Median hourly earnings of tool and die makers were $20.54 in 2002. The middle 50 percent earned between $16.33 and $25.64. The lowest 10 percent had earnings of less than $12.97, while the top 10 percent earned more than $30.74. Median hourly earnings in the manufacturing industries employing the largest numbers of tool and die makers in 2002 are shown below.
| Motor vehicle parts manufacturing | $25.64 |
| Metalworking machinery manufacturing | 20.02 |
| Forging and stamping | 19.97 |
| Plastics product manufacturing | 19.79 |
Tool and die makers are among the most highly skilled workers in manufacturing. These workers produce tools, dies, and special guiding and holding devices that enable machines to manufacture a variety of products we use daily—from clothing and furniture to heavy equipment and parts for aircraft.
Toolmakers craft precision tools and machines that are used to cut, shape, and form metal and other materials. They also produce jigs and fixtures (devices that hold metal while it is bored, stamped, or drilled) and gauges and other measuring devices. Die makers construct metal forms (dies) that are used to shape metal in stamping and forging operations. They also make metal molds for diecasting and for molding plastics, ceramics, and composite materials. Some tool and die makers craft prototypes of parts, and then determine how best to manufacture the part. In addition to developing, designing, and producing new tools and dies, these workers also may repair worn or damaged tools, dies, gauges, jigs, and fixtures.
To perform these functions, tool and die makers employ many types of machine tools and precision measuring instruments. They also must be familiar with the machining properties, such as hardness and heat tolerance, of a wide variety of common metals and alloys. As a result, tool and die makers are knowledgeable in machining operations, mathematics, and blueprint reading. In fact, tool and die makers often are considered highly specialized machinists. The main difference between tool and die makers and machinists is that machinists normally make a single part during the production process, while tool and die makers make parts and machines used in the production process. (See the statement on machinists elsewhere in the Handbook.)
Working from blueprints, tool and die makers first must plan the sequence of operations necessary to manufacture the tool or die. Next, they measure and mark the pieces of metal that will be cut to form parts of the final product. At this point, tool and die makers cut, drill, or bore the part as required, checking to ensure that the final product meets specifications. Finally, these workers assemble the parts and perform finishing jobs such as filing, grinding, and polishing surfaces.
Modern technology has changed the ways in which tool and die makers perform their jobs. Today, for example, these workers often use computer-aided design (CAD) to develop products and parts. Specifications entered into computer programs can be used to electronically develop drawings for the required tools and dies. Numerical tool and process control programmers use computer-aided manufacturing (CAM) programs to convert electronic drawings into computer programs that contain instructions for a sequence of cutting tool operations. (See the statement on computer-control programmers and operators elsewhere in the Handbook.) Once these programs are developed, computer numerically controlled (CNC) machines follow the set of instructions contained in the program to produce the part. Computer-controlled machine tool operators or machinists normally operate CNC machines; however, tool and die makers are trained in both operating CNC machines and writing CNC programs, and they may perform either task. CNC programs are stored electronically for future use, saving time and increasing worker productivity.
After machining the parts, tool and die makers carefully check the accuracy of the parts using many tools, including coordinate measuring machines (CMM), which use software and sensor arms to compare the dimensions of the part to electronic blueprints. Next, they assemble the different parts into a functioning machine. They file, grind, shim, and adjust the different parts to properly fit them together. Finally, the tool and die makers set up a test run using the tools or dies they have made to make sure that the manufactured parts meet specifications. If problems occur, they compensate by adjusting the tools or dies.
.Applicants with the appropriate skills and background should enjoy excellent opportunities for tool and die maker jobs. The number of workers receiving training in this occupation is expected to continue to be fewer than the number of openings created each year by tool and die makers who retire or transfer to other occupations. As more of these highly skilled workers retire, employers in certain parts of the country report difficulty attracting well-trained applicants. A major factor limiting the number of people entering the occupation is that many young people who have the educational and personal qualifications necessary to learn tool and die making may prefer to attend college or may not wish to enter production-related occupations.
Despite expected excellent employment opportunities, little or no growth in employment of tool and die makers is projected over the 2002-12 period because advancements in automation, including CNC machine tools and computer-aided design, should improve worker productivity, thus limiting employment. On the other hand, tool and die makers play a key role in building and maintaining advanced automated manufacturing equipment. As firms invest in new equipment, modify production techniques, and implement product design changes more rapidly, they will continue to rely heavily on skilled tool and die makers for retooling.
Most tool and die makers learn their trade through 4 or 5 years of education and training in formal apprenticeships or postsecondary programs. Apprenticeship programs include a mix of classroom instruction and job experience and often require 10,400 hours, or about 5 years to complete. According to most employers these apprenticeship programs are the best way to learn all aspects of tool and die making. A growing number of tool and die makers receive most of their formal classroom training from community and technical colleges, sometimes in conjunction with an apprenticeship program.
Even after completing their apprenticeship, tool and die makers still need years of experience to become highly skilled. Most specialize in making certain types of tools, molds, or dies.
Tool and die maker trainees learn to operate milling machines, lathes, grinders, wire electrical discharge machines, and other machine tools. They also learn to use handtools for fitting and assembling gauges, and other mechanical and metal-forming equipment. In addition, they study metalworking processes, such as heat treating and plating. Classroom training usually consists of mechanical drawing, tool designing, tool programming, blueprint reading, and mathematics courses, including algebra, geometry, trigonometry, and basic statistics. Tool and die makers increasingly must have good computer skills to work with CAD technology, CNC machine tools, and computerized measuring machines.
Workers who become tool and die makers without completing formal apprenticeships generally acquire their skills through a combination of informal on-the-job training and classroom instruction at a vocational school or community college. They often begin as machine operators and gradually take on more difficult assignments. Many machinists become tool and die makers.
Because tools and dies must meet strict specifications—precision to one ten-thousandth of an inch is common—the work of tool and die makers requires skill with precision measuring devices and a high degree of patience and attention to detail. Good eyesight is essential. Persons entering this occupation also should be mechanically inclined, able to work and solve problems independently, and capable of doing work that requires concentration and physical effort.
There are several ways for skilled workers to advance. Some move into supervisory and administrative positions in their firms; many obtain their college degree and go into engineering or tool design; and some may start their own shops.
The occupations most closely related to the work of tool and die makers are other machining occupations. These include machinists; computer-control programmers and operators; and machine setters, operators, and tenders—metal and plastic. Another occupation that requires precision and skill in working with metal is welding, soldering, and brazing workers.
Like tool and die makers, assemblers and fabricators assemble complex machinery. When measuring parts, tool and die makers use some of the same tools and equipment that inspectors, testers, sorters, samplers, and weighers use in their jobs.
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For lists of schools and employers with tool and die apprenticeship and training programs, contact:
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Toolmakers craft precision tools which are used to cut, shape, and form metal and other materials. They also produce jigs and fixtures (devices that hold metal while it is bored, stamped, or drilled) and gauges and other measuring devices. In addition to developing, designing and producing new tools and dies, these workers may also repair worn or damaged tools, dies, gauges, jigs, and fixtures. To perform these functions, tool and die makers employ many types of machine tools and precision measuring instruments. For example, these workers increasingly use computer-aided design (CAD) to develop products and parts.
Summary of: http://www.umsl.edu/services/govdocs/ooh20002001/358.htm
For example, an accountant must complete four years of college and work for several years in accounting to be considered qualified. Job Training Employees in these occupations usually need several years of work-related experience, on-the-job training, and/or vocational training. Job Zone Examples Many of these occupations involve coordinating, supervising, managing, or training others. Department of Labor Office of Apprenticeship Training, Employer and Labor Services (OATELS) website. Many of the occupations require working outside, and do not involve a lot of paperwork or working closely with others.
Summary of: http://online.onetcenter.org/link/summary/51-4111.00
Toolmakers craft precision tools that are used to cut, shape, and form metal and other materials. They also produce jigs and fixtures (devices that hold metal while it is bored, stamped, or drilled) and gauges and other measuring devices. In addition to developing, designing and producing new tools and dies, these workers also may repair worn or damaged tools, dies, gauges, jigs, and fixtures. Next, they measure and mark the pieces of metal that will be cut to form parts of the final product. Today, for example, these workers often use computer-aided design (CAD) to develop products and parts.
Summary of: http://www.umsl.edu/services/govdocs/ooh20022003/ocos225.htm
All of these modules are designed to reduce lead times and increase productivity. This is undeniably the most sophisticated electrode software on the market. The process is simple whilst at the same time flexible. PS-Moldmaker works with the designer through the process of preparing the detailed tooling and BOM for complex plastic injection and blow-molded products. The knowledge of how user defined parts and catalog parts are assembled brings quality and efficiency benefits to the downstream design and planning.
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Toolmakers craft precision tools which are used to cut, shape, and form metal and other materials. They also produce jigs and fixtures (devices that hold metal while it is bored, stamped, or drilled) and gauges and other measuring devices. Tool and die makers must have a much broader knowledge of machining operations, mathematics, and blueprint reading than most other machining workers. Firms commonly use computer aided design (CAD) to develop products. The designs can then be sent to computer numerically controlled (CNC) machines to produce the die.
Summary of: http://www2.jobtrak.com/help_manuals/outlook/ocos225.html
Tool and Dye Maker Career and Job Description Some of the most skilled employees in production are tool and dye makers. Toolmakers make a variety of tools and machines that must be utilized in the cutting, shaping, and forming of metals and other supplies. Besides the working on the development, design, and production of tools and dies, these employees might also make repairs on old or broken tools, dies, jigs, fixtures, and gauges. Additionally, workers need to have familiarity with machining properties, like heat tolerance and hardness, as well as an array of other normal metals and alloys. Lastly, tool and dye makers put the parts together, and file, grind, and polish the part as needed.
Summary of: http://www.careeroverview.com/tool-and-dye-maker-careers.html
Die makers construct metal forms (dies) that are used to shape metal in stamping and forging operations. In addition, tool and die makers design new tools and dies. Many tool and die makers now use computer-aided design (CAD) to develop products and parts. With CAD, workers enter specifications into computer programs. They like to be treated fairly and have supervisors who will back them up.
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Toolmakers craft precision tools and machines that are used to cut, shape, and form metal and other materials. They also produce jigs and fixtures (devices that hold metal while it is bored, stamped, or drilled) and gauges and other measuring devices. Some tool and die makers craft prototypes of parts, and then determine how best to manufacture the part. Finally, these workers assemble the parts and perform finishing jobs such as filing, grinding, and polishing surfaces. Modern technology has changed the ways in which tool and die makers perform their jobs.
Summary of: http://www.bls.gov/oco/ocos225.htm