the tools and experience that our engineering team has to offer. We will establish a set of best practices and will develop a data-driven production strategy that drives results while maintaining a high level of quality your customers have come to expect from your brand. To learn more about our services, please visit our contact page or call (206) 408-7603.

What is the Reverse Engineering Process?

a 3D scan is performed as part of the reverse engineering process

Reverse engineering is a term used to loosely describe the process of deducing how a product works. It is rare though when standard reverse engineering processes are used, or even considered. Like forward engineering—which is always used in the product development process—reverse engineering has proven steps that can add consistency to a convoluted set of tasks.

Where Does Reverse Engineering Make Sense?

Unlike forward engineering, reverse engineering needs often stem from the question of how a product works, lacking CAD drawings, mock-ups, or documentation to reference. Some of the most common ways reverse engineering is used in a manufacturing environment may include:

  • Create or re-create missing digital models of products.
  • Build additional products or parts without drawings or schematics.
  • A part or component of a product is no longer being produced.
  • Re-design of defective or under-performing products.
  • Refresh out-dated manufacturing methods or types of materials.

Reverse engineering is useful from a quality assurance standpoint. Disassembly of all components and pieces will yield a greater understanding of how well a product was constructed. This process grants the opportunity for tolerance measurements to be conducted post-assembly, ensuring that material strength and measurements are as expected. Additionally, protecting yourself from patent infringement may require reverse engineering of a similar competitor’s product.

Accurate Information Gathering Is the Foundation of Reverse Engineering

The data gathered during the reverse engineering process will serve as a virtual sketch, ideally to be displayed within powerful CAD software. Capturing this data from the part of the product you are seeking to reverse engineer will be the same regardless of your end goal. Measurements must be precise, and nuances such as material types down to the exact tension of screws must be tediously recorded for later analysis.

The technology required to take and record these measurements while vigilantly tracking them all will vary from project to project. Traditional tools, such as calipers, depth gauges, and scales, will reveal only some secrets of the products you are working with. Advanced technical options, like laser scanners and 3D scanners, will add a high degree of precision to your measurements. Cutting-edge tools present you with 3D data outputs that can be imported into CAD for further refinement.

a 3D scan is performed as part of the reverse engineering process

Create Accurate Models Using Accurate Data and Measurements

With the measurements now complete, and all observations recorded, your computer should hold the detailed dimensions and specifications of every aspect of the product you’re working with. From there you can begin the virtual building of the item within CAD software for analysis and manipulation. The automated functions contained within CAD software will deliver highly accurate and easy to understand final results.

Powerful CAD software can build a virtual representation of the product being reverse-engineered, presenting you with cost-effective, and time-saving options. The digital nature of the drawings will allow for collaboration regardless of geographic proximity to the project team or the actual product. You’ll be able to translate the interpreted product into a physical representation faster and with greater production agility.

Build Your Prototype

After turning data into a perfectly built and modified CAD drawing, the next step is to produce a physical object. Here you’ll resume the traditional steps of forward engineering with the production of a prototype. Those initial steps of reverse engineering may have provided you with a high-quality CAD drawing but added a time crunch to your time-line. If that’s the case, rapid prototyping is the perfect match for production.

There are many rapid prototyping options at your disposal, so choosing the one that’s best for your project will be determined by an in-depth analysis of the final CAD drawing and specs. 3D printing may be the best option for a reverse-engineered product, as you can accurately and quickly compare a produced prototype to the original design. This allows you to make finely tuned adjustments inside of your CAD design should the prototype need them.

Develop Your Reverse Engineering Process Based on Project Requirements

These steps will serve as a concise guide for establishing consistent reverse engineering protocols within your manufacturing processes. Given the broad spectrum of reverse engineering project types, as well as the unpredictability of results some adjustments will be necessary to match your specific manufacturing needs and goals. With the unexpected being an expected condition of reverse engineering, it’s advantageous to use external resources with experience in these processes. 

An engineering and manufacturing consultant can introduce the specific controls and tasks you need to accurately reverse engineer the parts and products specific to your production scenarios. They will introduce proven methodologies into an environment that promotes collaboration, communication, and accountability. As a result, your reverse engineering task runbook will be perfectly aligned to your manufacturing goals and drive improvements in all areas of your business.

The experienced engineers at Pacific Research Laboratories will guide you through reverse engineering best practices and will design a set of accountable processes that represent your goals. Our team will develop a communications strategy that keeps your project teams in coherence with each other in achieving project goals. To learn more about our services, please visit our contact page or call (206) 408-7603.