Current smoke detector technology is based on one of two general approaches. Photoelectric-based detectors are based on sensing light intensity that is scattered from smoke particles. Light from a source (LED) is scattered and sensed by a photosensor. When the sensor detects a certain level of light intensity, an alarm is triggered. Ionization-type smoke detectors are based on a radioactive material that ionizes some of the molecules in the surrounding gas environment. The current of the ions is measured. If smoke is present, then smoke particles neutralize the ions and the ion current is decreased, triggering an alarm.
Referring to
The ionization chamber 103 is basically two metal plates 104 a small distance apart. One of the plates 104 carries a positive charge, the other a negative charge. Between the two plates 104, air molecules received through the screen 105, made lip mostly of oxygen and nitrogen atoms, are ionized when electrons are kicked out of some molecules and picked up by other molecules as a result of collisions with alpha particles 102 from the radioactive material 101. The result is oxygen and nitrogen molecules that are both positively and negatively charged, such as NO+, O2−, OH−, HCO3+, and many other similar ions.
There are problems with the radioactive material that is currently used as an ionizer.
1. The radioactive material is a small amount and does not pose a health hazard to the homeowner as long as the material is not tampered with. It is possible that someone could tamper with the americium-based smoke detector and inadvertently inhale or ingest the americium. This can be a serious health hazard.
2. Although the amount of americium in each smoke detector is small (about 1 microCurie), the accumulated amount of material can add up. The typical user disposes of the smoke detector by throwing it in the household trash. It is possible that this material can then find its way into recycled material that could then find its way back into a home in a form that is not so innocuous as the original smoke detector.
Embodiments of the present invention replace the radioactive element of the standard ionization-type smoke detector with a field emission or field ionization ion source that is non-radioactive and uses no radioactive materials. The field emission ion source will operate at atmospheric pressures and will operate over a wide temperature range. What is described in detail below are embodiments that use carbon nanotubes as the field ionizer material, but there are many other materials that could be used for this application:
1. Functionalized or coated carbon nanotubes may be used to improve durability and lifetime and also reduce operating voltage. One example of this would be alkali-metal coated or alkali-salt coated carbon nanotubes.
2. Nanotubes or nanowires of other materials, such as Si, ZnO, GaAs, etc. These nanowires may also be functionalized or coated.
3. Metal or semiconducting microtips may be used, such as W or Mo (metals) or Si or Ge (semiconductors). It may be possible that a Spindt microtip configuration may be used with an emitter structure and a gate electrode.
An electric field on the order of several megavolts/cm (˜several 100 V/μm) is sufficient to produce electron emission from materials. One way to achieve these fields practically is to use conducting or semiconducting structures, or materials that have very high aspect ratios (they are tall and thin), and place them in an electric field. Because the high aspect ratios will concentrate the electric fields at the ends or tips of the structure, electron field emission can be achieved with applied electric fields as low as 1-10 V/μm since the electric field at the tips of these high aspect features can be as high as 100-1000 V/μm.
Initially, metal or Si microtip structures were designed and built to be used for field emission applications. See, C. A. Spindt and L. N. Heynick, U.S. Pat. No. 3,665,241, May 23, 1972. The first field ionization experiments were performed by Müller. See, E. W. Müller, Phys. Rev. Vol. 102, p. 618 (1956). There are two cases or methods to use field emitter structures as gas ionization sources:
Case 1) Electrically bias the structures negatively such that electrons are pulled from the field emitters into the gas environment (producing ions by electron-impact or electron capture); or
Case 2) Electrically bias the structures positively (the reverse of above) such that electrons are pulled from the gas molecules into the tips of the structures, thus producing positive ions.
In both cases, it is well documented (See, Robert Gomer, Field Emission and Field Ionization, pub. by the Am. Inst. of Physics, 1993, pp. 1-31 and 64-102) that the phenomenon that controls the behavior is quantum mechanical tunneling of electrons from the conduction band of the metal into the vacuum or gas environment as a result of high local electric fields (Case 1), or the reverse, electrons tunneling from the gas molecules into the metal (Case 2) from similar applied electric fields but polarized in the opposite direction.
There are issues that are considered for implementing embodiments of the present invention:
Gas adsorption and changing work function of the tip emitters: Since these emitters will operate in air, gas can form physical and chemical bonds to the surface, changing work function and aspect ratio and degrading emission properties. Carbon nanotubes are relatively inert compared to most metals (i.e., an oxide layer is not formed on the surface). They are flexible yet strong, (Young's Mod. of SWNT=1 TPa, max tensile strength=30 GPa. See, M.-F. Yu et al., Phys. Rev. Lett. 84, 5552 (2000)) and have high thermal conductivity. See, Savas Berber et al., “Unusually High Thermal Conductivity of Carbon Nanotubes”, PRL, V84, p. 4613, (2000). Based on these properties, the carbon nanotube is a good choice, as it is expected to be the most stable.
Ion erosion of the emitter: Water or oxygen ions may attach to the carbon nanotube material, converting it to CO or CO2. This may limit the life of the carbon emitters. It is found that this is true in high vacuum conditions. See, L. H. Thuesen, R. L. Fink, et al., J. Vac. Sci. Technol. B 18(2), p. 968, March/April 2000. For embodiments herein, the electrons are emitted into air at atmospheric pressure at low energy; thus, the electrons do not gain significant energy before impacting a molecule. Therefore, ions are created by electron capture (i.e., they are negative ions) and are repelled from the CNT electrode. The only concern may be positive ions. Positive ions can be created if the electron energy striking the molecule is high. Embodiments herein may adjust both the gap between the electrodes and the bias of the electrodes to change the electron impact energy and tune it for optimal performance. Furthermore, the impact of ions on the CNT emitters may be limited because ion energy will be imparted to other molecules as a result of high collision rates at atmospheric pressure.
There are examples of using carbon emitters as gas ionization sources in the literature. Dong et al. and Choi et al. used CNT emitters in ionization vacuum gauges. See, C. Dong et al., APL., 84, p. 5443, 2004, and In-Mook Choi, et al., APL., 87, p. 173104, 2005. They operated their devices in partial vacuum, different from the proposed approach, and with much higher electron impact energy than proposed herein. Riley et al. used multiwall carbon nanotubes to ionize He. See, D. J. Riley et al., “Helium Detection via Field Ionization from Carbon Nanotubes,” NanoLetters, 3, p. 1455 (2003). They were successful in ionizing He atoms at low pressures (4×10−5 mbar).
Peterson et al. measured the performance of both carbon nanotubes and polycrystalline diamond as a gas ionizer at atmospheric pressure and in the Case 1 mode, very similar to what is disclosed here. See, M. S. Peterson, W. Zhang, et al., Plasma Source Sc. and Technol., Vol. 14, pp. 654-660. (2005). First, using the highly graphitic polycrystalline diamond material, they were able to generate a current between 5 pA and 10 μA with voltages of 20 V and 340 V respectively, using a gap of 10 μm. They were able to maintain the current in one case over 40 hours in continuous DC mode. This demonstrates that oxygen ions did not significantly degrade the performance of the carbon-based electron source operating in air.
Referring to
The embodiments described herein detect smoke in the same way that the prior art detects smoke, but from monitoring the change in current through one or more of the grids or electrodes. For example, if electrons are emitted into the gas on a negative electrode, this would create negative ions that would be collected at the positive grid or electrode. However, if there is smoke present, then the negative ions may react with the smoke particles (typically carbon particles or hydrocarbon aerosols) and neutralize or mask the negative charge to create neutral particles; thus no current would arrive at the positive electrode. The current at each electrode may be monitored, and if a current decreases below a set value, an alarm may be triggered.
A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention.
This application for patent claims priority to U.S. Provisional Patent Applications Ser. Nos. 60/891,927, 60/941,858, and 60/844,761 which are hereby incorporated by reference herein.
Number | Date | Country | |
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60891927 | Feb 2007 | US | |
60941858 | Jun 2007 | US | |
60844761 | Sep 2006 | US |