Oct 13/20

Commercial Plastic Recycling: How Your Company Can Profit by Recycling Scrap Plastic

 

When your company has scrap plastic, it has three options for disposal: incineration, disposal in a landfill, or recycling. Our World in Data conducted a study comparing the three options. Recycling is the best option, having the lowest impact on global warming and energy use.

Disposing of scrap plastic in your commercial waste hauling is expensive. So, you can slash that expense by participating in commercial plastic recycling. The process is good for the environment and profitable for your company.

Profiting From Commercial Plastic Recycling

By selling your scrap plastic you can save on landfill fees and receive money for your manufacturing waste. There are numerous types of recyclable plastics generated by businesses including

• High-Density Polyethylene (HDPE)
• Low-Density Polyethylene (LDPE)
• Polypropylene (PP)

The recycling company will pick up your recyclable waste plastic at your location. They will haul it to their facility for weighing and processing. Your company will receive payment at the plastic scrap price for recyclables.

The scrap plastic is no longer taking up space in your regular trash containers. Therefore, by reducing your standard waste disposal cost, you render instant savings.

Cost Savings

The cost of standard waste disposal includes paying for the trash container, collection, transfer, and landfill costs. In addition, you have to pay tipping fees of $25 to $150 per ton, depending on location.

If during a normal year you dispose of 500,000 lbs. of plastic scrap and the tipping fee is $50 per ton, you have a yearly cost savings of $12,500 in just tipping fees by recycling that plastic. Compound that savings with the reduction in hauling collection and transfer fees and the savings are impressive. Now add in the profit from the plastic your recycle.

Scrap market prices cycle up and down, so there are always variables in the profit margin. If we take a median scrap price of $0.20 per pound, that 500,000 of plastic scrap has now generated a profit of $100,000.

The reduction of waste begins with manufacturing plants taking steps to recycle and reuse materials. In the automotive industry, 80% of each automobile is recyclable.

Vehicle parts produced using plastic compression molding are lightweight, strong, and have a quick turnout make them a foreseeable industry standard. Plastic scrap from the production of floor parts, seatbacks, headrests, crossbeams, and the housing for airbags can all be turned into profit for your business.

Eco-Friendly Advantages to Recycling

In addition to the substantial savings to your manufacturing costs, having an eco-friendling business is looked upon favorably by consumers. Impact on the environment includes:

• There is currently an estimated 80,000 tons of plastic in the Great Pacific garbage patch
• Every ton of plastic recycled saves 5.77kWh of energy
• Recycling plastic waste can reduce up to 40% of oil consumption, or 16.3 barrels of oil per ton recycled
• Reduces C02 emissions emitted when manufacturing new plastic
• Every ton of plastic recycles saves 7.4 cubic yards of landfill space

Recycling is both a waste-management strategy and a profit strategy for your business. Industrial plastic recycling solutions can reduce energy use and protect our landfills, resulting in improved eco-efficiency.

Recycle for the Economy and Profit

Mayco International conducts its manufacturing business in a way that is environmentally responsible. Commercial plastic recycling is just one of the many ways your business can have a positive impact on the environment while earning a profit.

Therefore, contact us with any questions you have about becoming affiliated with a Tier One supplier that puts conservation first in manufacturing.

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Star Prototype is about to rebrand to Star Rapid! Along with the name change will come some updates to our logo and our brand colours. The rebrand also coincides with an of our 60,000 square-feet of facilities and significant investment of US $2.5 million into cutting-edge equipment

To make sure our name change runs smoothly, we’d like to answer some of the most commonly asked rebranding questions.

Can’t find your answer? Feel free to contact us at [email protected]. We’re here to help make the process as easy and painless as possible.

Q: What is our new company name?

Star Rapid Limited

Q: Why did we change our name?

We changed our name for a range of reasons, the main one being to better reflect the range of services we provide. Star Rapid provides much more than prototyping services. We also offer 3D printing, rapid tooling, low-volume manufacturing and a range of finishing services.

Q: What is the company’s address?

Office in Hong Kong – for purchase orders and invoices

Star Rapid Limited
Unit 04, 11/F, Tern Plaza, 5 Cameron Road,
Tsim Sha Tsui, Kowloon, Hong Kong, 999077

Facilities in China – For customer visits and shipments

Star Rapid Manufacturing Co. Limited
15 Huan Mao 1 Road Zhongshan Torch Development Zone, Guangdong Province, 528437, People’s Republic of China

Name and Address in Chinese

中山世达模型制造有限公司
广东省 中山市 火炬开发区 环茂一路15号

Q: Do you need to update your existing NDA or PO?

No, your current NDA and PO are still valid and legally binding. On your next project a new NDA will be signed using the name Star Rapid Limited but all current NDA’s will still be honored.

Q:  Will the bank’s financial information change?

Yes.  We are in the final stages of creating a new account under the new company name.  If you are a current customer you will be contacted by your account executive with the details once this is finalized.

Q: Can we still use the Star Prototype bank account details?

We will be encouraging all customers to update to our new Star Rapid account details. However, we will keep the Star Prototype account open for 12 months after the official rebranding launch.  If you have any issues updating your accounts talk to your sales representative or email us at [email protected] and we will try to accommodate.

Q: What if I can’t update the account details right now?

If you can’t update our account details right now let us know and we will try to find an alternative solution to accommodate your needs.

Q: When will Star Prototype officially change to Star Rapid?

We are currently preparing to change our name to Star Rapid. This will take place towards the end of 2016. We will send you specific details soon.

Q: Who owns Star Rapid?

Star Rapid continues to be 100% owned by British engineer Gordon Styles.

Learn more about why we are rebranding in our latest blog post. If you have any questions not mentioned here, email us at [email protected]

Wanxiang Qianchao Co., Ltd. and its affiliated company Zhejiang Wanxiang Precision Co., Ltd. have obtained a patent authorization for "A bearing detection method and system" (publication number: CN202410843397.4), which was submitted in June 2024. 

The patent overview shows that this invention belongs to the field of precision measurement technology, and aims to improve bearing detection methods and systems, especially to propose an effective solution to the problem of large bearing flange flatness measurement errors. The method includes assembling the inner ring of the bearing to the rotating shaft of the rotating component, and allowing one end of it to fit tightly with the end face of the rotating shaft. Then, a tensioning device is used to press the other end of the inner ring with a set pressure to make it in a predetermined position. After that, the driving part of the rotating component drives the rotating shaft and the inner ring to rotate at a specific speed. After a preset period of time, the drive stops. 

Subsequently, the stylus of the measuring instrument contacts the measuring surface of the outer ring of the bearing. In this state, the driving part is started again to drive the rotating shaft and the inner ring to rotate at different speeds, while the stylus collects measurement data. This method effectively reduces the error in the bearing flange flatness measurement.

The Future of Fashion: How Artificial Intelligence is Revolutionizing the Industry

In recent years, the fashion industry has witnessed a significant transformation, thanks to the integration of Artificial Intelligence (AI). From design to production, AI is reshaping how fashion brands operate, offering innovative solutions that enhance creativity, efficiency, and sustainability.

AI in Fashion Design

One of the most exciting applications of Artificial Intelligence in fashion is in the design process. AI-powered tools can analyze vast amounts of data, including consumer preferences, market trends, and historical sales data, to generate design recommendations. This not only speeds up the design process but also ensures that the final products are more aligned with consumer demands.

Virtual Prototyping and 3D Modeling

Another groundbreaking innovation is the use of AI for virtual prototyping and 3D modeling. Platforms like Style3D leverage AI to create highly accurate digital replicas of garments. This allows designers to visualize and tweak their creations in a virtual environment before moving to physical production, significantly reducing waste and costs.

Personalized Shopping Experiences

AI is also revolutionizing the way consumers shop for fashion. By analyzing individual preferences and browsing behavior, AI algorithms can offer personalized recommendations, making the shopping experience more enjoyable and efficient. This level of personalization not only boosts customer satisfaction but also increases sales for brands.

Sustainability and Ethical Fashion

As the fashion industry faces increasing scrutiny over its environmental impact, AI offers a path toward more sustainable practices. By optimizing supply chains, reducing waste, and improving resource management, AI can help brands minimize their ecological footprint. Additionally, AI can assist in ensuring ethical labor practices by monitoring and analyzing supply chain data.

Conclusion

The integration of Artificial Intelligence in the fashion industry is not just a trend; it’s a fundamental shift that is here to stay. From design and production to personalized shopping and sustainability, AI is driving innovation and efficiency across the board. As technology continues to evolve, the possibilities for AI in fashion are limitless, promising a future that is both stylish and sustainable.

Sep 20/21

Is Chrysler Still Making Cars? (The Answer Is Yes)

 

The Chrysler Corporation claims the Dodge Charger as one of its biggest successes.

It’s not easy to make it in the automotive industry because of the large amount of competition. If you’re a car junky, you’ve seen some dramatic rises and falls in the industry.

One name that’s had its fair share of ups and downs is Chrysler. They have an extensive history of hardship and success. Many people wonder if they’re still making cars today.

Chrysler is still making cars today. Check out our quick guide on the company below.

The Beginning of Chrysler

In 1925, Walter Percy Chrysler founded Chrysler. Instead of letting himself be sucked up by a major automotive corporation, he set out to start his own.

He knew his knowledge and skill would take him far, and he was right. Walter had gained his skills from past experience as a mechanic. He had even been the Executive Director for General Motors in their Buick division.

Flash forward through time and you can see his visions come to fruition- thanks to hard work and advanced technology. The company has created popular Chrysler cars such as the Chrysler Pacifica and Jeep Grand Cherokee.

Getting Through Tough Times

The company found itself filing for bankruptcy in both 1979 and 2009.

Chrysler struggled in 1979 due to the major oil shortage. They exhausted themselves and their resources by trying to keep pace with other major competitors. Unfortunately, they needed a $1.5 billion dollar loan to get themselves out of the hole.

In 2009, America experienced a major economic recession. Money had been greatly mishandled within Chrysler’s management, and they formed an alliance with FIAT to stay afloat.

Back and Better

If you’re driving around in a luxurious Chrysler 300, you’re probably shocked the company even had to go through those tough times. Don’t worry because they’re back and better than ever with the cars to prove it.

The company makes the only plug-in hybrid minivan, and their cars are loved for their comfort. Plenty of people are driving Pacificas, Voyagers, and Chrysler 300s today.

Buyers will notice the addition of parking sensors and blind-spot monitors in the new Chrysler 300 Touring L and 300S. In addition, those buying a Chrysler 300 now have the option of purchasing a new Comfort Group package.

A small secret you may not know is that the company also has relationships with some of the world’s best automotive interior suppliers, including Mayco International. That name sounds awfully familiar!

We’re Happy to Help

Chrysler, internationally known automotive company has rightfully earned its place. While it’s been through hard times, it still stands today as an empire.

Many Chrysler owners love the comfortable and well-made interiors. Mayco International is happy to help create dream cars for such appreciative consumers.

We offer high-quality service to automotive companies from design to delivery. Our services include engineering, tooling, logistics, manufacturing, and assembling. So, Contact us today for a quote.

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Drawing or painting a picture is a great technique to convey one’s thoughts. Within the broad concept of industrial design, engineering drawing or technical drawing is an essential skill for designers working with the production of real objects.

Engineering drawings use standardized language and symbols to accurately and visually communicate all the information required to manufacture a product or part.

This guide is designed to help you create a clear engineering drawing understanding that accurately communicates your design intentions to your suppliers.

How to use a technical drawing for engineering verification? Here’s a practical application.

Go Now!

What is Engineering Drawing?

Engineering drawings, also known as mechanical drawings, manufacturing blueprints, drawings, etc., are technical drawings that show the shape, structure, dimensions, tolerances, accuracy, and other requirements of a part in the form of a plan. It helps to define the requirements of an engineering part and conveys the design concept.

Engineers use engineering drawings to convey information about a particular object. The term “detail drawing” refers to a drawing that is commonly used to specify the geometry required for the building of a component. Even the most basic components require a lot of drawings to fully describe them.

An engineering drawing can be used as a starting point for the creation of more comprehensive manufacturing drawings, manufacturing blueprints, mechanical drawings, dimensional prints, and more. Detailed information about the drawing, such as who drew it and who approved it, is contained in a title block or information box.

Why Use engineering drawings

The engineering drawing of a single part provides a visual representation of the structure, dimensions, tolerances, and other requirements of a part. In the manufacturing industry, a single-part drawing is often used as the unit of processing.

An engineer can make use of an assembly drawing to show a machine/equipment that is assembled from several parts to achieve a certain function. Assembly drawings are often used to verify that the actual production of individual parts meets the assembly requirements.

How to Prepare an Engineeringl Drawing

There are two common methods of engineering drawing: manual drawing and computer drawing.

Drawing boards, paper, rulers, calipers, and round gauges are essential tools for manual drawing. Suitable for university courses, they play an important role in developing the spatial imagination and conceptual skills that underpin creative thinking in university students.

Computer drawing, commonly used in CAD software, is more suitable for the contemporary manufacturing industry. CNC machining centers equipped with CNC systems can read data and information directly from digital files and generate machining programs accordingly, saving time and effort. At the same time, computerized drawing facilitates the modification of drawings, on the one hand allowing different versions of the design to be retained, and on the other hand eliminating the tedious process of manual drawing.

The 3D model can also be used in machining centers but requires engineering drawings to communicate important information such as materials, tolerances, special requirements, etc. We usually recommend the use of a 3D model in conjunction with engineering drawings.

Basic Components of an Engineering Drawing

Title block

The document’s title in an engineering drawing block is found in the bottom right-hand corner of the page. Also known as the information blocks, it includes the part name, the names of the people who worked on the part (design, checking, and approval), the name of the company, the drawing number, and other relevant information.

In addition, it includes technical details such as the measurement units, the angle of projection, the surface polish criteria, the scale, and the material of construction. Title blocks are used for a better understanding of all the parts of the technical drawing.

Coordinates

In large or complicated technical drawings, coordinates are commonly employed and positioned along the drawing’s boundaries. When discussing the drawing’s content, these points of reference serve as a guide.

Types of Lines

An engineering drawing doesn’t have equal lines. A part’s visible and concealed boundaries, centerlines, and other details can all be displayed using the various choices. The following are the types of lines.

Continuous line

A drawing line, or a continuous line, is the most common. It’s a visual representation of an object’s physical boundaries. To put it another way, a continuous line is used to draw the real objects. Variations in line thickness are used; thicker lines are used on the outside contour and thinner lines are used on the inner contour.

Hidden lines

Lines that are not visible to the naked eye can reveal information that would otherwise be obscured by the designs. The length of an interior step in a turned part can be shown using hidden lines instead of a section or cutout view.

Center lines

Parts with holes and symmetrical features can be shown by using center lines. Symmetry can reduce the number of dimensions in a drawing and make it more visually appealing, making it easier for the reader to comprehend.

Dimension lines

Extension lines are used to describe the data being collected. Two arrowheads separate the extension lines on the dimension line from the measurement above (or inside, as shown in the image above).

Broken view lines

When a view is broken, break lines appear. In the case of a part that is 3000 mm long and 10 mm wide and has the same geometric qualities, a break-out provides all the information without taking up too much space.

CNC machines necessitate complete views of the workpieces in order to cut them. Alternatively, the manufacturing engineer will have to re-create the entire part from the measurements alone.

Cutting plane lines

The cutting plane lines illustrate the path of the cutout in a cutout view. The A-A cutting line may be seen here bringing both types of holes into view.

Dimensions and Measurements

A Dimension is a numerical value that expresses the size, position, orientation, form, or any other geometric properties of a part in the relevant units of measurement. Dimensioning, thus, is the process of depicting on a drawing the size of an object, as well as any other data critical to its design and operation, by means of lines, numerals, symbols, notes, etc.

An object’s shape and size must be known before it can be constructed. As a result, an engineering drawing depicting the object’s form, dimensions, and other pertinent data is required. The size and location of various characteristics of the object are indicated by providing the dimensions. For example, it is used to determine the object’s dimensions, the name of its parts, and the diameter of the hole.

In addition, when parts are machined, it is often difficult to guarantee that a 10mm length can be 100% 10mm, and the final product may be 9.9mm or 10.2mm. This can be done by defining tolerances to limit the upper and lower limit deviations and helping suppliers understand important dimensions.

Types of Views

Used to express the external structure of the part shape. There are basic and auxiliary views, the latter including oriented view, a partial view, and an oblique view.

Orthographic view

The orthographic view is the core of an engineering drawing’s content. A 2D representation of a three-dimensional object is called an orthographic view or orthographic projection.

Thus, a 2D view must provide all the information necessary for the production of a part. Any length distortion is avoided with this representation.

As the most common method for conveying all the necessary information, multiview drawings often include three views:

• Front view
• Top view
• Side view

It’s conceivable that a few extra views are required to display all of the information. Less is definitely more.

Regionally, the views are a little different. Compare the US and ISO layouts by taking a look at this image.

Drawing layouts in ISO and the United States are in direct opposition to one another.

The one on the left is known as a first-angle projection. There is a top view, a front view, a side view, and so on in this arrangement. In Europe, the ISO standard is most commonly used.

A third-angle projection may be seen to the right of the image. All of these images are arranged in chronological order. The United States and Canada are particularly fond of this arrangement.

Isometric view

The figure above is an example of an isometric view. Isometric drawings depict three-dimensional objects. When compared to the front view, all vertical lines remain vertical, and parallel lines are depicted at a 30-degree angle.

Vertical and parallel lines have the correct length. Using a ruler and the scaling of the picture, for example, you can simply measure the length of a paper drawing. Angled lines are not the same.

It’s critical to know the difference between an isometric view and a perspective view. In art, perspective views depict an object as it appears to the human eye. Engineers do not rely on optical illusions but rather stick to the facts.

Partial view

A partial view is a view obtained by projecting a part of an object onto the basic projection plane. Use arrows with letters to indicate the part to be expressed and the direction of projection, and indicate the name of the view. The local view can be configured in the form of the basic view or configured and marked in the form of the configuration towards the view.

Detail view

As a callout or segment in other views, a detailed view shows the model in its entirety. The detail view often depicts the model at a much finer level of detail than the parent view does.

Auxiliary view

An auxiliary view is an orthographic view for non-horizontal or non-vertical planes. It aids in the presentation of inclined surfaces without distortion.

Oblique view

An oblique view is a view of an object projected into a plane not parallel to the basic projection plane. The oblique view is usually configured in the form of a view towards, with an arrow with a capital letter indicating the direction of projection, and the same letter marked above the corresponding oblique view. If necessary, a rotated configuration of the oblique view is allowed. The capital letter indicating the name of this view should be near the arrow end of the rotation symbol, and it is also permitted to mark the rotation angle after the letter.

In actual production, the shape of the part is very varied, only the above views are not enough to express the internal and external shape and structure of the part clearly, for this reason, there are a variety of ways to express the shape of the structure of the part: sectional view, cross-sectional views, partial enlargement view, etc.

Sectional view

You can better depict the interior of a complicated object, such as an automobile’s engine block, by sketching the object as it would appear if cut apart. In this manner, the sketch’s many hidden lines are erased.

Sectioning is the practice of drawing an object’s interior structure by illustrating it as if it had been cut apart. Sectioning is a common feature of many industrial designs.

Sectioning the block above results in blocks A and B, as shown. An object in a painting or sketch can be sectioned in any way you like, just like an apple.

Full sectioning

This type of section is called a full section when a cutting plane line passes completely through an object.

Sectioning an object can be done whenever a closer look is necessary. This object has been cut into two halves, as you can see.

Semi-sectional view

When the part has a symmetrical plane, the graph projected on the projection plane perpendicular to the symmetrical plane can be bounded by the symmetrical centerline, half of which is drawn as a sectional view and the other half as a view. This sectional view is called a semi-sectional view. The semi-sectional view is used for symmetrical members whose internal and external structures need to be expressed. The dividing line of the semi-sectional view is drawn with a single dotted line. Due to the symmetry of the graph, the internal structure of the parts has been clearly expressed in the section, and no hidden lines are drawn in the view part.

Broken out sections

Views with broken-out sections can be used to reveal the model’s inner details by cutting away material at a predetermined depth. The broken-out part is defined by a closed profile, typically a spline. Users can enter a precise depth or reference a place in another view to specify a depth.

Cross-sectional views

With respect to an object’s cross-sectional area, the orthographic projection of that object’s cross-section is equal to its overall area. A cylinder of height h and radius r, for example, has when seen in an orthogonal direction and along its central axis.

Partial enlargement view

The use of partial views in technical drawing documentation makes it easier to provide the needed details on parts. A lot of the time, it’s easier to show more detail about a part when you use partial views of the part.

Assembly Drawings

Engineers often make the mistake of trying to incorporate all the information about each individual part in an assembly drawing. This can be avoided if you keep in mind that the goal of these technical drawings is to facilitate the assembly process.

In order to accomplish this, you can utilize tools like section views, numbered pieces, general dimensions, cuts, and detail views (or close-ups).

Regardless of the method of attachment, it should be apparent where each component goes and how it is attached. For your benefit, make sure the bill of materials has accurate information about part numbers, names, and quantities. All of this will help you design assembly drawings that will make your projects in the machine shop more efficient. 

4 Common mistakes in engineering drawing

1. Dimensions marked incomplete, messy, omission, and repeated marking.

(1) The important dimensions of the parts must be marked directly.

(2) Avoid the appearance of closed dimensions.

(3) Mark the size to facilitate processing and measurement.

2. View errors. Views are incorrectly placed or do not correspond to each other and do not clearly express the design intent.

3. Workpiece dimensional accuracy requirements are high but not marked dimensional tolerance, resulting in large machining errors and scrap workpieces.

4. The technical requirements of the parts (including dimensional tolerances, form tolerances, and surface roughness) are not marked standardization.

Conclusion

For designers, engineers, and machinists, engineering drawings are one of the best ways to communicate ideas and perspectives.

Designers and engineers clearly draw part features and communicate important information through drawings to help suppliers accurately capture key information, understand design intent, and develop machining solutions. 

At WayKen, our experienced engineers and machinists can analyze all aspects of engineering drawings and give timely DFM feedback to ensure you always get the best-machined parts. Upload your CAD files and get a quote today!