EP-4741232-A1 - AUTOMATION COMPONENT

Abstract

The invention relates to an automation component (1) comprising a printed circuit board (PCB) with electrical components (B1,... ,B4) for fulfilling automation tasks, a first supply voltage connection (IN_24V) and A second supply voltage connection (S_GND) is designed for connecting a supply voltage (24V), wherein a reverse polarity protection circuit (VSS) is arranged between the first supply voltage connection (IN_24V) and a feed point (S_1P24V) of the supply voltage (24V) for the components (B1,... ,B4), wherein a bridging circuit (US) is integrated into the reverse polarity protection circuit (VSS), and is designed to maintain the energy flow for the electrical components (B1,...,B4) in the event of a voltage drop (SE) of the supply voltage (24V).

Inventors

• Naumovic, Albert
• Pusch, Julian

Assignees

• Siemens Aktiengesellschaft

Dates

Publication Date

20260513

Application Date

20241112

Claims (7)

1. Automation component (1), comprising a printed circuit board (PCB) with electrical components (B1,...,B4) for fulfilling automation tasks, a first supply voltage connection (IN_24V) and a second supply voltage connection (S_GND) designed for connecting a supply voltage (24V), wherein a reverse polarity protection circuit (VSS) is arranged between the first supply voltage connection (IN_24V) and a feed point (S_1P24V) of the supply voltage (24V) for the components (B1,...,B4), characterized in that a bridging circuit (US) is integrated into the reverse polarity protection circuit (VSS) and is designed to maintain the energy flow for the electrical components (B1,...,B4) in the event of a voltage drop (SE) of the supply voltage (24V).
2. Automation component (1) according to claim 1, wherein the reverse polarity protection circuit (VSS) comprises a P-channel MOSFET.
3. Automation component (1) according to one of claims 1 or 2, wherein the bridging circuit (US) comprises a PNP transistor (V2301).
4. Automation component (1) according to one of claims 1 to 3, wherein in the bridging circuit (US) the base of the PNP transistor (V2301) is protected by a high-resistance resistor (R2319) with 390 kOhm.
5. Automation component (1) according to one of claims 1 to 4, wherein the reverse polarity protection circuit (VSS) is implemented with a Zener diode (V2309) and a diode (V2310).
6. Automation component (1) according to one of claims 1 to 5, wherein the bridging circuit (US) maintains an energy flow into a buffer capacitor (C2412) with 330µF for 1ms via a support capacitor (C2300) with 1µF.
7. Automation component (1) according to one of claims 1 to 6, designed as a field device of automation technology and furthermore designed for short-term bridging of voltage dips in accordance with the requirement of IEC 61131-2.

Description

The invention relates to an automation component comprising a printed circuit board with electrical components for fulfilling automation tasks, a first supply voltage connection and a second supply voltage connection, configured for connecting a supply voltage, wherein a reverse polarity protection circuit is arranged between the first supply voltage connection and a supply voltage feed point for the components. In current circuits considered state-of-the-art as reverse polarity protection, this protection consists of a PMOS and a Zener diode. While this technology offers protection against reverse polarity, it does not meet the new requirements of IEC 61131-2, which stipulates that power supplies must withstand voltage dips of 1 ms and continue to function without any adverse effects. The existing solution has the disadvantage that it lacks mechanisms to bridge such voltage dips. Therefore, the current reverse polarity protection circuit is inadequate, especially in field devices used in automation technology, because it offers no protection against short voltage dips. One objective of the invention is to provide an automation component that can withstand voltage dips. For the automation component mentioned at the beginning, the task is solved by integrating a bridging circuit into the reverse polarity protection circuit, and designed to maintain the energy flow for the electrical components in the event of a voltage drop in the supply voltage. One design variant provides that the reverse polarity protection circuit incorporates a P-channel MOSFET. The SIL04P06Y component, for example, is a P-channel MOSFET. It is a power transistor suitable for use in a reverse polarity protection circuit for DC voltage. The MOSFET allows the current flow in a circuit to be controlled depending on the applied voltage. In conjunction with other components, the P-channel MOSFET can They can be used to implement a protective circuit that prevents damage from a DC voltage if the polarity is reversed. It is advantageous if the bridging circuit has a PNP transistor, whereby in the bridging circuit the base of the PNP transistor is protected by a high-resistance resistor. According to the invention, a mains bridging solution is integrated into the reverse polarity protection circuit by adding a PNP transistor. In the event of a mains failure, the PNP transistor becomes conductive, and the energy flow to the assembly is maintained via a buffer capacitor and a decoupling capacitor for the duration of the outage. A high-value resistor protects the base of the PNP transistor, and a BAS16 diode ensures reverse polarity protection. These features prevent uncontrolled device shutdowns and significantly increase the efficiency and reliability of the power supply systems. The mains bridging provided by the PNP transistor, in combination with the specific capacitor values, not only offers protection against voltage dips but also ensures that the devices meet the new requirements. This innovative combination results in a significant improvement in the reliability and efficiency of the power supply systems and fulfills the new standards requirements, representing a clear advancement over existing solutions. The drawing shows an embodiment of the invention, wherein it shows FIG 1 an automation component with a printed circuit board and the FIG 2 a reverse polarity protection circuit with an integrated bypass circuit. According to FIG 1 An automation component 1 comprising a printed circuit board (PCB) with electrical components B1,...,B4 for fulfilling automation tasks, particularly in industrial process automation, is shown. The automation component 1 has a first supply voltage connection IN_24V and a second supply voltage connection S_GND. The supply voltage connections IN_24V and S_GND are designed for connecting a 24V supply voltage and a ground potential. A reverse polarity protection circuit VSS is arranged between the first supply voltage connection IN_24V and a feed point S_1P24V, which provides the 24V supply voltage for components B1,...,B4. To prevent voltage dips SE in the 24V supply voltage from having a negative impact on the automation component 1, a bridging circuit US is integrated into the reverse polarity protection circuit VSS. According to FIG 2 A detailed representation of the reverse polarity protection circuit VSS is shown. The bypass circuit US is integrated within the VSS. The VSS reverse polarity protection circuit features a P-channel MOSFET in the supply voltage branch between the first supply voltage terminal IN_24V and the feed point S_1P24V. A mains bypass solution is integrated into the VSS by adding a PNP transistor V2301. In the event of a 24V supply voltage failure, the PNP transistor V2301 becomes conductive and can thus maintain energy flow for automation component 1, or its components B1,...,B4, via a decoupling capacitor C2300 in conjunction with a buffer capacitor C2412 for a period of 1 ms. A Zener