KR20150117391A - Multitude Atmosphere Sampling Device - Google Patents

Abstract

The present invention provides a multiple atmosphere sampling device for quickly and easily collecting various kinds of atmosphere samples all at once and precisely controlling a flow. The multiple atmosphere sampling device includes a case which includes a wheel on the lower side thereof, a vacuum pump which is installed on the lower side of the inner side of the case, a decompression chamber which is installed on the lower side of the inner side of the case and is connected to the vacuum pump, a plurality of inlets which are installed on the upper side of the case with a preset interval and receives the atmosphere according to the operation of the vacuum pump, a plurality of samplers which are installed in the case to collect the atmosphere samples according to the inflow of the atmosphere through the inlet, a plurality of flow controllers which are installed in the case to control the flow of the atmosphere which is inputted to the inlet and is transferred, and a plurality of transfer pipes which are installed to transfer the atmosphere inputted to the inlet by the vacuum pump via the sampler and the flow controller in order.

Description

{Multitude Atmosphere Sampling Device}

The present invention relates to a multi-atmosphere sampling device, and more particularly, to a multi-atmosphere sampling device capable of collecting various types of atmospheric samples simultaneously and simultaneously and precisely controlling the flow rate .

Generally, various pollutants are emitted from factories, homes, automobiles, etc., and it spreads in the air to cause air pollution. Such air pollution has a negative effect on human health life and emotional life, threatens the survival of living things, .

As industrialization has accelerated, the pollution status of the atmosphere is becoming increasingly serious. Therefore, many countries around the world are trying to prevent air pollution by monitoring, managing and supervising the state of air pollution.

Currently, the items that measure the degree of pollution in the atmosphere include items measuring the concentration of fine dust and items measuring the pollution degree of exhaust gas such as carbon dioxide, nitrogen oxide, sulfur oxide, hydrogen chloride, hydrogen fluoride, etc., Measurement methods and measuring devices have been developed and used.

In the case of air pollution measurement, the air sampling system is used to collect air samples for the items to be measured. Depending on the sampling method, direct sampling, container sampling, solvent sampling, solid collection, And a method based on collection space.

A conventional sample collection apparatus using a direct collecting method is disclosed in Patent Registration No. 10-0499726. Patent Publication No. 10-0499726 discloses a method of collecting a sample by using a difference between a vacuum pressure in a chamber and an atmospheric pressure in a sample collection bag installed in the chamber.

However, since the conventional sampling device constructed as described above is difficult to simultaneously collect a large number of contaminants, it is difficult to repeatedly collect the sample at a predetermined time interval, so that various air samples can be easily and precisely It is required to develop a sampling device capable of sampling.

The present invention has been made in view of the above, and it is possible to repeatedly collect samples at various times while collecting various kinds of air samples at the same time or changing the time and place, The present invention provides a multi-atmosphere sampling device capable of improving the accuracy and efficiency of air pollution measurement.

Another object of the present invention is to provide a multi-atmosphere sampling device capable of precisely and rapidly controlling a flow rate through a proportional control valve that is opened or closed in accordance with a control signal of a differential pressure sensor when controlling the flow rate of a gas transferred through a transfer pipe.

The multi-atmosphere sample collecting apparatus proposed by the present invention includes a case in which a wheel is installed at a lower portion, a vacuum pump installed in an inner lower portion of the case, a decompression chamber installed in an inner lower portion of the case and connected to the vacuum pump, A plurality of inlet ports provided at predetermined intervals on the upper surface of the case and through which the air is introduced according to the operation of the vacuum pump; a plurality of inlet ports provided in the case and installed to collect air samples as the air flows through the inlet port A plurality of flow controllers installed in the case to control a flow rate of air flowing into and flowing into the inlet; and an atmosphere introduced into the inlet by the vacuum pump is connected to the sampler and the flow controller sequentially And a plurality of conveying conduits installed to be conveyed via the conveying path.

Wherein the flow controller includes an orifice provided in the transfer conduit, a differential pressure sensor for measuring a pressure difference between a passage in front of the orifice of the transfer conduit and a rear passage, a temperature sensor for measuring a temperature on the inlet side of the transfer conduit, A proportional control valve installed to control the flow rate of the gas by changing the passage area of the gas, and a pressure difference measured by the differential pressure sensor and a temperature measured by the temperature sensor, And a controller for calculating the difference and outputting the flow difference as a control signal to the proportional control valve.

The samplers are installed to collect different types of chemically fractionated atmospheric samples.

Further, the present invention may further comprise an auxiliary vacuum pump installed in the lower portion of the case and connected to the decompression chamber.

According to the multi-atmosphere sampling apparatus according to the embodiment of the present invention, it is possible to collect various air samples at the same time, and it is possible to repeatedly collect samples repeatedly while changing the time or place, It is possible to improve accuracy and work efficiency when measuring air pollution through quick and accurate sampling.

According to the multi-atmosphere sampling system according to the embodiment of the present invention, accurate and rapid flow rate control can be performed by operating the proportional control valve according to the control signal of the differential pressure sensor, thereby enabling more accurate analysis and measurement of air pollution.

In addition, according to the multi-atmosphere sample collecting apparatus according to the embodiment of the present invention, it is possible to maintain a plurality of conveying pipes at uniform pressure by using the decompression chamber, so that accurate flow rate control is possible.

Further, according to the multi-atmosphere sampling apparatus according to the embodiment of the present invention, since the auxiliary vacuum pump is installed in addition to the vacuum pump, it is possible to use the auxiliary vacuum pump easily in case of sudden failure or deterioration of the pump.

1 is a perspective view illustrating a multi-atmosphere sampling apparatus according to a first embodiment of the present invention.
2 is a schematic diagram showing a multi-atmosphere sampling apparatus according to a first embodiment of the present invention.
3 is a flow diagram of a flow controller in a multi-atmosphere sampling system according to a first embodiment of the present invention.
FIG. 4 is a block diagram showing a flow controller in the multi-atmosphere sample collecting apparatus according to the first embodiment of the present invention.
FIG. 5 is a system diagram showing a multi-atmosphere sampling apparatus according to a second embodiment of the present invention.

Next, a preferred embodiment of a multi-atmosphere sampling device according to the present invention will be described in detail with reference to the drawings.

In the following description, the same reference numerals are used for the same technical elements, and detailed descriptions for avoiding redundant description are omitted.

The embodiments described below are intended to illustrate the preferred embodiments of the present invention in an effective manner and should not be construed to limit the scope of the present invention.

1 and 2, the multi-atmosphere sample collecting apparatus according to an embodiment of the present invention includes a case 10, a vacuum pump 20, a decompression chamber 30, an inlet 40, a sampler 50, , A flow controller (60), and a transfer line (42).

In the drawing, the dotted arrows indicate the direction in which the gas (atmosphere) flows.

The case 10 is formed in a substantially rectangular box shape and a plurality of wheels 12 are installed on the lower portion of the case 10 so as to be movable.

The vacuum pump (20) and the decompression chamber (30) are connected to each other and are installed in the inner lower portion of the case (10).

The inlet (40) is installed on the upper surface of the case (10) at a predetermined interval, and the atmosphere is introduced by the suction force generated by the operation of the vacuum pump (20).

The transfer pipe 42 is connected to the vacuum pump 20 such that the atmosphere flowing into the inlet 40 is sequentially sucked and transferred to the vacuum pump 20 via the sampler 50 and the flow controller 60 Respectively.

The transfer conduit 42 has one end connected to the inlet 40 and the other end connected to the decompression chamber 30.

The decompression chamber 30 is formed in a substantially rectangular box shape and is installed between the other end of the plurality of the transfer conduits 42 and the vacuum pump 20.

The inlet port 40, the transfer conduit 42, the sampler 50, and the flow controller 60 are installed in each case.

The sampler 50 is installed to collect air samples from the air flowing into the inlet 40 and being transported.

The four samplers 50 are installed so as to be able to collect different chemical compositional atmosphere samples.

For example, the four samplers 50 may include a filter using Teflon to collect an atmospheric sample of heavy metals, a filter using quartz fibers to collect air samples of polycyclic aromatic hydrocarbons (PAHs) A filter using nylon to collect atmospheric samples of the particulate matter, and a filter using glass wool to collect atmospheric samples of particulate matter.

The flow controller 60 is installed between the sampler 50 and the decompression chamber 30 to control the flow rate of the air flowing into the inlet 20 and transferred to the vacuum pump 20.

The flow controller 60 includes an orifice 62, a differential pressure sensor 64, a temperature sensor 66, a proportional control valve 68, and a controller 70, as shown in Figs.

The orifice 62 is installed in the transfer conduit 42 between the sampler 50 and the decompression chamber 30.

The differential pressure sensor 64 measures the pressure difference between the gas in the front partial passage and the rear partial passage of the orifice 62 of the transfer conduit 42.

The temperature sensor 66 is installed at one end of the transfer pipe 42 or the inlet 40 and measures the temperature.

 The proportional control valve 68 is provided to control the flow rate of the gas by changing the passage area of the transfer conduit 42.

The proportional control valve 68 may be a proportional control valve which is generally used for controlling the flow rate of the gas.

The controller 70 obtains the flow rate of the gas through the pressure difference of the gas measured by the differential pressure sensor 64 and the temperature measured by the temperature sensor 66 and calculates the difference between the detected flow rate and the set flow rate, To the proportional control valve 68 as a control signal.

The proportional control valve 68 regulates the passage opening / closing area of the transfer pipe 42 by using a motor or the like according to the output value of the controller 70.

Although not shown in the drawings, in the multi-atmosphere sample collecting apparatus according to an embodiment of the present invention configured as described above, a control module for controlling the vacuum pump 20, the flow controller 60, Depending on the design conditions, the control module can be configured to enable remote control and real-time monitoring of the user's mobile device, computer, management server, etc. in connection with wired / wireless communication.

As shown in FIG. 5, the multi-atmosphere sample collecting apparatus according to the second embodiment of the present invention further includes an auxiliary vacuum pump 22 installed inside the case 10 and connected to the decompression chamber 30 .

The auxiliary vacuum pump 22 is installed to be used alternately with the vacuum pump 20.

10: Case 12: Wheel
20: vacuum pump 22: auxiliary vacuum pump
30: decompression chamber 40: inlet
42: transfer pipe 50: sampler
60: Flow controller 62: Orifice
64: differential pressure sensor 66: temperature sensor
68: proportional control valve 70: controller

Claims (5)

A case provided with a wheel at a lower portion thereof,
A vacuum pump provided at an inner lower portion of the case,
A decompression chamber installed in an inner lower portion of the case and connected to the vacuum pump,
A plurality of inflow ports provided at a predetermined interval on the upper surface of the case and through which the air is introduced according to the operation of the vacuum pump,
A plurality of samplers installed in the case and connected to the inlet port and configured to collect an atmospheric sample as air flows through the inlet port;
A plurality of flow controllers installed inside the case and installed to control the flow rate of air flowing into and flowing into the inlet,
And a plurality of transfer conduits installed so that the atmosphere introduced into the inlet by the vacuum pump is sequentially transferred via the sampler and the flow controller.
The method according to claim 1,
Wherein the flow controller includes an orifice provided in the transfer conduit, a differential pressure sensor for measuring a pressure difference between a passage in front of the orifice of the transfer conduit and a rear passage, a temperature sensor for measuring a temperature on an inlet side of the transfer conduit, A proportional control valve installed to control the flow rate of the gas by changing the passage area of the gas, and a pressure difference measured by the differential pressure sensor and a temperature measured by the temperature sensor, And a controller for calculating the difference and outputting the flow difference as a control signal to the proportional control valve.
The method according to claim 1,
Wherein the plurality of samplers are configured to collect different types of chemical composition air samples.
The method according to claim 1 or 3,
Wherein the inlet port, the feed pipe, the sampler, and the flow controller are each provided with four air samplers.
The method according to claim 1,
Further comprising an auxiliary vacuum pump installed at an inner lower portion of the case and connected to the decompression chamber.

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