NL1028237C2 - System for detecting saturation of a gas filter comprises measuring the concentration of a gas component with and without post-filtration - Google Patents

Abstract

System for detecting saturation of a filter for removing a component (C1) from a gas stream comprises a distributor for splitting a gas stream from the filter into substreams, a post-filter for removing C1 from a substream, and detectors for detecting a difference in the concentration of C1 in the post-filtered substream and an unfiltered substream. An independent claim is also included for detecting saturation of a filter using a system as above by collecting a gas stream from the filter, splitting the gas stream into substreams, filtering a substream with a post-filter, detecting the concentration of C1 in an unfiltered substream and in the post-filtered substream, and detecting a concentration difference.

Description

System and method for detecting saturation of a filter

The invention relates to a system for detecting saturation of a filter. The invention also relates to an assembly of such a system and at least one filter. The invention further relates to a method for detecting saturation of a filter by means of such a system.

In countless situations it is desirable to be able to detect whether an essential gas filter is saturated or not, in order to be able to replace this gas filter in time. After saturation of the gas filter, dysfunction of the gas filter usually occurs, whereby the gas filter no longer functions properly. The malfunction of a filter as a result of saturation can lead to (serious) adverse consequences. For example, vehicles, buildings and gas masks can be equipped with one or more protection filters in order to prevent a chemical and / or biological attack.

can resist. The protection filter allows air extracted from the outside atmosphere to be purified from harmful components before it is introduced into the relevant vehicle, building or gas mask. However, if the protection filter is saturated, the extracted air will not be purified from harmful components, as a result of which these harmful components will end up in the vehicle, building or gas mask, which can entail serious health risks. In order to eliminate these risks, early detection of saturation of a protection filter is of particular importance. The direct coupling of an analytical device, such as, for example, a gas chromatograph, to the protection filter generally does not constitute an adequate solution for the early detection of saturation of the filter, since this device is not calibrated under current (changing) physical and chemical conditions of the airflow. time of saturation of the filter, which is disadvantageous for the measurement sensitivity, as a result of which saturation of the filter can only be observed with (undesired) delay.

The invention has for its object to provide an improved detection system for the rapid detection of saturation of a filter.

2

To this end, the invention provides a system of the type mentioned in the preamble, comprising: dividing means for dividing a gas stream originating from the filter into a plurality of partial streams, at least one after-filter for substantially removing at least one component forming part of the gas stream at least one sub-stream, wherein the after-filter and the filter are adapted to remove the same component from the gas stream, and detection means connecting to the sub-streams for detecting a concentration difference of the component between a sub-stream guided through the after-filter and an unfiltered sub-stream. By taking the partial flow filtered through the post-filter as a relative reference (zero point) in the eventual detection of a concentration of the component in the other partial flow, traces of the component can be detected instantaneously, at least relatively quickly with high sensitivity, in the captured gas flow, which indicates saturation of the filter. This relative reference can only be considered as a reference during the then present current conditions and physical properties of the partial flows. In the event of a change of circumstances, for example during a pressure change, the relative reference will be adjusted accordingly. The sub-filtered sub-stream serving as a relative reference has the same physical composition in particular with regard to pressure, temperature, and optionally moisture content as the physical composition of the unfiltered (non-post-filtered) sub-stream serving, so that the real-time and truthful presence of a minimal amount of the component actually to be removed by the filter can be observed. The observable concentration of the component depends on the nature of the component. In the case of inorganic substances, such as H 2 S and NH 3, concentrations from approximately 100 ppb can generally be observed relatively quickly and easily by means of the system according to the invention; in the case of organic substances, in particular hydrocarbons, concentrations can be observed from 100 ppb to 1 ppm, depending on the nature of the organic substance. With systems known from the prior art, it is generally not possible, or at least hardly possible, to detect concentrations of less than 5 ppm irrespective of the nature of the component to be detected. The post-filter is adapted to the filter, the post-filter being adapted to remove the same component or group of components, from a gas stream as the component or group of components that can be removed by the actual filter. Already at relatively low flow rates of the gas flow from about 1 ml / minute saturation of the filter can already be observed, whereby - for comparison - a flow rate of about 10 to 100 ml / minute is applied when measuring according to conventional methods. It will be clear that not the entire gas stream exiting the filter should be used for detection of a possible saturation of the filter. Typically, only a fraction of the emerging gas stream will be captured and analyzed by the system according to the invention. Since the dimensioning of the filters is generally standardized, and is therefore not very flexible, the gas flow will usually be captured on a regular discharge side of the filter. However, if possible, the gas flow should preferably be captured earlier in the filter in order to be able to determine saturation of a part of the filter even earlier. With the system according to the invention, saturation of a filter can thus be determined relatively easily, early and reliably, because use is made of representative, permanently updated reference data.

15

The captured gas stream can be divided into a plurality of partial streams. However, in order to keep the system relatively simple from a structural point of view, the distribution means are preferably adapted to divide the gas flow into two partial flows. One of the sub-streams is then passed through the post-filter, in order to be able to collect the required reference data, while the other sub-stream is directly fed to the detection means, in order to be able to detect a possible presence of a component to be filtered. However, it is also conceivable to use more than two sub-streams, wherein at least one after-filter is provided in each sub-stream with the exception of at least one sub-stream. In this way, different components or groups of components can be removed from the sub-streams by different after-filters in different sub-streams, in order to subsequently be able to be detected via the unfiltered sub-stream. A first partial stream can for instance be provided with a post-filter for removal of organic substances, in order to be able to generate a reference for organic substances; a second partial stream can be provided with a post-filter for removal of inorganic substances, in order to be able to generate a reference for inorganic substances; a third partial flow is thereby not provided with any after-filter and will be led directly to the detection means. In addition to such a configuration of the system according to the invention, it is also conceivable that a single post-filter is arranged for removal of several specific components, which generally makes the use of several different post-filters unnecessary.

The after-filter is de facto arranged for (substantially) complete removal of a specific component, multiple components and / or group of related components. In order to be able to realize complete removal, the post-filter is preferably formed by an absorption filter, more preferably a carbon filter. However, for certain applications and when filtering floating microparticles (aerosol) from the partial flow, it is also conceivable to use other types of filters, such as, for example, a "High Efficiency Particulate Air" filter (HEPA filter).

The detection means can be very diverse in nature depending on the component to be detected. However, the detection means preferably comprise at least one sensor. The sensor is in this case particularly adapted for detecting a component or group of components to be removed by the filter and post-filter with relatively high sensitivity. In order to allow the situational conditions to vary as little as possible in order to optimize the sensitivity of the system, whereby instantaneous detection of saturation of the filter can be realized, the partial flows are preferably alternately passed along the same sensor or set of sensors. To that end, the system preferably comprises switching means for successively guiding the partial flows to the detection means. The switching means may be provided with a control valve, which may or may not be manually adjustable. However, the switching means are preferably electronically operable, wherein the switching means can be switched each time after a certain period of time, preferably after 10 to 15 seconds, in order to be able to pass a different partial current through the detection means. In another particularly preferred embodiment the detection means comprise a plurality of sensors, the sensors being positioned such that each partial flow is provided with at least one separate sensor. In that case, several partial flows can be simultaneously passed along (separate) sensors or sets of sensors 30, which generally makes the use of switching means superfluous. Moreover, the sensors can then be adapted to the nature of the component (s) to be detected, in order to be able to optimize the analytical capacity of the system according to the invention. The sensor is preferably adapted to detect the concentration of the component at a temperature λ n o o o o -7.

5 higher than 100 ° Celsius. At elevated temperature, a difference in thermal and / or electrical conductivity in the sensor can usually be better observed. At the same time, atoms can be excitedly excited at an elevated temperature, after which a fall in the stable state will generate electromagnetic radiation with a specific observable wavelength. Every sensor is at. preferably formed by one of the following sensors: an optical cell (optical sensor), and a metal oxide semiconductor (MOS). The optical cell is generally provided with a coating sensitive to the component to be detected. If this coating comes into contact with the component, the amount of light, such as for example infrared or ultraviolet light, will influence the sensor, which is perceptible. The metal oxide semiconductor will in particular exhibit semiconductor properties at elevated temperature, the conductivity of the metal oxide depending on the activity of the oxidation reaction (combustion) of the component to be detected in the sensor, the activity depending on the one hand on the temperature in the sensor and on the other hand, depends on the concentration of the component to be detected in the partial stream. Generally, the amount of oxygen required for the oxidation reaction will be present in excess. However, it is conceivable to supply an additional, predefined amount of oxygen to the partial flow before it is passed through the sensor, in order to be able to effect complete combustion of the component to be detected. The detection means are arranged in an alternative preferred embodiment for detecting the concentration of the component on the basis of at least one of the following known techniques: photoionization detection (PID), flame ionization detection (FID), flame focal detection (FPD), electron capture detection, thermal conductivity detection (TCD), thermionic detection (TID), and gas chromatography.

Since the aforementioned detection techniques are known to a person skilled in the art, these techniques will not be explained separately.

In order to be able to make a comparison of the data collected during detection, the system preferably comprises a processing unit for comparing the detected concentrations of the component in the various sub-streams. The processing unit, often also referred to as a processor, is more preferably also arranged for controlling various components of the system, such as, for example, control valves that can be controlled electronically or not. In that case the system can be provided with a processing unit designed as a control unit and can function fully autonomously, whereby a comparison between the measured concentrations in the different partial flows can be carried out independently. The processing unit will generally be linked to a database in which data collected in the past for pattern recognition of the detection means are stored. During detection of the partial flows, the observed detection patterns can be compared with previously stored patterns, whereby the observed detection patterns can be compared relatively reliably, which leads to relatively early determination of any saturation of the filter.

In order to be able to give a warning during detection of saturation of the filter, the system is preferably provided with signal generating means for generating an auditory and / or visual signal. However, it is also conceivable that the system comprises transmitting means for communicating collected data to remotely positioned receiving means. In this way it is possible to observe remotely in case a situation of saturation of the filter occurs, which is particularly advantageous to be able to alert emergency services as soon as possible after the saturation of the filter has been established, after which the saturated filter can be replaced and / or other types of measures can be taken.

20

The invention also relates to an assembly of such a system according to the invention and at least one filter. The system is herein preferably connected substantially behind the filter from the flow direction of the gas flow. The filter can be very diverse in nature, but is preferably formed by one of the following filters: a protection filter, and an industrially applicable filter. In addition to using the system as a warning system for achieving protection filter saturation in, for example, vehicles, buildings or gas masks, it is also conceivable that the system is used as a monitoring system in industrial processes in which filters are required. For example, when air from compressed air is used in an industrial process, the compressed air usually has to be first purified by means of a filter (from oil residues, for example) before the air can be used in certain process flows. Also in such situations it is of great importance to be able to detect saturation of the filter as soon as possible in order to prevent contamination in the process stream.

The invention furthermore relates to a method of the type mentioned in the preamble, comprising the steps of: a) capturing at least a part of a gas stream emerging from the filter, b) dividing the captured gas stream into a plurality of partial streams, c ) filtering at least one substream through a post-filter, d) detecting the concentration of at least one specific component in the substream not passed through the post-filter, e) detecting the concentration of the component 10 in the post-filter guided partial flow, and f) detecting a concentration difference observed during steps d) and e). Observing a concentration difference during step f) indicates saturation of the (main) filter, after which the (main) filter must be replaced and / or cleaned. Preferably, step d) and step e) are performed simultaneously. In that case, however, use will have to be made of separate sensors. In case use is made of a collective sensor or set of sensors, step d) and step e) are preferably carried out successively. The successive detection of the concentration of the component in the various subflows can be achieved by using switch means that may or may not be operated electronically, such as for example a control valve.

20

In a preferred embodiment, the concentration of the component in the partial streams is detected in accordance with step d) and step e) at a temperature above 100 ° Celsius. Typically, at elevated temperature, the concentration of the component can be observed relatively quickly, accurately and reliably. In a particularly preferred embodiment, the concentration of the component in the partial streams is detected in accordance with step d) and step e) at rising temperatures of substantially 100 ° Celsius to substantially 600 ° Celsius, preferably from substantially 150 ° Celsius to substantially 550 ° Celsius. This temperature increases within a certain period of time, for example 10 seconds. Since the detection of the nature of the component is generally temperature-dependent, it is advantageous to measure over a certain temperature range in order to be able to make the analytical image of the components present in the partial flow as complete as possible.

1028237 8

The invention will be elucidated on the basis of non-limitative exemplary embodiments shown in the following figures. Herein: figure 1 shows a schematic representation of an assembly of a system according to the invention and a filter, and figure 2 shows a schematic representation of an alternative assembly of a system according to the invention and a filter.

Figure 1 shows a schematic representation of an assembly 1 of a system 2 according to the invention and a main filter 3. The main filter 3 can for instance be formed by a protection filter and / or industrial filter. The system 2 is arranged for detecting saturation of the main filter 3 and thereby malfunctioning of the main filter 3. Generally, a gas stream 4 will be passed through the main filter 3. A gas fraction 5 is captured from the gas stream 4 emerging from the main filter 3 by conventional means (not shown). The gas fraction 5 is led to a distribution unit 6, in which the gas fraction 5 is divided into two sub-streams 7, 8. One sub-stream 7 is passed through a post-filter 9, where, due to possible saturation of the main filter 3, not through the main filter 3 component or group of components removed is still removed in order to realize a reference partial flow 7.

Both the partial current 7 led through the post-filter 9 and the partial current 8 not led through the post-filter 9 are led to an electronic switch 10. Successively, both partial streams 7, 8 are furthermore led to a detection unit 11 in order to achieve a critical concentration difference of the aforementioned. component or group of components between the two sub-streams 7, 8. In this exemplary embodiment, the detection unit 1.1 comprises four metal oxide sensors 12, along which the partial currents 7, 8 are guided alternately. During analysis of each partial flow 7, 8 by the sensors 12, the sensors are heated from approximately 150 ° Celsius to approximately 550 ° Celsius, in order to be able to reliably observe as many components as possible. Since the situational conditions, in particular with respect to physical parameters, such as pressure and temperature, of both the reference partial stream 7 and the sample partial stream 8 are identical, relatively low concentrations of less than 1 ppm with relatively large sensitivity can be measured relatively quickly and reliably. The detection unit 11 further comprises a processing unit 13, a database 14, and a power supply 15, in order to be able to fully establish the saturation of the main filter 3 autonomously. In the event of a finding of saturation of the main filter 3, a signal can be sent via a transmitter 15 to, for example, a maintenance service, whereafter the main filter 3 can be cleaned and / or replaced.

5

Figure 2 shows a schematic representation of an alternative assembly 17 of a system 18 according to the invention and a filter 19. From a gas stream 20 guided by the filter 19, a gas fraction 21 is captured from a location approximately halfway through the filter 19 and fed to a distribution station 22. In the distribution station 22, the gas fraction is divided into three subflows 23, 24, 25 of substantially the same size. The first sub-stream 23 is led to a post-filter 26 for organic components, while the third sub-stream 25 is routed to a post-filter 27 for inorganic components. The second sub-stream 24 is not filtered in the system 18. All sub-streams 23, 24, 25 are further directed to a detection station 28, where the sub-streams component (group) can be specifically analyzed by directing the sub-streams 23, 24, 25 by separate sensors 29.30.31.

The detected data can then be compared in a separate processing unit 32, on the basis of which any saturation of the filter 19 can be determined.

20

It will be clear that the invention is not limited to the exemplary embodiments shown and described here, but that within the scope of the appended claims, countless variants are possible which will be obvious to those skilled in the art.

25 1028237

Claims (22)

1. O O O o - » CLAIMS 1. A system for detecting saturation of a filter, comprising: - dividing means for dividing a gas stream originating from the filter into several partial streams, - at least one after filter for substantially removing at least one of the gas stream forming part of the gas stream component from at least one sub-stream, wherein the after-filter and the filter are adapted to remove the same component from the gas stream, and 10. detection means connecting to the sub-streams for detecting a concentration difference of the component between a sub-stream guided through the after-filter and a unfiltered partial flow. 2. System as claimed in claim 1, characterized in that the distribution means are adapted to divide the gas flow into two partial flows. 3. System as claimed in claim 1 or 2, characterized in that each partial flow, with the exception of at least one partial flow, is provided with at least one after-filter. A system according to any one of the preceding claims, characterized in that the post-filter is adapted to remove a plurality of specific components. A system according to any one of the preceding claims, characterized in that the post-filter is formed by an absorption filter. 25 A system according to any one of the preceding claims, characterized in that the detection means comprise at least one sensor. 7. System as claimed in claim 6, characterized in that the detection means 30 comprise a plurality of sensors, the sensors being positioned such that each partial flow is provided with at least one separate sensor. 1. o q o o -7 A system according to claim 6 or 7, characterized in that the sensor is adapted to detect the concentration of the component at a temperature higher than 100 ° Celsius. A system according to any one of claims 6 to 8, characterized in that each sensor is formed by one of the following sensors: an optical cell, and a metal oxide semiconductor (MOS). 10. System as claimed in any of the foregoing claims 6-9, characterized in that the detection means are arranged for detecting the concentration of the component on the basis of at least one of the following techniques: photoionization detection (PID), flame ionization detection (FID), flame focal detection (FPD), electron capture detection, thermal conductivity detection (TCD), thermionic detection (TID), and gas chromatography. 15 11. System as claimed in any of the foregoing claims, characterized in that the system comprises a processing unit for comparing the detected concentrations of the component in the different partial flows. 12. System as claimed in any of the foregoing claims, characterized in that the system comprises transmitting means for communicating collected data to remotely positioned receiving means. 13. System as claimed in any of the foregoing claims, characterized in that the system comprises switching means for successively guiding the partial flows to the detection means. 14. System as claimed in claim 13, characterized in that the switching means can be operated electronically. 30 An assembly of system according to any one of the preceding claims and at least one filter. An assembly according to claim 15, characterized in that the system is connected substantially behind the filter, viewed from the direction of flow of the gas flow. 17. An assembly according to claim 15 or 16, characterized in that the filter is formed by one of the following filters: protection filter, and industrially applicable filter. 18. A method for detecting saturation of a filter by means of a system according to any one of claims 1-14, comprising the steps of: a) capturing at least a part of a gas stream exiting the filter, b) dividing the captured gas stream in a plurality of subflows, c) filtering at least one subflow through a post-filter, d) detecting the concentration of at least one specific component in the subflow not guided through the post-filter, e) detecting the concentration of the component in the partial stream passed through the post-filter, and f) detecting a concentration difference observed during steps d) and e). Method according to claim 18, characterized in that step d) and step e) are carried out simultaneously. A method according to claim 18, characterized in that step d) and step e) are carried out successively. 25 A method according to any one of claims 18-20, characterized in that the detection of the concentration of the component in the partial streams according to step d) and step e) takes place at a temperature above 100 ° Celsius. Method according to claim 21, characterized in that the detection of the concentration of the component in the partial streams according to step d) and step e) takes place at increasing temperatures of substantially 100 ° Celsius to substantially 600 ° Celsius, preferably from substantially 150 ° Celsius to substantially 550 ° Celsius.