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How to choose the right CNC machining material?
The materials are wrong, all in vain! In order to produce satisfactory products, the choice of materials is the most basic step and the most critical step. CNC machining can choose a lot of materials, including metal materials, non-metallic materials and composite materials.
Common metal materials include steel, aluminum alloy, copper alloy, stainless steel and so on. Non-metallic materials are engineering plastics, nylon, bakelite, epoxy resin and so on. Composite materials are fiber reinforced plastic, carbon fiber reinforced epoxy resin, glass fiber reinforced aluminum and so on.
Different materials have different physical and mechanical properties, and the correct selection of the right material is critical to the performance, accuracy and durability of the part. Starting from my own experience, this article will share with you how to choose low cost and suitable materials among many processing materials.
First, we need to determine the end use of the product and its parts. For example, medical equipment needs to be disinfected, lunch boxes need to be heated in the microwave oven, bearings, gears, etc., need to be used for load-bearing and multiple rotational friction.
After determining the use, starting from the actual application needs of the product, the use of the product is investigated, and its technical requirements and environmental requirements are analyzed, and these needs are transformed into the characteristics of the material. For example, parts of medical equipment may have to withstand the extreme heat of an autoclave; Bearings, gears and other materials have requirements for wear resistance, tensile strength and compressive strength. Mainly can be analyzed from the following points:
01 Environmental Requirements
Analyze the actual use scenario and environment of the product; For example: What is the long-term working temperature of the product, the highest/lowest working temperature, respectively, belonging to high temperature or low temperature? Are there UV protection requirements indoors or outdoors? Is it in a dry environment or a humid, corrosive environment? Etc.
02 Technical Requirements
According to the technical requirements of the product, the required capabilities are analyzed, which can cover a range of application-related factors. Such as: the product needs to have conductive, insulating or anti-static which of the capabilities? Is heat dissipation, thermal conductivity, or flame retardant required? Do you need exposure to chemical solvents? Etc.
03 Physical Performance requirements
Analyze the required physical properties of the part based on the intended use of the product and the environment in which it will be used. For parts subjected to high stress or wear, factors such as strength, toughness and wear resistance are critical; For parts exposed to high temperatures for a long time, good thermal stability is required.
04 Appearance and surface treatment requirements
The market acceptance of the product depends largely on the appearance, the color and transparency of different materials are different, the finish and the corresponding surface treatment are also different. Therefore, according to the aesthetic requirements of the product, the processing materials should be selected.
05 Processing performance considerations
The machining properties of the material will affect the manufacturing process and accuracy of the part. For example, although stainless steel is rust resistant and corrosion resistant, its hardness is high, and it is easy to wear the tool during processing, resulting in very high processing costs, and it is not a good material to process. The plastic hardness is low, but it is easy to soften and deform during the heating process, and the stability is poor, which needs to be selected according to actual needs.
Because the actual application requirements of the product are composed of a number of contents, there may be multiple materials that meet the application requirements of a product; Or the situation where the optimal selection of different application requirements corresponds to different materials; We may end up with several materials that meet our specific requirements. Therefore, once the desired material properties are clearly defined, the remaining selection step is to search for the material that best matches those properties.
The selection of candidate materials begins with a review of material properties data, of course, it is not possible to investigate thousands of applied materials, and there is no need to do so. We can start from the material category, and first decide whether we need metal materials, non-metallic materials or composite materials. Then the previous analysis results, corresponding to the material characteristics, narrow the selection of candidate materials. Finally, the material cost information is used to select the most suitable material for the product from a number of candidate materials.
At present, Honscn has selected and launched a number of materials suitable for processing, which have been a popular choice for our customers.
Introduction to the properties of metal materials
Metallic materials refer to materials with properties such as luster, ductility, easy conduction and heat transfer. Its performance is mainly divided into four aspects, namely: mechanical properties, chemical properties, physical properties, process properties. These properties determine the scope of application of the material and the rationality of the application, which is an important reference for us to choose metal materials.The following will introduce two types of metal materials, aluminum alloy and copper alloy, which have different mechanical properties and processing characteristics.
There are more than 1000 aluminum alloy grades registered in the world, each brand name and meaning are different, different grades of aluminum alloy in hardness, strength, processability, decoration, corrosion resistance, weldability and other mechanical properties and chemical properties there are obvious differences, each has its strengths and weaknesses.
hardness
Hardness refers to its ability to resist scratches or indentations. It has a direct relationship with the chemical composition of the alloy, and different states have different effects on the hardness of aluminum. The hardness directly affects the cutting speed and the type of tool material that can be used in CNC machining.
From the highest hardness that can be achieved, 7 series > 2 series > 6 series > 5 series > 3 series > 1 series.
intensity
Strength refers to its ability to resist deformation and fracture, commonly used indicators include yield strength, tensile strength and so on.
It is an important factor that must be considered in product design, especially when aluminum alloy components are used as structural parts, the appropriate alloy should be selected according to the pressure under.
There is a positive relationship between hardness and strength: the strength of pure aluminum is the lowest, and the strength of 2 series and 7 series heat-treated alloys is the highest.
density
Density refers to its mass per unit volume and is often used to calculate the weight of a material.
Density is an important factor for a variety of different applications. Depending on the application, the density of aluminum will have a significant impact on how it is used. For example, lightweight, high-strength aluminum is ideal for construction and industrial applications.
The density of aluminum is about 2700kg/m³, and the density value of different types of aluminum alloy does not change much.
Corrosion resistance
Corrosion resistance refers to its ability to resist corrosion when in contact with other substances. It includes chemical corrosion resistance, electrochemical corrosion resistance, stress corrosion resistance and other properties.
Corrosion resistance selection principle should be based on its use occasion, high-strength alloy used in a corrosive environment, must use a variety of anti-corrosion composite materials.
In general, the corrosion resistance of series 1 pure aluminum is the best, series 5 performs well, followed by series 3 and 6, and series 2 and 7 are poor.
processability
The machinability includes formability and machinability. Because formability is related to the state, after selecting the grade of aluminum alloy, it is also necessary to consider the strength range of each state, usually high strength materials are not easy to form.
If the aluminum is to be bent, drawn, deep drawing and other forming processes, the formability of the fully annealed material is the best, and on the contrary, the formability of the heat-treated material is the worst.
The machinability of aluminum alloy has a great relationship with the alloy composition, usually higher strength aluminum alloy machinability is better, on the contrary, low strength machinability is poor.
For molds, mechanical parts and other products that need to be cut, the machinability of aluminum alloy is an important consideration.
Welding and bending properties
Most aluminum alloys are welded without problems. In particular, some 5 series aluminum alloys are specially designed for welding considerations; Relatively speaking, some 2 series and 7 series aluminum alloys are more difficult to weld.
In addition, the 5 series aluminum alloy is also the most suitable for bending a class of aluminum alloy products.
Decorative property
When aluminum is applied to decoration or some specific occasions, its surface needs to be processed to obtain the corresponding color and surface organization. This situation requires us to focus on the decorative properties of materials.
Aluminum surface treatment options include anodizing and spraying. In general, materials with good corrosion resistance have excellent surface treatment properties.
Other characteristics
In addition to the above characteristics, there are electrical conductivity, wear resistance, heat resistance and other properties, we need to consider more in the selection of materials.
Orichalcum
Brass is an alloy of copper and zinc. Brass with different mechanical properties can be obtained by changing the content of zinc in brass. The higher the content of zinc in brass, the higher its strength and slightly lower plasticity.
The zinc content of the brass used in the industry does not exceed 45%, and the zinc content will be brittle and make the alloy performance worse. Adding 1% tin to brass can significantly improve the resistance of brass to seawater and Marine atmosphere corrosion, so it is called "navy brass".
Tin can improve the machinability of brass. Lead brass is commonly referred to as easy to cut national standard copper. The main purpose of adding lead is to improve the machinability and wear resistance, and lead has little effect on the strength of brass. Carving copper is also a kind of lead brass.
Most brasses have good color, processability, ductility, and are easy to electroplate or paint.
Red copper
Copper is pure copper, also known as red copper, has good electrical and thermal conductivity, excellent plasticity, easy hot pressing and cold pressure processing, can be made into plates, rods, tubes, wires, strips, foil and other copper.
A large number of products that require good electrical conductivity such as electrocorroded copper and conductive bars for the manufacture of EDM, magnetic instruments and instruments that must be resistant to magnetic interference, such as compass and aviation instruments.
No matter what kind of material, a single model basically can not meet all the performance requirements of a product at the same time, and it is not necessary. We should set the priority of various performance according to the performance requirements of the product, the use of the environment, the processing process and other factors, reasonable selection of materials, and reasonable control of costs under the premise of ensuring performance.
Starts with hardware, doesn't stop with hardware. Honscn is committed to providing fastener/CNC industry chain one-stop service.
1 Tool change of hat type magazineThe fixed address tool change mode is mostly adopted, and the tool number is fixed corresponding to the tool seat number. The tool change action is realized by the lateral movement of the tool magazine and the up and down movement of the spindle, which is referred to as the spindle tool change mode for short. Because it has no tool change manipulator, the tool selection action cannot be preselected before the tool change action. The tool change instruction and tool selection instruction are generally written in the same program segment, and the instruction format is as follows:M06 T
When the command is executed, the tool magazine first turns the tool holder corresponding to the tool number on the spindle to the tool change position, and switches the tool on the spindle back to the tool holder, and then the tool magazine turns the tool specified in the command to the tool change position and changes the spindle.For this tool magazine, even if TX x is executed before M06, the tool cannot be preselected, * the action of final tool selection is still executed when M06 is executed. If there is no TX X in front of M06, the system will give an alarm.2 Tool change of disc and chain magazine
Most of them use random address tool change mode. The corresponding relationship between tool number and tool seat number is random, but its corresponding relationship can be remembered by NC system. The tool change of this tool magazine depends on the manipulator. The action of the command and tool change is: the tool command TX controls the rotation of the tool magazine and turns the selected tool to the tool change working position, while the tool change command M06 controls the action of the tool change manipulator to realize the tool exchange between the spindle tool and the tool change position of the tool magazine. The tool selection command and tool change command can be in the same program segment or written separately. The actions corresponding to tool selection and tool change command can also be operated simultaneously or separately. The instruction format is as follows:
Tx x M06;When the command is executed, the tool magazine first turns the TX tool to the tool change position, and then the manipulator exchanges the tool of the tool magazine with the tool of the spindle to realize the purpose of changing the TX tool to the spindle.After reading the above two methods, it can be seen that method 2 overlaps the tool selection action with the machining action, so that when changing the tool, it is not necessary to select the tool and change the tool directly, which improves the work efficiency.
As mentioned earlier, the tool change command of the tool magazine is related to the machine tool manufacturer. For example, some tool magazines require that not only the Z axis must return to the tool change point, but also the Y axis must return to the tool change point. The program format is as follows:
When writing the instructions of tool selection and tool change in the same program section, the execution rules of tools from different manufacturers may also be different. If any, regardless of the writing order, the rules of tool selection and tool change shall be followed. Some rules stipulate that the tool selection command must be written before the tool change command is executed. Otherwise, the action is to change the tool first and then select the tool, as shown in the above program. In this case, if the tool selection command is not written before the M06 command is executed, the system will give an alarm.
1. Fault phenomenonWhen changing the knife, the manipulator is stuck and cannot change the knife. The position of the manipulator for changing the knife is offset, and the knife is changed.2 fault analysis and treatment
2.1 tool change principleThe machining center is a rotary tool magazine, and the tool change mechanism is cam type. The tool change process is as follows:(1) Write m06t01 to start the tool change and tool selection cycle.
(2) The spindle will stop at the oriented spindle stop point, the coolant stops, and the z-axis moves to the tool change position (second reference point).(3) Select the tool. After NC compiles it to PLC according to the t command, start selecting the tool. The tool magazine motor rotates and rotates the target tool number to the tool change point of the tool magazine. Note that the t command is the tool sleeve position of the tool magazine at this time.(4) The tool change motor drives the cam mechanism to rotate 90 from the parking position to grasp the tool in the effective tool sleeve and the tool in the spindle. At the same time, detect the change of the proximity switch state of the cam mechanism, the PMC output sends out the tool loosening command, the tool magazine tool sleeve tool loosening and the spindle tool loosening solenoid valve are powered on, the cam continues to rotate, drive the manipulator down, push down the tool handle and prepare for exchange. As shown in Figure 1.
(5) The manipulator rotates 180 to exchange the tool, the cam continues to move upward, install the tool into the spindle, and install the tool on the original spindle into the tool sleeve at the tool change position of the tool magazine. At the same time, the detection switch sends a tool tightening command to PMC, the solenoid valve loses power, the shaft tool handle is clamped, the butterfly spring retracts, and the spindle tool is clamped.(6) Change to the manipulator, continue to rotate 90 , and stop completing a set of tool change actions.2.2 fault analysis
Change the tool to the fourth step of 2.1. The tool change manipulator is stuck, and the spindle has been loosened for blowing, but the tool cannot be pulled out. Cut off the power and manually turn the tool change motor. After completing a tool change action, manually load and unload the tool, the action is normal, and the problems of spindle tightening tool are preliminarily eliminated. When the tool change process is performed again, the manipulator gets stuck and the manipulator claw at the tool magazine falls off. After the tool change is found, the manipulator installs the tool on the spindle and the position is offset, as shown in Figure 2.
After the tool is removed, it is found that the action is normal. The reason for this situation may be the offset between the manipulator and the spindle, or the deviation of the accuracy of the manipulator axis relative to the spindle axis, and the inaccurate positioning of the spindle will also lead to the offset of the tool change position. Implement the tool change action step by step, check the accurate positioning of the spindle, and eliminate the fault caused by inaccurate positioning. According to the table, the mechanicalThe axial position and rotation center distance of hand, knife sleeve and spindle are consistent, so the fault of mechanical jamming of mechanical mobile phone is also eliminated.
Recently, this machine tool mainly processes stainless steel and other material workpieces, with large cutting volume and heavy load. It runs under re cutting for a long time. It is found that the manipulator is not loose and the telescopic action of the manipulator claw is flexible. However, it is found that the adjustment block on the manipulator is worn. It is disassembled and observed that the adjustment block is mainly used to clamp the tool handle. After re repair and processing, try again, The offset disappears at the spindle position. The main cause of this fault is the large impact of the manipulator and frequent tool change, resulting in the loosening and wear of the clamping claw, as shown in Figure 3.
For a machine that not so long ago did not even exist, the uses for CNC machining centers have quickly become vast and continue to grow.
Woodworkers today are using these versatile machines for a variety of uses ranging from high-speed, flat-panel production work to very intricate carvings. Combining high speed boring with routing, profiling, cutting and other features, these computer-controlled marvels are being successfully utilized in shops that produce everything from beautiful high-end architectural woodwork to flanges for take up reels.
In the following pages, WOOD & WOOD PRODUCTS interviews woodworkers from around the country who have increased their productivity and accuracy while reducing labor costs through investments in CNC technology. Following are their stories.
SPEAKER MAKER USES CNC MACHINERY TO MAKE IT'S DIVERSE PRODUCT As an OEM supplier of audio speakers, the products that Tiffin, Ohio-based Ameriwood Industries International Inc. manufactures vary in size from small bookshelf-size speakers to large symphonic speakers.
Jim Harrington, plant manager of Ameriwood, said, "We do a variety of sizes and styles. We work with different types of materials, with different thicknesses and locations of holes. No two things are alike." Because of this product diversity, Ameriwood Industries (formerly Tiffin Enterprises) used to perform multiple machining operations for every item. Multiple operations meant that several workers had to handle each part, "and the more you handle it, the more opportunity there is for the product to be damaged," Harrington said.
To minimize parts handling -- and thus reduce their labor costs -- the company made an investment in a CNC machining center from Roger Stiles & Associates.
MACHINING CENTERS Vinyl overlayed particleboard is trimmed, cut-to-size, drilled and routed on the machining center. Computer programs are downloaded from a computer system directly into the machine's controller.
"We used CNC routers for a number of years," Harrington said. "The machining center is taking the place of routing and vertical-type drills." The machining center allows the company to do up to 12 workpieces at a time, Harrington said. After all the machining operations have been completed it is a "totally finished part" without need of further machining, Harrington added.
EFFICIENT PLANT HELPS COMPANY CONTROL COSTS In the past two years, Warvel Products-North Carolina has experienced dramatic price increases for the raw materials used to produce curved plywood components. These components are then sold to contract furniture manufacturers such as Haworth.
"We had 30 percent increases in our raw material costs," said sales manager Robbie Wiltcher, "so we have improved plant efficiency by purchasing machinery and technology that would allow us to absorb as much (of the price increase) as possible without passing these costs on. It is important for us as a vendor to help our customers be as competitive in their markets as possible." One of the ways Warvel did this was through the purchase of a multiple-station, four-axis CNC machining center from C.M.S North America. The machining center allows the company to mount up to six components at a time, and complements the company's existing three and five axis machining centers, Wiltcher said.
This is important, considering the amount of product which is shipped from the company's plant in Linwood, N.C. Approximately 100,000 parts a month are produced at the facility, the majority of which are customized. The company has a catalog with standard components, but Wiltcher said that 80 percent of the company's orders are made per customers specifications.
"The machine is capable of multiple machining tasks," Wiltcher said. "In most cases all that's left to do is light sanding and tee-nut installation where required." Another benefit, Wiltcher added, is the very tight tolerances obtained with the machine. The company supplies curved plywood which must integrate with plastic and steel components in ergonomic chairs.
"It is essential to be able to maintain tight tolerances in the various required operations such as drilling on angles, profiling and notching so that all of the different chair components fit together the way they were engineered. This machine provides all of these things," Wiltcher said.
To increase productivity even further, the company purchased machines and software that complement the machining center, including a digitizing machine. The digitizer will read a template part and the software will create a program which is downloaded into the machining center. The company also uses the system to internally produce its own compound tooling.
"The system has reduced the lead time on new tooling from months to days," said Wiltcher. "All of these capabilities assists our customers in bringing many new products to market rapidly and competitively." HIGH-TECH HELPS HIGH-END ARCHITECTURAL FIRM Powell Cabinet & Fixtures of Sparks, Nev., is a high-end architectural woodworking company whose work ranges from luxurious residences to glistening casinos.
The 42-year-old company, which bills itself as the oldest architectural woodworking company in the state of Nevada, is owned by the father/son team of Roger and Bill Powell.
One of the company's most recent projects was for the new Luxor Casino and Hotel in Las Vegas. The company did a variety of work at the hotel, including a 3 1/2-inch thick, 13-inch wide, solid-mahogany handrail that was built on a 255-foot radius. The handrail also featured solid-cast bronze support pieces and etched glass.
The handrail was manufactured utilizing a Komo VR 512 CNC machining center the company got in January 1993. Prior to that, the company had been doing everything with multiple machines. "The machining center is exceptional on irregular shapes and curves," Bill Powell said.
"It is more adaptable than to have a journeyman do it by hand. The radius work takes more time to program, but instead of having a journeyman woodworker spend several days on something, the machine will produce the same product in significantly less time." Powell added that there is a learning curve to the machine. "The purchase of the machine is just the first step," Powell said.
"The time that it takes to learn how to program and operate it is a major expense, as is the tooling and all the programming updates that are needed to keep up-to-speed." But while these factors need to be taken into account, Powell said he thinks it is becoming essential for companies to invest in high-technology equipment. According to Powell, one of the reasons the company purchased the machining center was because "the quantity of qualified, journeyman cabinetmakers that can produce this type of work is diminishing. You have to rely on the technical aspects of the industry to help fill that void," he said.
COMPANY GROWS A STEP AT A TIME When Denny Beuter and Bob Bloss formed Diamond Cut Inc. eight years ago they had a plan. The two men wanted their South Bend, Ind.-based company to become a leader in the field of commercial sound equipment. A daunting task made all the more difficult considering they did not own any sophisticated equipment.
"We went on the premise that we needed extremely good equipment to make a really good product," said Beuter. "But in order to get good equipment you have to have a product with enough volume to keep the machine running." What Beuter and Bloss did was to start slowly, acquiring equipment and producing parts for other companies. "We would do cutting and edging, anything to get work into the plant," Beuter said. "To sell machine time you have to do everything a little bit better than what the (source) companies can do in their own shop. We got real good, real fast, because otherwise we had to eat the cost of the job." From doing this job-shop-type-work, the next step was doing contract work. "My partner (Bloss), whose background is in the speaker business, went out (to speaker companies) and said, 'We can make speakers boxes for you and we can do them with high precision,'" Beuter said.
Diamond Cut began producing speaker cabinets for such companies as JBL and Panasonic. The product Panasonic wanted the company to produce necessitated an equipment upgrade. "The Panasonic people wanted a (speaker) box that was trapezoid shape," Beuter said. "This product would have been almost impossible to make with the router we were using." Beuter and Bloss chose a U-26 Morbidelli machining center from Tekna Machinery. The machine not only allows them to produce the trapezoidal shapes, it also has reduced labor costs. "For example, we had one full-time worker on the payroll whose only job was to make jigs, Beuter said. "I have no more jigs." While Diamond Cut has grown, with sales projected to reach around $2 million in 1994, the company continues to move toward that plan. In 1993, the company started a proprietary line of heavy-duty commercial sound equipment under the moniker, Bull Frog.
The Bull Frog equipment is sold throughout the United States and a number of countries around the world. "For 24-hours a day, for the last three months, we have been so busy with our own proprietary work that we have not been able to do any outside work, Beuter said.
"Hopefully by the end of the year we will be completely out of contract work." BOOTH MAKER FINDS SIGN TO SUCCESS Utilizing a variety of materials, Farmington Displays of Farmington, Conn., creates trade show displays for companies in industries as diverse as food, computers and guns.
Farmington Displays, which was founded in 1973 by Paul DiTommaso Sr., counts 278 companies as its clients. On average, Farmington Displays' clients update their booths every three to five years.
"We have a pretty good job flow," said general manager Sal DiTommaso, son of Paul Sr. and one of three sons and a daughter currently working for the company. "Not everybody is building their booth at the same time." Farmington Displays boasts an impressive client list, including General Electric, NEC and gun manufacturer Smith & Wesson. In the traditionally very labor-intensive field of display manufacturing, the company stands out for its use of high-technology equipment. More than three years ago, after extensive research on available machinery, the company began its investment in CNC machinery.
"The first thing that sparked my interest in obtaining CNC machinery was watching one of my men cutting out an eight-foot circle," said Sal DiTommaso. "It was so archaic, I just said there had to be another way to do it." Farmington Display's plant now features two Heian CNC routers and a computerized panel saw from Stiles Machinery, as well as a computerized graphic/design laboratories linked together as a Local Area Network.
The Heian machining centers have allowed the company to branch out into areas such as manufacturing signage and store fixtures. Farmington Displays had always created graphics for signs, but the CNC routers allow the company to manufacture them in-house. Additionally, the company is now doing contract machining for other, non-competing manufacturers.
To create their distinctive products, the company utilizes a variety of materials. On its CNC routers, the company utilizes everything from acrylics to solid woods. On a separate metal machining center the company works with brass and other metallic alloys. "We don't farm anything out," DiTommaso said. "We try to keep everything in-house so that we have complete quality control over the finished product." FAMILY-OWNED LUMBER YARD SEIZES CHANCE TO DIVERSIFY ITS BUSINESS In 1922, Hans Lars founded Hansen Lumber in Galesburg, Ill. Over the next 70 or so years, the business would be handed down from family-member to family-member, and would remain a traditional lumber yard.
It remained solely a lumber yard until two years ago when Hansen Lumber seized an opportunity to diversify. The company was asked to do some circular panel cutting for a Galesburg-based manufacturer of wooden reels. Approximately a year later that manufacturer, who believed the reel industry was going to dominated by the use of plastics, first contemplated shuttering the facility and then offered to sell the business -- and its client list -- to Hansen Lumber.
The family-owned company, currently being run by Shard Hansen, the founder's grandson, with help from his daughter Karen (the fourth-generation family member in the business), decided to purchase the company, and quickly realized the need to upgrade its equipment.
"Taking up wire or rope around a reel must be done at very high feed rates, especially if it is a small diameter wire, because unless your doing it at a 1,000 feel a minute it would take forever to wind," said Hansen, "so the arbor hole has to be exact. If the arbor hole is off center the whole thing will be jerking." A little more than a year ago the company purchased a CNC machining center from Accu-Router. The machine features two vertical routers, which can machine 1 1/2 inch southern yellow pine industrial grade plywood used for the flanges on the reels and maintains tight tolerances.
Prior to working with the machining center, the company would have to cut out a square and in subsequent steps radius the panel down to the required size and shape.
Having a high-technology machining center not only provides for accuracy, it also helps to utilize the plywood. "Our flanges range in size from eight inches to 48 inches round," said Hansen.
"When we are cutting the circles, we can nest them in such a fashion that we get great yield and waste is very nominal." CNC EQUIPMENT HELPS CARVING COMPANY MAKE BEAUTIFUL MUSIC Investing, not only in new equipment, but also in the training of its workforce has helped this Thomasville, N.C.-based carving company increase its capacity while reducing its overhead.
Founded in 1968, Piedmont Carving carves furniture parts -- specializing in chair parts -- and parts for such musical instruments as the cello and guitar.
Over the last few years, the company has sold some of its older carving machines and invested that money in computerized machinery including CNC Robot Carvers from Thermwood Corp.
"We used to have 13 carving machines and we would run all of them in one shift," said Gay Jones, who along with her twin brother Ray, and her father, company-founder Jimmy, own the business. "We sold three carving machines and still are projecting to triple our capacity with the robotic carvers." The company has reduced its labor costs in part by computerizing its carving, but also by cross training its 29 employees so that they can work on other machines in the shop.
Learning to efficiently use the CNC robot was a difficult challenge for the company, Gay Jones said, "but I'm glad we did because it gives us an advantage over companies who are just now getting into robotic carving." Piedmont Carving bought its first robotic carver four years ago. The company is planning to purchase additional machines.
One of the benefits of computerized machinery is consistency. This is important when Piedmont is crafting its furniture and musical instrument components.
"Chair parts have to fit together perfectly when they're sent to the manufacturer," Jones said. "With the robotic carving everything stays so consistent. This consistency is also very important when we are doing the musical instruments because the craftsmanship that goes into the part can affect the sound." CARVING WOOD PARTS 20 AT A TIME Intricate handcarvings are being quickly and accurately duplicated by Carving Research Inc. of Huntersville, N.C., using a 20-head Kitako CNC Machining Center distributed by Tekmatex Inc.
Carving Research is a 2-year-old, 12-employee company with projected 1994 sales of $840,000. The company supplies intricate wood carvings to such major residential furniture makers as Henredon Furniture Industries Inc. and Baker Furniture Co.
What once had to be done one at a time by master handcarvers can now be done 20 at a time by the company. This results not only in time savings but cost savings as well, without sacrificing the look of the product, according to company owner Tom Bowker. An example of the speed of the machine is a rice carved bed post; typically it would take a master handcarver approximately six to eight hours to complete, "while we can do it in an hour," Bowker said.
To produce the carvings, an initial handcarved template is made. This carving is sent to Tekmatex, where a digitizing machine creates a computer program which can be downloaded into the machining center. Once this program is completed, an infinite number of a given carving can be created with precision.
There are certain "essential ingredients" to creating the carvings, said Bowker. Tooling is one of the most important. Because of the nature of the product, the Carving Research utilizes unique tooling, including a razor-sharp veining bit developed by Oertli Woodworking Tools Inc. that leaves such a clean cut, that secondary carvings are not necessary, Bowker said. Another example is a 1/16-inch flat-bottom or straight router bit which is used on many of the carvings.
"Nobody else uses anything like that," Bowker said.
"Because of the intricacies of many of the carvings, we have to use a wider variety of tooling including some carbide tooling, than what you would use if running a normal carving operation. Many of our bits have to be small because you have to get in and do a cut and make it look like it was done with a chisel.