Top Tips to Choose the Best Connectors

From smart phones to sophisticated machineries that manufacture them, you can find an electrical connector in many forms. If you are an electrical industrialist or purchase engineer, it is essential to have some key factors in mind before making your final choice.

Here are a few essential aspects to check while choosing a connector:


Power of the connector is a determining factor. The market offers a wide range of connectors with different power-ratings. Identify your requirement and choose the one that meets the purpose.

A low power variant may not give you the expected efficiency and on the other hand, a high power connector can even damage the entire system.


The density of a connector is yet another influential factor in the present day. The higher the connector density, the more compact your machine design will be. This is especially important in case of complex machineries. In order to keep it solid at the same time give exceptional performances, it is essential to choose a high-density connector.

Temperature Resistance

Another important feature that adds to the quality of a connector is its capacity to withstand high temperatures. Most of these connectors are used in intricate machineries and they undergo immense heat exposure during their functioning. High-end connectors are often passed through multiple levels of testing to ensure its temperature resistance.


The transmission speeds of connectors are quite significant for their overall performance. Many of the latest connectors ensure to meet high transmission speeds. ExaMAX High Speed Backplane Connectors are one of the best you can get in the market these days.

Mating Features

The mating features of any connector play an important role in determining its performance, quality and durability. Before you choose your connector, ensure that you scout through specifications to analyze its mating features. The angle of mating, the number of mating cycles, etc. will be clearly mentioned in the specifications, which help to find the one matching your requirements. Mating cycles are especially important for connectors that are mated and unmated frequently. For a USB connector the mating cycles will be in thousands where as for a board to board connector will have a lesser mating cycle.

The easiest way to decide on a connector is often to choose the best brands. The connectors manufactured by prominent brands will have all major certifications, which makes it trustworthy. In that case, you will not have to compromise in terms of quality and safety.

3 Basic Types of Electrical Connectors

Any electrical equipment will have different types of electrical connectors within. Each connector comes in different shapes, sizes, and materials. Function is another key factor that classifies the connectors.

From connecting a wire to a board to joining key elements on a PCB, connectors play diverse roles and serve many applications. Despite their simple design, they connect and bring power/signals to the system. Key factors that determine the quality of a good connector is its reliability, signal integrity, speed performance, power rating durability, and ease of assembly.

Connector manufacturers offer an extensive array of tried and tested product solutions.

There a few common connectors which are worth the mention:

8P8C Connector

8P8C connector, where 8P8C stands for “eight positions, eight conductors” have eight positions, with corresponding conductors in the mating socket assigned to each. It is basically a modular connector and was primarily used in telephone wire applications. Today, they serve many applications and functions like being used to interface Ethernet jacks.

The 8P8C connectors have a male plug and a corresponding female socket connection. It carries eight contacts and when they get aligned with the corresponding eight conductors within the sockets, electrical signals get transmitted. Apart from Ethernet and telephone wires, they are also used in computer applications and other communication cables.

Generally, most modular connectors are technically named after the number of positions and conductors. They include sizes like -4-,-6-, 8-, and -10-. For instance, a 10P8C will have ten positions with eight conductors.

D-Subminiature Connectors

D-subminiature is much similar to 8P8C, as they are used in computer and play a critical function on modems. Though the name states “subminiature”, these are larger than most modern computer connectors. The connector has a D-shaped metal component that defines its shape and protects it. It also consists of two or more rows of pins with varying numbers in the male connector and a similar set of receiving ends in the female part. The male connector with a pin is called a plug whereas the receiving part that houses the contacts that connect these pins is called a socket. This connection is established to transmit electrical signals. This variant has the capability to provide protection against electromagnetic interference, commonly known as EMI.

USB Connectors

USB or Universal Serial Bus is a very common type of connector. They are small interfaces used to attach multiple devices to a computer. You can see at least two USB ports in any standard laptop that support external USB connectors and cables, while desktops have up to 4 USB ports in general. USB connectors gained much popularity and recognition, as it can be connected and disconnected easily while the device is still working. This contributed to its widespread use in computer applications that constantly require plugging and unplugging external devices, especially for transferring data.

Industrial Processes And Emerging Technologies

Technology has been playing an incredible role in transforming the way industrial processes are performed. Whether it is a machine-to-machine communication or augmented reality, technology has been helping industries in every possible way to streamline and automate their work. Emerging technologies, like 3D printing, robots, algorithms, etc., have the power to completely transform the existing manufacturing processes. Or, in other words, modern technology has the potential to make our lives better. A rapid increase in the level of sophistication in technology has a strong impact on the workforce.


Robots are being increasingly used to perform all sorts of industrial tasks. The developed parts of the world have witnessed a sharp rise in the demand for automated machines and equipment. Approximately, there are more than 2 million robots in use and the number is expected to rise quickly in coming years. Japan is leading the list of countries with the most number of robots. Recent years have witnessed a major decrease in the costs of automation and robotics.

Additive manufacturing

Additive manufacturing or 3D printing is an emerging technology that enables industries to manufacture three-dimensional objects. It is a process of building complex products by adding ultrathin layers of materials one by one. Currently, only selected items are being created out of a single material, for instance, medical implants and plastic prototypes. Comparing 3D industrial technology with that of traditional, additive manufacturing enables industries to manufacture new shapes without worrying about manufacturing limitations.

Autonomous technology

Autonomous technology, such as unmanned cars, is stretching the possibility of producing highly sophisticated industrial machines capable of performing the unthinkable. It has a great potential in making industrial processes seamlessly smooth with hardly any human intervention. Autonomous robots have already been deployed by a number of industries worldwide to perform quality control and inspection related tasks.

Augmented reality

Augmented reality is about the augmentation of the elements of physical world. By using handheld sensors, people can simulate various situations or, in other words, augmented reality enables us to create an illusion of reality. This technology can help engineers build incredible industrial solutions. One of the practical applications of this technology is the training of military recruits where they are tested with various virtual situations.

Conclusively speaking, new technologies are enabling engineers to develop intelligent machines that can perform multiple industrial tasks with great precision and speed. Companies need to invest in automation technology in order to maintain competitiveness and meet growing demand for innovation and modernity.

Purpose of Tensile Testing and Its Use in the Plastic Industry

One of the most elementary tests that can be performed on a product is the tensile test to check the breaking resistance of a product. A test specimen is kept under tension to practice opposing forces acting upon opposite faces both located on the same axis that attempt to pull the specimen apart. These tests are simple to set and complete and reveal many characteristics of the products that are tested. These tests are measured to be fundamentally the reverse of a compression test.

Purpose of this test

Usually, this test is designed to run until the specimen breaks or fails under the specific load. The values that are calculated from this type of test can vary but are not limited to tensile strength, elongation, ultimate strength, modulus of electricity, yield strength, and strain hardening. The measurements taken during the test reveal the characteristics of a material while it is under a tensile load.

Tensile Testing for Plastics

Composites and Plastic are polymers with substances added to improve the performance or reduce costs. Plastic may be pressed or cast or extruded into sheet, film, or fibre reinforced plate, glass, tubes, fibre, bottles and boxes. Thermohardening or thermosetting plastics can be brittle or hard and temperature resistant. Thermosets include polyester resins, epoxy resins, polyurethane, phenolic resins, non-meltable, non-deformable and polyurethane. Polymers and plastics can be tested to measure product quality. The tests measure the weight required to split or break a plastic test material and sample elongation or stretch to that breaking load. The resulting data help to identify product quality and quality control checks for materials.

Plastic testing instruments, universal test machines provide a constant rate of extension because plastic tensile test behaviour is dependent on the speed of the test machine. The specimens loaded on the machines are set as per ASTM, DIN, ISO tensile test specimen dimensions. The Plastic tester machine should always rely on standard terms and conditions. As per ASTM D638, Plastic tensile test standards help to measure strain below 20 percent extension values. High strain can be measured by the machine, digital reader. Thin sheet sample testing is done as per the standard ASTM D882.

A high-quality testing machine is designed to measure the strength of a specific product, test method and product type. A good instrument can be the only solution required for your quality assurance and a worse choice can make you go in the loss too. So choose the instrument smartly.