This article has been supervised based on the advanced technical expertise and insights we have cultivated since our founding in 1919 as a leading company in plastic processing. Our department continuously analyzes market trends and the latest technologies in ultra-compact, high-precision micro motors, focusing on providing high-value-added information to designers and developers. As a team of experts with in-depth knowledge of product characteristics, we support our customers\u2019 problem-solving and technological innovation by delivering accurate and practical content.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n
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Basic Mechanism and Operating Principles<\/a> of Electric Motors<\/h2>\n![\"What](\"https:\/\/cik-ele.com\/wp-content\/uploads\/2026\/04\/021ccd7ada7f638598902a8fbd95bbdd-540x360.jpg\")
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An electric motor is a device that converts electrical energy into mechanical rotational motion, and its operating principles are deeply rooted in the laws of physics. When selecting a motor for industrial applications, a correct understanding of these operating principles<\/a> is essential.<\/p>\nBy understanding how electric motors convert electricity into force, as well as their basic structure and operating mechanisms, you will be able to select the most appropriate motor for your product development.<\/p>\n
Topics Covered in This Section<\/strong><\/p>\n\n- What Is an Electric Motor?<\/li>\n
- Basic Structure of Electric Motors<\/li>\n
- The Rotation Principle of Electric Motors<\/li>\n<\/ul>\n
Understanding this foundational knowledge provides the basis for making optimal motor selection decisions in product development.<\/p>\n
<\/p>\n
What Is an Electric Motor?<\/span><\/h3>\nAn electric motor is a general term for a device that converts electrical energy into mechanical energy. Known as a “electric motor” in Japanese, it generates rotational motion by utilizing the interaction between a magnetic field and an electric current.<\/p>\n
According to various studies, motor drive systems account for approximately 50% of global electricity consumption. As a critical component supporting modern society, they are utilized in every field, from household appliances to industrial machinery, medical equipment, and precision instruments. They come in a wide range of sizes, from micro-motors<\/a> measuring just a few millimeters to large industrial motors spanning several meters and can handle power outputs ranging from a few milliwatts to several megawatts. In product development, selecting the right motor<\/a> for the application determines the overall performance of the equipment.<\/p>\n <\/p>\n
Basic Structure of Electric Motors<\/span><\/h3>\nElectric motors are primarily composed of two main components. (The roles of some motor parts differ from those described below.)<\/p>\n
\n\n\n\nComponent Name<\/strong><\/td>\nRole and Characteristics<\/strong><\/td>\n<\/tr>\n\nStator\u00a0(Stator)<\/span><\/td>\n \u00a0The stationary part that does not rotate.<\/p>\nIt generates a magnetic field and consists of permanent magnets or coils (electromagnets).<\/td>\n<\/tr>\n
\nRotor\u00a0(Rotor)<\/td>\n \u00a0The part that rotates within the magnetic field.<\/p>\nIt is wound with coils, and a magnetic field is generated when an electric current is passed through them.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n
There is a small gap called the “air gap” between the stator and the rotor, and magnetic force is transmitted through this gap. Although the structure of the stator and rotor differs depending on the type of motor, the basic principle of generating rotational force through the interaction of magnetic fields remains the same.<\/p>\n
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The Principle of Rotation in Electric Motors<\/span><\/h3>\nAn electric motor rotates by utilizing the Lorentz force generated when an electric current flows through a conductor (coil) placed within a magnetic field. When the magnetic field and the electric current are perpendicular to each other, a force is generated in a direction perpendicular to both. The direction of this force is determined by Fleming\u2019s left-hand rule. This force is used to generate torque on the rotor, enabling continuous rotation.<\/p>\n
In the case of brushed motors, the commutator and brushes work together to switch the direction of the current at the appropriate timing, enabling the rotor to continue rotating in a single direction. The rotor\u2019s rotational speed can be controlled by adjusting the supplied voltage and current.<\/p>\n
Furthermore, the magnitude of the generated torque (rotational force) varies depending on the number of turns in the coils attached to the rotor and the strength of the magnets. By optimizing these factors, it is possible to design motors with performance tailored to specific applications.<\/p>\n
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History and Development of Electric Motors<\/h2>\n
![\"What](\"https:\/\/cik-ele.com\/wp-content\/uploads\/2026\/04\/747d7ee4fa2a6b7846e1e5a938f06da9-540x360.jpg\")
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The history of electric motors dates back to the early 19th century, and they have evolved through continuous technological innovation from the era of the Industrial Revolution to the present day. Motor technology, which was researched as a new power source to replace the steam engine, was put into practical use thanks to the efforts of many inventors and researchers.<\/p>\n
Continuous improvements have been made since then, leading to the high-performance motors of today. Understanding this historical progression clarifies the challenges that modern motor technology has addressed.<\/p>\n
Topics Covered in This Section<\/strong><\/p>\n\n- The Dawn of Electric Motors (1820s\u20131880s)<\/li>\n
- The Path to Practical Application (1880s\u2013Early 1900s)<\/li>\n
- Evolution into Modern Motor Technology<\/li>\n<\/ul>\n
Motor technology, which was researched as a new power source to replace the steam engine, was put into practical use through the efforts of many inventors and researchers and has evolved into today\u2019s high-performance motors.<\/p>\n
<\/p>\n
The Dawn of the Electric Motor (1820s\u20131880s)<\/span><\/h3>\nIn 1821, British scientist Michael Faraday discovered the basic principles of motors and generators. Faraday observed the phenomenon of a conductor carrying an electric current moving within a magnetic field, thereby demonstrating the principle of electromagnetic rotation.In 1831, he discovered the law of electromagnetic induction, which became the foundation for later motor development. This law explains the phenomenon whereby a changing magnetic field generates an electric current, and it is the fundamental principle applied to both generators and motors.<\/p>\n
In 1834, Thomas Davenport of the United States built a battery-powered direct current motor, taking the first step toward practical motors. Davenport succeeded in powering a printing press using a small electric motor, demonstrating the potential of electric power to the world.<\/p>\n
This period was a crucial era in which the relationship between electricity and magnetism was scientifically elucidated and the foundations of motor technology were established.<\/p>\n
<\/p>\n
The Road to Practical Application (1880s\u2013Early 1900s)<\/span><\/h3>\nIn 1888, Nikola Tesla invented the two-phase AC induction motor, ushering in the era of practical motors. Following the controversy between Tesla and Thomas Edison known as the \u201cWar of Currents,\u201d AC power transmission systems became the mainstream.<\/p>\n
Although Edison advocated for direct current (DC), the alternating current (AC) system offered a decisive advantage for long-distance power transmission because it allowed voltage to be freely adjusted using transformers. The AC system was well-suited for long-distance transmission, serving as a catalyst for the rapid expansion of industrial motor applications.<\/p>\n
At the 1893 Chicago World\u2019s Fair, the AC power transmission system was adopted, and its superiority was widely recognized. AC motors played a vital role as the power source for lighting and exhibition equipment within the venue, impressing visitors with the future of electrical technology.<\/p>\n
From this point onward, the use of motors in industrial sectors such as factories and transportation began in earnest, accelerating the transition to an electrified society.<\/p>\n
<\/p>\n
Evolution to Modern Motor Technology<\/span><\/h3>\nEntering the 20th century, motor technology became increasingly diverse and high-performance. Advances in materials science and electronics significantly drove improvements in motor performance. The main directions of technological innovation are as follows.<\/p>\n
\u00a0[Key Points in the Evolution of Modern Motor Technology]<\/strong><\/p>\n\n- \u00a0The emergence of powerful permanent magnets (such as neodymium magnets)<\/li>\n
- \u00a0Achievement of compact and high-efficiency designs<\/li>\n
- \u00a0Development of application-specific motors<\/li>\n
- \u00a0Integration with electronic control technology<\/li>\n<\/ul>\n
In particular, the advent of powerful permanent magnets, such as neodymium magnets, has made it possible to develop motors that are compact yet capable of high output. Neodymium magnets, invented and put into practical use in the 1980s, possess approximately 10 times the magnetic force (energy product) compared to conventional ferrite magnets, revolutionizing the miniaturization of motors.<\/p>\n
In recent years, specialized motors tailored to specific applications\u2014such as coreless motors and brushless motors\u2014have been successively put into practical use, expanding their scope of application in the fields of medical equipment and precision instruments. Combined with advances in semiconductor technology, it has also become possible to achieve more precise and efficient motor control.<\/p>\n
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Main Types and Characteristics of Electric Motors<\/h2>\n
![\"What](\"https:\/\/cik-ele.com\/wp-content\/uploads\/2026\/04\/066c22a8cc9c467cb9a423e45559b152-540x126.png\")
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Electric motors are classified into many types based on differences in drive mechanisms and structure. Broadly, they are divided into direct current (DC) motors and alternating current (AC) motors, and there are further subcategories based on various structural features, such as brushed and brushless, and iron-core and coreless (core-less) types.<\/p>\n
Contents of this section<\/strong><\/p>\n\n- Differences Between DC Motors and AC Motors<\/li>\n
- Brushed Motors and Brushless Motors<\/li>\n
- Features and Industrial Applications of Coreless Motors<\/li>\n<\/ul>\n
Each type of motor has its own unique characteristics, and selecting the optimal type based on the application and required performance is key to successful product development.<\/p>\n
<\/p>\n
Differences Between DC Motors and AC Motors<\/span><\/h3>\nElectric motors are broadly classified into DC motors (direct current motors) and AC motors (alternating current motors) based on the type of power source. Understanding the characteristics of both types enables the selection of the most suitable motor for product development.<\/p>\n
DC motors offer excellent controllability and are suitable for applications requiring precise speed control and positioning. Since rotational speed can be adjusted simply by changing the voltage, designing the control circuit is relatively straightforward.<\/p>\n
On the other hand, AC motors feature a simple structure and high durability, making them widely used in industrial machinery. Another advantage is that they can utilize commercial power directly, helping to reduce operating costs for large-scale equipment.<\/p>\n
\n\n\n\nItem<\/strong><\/td>\nDC motor<\/strong><\/td>\nAC motor<\/strong><\/b><\/td>\n<\/tr>\n\nPower supply<\/td>\n DC power supply<\/p>\n(Battery, DC power supply)<\/td>\n
AC power<\/p>\n(Mains power)<\/td>\n<\/tr>\n
\nControlability<\/td>\n Precise speed control is easy<\/td>\n Requires an inverter for control<\/td>\n<\/tr>\n \nStructure<\/td>\n Relatively complex<\/p>\n(commutator, brushes)<\/td>\n
Simple and robust<\/td>\n<\/tr>\n \nMain Applications<\/td>\n Precision equipment, medical devices, mobile devices<\/td>\n Industrial machinery, home appliances, pumps<\/td>\n<\/tr>\n \nMaintenance<\/td>\n Brush replacement required<\/p>\n(If equipped with brushes)<\/td>\n
Maintenance-free<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\nPlease select the optimal motor based on the application and power supply environment.<\/p>\n
<\/p>\n
Brushed Motors and Brushless Motors<\/span><\/h3>\nDC motors are classified as brushed or brushless based on their current commutation method.<\/p>\n
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<\/p>\nBy understanding how electric motors convert electricity into force, as well as their basic structure and operating mechanisms, you will be able to select the most appropriate motor for your product development.<\/p>\n
Topics Covered in This Section<\/strong><\/p>\n Understanding this foundational knowledge provides the basis for making optimal motor selection decisions in product development.<\/p>\n <\/p>\n An electric motor is a general term for a device that converts electrical energy into mechanical energy. Known as a “electric motor” in Japanese, it generates rotational motion by utilizing the interaction between a magnetic field and an electric current.<\/p>\n According to various studies, motor drive systems account for approximately 50% of global electricity consumption. As a critical component supporting modern society, they are utilized in every field, from household appliances to industrial machinery, medical equipment, and precision instruments. They come in a wide range of sizes, from micro-motors<\/a> measuring just a few millimeters to large industrial motors spanning several meters and can handle power outputs ranging from a few milliwatts to several megawatts. In product development, selecting the right motor<\/a> for the application determines the overall performance of the equipment.<\/p>\n <\/p>\n Electric motors are primarily composed of two main components. (The roles of some motor parts differ from those described below.)<\/p>\n It generates a magnetic field and consists of permanent magnets or coils (electromagnets).<\/td>\n<\/tr>\n It is wound with coils, and a magnetic field is generated when an electric current is passed through them.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n There is a small gap called the “air gap” between the stator and the rotor, and magnetic force is transmitted through this gap. Although the structure of the stator and rotor differs depending on the type of motor, the basic principle of generating rotational force through the interaction of magnetic fields remains the same.<\/p>\n <\/p>\n An electric motor rotates by utilizing the Lorentz force generated when an electric current flows through a conductor (coil) placed within a magnetic field. When the magnetic field and the electric current are perpendicular to each other, a force is generated in a direction perpendicular to both. The direction of this force is determined by Fleming\u2019s left-hand rule. This force is used to generate torque on the rotor, enabling continuous rotation.<\/p>\n In the case of brushed motors, the commutator and brushes work together to switch the direction of the current at the appropriate timing, enabling the rotor to continue rotating in a single direction. The rotor\u2019s rotational speed can be controlled by adjusting the supplied voltage and current.<\/p>\n Furthermore, the magnitude of the generated torque (rotational force) varies depending on the number of turns in the coils attached to the rotor and the strength of the magnets. By optimizing these factors, it is possible to design motors with performance tailored to specific applications.<\/p>\n <\/p>\n The history of electric motors dates back to the early 19th century, and they have evolved through continuous technological innovation from the era of the Industrial Revolution to the present day. Motor technology, which was researched as a new power source to replace the steam engine, was put into practical use thanks to the efforts of many inventors and researchers.<\/p>\n Continuous improvements have been made since then, leading to the high-performance motors of today. Understanding this historical progression clarifies the challenges that modern motor technology has addressed.<\/p>\n Topics Covered in This Section<\/strong><\/p>\n Motor technology, which was researched as a new power source to replace the steam engine, was put into practical use through the efforts of many inventors and researchers and has evolved into today\u2019s high-performance motors.<\/p>\n <\/p>\n In 1821, British scientist Michael Faraday discovered the basic principles of motors and generators. Faraday observed the phenomenon of a conductor carrying an electric current moving within a magnetic field, thereby demonstrating the principle of electromagnetic rotation.In 1831, he discovered the law of electromagnetic induction, which became the foundation for later motor development. This law explains the phenomenon whereby a changing magnetic field generates an electric current, and it is the fundamental principle applied to both generators and motors.<\/p>\n In 1834, Thomas Davenport of the United States built a battery-powered direct current motor, taking the first step toward practical motors. Davenport succeeded in powering a printing press using a small electric motor, demonstrating the potential of electric power to the world.<\/p>\n This period was a crucial era in which the relationship between electricity and magnetism was scientifically elucidated and the foundations of motor technology were established.<\/p>\n <\/p>\n In 1888, Nikola Tesla invented the two-phase AC induction motor, ushering in the era of practical motors. Following the controversy between Tesla and Thomas Edison known as the \u201cWar of Currents,\u201d AC power transmission systems became the mainstream.<\/p>\n Although Edison advocated for direct current (DC), the alternating current (AC) system offered a decisive advantage for long-distance power transmission because it allowed voltage to be freely adjusted using transformers. The AC system was well-suited for long-distance transmission, serving as a catalyst for the rapid expansion of industrial motor applications.<\/p>\n At the 1893 Chicago World\u2019s Fair, the AC power transmission system was adopted, and its superiority was widely recognized. AC motors played a vital role as the power source for lighting and exhibition equipment within the venue, impressing visitors with the future of electrical technology.<\/p>\n From this point onward, the use of motors in industrial sectors such as factories and transportation began in earnest, accelerating the transition to an electrified society.<\/p>\n <\/p>\n Entering the 20th century, motor technology became increasingly diverse and high-performance. Advances in materials science and electronics significantly drove improvements in motor performance. The main directions of technological innovation are as follows.<\/p>\n \u00a0[Key Points in the Evolution of Modern Motor Technology]<\/strong><\/p>\n In particular, the advent of powerful permanent magnets, such as neodymium magnets, has made it possible to develop motors that are compact yet capable of high output. Neodymium magnets, invented and put into practical use in the 1980s, possess approximately 10 times the magnetic force (energy product) compared to conventional ferrite magnets, revolutionizing the miniaturization of motors.<\/p>\n In recent years, specialized motors tailored to specific applications\u2014such as coreless motors and brushless motors\u2014have been successively put into practical use, expanding their scope of application in the fields of medical equipment and precision instruments. Combined with advances in semiconductor technology, it has also become possible to achieve more precise and efficient motor control.<\/p>\n <\/p>\n Electric motors are classified into many types based on differences in drive mechanisms and structure. Broadly, they are divided into direct current (DC) motors and alternating current (AC) motors, and there are further subcategories based on various structural features, such as brushed and brushless, and iron-core and coreless (core-less) types.<\/p>\n Contents of this section<\/strong><\/p>\n Each type of motor has its own unique characteristics, and selecting the optimal type based on the application and required performance is key to successful product development.<\/p>\n <\/p>\n Electric motors are broadly classified into DC motors (direct current motors) and AC motors (alternating current motors) based on the type of power source. Understanding the characteristics of both types enables the selection of the most suitable motor for product development.<\/p>\n DC motors offer excellent controllability and are suitable for applications requiring precise speed control and positioning. Since rotational speed can be adjusted simply by changing the voltage, designing the control circuit is relatively straightforward.<\/p>\n On the other hand, AC motors feature a simple structure and high durability, making them widely used in industrial machinery. Another advantage is that they can utilize commercial power directly, helping to reduce operating costs for large-scale equipment.<\/p>\n (Battery, DC power supply)<\/td>\n (Mains power)<\/td>\n<\/tr>\n (commutator, brushes)<\/td>\n (If equipped with brushes)<\/td>\n Please select the optimal motor based on the application and power supply environment.<\/p>\n <\/p>\n DC motors are classified as brushed or brushless based on their current commutation method.<\/p>\n\n
What Is an Electric Motor?<\/span><\/h3>\n
Basic Structure of Electric Motors<\/span><\/h3>\n
\n\n
\n Component Name<\/strong><\/td>\n Role and Characteristics<\/strong><\/td>\n<\/tr>\n \n Stator\u00a0(Stator)<\/span><\/td>\n \u00a0The stationary part that does not rotate.<\/p>\n \n Rotor\u00a0(Rotor)<\/td>\n \u00a0The part that rotates within the magnetic field.<\/p>\n The Principle of Rotation in Electric Motors<\/span><\/h3>\n
History and Development of Electric Motors<\/h2>\n
<\/p>\n\n
The Dawn of the Electric Motor (1820s\u20131880s)<\/span><\/h3>\n
The Road to Practical Application (1880s\u2013Early 1900s)<\/span><\/h3>\n
Evolution to Modern Motor Technology<\/span><\/h3>\n
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Main Types and Characteristics of Electric Motors<\/h2>\n
<\/p>\n\n
Differences Between DC Motors and AC Motors<\/span><\/h3>\n
\n\n
\n Item<\/strong><\/td>\n DC motor<\/strong><\/td>\n AC motor<\/strong><\/b><\/td>\n<\/tr>\n \n Power supply<\/td>\n DC power supply<\/p>\n AC power<\/p>\n \n Controlability<\/td>\n Precise speed control is easy<\/td>\n Requires an inverter for control<\/td>\n<\/tr>\n \n Structure<\/td>\n Relatively complex<\/p>\n Simple and robust<\/td>\n<\/tr>\n \n Main Applications<\/td>\n Precision equipment, medical devices, mobile devices<\/td>\n Industrial machinery, home appliances, pumps<\/td>\n<\/tr>\n \n Maintenance<\/td>\n Brush replacement required<\/p>\n Maintenance-free<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n Brushed Motors and Brushless Motors<\/span><\/h3>\n
![\"What](\"https:\/\/cik-ele.com\/wp-content\/uploads\/2026\/04\/c7887a92414f854a9067849a51b9bb02-540x360.jpg\")
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