This invention relates to gas scrubbers in general, and more particularly to a temperature-based method and system for estimating the scrubbing capacity of a gas scrubber, such as a CO2 scrubber used in a re-breathing apparatus.
Closed-circuit re-breathers (CCRs) are used by divers, miners, firefighters and a variety of other personnel who must work under environmental conditions where breathable air is either unavailable or in short supply. Generally speaking, a CCR includes a carbon dioxide (CO2) scrubber that removes the CO2 produced by the person wearing the CCR. The CO2 scrubber includes one or more substances that will “scrub”, i.e. react with, the CO2 in order to remove the CO2 so that gas exiting the scrubber can be inhaled again by the person wearing the CCR. Since the removal of the CO2 is critical, it is important for the user to know when the CO2 scrubber is losing its ability to scrub the exhaled CO2.
A variety of approaches have been used to determine the scrubbing capacity that remains in a CCR that is in use. For example, U.S. Pat. No. 4,154,586 (Jones) discloses a method in which the CO2 scrubbing material changes color when it is spent. However, in underwater diving and fire-fighting applications, the user may not be able to see such a color change. Another approach is described in U.S. Pat. No. 4,146,887 (Magnante) where a temperature difference between the ambient environment and one location inside the scrubber is measured, and the measured temperature difference is used to predict and provide an “end-of-life” indication. However, variations in ambient conditions, e.g. temperature, can cause the end-of-life indication to come too early (the scrubber could continue to remove CO2) or too late (the scrubber ceases to remove enough CO2 before the indicated end-of-life) in the life of the scrubber.
Still another approach is described in U.S. Pat. No. 4,440,162 (Sewell) where temperature is measured at a predetermined location in the scrubber. When the temperature exceeds a pre-set value, an alarm is triggered. However, prior to the alarm, this approach does not provide the user with any way of knowing what the remaining capacity or utilized capacity of the CO2 scrubber is. In addition, the temperatures in the reactive material will depend on the ambient temperature, thus resulting in alarms being provided when an alarm should not be given.
Since the endurance of a CO2 scrubber varies with ambient temperature, ambient pressure and with a user's breathing rates, it is desirable to provide a user with updated capacity-information that has been generated by taking account of such operating parameters. However, the above-described prior art approaches are either impractical for certain applications, or do not provide such ongoing information.
Two known approaches exist that might give such desired ongoing information. U.S. Pat. No. 6,618,687 (Warkander) describes the use of temperature changes inside the space occupied by the CO2 reactive material to give nearly continuous readings for remaining capacity; and EU patent EP 1316 331 B1 (Parker) describes a method that compares temperature readings to pre-determined temperature distribution characteristics. Both compare the temperature at predetermined locations to the warmest part of the reactive material. Such a comparison achieves reasonably good end-of-life predictions when the highest temperature remains steady. Unfortunately, the highest temperature does not remain steady. For example, in
Using the highest temperature to predict end-of-life may not be advisable for all types of scrubbers. For example, the method in Warkander and the method in Parker were developed with diving rebreathers, which tend to be less efficient than a rebreather for dry-land use. A low efficiency scrubber may last only half as long (i.e. 50%) as a high efficiency scrubber. In low efficiency scrubbers, CO2 will reach its level of exhaustion before the highest temperature starts to decline. For instance, had the recordings in
U.S. Pat. No. 7,987,849 (Heesch) describes a method for determining the consumption of a CO2 scrubber in a patient's respirator using measurements of the patient's breathing and comparing it to an estimate of the scrubber's maximum capacity of CO2 scrubbing. The maximum capacity of a CO2 scrubber may be known fairly well for a patient being breathed quietly in an operating room with a controlled ambient temperature. However, for a rebreather that is used where the conditions vary, the efficiency of a scrubber may vary from under 20% to over 80% of its maximum (theoretical) capacity (Nuckols et al., Life Support Systems Design; Simon and Schuster Custom Publishing, Needham Heights, M A 1996. ISBN 0-536-59616-6). Given this range of efficiencies, Heesch's method will not be accurate enough for many uses. For example, in underwater diving, the workload of the diver, ambient temperature range and ambient pressure range can vary significantly.
U.S. Patent Application 2014/0345610 (Unger) describes a method wherein a consumption indicator, consisting of a melting material, measures the total reaction heat, which is purported to be related to the consumption of reactive material. However, the temperature of the reactive material is, in practice, almost unaffected by the work rate (CO2 production) of the wearer. Therefore, such a consumption indicator will not work well in many situations.
U.S. Pat. No. 6,003,513 (Readey) describes a system that provides a general idea of the life of the reactive material based on where “localized heating” takes place. However, all of Readey's temperature sensors (shown as temperature strip 100 in Readey's FIG. 2) are placed in the flow of gas that is about to enter the reactive material. Readey's temperature sensors are not in contact with the canister or the reactive material. Therefore, they will read the temperature of the gas, but not the temperature of the reactive material. In addition, Readey's FIG. 8 shows that the temperature profile is assumed to have a local maximum that travels downstream as the reactive material is consumed. As is illustrated in the present
Since the endurance of a CO2 scrubber varies with ambient temperature, ambient pressure and with a user's breathing rates, and it is desirable to provide a user with updated capacity-information that has been generated by taking into account such operating parameters as to the remaining capacity or utilized capacity of the CO2 scrubber, which is something that the above-described prior art approaches do not do.
The invention may be embodied as a method. In one such method, the scrubbing capacity, which may be the capacity utilized or the capacity remaining, of a gas scrubber (e.g. a CO2 scrubber) is estimated. For example, a method according to the invention may include the following steps:
The invention may be embodied as a gas scrubber having a system for estimating the remaining scrubbing capacity or the utilized scrubbing capacity of a gas scrubber (e.g. a CO2 scrubber). For example, such a gas scrubber may include the following:
Embodiments of the invention are further described with reference to the following description and to the drawings, wherein corresponding reference characters indicate corresponding parts throughout the several views of the drawings and wherein:
Generally speaking the invention may be embodied as a method or a system for estimating the scrubbing capacity of a gas scrubber that scrubs a gas, such as carbon dioxide (“CO2”) via a Thermic reaction, from an exhaust gas. Exhaust gas may be made to flow through a canister 10 that contains a material that chemically binds or transforms the gas as that gas flows from an inlet 13 of the canister 10 toward an outlet 16 of the canister 10 along a flow path 19. The material inside the canister 10 causes a Thermic reaction to occur so that scrubbed gas that exits the canister 10 via the outlet 16 includes a lower concentration of the gas component that reacts with the reactive material.
A plurality of temperature sensors 22 may be distributed along the flow path 19. The temperature sensors 22 may include a first temperature sensor 22 (T1) positioned at the canister's inlet 13 and subsequent temperature sensors 22 (T2−T9) spaced along the flow path 19. At a plurality of times, temperatures at each temperature sensor 22 are measured and the temperature differences between adjacent pairs of sensors 22 are calculated. For each pair, the largest of those measured temperature differences is identified. The normalized temperature difference for each pair at a particular time is calculated as the temperature difference at that time for that pair divided by the largest difference for that pair. These normalized temperature differences may be combined to provide an estimate of the remaining scrubbing capacity or utilized scrubbing capacity of the reactive material. Such an estimate is referred to herein as a “life-value.” For example, a weighted average of the normalized temperature differences may be calculated and used to provide a life-value, which can then be used to determine the predicted remaining capacity or estimated utilized capacity of the gas scrubber. In some embodiments of the invention, weighting factors may be selected for particular pairs of temperature sensors based on experimentally-determined relationships between the normalized temperature differences and the remaining scrubbing capacity or utilized scrubbing capacity. In this manner, some of the temperature differences may be given more influence than others of the temperature differences. The remaining scrubbing capacity or utilized scrubbing capacity can be represented visually on a display 25 as a percentage of an initial scrubbing capacity or a final scrubbing capacity, and/or as the time remaining at the current rate of use.
Accordingly, embodiments of the present invention may be a method of estimating the remaining scrubbing capacity or the utilized scrubbing capacity of a gas scrubber. In addition, embodiments of the present invention may be a method or system of providing a visual display of the remaining scrubbing capacity or utilized scrubbing capacity of a gas scrubber that scrubs a gas during a Thermic reaction. Further, embodiments of the present invention may be a method of or system for estimating the remaining scrubbing capacity or utilized scrubbing capacity of a CO2 scrubber. Also, embodiments of the present invention may be a method of or system for estimating the remaining scrubbing capacity or utilized scrubbing capacity of a gas scrubber (e.g. a CO2 scrubber) in a way that is nearly independent of ambient conditions. The present invention may provide a method of determining and visually displaying the approximate remaining scrubbing capacity or utilized scrubbing capacity of a CO2 scrubber used in a re-breathing system.
In order to describe the invention and provide additional information by which to understand the invention, a particular embodiment of the invention is described below, which is a CO2 scrubber. However, it should be noted that the invention is not limited to a CO2 scrubber, or a scrubber in which an exothermic reaction takes place. For example, the invention may be embodied as a scrubber in which an endothermic reaction occurs. Referring now to the drawings, and more particularly to
During the effective life of the reactive material, Thermic reaction takes place within canister 10. It is to be understood that while the present invention will be described herein relative to a CO2 scrubber, the present invention can be used in conjunction with other types of scrubbers that produce an exothermic or endothermic reaction.
The canister 10 with reactive material inside is disposed in a flow of the exhaust gas such that the exhaust gas flows into an inlet 13 of the canister 10 and flows through along a flow path 19. Inside the canister 10, a reaction gas is produced by the exothermic reaction or endothermic as the case may be, and exits the canister 10 at an outlet 16 thereof.
A plurality of temperature sensors 22 may be distributed along the flow path 19. As an example, temperatures detected by the sensors 22 (T1-T9) are shown in
By calculating the temperature difference between two adjacent temperature sensors (e.g. T1 and T2, or T2 and T3, or T3 and T4 or T4 and T5) a measure of the chemical activity of the reactive material in the area between those two temperature sensors can be obtained.
While gas is flowing through the canister 10, the largest difference in temperature in each section (e.g. ΔT2,1 max) is determined frequently by the processor 28. The relative activity (r) of each section may be calculated by the processor 28. For example, a normalized temperature difference may be a good indicator of the relative activity within a section. Such a normalized temperature difference may be calculated by dividing the current temperature difference for each pair of temperature sensors 22 by its own maximum temperature difference (e.g. rT2,1=ΔT2,1/ΔT2,1 max). In this usage, the “maximum temperature difference” is the maximum since the reactive material was initially put into service. This nuance may be important because the useful life of the reactive material may occur over multiple use-sessions. That is to say that, use of the scrubber (and therefore, the reactive material) may be intermittent, and in that situation, the maximum temperature difference may have occurred during a prior use-session. Using the data of
A weighted average of these ratios may be calculated.
When data from tests at different ambient temperatures, wearer workloads, different reactive materials, and atmospheric pressures are plotted together, the weighting factors may be adjusted until a close prediction of the endurance time is obtained. Also, a desired safety margin can be determined, and the gauge adjusted to avoid excessive CO2 remaining in the gas that leaves the canister 10.
From
The temperature of the reactive material may be influenced by the ambient temperature. However, by calculating the temperature difference between two sensors the effect of ambient temperature is reduced. The temperature of the reactive material may also vary with the heat capacity of the gas (i.e. type of gas, such as air or O2) and barometric pressure in the canister 10. It may also depend on the CO2 partial pressure in the exhaust gas. By calculating the relative activity of a section in the canister 10, the influences of the heat capacity of the exhaust gas and the CO2 partial pressure are minimized since they are essentially constant. The combining the normalized temperature differences and/or weighted-normalized temperature difference, for example, by use of a weighted average, the relative activity in several sections in the canister 10 is combined. Such a system and/or method is suitable for use with high efficiency scrubbers.
The geometry and flow patterns of scrubbers may differ. Therefore, the exact placement of temperature sensors may depend on the particular scrubber being utilized. People skilled in the art will realize that the number of temperature sensors utilized can be different than that described herein, and that the choice of weighting factors may change the accuracy of the indication provided by the gauge.
Most CCRs have condensation forming inside them, and those used for diving may leak. The temperature sensors 22 can also be used to indicate the presence of such water in the reactive material, because there would be reduced or no chemical activity in wet parts of the reactive material. It is likely that the temperature in wet parts of the reactive material would be far lower than in the dry reactive material and the processor 28 may be programmed to recognize such a low temperature situation, and then indicate to the user that water is present.
Since temperature increases in a CO2 scrubber 90 may vary depending on ambient pressure, ambient temperature, the amount of CO2 in the exhaust gas and the wearer's breathing rate, it may be necessary to provide and use calibration curves/functions for specific applications and/or operating environments, and then cause the processor 28 to execute a particular program corresponding to those applications and/or environments cause accordingly. Further, it may be necessary to combine a number of calibration curves/functions to yield an average function which, in the average usage, will provide the user with a “safe” indication of remaining scrubbing capacity.
In describing the systems above that are in keeping with the invention, methods that are in keeping with the invention have also been described.
In one variation of such a method, one or more of the normalized temperature differences are weighted, for example by multiplying the normalized temperature difference by a predetermined number, and then for those that have been weighted, the weighted-normalized temperature difference is used in the step 221, rather than the corresponding normalized temperature difference. The resulting comparison value may be said to be “influenced” more by those normalized temperature differences having a predetermined number greater than one, and “influenced” less by those normalized temperature differences having a predetermined number less than one.
The advantages of the present invention are numerous. The method and system can be used to provide a more accurate and ongoing indication of the remaining scrubbing capacity or utilized scrubbing capacity of a gas scrubber that produces an exothermic reaction or endothermic reaction. Thus, the user is not forced to react prematurely to a last-minute, end-of-life alarm, but is instead given ample notice as to when the scrubber's end-of-life is expected. This is especially important when the present invention is applied to CO2 scrubbers used in re-breathing systems. Through the use of the methods described herein, the estimate of remaining scrubbing capacity or utilized scrubbing capacity is nearly independent of ambient conditions. Further, the present invention can be adapted to a variety of exothermic or endothermic reaction type gas scrubbers. Still further, a variety of operating environments, reactive materials and styles of packing the reactive material, can be accommodated merely by providing relevant calibration curves/functions.
Although the invention has been described relative to specific embodiments thereof, the invention is not limited to such embodiments. Hence, the present invention is deemed limited only by the appended claims and the reasonable interpretation thereof.
This application claims the benefit of priority to U.S. provisional patent application Ser. No. 62/320,415, filed on Apr. 8, 2016.
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/026729 | 4/8/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/177212 | 10/12/2017 | WO | A |
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Number | Date | Country |
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1316331 | Jul 2007 | EP |
Entry |
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Nuckles et al., Life Support Systems Design, pp. 105-110 1996. |
Number | Date | Country | |
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20190111287 A1 | Apr 2019 | US |
Number | Date | Country | |
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62320415 | Apr 2016 | US |