JPS6349710Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a collection control device that is connected to a collection device for collecting suspended particulate matter in the air and collects the suspended particulate matter according to wind direction.

2. Description of the Related Art Conventionally, a device as shown in FIG. 1 has been known as a device for collecting suspended particulate matter in the air. That is, in FIG. 1, a is a suspended particulate matter sampler, b
is a suction pump, and c is a conduit that connects the sampler a and the suction pump b, with a flow meter d and a flow control valve e interposed therein, and air in the sampler a is sucked by the operation of the suction pump b, As a result, the collection section f of the sampler a where the paper is placed
Suspended particulate matter such as soot and dust in the air is sucked in and collected. Note that g in the figure is a sampler cover, and h and i are pressure gauges, respectively.

However, although this type of conventional collection device can measure the amount and type of suspended particulate matter in the entire area where the collection device is installed, it is not possible to determine which direction the collected material came from. It was not clear which direction most of the substances came from, and it was not possible to accurately analyze and clarify the state of their floating distribution.

The present invention was developed in view of the above circumstances, and by connecting to a collection device for collecting suspended particulate matter in the air and controlling the operating state (collection state) of the collection device, It is possible to sort and collect suspended particulate matter, etc. by wind direction, and therefore not only can the amount and type of suspended particulate matter, etc. in the entire area be measured at the collection installation location, but also the amount and type of suspended particulate matter, etc. can be measured according to the direction and wind speed of the area. It can also measure the amount and type of suspended particulate matter, etc.
It is an object of the present invention to provide a collection control device for suspended particulate matter in the air that can accurately analyze and clarify the floating distribution state of suspended particulate matter.

Hereinafter, one embodiment of the present invention will be described with reference to FIG.

A in Fig. 2 indicates a collection control device, in which an anemometer 1 and an anemometer 2 are installed, respectively, and these anemometer 1 and anemometer 2 collect suspended particulate matter, etc. in the air. The wind direction and wind speed at each location are measured. As the anemometer 1 and the anemometer 2, appropriate ones such as a photoelectric type, an ultrasonic type, a power generation type, etc. can be used.

The wind vane 1 and the anemometer 2 are connected to a converter 5 via cables 3 and 4, and the cables 3 and 4 generate electricity in the wind vane 1 and the anemometer 2 in accordance with the wind direction and wind speed. The signal is transmitted to converter 5. The electrical signal is transmitted by the converter 5 to a preset wind direction range (for example, in this embodiment, the wind direction is set in a range from northwest to
It is divided into four ranges: northeast (N), northeast to southeast (E), southeast to southwest (S), and southwest to northwest (W))
A discriminator that detects whether the wind speed is above or below a set wind speed (minimum wind speed at which the wind vane can operate) and sends a detection signal corresponding to the wind direction and speed as a control unit. Sent to 6. This discriminator 6 generates a discrimination signal based on the detection signal and sends this discrimination signal to a power relay amplifier 7, which amplifies this discrimination signal and sends it to a control box 8. There are a plurality of (five in this embodiment) relay switches 9 in the control box 8.
a to 9e are arranged, and each output terminal of these relay switches 9a to 9e is connected to one of the plurality of (five in this embodiment) output terminals 10a to 10e attached to the control box 8. It is connected to the corresponding output ends 10a to 10e, and among these, the output ends 10a to 10d are made to correspond to the four directions N, E, S, and W divided according to the wind direction. Then, according to the discrimination signal sent from the power relay amplifier 7, one of the plurality of relay switches 9a to 9e is discriminated and selected and excited, so that only the discriminated relay switch is turned on. Power for driving the suction pump of the collection device is supplied to the connected output end, but in this case, if the wind speed detected by the anemometer 2 is less than the set wind speed, the relay switch 9a classified according to the wind direction is activated. -9d is not sent, and therefore, no power is supplied to the output terminals 10a to 10d connected to these, and the no-wind relay switch 9e is selected, which causes the no-wind output terminal to Power is supplied.

That is, the electrical signal generated by the anemometer 2 is transmitted to the converter 5.
Here, the voltage value of the electrical signal is compared with the set value, and as a result, the voltage value of the electric signal is higher than the set value (higher than the set wind speed)
If so, the power supply to the windless output terminal 10e is stopped, and one of the switches 9a to 9d corresponding to the wind direction is turned on. In addition, when the voltage value of the electric signal generated by the anemometer 2 is less than the set value, the supply of pump driving power to the output ends 10a to 10d for each wind direction is stopped, and
Electric power is supplied to the output end 10e when there is no wind.

Reference numeral 11 denotes an hour meter which accumulates the time during which each of the relay switches 9a to 9e is on, and therefore the time during which pump driving power is supplied to the corresponding output terminals 10a to 10e for each wind direction. Furthermore, numeral 12 in the figure is a recorder.

Next, when using the collection control device for suspended particulate matter in the air with the above configuration to collect suspended particulate matter by wind direction and wind speed in the vicinity where this device is installed, first Five conventional collection devices with the configuration shown in the figure are installed in parallel, and the first to
Each suction pump b ₁ of the fifth collection device 13a to 13e
_b5 are connected to the output ends 10a to 10e of the control box 8 using power lines 14a to 14e, respectively. As a result, any one of the first to fifth collection devices 13a to 13e is driven by electric signals generated in the anemometer 1 and the anemometer 2 in accordance with the wind direction and wind speed at the installation location of the collection device. This allows floating particulate matter to be collected depending on the wind direction.

That is, the wind direction and wind speed at the installation location of the collection devices 13a to 13e are measured by the anemometer 1 and the anemometer 2. If it is in the northwest or northeast range, the discriminator 6 gives a command to turn on the relay switch 9a, which closes the circuit, thereby supplying pump driving power to the output end 10a. Therefore, the pump b ₁ of the first collection device 13a for each wind direction connected thereto is activated.
The sampler _a1 of the first collection device 13a collects suspended particulate matter in the air, but in this case, the other second to fifth collection devices 13b to 13e are not operating, so Suspended particulate matter is not collected in each of the samplers a ₂ to _{a 5} of these devices 13b to 13e. Next, if the wind direction changes and is in the northeast or southeast range, this change will cause the wind vane to
is detected, the relay switch 9b is turned on, and power is supplied to the output end 10b connected to the relay switch 9b.
The suction pump _b2 is activated, and the second collection device 13b collects suspended particulate matter,
The relay switch 9a is turned off, thereby stopping the supply of power to the output terminal 10a,
Collection by the first collection device 13a is stopped. Furthermore, when the wind direction changes from southeast to southwest, the relay switch 9c is turned on and the wind direction
The collection device 13c is activated to collect suspended particulate matter, and when the wind direction is in the southwest to northwest range, the relay switch 9d is turned on and the fourth collection device 13d according to wind direction Collects suspended particulate matter.

Additionally, when the wind speed becomes slower than the minimum wind speed for operating the anemometer 1, the discriminator 6 sends out a command to turn on the relay switch 9e, and power is supplied to the no-wind output terminal 10e. hour 5th
The collection device operates, thereby collecting suspended particulate matter in the air, but in this case, the collection of suspended particulate matter by the first to fourth collection devices 13a to 13d is stopped. .

In addition, in the process of collecting suspended particulate matter, the time during which each of the relay switches 9a to 9e is in the ON state, that is, the time during which each of the collection devices 13a to 13e is collecting suspended particulate matter, It is integrated by the hour meter 11.

By using the device of this embodiment and connecting it to an existing collection device, suspended particulate matter in the air can be sorted and collected according to wind direction, and the collected suspended particles It is possible to easily analyze and clarify the direction in which suspended particulate matter is distributed and where it comes from, along with the collected amount and type, and it is possible to accurately grasp the distribution state of suspended particulate matter near the installation location of the device. So it is very convenient.

In this case, in this embodiment, when the wind vane 1 is not actually operating in a state of no wind or light wind (even in this case, the pointer of the wind vane 1 indicates a certain wind direction, (The wind direction instruction is not accurate because the wind direction is too low to operate), the collection of suspended particulate matter by the wind direction collection devices 13a to 13d has been stopped; Since this is carried out by a windless collection device 13e that is separate from the collection devices 13a to 13d, each wind direction collection device 13a to 13d collects wind when the wind is in the correct wind direction range, respectively. Therefore, the reliability of collection by wind direction is high. Further, in the above embodiment, an hour meter 11 is provided corresponding to each of the wind direction collecting devices 13a to 13d and the windless collecting device 13e, so that the sampling time for each wind direction is accumulated. This is useful for sample analysis, as it is possible to calculate the amount of collected particles per unit time corresponding to each wind direction. The amount and type of suspended particulate matter collected by the windless sampler 12e are compared with the suspended particulate matter collected by the wind direction-specific collection devices 13a to 13d. By doing so, the distribution state of suspended particulate matter can be analyzed and elucidated in more detail from various points of view.

In the above embodiment, the wind direction is divided into four ranges: northeast, southwest, but it is not limited to this, and can be divided in various ways depending on the installation location of the device, purpose, etc. Further, the collection device may be a single-stage type that collects suspended particulate matter in all particle size ranges, or it may be a multi-stage type with two or more stages that collects particles in predetermined particle size ranges for each wind direction. You can.
In addition, a control collection device is installed that continuously collects suspended particulate matter regardless of wind direction or wind speed, and is connected to an output terminal that continuously supplies power to the control device. This also allows control data to be obtained. Furthermore, although the above embodiment describes the collection of suspended particulate matter, it is also possible to similarly collect gases, mist, etc. in the air according to wind direction. In this case, the sampler can be configured to contain an absorbent or adsorbent that absorbs or adsorbs these gases, mist, etc. Additionally, an absorbent or adsorbent may be housed in the sampler to absorb or adsorb and collect gases, mist, etc., and paper or the like may be arranged to collect floating particulate matter. The structure of the present invention may be changed without departing from the gist of the present invention.

As explained above, the present invention includes an anemometer 1, an anemometer 2, a wind direction indicated by the anemometer 1, and an anemometer 2.
a converter 5 that detects the wind speed indicated by and outputs electric signals corresponding to the wind direction and wind speed, and a converter 5 that discriminates the electric signal outputted by the converter 5 and generates a discrimination signal corresponding to the wind direction and wind speed. A collection device 13a having a discriminator 6 and a plurality of samplers _a1 to _a4 divided by wind direction for collecting suspended particulate matter etc. when the wind vane 1 is in operation. - 13d suction pumps b ₁ - _{b 4} and suction pump b ₅ of the collection device 13e, each having a windless sampler a ₅ for collecting suspended particulate matter etc. when the wind vane 1 is in an inoperable state. It has output terminals 10a to 10e to which it is connected, receives a discrimination signal from the discriminator 6, and connects the plurality of output terminals 10a to 10e in response to the discrimination signal.
A control box 8 that supplies power to operate the suction pumps b ₁ to _{b 5} is provided at a predetermined output end of the pumps, and the wind speed measured by the anemometer 2 is the minimum wind speed for operating the anemometer 1. Output ends connected to suction pumps b ₁ to b ₄ of collection devices 13 a to 13 d having samplers a ₁ to a ₄ according to wind direction corresponding to the wind direction measured by the wind vane 1 when the wind direction becomes larger. 10a to 10d, and when the wind speed measured by the anemometer 2 becomes lower than the minimum wind speed for operating the anemometer 1, the collection device 1 having the above-mentioned windless sampler _A5
Since it is configured to supply power to the output end 10e connected to the suction pump _b5 of 3e, it can be connected to an existing collection device to easily sort and collect suspended particulate matter in the air according to wind direction. This makes it possible to accurately analyze and clarify the suspended distribution state of suspended particulate matter, etc. near the measurement location.

In this case, according to the control device of the present invention, accurate analysis can be performed by controlling the wind direction sampler and the windless sampler and using them together. In other words, when there is no wind or a light wind, the wind vane pointer indicates a certain wind direction, but the wind direction indication is not accurate. Since the collection of suspended particulate matter, etc. by the wind direction sampler has been stopped, and the collection is done by a windless sampler that is separate from the wind direction sampler, each wind direction sampler has the correct amount of wind. Those within the wind direction range are collected. Therefore, the selection reliability of collection by wind direction is high, and therefore, by comparing the collection results by these samplers by wind direction and by the no-wind sampler, it is possible to clarify the distribution state of suspended particulate matter etc. very accurately. It is something.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a conventional airborne particulate matter collection device, and FIG. 2 is a block diagram showing an embodiment of the present invention. 1... Wind vane, 2... Anemometer, 5... Converter,
6... Discriminator, 10a-e... Output end, 13...
Collection device.

Claims (1)

[Scope of utility model registration request] An anemometer 1, an anemometer 2, a converter 5 that detects the wind direction indicated by the anemometer 1 and the wind speed indicated by the anemometer 2 and outputs electrical signals corresponding to these wind directions and wind speeds, respectively; a discriminator 6 for discriminating electrical signals output by the wind vane 1 and generating discriminating signals corresponding to the wind direction and wind speed; and a wind direction for collecting suspended particulate matter when the wind vane 1 is in operation. The suction pumps b ₁ to b ₄ of the collection devices 13a to 13d each having a plurality of separately separated samplers a ₁ to _{a 4} for each wind direction and the wind vane 1 are not in operation to capture suspended particulate matter, etc. Output ends 10a to 10e respectively connected to a suction pump _b5 of a collection device 13e with an airless sampler _a5 for collecting
receives a discrimination signal from the discriminator 6, and operates the suction pumps _b1 to _b5 at a predetermined output end of the plurality of output ends 10a to 10e in response to the discrimination signal. and a control box 8 for supplying electric power, and corresponds to the wind direction measured by the anemometer 1 when the wind speed measured by the anemometer 2 becomes greater than the minimum wind speed for operating the anemometer 1. Wind direction sampler
Power is supplied to any of the output ends _10a to _10d connected to the suction pumps _b1 to _b4 of the collection devices 13a to 13d having a1 to a4, and the wind speed measured by the anemometer 2 is determined from the wind direction. When the wind speed falls below the minimum wind speed for operating the total 1, power is supplied to the output end 10e connected to the suction pump _b5 of the collection device 13e having the windless sampler _a5 . A collection control device for suspended particulate matter in the air.