Category Archives: Manufacturer

Choosing the Right Metal Hole Saw

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Hole saws are cylindrical cups with a serrated edge to cut various sizes of holes in a variety of materials. The serrated edge is designed to cut the hole; the other end is designed to be driven by an arbor or drill chuck. There is a wide variety of hole saws available in the marketplace, from inexpensive carbon steel hole saws to extremely specialized, application driven hole saws. The most commonly used saw, however, is the bi-metal hole saw.

 

Advantages of Bi-Metal Hole Saws

Most users prefer a bi-metal hole saw for the majority of their work because it is compatible with a wide variety of materials. It also cuts faster and smoother and with reduced vibration due to the variable pitched teeth.

 

Hole saws have two different types of steel joined together to form the edge of the cutting end of the hole saw. High speed steel is joined to a soft spring steel to form a durable edge that will cut a multitude of materials and help provide long life. High speed steel is used on the outer edge due to its wear resistance properties and forms the cutting edge of the teeth. Soft, spring steel creates a flexible backing material that allows the hole saw to absorb impacts of the job of drilling holes in difficult-to-cut materials.

 

A good bi-metal hole saw will easily cut through softer materials, such as plastic and wood-based items, as well as harder materials, such as steel and stainless steel. The type of high speed steel chosen by the hole saw manufacturer will contribute greatly to the performance of the hole saw. The best bi-metal hole saws will be made with high speed steel that has a high percentage of cobalt content.

 

More important to users is the life they will get from their bi-metal hole saw, or how many holes they will be able to cut before needing to replace it. In addition to using high speed steel with cobalt, the heat treatment process used by the manufacturer will impact the life expectancy of the hole saw.

 

One common frustration users have with cutting holes with a hole saw is removing the plug, or slug, from the cup after the cut is complete. Look for slots that are accommodating to easily work the plug from the cup.

 

Tips on Arbors and Pilot Bits

Cutting a hole with a hole saw requires the use of an arbor and often a pilot bit. Arbors, also called mandrels, are designed to connect a hole saw to a drill chuck as well as hold the pilot bit. They are made from hardened steel and alloy steel components for long life, as they need to last through multiple hole saws. Arbors connect to the hole saw with a thread in the cap of the hole saw. Hol”-18 thread drives hole saws 1-1/4″ and larger. The larger hole saws (1-1/4″ and larger) also have drive pin holes in the cap which receive drive pins from the arbor to facilitate quick and easy changes of the hole saw. Smaller hole saws connect to the arbor only with the thread and often get locked onto the arbor requiring tools to remove the hole saw.

 

There are quick-change systems in the market to help with quickly changing small hole saws on the arbor without the use of supplementary tools. The best sawing systems are universal. They will operate as a quick-change system with any brand of hole saw. Also, look for systems that don’t require the use of any proprietary components or adapters to operate. These adapters often lock onto the hole saw and may require the use of tools to remove the hole saw and may not deliver the tool-free changes you are looking for.

 

Pilot bits take most of the punishment in hole saw drilling. Many users drill with some oscillation movement to help clear chips from the cut. This puts a lot of side pressure on the pilot bit.

 

When drilling holes with a hole saw, you need a complete system designed to deliver the performance you need to do the job. This means all components of the system, not just the hole saw, need to provide you with durability and performance. When you choose the right system, you’ll find that cutting holes has never been easier.

 

If you need more information or choice of hole saws, welcome to check out K&W Tools Co., Ltd. – the company has specialized in kinds of metal cutting saws and woodworking saws for years. To get more details of metal hole saws, please do not hesitate to contact with K&W.

 

Article Source: https://www.grainger.com/content/supplylink-choosing-hole-saw

Understanding Hydraulic Pump Types and Differences

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There are many types of machinery that are driven by or actuated by a hydraulic pump. There are a variety of different systems that are used to generate the flow and pressure required and they all have a hydraulic fluid and a system that controls the fluid and pressure with hydraulic valves. The pump needs to drive and this can be done by any force generating device such as an electric motor, an internal combustion engine, wind power or even a person operating a lever or crank.

 

How It Works

A hydraulic fluid is put under pressure by the hydraulic pump and the pressure can then be used to drive a piston or drive unit via hydraulic lines. A hydraulic valve is used to switch the force on and off to give control of the device. The control can be mechanical or electrical and may be actuated manually through a lever or a button or automatically through control system.

 

Volume and Pressure

There are many different hydraulic systems and they all used a combination of volume displacement and pressure to work. The higher the pressure the more robust a system needs to be because of the tremendous forces involved. In general higher pressure systems are more efficient and the higher the pressure the less flow is required for the same application of force. There are two general types of pumps fixed displacement types that displace the same amount of fluid every cycle and adjustable displacement types that can vary the displacement for increased or decreased pressure.

 

Pump Types

There are many different types of hydraulic pumps that have different applications. Screw type pumps are good for high volumes at relatively low pressure. They are simple and effective but not particularly efficient. A gear pump has a more balanced pressure and flow and is very simple but is not very efficient particularly as pressure increases.

 

The vane pump is widely used in system of medium pressure up to 150 bar and beyond. While the axial piston pump is used in applications that require the highest efficiency. Where high pressure above 300 bars is needed the radial piston pump combine high pressure and low flow rates needed in these applications.

 

If you need more information of hydraulic pumps, please come and visit ANSON Hydraulics Industrial Ltd. – they are the professional manufacturer of various vane pumps. You can find variable vane pump, fixed displacement vane pump, hydraulic power pack unit, and much more hydraulic pumps there. To get more details, welcome to check out their website and feel free to contact with ANSON.

 

Article Source: http://peerlessengineering.com/understanding-hydraulic-pump-types-and-differences/

Mountain Bike Suspension Forks – A Buyer’s Guide

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Mountain bike suspension forks vary massively when it comes to travel, shock damping ability, stiffness and weight – and that’s before we even get onto price, which can run into hundreds or even thousands of pounds.

 

That means it’s important to know what to look for when buying a new fork.

 

What to Think About When Buying A Fork?

  • Travel

Mountain biking is a very diverse sport and there are suspension forks designed for every type of bike: cross-country bikes generally offer 80 to 120mm of suspension travel, trail bikes range from 120 to 140mm, enduro and all-mountain bikes have between 150 to 170mm, and gravity/downhill rigs go from 180 to 210mm.

 

The first question is how much travel will work best for you? All other things being equal, the further your fork can move, the more smoothly it can absorb impacts. But longer-legged forks have to be heavier to cope with the extra leverage and bigger impacts.

 

An extra 10mm of travel will tip head and seat angles back by roughly one degree, which makes steering slower and more stable. Running too long a fork can also overstress your frame and void the warranty, so always check what the recommended travel is for your bike before upgrading. In general, it’s best to replace your existing suspension fork with one with that offers a similar amount of suspension.

 

That said, many forks have travel-adjust features. These either let you drop the travel in small steps to tweak the bike’s geometry and handling to taste, or crush it down dramatically to give a shorter, stiffer fork.

 

  • Budget

The next question is budget. Sadly, there aren’t many budget forks that deliver a smooth suspension stroke and stiff, screw-through axle structure without weighing a ton. Damping circuits are also simpler on cheaper models, which mean less control in high impact or multiple-hit situations.

 

There’s a clear progression in standards of control and consistency up to around £400 / US$670, but after that the waters get a lot murkier and it’s time to be honest about yourself and your riding. The overall performance and reliability of basic forks has definitely improved though.

 

  • Control

The more travel you have, the harder it is to control – which makes damping control paramount. You should at least get adjustable rebound damping so the fork returns smoothly to its natural ride height, rather than bouncing back up with a clang. More advanced forks also have compression damping to help the spring slow down and absorb the impacts.

 

Top-end forks split compression damping into two separate circuits – low speed for controlling loads such as braking, cornering or movement under pedaling, or high speed for controlling sudden large loads such as square-edged rocks or landings. Having lots of damping adjustment is only useful if you know what you’re doing with it and have the time to tune it correctly though, so be honest rather than pretending that you’ll become a pro suspension fork tuner overnight.

 

If you’re likely to plug the fork in, do the minimum setup tweaking and then ride it day in, day out without servicing it then you’ll want a simple but totally reliable unit. If you clean and care as much as you ride, then you can get something a bit needier. If you’re a real fork fettler who’ll spend hours with a shock pump and a safe cracker’s level of dial turning dexterity to find your suspension sweet spot then it’s worth having a full range of adjustments to exploit.

 

  • Strength / Weight

As well as travel and tuning, you need to think about how much strength you really need, or you’ll just be carrying extra weight you’ll never use. Light, tight forks will suit climbers and other cross-country riders, while super-plush traction Hoovers are worth the extra weight for progressive envelope pushers. Getting the right balance is really important. Fork strength is hard to gauge though, so go by the manufacturer’s recommendations.

 

  • Compatibility

Most modern suspension forks use tapered steerer tubes which measure 1.5in at the crown and 1.125in at the stem.

 

There are also three different axle standards to consider: 9mm quick-releases can still be found on some lower end forks, though the majority of cross-country and trail forks now use 15mm thru-axles. Longer travel suspensions forks for enduro and downhill frequently use 20mm thru-axles.

 

If you have any interest in much more bicycle front forks, I recommend you to visit BEV International Corp. – they are the professional bike parts and accessories manufacturer in Taiwan. You can find kinds of bicycle frames, front forks, saddles, wheel sets there. To get more information of front fork series, welcome to check out their website and feel free to contact with BEV.

 

Article Source: https://www.bikeradar.com/gear/article/mountain-bike-suspension-forks-a-buyers-guide-55/

Do You Know What Narrow Fabrics Are?

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Have you ever heard about narrow fabrics? If your answer is NO, maybe you will wonder what exactly the term “narrow fabrics” includes. Here is a short explanation of the type of fabric:

 

By definition, narrow fabrics are “any non-elastic woven textile having a width of 12 inches or less and a woven selvage on either side.” They are small strips of fabric, often designed for a specific and practical purpose. Cords, braids, and lanyards are commonly used items that are also narrow fabrics. They are woven on special looms, including the recently developed quad axial loom which allows for the insertion of yarn from four directions and makes both a thinner and stronger product than the traditional layered strips joined with Z fibers were.

 

Narrow fabrics were initially used in the garment industry on hats, corsets, and lingerie and in military uniforms as well. Nowadays soldiers will also find narrow fabrics in their pack webbing and parachutes as well as their waist belts, helmets, and body armor.

 

If you pay attention to the everyday objects in your life, you will see lots of narrow fabrics, from the seat belts in your car, to the leash you walk your dog on, to the tough fabric edging on your mattress.

 

Recently, as technology has advanced, narrow fabrics have been used to make 3D medical devices such as the woven bifurcate that is used to treat aortic abdominal aneurysms. The strong fabric device is threaded into place to support the artery and reduce the aneurysm. Eventually, as the patient heals, this device will become a part of the artery itself.

 

During a procedure used to replace damaged heart valves, a narrow fabric medical device is used to fish out any surgical debris after the new valves are in place. The future promises more such medical technology. Other commonly known narrow fabrics used in the healthcare industry include rigid gauze, bandages, and fiberglass bands.

 

And, of course, narrow fabrics are used to join carpet seams during installation, whether inside the house or on the football field.

 

Narrow fabrics can be found almost anywhere and have a myriad of uses from every day to high tech. So the next time you take your dog for a walk or admire the carpet in your living room, remember narrow fabrics!

 

If you have any interest in narrow fabrics, come and visit Maw Chawg Enterprise Co., Ltd. – they are the professional yarn supply in Taiwan. You can find kinds of quality fabrics there. To get more details, welcome to check out their website and feel free to contact with Maw Chawg.

 

Article Source: https://www.bondproducts.com/narrow-fabrics/

Reducing Sinker and Wire EDM Consumable Costs

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A key area for improvement in EDM operations is the reduction of EDM consumables. New technologies, machine settings, and improved material grade limit ram or sinker EDM electrode wear to 0.1% while maintaining productive machining speeds. For wire EDM, new low-consumption technologies reduce the biggest expenses—the wire itself—by as much as 50 percent.

With all EDM machines, you experience the benefits of designing and cutting complex shapes and tapered holes with hard metals. You can depend that the machine has the capacity to cut exactly what you want. Sinker EDM machines use an electrode and workpiece submerged in liquids such as oil or dielectric water. A power supply is connected to the electrode and generates an electrical potential between both of the parts, producing a breakdown to form a plasma channel and spark jumps. The sparks initiated by the power supply often times strike one another.

In the sinker EDM process, wear on the electrode starts as soon as the erosion process begins. As metal is burned away on the workpiece, the electrode gradually experiences wear loses its fine details, and is dimensionally changed. Minimizing electrode wear is not only critical to reducing costs and lead times but also improving part accuracy.

From a general sinker EDM perspective, quality graphite electrode materials provide the most productive machining speed. The wear rate of a graphite electrode depends largely on the size of the detail, the electrode reduction amount, and the power settings used. However the grade of the graphite is a contributing factor. Using the correct grade of graphite will limit wear and rate of erosion.

Wire electrical discharge machining uses a single string of thin metal wire to cut thick metals for precise incisions and splits. Similar to Sinker EDM, Wire EDM uses an electrode and spark to cut metal. Using a spark erosion technique, Wire EDM machining submerges the part being cut in deionized water and the wire acts as the electrode, creating a spark that roughs or skims the part into the desired shape without the wire ever coming in contact with the part.

The price of a wire EDM machine is minimal when compared to the cost of the wire over the life expectancy of the machine. Excessive wire consumption on a wire electrical discharge machine is costly. Technology that allows slower unspooling speeds without compromising results appears to be the answer. The wire is the single highest expense in operating a wire EDM. With even the least expensive EDM wire running $5 to $6 per pound, investing in low-wire consumption EDM machines appears to be the answer.

A key area for improvement in EDM operations is the reduction of EDM consumables. For Sinker EDM users, consider using better grades of quality materials to reduce cost. For Wire EDM users, consider investing in new technology with machine settings that reduce the amount of wire used.

Article Source: https://graphel.com/blog/save-money-edm-sinker-consumable-costs/

Tips for Making Sheet-Metal Parts

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Follow these straightforward guidelines to create durable parts that exactly meet your design’s requirements.

 

In sheet-metal fabrication, parts are formed from metal sheets by punching, cutting, stamping, and bending. 3D CAD files are created using a host of different CAD packages and then converted into machine code, which controls machines that precisely cut and form the sheets into the final parts. Sheet-metal parts are known for their durability, which makes them great for a wide variety of applications. Parts for low-volume prototypes and high-volume production runs are most cost-effective due to large initial setup and material costs.

 

Below are some tips and guidelines for designing sheet-metal parts. If you follow the design advice and maintain the tolerances expressed in this article, you are more likely to end up with parts that meet the needs of your designs.

 

Wall Thickness

Parts should maintain a uniform wall thickness throughout their entirety, but this should be easy because parts are formed from a single sheet of metal.

 

Bends

Sheet-metal brakes bend sheets into a part’s desired geometry. Bends in the same plane should be designed in the same direction to avoid having to reorient the part during manufacturing, which will save money and time. Another trick is to keep the bend radius consistent to keep parts more cost-effective. Thick parts tend to become inaccurate, so they should be avoided if possible.

 

Rule of thumb: To prevent parts from fracturing or distorting, make sure to keep the inside bend radius at least equal to the sheet’s thickness.

 

Curls

Holes should be placed away from the curl at least a distance equal to the radius of the curl plus the material’s thickness. Bends should be at least six times the material’s thickness plus the radius of the curl.

 

Rule of thumb: Outside radius of curls must be at least twice the sheet’s thickness.

 

Countersinks

Countersinks must be separated from each other by a distance of at least 8 times the material thickness, from an edge by at least 4 times the material’s thickness, and from a bend by at least 3 times the material’s thickness.

 

Rule of thumb: The maximum depth for a countersink is 3.5 times the material’s thickness.

 

Hems

Hems are folds to the edge of a part that create rounded, safe edges. Hems may be open, flat, or tear-dropped, and tolerances depend on the hem’s radius, material thickness, and features near the hem. It should be noted that flat hems should be avoided because they risk fracturing the material at the bend.

 

Rule of thumb: For open hems, the inside diameter should at least equal to the material thickness (larger diameters tend to lose their circular shapes); and the return length should be at least 4 times the material’s thickness. Tear-dropped hems must maintain an inside diameter of at least equal to the material’s thickness, an opening of at least ¼ the material’s thickness, and the return length should also be at least 4 times the material’s thickness.

 

Holes and Slots

Holes and slots may become deformed if positioned near a bend. The minimum distance that holes should be placed from a bend is a function of the material thickness, bend radius, and the hole’s diameter. Holes should be at least 2.5 times the material thickness plus the bend radius away from any bends. Slots should be placed 4 times the material’s thickness plus the bend radius away from the bend.

 

Be sure to put holes and slots at least twice the material’s thickness from an edge to avoid a “bulging” effect. And holes should be separated from each other by at least 6 times the material’s thickness.

 

Rule of thumb: Keep hole and slot diameters at least as large as the material’s thickness. Higher-strength materials require larger diameters.

 

Notches and Tabs

Notches must be at least one-eighth of an inch (3.175 mm) away from each other. For bends, notches must be at least 3 times the material’s thickness plus the bend radius. Tabs must be at least 0.04 inches (1 mm) from one another or the material’s thickness, whichever is greater.

 

Rule of thumb: Notches must be at least 0.04 inches (1 mm) thick or as thick as the material, whichever is greater. A tab should not be any longer than 5 times its width. Tabs must be at least 0.126 inches (3.2 mm) thick, or two times the material’s thickness, whichever is greater. Tab length should be no larger than 5 times its width.

 

Corner Fillets and Relief Cuts

Sheet-metal parts may have sharp corners, but designing a fillet of ½ the material’s thickness will make parts more cost-effective.

 

Relief cuts help parts avoid “overhangs” and tearing at bends. Overhangs become more prominent for thicker parts with smaller bend radii, and may even be as large as one half of the material’s thickness. Bends made too close to an edge may cause tearing.

 

Rule of thumb: Relief cuts for bends must be at least one sheet’s thickness in width, and be longer than the bend radius.

 

If you have any interest in sheet metal process, I recommend you to visit the website of Tailift Co., Ltd. – they are the professional manufacturer for kinds of high-quality sheet metal machines and punch presses. To get more information of sheet metal machine series, please do not hesitate to check out their website and feel free to contact with Tailift.

 

Article Source: https://www.machinedesign.com/mechanical/tips-making-sheet-metal-parts

How to Repair a Shoe with Rubber Shoe Cement?

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Shoes that are torn or those with separated soles can be repaired with rubber shoe cement. Rubber shoe cement is made of latex polymers designed to stick together two pieces of rubber. However, rubber cement can be used to create a waterproof and temporary coating over holes in the fabric or leather part of shoes, if painted on and allowed to dry. Rubber cement can also serve as a protectant to prevent wear and tear on shoes.

 

Holes Part:

Step 1

Estimate the size of the hole. Cut or tear a napkin or piece of paper towel in the approximate shape of the hole. This piece should be twice the size of the hole.

 

Step 2

Place the torn napkin or paper towel inside the shoe, aligning it with the hole.

 

Step 3

Brush one thick coat of rubber cement over the hole on the outside of the shoe. The most effective method to cover the hole is by using long, steady strokes. Ensure the shoe cement is coating the napkin or paper towel and a 1- to 2-inch area surrounding the hole.

 

Step 4

Allow rubber cement to dry for three to four hours.

 

Step 5

Apply a second thick coat over the original area. Allow to dry for three to four hours. Once two coats of rubber cement have dried on a shoe, it can be worn.

 

Soles Part:

Step 1

Remove any dirt or debris from between the sole and the body of the shoe. Dirt and debris will prevent the rubber cement from adhering properly.

 

Step 2

Apply a thick coating of rubber cement to the exposed area of the sole.

 

Step 3

Press the sole firmly to the shoe, applying pressure for one to two minutes.

 

Step 4

Place the shoe on a flat surface with a heavy object on top of it. This allows rubber cement to properly adhere in the correct places. Leave the shoe alone for 48 hours. After 48 hours, the shoe is fit to wear.

 

To get more information of shoe cement or shoe adhesive, I highly recommend you to visit Great Eastern Resins Industrial Co. Ltd. – they are the professional adhesive manufacturer in Taiwan. You can find kinds of industrial glue and shoe adhesive there. Learn more details, please do not hesitate to contact with GRECO.

 

Article Source: https://www.hunker.com/13422479/how-to-repair-a-shoe-with-rubber-cement

Explanation of Epoxy and Epoxy Adhesive

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Epoxy is an organic compound. It is made up of chains of carbon linked to other elements such as hydrogen, oxygen, or nitrogen. This link occurs via a covalent bond, in which the elements share a pair of electrons to stay together.

 

The epoxy term is a broad one. It can be used to describe the epoxide functional group, which is made up of a chain of carbon and oxygen atoms. Since functional groups determine the main characteristics of a molecule during a chemical reaction, this means molecules that contain the epoxide functional group can react chemically to create a rigid, yet highly flexible material.

 

The term epoxy can also be used to refer to the epoxy resins that appear after curing. Curing is a chemical process in which a material hardens after exposure to air, heat, or chemical additives. In epoxy, curing occurs with the help of a catalyst, which is chemical additive that increases the rate of a chemical reaction. This results in an exothermic reaction that creates a cross-linkage in the polymer. This cross-linkage is responsible for the rigidity and strength of epoxy materials.

 

Creating Epoxy Adhesives

Epoxy resin and hardener curing conditions can be modified to create the desired mechanical strength and property in the material. This means choosing the right temperature or humidity settings for the curing process to obtain epoxy materials that are resistant to heat, electricity, or chemicals. As a result, a variety of epoxy adhesives have been developed to suit a broad range of applications from automobiles to golf clubs. They are suitable for any product requiring a high strength adhesive and can be used on a variety of materials.

 

Properties of Epoxy Adhesives

As adhesives, the epoxy material needs to withstand heat, water, and harsh chemicals. It also needs to have a high level of adhesion on a variety of substrates and be flexible enough to be molded into different shapes. All these properties can be achieved by controlling the conditions in which the adhesives are created.

 

Epoxy adhesives are also durable and can withstand heavy loads, making them excellent structural adhesives. Epoxies come in either one-component or two-component systems. The main difference between the systems is the difference in curing temperatures.

 

One-Component Epoxy Adhesives

One-component epoxy adhesives are cured at temperatures between 250 and 300 degrees Fahrenheit. They are formulated without the aid of a catalyst and cure faster than two-component epoxy systems.

 

One-component systems have excellent adhesive properties and are resistant to harsh external environments. This makes them an excellent alternative to welding and rivets, as they possess similar properties to maintain structural integrity.

 

Two-Component Epoxy Adhesives

Two-component epoxy adhesives are also known as a two-part epoxy. They are cured at lower temperatures compared to one-component systems. The curing is done with the help of catalysts, and the process can be accelerated by heat. Cross-linking in the polymers increases during this heat acceleration process to give the epoxy superior properties.

 

Two-component epoxy adhesives are highly stable. They also have a wide variety of applications, such as bonding, sealing, and coating. They can be treated to resist high temperatures and have fast curing times.

 

Choosing the Right Epoxy Adhesive

One factor to consider when choosing an epoxy adhesive is the work life. This is how much time an epoxy adhesive takes to harden and dry. However, this is not to be confused with cure time, which refers to the length of time it takes for the internal chemical reactions to complete and the epoxy to reach its full strength.

 

A good example would be the long work life polyamide epoxy adhesive versus a metal bonding epoxy adhesive. Both are made by Infinity Bond, and both require 24 hours to become completely cured. However, the long work life polyamide epoxy has a work life of 200 to 700 minutes, while the metal bonding epoxy has a work life of only 9 to 12 minutes.

 

To choose the right epoxy adhesive based on work life, simply determine the approximate length of time your job will take. You do not want your epoxy adhesive to harden and dry before your job is finished. Neither do you want your materials to shift nor is slide after your job complete because your epoxy adhesive has not dried and hardened in time.

 

Another factor to consider when choosing the right epoxy adhesive is the material of the substrate. Even though two-component epoxy adhesives are generally suitable for all substrates, from metal to plastic to glass and wood, special epoxy adhesives have been developed.

 

Some examples of special epoxy adhesives include the electrical epoxy by Infinity bond. Designed for use in electrical potting processes, this epoxy adhesive is highly resistant to shock and vibrations, and repels moisture to prevent corrosion. All of which are highly desirable properties in electrical potting.

 

Lastly, color is also a contributing factor when deciding which epoxy adhesive to choose. For highly visible jobs, the epoxy adhesive has to blend in with the substrate for aesthetic appeal. Luckily, two-part epoxy adhesives have been developed in a variety of colors, and even come in a clear version for those hard-to-match colors.

 

If you have interest in epoxy adhesives, I sincerely recommend you to come and visit Epolab Chemical Industries Inc. – they are the professional epoxy resin manufacturer in Taiwan. To get more information of it, check out their website and feel free to contact Epolab.

 

Article Source: https://www.hotmelt.com/blogs/blog/adhesive-academy-epoxy-explained

Do You Know What Wetsuit Socks Are? And Why Do You Need Them?

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Have you ever heard wetsuit socks? And do you know what they are and what do they do?

Neoprene Socks

In all honesty, these neoprene socks do more than just make getting in and out of wetsuit boots easier, they also have a ton of other awesome features! Whether you’re a surfer, a diver, paddler or an open water swimmer, wetsuit socks are a great layering piece for water sports – and they can even be worn alone.

 

Just like cold hands, cold feet can also put a damper on your next water sport adventure and no one has the time for that. So, starting with the basic question here, what are wetsuit socks and what do they do?

 

Just like neoprene gloves or hoods are meant to protect your hands and head, these swim socks were designed to protect your feet from outer elements. Similar to regular socks, but the neoprene version of them, wetsuit socks are a great inexpensive layering piece (worn with or without wetsuit boots) that also insulate feet and wick away moisture. And for all you paddlers out there, socks provide extra splash protection!

 

If you have any interest in much more choice of wetsuit socks, come and visit Pacific Eagle Enterprise Co., Ltd. – they specializes in kinds of wetsuits, hunting waders, and Neoprene accessories. To get more information of their products, welcome to check out their website and feel free to contact with Pacific Eagle.

 

 

Article Source: https://www.wetsuitwearhouse.com/blog/wetsuit-socks/

Three Tips to Keep Hydraulic Cutting Tools Healthy

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Hydraulic cutting tools and crimpers are the key to modern termination techniques. Hydraulic termination tools are arguably the largest and most complex devices in a contractor’s gang box. They’re certainly not in the same category as expendable tools like 3/8-in. variable speed drills. In fact, they’re more costly to replace than almost all hand tools. It’s no wonder good preventive care and maintenance is essential.

 

Hydraulic Cutters And Crimpers Are Key To Modern Termination Techniques

 

Hydraulic termination tools are arguably the largest and most complex devices in a contractor’s gang box. They’re certainly not in the same category as expendable tools like 3/8-in. variable speed drills. In fact, they’re more costly to replace than almost all hand tools. It’s no wonder good preventive care and maintenance is essential to extended tool life and increased worker productivity. By investing some time in staff training and a nominal amount of money for maintenance, good hydraulic tool performance will repay you many times over in the long run.

 

The following three tips should help you maintain these valuable tools.

 

Tip 1: Keep Them Clean

The primary cause of premature hydraulic tool failure is dirt and contamination. Usually, pistons and rams are the areas on a remote head where dirt and contaminants enter (unless you leave the hydraulic fluid reservoir open, which we don’t generally recommend in field operations).

 

To combat dirt and contamination, make sure you follow these preventive maintenance steps.

 

  • Brush and wipe clean all hydraulic connections before you insert them into a hydraulic pump or remote head.

 

Always use fiber brushes when cleaning your hydraulic tools—never metal-bristled brushes. Metal can score a piston, creating an area for dirt and other contaminants to collect and migrate into the hydraulic fluid. This increases the chance of compromising your tool’s rings and ball seats as well as the tool pump itself.

 

  • Clean hydraulic heads with non-petroleum solvents whenever possible to reduce contamination of traveling surfaces and hydraulic interfaces.

 

Not all makes of hydraulic tools have the same type of seals. For example, certain petroleum-based products may negatively affect rubber or neoprene O-rings on pistons and ram followers. In fact, some tool manufacturers will require the use of specific solvents while others will restrict the use of these same solvents.

 

  • Clean your hydraulic tool daily when you’re using it in adverse conditions.

 

Working near salt water is probably the worst situation. While most hydraulic tool manufacturers test their products in salt-spray chambers during design and certify they can withstand such exposure up to 24 hr. or more, it’s still important you clean your tool after each use in such an environment.

 

Most manufacturers recommend flushing the tool with clean water and wiping it down with a recommended solvent. If you fail to do this, you can expect long-term damage. Also, the “dirty” tools might contaminate other tools stored in your gang box.

 

Tip 2: Use Them Properly

Misuse and abuse are strong causes for tool failure. Using hydraulic tools for hammering or prying is an obvious misuse; however, many manufacturers report this type of equipment abuse as a common sight during repair and reconditioning.

 

Other reports include the obvious field installation of extension handles (commonly referred to as cheaters) to improve a tool’s performance. Actually, these handles don’t increase performance at all because the tool’s output force is fixed. Basically, you’re just placing undue stress on your tool with these handles. More importantly, you’re compromising its dielectric properties, since the extension handles may cut into your tool’s insulation.

 

Manufacturers also report instances where an operator used a soft-metal hydraulic cutter to cut reinforcing bar or some other very hard metal. This is very dangerous! Besides tool failure, individual pieces can shatter and break away, potentially causing injury. (Even when you’re using a hydraulic cutter or crimping tool properly, always wear eye protection.)

 

Finally, manufacturers talk of obvious incorrect selections of tooling, dies, and connectors. This negatively impacts tool performance. For example, if you use a connector from Manufacturer A with dies from Manufacturer B in a tool from Manufacturer C, you certainly would have compatibility problems. More importantly, the resulting connection is questionable. This brings liability into play. Here’s what you should do to ensure compatibility:

 

  • Verify your tool’s acceptance of available dies and/or connectors.

 

  • Check with the connector manufacturer’s published data and verify which tools and dies it recommends for a specific connector.

 

Tip 3: Be Sure To Follow Maintenance Schedules

Your self-contained hydraulic tools will last five to 15 years with proper care and maintenance. Make sure you check their system operation yearly.

 

You can expect the same life expectancy for electric-powered pumps. You should check their system operation yearly as well. The best preventive maintenance procedure for pumps is an annual hydraulic oil change.

 

You need to make a yearly check of hydraulic hoses (both insulated and non-insulated) for cracks and leaks. Most electric powered crimping tool manufacturers have hydraulic hose care manuals. Make sure you refer to them before and after tool usage. Do not attempt to repair a hydraulic hose. Contact your tool manufacturer, and replace it with a new one.

 

If you need more information about hydraulic cutting tools, please do not miss Tai Cheng Hydraulic Industry Co., Ltd. – they are the well-known hand tool manufacturer in the industry. Get more details about punching tools and cutting tools, contact Tai Cheng immediately.

 

 

Article Source: https://www.ecmweb.com/content/three-tips-keep-hydraulic-tools-healthy