JP2017032456A - Atmosphere sampling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an atmosphere sampling device enabling a continuous atmosphere observation to be performed for a long period which has been difficult with a conventional device at a place such as a remote place and the like where a power supply such as a commercial power supply cannot be secured.SOLUTION: An atmosphere sampling device for observing an atmosphere has an atmosphere sampling device, a power supply, and electric power supply means from the power supply to the atmosphere sampling device, and includes a mechanism (A) for collecting a suspended particulate matter of the atmosphere in the filter surface by continuously sucking the atmosphere by a suction pump via a filter. In addition, the filter is automatically collected and stored for each elapse time arbitrarily set from one hour to 30 days, and a mechanism (B) for supplying a new filer to a collection position of the suspended particulate matter. As the power supply, a fuel cell whose output is in a range of 10 to 200 W and a secondary battery are provided.SELECTED DRAWING: None

Description

The present invention relates to a sampling device for suspended particulate matter in the atmosphere, and has a function of replacing a filter every arbitrary time, and uses an independent power source combining a fuel cell and a secondary battery as a power source. In a place where a power source such as a commercial power source cannot be secured, long-term continuous air sampling that has not been possible until now is possible.

Airborne particulate matter present in the atmosphere reaches the lungs during respiration, and there is concern about adverse effects on the human body. For this reason, environmental standards concerning air pollution are established, and various measurement techniques and devices are used for that purpose.

The method for measuring particulate matter is roughly classified into a filter method for sucking air and filtering and collecting the particulate matter on a filter, and a method using an automatic measuring instrument.

In general, the expression of the concentration of particulate matter in the atmosphere is generally a number concentration based on the number of particulate matter contained in the air per unit volume or a mass concentration based on the mass of the particulate matter. However, the relationship between air pollution and health effects has often been regarded as a correlation with mass concentration. As a standard measurement method for particulate matter, a filter method has been employed in which a mass concentration is measured by filtering and collecting on a filter with a low volume air sampler for a certain period of time. In this method, the average mass concentration C (μg / m 3) in the atmosphere during the measurement period is obtained by measuring the mass M (μg) of the particulate matter collected on the filter by the following formula. Here, V is a flow velocity (m3 / hr), and t is a sampling time (hr).
C = M / (V × t)

The filter method is the most reliable measurement method as typified by the Federal Standard Measurement Method of the US EPA, and is a device with a relatively simple configuration consisting of a combination of a pump and a filter as a basic configuration. The mass concentration of the particulate matter collected on the filter over time is measured.

However, such a method has a problem that it takes time and effort to manage the filter because it is necessary to replace the filter periodically. Even if a small pump is used, the power consumption of the pump is as large as about 10 W, so there is no problem in a place where a commercial power source can be secured. However, when only a secondary battery is used as a power source, the battery is empty in a short time. Therefore, it is necessary to frequently replace the secondary battery or to transport a large battery, which is troublesome to manage. For this reason, the use is usually limited to measurement in a place where a person can manage.

On the other hand, as an automatic measuring device, a method by a β-ray absorption method and a piezoelectric balance method is added. At present, automatic measuring instruments of the β-ray absorption method are mainly used as measuring instruments for constant monitoring.

As an automatic measuring instrument, for example, as in Reference 1, an automatic measuring instrument that collects suspended particulate matter in the atmosphere and then continuously measures it by X-ray fluorescence analysis and β-ray mass spectrometry has been introduced. . Although this is an apparatus that automatically performs from suction to measurement and has the merit that it can always be observed, it has a large power consumption because it is integrated with the analyzer (for example, Kimoto, the applicant of Patent Document 1). PM-712 manufactured by Denki Kogyo Co., Ltd. has a power consumption of 450 VA), which can be used only in places where commercial power can be used.

As described above, there is a problem that applicable places are limited in measurement and observation of suspended particulate matter by either the filter method or the automatic measuring device. Therefore, it is subject to restrictions especially when performing outdoor observations in mountainous areas.

In recent years, transboundary air pollution due to PM2.5 has become a problem, but suspended particulate matter in the atmosphere is also included in, for example, field burning and exhaust gas in trucks. In many cases, it is difficult to distinguish between those generated from the sea and the transboundary pollution. This is not only a quantitative problem but also a qualitative problem. In order to avoid the influence from the vicinity of the observation point, it is preferable to observe at a remote place such as in the mountains or remote islands away from the isolat, but as mentioned above, it is limited by the place due to power shortage is the current situation.

JP 2008-261712 A

  The subject of this application is providing the atmospheric sampling apparatus which enables long-term continuous atmospheric observation which was difficult conventionally in places, such as a remote place where power sources, such as commercial power, cannot be secured.

In order to solve the above problems, the present invention provides the following atmospheric sampling apparatus.

(1) An atmospheric sampling device for atmospheric observation, comprising an atmospheric sampling device, a power source, and power supply means from the power source to the atmospheric sampling device, and the atmospheric sampling device includes a filter and a suction pump A mechanism (A) for collecting suspended particulate matter in the atmosphere on the surface of the filter by continuously sucking the atmosphere with the suction pump through at least the filter; The filter, in which suspended particulate matter is collected, is automatically collected and stored every time that is arbitrarily set between 30 days from the time, and a new filter is placed at the suspended particulate matter collecting position. An atmosphere characterized by having a mechanism (B) to be supplied and further having a power source including a fuel cell having an output of 10 to 200 W and a secondary battery as the power source. It is a sampling apparatus.
(2) Further, in the mechanism (A), the filter is any one of a tape-shaped collection filter, a rotary collection filter, and an exchangeable collection filter. The time arbitrarily set in the mechanism (B) By providing a mechanism for collecting, storing and supplying the filter by shifting the position at every passage so that the collection filter is continuously supplied to the collection position of the suspended particulate matter at regular time intervals. (1) The air sampling device according to (1).
(3) Further, in the power source, the fuel cell is a direct methanol fuel cell, the fuel cell is capable of charging the secondary battery, and the power supply means is a direct DC / DC converter, and The air sampling apparatus according to any one of (1) to (2), wherein the air sampling apparatus is at least one means selected from the group consisting of DC / AC inverters.
(4) Moreover, the fuel used for the said fuel cell is methanol aqueous solution with a density | concentration of 80%-99.5% of range, It is an atmospheric sampling apparatus as described in (3) characterized by the above-mentioned.

The present invention relates to a sampling apparatus for suspended particulate matter in the atmosphere, and has a function of replacing a filter at an arbitrary time, and uses an independent power source combining a fuel cell and a secondary battery as a power source. In order to provide a sampling device for atmospheric observation that enables continuous long-term atmospheric observation, which was difficult in the past, such as in remote locations where commercial power sources cannot be secured, the power supply is insufficient. The restriction of the place caused by can be removed.

The conceptual diagram which shows an example of the apparatus for atmospheric sampling of the atmospheric sampling apparatus of this invention The conceptual diagram which shows an example of the apparatus for atmospheric sampling of the atmospheric sampling apparatus of this invention The conceptual diagram which shows an example of the apparatus for atmospheric sampling of the atmospheric sampling apparatus of this invention Schematic diagram showing an example of the configuration of the fuel cell of the present invention The conceptual diagram which shows an example of the means to supply electric power required for an atmospheric sampling apparatus from the power supply of this invention

In order to achieve the above object, an atmospheric sampling apparatus for atmospheric observation of the present invention comprises an atmospheric sampling device, a power source, and a power supply means from the power source to the atmospheric sampling device, and the atmospheric sampling device is a filter. And a mechanism (A) for collecting suspended particulate matter in the atmosphere on the filter surface by continuously sucking the atmosphere with the suction pump through at least the filter. In addition, the filter automatically collects and stores the filter that collects suspended particulate matter every time that is arbitrarily set between 1 hour and 30 days, and a new filter is suspended in particulate form. It has a mechanism (B) that is supplied to the substance collection position, and further has a power source including a fuel cell and a secondary battery whose output is in the range of 10 to 200 W as the power source. It is air sampling device according to claim.

As described in the background art, a technique for collecting airborne particulate matter on a filter using a filter and a pump has been put into practical use for a long time. However, since it is difficult to secure a power source, those that can be used in remote areas such as in the mountains are limited to extremely short-term measurements, and frequent replacement of the power source or filter is necessary. It is difficult to sample continuously.

In order to solve the problem, it is only necessary to achieve two things: (1) reducing the labor required for replacing the filter by human power, and (2) solving the problem of insufficient power supply. Regarding power shortage, it is conceivable to extend the power supply for a long time by using a solar cell or the like. (3) Ensuring the stability of the power supply is also important.

Therefore, first, in order to reduce the labor involved in filter replacement, in the present invention, air is continuously sucked by a suction pump through at least a filter, thereby trapping suspended particulate matter in the air on the filter surface. A mechanism for collecting (A), and a filter that automatically collects and stores the filter, in which suspended particulate matter is collected, every time that is arbitrarily set between 1 hour and 30 days At the same time, a new filter has a mechanism (B) that is supplied to the collection position of the suspended particulate matter.

1 to 3 are conceptual diagrams of an atmospheric sampling device, which will be described. In FIG. 1, the air and airborne particulate matter sucked into the introduction part (5) from the atmosphere intake part (3) by the suction pump (4) are supplied to the tape filter (1) and (2). -It collects on the tape filter of (6) supplied for every time interval set arbitrarily between winders. The filter is a mechanism in which the filter is recovered by the winding unit (2) after being exposed to the sucked air for an arbitrary time. Therefore, by winding up at (2) at regular intervals, it becomes possible to sample the suspended particulate matter unattended and periodically. At this time, it is also preferable to protect the collected filter with the protective film (8) supplied from the protective film supply unit (7).

Here, it is preferable to adjust the flow rate because the air flow rate decreases when the filter is clogged. Therefore, it is preferable to keep the suction amount of the atmosphere constant by attaching a flow rate control device in front of the suction pump of (4). However, in order to minimize the power required for the flow rate control, it is also possible to minimize the flow rate fluctuation by replacing the filter in a relatively short period of time. Further, instead of the flow rate control device, a pressure gauge is installed to measure the pressure, whereby the suction speed can be calculated from the correlation between the pressure and the flow rate, and the average flow velocity can be obtained therefrom.

The shape of the air intake part (3) is not particularly limited, and conventional techniques can be used. For example, in order to avoid the influence of rain and snow, it is a preferable example to have an umbrella-like structure that does not allow rain or snow. Moreover, the shape of the air introduction part to the filter of (5) is not limited, for example, a straight or curved metal pipe is a good example, and a conventional technique can be used for the air introduction part. For example, it is a preferable example to provide a pipe with a method of incorporating a device called a cyclone and classifying suspended particulate matter classified into PM10 and PM2.5.

In addition, a plurality of configurations relating to the filters (1), (6), (2), (7), and (8) can be installed on the air flow path. By arranging a coarse filter on the upstream side and a fine filter on the downstream side, it is possible to collect particles for each particle diameter.

The conceptual diagram of FIG. 2 is characterized in that an exchangeable collection filter is used in place of the configuration related to the filters of (1), (6), (2), (7), and (8) in FIG. In FIG. 2, the configuration related to the filter A shown by (9), (10), (14), and (16) and the configuration related to the filter B shown by (12), (13), (17), and (18) are provided. Yes. The exchangeable collection filter here means that airborne particles are collected in the filter A (9) by flowing air through the components related to the filter A at an arbitrary time. Air does not flow through the components related to the filter B, and at other timing, air is passed through the components related to the filter B, so that suspended particulate matter in the atmosphere is collected by the filter B (12). It is a mechanism for controlling the air flow so as not to flow. Here, it is preferable that the air inlet to the filters of (14) and (17) can be opened and closed so that an air flow path can be selected, and the filters of (16) and (18) are used. It is a preferable mode that an atmospheric flow path can be selected by using a mechanism that can open and close the outlet of the atmospheric air. Alternatively, it is also preferable that an air flow path can be selected by using a mechanism capable of opening and closing both the air inlet and the air outlet through the filter. Here, the configuration using two filters, filter A and filter B, is described. By increasing the number of configurations including the above-mentioned filters, the air flow path is changed at every set time, and in order It is possible to collect airborne particulate matter on many filters. Here, the positions of the components related to each filter can be changed, and the positions of the components related to each filter are not changed, but the air flow itself can also be changed. As described above, it is also possible to collect particles for each particle diameter by installing a plurality of filters from upstream to downstream in the components related to one filter.

In the conceptual diagram of FIG. 3, instead of the configuration related to the filters of (1), (6), (2), (7), and (8) of FIG. 1, the rotary collection filter configured by (22) and (23) It is characterized by being. Here, sampling is performed while shifting the collection position of the suspended particulate matter in the atmosphere by rotating the filter of (22) from the viewpoint of the rotational axis of (23). It is an effective technique to increase the number of samples that can be sampled by changing the position of the rotation axis. In addition, as described above, by providing a plurality of filter units from upstream to downstream, it is possible to collect particles for each particle diameter.

  Next, the power supply will be described. Commercial power sources are widely used as power sources for air sampling devices used for sampling airborne particulate matter. However, there is a problem that it is difficult to secure a commercial power source in some places. In such a case, an independent power source (mainly a secondary battery or a combination of a secondary battery and a solar battery) is used as power supply means.

Since the power source by the secondary battery has a limit in the weight that can be carried, only a small amount of power can be supplied. For example, in consideration of a commercially available lead-acid battery, when the voltage is 12 V, the weight is 20 kg, the battery capacity is 40 Ah, and the power consumption of the pump is 10 W, the continuous operation period is 48 hours in calculation. Therefore, it is necessary to change the storage battery once every two days. In order to extend the period in which continuous operation is possible by replacing the battery once, it is necessary to prepare a lead storage battery of about 100 kg in order to operate for 10 days, for example, without increasing the number of batteries. In such a case, if it is a remote area, especially a mountainous area where there is no method other than transportation by human power, there is a problem that it is not realistic to transport and exchange a 100 kg storage battery every 10 days. When using a lithium battery, the weight can be reduced to about half to 2/3, or it is still necessary to transport and replace a 50 kg battery, and it is usually necessary to operate at about 0 ° C. to 30 ° C. However, it is difficult to use in cold areas or in areas with large temperature differences.

On the other hand, power sources using natural energy such as solar cells and wind power generation and power sources that combine secondary batteries have also been proposed. However, solar cells and wind power generation are subject to sunshine due to unseasonable weather such as snow and rain, and the surrounding environment. There is a problem that the amount of power generation fluctuates accordingly due to time reduction or wind intensity, and there is a problem in stability even when both are combined. In addition, a solar cell of a size that can be carried has a maximum output of several tens of watts and has a problem in portability. The same applies to wind power generation.

Although it is conceivable that a generator is used to charge the secondary battery, air pollutants are generated from the generator itself, which is not suitable for sampling the atmosphere. Moreover, since fuel consumption is fast, it is about 3 days if it can be used.

The inability to secure a suitable power source in this way hinders air sampling from a remote location. Therefore, in the present invention, a power source including a fuel cell and a secondary battery whose output is in the range of 10 to 200 W is used as the power source. Many studies on fuel cells have been conducted, and are described, for example, in Electrochemical Handbook 6th Edition, p616-637. In particular, a fuel cell using a polymer electrolyte membrane uses a proton-conducting ion exchange membrane as an electrolyte, and catalyst electrode fine particles and a gas diffusion electrode are directly joined to the surface of the ion exchange membrane-electrode assembly. Power generation using chemical reaction that can extract electricity and heat by catalysis by supplying fossil fuel such as water containing hydrogen gas or methanol solution to the anode side and supplying oxygen-containing gas such as oxygen or air to the cathode side System. Due to the chemical power generation, unlike the internal combustion engine, high-efficiency power generation that is not controlled by the Carnot cycle is possible.

A conceptual diagram of a general configuration of a fuel cell is shown in FIG. 4 and will be described based on this. At least the fuel cell includes the above-described ion exchange membrane-electrode assembly, a fuel flow path for supplying fuel to the surface in contact with the anode, and an oxidant flow path for supplying oxidant to the surface in contact with the cathode. A single cell having a separator formed, or a stack (24) in which a plurality of single cells are stacked, a fuel supply mechanism for supplying fuel to a fuel inlet of the single cell or stack, and a mechanism for circulating fuel as required ( 25), an oxidant supply mechanism that supplies an oxidant mainly composed of air to the oxidant inlet of the single cell or stack, and a mechanism (26) that circulates as necessary, and exhaust gas discharged from the single cell or stack. A mechanism (27) for discharging directly or indirectly to the outside, and a direct current (28) generated from a single cell or stack via the control mechanism (29) for atmospheric sampling. A mechanism for feeding (30) to become from the storage mechanism for storing these (31), also those having a mechanism for controlling the mechanism temperatures including. As specific examples, for example, the parts of (24), (25), (26), (27) and (31) are shown in Electrochemical Handbook 6th edition, P636 and P620, 77429, EP2239808, etc. describe the internal structure, but it is not limited, and when expressing a fuel cell, the single cell or stack is often shown as a fuel cell. FIG. 4 shows a fuel cell system including a mechanism and temperature control including supply and control of fuel and oxidant to the fuel cell shown in the conceptual diagram of FIG. Here, the fuel supply mechanism includes fuel supply from the fuel tank, and the fuel tank itself is preferable whether it is inside or outside the housing mechanism.

In the present invention, a direct methanol fuel cell using an aqueous methanol solution as the fuel is particularly preferable as the fuel cell. This is because when hydrogen is used as the fuel, the energy density is low, so that methanol, which is a liquid fuel, can supply electric power for a long time.

In the present invention, it is preferable that the fuel cell is electrically connected to a secondary battery, and the power generated by the fuel cell can be charged to the secondary battery. The output of the fuel cell is preferably in the range of 10W to 200W, more preferably in the range of 20W to 200W. When the output is less than 10 W, there is a possibility that the power supply amount is insufficient. On the other hand, when it exceeds 200 W, the weight also increases, so that there is a problem that it becomes difficult to transport especially when used in a remote place.

Since electric power is used for starting the fuel cell, a configuration in which electric power stored in the secondary battery at the time of starting the fuel cell can be used from an electrically connected secondary battery is preferable. Further, it is preferable that the fuel cell can be charged by supplying power from the fuel cell to the secondary battery after the fuel cell is started. In that case, the fuel cell always monitors the state of the secondary battery to monitor the state of charge of the secondary battery and start the fuel cell so that the state of charge of the secondary battery is always within the arbitrarily set range. It is a preferred configuration to stop. By always keeping the secondary battery in a constant charge state, it is possible to provide a highly stable system, and when power is stored in the secondary battery, by stopping the fuel cell, It is possible to make the fuel last longer.

Preferred examples of the secondary battery used in the present invention include a lead storage battery, a nickel hydride battery, a nickel cadmium battery, a lithium ion battery, a lithium polymer battery, and a vanadium battery. Particularly preferred are lead storage batteries, nickel cadmium batteries, and lithium ion batteries. Lead storage batteries and nickel cadmium batteries are highly reliable batteries, and are effective in providing highly reliable batteries for the outdoor power supply system of the present invention. Since a lithium ion battery can be reduced in size, it can provide a merit that it is easy to carry. In addition, as the secondary battery, a battery that is durable in repeated charge and discharge is preferable, and in consideration of temperature characteristics, a lead storage battery and a nickel cadmium battery are preferable, and a particularly preferable secondary battery is a lead storage battery, especially a deep cycle type lead. It is a storage battery.

The capacity of the secondary battery can be appropriately selected according to the application, but it tends to be preferable to use a battery with a 20 hour rate capacity of 5 Ah to 200 Ah. Particularly preferred is 10 Ah to 150 Ah. If it is 5 Ah or less, the battery capacity tends to be insufficient, and if it exceeds 200 Ah, it tends to be too heavy. As an example, when the output of the fuel cell is 45 W, 10 Ah to 100 Ah, more preferably 20 Ah to 70 Ah, and 110 W, 50 Ah to 200 Ah, more preferably 40 Ah to 80 Ah, is one standard. If the capacity of the secondary battery is too small relative to the output of the fuel cell, charging will be completed immediately, and the frequency of starting and stopping the fuel cell will increase. Tend to. If it is too large, it tends to be heavy and difficult to carry.

As a means for supplying necessary power to the air sampling device from a power source including a fuel cell and a secondary battery, a mechanism for supplying power directly or via at least one means of a DC / DC converter or a DC / AC inverter It is. Any type of DC / DC converter or DC / AC inverter can be selected. FIG. 5 shows a schematic diagram of the configuration. The positive electrode and the negative electrode of the fuel cell (32) are connected to the positive electrode and the negative electrode of the secondary battery (33) through electric wires, respectively. Is preferably connected to the power supply means (34) required for the air sampling and from there to the atmospheric sampling device (35).

Since the amount of power that can be generated is proportional to the amount of fuel, the size of the fuel tank can be changed in accordance with the period of operation. When methanol is used as the fuel, the fuel in the fuel tank is preferably a methanol aqueous solution having a concentration in the range of 80 to 99.5%. The higher the concentration, the longer it can be used, and it is desirable to exceed 80%. On the other hand, since the active ingredient of methanol is a deleterious substance, it is difficult to handle, so a concentration of 99.5% or less is preferable. More preferably, it is 85 to 95% of range. The direct methanol fuel cell preferably has a configuration in which diluted methanol is supplied to the fuel cell stack after the high-concentration fuel is taken in and then diluted in the fuel cell body. If high-concentration methanol flows into the fuel cell stack, it may lead to a decrease in output, so the concentration of diluted methanol is particularly preferably in the range of 0.3% to 10%. Further, as the fuel amount, it is preferable that an electric power amount of 0.6 kWh to 90 kWh can be supplied by one fuel change. Depending on the efficiency of the power supply system, 1 L to 80 L is a standard for methanol. If the amount of power that can be supplied in a single fuel change is less than 0.6 kWh, the frequency of fuel change tends to be high and maintenance tends to be complicated, and if it exceeds 90 kWh, the fuel tends to be heavy and difficult to change. is there.

In addition, it is preferable that the secondary battery also has a charging mechanism using natural energy. The combination with the solar power generation device, the wind power generation device, and the hydroelectric power generation device can further reduce the maintenance frequency, and enables continuous driving for a longer period. A particularly preferred combination is a small photovoltaic power generator.

The air sampling apparatus of the present invention is housed in a plurality of housings for the purpose of reducing the weight during transportation in order to increase the portability and reduce the restrictions depending on the installation location, and operate by connecting the housings after transportation. It is also possible to make it possible. In this case, when considering portability to a mountainous area or the like, it is preferable that each be 40 kg or less. When the weight exceeds 40 kg, it tends to be difficult to carry as a power supply system. More preferably, it is 30 kg or less, More preferably, it is 25 kg or less.

EXAMPLES Hereinafter, although this invention is demonstrated concretely using an Example, this invention is not limited to these Examples.

EFOY Pro800 (output 45W, direct methanol fuel cell) manufactured by SFC Energy is used as the fuel cell, and connected separately to M10 (fuel cartridge for fuel EFOY Pro800 including 10 L of methanol) which is a fuel cartridge manufactured by SFC Energy. Then, it was housed in a duralumin casing (52 cm × 65 cm × 25 cm) having a thickness of 3 mm. The casing was provided with an air inlet for supplying air to the fuel cell. The weight was 18 kg. Separately, a 12V-42 Ah deep cycle lead-acid battery connected to a 25 W-DC / DC converter was similarly housed in a duralumin casing (52 cm × 65 cm × 25 cm) of the same type. The weight was 15 kg.

As the air sampling device, the device of the type shown in FIG. 2 is used, and as the means for supplying power from the fuel cell and the secondary battery to the air sampling device, the device of FIG. 5 is adopted. The filter was collected once a week for 5 weeks and automatically and continuously operated for a total period of 840 hours. From the power consumption and operation time of the pump, the total power consumption was 8.4 kWh, and about 8 L of the fuel-powered cartridge was consumed. During this time, no maintenance work such as filter replacement or refueling was required.

  According to the present invention, it is possible to provide an air sampling apparatus that enables long-term continuous air sampling even in a remote place where a power source such as a commercial power source cannot be secured.

(1) Tape filter (supply side)
(2) Tape filter (winding)
(3) Air intake part (4) Air suction pump (5) Air introduction part to filter (6) Tape filter (7) Protection film supply part (8) Protection film (9) Filter A
(10) Flow path connected to filter A (11) Atmospheric intake part (12) Filter B
(13) Flow path connected to filter B (14) Atmospheric inlet to filter A (15) Intake pump (16) Atmospheric outlet from filter A (17) Atmospheric inlet to filter B (18) Atmospheric outlet from filter B (19) Atmospheric intake section (20) Atmospheric suction pump (21) Atmospheric introduction section to filter (22) Filter (23) Rotating shaft of filter (24) Single cell, or stack of multiple single cells (25) Fuel supply mechanism and mechanism to circulate fuel as required
(26) Oxidant supply mechanism and mechanism for circulation as necessary
(27) Mechanism for discharging exhaust gas directly or indirectly to the outside
(28) DC current generated from a single cell or a stack in which a plurality of single cells are stacked (29) Control mechanism
(30) Mechanism for supplying DC current to secondary battery and device (31) Storage mechanism (32) Fuel cell (33) Secondary battery (34) Power supply means to atmospheric sampling device (35) Atmospheric sampling device

Claims (4)

An atmospheric sampling device for atmospheric observation, comprising an atmospheric sampling device, a power source, and power supply means from the power source to the atmospheric sampling device, the atmospheric sampling device comprising a filter and a suction pump, and at least the The filter has a mechanism (A) for collecting suspended particulate matter in the atmosphere on the filter surface by continuously sucking the atmosphere with the suction pump through the filter, and the filter has 1 to 30 hours. The filter in which suspended particulate matter has been collected is automatically collected and stored every time set arbitrarily during the day, and a new filter is supplied to the suspended particulate matter collection position. An atmospheric sump characterized by having a mechanism (B), and further comprising as its power source a fuel cell having an output in the range of 10 to 200 W and a power source including a secondary battery Packaging equipment. In the mechanism (A), the filter is any one of a tape-shaped collection filter, a rotary collection filter, and an exchange-type collection filter. In the mechanism (B), the position is set at every arbitrarily set time. A mechanism is provided for collecting, storing and supplying the filter by continuously supplying the collection filter to the collection position of the suspended particulate matter at regular time intervals by shifting. Item 1. The atmospheric sampling device according to Item 1. In the power source, the fuel cell is a direct methanol fuel cell, the fuel cell is capable of charging the secondary battery, and the power supply means is directly from a DC / DC converter and a DC / AC inverter. The air sampling device according to claim 1, wherein the air sampling device is at least one member selected from the group consisting of: The atmospheric sampling apparatus according to claim 3, wherein the fuel used in the fuel cell is a methanol aqueous solution having a concentration of 80% to 99.5%.