D13003K Datasheet, Pinout, Power Ratings & Applications

Introduction to d13003k, d13003k pinout, d13003k features, d13003k applicationsHi Friends! I welcome you on board. Thank you for clicking this read. In this post today, I’ll document the Introduction to D13003K.The D13003K is an NPN silicon transistor mainly employed for switching and amplification purposes. It comes with a power dissipation of around 50W which demonstrates the amount of energy this device releases during the functioning of this device. As this is an NPN transistor as here electrons are the major charge carriers. The collector current is 1.8A which means it can support load under 1.8A. The emitter-base voltage is 9V which means it needs 9V to bias this device and start the transistor action.I suggest you read this post all the way through as I’ll walk you through the complete Introduction to D13003K covering pinout, datasheet, power ratings, working principle, applications, and physical dimensions.Let’s get started.

Introduction to D13003K

  • The D13003K is a power transistor made of silicon material and falls under the category of NPN transistors.
  • This device is composed of three layers where one is a p-doped layer that stands between the two n-doped layers.

  • This component comes with three terminals known as collector, emitter, and base. All these terminals are different in terms of doping concentrations.
  • The power dissipation of this device is 80W which is the amount of power released during the working of this device.

Introduction to d13003k, d13003k pinout, d13003k features, d13003k applications

  • The D13003K belongs to bipolar junction transistors where electrons are the major carriers. The bipolar junction transistors are divided into two main types NPN transistors and PNP transistors. In NPN transistors electrons are the major carriers while in the case of PNP transistors holes are the major carriers. They are called bipolar junction transistors because both electrons and holes are responsible for the conductivity inside the transistor.
  • These bipolar junction transistors are current-controlled devices because a small current at the base terminal is employed to control large output current at the remaining terminals.
  • The MOSFETs, on the other hand, are voltage-controlled devices that come with terminals named drain, source, and gate.
  • The mobility of electrons is better than the mobility of holes the reason NPN transistors are preferred over PNP transistors for a range of applications.

D13003K Datasheet

Before you embed this device into your electrical project, it is better to scan through the datasheet of D13003K. The datasheet features the main characteristics of the device. Click the link below to download the datasheet of D13003K:

Download D13003K Datasheet, Pinout, Power Ratings & Applications

D13003K Pinout

The following figure represents the pinout diagram of D13003K.Introduction to d13003k, d13003k pinout, d13003k features, d13003k applicationsThis NPN transistor contains three terminals known as:1: Base2: Collector3: EmitterAll these terminals come with different doping concentrations. The collector terminal is lightly doped while the doping concentration of the emitter terminal is high. The base side is 10-times more doped than the collector side.

D13003K Working Principle

  • The base pin plays a vital role to start the transistor action. When voltage is applied at the base pin, it will bias the device, and as a result, the current will start flowing from the collector to the emitter terminal.
  • As this is an NPN transistor here current flows from collector to emitter terminal and in the case of PNP transistor current flows from emitter to collector terminal.

Introduction to d13003k, d13003k pinout, d13003k features, d13003k applications

  • These bipolar junction devices are not symmetrical in nature. And the different doping concentration of all three terminals is responsible for the lack of symmetry of this device.

  • This means if we try to exchange emitter and collector terminals then the device will start working in reverse active mode, and stop working in forward active mode.

D13003K Power Ratings

The following table features the absolute maximum ratings of D13003K.

Absolute Maximum Ratings of D13003K
Pin No. Pin Description Pin Name
1 Collector-emitter voltage 400V
2 Collector-base voltage 700V
3 Base-emitter voltage 9V
4 Collector current 1.8A
5 Power dissipation 50W
6 Base current 0.9A
7 Operating and storage junctiontemperature range -55 to 150C
  • While embedding this chip into your project, make sure the ratings don’t exceed the absolute maximum ratings. Otherwise, it will put your entire project at stake.
  • The junction temperature and storage temperature ranges from -55 to 150C.
  • It is important to note that, don’t apply these ratings more than the required time, else they can affect device reliability.
  • The collector-emitter 400 and collector-base voltage is 700. And total power dissipation is 50W which demonstrates that this device will release 50W energy during the working of this device.

D13003K Applications

D13003K is used in the following applications.

  • Used in a common power amplifier.
  • Used in voltage regulator circuits.
  • Used in electronic Ballasts.
  • Used in Bistable and Astable multivibrators circuit.
  • Incorporated in modern electronic circuits.

  • Used in the high switching power supply.
  • Used in high-frequency power transform.
  • Employed to support loads under 1.8A.
  • Used in energy-saving lights.

D13003K Physical Dimensions

The image below represents the physical dimensions of D13003K.By reading those dimensions you can evaluate the space required for your component in the electrical project.That’s all for today. Hope you find this article helpful. If you have any questions, you can pop your comment in the section below. I’m willing to help you the best way I can. You’re most welcome to share your valuable feedback and suggestions around the content we share so we keep coming up with quality content customized to your exact needs and requirements. Thank you for reading the article.

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