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| Brand Name: | ZXY |
| Model Number: | ZXY-4R7 |
| MOQ: | Negotiable |
| Price: | Negotiable |
| Packaging Details: | Carton |
| Payment Terms: | T/T |
The 4R7 Print SMT Inductor, with an inductance value of 4.7 microhenries (denoted as 4R7), is a specialized surface - mount technology (SMT) component. It features a unique print - based manufacturing process, which might involve printing conductive materials directly onto a substrate to form the inductor's coils. This innovative approach can potentially offer cost - effective production and precise control over the inductor's geometry. Its SMT form factor allows for easy integration into compact printed circuit boards (PCBs), making it highly suitable for space - constrained applications such as mobile devices, IoT sensors, and miniaturized electronics. This inductor is designed to handle specific electrical currents and frequencies, playing a crucial role in power management circuits, where it helps in filtering out unwanted electrical noise and regulating current flow, ensuring stable and efficient operation of the overall electronic system.
The 4R7 Print SMT Inductor offers significant advantages in terms of manufacturing process, dimensional fit and circuit functionality to support the performance enhancement of electronic devices.
1. Unique Manufacturing Process Advantage: Adopting the innovative printing manufacturing process, the conductive material is printed directly on the substrate to form the inductor coil. This process greatly reduces production costs compared to traditional winding methods, eliminating the need for complex winding equipment and manual operation, reducing time and labor costs. At the same time, the inductor geometry can be accurately controlled, and the precise printing technology ensures that the dimensions, number of turns and other parameters of the inductor coils are highly accurate, making the inductance value more stable and improving the consistency of inductor performance to meet the needs of high-precision circuit design.
2. Compact space advantage: As a SMT component, it is compact in size and can be easily integrated into printed circuit boards (PCBs) with limited space. In today's pursuit of miniaturized electronic devices, such as thin and light smartphones, tiny IoT sensors, and all kinds of micro-electronic products, their compact form factor can make full use of board space to achieve a denser circuit layout, which helps to miniaturize products without taking up too much valuable internal space.
3. Superior circuit function advantage: designed to handle specific currents and frequencies, playing a key role in power management circuits. It can efficiently filter out unnecessary electrical noise in the circuit, just like installing a “purifier” to the circuit, avoiding the impact of noise interference on the circuit and ensuring pure signal transmission. At the same time, precise regulation of current flow, stabilize the circuit current output, to protect the entire electronic system stable, efficient operation, enhance the performance and reliability of electronic equipment .
| Performance Feature | Description |
| Inductance Value | 4.7 microhenries (4R7). This value is well - defined and crucial for applications such as energy storage and filtering in power - related circuits, ensuring accurate electrical performance in these functions. |
| Manufacturing Process | Utilizes a print - based manufacturing method. Conductive materials are printed directly onto the substrate to form the inductor coils. This process enables cost - effective production as it reduces the need for complex winding procedures. It also allows for precise control over the inductor's geometry, resulting in high - consistency inductance values. |
| Package Type | SMT (Surface - Mount Technology) package. The chip - type design is compact, allowing for easy integration onto printed circuit boards (PCBs). This is highly suitable for space - constrained applications, including mobile devices, IoT sensors, and miniaturized electronics, facilitating miniaturized circuit designs. |
| Current - carrying Capacity | Engineered to handle specific electrical currents. It can meet the current requirements of various circuits, ensuring stable operation under different load conditions, which is essential for power - related applications. |
| Frequency Response | Designed to operate within specific frequency ranges. It can effectively filter out unwanted electrical noise at relevant frequencies, playing a key role in maintaining the purity of electrical signals in the circuit. |
| Thermal Performance | Although not emphasized as prominently as some other features, the inductor is likely to have reasonable thermal performance. The printed construction may have an impact on heat dissipation, and it is expected to be able to withstand normal operating temperatures without significant performance degradation. |
| Mechanical Strength | While not as robust as some alloy - molded inductors in terms of mechanical strength, the printed structure still has a certain level of durability. It can generally withstand the normal handling and soldering processes during PCB assembly. |
| Tolerance Level | Likely has a defined tolerance level for inductance. This tolerance ensures that the inductance value remains within an acceptable range, providing reliable performance across different circuit applications. |
| DC Resistance | Has a relatively low DC resistance, which helps in minimizing power dissipation when current flows through it. This improves the overall efficiency of the circuits it is incorporated into, reducing unnecessary energy consumption. |
|
| Brand Name: | ZXY |
| Model Number: | ZXY-4R7 |
| MOQ: | Negotiable |
| Price: | Negotiable |
| Packaging Details: | Carton |
| Payment Terms: | T/T |
The 4R7 Print SMT Inductor, with an inductance value of 4.7 microhenries (denoted as 4R7), is a specialized surface - mount technology (SMT) component. It features a unique print - based manufacturing process, which might involve printing conductive materials directly onto a substrate to form the inductor's coils. This innovative approach can potentially offer cost - effective production and precise control over the inductor's geometry. Its SMT form factor allows for easy integration into compact printed circuit boards (PCBs), making it highly suitable for space - constrained applications such as mobile devices, IoT sensors, and miniaturized electronics. This inductor is designed to handle specific electrical currents and frequencies, playing a crucial role in power management circuits, where it helps in filtering out unwanted electrical noise and regulating current flow, ensuring stable and efficient operation of the overall electronic system.
The 4R7 Print SMT Inductor offers significant advantages in terms of manufacturing process, dimensional fit and circuit functionality to support the performance enhancement of electronic devices.
1. Unique Manufacturing Process Advantage: Adopting the innovative printing manufacturing process, the conductive material is printed directly on the substrate to form the inductor coil. This process greatly reduces production costs compared to traditional winding methods, eliminating the need for complex winding equipment and manual operation, reducing time and labor costs. At the same time, the inductor geometry can be accurately controlled, and the precise printing technology ensures that the dimensions, number of turns and other parameters of the inductor coils are highly accurate, making the inductance value more stable and improving the consistency of inductor performance to meet the needs of high-precision circuit design.
2. Compact space advantage: As a SMT component, it is compact in size and can be easily integrated into printed circuit boards (PCBs) with limited space. In today's pursuit of miniaturized electronic devices, such as thin and light smartphones, tiny IoT sensors, and all kinds of micro-electronic products, their compact form factor can make full use of board space to achieve a denser circuit layout, which helps to miniaturize products without taking up too much valuable internal space.
3. Superior circuit function advantage: designed to handle specific currents and frequencies, playing a key role in power management circuits. It can efficiently filter out unnecessary electrical noise in the circuit, just like installing a “purifier” to the circuit, avoiding the impact of noise interference on the circuit and ensuring pure signal transmission. At the same time, precise regulation of current flow, stabilize the circuit current output, to protect the entire electronic system stable, efficient operation, enhance the performance and reliability of electronic equipment .
| Performance Feature | Description |
| Inductance Value | 4.7 microhenries (4R7). This value is well - defined and crucial for applications such as energy storage and filtering in power - related circuits, ensuring accurate electrical performance in these functions. |
| Manufacturing Process | Utilizes a print - based manufacturing method. Conductive materials are printed directly onto the substrate to form the inductor coils. This process enables cost - effective production as it reduces the need for complex winding procedures. It also allows for precise control over the inductor's geometry, resulting in high - consistency inductance values. |
| Package Type | SMT (Surface - Mount Technology) package. The chip - type design is compact, allowing for easy integration onto printed circuit boards (PCBs). This is highly suitable for space - constrained applications, including mobile devices, IoT sensors, and miniaturized electronics, facilitating miniaturized circuit designs. |
| Current - carrying Capacity | Engineered to handle specific electrical currents. It can meet the current requirements of various circuits, ensuring stable operation under different load conditions, which is essential for power - related applications. |
| Frequency Response | Designed to operate within specific frequency ranges. It can effectively filter out unwanted electrical noise at relevant frequencies, playing a key role in maintaining the purity of electrical signals in the circuit. |
| Thermal Performance | Although not emphasized as prominently as some other features, the inductor is likely to have reasonable thermal performance. The printed construction may have an impact on heat dissipation, and it is expected to be able to withstand normal operating temperatures without significant performance degradation. |
| Mechanical Strength | While not as robust as some alloy - molded inductors in terms of mechanical strength, the printed structure still has a certain level of durability. It can generally withstand the normal handling and soldering processes during PCB assembly. |
| Tolerance Level | Likely has a defined tolerance level for inductance. This tolerance ensures that the inductance value remains within an acceptable range, providing reliable performance across different circuit applications. |
| DC Resistance | Has a relatively low DC resistance, which helps in minimizing power dissipation when current flows through it. This improves the overall efficiency of the circuits it is incorporated into, reducing unnecessary energy consumption. |
