Benefits of Using Automatic Lathes

No matter their size, CNC lathes are designed to make intricate cuts on different types of material, specifically wood, plastic, and metal—making CNC machines key players in glassworking, metal spinning, metalworking, and wood turning. These machines can be used to produce anything from plane surfaces and screw threads to three-dimensional, complex products. And, because they’re easily set up and operated, CNC lathes are a growing necessity for companies of any size and production level.

These machines offer tremendous repeat-ability, top-notch accuracy, versatile functionality, and customized programming, making CNC lathes the perfect solution for the following industries: automotive, electronics, aerospace, firearm manufacturing, sporting and many others.

Your overall productivity depends on the efficiency of the tools you use, period. Ineffective equals slow. Slow equals less profit. In order to fulfill your work orders and gain higher production levels, you need to have the right machine, and that machine needs to be in the highest condition to perform.

Article Source: https://asimachinetool.com/blog/benefits-of-using-cnc-lathes/

Victor Taichung Sees 70% of Orders for Customized Machine Tools

Taiwan-based machine maker Victor Taichung Machinery Works has coped with waning competitiveness in prices for the export markets by offering customized manufacturing services to create product differentiation, with around 70% of orders associated with customization, according to company chairman MH Huang.

 

Huang said that Taiwan machine tool makers used to see their quotes some 30-40% lower than those offered by their biggest competitors from Japan, but such a price competitiveness has been significantly undermined by the sharp depreciation of the Japanese yen. As a result, international customers have turned to Japan machine tool brands, directly squeezing the survival space for Taiwan makers.

 

Huang said that since 2013, Victor Taichung has maintained a customer value-creating application center, gathering the firm’s experienced sales staff and engineers to directly face customers and respond to their actual needs. This way, Victor Taichung can agilely adjust its product development strategies based on direct responses from customers, thus effectively boosting product values and customer loyalty through customized production services.

 

Huang stressed that Taiwan machine tool makers cannot compete well with China and Korea rivals in terms of production volume of low- to medium-tier models or with Japan makers in the market for high-end products. Accordingly, he indicated, it will be a major challenge for business transformation of Taiwan machine tool builders as to how they can work out differentiation to highlight corporate values and even develop the market for higher-end products.

 

If you have any interest in vertical machining centers and much more custom machine tools, come and visit Victor Taichung Machinery Works Co., Ltd. for more details!

 

Article Source: https://www.twmt.tw/victor-taichung-sees-70-of-orders-for-customized-machine-tools/

Do You Know What BTA Drilling Is?

What is BTA Drilling?

Start Here: Deep Hole Drilling Overview

BTA drilling is a deep hole drilling process that uses a specialized drilling tool on a long drill tube to produce deep holes in metal, from holes with a diameter of 20 mm [0.80 in] and larger, up to depth-to-diameter ratios of 400:1. BTA drilling is the most effective method of drilling deep holes, as it is a cleaner, more reliable and capable process than conventional twist drills, and can achieve larger diameters and higher feed rates than the alternative gundrilling.

 

BTA drilling tool heads are threaded or mounted onto long drill tubes, and use multiple cutting surfaces on a single tool to remove chips efficiently, exhausting them using high-pressure coolant through holes in the tool head, then out the drill tube and through the machining spindle. BTA tooling is available in brazed or inserted carbide configurations.

 

BTA stands for Boring and Trepanning Association, and is also sometimes referred to as STS (single tube system) drilling, as it uses one single drill tube for the BTA tool, compared to other processes such as ejector drilling, which use two.

 

BTA Drilling vs Gun Drilling

BTA drilling can achieve drill feed rates of typically 5-7 times faster than gundrilling at the same diameter, due to the tool design, more efficient chip exhaust, and machine design and power. BTA drilling machines introduce coolant around the tool head, and evacuate chips through the drill and machine spindle, compared to gundrilling, where coolant is introduced internally and chips exit through an external groove. BTA drilling is effective in holes from 20 – 200 mm [0.80 – 8.00 in], a greater size range than gundrilling.

 

Optimal Specifications for BTA Drilling

BTA deep hole drilling is the ideal process for a range of larger deep hole drilled depths and diameters. BTA drilling, and secondary processes, are capable of drilling extreme depth-to-diameter ratio holes while achieving strict tolerances.

 

BTA Tooling Diameter Range

  • 8 – 65 mm Brazed Disposable BTA
  • 10 – 114 mm Spade Drill BTA
  • 16 – 28 mm Indexable BTA, Single Insert
  • 25 mm +     Indexable BTA, Multiple Insert

 

BTA Drilling Equipment

Deep hole drilling machines that are designed to perform BTA and related processes are complex systems of high-precision components, designed and built for extremely deep holes and strict tolerances.

 

If you need more information of BTA drilling equipment, I sincerely recommend you to visit Honge Precision Industries Corp. – they can provide high-quality and high-performance BTA deep hole drilling machine for clients. To get more details of this hole drilling machine, welcome to check out their website and feel free to contact with Honge Precision Industries!

 

Article Source: https://www.unisig.com/information-and-resources/what-is-deep-hole-drilling/what-is-bta-drilling/

Guillotine vs. Swing Beam Shear

Guillotine Shear

A guillotine shear is a machine that can shear or cut various materials with a guillotine design. The word “guillotine” is associated with a blade that drops along a vertical track. This type of machine was primarily used in familiar history as a method of execution, particularly in the French Revolution, but the modern guillotine shear cutter is a tool used to form and shape products for a market.

 

The principles of the guillotine shear were incorporated into the design of metal shears and have been the primary design for all of these years. Some of the shortcomings of a guillotine shear are that it must run in gibs and ways and therefore need a certain amount of clearance which has a direct effect on the thinnest sheet than can be cut.

 

Also, the ram moves down with approximately 1 degree of backward motion. This allows the cut sheet to clear the back gauge and drop, although sometimes even this is not enough and the cut part is wedged between the lower blade and the back gauge.

 

When a guillotine shear has a throat it must be heavily re-enforced to avoid the deflection that would normally result from a deep throat. The apron of the upper ram is heavily gusseted to keep the blades parallel to the bottom blades. This system has worked well for hundreds of years however times change and new engineering becomes available.

 

Swing Beam Shear

On a swing beam shear the ram moves on bearings so there is no play what so ever. This allows the swing beam shear to be able to cut paper as long as the blades are sharp. The ram moves from a fulcrum point in the rear of the side frames giving the shear a massive amount of plate between it and the cutting point. This means almost no detectable deflection.

 

The back gauge is attached to the bottom of the cutting column and moves up as the blade goes down. This means there will never be a possibility for the material to become stuck between the blade and the back gauge.

 

Rather than gussets on the apron a swing beam shear wraps the entire ram as one solid gusset making it much stronger than a similarly gusseted ram. It can have a deep throat with no possibility of deflection and can cut even the thickest piece of metal with a very low rake angle.

 

In my opinion the swing beam shear reviewed the short comings of the guillotine shear and fixed them; however, it is important to remember that before making a decision on purchasing any kind of a shearing machine factors such as the type of shear, required capacity, productivity options, and safety should be carefully evaluated.

 

One important consideration used in deciding what shear is the right one for any job is the capacity required to perform the job. Most of the shears on the market today list capacities for mild steel and stainless steel. It is advised to compare a fabricator’s requirements to those of the actual machine.

 

Some shear capacities are rated on mild steel, which may have 60,000 pounds per square inch (PSI) tensile strength, while others are rated for A-36 steel or 80,000 PSI tensile strength. Capacities for stainless steel are almost always less than those for mild or A-36 steel. Surprisingly enough certain grades of aluminum require as much power to shear steel does. As always, when making a decision on any kind of metalworking machinery purchase, it is important to work with a reputable and knowledgeable company that can answer all the questions regarding the performance and capacity for the machine.

 

To get more details of swing beam shear, welcome to visit Yeh Chiun Industrial Co., Ltd. – they are the professional manufacturer of specializing in hydraulic shears. Learn more information, please do not hesitate to contact with Yeh Chiun anytime!

 

Article Source: https://www.cmarshallfab.com/guillotine-vs-swing-beam-shear/

Buying a Wire EDM: Speed, Accuracy and Finish

What kind of surface finish can the purchaser of a wire EDM expect with today’s technology?

 

The two things every wire electrical discharge machine (EDM) user wants are speed and accuracy. Unfortunately, these objectives are usually incompatible. You don’t get speed with precision, and you can’t achieve high accuracy without also achieving a fine surface finish. Accuracy and surface finish go together. Speed and accuracy do not.

 

Cutting Speed, Accuracy and Surface Finish

EDM units from the early 1980s might achieve cutting speeds of 3 to 4 square inches per hour. With changes in machine design and power supplies, speeds of 17 square inches per hour became attainable in the 1990s. Today, with improved power supplies, working in conjunction with sophisticated adaptive controls, it is not uncommon to achieve 24, 37 and in some cases 45 square inches per hour.

 

The type of material and the height of the part being cut are critical as well. It is generally easier and faster to cut hardened tool steel than cold-rolled steel, for example. The harder material is the better. Typically, tool steels, carbide and special alloys have fewer impurities and lower porosity, making them easier to cut. Cold-rolled steel may contain impurities, so wire cutting is slower, and the surface finish is poorer. Although aluminum is easy to cut at higher speeds, the material is so soft that it is very difficult to get a good surface finish. Even a 30-microinch surface finish is difficult to achieve in aluminum. In contrast, it is possible to cut a 3-inch-thick carbide workpiece, with accuracies of ±0.0001 inch, and still produce a of 5-microinch Ra surface finish.

 

A typical wire EDM process consists of several passes, traveling at varying speeds. The first pass is generally a roughing pass designed to cut as quickly as possible, while accuracy and surface finish are less of a concern. Each subsequent skim cut travels at progressively faster speeds, takes less and less material while steadily improving dimensional accuracy and quality of the surface finish.

 

During the finish cuts, the tension on the wire is increased, the current is reduced, and the voltage gap narrowed, allowing the user to refine the spark and the distance the spark jumps from the wire to the part. The offset applied to the last finish pass might be as small as 3 microns. To achieve a 4- or 5-microinch Ra finish, as many as six or seven skim cuts might be necessary. Whereas the diameter of a cutting tool determines the offset in milling, the EDM controller applies a cutter comp based on the diameter of the wire. For example, if a 0.010-inch-diameter brass wire is used, the cutter comp will approach 0.005 inch plus a spark gap as the wire gets closer and closer to the part surface, and possibly finish at 0.0051 inch.

 

To achieve these close tolerances and super-fine surface finishes, every parameter must be properly set. The right type of EDM wire must be selected. The wire must have the right diameter and tensile strength. The power setting and tension of the wire must also be right. The condition of the deionized water and flushing arrangements must be optimized, as well.

 

Machine Accuracy

When attempting to hold ±0.0001-inch positional accuracy with wire EDM, the shop environment becomes a factor. For example, both steel and carbide have a thermal expansion coefficient of ~6.8 ppm per degree Fahrenheit. This means that, for every 2°F change in shop temperature, a 12-inch part could grow as much as 0.00016 inch, putting the operation over the 0.0001-inch tolerance it is trying to hold. To be successful under these conditions, a shop must be able to hold its ambient temperature within 1°F in either direction during an eight-hour period. Controlling the temperature of the dielectric solution to ±1°F also helps control the temperature of the machine and the workpiece.

 

The two most common machine designs use either ballscrews or linear-motion systems. In terms of machine accuracy, each design has pluses and minuses, which must be explored when choosing a wire EDM unit.

 

High-precision glass scales are used to negate the effects of pitch error or backlash on the linear feedback. On the best machines, high-resolution servodrives with fine increments are used to position the wire, thus improving surface finish and accuracy. Adaptive controls can compensate for thermal growth. High-speed circuitry in servomotors enables them to react instantaneously for finer control of the spark. High-peak power supplies can now put more electrical energy into the wire, greatly enhancing productivity.

 

If you need more information of EDM machine manufacturers, I sincerely recommend you to visit Excetek Technologies Co., Ltd. – the company specializes in manufacturing high-quality EDM machines. To get more details of EDM machining, welcome to check out their website and feel free to contact with Excetek!

 

Article Source: https://www.mmsonline.com/blog/post/buying-a-wire-edm-speed-accuracy-and-finish

Machining Performance Reveals Opportunities for Efficiency Gain, The Value of Tooling Choices That Save Time Will Be The Important Key

As more sophisticated insight into machining performance reveals opportunities for efficiency gain, the value of tooling choices that save time will become increasingly clear.

 

The promise of Industry 4.0 is great news for the adoption of advanced cutting tools. The reason: In interconnected manufacturing systems in which comprehensive data reveal the performance of the system, the impact of an advanced tool becomes clear.

 

Historically, the lack of clarity about manufacturing performance has been the main impediment to shops embracing high-end cutting tools. Tools typically account for just 3 percent of the per-piece production cost of a machined part. However, a tool’s price tag is more visible than its benefits. This fact leaves manufacturers frequently pursuing cost-saving steps that have little impact. For example, at 3 percent of unit cost, finding tooling that is one-third less expensive will only cut the per-piece part cost by 1 percent. Something similar is true of tool life: Even doubling tool life will only cut cost per part by 1.5 percent. However, finding tooling that provides for significantly faster machining or reduced non-cutting time enables each unit of machine and labor time to deliver more parts, likely cutting the cost per piece by 10 or 15 percent.

 

This argument makes sense in the abstract. The problem is, it can be hard to marshal the data to prove this case as it applies to a specific tool in a specific cut. That is where Industry 4.0 comes in. We are moving into a world in which manufacturing systems increasingly do marshal data such as this, and manufacturers increasingly make use of it.

 

To get more efficient cutting tools, come and visit Shin-Yain Industrial Co., Ltd., they can meet all your requirements of cutting tools.

 

Article Source: https://www.mmsonline.com/blog/post/iscar-leader-describes-tool-technology-for-machine-shops-acting-on-data

Tips for Making Sheet-Metal Parts

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

What You Need Pay Attention When Buy Edge Banding Machine?

You need pay attention to some item when buying edge banding machine. Let’s move on and see these tips!

 

  1. The matching of edge banding machine mainly depends on the shape characteristics of the workpiece to be machined, the type of edge sealing material, and the productivity and quality.

 

  1. Linear edge banding commonly used in office furniture and cabinets and other simple products, mainly considering the yield and some of the features or configuration:
  • The PVC or ABS scraper device for sealing material
  • Solid wood edge, need to add finishing knife and sanding device
  • In order to ensure the quality of the edge is not affected by low winter temperatures the best choice, edge banding machine equipped with far infrared preheating device
  • Additional configuration options: automatic tracking fillet trimming function, cutter device, etc.

 

  1. Automatic edge banding machine has many functions, mainly include: pre milling, glue, edge, blunt, rough trimming, refinement, tracking, scraping, polishing, slotting, which is characterized by high efficiency, automation, high precision, and beauty.

 

These features are also based on various types of division, some is relatively simple, with glue block, scraping, polishing, finishing, and other functions, some more comprehensive, almost all functions are, these are based on the customer base, to buy sheet.

 

  1. Edge curve can be processed in several ways. The curve edge banding machine in order to achieve a stable high level of quality, the NC machining center or NC edge machine, the two machines for some special surfaces edge can show special advantages, such as the edge with the length of the counter can make the smallest circumference of the gap edge docking that is more suitable for the manufacture of high-end furniture products. The difference between the two is that all processes from saw cut to the last parts forming the machining center, complete sealing and trimming process of CNC sealing machine dedicated only, using the processing center edge is the edge takes a larger total processing time, reduces the production efficiency.

 

Most manufacturers use manual edge machining curved parts, especially sheet metal parts within the arc, the maximum edge machine will decide by the wheel diameter can be processed Curve depth. Manual edge banding machine sealing curved edge has the advantages of simple operation, less investment. But due to edge by hand, quality is relatively high, mainly in the lower bonding strength, poor repeatability, high rework rate. At the same time manual sealing machine for thick edge banding commonly used (1.0-3.0mm) edge is relatively difficult but, to use some thin edge sealing strip is not visible on the component (0.4-1.0mm) can be made straight and curve processing.

 

  1. Generally, the use of manual edge banding machine and automatic linear edge sealing machine can meet the requirements of the general product, and the product will improve the efficiency and reduce the production cost.

 

  1. Automatic edge banding machine with preheating, glue, trimming, scraping, polishing and other functions, the current use of this structure there are several large manufacturers, some small manufacturers are eliminating the need for preheating, scraping and other functions, and even the polishing function is not.

 

  1. Listen to the manufacturer’s product introduction, from the machine specifications, performance, use, operation methods, prices, services, and so on, so that the machine needs to have a general perceptual knowledge.

 

  1. Look at the outside of the body in good condition. Check the parts, accessories are complete, look at the demonstration of the operation of the factory demonstration, look at the bonding effect, and master the operation of the machine Essentials.

 

  1. Open the machine to run the test. Check the power supply, gas supply line is smooth, sensitive; the main spindle is running smoothly, no noise.

 

  1. As can be seen from the above analysis, the purchase and use of edge banding machine should pay attention to product output and the ability to adapt to market demand, so as to select different levels of automation equipment and combinations.

 

If you need more information about edge banding machines, please do not miss Boarke Machine Co., Ltd. – you can find kinds of woodworking machines on their website. Now, contact with Boarke for more details!

 

Article Source: https://www.linkedin.com/pulse/what-you-need-pay-attention-when-buy-edge-banding-machine-wenlong-han

What Is A Deep Hole Drilling Machine?

Do you know what a deep hole drilling machine is? Have you encountered this type of machine before?

 

A deep hole drilling machine is a mechanism used in the process of deep hole drilling. Commonly, it is used to produce deep, straight holes especially in metals particularly in the process of gun making. Deep hole drilling machines are the best mechanism to produce accurate holes necessary for most manufacturing processes.

 

Deep hole drilling is the machining of holes with a relatively large depth to a diameter ratio. Essentially, any hole deeper that ten times the diameter of the material should certainly constitute the process of deep hole machining. Specialized drilling technique should be considered in dealing with these processes.

 

Interesting to note as well: deep hole drilling machines were initially developed for manufacturing of guns and armaments. It was used to drill gun barrels. Throughout time, however, other industries also saw the potential of this tool. Nowadays, a lot of industries such as energy, oil and gas use gun drilling machines for resource exploration. It is also useful in the metal cutting industries, automotive, aircraft, petro-chemical industries. Gun drilling mechanisms are also found useful even in the medical field.

 

Construction of deep hole drilling machines is not only expensive but a difficult task as well. It requires specific planning and a variety of tools and machinery. Despite the difficulty of production, deep hole drilling machines are still seen as an important machine in most processes in different industries.

 

Depending on the required processes, there are different kinds of deep hole drilling machines. As a machinist, you have to consider the dimensions of the machine you are going to use, and the dynamics of the materials. In addition to the machine dimensions, power and dynamics, compatibility of these tools with various machines is primarily determined by the fluid delivery and chip exhaust systems. Achieving a perfect deep hole is not only reliant to the drilling machine but to a variety of mechanisms or systems. The two most common deep hole drilling systems enforced by different industries are gun drilling system and the BTA system.

 

Here is how a drill machine operates in the system of gun drilling: the drill is positioned and held in a spindle nose. It is then guided to a pre-started hole to avoid vibration of the drill. With this setup, the gun drill system operates in full accuracy. The high pressure coolant flushes the chips and lubricates the system. This operation produces the fine finish and burnished surface of the hole.

 

Important to note as well that, in using a drilling machine, safety precautions must be enforced. As with all power equipment, safety and security of you and your environment plays a crucial role. For instance, you must wear the correct and appropriate working clothes in using a deep hole drilling machine. An appropriate uniform lessens the possibility of an accident. Make sure also that you know how the machine works so that you can preempt an incident waiting to happen.

 

If you need more information about hole drilling machine, please choose Honge Precision Industries Corp. – the company’s deep hole drilling machine has wide range of model, suitable for various industrial part’s deep hole drilling. Due to its excellent quality, good management system and superior after-sales service, Honge has already enjoyed a long-lasting good reputation in the world market. Learn more details, feel free to contact Honge at 886-4-2496-0300.

 

 

Article Source: https://www.quora.com/What-is-a-deep-hole-drilling-machine

Best Square Pipe Making Machine: Recommend Roll Forming Machines Manufacturer – Yunsing Industrial

Taiwan First Choice of Roll Forming Machine Supplier

Established in 1972, Yunsing Industrial Co., Ltd. hold “adhering to excellent quality and enhanced reliability to create outstanding customer satisfaction” as our business philosophy, Yunsing has accumulated more than 40 years of experience specializing in manufacturing steel plate automatic cold roll forming machines with advanced technologies and superior quality products, such as roofing and wall cladding, corrugated sheets, stepped tile roofing, floor decking, C-Purlin, rolling shutters and door frames.

 

Below, I will present you an excellent machine from Yunsing, that’s square pipe making machine.

 

Square Pipe Roll Forming Machine


YS-300 Square Pipe Making Machine complete with hydraulic cutting, including angular cutting, and punching hole devices by computer system.

 

Yunsing’s roll forming machines are driven by chain in hydraulic system. Chain Drive System can save the power compare with other system. That also means that customers do not need to pay the extra power fee during production of steel channel.

 

Features:

  • Without any welding
  • Using raw material is Galvanized coils, so the pipe inside is also galvanized
  • The length of the pipe is variable
  • All punching and cutting, inclduling angular cutting are automatic
  • Automatic stacker, so two workers can handle this production line

 

Certificate:

SGS; CE

 

Order Information:

  • Minimum Order: one set
  • Branded Product
  • FOB: Any port in Taiwan

 

If you need more information about square pipe making machine, please come and visit Yunsing Industrial Co., Ltd. for further details.

 

 

Yunsing Industrial Co., Ltd.

No, 472, Yen Ping N. Rd., Sec. 6, Taipei, Taiwan R.O.C

TEL: +886-2-28120007

FAX: +886-2-28131932

Email: info@yunsing.com.tw