KR102184793B1 - Automatic GHG emission measurement system - Google Patents

Abstract

The present invention relates to a system for automatically measuring GHG emissions, and more particularly, a plurality of sample collection units installed to surround a target plant to periodically collect samples of surrounding gases, and gas collected from each sample collection unit. A gas analysis unit for analysis, a gas supply unit for sampling the gas samples collected from the sample collecting unit and injecting them to the gas analysis unit, and a gas sample collecting unit by controlling the sample collecting unit, and controlling the gas supply unit And a control unit for supplying the sampled gas to the gas analysis unit.
According to the present invention as described above, it is possible to improve analysis reliability by periodically collecting and automatically analyzing gas samples while the target plant is grown, and calibration is performed using a calibration gas and a calibration gas before analyzing the sample. To improve the work efficiency for sample analysis.

Description

Automatic GHG emission measurement system

The present invention relates to an automatic measurement system, and more specifically, a greenhouse capable of improving analysis reliability by periodically collecting and automatically analyzing gases generated in the vegetation process of a plurality of target plants, but performing dry calibration before analysis. It relates to an automatic measurement system for gas emissions.

In general, various pollutants are discharged from factories, homes, automobiles, etc. and spread into the air, causing air pollution. Such air pollution adversely affects human health and emotional life, threatens the survival of living organisms. It can even cause change.

As industrialization is accelerating in recent years, the pollution of the air is becoming more and more serious, so many countries around the world are making efforts to prevent air pollution by monitoring, managing, and supervising air pollution by measuring the level of air pollution.

To this end, the difference between the vacuum pressure in the chamber and the atmospheric pressure inside the sample collection bag installed inside the chamber, as disclosed in Patent Registration No. 10-0499726, to collect gas samples generated from the target object or plant. Contents of collecting samples by using are disclosed.

However, there is a problem in that the reliability of each material contained in the gas inside the chamber is not uniformly distributed.

In addition, depending on the state of the atmosphere, there is a problem that the effectiveness is very low, such as collecting a sample different from the actual atmospheric state because only a local part is collected rather than the whole.

In addition, there is a problem in that the reliability of the analysis is low because foreign substances are introduced or the pressure is not constant in the process of analyzing the collected sample.

Accordingly, development of a technology capable of improving the reliability of analysis by automatically collecting a plurality of samples to be collected periodically for a long period of time, preventing denaturation and mutation of samples, and automatically analyzing by maintaining a constant pressure. This is an urgent need.

Accordingly, the present invention has been devised to solve the above problems, and is installed to surround a target plant, and a plurality of sample collection units for periodically sampling the surrounding gas samples, and the gas collected from each sample collection unit A gas analysis unit for analysis, a gas supply unit for sampling the gas samples collected from the sample collecting unit and injecting them to the gas analysis unit, and a gas sample collecting unit by controlling the sample collecting unit, and controlling the gas supply unit Including the control unit for supplying the sampled gas to the gas analysis unit, it is possible to improve the analysis reliability by periodically collecting and automatically analyzing gas samples while the target plant is cultivated. The purpose of this study is to provide an automatic measurement system for greenhouse gas emissions that can improve the work efficiency of sample analysis by performing calibration using and calibration gas.

The present invention for achieving the above object is installed to surround a target plant, a plurality of sample collection units for periodically collecting ambient gas samples, a gas analysis unit for analyzing the gas collected from each of the sample collection units, the A gas supply unit for sampling the gas samples collected from the sample collection unit and injecting them into the gas analysis unit, and a gas sample by controlling the sample collection unit, and controlling the gas supply unit to collect the gas sampled by the gas analysis unit. It includes a control unit for supplying.

Preferably, a gas sample is periodically collected by the control unit and supplied to the gas analysis unit, thereby reducing the number of workers and costs, and improving work efficiency.

And having a sampling space therein so that the target plant is located, a sampling body installed on the terrain in which the target plants vegetation, and a sampling unit provided in the sampling body to collect gas present in the sampling space, and , The sampling body is installed from the time the target plant is young, and samples are periodically collected until the target plant is fully grown by the collection unit.

In addition, the sampling space part includes a lower sampling space part, an intermediate sampling space part, and an upper sampling space part.

In addition, the sampling body has the lower sampling space portion therein, a first-stage body installed on the terrain where the target plants vegetation, and a two-stage body provided on the upper side of the first-stage body. , Having the upper sampling space inside, a three-stage main body provided on the upper side of the two-stage main body, a main body connecting part interconnecting the first-stage main, second-stage, and third-stage main body, and opening and closing the upper sampling space upwardly It includes an upper door provided on the upper end of the first stage body, and a door driving part for operating the upper door.

In addition, each of the monoliths includes an upper frame forming an upper end of each of the sampling spaces, a lower frame formed at a predetermined interval below the upper frame to form a lower end of each of the sampling spaces, the upper frame and the lower frame It includes a vertical frame connecting each corner of the, and a panel provided between the upper frame, the lower frame, and the vertical frame to form a side surface of each of the sampling space.

And the main body connection portion, a first locking hole formed on the lower side of the upper frame of one monolith, and a second locking formed on the upper side of the lower frame of the other monolithic body positioned above the one monolithic body. It includes a ball, and a connection clip having elasticity, the first locking hole and the second locking jaw formed at both ends for each of the locking hole.

In addition, it further includes a sealing portion for sealing between the upper frame and the lower frame of the two adjacent single body.

And the sealing part, a first sealing installation groove formed at the lower end of the lower frame, a second sealing installation groove formed at the upper end of the upper frame to correspond to the first sealing installation groove, and the first sealing installation groove It includes a sealing installed in the second sealing installation groove.

In addition, the connection clip, a first locking jaw to be caught in the first locking hole, a second locking jaw to be caught in the second locking hole, and the lower end is connected to the first locking jaw, and the upper end is It includes a clip body connected to the second locking jaw and covering the outer side of the upper frame and the lower frame.

And the clip body is formed in a straight line.

In addition, the clip body is connected to the first clip body, the first clip body inclined outward toward the upper side, and the second clip body is connected to the second hook, and the first clip body is inclined toward the outside toward the lower side. It includes a second clip body to be connected.

And the clip body further includes a clip operation unit for deforming any one or more of the upper end and the lower end to open in opposite directions.

In addition, the clip operation unit is formed to protrude outside at least one of a lower end and an upper end of the clip body.

And the upper door, a door base frame provided to cross the middle of the upper frame of the three-tier body, a first upper door rotatably provided at one end of the door base frame to open and close a part of the upper sampling space. And a second upper door rotatably provided at the other end of the door base frame to open and close the rest of the upper sampling space.

In addition, the door driving unit may include a door moving frame positioned above the door base frame, a door driving cylinder provided on the door base frame to move the door moving frame in an up-down direction, and one end of the door moving frame It is rotatably connected and includes a driving link rotatably connected to each of the upper door at the other end, and when the door moving frame is moved upward by the door driving cylinder, each driving link is moved upward As a result, each upper door is rotated upward to open the sampling space, and when the door moving frame is moved downward by the door driving cylinder, each upper door rotates downward as each driving link is moved downward. And the sampling space is closed.

And the collection unit is provided in the first stage body, a first collection unit for collecting samples of the lower sampling space, a second collection unit provided in the second stage body to collect samples of the intermediate sampling space, and the third It is provided in the single body and includes a third collection unit for collecting a sample of the upper sampling space.

In addition, each of the collection units, the collection port is opened to the lower side, a plurality of collection bodies formed to increase the cross-sectional area toward the lower side, a mixing storage tank for collecting and mixing the gas collected from each of the collection bodies, each of the collection bodies And a suction pipe for communicating the collecting port of the mixed storage tank with the mixed storage tank, and a suction pump for suctioning the gas of the sampling space through the collecting port of each collecting body.

And the sampling port of the sampling body further includes a filter unit for filtering dust contained in the gas to be sucked.

In addition, before collecting the gas by the sampling unit, it further includes a circulation unit for circulating the gas of the sampling space unit.

In addition, the sampling unit and the circulation unit are controlled by the control unit, and the circulation unit is controlled to circulate the gas of the sampling space unit 1 to 3 minutes before sample collection by the collection unit.

In addition, the control unit controls at least one of the first collecting unit, the second collecting unit, and the third collecting unit to collect samples, respectively.

In addition, the control unit controls the door driving unit to open and close the upper door every 25 to 35 minutes.

In addition, the gas supply unit includes a sample mixing unit for mixing and discharging any one of the sampling gas, the calibration gas, and the calibration gas supplied from the sample collection unit, and discharges through the sample mixing unit. And a sample collection unit for collecting and sampling a predetermined amount of gas, and a sample injection unit for injecting any one of the ampoules of the gaseous collecting unit into the gas analysis unit.

In addition, the sample mixing unit includes a sample mixing housing having a mixing space part for filling the gas introduced therein, a calibration gas supply part for supplying a calibration gas for calibration to the mixing space part, and calibration of the gas analysis part to the mixed space part. A calibration gas supply unit for supplying a calibration gas for supply, a sample gas of the sample collection unit, a calibration gas of the calibration gas supply unit, and a calibration gas of the calibration gas supply unit into the mixing space unit of the sample mixing housing, A selection valve part for supplying the gas of the mixing space part to the sample collection part, and the selection valve part control the sample gas of the sample collection part, the calibration gas of the calibration gas supply part, and the calibration gas of the calibration gas supply part. And a selection valve control unit for supplying to the mixing space part of the mixing housing.

And the test gas supply unit includes a first test gas supply unit and a second test gas supply unit, and each of the test gas supply units includes a test gas container filled with a test gas inside, for storing the test gas at atmospheric pressure therein. A calibration gas storage unit, a calibration gas sensor for measuring the pressure of the calibration gas container, and a calibration gas for adjusting to atmospheric pressure when the calibration gas pressure of the calibration gas container is higher than atmospheric pressure by receiving a signal from the calibration gas sensor It includes a control unit.

In addition, the calibration gas supply unit includes a first calibration gas supply unit and a second calibration gas supply unit, and each of the calibration gas supply units includes a calibration gas container filled with calibration gas inside, and stores a calibration gas at atmospheric pressure therein. A calibration gas storage unit for measuring the pressure of the calibration gas container, a calibration gas sensor for measuring the pressure of the calibration gas container, and a calibration for adjusting to atmospheric pressure when the calibration gas pressure of the calibration gas tank is higher than atmospheric pressure by receiving a signal from the calibration gas sensor It includes a gas control unit.

And the calibration gas container and the calibration gas container is any one of a sample bag and a high-pressure gas cylinder.

In addition, the selection valve part, at least one sample gas valve for introducing the gas of the gas sample into the mixing space part, a first check valve for introducing the black gas of the first black gas supply part into the mixing space part, the A second calibration valve for introducing the calibration gas of the second calibration gas supply unit into the mixing space unit, a first calibration valve for introducing calibration gas from the first calibration gas supply unit into the mixing space unit, and the second calibration gas supply unit And a second calibration valve for introducing a calibration gas into the mixing space part, and a discharge valve for discharging the gas of the mixing space part to the sample collection part.

In addition, the mixing space part includes a first mixing space part and a second mixing space part, and in the sample mixing housing, any one of the gas of the gas sample and the calibration gas of the calibration gas supply part and the calibration gas of the calibration gas supply part flows in. A first mixing housing provided on the outside and a first mixing housing provided on the outside, and a gas mixed in the first mixing space inside and filled with the gas mixed in the first mixing space and discharged to the sample collection part. And a second mixing housing in which a second mixing space part is formed.

In addition, the sample collection unit may include a sample collection housing having a collection space therein, a sample inlet pipe for introducing gas into the collection space by being connected to a discharge valve of the selection valve unit, and supplied to the collection space through the sample inlet pipe. And a plurality of ampoules for storing a predetermined amount of gas, and a sample discharge pipe for discharging the gas collected in any one of the plurality of ampoules to the sample injection unit.

And it further includes a sample protection unit for preventing and minimizing the transformation and transformation of the gas of the collection space and the plurality of ampoules.

In addition, the sample protection unit has a sample protection space portion for accommodating the sample collection housing and a plurality of ampoules therein, a sample protection housing for isolation from ambient temperature, and ventilation of the gas of the sample protection space portion of the sample protection housing And a protective ventilation part for filtering the gas in the sample protection space part of the sample protection housing.

And the sample protection housing is a resin material formed by a combination of fluorine and carbon.

In addition, the sample protection housing is formed of Teflon.

In addition, the sample injection unit may include a rotatable sample injection housing, a plurality of entrances provided at regular intervals along the outer circumferential direction of the sample injection housing, and a plurality of samples to be moved or temporarily stored by alternately communicating two adjacent ones of the plurality of entrances. The formed movement path, a connection path for communicating two adjacent movement paths, a vacuum pumping part for suctioning gas by generating a vacuum by being connected to the entrance of the movement path connected by the connection path, and for rotating the sample injection housing It includes a rotation driving unit, and after suctioning and temporarily storing a sample of the sample collection unit by the vibration pump, it is injected and recovered to pass through the gas analysis unit through the corresponding entrance, and the sample injection housing is rotated by the rotation driving unit. An adjacent new moving path is connected to the gas analysis unit to perform analysis, and this is repeated.

In addition, the entrance includes a first entrance and a second entrance, a third entrance, a fourth entrance, a fifth entrance, and a sixth entrance, and the moving path is a second entrance connecting the second entrance and the third entrance. 1 movement path, a second movement path connecting the fourth inlet and the fifth inlet, and a third movement path connecting the sixth inlet and the first inlet, each of the passages being sampled by the vacuum pump. Is filled and sequentially connected to the gas analysis unit for analysis.

In addition, both ends of the connection path are connected to respective entrances so as to connect a movement path connected to the sample collection unit and another movement path connected to the vacuum pump, and the sample filled in the movement path not connected to the connection path is The sample is injected into the gas analysis unit through one of the entrances, and the sample passing through the gas analysis unit is moved to the corresponding movement through the other of the two entrances, and then, another adjacent movement path is connected to the gas analysis unit. Analyze the sample and repeat.

In addition, the vacuum pumping unit may include a vacuum pump for sucking gas from the moving path, a first vacuum inlet pipe communicating with the moving path, a second vacuum inlet pipe communicating with the vacuum pump, and discharging the gas to the outside. A vacuum discharge pipe, a vacuum valve for connecting the first vacuum inlet pipe and the second vacuum outlet pipe or connecting the second vacuum inlet pipe and the vacuum outlet pipe, and controlling the vacuum pump and the vacuum valve to control the flow of gas It includes a vacuum control unit.

And in a state in which the vacuum valve connects the first vacuum inlet pipe and the second vacuum inlet pipe, the vacuum pump is operated so that the sample to be analyzed is connected to the connection path and the first vacuum inlet pipe. And the second vacuum inlet pipe is sucked and filled, and the sample injection housing rotates while the operation of the vacuum pump is stopped to connect the moving path filled with the sample to be analyzed to the gas analysis unit and the analysis is completed. The moving path filled with the sample is connected to the first vacuum inlet pipe and discharged to the outside through the vacuum discharge pipe.

In addition, it further includes a moisture removal unit for removing moisture from the collected gas sample.

The moisture removal unit includes a gas cooling unit for first removing moisture by rapidly cooling the sample gas, and a gas heating unit for secondary removal of moisture by heating the moisture removed through the gas cooling unit.

As described above, according to the automatic GHG emission measurement system according to the present invention, a gas sample is periodically collected and automatically analyzed while the target plant is grown, thereby improving analysis reliability.

In addition, it is a very useful and effective invention to improve the work efficiency for sample analysis by performing calibration using a calibration gas and a calibration gas before analyzing a sample.

1 is a diagram showing a system for automatically measuring greenhouse gas emissions according to the present invention,
2 is a view showing a sample collection unit according to the present invention,
3 is a view showing a main body connection according to the present invention,
4 is a view showing an upper door and a door driving unit according to the present invention,
5 is a view showing another embodiment of a collection unit according to the present invention,
6 is a view showing each collection unit according to the present invention,
7 is a view showing a state in which the side door of the sample collecting unit according to the present invention is further provided,
8 is a view showing a gas supply unit according to the present invention,
9 is a view showing a sample mixing unit according to the present invention,
10 is a view showing a mixing space part of another embodiment according to the present invention,
11 is a view showing a sample collection unit according to the present invention,
12 is a view showing a sample injection unit according to the present invention,
13 is a view showing a moisture removal unit according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The detailed description to be disclosed hereinafter together with the accompanying drawings is intended to describe exemplary embodiments of the present invention, and is not intended to represent the only embodiments in which the present invention may be practiced. The following detailed description includes specific details to provide a thorough understanding of the present invention. However, those of ordinary skill in the art to which the present invention pertains knows that the present invention may be practiced without these specific details.

In some cases, in order to avoid obscuring the concept of the present invention, well-known structures and devices may be omitted, or may be shown in a block diagram form centering on core functions of each structure and device.

Throughout the specification, when a part is said to "comprising or including" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary. do. In addition, the term "... unit" described in the specification means a unit that processes at least one function or operation. In addition, "a or an", "one", "the" and similar related words are different from this specification in the context of describing the present invention (especially in the context of the following claims). Unless otherwise indicated or clearly contradicted by context, it may be used in a sense encompassing both the singular and the plural.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a system for automatically measuring greenhouse gas emissions according to the present invention, FIG. 2 is a view showing a sample collecting unit according to the present invention, and FIG. 3 is a view showing a main body connection unit according to the present invention, 4 is a view showing the upper door and the door driving unit according to the present invention, Figure 5 is a view showing another embodiment of the collection unit according to the present invention, Figure 6 is a view showing each collection unit according to the present invention, 7 is a view showing a state in which the side door of the sample collection unit according to the present invention is further provided, FIG. 8 is a view showing a gas supply unit according to the present invention, and FIG. 9 is a view showing a sample mixing unit according to the present invention. 10 is a view showing a mixing space unit according to another embodiment of the present invention, Fig. 11 is a view showing a sample collecting unit according to the present invention, and Fig. 12 is a view showing a sample injection unit according to the present invention 13 is a view showing a moisture removal unit according to the present invention.

As shown in the figure, the automatic GHG emission measurement system includes a sample collection unit 100, a gas analysis unit 200, a gas supply unit 300, and a control unit 400.

The sample collection unit 100 is installed to surround the target plant and is provided with a plurality of samples to periodically collect the surrounding gas samples.

And the gas analysis unit 200 is provided to analyze the gas collected from each sample collection unit 100.

The gas supply unit 300 is provided to sample the gas samples collected by the sample collection unit 100 and inject them into the gas analysis unit 200.

And the control unit 400 is provided to control the sample collecting unit 100 to collect a gas sample, and to control the gas supply unit 300 to supply the sampled gas to the gas analysis unit 200.

According to such an automatic GHG emission measurement system, in a state in which a plurality of sample collection units 100 are installed to surround the target plant, gas samples are periodically collected by the control unit 400 and are automatically sent to the gas analysis unit 200. To be supplied.

Accordingly, real-time and periodic measurements are possible, thereby improving inspection reliability, and reducing the number of workers and costs compared to the prior art, thereby improving work efficiency.

To this end, the sample collection unit 100 includes a sampling body 110 and a collection unit 120 as shown in FIG. 2.

The sampling body 110 has a sampling space part 102 inside so that the target plant is located, and is installed on the terrain where the target plant vegetation.

And the sampling unit 120 is provided in the sampling body 110 is provided to collect the gas existing in the sampling space unit 102.

Here, the sampling body 110 is installed from the time the target plant is young, and periodically collects a sample until the target plant is fully grown by the collection unit 120.

To this end, the sampling space unit 102 includes a lower sampling space part 102a, an intermediate sampling space part 102b, and an upper sampling space part 102c.

In addition, the sampling body 110 includes a first body 111 and a second body 112, a third body 113, a body connection 114, an upper door 115, and a door driving part 116.

The first stage body 111 has a lower sampling space portion 102a therein, and is installed on the terrain in which the target plant vegetation.

In addition, the two-stage body 112 has an intermediate sampling space portion 102b therein, and is provided on the upper side of the first-stage body 111.

The three-stage main body 113 has an upper sampling space portion 102c therein, and is provided on the upper side of the two-stage main body 112.

In addition, the main body connection portion 114 interconnects the first stage body 111, the second stage body 112, and the third stage body 113.

The upper door 115 is provided at the upper end of the first stage body 111 to open and close the upper sampling space 102c upwardly.

And the door drive unit 116 is provided to operate the upper door 115.

Each of these single bodies (111, 112, 113) is the upper frame (1112, 1122, 1132) and the lower frame (1114, 1124, 1134), vertical frames (1116, 1126, 1136) and panels (1118, 1128, 1138) Consists of

Upper frames 1112, 1122, 1132 form upper ends of each of the sampling space portions 102a, 112b, and 112c.

In addition, the lower frames 1114, 1124, and 1134 are formed to be spaced apart from the upper frames 1112, 1122, and 1132 at a predetermined interval to form the lower ends of each of the sampling spaces 102a, 112b, and 112c.

The vertical frames 1116, 1126, and 1136 connect each corner of the upper frames 1112, 1122, 1132 and the lower frames 1114, 1124, 1134.

And the panel (1118, 1128, 1138) is provided between the upper frame (1112, 1122, 1132), the lower frame (1114, 1124, 1134), the vertical frame (1116, 1126, 1136), each sampling space (102a, 112b, 112c) are provided to form side surfaces.

Here, the main body connection portion 114 is composed of a first locking hole 1142, a second locking hole 1144 and a connection clip 1146, as shown in FIG.

The first locking hole 1142 is formed on the lower side of the upper frame 1112, 1122, 1132 of any one single body (111, 112, 113).

In addition, the second locking hole 1144 is formed on the upper side of the lower frame 1124 of the other single body 112 located on the upper side of one single body 111.

The connection clip 1146 has elasticity, and locking projections 1146a and 1146b for engaging the first locking hole 1142 and the second locking hole 1144, respectively, are formed at both ends.

The connection clip 1146 is composed of a first locking jaw (1146a), a second locking jaw (1146b) and a clip body (1146c).

The first locking jaw 1146a is provided to be caught in the first locking hole 1142.

And the second locking jaw (1146b) is provided to be caught in the second locking hole (1144).

Clip body (1146c) is connected to the lower end of the first engaging jaw (1146a), the upper end is connected to the second locking jaw (1146b), corresponding upper frames (1112, 1122, 1132) and lower frames (1114, 1124, 1134) ) Is provided to cover the outside.

This clip body (1146c) is formed in a straight line so as to contact the outer surfaces of the upper frame and the lower frame.

On the other hand, the clip body (1146c) includes a first clip body (1146c-1) and a second clip body (1146c-2).

The first clip body 1146c-1 is connected to the first engaging jaw 1146a, and is formed to be inclined to the outside as it goes upward.

And the second clip body (1146c-2) is connected to the second locking jaw (1146b), and is connected to the first clip body (1146c-1) inclined outward toward the lower side.

The clip bodies 1146c-1 and 1146c-2 of each of these embodiments further include a clip operation unit 1148.

The clip manipulation unit 1148 is provided to deform one or more of the upper and lower ends of the clip bodies 1146c-1 and 1146c-2 in each embodiment to be wide open in opposite directions.

The clip operation unit 1148 is formed to protrude outside at least one of the lower end and the upper end of the clip bodies 1146c-1 and 1146c-2.

The operator grips the protruding clip operation unit 1148 and deforms the clip bodies 1146c-1 and 1146c-2 so that the locking jaws 1146a and 1146b can be seated or separated from the locking holes 1142 and 1144. I can.

And it further includes a sealing portion 117 for sealing between the upper frame 1112 and the lower frame 124 of the two adjacent single body (111, 112).

The sealing part 117 is composed of a first sealing installation groove 1172, a second sealing installation groove 1174 and a sealing 1176.

The first sealing installation groove 1172 is formed at the lower end of the lower frames 1114, 1124, 1134 of the unit body 111, 112, 113.

In addition, the second sealing installation groove 1174 is formed at the upper end of the upper frame (1112, 1122, 1132) of the unit body (111, 112, 113) to correspond to the first sealing installation groove (1172).

The sealing 1176 is installed in the first sealing installation groove 1172 and the second sealing installation groove 1174.

In addition, the upper door 115 includes a door base frame 1152, a first upper door 1154 and a second upper door 1156, as shown in FIG. 4.

The door base frame 1152 is provided so as to cross the middle of the upper frame 1132 of the three-stage body 113.

In addition, the first upper door 1154 is rotatably provided at one end of the door base frame 1152 to open and close a part of the upper sampling space 102c.

The second upper door 1156 is rotatably provided at the other end of the door base frame 1152 to open and close the rest of the upper sampling space 102c.

In addition, the door driving unit 116 includes a door moving frame 1162, a door driving cylinder 1164 and a driving link 1166.

The door moving frame 1162 is located above the door base frame 1152.

In addition, the door driving cylinder 1164 is provided on the door base frame 1152 and is provided to move the door moving frame 1162 in the vertical direction.

One end of the driving link 1166 is rotatably connected to the door moving frame 1162, and the other end is rotatably connected to each of the upper doors 1154 and 1156, respectively.

Looking at the operating state of the upper door 115 by the door driving unit 116, when the door moving frame 1162 is moved upward by the door driving cylinder 1164, each driving link 1166 moves upward. Accordingly, each of the upper doors 1154 and 1156 is rotated upward to open the sampling space 102.

Conversely, when the door moving frame 1162 is moved downward by the door driving cylinder 1164, as each driving link 1166 is moved downward, each upper door 1154, 1156 is rotated downward and sampled. The space 102 is closed.

And, as shown in Figure 5, the collecting unit 120 is composed of a first collecting unit 121, a second collecting unit 122, and a third collecting unit 123.

The first collecting part 121 is provided in the first stage body 111 and provided to collect a sample of the lower sampling space part 102a.

In addition, the second collection unit 122 is provided in the two-stage body 112 and is provided to collect a sample of the intermediate sampling space unit 102b.

The third collecting unit 123 is provided in the three-stage body 113 and provided to collect a sample of the upper sampling space unit 102c.

Each of the first collecting unit 121, the second collecting unit 122, and the third collecting unit 123 are, as shown in FIG. 6, the collecting bodies 1212, 1222, 1232 and the mixed storage tank 1214, 1224, 1234), suction pipes 1216, 1226, 1236, and suction pumps 1218, 1228, 1238.

Here, since the first collecting unit 121, the second collecting unit 122, and the third collecting unit 123 have the same configuration, it will be described as the third collecting unit 123.

The collecting body 1232 is formed in a plurality, and the collecting port 1233 is opened downward, and the cross-sectional area increases toward the lower side.

And the mixed storage tank 1234 is provided to collect and mix the gas collected from the sampling body 1232.

The suction pipe 1236 is provided to communicate the collecting port 1233 of the collecting body 1232 and the mixed storage tank 1234.

In addition, the suction pump 1238 is provided to suck the gas of the sampling space 102 through the sampling port 1233 of the sampling body 1232.

Here, each of the collection units 121, 122, 123 is further provided with a filter unit 124.

The filter unit 124 is provided in the collecting port 1233 of the collecting body 1232 and provided to filter the dust contained in the inhaled gas.

And before collecting the gas by the sampling unit 120, further includes a circulation unit 130 for circulating the gas in the sampling space unit 102.

The collection unit 120 and the circulation unit 130 are controlled by the control unit 400.

The control unit 400 controls the circulation unit 130 to circulate the gas in the sampling space unit 102 1 to 3 minutes before sample collection by the collection unit 120.

Accordingly, as the components included in the gas of the sampling space 102 are uniformly distributed throughout, the effectiveness of the sample may be improved.

In addition, the control unit 400 controls one or more of the first collecting unit 121, the second collecting unit 122, and the third collecting unit 123 to collect samples, respectively.

Accordingly, samples of the lower sampling space 102a, the intermediate sampling space 102b, and the upper sampling space 102c can be respectively collected, so that the samples can be collected by height.

In addition, the control unit 400 controls the door driving unit 116 to open and close the upper doors 1154 and 1156 every 25 to 35 minutes.

Accordingly, the sampling space unit 102 is ventilated to prevent the sampling of an incorrect sample.

In addition, as shown in FIG. 7, the sample collecting unit 100 is further provided with a side door 180.

At least one side door 180 is provided on the side of the sampling body 110 to open and close the sampling space 102 in the lateral direction.

Accordingly, external air may be introduced or discharged in the lateral direction, and the sampling unit 120 located in the sampling space unit 102 may be managed.

This side door 180 is rotated by a hinge or slid by a rail, it is natural that it can be automatically opened and closed by a motor and a cylinder.

In addition, the gas analysis unit 200 includes a gas chromatograph, a pump, a mass flow controller, a chromatograph, a gas pressure regulator, and a check valve.

In the gas chromatograph, a column may be used to analyze the components of the injected gas, and since it is already applied to the industrial field, a more detailed description will be omitted.

In addition, as shown in FIG. 8, the gas supply unit 300 includes a sample mixing unit 500, a sample collection unit 600, and a sample injection unit 700.

The sample mixing unit 500 is provided to introduce any one of the sampling gas, the calibration gas, and the calibration gas supplied from the sample collection unit 110, and then mix and discharge the sample.

In addition, the sample collection unit 600 has a plurality of ampoules 324, and collects a predetermined amount of gas discharged through the sample mixing unit 310 to sample.

The sample injection unit 700 is provided to inject any one gas from the ampoules 324 of the sample collection unit 320 into the gas analysis unit 200.

To this end, the sample mixing unit 500 is a sample mixing housing 510 and a calibration gas supply unit 520, a calibration gas supply unit 530, a selection valve unit 540 and a selection valve control unit ( 550).

The sample mixing housing 510 has a mixing space part 512 for filling the gas introduced therein.

And the calibration gas supply unit 520 is provided to supply the calibration gas for calibration to the mixing space (512).

The calibration gas supply unit 530 is provided to supply a calibration gas for calibration of the gas analysis unit 200 to the mixing space unit 512.

In addition, the selection valve part 540 is the mixing space part 512 of the sample mixing housing 510, and the sample gas of the sample collection part 100 and the calibration gas of the calibration gas supply part 520, and the calibration of the calibration gas supply part 530 It is provided to introduce any one of the gases and to supply the gas from the mixing space part 512 to the sample collection part 320.

The selection valve control unit 550 controls the selection valve unit 540 to transfer any one of the sample gas of the sample collecting unit 100, the calibration gas of the calibration gas supply unit, and the calibration gas of the calibration gas supply unit of the sample mixing housing 510. It is provided to supply to the mixing space (512).

Here, the calibration gas and the calibration gas use a standard gas, and the standard gas consists of a gas containing the component to be analyzed at a certain molar fraction concentration, and creates and calibrates the standard for interpreting the results of the gas analyzer 200 It is used to

In the actual analysis, the molar fraction concentration of the gas sample can be quantitatively calculated by comparing the two results after testing the standard gas and the gas sample.

In addition, the calibration gas supply unit 520 includes a first black gas supply unit 522 and a second black gas supply unit 524.

Each of the test gas supply units 522 and 524 has the same configuration, and will be described as a first test gas supply unit 522, and the test gas container 5222, the test gas storage unit 5224, and the test gas sensor 5226 , And black gas control unit 5228.

The black gas container 5222 is filled with black gas therein.

In addition, the calibration gas storage unit 5224 is provided to store the calibration gas at atmospheric pressure therein.

The calibration gas sensor 5226 is provided to measure the pressure in the calibration gas container 5222.

In addition, the calibration gas control unit 5228 is provided to adjust to atmospheric pressure when the calibration gas pressure of the calibration gas container 5222 is higher than atmospheric pressure by receiving a signal from the calibration gas sensor 5226.

In addition, the calibration gas supply unit 530 includes a first calibration gas supply unit 532 and a second calibration gas supply unit 534.

Each of the calibration gas supply units 532 and 534 has the same configuration, and will be described as the first calibration gas supply unit 532, and the calibration gas container 5322, the calibration gas storage unit 5324, and the calibration gas sensor 5326 And a calibration gas control unit 5328.

The calibration gas container 5322 is filled with calibration gas.

And the calibration gas storage unit 5324 is provided to store the calibration gas at atmospheric pressure therein.

The calibration gas sensor 5326 is provided to measure the pressure of the calibration gas container 5322.

In addition, the calibration gas control unit 5328 is provided to adjust to atmospheric pressure when the calibration gas pressure of the calibration gas container 5322 is higher than atmospheric pressure by receiving a signal from the calibration gas sensor 5326.

Here, the calibration gas container 5222 and the calibration gas container 5322 are either a sample bag or a high-pressure gas cylinder.

This sample bag is a container in which gas samples are stored, and the gas can be manually collected using a fluorine-based polymer resin bag on a portable basis.

In addition, the selection valve unit 540 includes sample gas valves 541 and 542, a first check valve 543, a second check valve 544, a first calibration valve 545, and a discharge valve 547.

The sample gas valves 541 and 542 are provided with at least one for introducing the gas of the gas sample into the mixing space unit 512, and include a first sample gas valve 541 and a second sample gas valve 542 do.

In addition, the first check valve 543 is provided to introduce the black gas from the first black gas supply unit 522 into the mixing space unit 512.

The second check valve 544 is provided to introduce the black gas from the second black gas supply unit 524 into the mixing space part 512.

In addition, the first calibration valve 545 is provided to inflow the calibration gas of the first calibration gas supply unit 532 into the mixing space unit 512.

The second calibration valve 546 is provided to inflow the calibration gas of the second calibration gas supply unit 534 into the mixing space unit 512.

In addition, the discharge valve 547 is provided to discharge the gas from the mixing space part 512 to the sample collection part 320.

Here, the first sample gas valve 541 and the second sample gas valve 542, the first check valve 543, the second check valve 544, the first calibration valve 545 and the second calibration valve 546 ), as only one of them is open and the others are closed, only one open gas is introduced into the mixing space part 512.

Further, the discharge valve 547 is kept open to discharge the mixed gas.

Meanwhile, as shown in FIG. 10, in another embodiment, the mixing space part 512 includes a first mixing space part 512a and a second mixing space part 512b.

In addition, the sample mixing housing 510 includes a first mixing housing 512 and a second mixing housing 514.

The first mixing housing 512 has a first mixing space part 512a into which any one of the gas of the gas sample, the calibration gas of the calibration gas supply unit 520 and the calibration gas of the calibration gas supply unit 530 is introduced, and the outer side It is equipped with.

In addition, the second mixing housing 514 is located inside the first mixing housing 512 so that the gas mixed in the first mixing space 512a is filled therein and discharged to the sample collecting unit 320. A space part 512b is formed.

The sample collection unit 600 includes a sample collection housing 610, a sample inlet pipe 620, an ampoule 630, and a sample discharge pipe 640, as shown in FIG. 11.

The sample collection housing 610 has a collection space 611 formed therein.

Further, the sample inlet pipe 620 is connected to the discharge valve 547 of the selection valve unit 540 and is provided to introduce gas into the collection space unit 611.

A plurality of ampoules 630 are provided, and are provided to collect and store a predetermined amount of gas supplied to the collection space 611 through the sample inlet pipe 620.

In addition, the sample discharge pipe 640 is provided to discharge the gas collected in any one of the plurality of ampoules 630 to the sample injection unit 700.

Here, the sample collection unit 600 further includes a sample protection unit 650.

The sample protection unit 650 is provided to prevent and minimize the gas of the collection space unit 611 and the plurality of ampoules 630 from being denatured and transformed.

The sample protection unit 650 includes a sample protection housing 652, a protection ventilation unit 654, and a protection purification unit 656.

The sample protection housing 652 has a sample protection space portion 653 for accommodating the sample collection housing 610 and a plurality of ampoules 630 therein, and is provided to isolate it from the ambient temperature.

In addition, the protective ventilation unit 654 is provided to ventilate the gas in the sample protection space portion 653 of the sample protection housing 652.

The protection and purification unit 656 is provided to filter the gas in the sample protection space 653 of the sample protection housing 652.

Here, the sample protection housing 652 is a resin material formed by a combination of fluorine and carbon, and, as an example, is formed of Teflon.

In addition, as shown in FIG. 12, the sample injection unit 700 includes a sample injection housing 710 and an entrance 720, a moving path 730, a connection path 740, a vacuum pumping unit 750, and a rotation drive unit. 760)

The sample injection housing 710 is rotatably provided.

In addition, a plurality of entrances 720 are provided at regular intervals along the outer circumferential direction of the sample injection housing 710.

A plurality of moving paths 730 are formed so that the sample is moved or temporarily stored by alternately communicating two adjacent ones of the plurality of entrances 720.

In addition, the connection path 740 is provided to communicate two adjacent movement paths 730.

The vacuum pumping unit 750 is connected to the entrance of the moving path 730 connected by the connection path 740 to generate a vacuum to suck gas.

In addition, the rotation driving unit 760 is provided to rotate the sample injection housing 710.

Looking at the operating state of the sample injection unit 700, the sample from the sample collection unit 600 is sucked and temporarily stored by the vibration pump 750, and then injected to pass through the gas analysis unit 200 through the corresponding entrance and Is recovered.

In addition, the sample injection housing 710 is rotated by the rotation driving unit 760 so that the adjacent new moving path is connected to the gas analysis unit 200 to perform analysis, and this is repeated.

Here, as an example, the entrance 720 includes a first entrance 721 and a second entrance 722, a third entrance 723, a fourth entrance 724, a fifth entrance 725, and a sixth entrance ( 726).

In addition, the moving path 730 includes a first moving path 731, a second moving path 732, and a third moving path 733.

The first transfer route 731 connects the second entrance 722 and the third entrance 723, the second transfer route 732 connects the fourth entrance 724 and the fifth entrance 725, The third transfer path 733 connects the sixth entrance 726 and the first entrance 721.

Each of these moving paths 731, 732, 733 is connected to the gas analysis unit 200 by a sample injection housing 710 that is sequentially rotated by filling a sample by a vacuum pump 750 and analyzed.

In addition, the connection path 740 is connected at both ends to the respective entrances 723 and 725 so as to connect the moving path 731 connected to the sample collection unit 600 and the other moving path 732 connected to the vacuum pump 750. Is made to communicate with each of the moving paths 731 and 732.

The sample filled in the moving path 733 not connected to the connection path 740 is injected into the gas analysis unit 200 through one of the two entrances 721 and 726, and the gas analysis unit 200 The passed sample is moved to the corresponding movement path 733 through the other one of the two entrances 721 and 726.

Thereafter, the sample injection housing 710 is rotated by the rotation driving unit 760 so that another adjacent moving path 731 is connected to the gas analysis unit 200 to analyze the sample, and repeat this.

The vacuum pumping unit 750 includes a vacuum pump 751, a first vacuum inlet pipe 752, a second vacuum outlet pipe 753, a vacuum outlet pipe 754, a vacuum valve 755, and a vacuum control unit 756. do.

The vacuum pump 751 is provided to suck gas from the moving path 730.

In addition, the first vacuum inlet pipe 752 communicates with the moving path 730, and the second vacuum inlet pipe 753 communicates with the vacuum pump 751.

The vacuum discharge pipe 754 is provided to discharge gas to the outside.

In addition, the vacuum valve 755 connects any two of the first vacuum inlet pipe 752, the second vacuum outlet pipe 753 and the vacuum outlet pipe 754.

In other words, the vacuum valve 755 is provided to connect the first vacuum inlet pipe 752 and the second vacuum outlet pipe 753 or to connect the second vacuum outlet pipe 753 and the vacuum outlet pipe 754.

The vacuum controller 756 is provided to control the flow of gas by controlling the vacuum pump 751 and the vacuum valve 755.

Looking at the operating state of the vacuum pumping unit 750, the vacuum pump 751 is operated in a state in which the vacuum pump 751 connects the first vacuum inlet pipe 752 and the second vacuum inlet pipe 753 The sample to be analyzed is sucked and filled into the two moving paths 731 and 733 communicated through the connection path 740, the first vacuum inlet and outlet pipe 752 and the second vacuum inlet and outlet pipe 753.

And while the operation of the vacuum pump 751 is stopped, the sample injection housing 710 rotates to connect the moving path filled with the sample to be analyzed to the gas analysis unit 200, and at the same time, the sample filled with the analyzed sample is moved. The furnace is connected to the first vacuum inlet pipe 752 and discharged to the outside through the vacuum outlet pipe 754.

And, as shown in Figure 13, the greenhouse gas emission automatic measurement system further includes a moisture removal unit (800).

This moisture removal unit 800 is provided to remove moisture from the collected gas sample.

The moisture removal unit 800 includes a gas cooling unit 810 and a gas heating unit 820.

The gas cooling unit 810 is provided to first remove moisture by rapidly cooling the sample gas.

In addition, the gas heating unit 820 is provided to heat the moisture removed through the gas cooling unit 810 to secondarily remove the moisture.

Accordingly, by removing moisture contained in the gas, the inspection accuracy can be improved.

100: sample collection unit 110: sampling body
120: sampling unit 200: gas analysis unit
300: gas supply unit 400: control unit
500: sample mixing unit 510: sample mixing housing
520: calibration gas supply unit 530: calibration gas supply unit
540: selection valve unit 550: selection valve control unit
600: sample collection unit 610: sample collection housing
620: sample inlet pipe 630: ampoule
640: sample discharge pipe 700: sample injection part
800: moisture removal unit

Claims (13)

A plurality of sample collection units installed to surround a target plant and periodically collecting samples of surrounding gases;
A gas analysis unit for analyzing the gas collected from each of the sample collection units;
A gas supply unit for sampling the gas samples collected from the sample collecting unit and injecting them into the gas analysis unit; And
And a control unit for controlling the sample collection unit to collect a gas sample, and controlling the gas supply unit to supply sampled gas to the gas analysis unit, and
The sample collection unit,
A sampling body having a sampling space therein so that a target plant is located, and installed on a terrain in which the target plant vegetation; And
Includes; a sampling unit provided in the sampling body for collecting the gas present in the sampling space,
The sampling body is installed from the time the target plant is young, and periodically collects samples until the target plant is fully grown by the control unit,
The sampling body,
A single-stage body having a lower sampling space therein and installed on the terrain in which the target plant vegetation;
A two-stage body having an intermediate sampling space therein and provided on an upper side of the first-stage body;
A three-stage body having an upper sampling space therein and provided on the upper side of the two-stage body;
A main body connecting portion interconnecting the first, second, and third stages;
An upper door provided at an upper end of the first stage body to open and close the upper sampling space portion upwardly; And
Includes; a door driving unit for operating the upper door,
Each of the above monoliths,
An upper frame forming an upper end of each of the sampling spaces;
A lower frame formed to be spaced apart at predetermined intervals under the upper frame to form a lower end of each of the sampling spaces;
A vertical frame connecting each corner of the upper frame and the lower frame; And
Includes; a panel provided between the upper frame, the lower frame, and the vertical frame to form side surfaces of each of the sampling spaces,
The main body connection part,
A first locking hole formed on the lower side of the upper frame of any one single body;
A second locking hole formed on the upper side of the lower frame of the other single body located on the upper side of the single body; And
A system for automatically measuring greenhouse gas emissions comprising: a connecting clip having elasticity and having a locking jaw formed at both ends of each of the first and second locking holes. delete delete The method of claim 1, wherein the upper door,
A door base frame provided to cross the middle of the upper frame of the three-tier body;
A first upper door rotatably provided at one end of the door base frame to open and close a portion of the upper sampling space; And
2nd upper door rotatably provided at the other end of the door base frame to open and close the rest of the upper sampling space. The method of claim 1, wherein the gas supply unit,
A sample mixing unit for temporarily storing and discharging any one of the sampling gas supplied from the sample collecting unit, the calibration gas and the calibration gas;
A sample collection unit having a plurality of ampoules and collecting a predetermined amount of gas discharged through the sample mixing unit and forming a sample; And
Automatic GHG emission measurement system comprising a; sample injection unit for injecting any one gas of the ampoule of the sample collection unit into the gas analysis unit. The method of claim 5, wherein the sample mixing unit,
A sample mixing housing having a mixing space for filling the gas introduced therein;
A calibration gas supply unit for supplying a calibration gas for calibration to the mixing space;
A calibration gas supply unit for supplying a calibration gas for calibration of the gas analysis unit to the mixing space unit;
Injecting one of the sample gas of the sample collection unit, the calibration gas of the calibration gas supply unit, and the calibration gas of the calibration gas supply unit into the mixing space unit of the sample mixing housing, and supplying the gas of the mixing space unit to the sample collection unit A selection valve unit for; And
Greenhouse gas comprising: a selection valve control unit for controlling the selection valve unit to supply any one of the sample gas of the sample collection unit, the calibration gas of the calibration gas supply unit, and the calibration gas of the calibration gas supply unit to the mixing space unit of the sample mixing housing; Automatic emission measurement system. The method of claim 6,
The calibration gas supply unit,
Including a first black gas supply and a second black gas supply,
Each of the test gas supply units,
Black gas container filled with black gas inside;
A calibration gas storage unit for storing a calibration gas at atmospheric pressure therein;
A calibration gas sensor for measuring the pressure of the calibration gas container; And
When receiving the signal from the calibration gas sensor, when the calibration gas pressure of the calibration gas container is higher than atmospheric pressure, a calibration gas control unit configured to adjust to atmospheric pressure; The method of claim 7,
The calibration gas supply unit,
Including a first calibration gas supply and a second calibration gas supply,
Each of the calibration gas supply units,
Calibration gas container filled with calibration gas inside;
Calibration gas storage unit for storing the calibration gas at atmospheric pressure therein;
A calibration gas sensor for measuring the pressure of the calibration gas container; And
When the calibration gas pressure of the calibration gas tank is higher than atmospheric pressure by receiving the signal from the calibration gas sensor, a calibration gas control unit for adjusting to atmospheric pressure; The method of claim 8, wherein the selection valve unit,
At least one sample gas valve for introducing the gas of the gas sample into the mixing space;
A first check valve for introducing the test gas from the first black gas supply part into the mixing space part;
A second check valve for introducing the test gas from the second black gas supply part into the mixing space part;
A first calibration valve for introducing the calibration gas of the first calibration gas supply unit into the mixing space;
A second calibration valve for introducing the calibration gas from the second calibration gas supply unit into the mixing space; And
Automatic GHG emission measurement system comprising a; discharge valve for discharging the gas from the mixing space to the sample collection unit. The method of claim 9, wherein the sample collection unit,
A sample collection housing having a collection space therein;
A sample inlet pipe connected to the discharge valve of the selection valve part to introduce gas into the collection space part;
A plurality of ampoules for storing a predetermined amount of gas supplied to the collection space through the sample inlet pipe; And
Automatic GHG emission measurement system comprising a; sample discharge pipe for discharging the gas collected in any one of the plurality of ampoules to the sample injection unit. The method of claim 5,
A water removal unit for removing moisture from the collected gas sample; greenhouse gas emission automatic measurement system further comprising. delete delete

Images