1. Field of the Invention
This invention relates to a volumetric control system for blower filter devices that is particularly suited for a breathing hood connection.
2. Background Art
State-of-the-art blower filter devices are characterized by the disadvantage that the flow of air supplied to the hood varies depending on how clogged the filter is. When the filter is new and clean, more air passes through the filter as is required in accordance with applicable standards in a given individual case. Similar problems occur when different filters are to be used.
The resulting disadvantages are increased power consumption and increased air throughput. Another problem arising with the gradual clogging of the filter is that it is not known when the flow of air supplied to the hood falls below the required quantity. Another problem is that the type of breathing connection that is used for the breathing hood influences the volumetric air flow.
Various types of volumetric controls have been designed to remedy this problem. EP 0 35 29 38 A2 proposes to measure the differential pressure between a measuring point in front of, and a measuring point behind, the impeller wheel of the fan and to use this signal for controlling the blower speed.
EP 0 62 10 56 A1 proposes to measure the dynamic pressure at the outlet of the blower filter device. The dynamic pressure is produced by the flow resistance of the hood and can also be used as a measure of volumetric air flow. In addition, this design features another sensor of the thermistor type in a side duct that monitors preset volumetric air flow limits and triggers an alarm signal when the air flow drops below these limits.
Fl 80606 describes a design in which the fan motor is used as a detector so that the electrical control circuit measures the power drawn by the fan motor and the effective voltage at its poles. The design uses the properties of the rotary blower, as the air volume that flows through the blower per time unit is proportional to the rotor torque, and the pressure difference is proportional to the rotational speed. This solution is improved by DE 195 02 360 A1 in that the fan output is controlled based on current and rotational speed.
Despite this comprehensive development effort, no one as yet has succeeded in keeping the volumetric air flow constant regardless of the filters and hoods that are used. Dynamic pressure measurement behind the fan or negative pressure measurement behind the fan can only be used to measure volumetric flow if the flow resistance values of the hood or filters are known. This means for practical purposes that the flow resistance values of filters and hoods have to be kept constant at narrow tolerances during production in order for these methods to work.
It is one aim of this invention to keep the volumetric flow constant within tolerance ranges regardless of the filters and hoods used. This is accomplished through the characterizing features of claim 1 while advantageous embodiments are the subject of the dependent claims herein.
According to the invention, a control unit controls the volumetric flow of blower filter devices by determining a differential pressure between measuring points and converting it into a control signal while at least two measuring points are arranged in the air flow behind the fan impeller wheel and in front of the consumer, in particular, the breathing hood. A number of tests have proven that the pressure difference in this measuring arrangement depends on volumetric air flow but is largely independent of the flow resistance of the filter(s) and the breathing connection at the breathing hood.
The volumetric control for blower filter devices, as seen in
With this measuring point arrangement, the pressure difference depends on the volumetric air flow but is largely independent of the flow resistance of the filter(s) 13 and the breathing connection at 14 between the breathing hose 9 and the breathing hood 15. In this way, the volumetric air flow can be kept constant within tolerance ranges regardless of the filter(s) 13 and breathing connection at 14 for breathing hoods 15 used.
In a preferred embodiment, the measuring points 1,2 are positioned in the air flow within the blower filter device 4 behind/downstream the impeller wheel 5 and in front/upstream of the outlet 8 of the blower filter device 4. The pressure sensors 10,10′ and control equipment with power supply can thus be integrated in an optimum way into a compact unit with the blower filter device 4.
Alternatively, as shown in
The control unit 11 compares the pressure difference with preset limiting values. If the pressure difference is outside preset limiting values, the control unit 11 tries to set the volumetric air flow to the desired level (such as 125 l/min to 140 l/min) by adjusting the impeller wheel output. If this cannot be done, the signaling device 12 is activated that alerts the user. This can be arranged by linking a measuring system with the fan 6 in such a way that the signaling device 12 is activated whenever the fan output exceeds or falls below limits, or by linking the signaling device 12 with the control unit 11 in such a way that the signaling device 12 is activated when the differential pressure exceeds or falls below a predetermined/preset differential pressure.
Number | Date | Country | Kind |
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100 21 581 | Apr 2000 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE01/01456 | 4/6/2001 | WO | 00 | 5/27/2003 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO01/80952 | 11/1/2001 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5322058 | Pasternack | Jun 1994 | A |
5950621 | Klockseth et al. | Sep 1999 | A |
Number | Date | Country |
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0 352 938 | Jan 1990 | EP |
2 680 467 | Feb 1993 | FR |
Number | Date | Country | |
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20030180149 A1 | Sep 2003 | US |