What are precision machines

What are precision machines?

The precision machine tool is far from being a novelty in the metallographic industry. Rather, it is a necessity without which parts cannot be machined to high accuracy. Therefore, this equipment is of particular importance and must be present in every laboratory dealing with the study of thin sections.

Here are several classifications of precision machines.
According to the groups they can be divided into:

  • turning
  • drilling and boring
  • grinding
  • gear-machining
  • milling

Then the manufacturer subdivides them by accuracy classes:

  • class P (increased)
  • class B (high)
  • class A (especially high)
  • class C (extremely precise)

Machining and manufacturing of parts on precision machines makes it possible to obtain products and workpieces with surfaces corresponding to individual one-time or large bulk orders, providing products with precise positioning of axes, giving the correct geometric shape with low, or no, roughness. The machines utilize active monitoring devices and a high level of automatic equipment control.

A precision machine tool with limitless possibilities

These machines are used for machining metals and other materials in order to achieve high-precision milling or drilling for threading internal and external threads, profiles and grooves in products.

These are the demands placed on products in aircraft construction, ship modeling, die and mold milling and many other modern manufacturing industries.

Precision machines in high-tech development

Metkon precision machine tools are used in various industries: metallurgy, geology, electronics, research, biomedical or industrial laboratories.

As a method to examine and determine the quality of metals, various alloys, polymer compounds, ceramics and composites, metallographic equipment helps to assess their quality and properties:

  • cutting machines (abrasive and precision)
  • presses for pressing
  • drying cabinets
  • and other, special equipment

A special place was taken by precision machines in the field of petrography. The method of petrographic research on such machines is the basic one in metallography and helps to obtain precise results, without deviations in readings and with a short time of their preparation.

The sample preparation process consists of grinding, homogenization, hydrolysis and other operations carried out over the analysis sample in order to obtain the necessary data.

Applications

  • microscopy
  • chromatography
  • materialography
  • X-ray structural, instrumental, chemical and other types of analysis
Welding in construction industry

Welding in construction industry

One of the main technological processes in the construction industry is the connection of parts and elements by welding. Welding is used in the manufacture and installation of metal and reinforced concrete structures, process pipelines and equipment of various grades of steel, non-ferrous metals and alloys, other materials.

Productivity to ensure the necessary quality of welding, efficiency of construction and installation work and reliability of buildings and structures are determined in no small measure, the technical level and qualifications of specialists.

This is all the more important in terms of using for structures of difficult to weld effective steels and alloys, the use of new welding materials and increasingly sophisticated welding equipment, the application of new and progressive technological processes, increasing demands on the quality of building products created.

The content of the lecture notes corresponds to the curriculum of the section “Welding in construction” of the discipline “Metals and welding in construction”. The material is somewhat broader, which allows using it when working on the course and diploma projects.

About welding

The problem of firm connection of solid materials has been of great importance since ancient times. The processes of joining parts made of metal, wood, stone, ceramics, bricks, plastics, etc., as well as separating and crushing them complement each other and form the basis for the processing of solid materials. Without these processes it is impossible to imagine industry and construction nowadays.

There are two large groups of compound solids

  1. Mechanical methods of joining
  2. Methods of connection by molecular and atomic forces of adhesion

The first group includes various types of bolted connections, rivet and wedge connections, tight fit, etc.; the second group includes welding, brazing, gluing, cementing, etc.

The second group listed methods of connection of solid bodies differ in their features, and has its own areas of application, complementing each other, and allow you to perform a variety of production tasks.

The methods of the first group allow to obtain detachable joints, i.e. giving the possibility to separate the parts without destroying them. Connections of the second group are mostly inseparable.

One of the main methods of the second group is welding, which allows to join almost all metals and their alloys, glass, plastics, ceramics, etc. Welding methods are constantly improving, the scope of their application is expanding. This is required by the rapid development of technology, the use of new materials, the creation of new original designs.

What Is CNC Machining

What Is CNC Machining?

CNC machining, or Computer Numerical Control machining, refers to a production technique in which industrial equipment and machinery are controlled by pre-programmed software application. The method may be utilized to operate a wide range of sophisticated gear, including mills, latches, and grinders. 3D cutting operations may be completed in a one set of instructions using CNC machining.

The movement of manufacturing tools and machinery is dictated by pre-programmed computer software. The CNC method overcomes — and hence replaces — the constraints of manual control, which requires live operators to direct milling tool orders via levers, wheels, and buttons. A CNC system may appear to the untrained eye to be a standard set of computer parts, but the console and software used in CNC set it apart from all other kinds of computation.
Learn more about CNC machining and CNC programming if you’re interested in using CNC manufacturing to make a variety of items. You may also want to understand about the various types of CNC machines and the types of jobs they can perform to determine whether they can satisfy your requirements.

How does CNC machining work?

When a CNC system is turned on, the required designs are programmed to software and sent to appropriate equipment and machines, which, much like a robot, carry out the dimensional duties as defined.

In CNC cutting, the numerical system’s code generator frequently assumes that steps are faultless, despite the potential of mistakes, which is increased when the machine is commanded to cut in more than one direction at the same time. A set of inputs called the part-program determines where a tool is placed in a numerical system.

Punch cards are used to input programming into a numerical controlling system. CNC machine programming, on the other hand, are input into computers through tiny keyboards. The program stays within the memory. As a result, CNC systems have considerably greater processing capability. Best of all, CNC machines are far from static, as fresh prompts may be included to current programs by modifying the code.

Programming CNC Machines

Machines in CNC production have a numerical control mechanism, which uses a software application to impact an item. The language underpinning CNC machining is known as G-code. It is used to regulate the feed rate, speed, and synchronization of a corresponding machine.
The technique has been embraced across the industrial industry as a result of these capabilities, and CNC manufacturing is especially important in the fields of metal and plastic manufacture. Learn more about the many types of machining systems that are utilized, as well as how CNC machine programming completely automates CNC production, in the sections below:

1. Machining Systems with Open/Closed Loops

Position control is decided by a closed loop or open loop system during the CNC manufacturing process. Signaling between the CNC controller as well as the motor is done in a single direction with the former. A closed-loop CNC system allows the controller to receive feedback, which allows for mistake correction. As a result, a closed-loop system can correct velocity and position anomalies.

Movement is generally directed across the X and Y axes in CNC machining. Stepper or servo motors, which repeat exact motions as defined by the G-code, are used to position, and guide the tool. The procedure can be conducted using open-loop control if the force and speed are low. Closed-loop control is essential for everything else to maintain the speed, consistency, and accuracy required for industrial applications like metalwork.

2. CNC Machining Is a Completely Automated Process

The manufacturing of parts using pre-programmed software is mostly automated in today’s CNC protocols. Computer-aided design (CAD) software is used to define the dimensions for a particular item, which is subsequently transformed into an actual final product using computer-aided manufacturing (CAM) software.

A range of tools, including as cutters and drills, may be required for any given workpiece. In order to meet these demands, many modern devices integrate several operations into a single cell. An installation might also consist of numerous machines as well as set of robotic hands, all controlled from the same program. Regardless of the configuration, the CNC process ensures component uniformity that would be difficult, if not impossible, to achieve by hand.

CNC Machines Come in a Variety of Shapes and Size

The first numerical control devices originate from the 1940s, when motors were used to control the movement of pre-existing tools for the first time. As technology progressed, analog computers and, eventually, digital computers were added to the machinery, resulting in the birth of CNC machining.
The most popular CNC-controlled operations are ultrasonic welding, hole punching, and laser cutting. The great majority of CNC arsenals nowadays are entirely electronic. Ultrasonic welding, hole-punching, and laser cutting are some of the most typical CNC-controlled operations. The following are the most often utilized machines in CNC systems:

1. CNC Milling Machines

CNC mills may execute programs that consist of number and letter prompts that guide parts over different lengths. A mill machine’s programming might be based on G-code, or a proprietary language established by a manufacturing team. A three-axis system (X, Y, and Z) is standard on mills, however most modern mills can accept three more axes.

2. Lathes

With indexable tools, parts are cut in a circular direction on lathe machines. Lathe cuts are made with precision and speed thanks to CNC technology. CNC lathes are used to create intricate designs that would be impossible to achieve with a manually operated machine. CNC-controlled mills and lathes have comparable control functions in general. Lathes, like CNC mills, can be controlled using G-code or proprietary code. Most CNC lathes, on the other hand, have only two axes: X and Z.
CNC lathes are used to create intricate designs that are impossible to achieve with manually operated equipment.

Plasma Cutting Machines

A plasma torch slices the material in a plasma cutter. The method is most commonly used on metals, although it may also be used on other surfaces. Plasma is created using a mix of compressed air gas and electrical arcs to provide the speed and heat required to cut metal.

Electric discharge CNC machines

Electric-discharge machining (EDM), also known as die sinking or spark machining, is a method that uses electrical sparks to mold workpieces into certain forms. Current discharges between two electrodes occur in EDM, and this eliminates portions of a workpiece.
The electric field gets more powerful and hence stronger than the dielectric as the space between the electrodes shrinks. A current can now travel between the two electrodes as a result of this. As a result, each electrode removes a part of the workpiece. The following are examples of EDM subtypes:

Water jet cutters

Water jets are CNC machining tools that use high-pressure water jets to cut hard materials like stone and metal. In certain situations, sand or another abrasive substance is added to the water. This method is frequently used to shape manufacturing machine components.
Water jets are used as a cooler option for materials that cannot withstand the high temperatures generated by conventional CNC machines. Water jets are used in various industries, including aerospace and mining, because of their cooling nature. They are used for carving and cutting, among other things. Water jet cutters are also used in applications that need highly delicate material cuts, as the lack of heat avoids any changes in the material’s fundamental characteristics that may occur with metal on metal cutting.

Final words

You can rely on CNC technology to manufacture an almost infinite variety of items fast and correctly since it can incorporate so many additional tools and components. For example, when complex cuts at various levels and angles on a workpiece are required, a CNC machine can do the task in minutes. While keeping these facts in mind, you can go for the best CNC Machine out there.

Welding History

Welding History

What is welding?

Welding is a technique of joining metallic parts through high temperatures, adding fillers to make a pool, and cooling them to allow their fusion. Materials used to generate heat sources include gas, electricity, laser beams, friction, and ultra-recently robotic-welding.

Friction stir-welding, laser-welding, and ultrasonic-welding are some of the processes commonly used in joining aluminum. Welding of Aircraft-grade aluminium is not possible by using traditional-welding methods to its oxide layer, thus requiring alternating current.

The sight of welding-rods emitting sparks and holding pieces of metal together excites a curious mind to wander back to medieval times. How did the ancient people manage to pull off such a feat without electrode rods?

The History of Welding

The history of welding is traced to the Bronze age that occurred 2000 years ago. During the time, gold circular boxes were made from pressure welded lap joints.

Then in approximately 1000 B.C. came the Iron age. Many tools believed to have been made during this time are traced to the Egyptians and inhabitants of the eastern Mediterranean area, who were thought to have learned to weld iron pieces together.

The development of the art of blacksmithing in the middle ages led to the production of many iron items through hammering. Typical-welding as it is today was invented in the 19th century.
Chronological Advances in Welding’s/cutting Techniques

1800

Humphrey Davy is credited with arc production by the use of a battery to create two electrodes. Edmund Davy was instrumental in the discovery of acetylene in 1836. Mid 19th century witnessed the invention of the generator, which popularised arc lighting.
The late 1800s led to the development of gas-welding and cutting. As a result, arc-welding with the carbon arc and metal arc was developed, and what came to be known as resistance-welding became a practical joining process.

1880

Augusta De Meritens used the heat of an arc for joining lead plates for storage batteries in 1881. His student Nikolai N. Bernados made progress in welding’s cast iron and lead. The periods between the 1890s and early 1900s were the years of carbon arc-welding.

1890

C.L. Coffin of Detroit became the pioneer in using a metal electrode for arc welding-processes which involved the deposit of filler metal in the joint to create a weld. On the other side, N.G. Slavianoff was busy with the same idea of transferring metal across an arc, but instead, to cast metal in a mold.

1900

Strohmrnger brought into the picture a clay or lime-coated metal electrode. Oscar Knellberg brought in a coated electrode between 1907 to 1924. Stick electrodes were made by dipping bare iron wire in mixtures of carbonates and later drying the coating.

At the same time, resistance-welding continued to be developed, and processes like spot-welding, seam-welding, projection-welding, and flash butt-welding became commonplace, with Elihu Thomson being credited their originator tag.

The invention of thermite-welding in 1903 by Goldschmidt was accelerated by the need to weld railroad rails. Gas-welding and cutting were advanced by the emergence of a torch that was used with acetylene during this period.

With First World War came the demand for armaments, and many companies began to manufacture electrodes and welding-machines to meet the demand.

1920

Automatic-welding came about and utilized electrode wires and arc voltage to control the feed. Thanks to P.O. Nobel who introduced it to be used in building women motifs shafts and crane wheels. The automotive industry adopted its use in the production of rear axles housings.

During the 1920s, various electrodes were developed, fuelling debates on heavily coated rods versus light coated rods.

1930

The arrival of stud-welding to attach wood decking and metal popularized what later became helpful in the shipbuilding and construction industries. Then came the automatic submerged arc-welding process, which was used in shipyards and ordinance factories.

1940

The Gas metal arc-welding (GMAW)was developed in 1948 and replaced Gas Tungsten. Here the tungsten electrodes were replaced by electrodes wires using constant voltage power sources. The process was initially meant to deal with non-ferrous metals, and users tried to introduce this on steel, but the cost of gas impeded its use.

1950

Russian scientists K.V. Lyubavskii and N.M. Novozhilov came ump using consumable electrodes subjected through the use of carbon dioxide. Consumable electrodes were immediately adopted because they utilized equipment that was initially applied to gas metal arc-welding. The introduction of smaller diameter electrode wires allowed welding on thin materials and gained more popularity.
Plasma arc-welding came in 1957.

1960

The early 1960s witnessed the use of inert gas that economizes oxygen through spray-type arc transfer. The electron beam-welding-process, which uses a focused beam of electrons, was introduced in 1957.

The US automotive industry and aircraft engine industries are heavy users of electron beam-welding. Due to the high strength-to-weight ratio of aluminium, it is popular in the aviation industry. One of the ways of attaching aluminum to aircraft is through welding’s.

The electro-molding process was introduced in 1959 for the fabrication of welded diesel engine blocks. The electro gas was introduced in 1961.

Laser-welding developed by Bell Telephone Laboratories leads the newest processes used for cutting metals and aluminum in the automotive industry. Manual metal arc-welding has become popular in cast iron welding’s.

Recent Welding Developments

Welding-techniques have continued to be invented, with the latest being the use of AI robotics to perform strenuous tasks such as cast iron-welding on vehicles or fixing hard surfaces. Furthermore, robotics reduces human injuries through lifting and welding’s; this releases people to work in other productive areas.