Greenomics Corp.Greenomics Corp.<div class="ExternalClassCADE4161F03F4EDE8178C0F7F4C9668C"><p>Aiming to use renewable resources, non-toxic and biodegradable materials wherever possible, Greenomics Corp. transformed content from corporate team sustainability workshops into an entertaining board game which is now available for professionals and families alike.</p><p>The game box and board are made from post-consumer recycled paper. They were designed to not require glue, and be hand-assembled. By basing the design on standard sizes of paper, paper off-cut waste from manufacturing was minimized to approximately 1% of the overall material used, and the off-cuts are recycled. </p><p>Materials for the bulk of the game are sourced and manufactured locally, reducing shipping upstream. In case of breakage or loss, Greenomics ships replacement pieces for a nominal shipping fee.</p><p>After use, since non-toxic soy and water based inks have been used in the game board and box, they can be both recycled and composted. The plastic play-pieces are recyclable HDPE. Disposal considerations are explained in the game’s instructions. The Greenomics team continues to look for alternatives to their dice and resealable plastic bag used to contain the game pieces.</p></div><div class="ExternalClass3C5D827E5A154D96B37CCE89D0CE8AE0"><p>Greenomics the Game engages teams and families in sustainability as entertainment and team building. The game board and box are made from post-consumer recycled paper and the design eliminates the need for glue. The game pieces are made from recyclable HDPE.</p></div>Greenomics the Gamehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-large.jpg, Largehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-600x600.jpg, Image

 

 

<div class="ExternalClass308499D51C2C4ECD95595EBCEBF85504"><ul><li>Made from post-consumer recycled paper</li><li>Box and board require no glue </li><li>Hand assembled, durable and reusable</li><li>Recyclable or compostable parts after use</li></ul></div>100.00000000000090.00000000000000101011111111111101111RecycledRecyclable

 

 

https://www.greenomics.ca/, Website<div class="ExternalClassCADE4161F03F4EDE8178C0F7F4C9668C"><p>Aiming to use renewable resources, non-toxic and biodegradable materials wherever possible, Greenomics Corp. transformed content from corporate team sustainability workshops into an entertaining board game which is now available for professionals and families alike.</p><p>The game box and board are made from post-consumer recycled paper. They were designed to not require glue, and be hand-assembled. By basing the design on standard sizes of paper, paper off-cut waste from manufacturing was minimized to approximately 1% of the overall material used, and the off-cuts are recycled. </p><p>Materials for the bulk of the game are sourced and manufactured locally, reducing shipping upstream. In case of breakage or loss, Greenomics ships replacement pieces for a nominal shipping fee.</p><p>After use, since non-toxic soy and water based inks have been used in the game board and box, they can be both recycled and composted. The plastic play-pieces are recyclable HDPE. Disposal considerations are explained in the game’s instructions. The Greenomics team continues to look for alternatives to their dice and resealable plastic bag used to contain the game pieces.</p></div><div class="ExternalClass3C5D827E5A154D96B37CCE89D0CE8AE0"><p>Greenomics the Game engages teams and families in sustainability as entertainment and team building. The game board and box are made from post-consumer recycled paper and the design eliminates the need for glue. The game pieces are made from recyclable HDPE.</p></div>Greenomics the Gamehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-large.jpg, Largehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-600x600.jpg, Image

 

 

https://www.greenomics.ca/, Websitehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-600x600.jpg, Imagehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-large.jpg, Largehttp://www.nzwc.ca/focus/design/portfolio/ProductImages/greenomics-small.jpg, Small

Pre-use involves all the steps from cradle (the origin of the materials) to the customers door; manufacturing/production, distribution and sale.
Sourcing resources that are rapidly renewed through natural cycles can reduce dependence on non-renewable materials. This promotes natural production systems that can continue indefinitely (in theory).
It’s important to consider compostability from the beginning. Material chemistry, processing additives, and trace elements (e.g. inks) can affect how well a product or package exceeds standards for compostable certification. These will also affect whether the materials are suitable for another industry’s use (e.g. methane extraction).
Minimize the environmental impact of a product or packaging by reducing the volume and/or weight of materials used. This “dematerialization” can happen both by making the item itself out of less material, and by optimizing the raw material extraction and manufacturing processes to reduce the amount of material used.
Byproducts are the materials created during manufacture that are not used in the final item. Planning the next use of these byproducts by another industry, or internally, can contribute significantly to waste reduction.
Reduce energy use wherever possible. Renewable energy to power extraction and manufacturing reduces reliance on non-renewable sources. Using energy efficient machinery further cuts resource and energy costs.
Reducing weight of a product and its package can considerably reduce energy use during transportation and manufacture; however, reducing the weight should not jeopardize product life span through reduced performance .
A package should protect its contents, and inform and appeal to the consumer without using excess material. Together, the product and package should be strong enough to reach the consumer without damage. The more efficiently it is designed for transport, storage and display, the better it is at reducing waste.
Some manufacturing techniques produce less waste than others. Low waste manufacturing processes consider effluent and byproduct control to limit the spread of waste, minimize materials used (e.g. additive manufacturing) or find uses for by-products (e.g. cascading subtractive).
Transport happens at all stages of the life cycle. Considering relative greenhouse gas emissions from different modes of transportation - rail, ocean, air, road – can be an important step, and an easy one to optimize in the production chain.
Optimizing energy efficiency and encouraging eco-efficient appliances influence how much energy is used once a product or package is in the consumer’s hands.
Consumer preference analysis can determine whether a product or package is actually meeting its intended use; a well-designed product reduces the chance of premature disposal.
Instructions are an opportunity to communicate value to the consumer. If a customer doesn’t fully understand how a product or package works or needs to be maintained, it opens the way for breakage, under-use, and early disposal.
Design to increase product longevity reduces the number and frequency of replacements.
The more prominent, catchy, and clear disposal instructions are, the more likely the consumer will be able to reach the goal of reducing waste after use. Better designs will accommodate regional infrastructure capacity for waste disposal.
If taking the product or package apart is complex, it can limit or prohibit disassembly post-use. Designing with fewer parts and design for intentional disassembly increases re-use, reclamation, and recycling.
Design for direct reuse is more efficient than disassembly or recycling. This means creating a product that can be directly reused at the end of life, without extra processing.
Byproducts, effluent, and even post-use products and packaging can supply another industry’s production line. This is called industrial ecology, or industrial symbiosis, and is arranged apart from consumer/municipal recycling systems.
Designing a product for a specific waste stream (e.g. recycling, composting, methane extraction) is first-stage systems thinking; collaborating with the waste handling industry is the next. Ensuring there is an end market for the product and packaging post use, and that this market is available wherever the item is sold, is integral to optimizing end-of-life.
Designing for recycling is a basic and accessible way to reduce waste after use. The recycling industry collects commonly used materials, processes and sells them into a new system of production. This can be an energy and transport-intensive process, and usually results in downgrading of materials over multiple recycling cycles. Designing for optimal recyclability and up-cycling (recycling to a product of equal or higher value) is a next-level way to approach this principle.
Composting is the recycling of organic materials – biological nutrients to feed rapidly renewable resources. Not all products or packages can or should be designed to be compostable, but some industries are especially suitable for it, such as foodware and food packaging. Designing a compostable product requires careful consideration of materials, certification, and that the conditions required to compost are met in the market area.