Active ionization device for discharging electrostatic charges, comprising a device for optically indicating an operating state
The active ionization device with an integrated optical indication system addresses the challenge of monitoring high-voltage electrode status, offering a cost-effective and safe visual confirmation of operation, thereby improving safety and reliability.
Patent Information
- Authority / Receiving Office
- EP · EP
- Patent Type
- Applications
- Current Assignee / Owner
- ILLINOIS TOOL WORKS INC
- Filing Date
- 2025-09-18
- Publication Date
- 2026-06-17
AI Technical Summary
Existing high-voltage electrodes for neutralizing surface charges face challenges in monitoring their operating state, particularly in potentially explosive atmospheres and environments where personal contact cannot be guaranteed, and passive discharge electrodes lack effective functional monitoring and current-limiting components, leading to safety risks.
An active ionization device with an integrated optical indication system that converts high voltage into an operating voltage to display the electrode's status using a series circuit of an ohmic resistor and a light source, such as an LED, without requiring a control system, allowing direct visual indication of the electrode's operating state.
Provides a simple and cost-effective means for operators to visually confirm the electrode's functioning under various conditions, enhancing safety and operational reliability by eliminating the need for separate control systems and ensuring visible status indicators directly on the electrode.
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Abstract
Description
[0001] The present invention lies generally in the field of high-voltage electrode arrangements, which are used as discharge electrodes in a wide variety of applications. Specifically, the invention relates in particular to a device for monitoring the operational reliability of at least one active ionization device for neutralizing surface charges, especially charges on railway materials.
[0002] High-voltage electrodes for neutralizing surface charges are known in a wide variety of designs and configurations. In particular, such high-voltage electrodes are used as active ionization devices for dissipating electrostatic charges.
[0003] A high-voltage electrode arrangement of the type considered herein is known, for example, from German patent application DE 3 425 142 A1, where it is referred to as a high-voltage electrode comprising at least two individual electrodes. The high-voltage electrode arrangement known from this prior art is spatially separated from a voltage supply and current measuring device and connected via electrical conductors.
[0004] The processing of a wide variety of materials, including (but not limited to) web-based materials such as paper or plastic webs, requires web areas that are largely free of static electricity, particularly static charges resting on the surface of the web materials. In many cases, such charge-free conditions are generally desirable to prevent, for example, unwanted adhesion between layers of the material, whether stacked or intended to be stacked.
[0005] In other applications, it can be advantageous to first create a charge-free web surface in order to then selectively apply a very specific amount of charge. This approach is particularly useful when a controlled attenuation force of the different web layers is desired, determined by the amount of surface charge, or when the web surfaces of, for example, a paper web need to be prepared for an electrostatically assisted printing process.
[0006] However, the field of application of the present invention is not limited to the electrostatic discharge of materials in web form, but also relates to so-called "one-piece flow" applications, in which in particular individual parts or assemblies, such as printed circuit boards, plastic parts, glasses, etc., are to be electrostatically discharged.
[0007] It is known to use active discharge electrodes for such discharge processes. These electrodes are based on the principle of targeted ionization of the air molecules located between the active discharge electrode (positioned close to the surface) and the surface, sufficient to dissipate all surface charges within a given time. However, the high voltage required to apply to these electrodes for sufficient ionization is a disadvantage, particularly when such active discharge systems or electrodes are to be used in potentially explosive atmospheres. Under certain conditions, this can easily lead to an unwanted, ignitable spark.
[0008] Furthermore, the high voltages required by these active discharge electrodes are a disadvantage if effective protection against personal contact cannot be guaranteed in a given application. Nevertheless, such active discharge electrodes are predominantly used in modern technology because monitoring the ionization current they conduct is relatively straightforward. Such a current flowing through the intentionally created ionization path serves as an indicator that the active discharge electrode is functioning correctly. If no current flow is detected, the ionization path, which is essential for dissipating surface charges, is not formed, thus indicating that the active discharge electrode is not functioning correctly.
[0009] To circumvent the aforementioned disadvantages of active discharge systems or active discharge electrodes, it is also known to use so-called passive discharge electrodes, which are not based on the operating principle of an actively and artificially created ionization zone. Such passive discharge electrodes are mostly cord- or wire-like structures, for example, cords with carbon fibers, grounding tongues, brushes, or so-called "tinsle bars." These passive discharge electrodes are arranged at a short distance from the surface of the material web or material to be discharged and are connected to a reference or ground potential.Due to their mostly pointed shape, the electric field lines emanating from the surface charges concentrate at the ends of the individual elements extending towards the surface to be discharged, so that the resulting high electric field strength ensures that these surface charges flow away across the small gap between the electrode elements and the surface even if this gap is not additionally ionized by actively applying an ionization voltage.
[0010] However, such passive discharge electrodes have the disadvantage that simple functional monitoring, i.e., monitoring to ensure that the electrode can dissipate charges, is not guaranteed.
[0011] Furthermore, such passive discharge elements lack current-limiting components, which means that under certain conditions, an ignitable spark can occur between the surface to be discharged and a single protruding fiber. This can even happen within such a passive discharge electrode (discharge cord, grounding tongue, brush, "tinsle bars," etc.), since surface charges on a path are rarely homogeneous, but rather exhibit a multitude of charge regions with varying charge levels and polarities.
[0012] Because of these disadvantages, active discharge systems or active discharge electrodes for neutralizing surface charges are preferred in many applications instead of passive discharge electrodes.
[0013] For a specific design of such a high-voltage electrode arrangement, reference is made to publication EP 0 384 022 B1. In such an arrangement, the high-voltage electrode is connected to a high-voltage power supply via a high-voltage cable (a high-voltage supply line).
[0014] With such an arrangement, the operator cannot see at the electrode itself whether high voltage is present or not. Therefore, high-voltage power supplies are generally equipped with indicator lights that inform the operator about the operating status of the high-voltage electrode. Such information is important not only for safety reasons, but also for ensuring smooth workflows.
[0015] However, the function indicator of the high-voltage power supply is often not visible from the location of the high-voltage electrode.
[0016] It is also possible that the power supply indicates high voltage is switched on, but this voltage is not present at the electrode due to a break in the high-voltage cable. In applications with multiple high-voltage electrodes operating on multiple high-voltage power supplies, it can be difficult to determine the operating status of a specific electrode.
[0017] For these reasons, the operator and owner of such a system has an interest in an operating and function indicator directly at the electrode.
[0018] The technical problems of an operating indicator at the electrode are, firstly, the high operating voltage of the electrode, amounting to several kV, and secondly, the lack of a counter-potential when electrodes are operated unipolar and the operating current flows from the electrode via a corona discharge.
[0019] Therefore, to this day no operating indicator for high-voltage electrodes is available that meets practical requirements.
[0020] The invention is therefore based on the objective of providing a high-voltage electrode arrangement serving as an active ionization device, which includes a simple and cost-effective operating state detection system, which in turn enables the realization of an easily perceptible display of the operating state for the operating personnel under practically all operating conditions.
[0021] This problem is solved in particular by the subject matter of independent claim 1, wherein advantageous further developments of the active ionization device are specified in the dependent claims.
[0022] Accordingly, the invention relates in particular to an active ionization device for dissipating electrostatic charges, which can be connected to at least one high-voltage source and is designed as at least one electrode, in particular free-standing in space, and especially in the form of a single electrode. In particular, the at least one electrode can have a free end pointing in a principal direction.
[0023] According to the invention, it is particularly provided in this context that the active ionization device has a device for optically indicating an operating state of the active ionization device and in particular of the at least one electrode of the active ionization device.
[0024] The device for optically indicating the operating state of the active ionization device is designed to optically indicate the operating state of the active ionization device, and in particular the operating state of the at least one electrode, to which at least one high voltage may be applied, without control and in particular without any control associated with the device for optically indicating the operating state of the active ionization device.
[0025] The advantages achievable with the solution according to the invention are obvious: Firstly, the active ionization device itself has a corresponding function indicator, preferably directly on the at least one electrode. This provides the operator with an easily perceptible indication of the operating status in a simple yet effective manner.
[0026] In order to manufacture the active ionization device as simply and cost-effectively as possible despite the operating state monitoring, the invention provides in particular that the device for optically indicating the operating state is designed without a corresponding control system. In other words, the device for optically indicating the operating state of the active ionization device is preferably directly galvanically connected to the at least one electrode of the active ionization device and is operated via the high voltage applied to the at least one electrode.
[0027] In particular, it is thus provided according to the invention that the active ionization device does not have a control device associated with the device for optically indicating the operating state of the active ionization device for controlling the device for optically indicating the operating state of the active ionization device.
[0028] According to preferred implementations of the active ionization device, it is provided that the active ionization device has a converter device associated with the device for optically indicating the operating state of the active ionization device, which is configured to convert a high voltage provided by the high voltage source of the at least one electrode, in particular one standing freely in space, into an operating voltage necessary for operating the device for optically indicating the operating state of the active ionization device.
[0029] According to one possible realization of the last-mentioned embodiment of the active ionization device according to the invention, the inverter device comprises a series circuit consisting of at least one ohmic resistor and at least one light source, in particular in the form of an LED.
[0030] The device for optically indicating the operating status of the active ionization device preferably comprises at least one light-emitting diode (LED). Of course, it is also conceivable that another light source is provided.
[0031] In possible embodiments of the active ionization device, the optical indication device could be configured to output a different optical signal depending on the magnitude of the high voltage applied to the at least one electrode via the high-voltage source. For example, depending on the magnitude of the high voltage applied to the at least one electrode via the high-voltage source, a light source, in particular a light-emitting diode (LED), could simulate light of a different color for the optical indication device.
Claims
1. Active ionization device for dissipating electrostatic charges, which can be connected to at least one high-voltage source and is designed as at least one electrode, in particular free-standing in space, especially in the form of a single electrode, characterized by the fact thatThe active ionization device includes a device for optically indicating an operating state of the active ionization device and, in particular, of the at least one electrode of the active ionization device, wherein the device for optically indicating the operating state of the active ionization device is designed to optically indicate the operating state of the active ionization device and, in particular, of the at least one electrode, to the at least one electrode, without control and, in particular, without any control associated with the device for optically indicating the operating state of the active ionization device.
2. Active ionization device according to claim 1, wherein the active ionization device does not have a control device associated with the device for optically indicating the operating state of the active ionization device for controlling the device for optically indicating the operating state of the active ionization device.
3. Active ionization device according to claim 1 or 2, wherein the active ionization device comprises a converter device associated with the device for optically indicating the operating state of the active ionization device, which is configured to convert a high voltage provided by the high voltage source of the at least one electrode, in particular one standing freely in space, into an operating voltage necessary for operating the device for optically indicating the operating state of the active ionization device.
4. Active ionization device according to claim 3, wherein the inverter device comprises a series circuit of at least one ohmic resistor and at least one light source, preferably in the form of an LED.
5. Active ionization device according to one of claims 1 to 4, wherein the device for optically indicating the operating state of the active ionization device is designed to output a different optical signal, and in particular an optical signal different with respect to a flashing frequency, with respect to a wavelength or color and / or with respect to an intensity, depending on the amount of a high voltage connected to the at least one electrode by means of the high voltage source.