Air Ion Counter - Summary of Instructions
(For more detailed explanation - see the full instructions)
The 20-foot long ground cord should be used to connect the meter to earth ground for most types of measurements -- especially if you are measuring near an ionizer. Make sure the wind guard (black plastic cover) is in place over the top slot in the meter, for most types of measurement. Switch both the POLARITY and MEASURE switches to the center position (the center is between "+" and "-" on one, and "STANDBY" on the other). Switch the RANGE knob to "19.99". Wait 10 to 15 seconds until the display is stable +/- 2 counts (+/- 0.02). Press and hold down the right switch to "RE-ZERO" for a second or longer. Then release that switch. Repeat this until the display reads between -0.02 and + 0.02 for at least 10 seconds after release. The meter is now at a proper "ZERO" and is ready to take measurements for at least 10 minutes before you will require another RE-ZERO step. If you change the knob to another range like "199.9", you will need to RE-ZERO again.
To measure, point the top slot (the one that is usually covered by the "wind guard") toward the ion source. At any time, you can change the POLARITY switch to + or -, to measure + or - ions, respectively. The display will immediately jump to a high value when you switch POLARITY, but it will settle to near zero in 10 to 15 seconds. Then turn the right-side switch to MEASURE. This will turn on the fan, and the display will read the correct number of thousands of ions per cubic centimeter in the air. For example, if the POLARITY is set to "-", and the display reads "-0.86", this is 860 negative ions/cm3. If it reads -12.63, it means 12,630 negative ions/cm3 (=12.63 kilo-ions/cm3). When not measuring, leave the right switch on STANDBY to conserve battery power (STANDBY uses 1/8 the power of MEASURE). If when measuring near a strong source of ions, the display may go over-range; it will read a "1" at the far left with no other digits. Then switch the RANGE to a higher number, like 199.9 or 1999. You must do the RE-ZERO step again after a range switch. That is, set both toggle switches to center position, wait, and then set the right-side toggle to RE-ZERO and release. The less sensitive ranges 199.9 and 1999 will respond faster than the 19.99 range, which uses a slower filter.
Avoid measuring ions near charged plastic like synthetic fabric clothing. The excess charge will reduce both positive and negative ion counts in the region. Sometimes ions do not mix well in a room. There may be a cloud of negative ions in one area with almost no ions just a few inches away. Any fan (even a slow one) helps mix ions in a room. Without some mechanism for circulating the air, you may see the ion count go low, then high, then low, irregularly as a "cloud" of ions sloshes back and forth.
This meter reads exclusively the negative ions in the air when POLARITY is on "-", and positive on "+". Both ions can co-exist in the same volume of air, or there may be more of one than another.
If you see all three decimal points at the same time, the battery is low. Unscrew the back to replace it with a common 9 volt alkaline battery. Make sure that you put in the new battery so that the wire does not interfere with the motion of the fan.
The full instructions (which follow) are at page number:
General Instructions..........................................................................................................1
Problems........................................................................................................................4
About Air Ions..................................................................................................................5
How it Operates/How to Optimize Measurements....................................................................9
Specifications................................................................................................................12
Air Ion Counter - Instructions
This meter (Air Ion Counter) pulls air into the slot in the top. Then the air exits out the hole in the bottom. The top slot, which is shielded by a snap-in black "wind-guard", should be pointed toward the area of air that you want to measure. For reliable measurement, the meter's case should not have any static charge (static electricity) on it. (See "How the Air Ion Counter Operates..." at the end of these instructions for an explanation.) The case is conductive and will remain free of static charge if the meter is connected to earth ground through the long ground cord (supplied). The meter's feet are also conductive so if they are sitting on a grounded metal sheet, there will be no static charge, and measurement will be accurate. If you use the ground cord, the allegator clip side of the cord must be connected to earth ground. A metal water pipe or faucet will work as a ground. Usually, the metal screw in a wall switch plate or outlet plate is also grounded, so it can be unscrewed a little in order to connect the allegator clip to the screw head.
The only time that the ground cord does not need to be used is if the meter can remain "un-charged" (that is, it remains at ground potential) even without the cord. This can be done if the meter is not used near an ionizer and if the meter is touched at least once a minute by someone who is electrically connected to ground or who touches ground frequently. If you are walking on carpet while holding the meter, you should try to touch a grounded object more frequently at least once every 10 seconds, or you should use the ground cord.
A black wind-guard is snapped into the slot on the top face of the meter. This wind-guard should generally remain in that position unless both "+" and "-" ion readings are greater than "2.00" (thousand ions per cm3). An explanation for this is in "How the Air Ion Counter Operates..." When measuring ions indoors, remember that if the air is not moving, it is also not mixing well. This may lead to ion quantities that differ drastically from one area to another area in a room, even over a distance of a few cm. A more uniform ion density will result if the air in a room is moving, such as from a fan, so it will be well mixed.
To operate the meter, flip the POLARITY switch to its center position, half-way between "+" and "-", and the MEASURE switch should be on STANDBY, which is that switch's center position. Then turn the knob to whichever of the three ranges is required. Usually this is 19.99 (thousand ions/cm3), which is the most sensitive range. It reads up to 19,990 ions/cm3. Wait until the display becomes stable to within +/-2 counts. This will be about 10 seconds after the meter is turned on. Then flip the MEASURE switch down to RE-ZERO, and hold it there at least a second. It will return to STANDBY when you release it. Do this RE-ZERO step a few times until the display is stable at between 0.02 and -0.02 for at least 5 seconds. Then flip the POLARITY switch to whichever polarity ("+" or "-") you want to measure. Wait for the display to become stable, but if a breeze is blowing and the air contains a large number of ions, the display may not become very stable. In that case, wait at least 10 seconds after flipping the POLARITY switch. Then flip the MEASURE switch upward. This will turn on the fan, and you should hear the fan running.
You should keep the inlet slot (at the top) reasonably far (such as 2 feet or 60cm) from any solid object. To do this you can hold the meter at arm's length while measuring. Solid objects are often electrically charged and alter the number of ions present in their vicinity. You'll see that the number of ions/cm3 is usually higher in the center of a room away from any furniture that it is directly next to any furniture. This meter will take correct readings even near solid objects, however, the ion count is usually fairly low near solid objects. Do not move the meter while you are reading the number on the display (Hold it still each time you read it). This will keep the displayed number more stable.
If you switch POLARITY from "+" to "-" or "-" to "+", wait at least 10 seconds before the reading will be accurate. You do not need to RE-ZERO. Approximately every 10 to 30 minutes, the RE-ZERO function should be repeated. If you flip the POLARITY switch to its center position and the display does not read near zero after it becomes stable, it is time to RE-ZERO. This will be necessary if the temperature has changed significantly or if you change ranges (between 19.99, 199.9, and 1999). To RE-ZERO again, wait for the display to become stable with POLARITY in its center position. Then flip the MEASURE switch down to RE-ZERO and hold a few seconds. Any error in the "zero" reading is added to or subtracted from the reading. If while you are measuring, the number of ions in the air is quite large, the meter will read over-range. This is shown by a "1" in the extreme left of the display, and no other digits will be visible. If this happens, turn the RANGE knob clockwise to a higher number, and perform the RE-ZERO step again (set POLARITY at neutral, wait, flip MEASURE switch to RE-ZERO a few seconds).
The number of ions per cubic centimeter is whatever is shown on the display multiplied by 1000. For example, if the RANGE knob is set at 199.9 and the display reads "-125.7", it means 125,700 negative ions per cm3. The polarity shown on the display (blank if positive, "-" if negative) should be the same as what you set on the POLARITY switch. If the polarity on the display does not agree with what is on the switch, RE-ZERO the unit. Only in one special circumstance will these two polarities not agree. If, for example, the POLARITY switch is set to "+", and the air near an ionizer has 1 million negative ions per cm3 and zero positive ions, the display will actually read a small negative number, which is about 1/5000 of the number of the opposite polarity. In this example, the display will read negative 1 million x 1/5000 = negative 200 ions per cm3, even though the POLARITY switch is set at positive. (In an example like this, it will be obvious by measuring both "+" and "-", that the "-" is very high compared to "+".) One more feature of the meter should be noted: if the POLARITY switch is set to its center position, the meter will read 1/10 of the sum of the number of positive ions/cm3 minus the number of negative. If the number of positive ions equals the number of negative ions/cm3, the display will read zero. If there are 100,000 negative ions/cm3 so that the display will read -100.0 when POLARITY is "-", and only 10,000 positive ions/cm3 (display reads 10.0 when POLARITY is set to "+"), then the display will read (10.0 -100.0) x 1/10 = "-9.0" if the POLARITY switch is later set to the neutral position. This means that if all the positive ions in the air were neutralized by negative ions, there would still be an excess of negative ions(90,000/cm3), but the meter, when set to the neutral POLARITY position, will read 1/10 of this excess. Therefore, if you want to take a quick reading of the total excess number of ions/cm3 (whatever is left over if positive and negative neutralized each other to whatever extent possible), switch the POLARITY to neutral, flip the MEASURE switch upward, and multiply the number on the display by ten.
Battery drain is about 4 ma on STANDBY, and 35 ma on MEASURE (with the fan running). Battery life is about 60 hours on STANDBY, and about 5 hours on MEASURE. The battery is a standard 9V alkaline. The meter is shipped with a battery inside. When the battery voltage drops below about 7.9, all three decimal points (. . . ) will become visible. Then unscrew the back of the meter and replace the battery. Be careful to position the battery so that the wires do not interfere with the motion of the fan. If the battery has become very weak (below 5.9 volts) and is not replaced before then, it may cause the three decimal points (. . . ) not to display properly so it will not indicate low battery. Or it may cause all numbers on the display to be blank. If this occurs, then when you turn on the fan (MEASURE), either it will not turn at all, or it will turn slowly and you will hear by the sound that it is turning more and more slowly. In this case, you should replace the battery. If a rechargeable battery is used, an 8.4V type (not a 7.2V type) should be installed. The meter's case is coated with a conductive paint and it should not be cleaned with solvents. If cleaning is required, use only water and a cloth, and only on the outside. If the inside of the meter becomes very dusty, you might notice the following effect: when the meter is on 19.99 range, and STANDBY, in an area with very few ions, the display will settle at a more negative number when POLARITY is "-" than when POLARITY is "+". If after you wait at least 30 seconds after switching POLARITY, the difference between the displayed numbers on "-" and "+" is more than 0.10 (100 ions/cm3), then some dust or lint is inside, forming a slightly-electrically-conducting bridge between the internal collector plate and the metal chamber which surrounds the collector plate. This dust will cause a difference between the "STANDBY" the "+" and "-" readings equal to the amount displayed. To clean out the dust, turn off the meter and pull the black wind guard off from the top of the meter. Then look at the brass square (collector plate) inside. The three wires that are connected to it go up through (3) holes. Make sure that no dust or lint touches any of the three wires where it goes through the holes. Then make sure the brass has no dust or lint that touches between the brass square and the right or left side of the metal chamber, and make sure the brass square is centered (left & right). If it is not in the center, it can be pushed to center it. Blow out any dust, or clean with a strip of writing paper or a wire, if any dust is inside. If cleaning is done properly, the difference in the display reading in still air (you may have to cover the top of the meter with your hand to stop the air flow) between "+" and "-" should be less than 0.10 (100 ions/cm3). If you make this measurement in a room with moving air and a large number of ions present, the difference in reading between POLARITY "+" and "-" is supposed to be large. That is why the test should be in still air with a normally low ion count (less than 0.50, of both "+" and "-" ions).
Problems
:
If the fan does not rotate when the MEASURE switch is flipped to the up position, flip the switch between MEASURE and STANDBY a few times. (Sometimes some dust may prevent the MEASURE switch from going fully to the "up" position). If that doesn't work, turn off the meter and unscrew the back. Spin the fan with your finger to make sure it can turn freely. Sometimes the battery is replaced in a position so that the battery wire interferes with the fan motion. If so, change the battery position. The fan blade is on a small steel shaft. If the fan blade is positioned too far forward or backward on this shaft, it may hit something and not be able to turn. Just use your finger or pry with a flat-head screwdriver to push the fan backward or forward so it can turn freely. If the fan seems to be getting slower (the sound of the fan has a lower and lower pitch), replace the battery.
If all 3 decimal points show, or if the display remains blank when turned on, replace the battery by unscrewing the back.
If the number displayed changes frequently and does not remain stable, make sure the meter is grounded. Sometimes a screw or metal object that is supposed to be "earth grounded" is actually not, and if you connect the allegator clip of the ground cord to that, the meter may be unstable. Check by measuring the resistance with a multimeter between the jack on the ground cord and a water pipe. It should be less than 100 K ohms. Another way to check is to charge yourself by pointing a negative ionizer toward yourself for a few seconds, and then touch the jack on the ground cord. It should spark if it is connected to earth ground. If it does not spark, try the same test by touching a water pipe. If you spark when you touch a water pipe but not when you touch the jack on the ground cord, the ground cord is not connected to earth ground, and you should find a good earth ground to connect to.
If you are measuring the output of a negative ionizer and you notice that the meter is detecting a large number of positive ions (especially when the inlet slot is pointed away from the ionizer), it means the meter is not properly grounded. That is, the meter is charging to a very high negative voltage. The voltage is so high that it is causing the air near it to spark and produce ions. The positive ions in the air are then attracted to the negatively-charged meter. This can create a very large number of positive ions, and the meter will detect a small fraction of them even if the POLARITY is set to "-".
About air ions:
Almost all "+" natural ions come from radioactivity. About 40% of natural air ions come from radioactive minerals in the ground. Each time a radioactive atom decays releasing an alpha particle in the air, it produces 50,000 - 500,000 air ion pairs. Another 40% comes from radon in the air (which produces about 250,000 ion pairs for each radon atom), and 20% comes from cosmic rays (high-energy protons from distant supernovas). Indoors, ions "live" on average about 30 seconds before touching a surface and shorting to ground. Outdoor ions usually "live" several minutes. Negative ions come from radioactivity and evaporating water. Also lightning, thunderstorms, and forest fires contribute "+" and ions, but since these ions are not produced during fair weather, it is usually only radioactivity and evaporating water that produce ions outdoors. Normal fair-weather ion concentrations are 200 to 800 negative and 250 to 1500 positive ions per cubic centimeter. Indoor levels are usually lower. Several hours before a storm, + ion concentration will increase dramatically, sometimes exceeding 5000 ions/cm3. During a storm, - ions increase to several thousand per cm3 while + ions decrease, often to below 500.
Ions are usually produced by high-energy events, such as an open flame or a very hot object (hot enough to glow). Hot objects usually emit equal numbers of "+" and "-" ions. In addition, high DC voltage (over 1000 Volts), especially when connected to pointed metal edges or needles, will produce ions of the same polarity as the voltage source. This is the basis of ion generators. Evaporating water will produce "-" ions in the air and as a consequence leave "+" charges behind in the water that hasn't yet evaporated. If the excess "+" charges left behind are not conducted back to ground, the water will become "+" enough that "-" ion production will cease. For example, a fountain that has a motor that plugs into the wall will continuously produce "-" ions (until the water runs out) but a battery operated fountain will stop producing "-" ions after a few minutes if the fountain is well insulated from ground. The same is true of a battery-powered air ionizer. In general, for every 3x10-13 water molecule that evaporates, one water molecule carries an excess "-" charge.
Because a large concentration of + ions can attract - ions, high concentrations of + and - ions are often found together. Typically, a high concentration (1000 or more) of both may be found in one area outdoors while low concentration (300 or less) is found typically one city block away. A cloud of pure + ions (no -) with a concentration of 1000 ions/cm3 would be very unstable and would fall apart if its diameter were more than about 30m (100'). For this reason, high concentrations of exclusively + (or exclusively -) ions tend to be compact, and don't extend more than about 30 m. While testing indoors, you may find high - in one area of a room and high + in another, because rooms are usually small compared to 30 m (100').
The life time of "fast" ions (these are the most common type) is determined by how long they last before they collide with a solid (or dust) which usually neutralizes their charge. Indoors electric fields are stronger than outdoors. Plastic surfaces charge to a typical potential of negative 1000 volts. This produces electric fields of 500-5000 volts per meter near the plastic surface. The electric field repels negative ions (air molecules with an extra O- or OH-. The mobility of fast - ions is about 1.2x10-4 m/s per V/m, so at 2000 V/m, - ions are repelled at a speed of 2000x 1.2x10-4 = .24m/s (meters per second). Positive ions (air molecules with an extra H+ or positive ammonia or carbonate molecule) are attracted to the plastic by the same field. Their mobility is slightly lower (about 1.0 x 10-4 m/s per V/m) and they have a slightly slower speed of .2 m/s if exposed to 2000 V/m in this example. When the + ions touch the plastic, they give up their + charge. This partially neutralizes the - charge on the plastic. Under typical conditions, complete neutralization of the - charge on the plastic would occur in a few hours or days. However, dust blowing by will rub against the plastic and acquire a + charge. This dust carries the + charge away (ultimately to Earth ground). As a result, the plastic always retains a little negative charge. A good way to standardize (and lengthen) the lifetime of indoor ions is to put them in a large cardboard box. Lifetime then is about 50 sec, regardless of humidity, so if, for example, 4 pCi/L of radon is in the box, it will produce a continuous 1600 + ions/cm3 in the box.
You can produce negative ions directly by combing your hair with a plastic comb. If you then blow air past the comb, the air will have between 10,000 and 100,000 negative ions/cm3 immediately next to the comb. The number is lower in high humidity. Also, your breath contains about 20,000 to 50,000 negative ions/cm3 from the evaporating water, but you must be grounded to exhale a concentration this high. If you are insulated from the earth ground, you will become more positively charged with each exhalation (by about 5 volts) because your breath is removing negative charge. Eventually, you will become sufficiently positive (after exhaling about 20 times), that the negative ions will immediately return to you. This is the same effect that may occur in building cooling systems that use an evaporating water tower. If not properly grounded, the water pump and vents may become very positive. (If the inside vents are isolated from the evaporating water via a heat exchanger, the vents may become very positive and produce a large number of + ions. This can be corrected simply by grounding the vent).
Both + and - ions come from combustion (flame, wood burning, cigarette smoke, and car exhaust) and from very hot surfaces (hot enough to glow).
Indoors, near ground level (basement), most "+" ions come from radon, and a reading of 1000 "+" ions/cm3 means about 4 pCi/L of radon; the maximum allowable amount in the U.S. (This number of ions is directly proportional to radon concentration multiplied by average ion lifetime: strong electric fields indoors will reduce the ion lifetime.) Because it is unlikely that a level so high (1000, or 1.00 on the counter) can come from anything else (other than flame, smoke, or a hot electric heating element), it is likely that 1000 ions/cm3 in a basement means about 4 pCi/L of radon are present (or 2000 ions/cm3 = 8 pCi/L, etc.). Note that if radon is the source of the ions, then the concentration of ions will be approximately equal throughout the basement. If it is instead 1000 near a hot water heater but only 100 ions/cm3 elsewhere, it is not radon.
If the average "+" ion count is low (for example, less than 100), then there is essentially no radon present. It is not possible to "hide" the ions that radon produces. "No ions" means "no radon". Occasionally, a small piece of dust will discharge on the plate. Dust is usually "-", so the plate will read typically -1000 (-1.00) or so, even if the POLARITY switch is on "+". This will return to normal in about 3 seconds. Holding the counter near any alpha particle source (Uranium, Thorium, etc.) will produce very high ion readings, especially "+". This ion Counter can therefore directly be used in place of a Geiger Counter. Turn the switch to STANDBY and polarity to "+". Remove the wind guard and hold the top of the ion Counter close to the test source of possible radioactivity. If .1 microCurie of 5 to 8 MeV alpha (Uranium, Thorium, Radium) is entering the top hole, the display will read 250,000 ions/cm3 ("250" on the 1999 scale). These alpha particles can only travel through about 5 cm (2") of air, so hold the top of the counter very near the suspected source. The display is proportional to the radioactivity present. Neutrons can also be detected by putting a thin layer of plastic (a hydrogen source) over the rectangular slot. This will convert hi-energy neutrons to protons, which can be detected because protons create ion pairs. Sensitivity is a few orders of magnitude less than sensitivity to alpha particles (as described above).
How the Air Ion Counter Operates (and How to Take Accurate Readings)
This meter operates by sampling the air, which is pulled into the slot in the top and exits out the round hole in the bottom, at the rate of 800 cm3 per second. While inside the meter, either negative or positive ions (depending on how the POLARITY switch is set) are taken from the fast-flowing air and deposited onto an internal collector plate. The number of elementary charges per second that hit the collector plate is measured (by measuring the voltage of the collector plate, which is connected to ground through a 10 G ohm resistor). The POLARITY switch selects which polarity of ions (+ or -) will be measured. This switch forces the voltage of a metal chamber, which surrounds the collector plate, to be either +10, 0, or -10 volts with respect to ground. If POLARITY is set at "+", the chamber will be at +10 volts and the positive ions in the air inside the chamber will be accelerated away from the outer walls of the chamber and toward the "grounded" central collector plate. At this "+" setting, negative ions will actually be accelerated away from the collector plate so in that case, the collector plate will only detect positive ions, and not detect negative ions. Similarly, if the POLARITY is set at "-", the collector plate will only detect negative ions.
Three effects can interfere with ion readings, and should be avoided:
1) If the plastic case of the Air Ion Counter has a significant static electric charge, either "+" or "-", the meter will read too low. For example, if the POLARITY switch is set to "+", and the plastic case of the meter is accidentally carrying excess positive charge, the case will repel positive ions that are in the air. Therefore, + ions won't enter the top slot and the reading will be much too low. Even if the POLARITY switch is then changed to "-", the meter will continue to read too low, because negative ions will be attracted to the (positive) case and will not enter the meter properly at the top. Therefore, the case must be connected to ground (with the supplied long cord) unless you are sure that the case does not have a static charge. When measuring near a negative ionizer, this grounding is essential, because the ionizer will rapidly charge the case negative. Also, any highly charged objects (objects with a lot of "static electricity", including clothing made of synthetic cloth, and plastic objects that have been handled or rubbed recently) should be kept away from the area where ions are being measured. This surface charging can affect any plastic object near an ionizer, including the plastic enclosure of an ionizer (if the ionizer is not well designed). In this situation, an ionizer may produce a large number of negative ions immediately after it is turned on, but then the output of negative ions reduces to near zero after a time interval of a few seconds or more. (If this happens, the enclosure of the ionizer in question should be redesigned to be electrically conductive and it should be connected to earth ground). Any battery -operated ionizer will also have a similar problem unless the enclosure is connected to ground. That is, the battery-powered ionizer will charge more and more positive until it can emit no more negative ions, because the negative ions are attracted back to the ionizer and never leave the vicinity.
2) Another effect that can interfere with ion detection is that ions are usually not distributed uniformly throughout a volume. This is especially important indoors. In a room, a slight air breeze can blow an area of high ion concentration away from the ion counter and then later the breeze may blow the ions back toward the ion counter. Therefore the number displayed may be high, but then go to near zero, and back to a high number again. A similar (irregular) distribution of ions occurs near an ionizer. Usually in an ionizer the ions travel out from an electric needle. If the air in the room is not moving, the ions travel only to a distance of about 200 to 300 cm away from the needle, and then the ions stop and travel back to the ionizer or to other grounded objects that are nearby. Also the number of ions is large in the straight forward direction, but is much smaller at wide angle, more than about 45 away from forward. Therefore an ion counter that is held about 250 cm away from an ionizer (straight in front of the needle) may read low, then high, then low, etc. This is because the distance that ions travel varies between 200 and 300 cm, and slight breezes in the room can blow the "cloud" of ions backward and then forward. The same high-low-high can occur at the side of an ionizer, for example, only 50 cm away. The direction of the "beam" of ions coming out may change because of slight room breezes. If a fan is used to mix the air in the room, the distribution of ions will become more uniform, and measurements will be much more stable. The fan will make the ions travel out to all areas of the room.
3) If the wind guard at the top of the Air Ion Counter is removed, the reading will become much more sensitive to stray static electricity. For example, if the wind guard is not in place on top, and the top is moved toward a positively charged surface (like a TV screen), the display will show a large positive number as long as the top continues to move closer to the TV screen. When the motion stops however, the display will settle back to near zero after about 10 seconds. In fact, this effect can be used to measure the charge on surfaces; when approaching a surface at a certain speed, the display (if properly RE-ZEROED first) will read the correct polarity of the surface and will show a number proportional to the amount of surface charge. When you are measuring air that has mostly negative or mostly positive ions (but is not a mix of both positive and negative ions), then the measured number of ions per cm3 will not change much if the wind guard is removed. (The number is usually about 10% high if the wind guard is removed). However, a mix of positive and negative ions is less stable, and the number of ions per cm3 will decrease every time the air must go around a sharp turn, such as at the wind guard. This sharp turn causes positive and negative to neutralize each other partially. As a result, the wind guard may reduce the number of positive (and also negative) ions per cm3 by 10% to 50%, with the highest reduction occurring at the highest ion density. For this reason, the wind guard should not be used if the reading is high for both positive and negative ions. That is, if, with the wind guard installed, you measure the number of both positive and negative ions/cm3, and both numbers are higher than 2.00 (thousand ions/cm3), you should remove the wind guard for accurate (+/-25%) readings. If only one (or neither) polarity is above 2.00 (thousand ions/cm3), the readings will be accurate whether or not you keep the wind guard installed, but the wind guard helps shield the Air Ion Counter from static electricity. It also is useful if reading outside in windy conditions, because it limits the wind speed inside the Air Ion Counter.
Specifications:
Air flow: 800 cm3/sec (linear speed is 160 cm/sec through a polarization field of 2500 V/m and the system is designed to collect 60% of the ions in still air. A lower percentage is collected if air is forced faster than 160 cm/sec through the inlet slot and a higher percentage than 60% is collected if a reverse air flow slows the air flow. This maintains the accuracy in windy conditions.)
Dynamic Range: 10 - 1,999,000 ions/cm3, both selectively "+" and selectively "-".
Setting time: Approx.
2 seconds (response time), and 10 sec (after switchover
between "+" and "-")
Noise level: (2 second-weighting) approximately 10 ions/cm3
Input resistance: 1010 Ohms.
Accuracy: +/-25% for fast ions (mobility greater than 8 x 10-5 m/s per V/m - these are the most numerous ions. The Air Ion Counter is less sensitive to "slow" ions such as charged pieces of dust).
Battery: One 9V alkaline. Current drain is about 4ma on STANDBY, and 35ma on MEASURE. All 3 decimal points display when battery becomes weak (below 7.9V). Battery life is about 60 hours on STANDBY and 5 hours on MEASURE.
Ion Selectivity (crosstalk): 1:5000. That is, if POLARITY is set to "+", the meter will
display 1/5000 of the "-" ion density (as a negative number) if there are many negative ions and no positive ions. With POLARITY set in its center position, the meter will read a number which is 1/10 the "+" density, minus 1/10 the "-" density.
Warranty: 1 year
Assembled in USA.