KR20130076775A - Exhaust gas analyzer and drain separator - Google Patents

Abstract

PURPOSE: An exhaust gas analyzing device and a drain separator are provided to prevent the penetration of the water stagnated in a gas-liquid separating chamber into an exhaust-gas outflow path discharging exhaust gas, in which gas and moisture are separated, from the gas-liquid separating chamber. CONSTITUTION: An exhaust gas analyzing device includes a gas-liquid separating chamber (41), an exhaust-gas inflow path (42), an exhaust-gas outflow path (43), and a drain (44). The gas-liquid separating chamber separates moisture contained in the exhaust gas. The exhaust-gas inflow path includes an exhaust gas inlet (42x) arranged on a lateral wall (401) forming the gas-liquid separating chamber and makes the exhaust gas flow into the gas-liquid separating chamber. The exhaust-gas outflow path includes an exhaust gas outlet (43x) arranged on the other lateral wall (402) forming the gas-liquid separating chamber and guides the exhaust gas in which gas and moisture are separated by the gas-liquid separating chamber to an analyzing device. The drain includes a drainage hole arranged on a portion of the lateral wall lower than the exhaust gas outlet and discharges the separated moisture to the outside.

Description

Exhaust Gas Analyzer and Drain Separator {EXHAUST GAS ANALYZER AND DRAIN SEPARATOR}

The present invention relates to an exhaust gas analyzer for analyzing a component contained in exhaust gas such as, for example, engine exhaust gas, and more particularly, to a drain separator used in the exhaust gas analyzer.

Conventionally, in the exhaust gas analyzer which analyzes the component in engine exhaust gas, as shown in patent document 1, it includes in exhaust gas in the front end which introduces waste gas into the analyzer which comprises the said exhaust gas analyzer. A drain separator for removing moisture such as steam or water is provided.

Since the exhaust gas analyzer is required to have good responsiveness, the drain separator needs to improve the gas replacement efficiency. For this reason, it is necessary for the drain separator to have high gas-liquid separation ability at a small capacity.

For example, as a drain separator incorporated in a conventional exhaust gas analyzer, a gas-liquid separation chamber, an exhaust gas introduction path for introducing exhaust gas into the gas-liquid separation chamber, and a gas-liquid separated exhaust gas, as shown in FIG. There is an exhaust gas deriving furnace leading to the analyzer, and a drain passage for discharging the gas-liquid separated water to the outside. An exhaust gas introduction passage is formed on one side of the opposing side wall of the gas-liquid separation chamber, and an exhaust gas outlet passage and a drainage passage are formed on the other side of the opposing side wall. Further, a suction pump is provided on the downstream side of the drainage passage, and is configured to discharge the accumulated water and the like in the gas-liquid separation chamber from the drainage passage.

In addition, due to the request for downsizing of the exhaust gas analyzer, the suction pump incorporated in the exhaust gas analyzer is also downsized. When the suction pump is downsized in this manner, the suction capacity of the suction pump is reduced, and the flow rate that can be drained by the drainage passage is reduced.

In this way, when the suction capacity of the suction pump is small and the rate at which water collects in the gas-liquid separation chamber is faster than the suction rate at which water is sucked from the gas-liquid separation chamber, the water flows from the gas-liquid separation chamber to the position where the exhaust gas discharge path is provided. As a result, there is a problem that water infiltrates into the exhaust gas outlet. This problem is particularly remarkable since the moisture in the exhaust gas increases with the recent improvement in the combustion efficiency of the engine. Moreover, when using in the place where the ambient temperature is low, since the water vapor | condensation contained in exhaust gas condenses and it uses in the place where the ambient temperature is high, since the quantity of the water which accumulates in gas-liquid separation chamber increases more, the said The problem becomes noticeable.

[Patent Document 1] Japanese Patent Application Laid-Open No. 2006-10555

Thus, the present invention has been made to solve the above problems at once, making it difficult to infiltrate the water accumulated in the gas-liquid separation chamber into the exhaust gas deriving path leading the gas-liquid separated exhaust gas to the analyzer, and the gas-liquid separation chamber The main scavenging task is to prevent water droplets falling from the upper surface of the surface from penetrating.

That is, the exhaust gas analyzer according to the present invention has a gas-liquid separation chamber that separates moisture contained in the exhaust gas, and an exhaust gas inlet provided at one side wall that forms the gas-liquid separation chamber. An exhaust gas introduction path for introducing gas into the gas-liquid separation chamber, and an exhaust gas outlet provided on the side wall of the other side forming the gas-liquid separation chamber, and exhaust gas separated by the gas-liquid separation chamber from the gas-liquid separation chamber. An exhaust gas discharge path for guiding the gas to an analyzer and a drain hole provided below the exhaust gas discharge port at a side wall forming the gas liquid separation chamber, and a drain path for discharging water separated by the gas liquid separation chamber to the outside; The exhaust gas outlet port side of the exhaust gas outlet is bent upward from the inside of the gas-liquid separation chamber, the exhaust gas outlet port side or It is open toward downward. It is characterized by the above-mentioned.

In this case, since the exhaust gas outlet port side of the exhaust gas outlet path is bent upward in the gas-liquid separation chamber, the position of the exhaust gas outlet port can be provided above the position of the conventional exhaust gas outlet port, Water accumulated in the gas-liquid separation chamber may make it difficult to enter the exhaust gas outlet. In addition, the flow path on the downstream side other than the exhaust gas deriving passage side to the exhaust gas deriving passage side can be made to have the same configuration as the conventional one, and there is no need to change the piping configuration to the analyzer from the conventional one. . Here, as a configuration that makes it difficult to infiltrate water into the exhaust gas outlet, it is conceivable to bend the exhaust gas outlet side toward the exhaust gas outlet upward and to open the exhaust gas outlet upwards. Condensation or water droplets condensed on the upper surface of the chamber may fall and invade the exhaust gas outlet. In this respect, in the present invention, since the exhaust gas outlet port is opened toward the side or the bottom, water droplets condensed or adhered to the upper surface of the gas-liquid separation chamber can be prevented from entering the exhaust gas outlet passage.

It is preferable that the exhaust gas inlet is open toward the side wall of the other side of the gas-liquid separation chamber, and the exhaust gas inlet is open toward the direction along the opening direction of the exhaust gas inlet. In this way, the exhaust gas introduced into the gas-liquid separation chamber from the exhaust gas introduction passage can be prevented from directly intruding into the exhaust gas derivation passage, thereby further improving the gas-liquid separation performance, and also introduced into the gas-liquid separation chamber from the exhaust gas introduction passage. Dirt contained in the exhaust gas can easily accumulate in the gas-liquid separation chamber, making it difficult to invade the analyzer from the exhaust gas outlet.

In order to realize the structure of the present invention without changing the configuration of the drain separator incorporated in the conventional exhaust gas analyzer, the side wall flow passage formed on the other side wall forming the gas-liquid separation chamber is provided. An inner flow passage having a bent shape formed by a flow path forming member mounted to the gas-liquid separation chamber side opening of the side wall flow passage, wherein one opening of the inner flow passage communicates with the side wall flow passage, It is preferable that the opening on the side serves as the exhaust gas outlet. In this case, simply mounting the flow path forming member on the side wall flow passage (corresponding to the conventional exhaust gas discharge passage), bending the exhaust gas outlet side of the exhaust gas discharge passage upward, It can be configured to face downward.

In order to improve the gas-liquid separation performance by preventing water splashed by the exhaust gas flowing into the gas-liquid separation chamber from entering the exhaust gas discharge path, the exhaust gas is discharged to the downstream side of the exhaust gas inlet in the gas-liquid separation chamber. It is preferable that an intrusion prevention plate is provided to prevent water scattered by the exhaust gas flowing in from the gas introduction path from entering the exhaust gas discharge path. In addition, when the exhaust gas comes into contact with the intrusion prevention plate, it is easy to separate the moisture contained in the exhaust gas from the exhaust gas.

The block forming the gas-liquid separation chamber is divided into a first block element including the one side wall and a second block element including the other side wall, and the exhaust gas introduction passage is formed in the first block element. The sidewall flow path and the drainage path are formed in the second block element, and the flow path forming member is mounted in the gas-liquid separation chamber side opening of the sidewall flow path formed in the second block element. In this way, the number of parts of the drain separator of the exhaust gas analyzer can be reduced as much as possible, and the flow path forming member is attached to the second block element while the first block element and the second block element are separated. Since the first block element and the second block element need to be superimposed, the assembly is also easy.

According to the present invention configured as described above, since the exhaust gas outlet port side of the exhaust gas outlet passage is bent upward, and the exhaust gas outlet port is open toward the side or the bottom, the exhaust gas separated from the gas-liquid separation chamber is analyzed. In addition to making it difficult to infiltrate water accumulated in the gas-liquid separation chamber into the exhaust gas discharge passage leading to the equipment, it is possible to prevent water droplets falling from the upper surface of the gas-liquid separation chamber from entering. can do.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic diagram which shows the structure of the waste gas analyzer of this embodiment.
2 is a longitudinal sectional view showing a configuration of a drain separator of the same embodiment;
Fig. 3 is a view of the drain separator of the same embodiment as seen from the exhaust gas introduction path side;
4 is a longitudinal sectional view showing a configuration of a flow path forming member according to a modified embodiment.
Fig. 5 is a longitudinal sectional view showing the structure of a conventional drain separator.

EMBODIMENT OF THE INVENTION Below, the exhaust gas analyzer 100 concerning this invention is demonstrated with reference to drawings.

The exhaust gas analyzer 100 of the present embodiment directly introduces engine exhaust gas discharged from an engine and analyzes a component to be included in the exhaust gas, and analyzes a small exhaust gas in which a drain separator and an analyzer are integrated. Device.

Specifically, as shown in FIG. 1, the sampling probe 2 provided in the exhaust pipe of an automobile and sampling the engine exhaust gas (hereinafter referred to as 'exhaust gas') discharged from the exhaust pipe, and the sampling probe ( 2) an oil catcher 3 provided downstream of the exhaust gas to remove oil and the like from the exhaust gas, and a gas-liquid separator for removing water contained in the exhaust gas passing through the oil catcher 3 (hereinafter referred to as a 'drain separator'). (4). The oil catcher 3 and the drain separator 4 are connected by an introduction line L0.

It branches from the drain separator 4 to the measurement line L1 for inducing exhaust gas to the analyzer 6 and to the drain line L2 for discharging the water removed by the drain separator 4.

The measuring line L1 includes a dust collecting filter 5 for removing dust included in the exhaust gas gas-liquid separated by the drain separator 4 and an exhaust gas passing through the dust collecting filter 5. An analyzer 6 for analyzing a predetermined measurement target component is provided. In addition, a suction pump 7 for flowing exhaust gas through the measurement line L1 is provided between the dust collection filter 5 and the analyzer 6 in the measurement line L1, and the dust collection filter 5 and suction An air supply line L3 for introducing air to purge and zero correct the analyzer 6 is connected between the pumps 7 via a three-way solenoid valve 8. In addition, a pressure sensor 9 is provided between the three-way solenoid valve 8 and the suction pump 7. In addition, the air supply line (L3) is provided with a dust collecting filter 10 for removing dust contained in the air. Further, between the suction pump 7 and the analyzer 6 in the measurement line L1, a calibration gas line L4 for introducing a calibration gas and span correcting the analyzer 6 is connected. have. In this calibration gas line L4, a pressure reducer 11 such as ceramic hollow particles is provided. Further, the drain line L2 is provided with a filter 12 for filtering the water separated by the drain separator 4 and a suction pump 13 for discharging the water separated by the drain separator 4. .

As shown in FIG. 2, the drain separator 4 includes a gas-liquid separation chamber 41 that separates water, such as steam and / or water, contained in the exhaust gas, and one of which forms the gas-liquid separation chamber 41. An exhaust gas introduction passage 42 having an exhaust gas introduction port 42x provided on the side wall 401 (first block element 4A described later) and introducing the exhaust gas into the gas-liquid separation chamber 41; It has exhaust gas outlet 43x provided in the side wall 402 (2nd block element 4B mentioned later) which forms the gas-liquid separation chamber 41, and gas-liquid separation by the gas-liquid separation chamber 41 is carried out. The exhaust gas outlet passage 43 for guiding the exhaust gas to the analyzer 6 and the other side wall 402 for forming the gas-liquid separation chamber 41 is provided below the exhaust gas outlet 43x. Drainage (drain port) having a 44x, the drainage path for discharging water separated by the gas-liquid separation chamber 41 to the outside (de And a is a) (44). In addition, one side wall 401 and the other side wall 402 of this embodiment are side walls which mutually oppose. Moreover, the drain port 44x is provided in the vicinity of the bottom face from the other side wall 402.

Specifically, the drain separator 4 is made of, for example, a block made of metal having high thermal conductivity such as aluminum or copper, and divided into two divided first block elements 401 forming the gas-liquid separation chamber 41; It has a second block element 4B. This first block element 4A extends outward from the front surface of the casing C of the exhaust gas analyzer 100. On the other hand, the second block element 4B is disposed inside the casing C of the exhaust gas analyzer 100.

The first block element 4A has a concave portion 4A1 forming the gas-liquid separation chamber 41. The exhaust gas introduction passage 42 is formed therein and the exhaust gas introduction passage 42 is formed therein. A plurality of heat dissipation fins F1 are formed radially around (see Fig. 3). The bottom wall of this recessed part 4A1 becomes one side wall 401 which forms the gas-liquid separation chamber 41 mentioned above. In addition, the exhaust gas introduction passage 42 is a flow path forming a straight line, and an introduction line constituting the introduction line L0 for introducing the exhaust gas sampled by the sampling unit 2 is introduced into the upstream end 42u. Piping H1 is connected. The plurality of heat dissipation fins F1 are formed along the flow path direction of the exhaust gas introduction passage 42. By providing a plurality of heat dissipation fins F1, the heat from the exhaust gas transmitted to the first block element 4A is radiated to the outside and cooled, and the water vapor in the exhaust gas is made liquid from the gas. have.

The second block element 4B has a concave portion 4B1 forming the gas-liquid separation chamber 41, and the side wall flow passage 431 constituting the exhaust gas discharge passage 43 is formed therein, A drainage passage 44 is formed in parallel with the side wall passage 431. The bottom wall of this recessed part 4B1 becomes the other side wall 402 which forms the gas-liquid separation chamber 41 mentioned above. In addition, the side wall flow path 431 is a straight flow path, and the downstream end portion 431d has a discharge pipe H2 constituting the measurement line L1 for leading the exhaust gas to the analyzer 6. Connected. Moreover, the drain path 44 is a linear flow path, and the discharge line H3 which comprises the drain line L2 for discharging drain water outside is connected to the downstream end part 44d. In addition, in the side wall (the other side wall 402) in the second block element 4B, the internal volume of the gas-liquid separation chamber 41 is made to be as large as possible between the side wall flow passage 431 and the drain passage 44. Puddle portion 4B2 is formed. In addition, similar to the first block element 4A, the second block element 4B is provided with a plurality of heat radiation fins F2 radially around the side wall passage 431. The plurality of heat dissipation fins F2 are formed along the flow path direction of the side wall flow path 431. By providing a plurality of heat dissipation fins F2, the heat from the exhaust gas transmitted to the second block element 4B is radiated to the outside to be cooled, and more water vapor in the exhaust gas is made from the gas to the liquid. have.

Further, an upstream side end portion (gas-liquid separation chamber side opening) 431u of the side wall flow passage 431 is formed on the side wall (the other side wall 402) in the second block element 4B. Further, the upstream side end portion 431u of the side wall flow passage 431 is provided to face the exhaust gas inlet 42x formed in the side wall (one side wall 401) in the first block element 4A. And the flow path forming member 4C is attached to this upstream end 431u.

This flow path forming member 4C is made of, for example, a resin, and as shown in FIG. To form. The internal gas passage 432 and the side wall passage 431 constitute the exhaust gas deriving passage 43. Moreover, one end side of the inner flow passage 432 functions as a mounting portion which is mounted in close contact with the outer circumferential surface of the upstream side end portion 431u of the side wall flow passage 431.

Then, in a state where one end side of the inner flow passage 432 is attached to the upstream side end portion 431u of the side wall flow passage 431, one end side opening of the inner flow passage 432 communicates with the side wall flow passage 431, and the inner flow passage The other end side (upper side) opening of 432 becomes the exhaust gas outlet 43x. That is, by mounting the flow path forming member 4C on the upstream side end portion 431u of the side wall passage 431, the exhaust gas outlet 43x side of the exhaust gas outlet passage 43 is formed inside the gas-liquid separation chamber 41. It will be bent upwards. The upper end opening (exhaust gas outlet 43x) of the inner flow passage 432 is located above the upstream end portion 431u of the side wall flow passage 431. In addition, the upper end opening (exhaust gas outlet 43x) of the inner passage 432 opens toward the direction inclined slightly downward from the side or the side. In the present embodiment, the exhaust gas outlet 43x is substantially in the same direction as the opening direction of the exhaust gas inlet 42x, that is, toward the side wall 402 (second block element 4B) on the other side. Formed. This makes it difficult for the dust contained in the exhaust gas introduced from the exhaust gas inlet 42x to enter the exhaust gas outlet 43x. In addition, the opening direction of the exhaust gas introduction port 42x is a direction toward the side wall 402 of the other side of the gas-liquid separation chamber 41.

In addition, in this embodiment, the water scattered by the exhaust gas which flows in from the exhaust gas introduction passage 42 in front of the exhaust gas introduction port 42x in the gas-liquid separation chamber 41 intrudes in an exhaust gas lead-out passage. An intrusion prevention plate 45 for preventing is provided. The intrusion prevention plate 45 is provided to cover the exhaust gas inlet 42x, and is screwed to the side wall (one side wall 401) in the first block element 4A in this embodiment. It is. By this intrusion prevention plate 45, the exhaust gas flowing from the gas introduction passage 42 and the water contained in the exhaust gas can be prevented from invading into the gas extraction passage 43 as it is, thereby improving the gas-liquid separation performance. have. In addition, the exhaust gas introduced from the gas introduction passage 42 makes contact with the intrusion prevention plate 45 to facilitate the separation of water contained in the exhaust gas from the exhaust gas. In addition, since the intrusion prevention plate 45 exhibits a function of blocking water accumulated in the gas-liquid separation chamber 41, water accumulated in the gas-liquid separation chamber 41 can be made difficult to invade into the gas discharge passage 43.

In addition, the first block element 4A and the second block element 4B configured as described above are mounted on the first block element 4A after the flow path forming member 4C is mounted on the second block element 4B. The sealing member 4D, such as an O-ring, is sandwiched between the outer circumferential wall of the recess 4A1 and the outer circumferential wall of the recess 4B1 in the second block element 4B. In this way, the drain separator 4 is assembled. The drain separator 4 assembled in this way connects the lead pipe H2 to the downstream end portion 431d of the exhaust gas lead-out passage 43 of the second block element 4B, and The discharge pipe H3 is connected to the downstream end 44d to be accommodated in the casing C.

According to the exhaust gas analyzing apparatus 100 which concerns on this embodiment comprised in this way, since the exhaust-gas discharge port 43x side of the exhaust-gas discharge path 43 is bent upwards inside the gas-liquid separation chamber 41, The position of the exhaust gas outlet 43x can be provided above the position of the conventional exhaust gas outlet so that water accumulated in the gas-liquid separation chamber 41 can be made difficult to invade the exhaust gas outlet 43. . In addition, since the exhaust gas outlet port 43x is opened toward the side, water droplets condensed or adhered to the upper surface of the gas-liquid separation chamber 41 can be prevented from entering the exhaust gas outlet path 43. In addition, since the exhaust gas deriving passage 43 is bent upward by using the channel forming member 4C, the configuration other than the channel forming member 4C does not need to change the configuration of the conventional exhaust gas analyzing apparatus.

The present invention is not limited to the above-described embodiments.

For example, in the said embodiment, although the exhaust gas discharge port 43x opened substantially toward side, it may be comprised so that it may open toward the downward or vertical downward inclination 45 degree, for example.

Moreover, although the flow path forming member 4C of the said embodiment had the internal flow path 432 which forms the shape bent in substantially "U" shape, as shown in FIG. It may have an internal flow path 432 forming a bent shape.

Further, water droplets can be prevented further by providing a shade on the upper portion of the exhaust gas outlet 43x that opens toward the side. In the said embodiment, it is considered to provide the shade part integrally in the upper part of the upper side opening part in 4 C of flow path forming members.

In addition, the opening direction of the exhaust gas outlet port 43x of the said embodiment opens in the direction according to the opening direction of the said exhaust gas inlet port 42x, and it is exhaust gas when it sees from the exhaust gas inlet port 42x. You may comprise so that opening of the outlet 43x may not be seen. That is, you may comprise so that the opening direction of the exhaust gas discharge port 43x may be directed toward the other side wall 402 side as the limit orthogonal to the opening direction of the exhaust gas introduction port 42x. In this way, the exhaust gas introduced from the exhaust gas introduction passage 42 into the gas-liquid separation chamber 41 can be prevented from directly intruding into the exhaust gas discharge passage 43, and the gas-liquid separation performance can be further improved. Dust contained in the exhaust gas introduced from the exhaust gas introduction passage 42 into the gas-liquid separation chamber 41 can be made difficult to invade the analyzer 6 side from the exhaust gas extraction passage 43. In addition, the above-described effect can also be achieved by simply disposing the exhaust gas inlet 42x and the exhaust gas outlet 43x so as not to face each other.

In addition, in the above embodiment, the drain separator 4 is constituted by the first block element 4A, the second block element 4B, and the flow path forming member 4C. In addition, the gas-liquid separation chamber 41 Each of the exhaust gas introduction passage 42, the exhaust gas discharge passage 43, the drain passage 44, and the like may be constituted by separate members.

In addition, in the said embodiment, although one side wall 401 and the other side wall 402 were mutually opposing side walls, other side walls mutually adjoining each other like a mutually adjacent side wall etc. may not be sufficient.

In addition, in the said embodiment, although the exhaust gas discharge port 43x and the drain port 44x were shown in the example provided in the same side wall (other side wall 402) side, the drain port 44x is an exhaust gas discharge port. As long as it is a position lower than 43x and the exhaust-gas introduction port 42x, you may provide in any side wall.

Moreover, as an aspect which bends the exhaust gas outlet port side to the exhaust gas discharge | emission path upward, it may be bent upwards in a perpendicular upward direction like the said embodiment, and may be bent upwardly inclined upward from the vertical upwards.

In addition, although the suction pumps 7 and 13 are provided in each of the measurement line L1 and the drain line L2 in FIG. 1, one suction downstream of the exhaust point of the measurement line L1 and the drain line L2 is provided. By providing the suction pump, the measuring line L1 and the drain line L2 may be sucked by the same suction pump. In this case, since the suction force of the drain line L2 by the suction pump falls and the flow volume which can drain water becomes small, and water accumulates easily in the gas-liquid separation chamber 41, the effect of this invention is more remarkable. Done.

It is needless to say that the present invention is not limited to the above-described embodiment, and that various modifications are possible without departing from the spirit of the present invention.

100 ... Exhaust gas analyzer 4. Drain separator
41 ... Gas-liquid separation chamber 401. One side wall
42 ... 42x... Exhaust gas inlet
402. The side wall 43 on the other side; Exhaust gas
43x... Exhaust gas outlet 431. Side wall
432. Internal passage 44. drain
44x... Drain 4A. First block element
4B. Second block element 4C... Flow path forming member
6 ... Analyzer

Claims (5)

A gas-liquid separation chamber for separating water contained in exhaust gas,
An exhaust gas introduction passage having an exhaust gas introduction port provided on one side wall side forming the gas liquid separation chamber, and introducing the exhaust gas into the gas liquid separation chamber;
An exhaust gas deriving passage having an exhaust gas deriving port provided on the side wall of the other side forming the gas-liquid separation chamber and guiding the exhaust gas separated by the gas-liquid separation chamber to an analyzer;
It has a drain hole provided below the exhaust gas outlet from the side wall forming the gas-liquid separation chamber, and provided with a drain passage for discharging the water separated by the gas-liquid separation chamber to the outside,
And an exhaust gas outlet port side of the exhaust gas outlet passage is bent upward from the inside of the gas-liquid separation chamber, and the exhaust gas outlet port opens laterally or downwardly. The method according to claim 1,
The exhaust gas inlet is opened toward the side wall of the other side of the gas-liquid separation chamber,
And the exhaust gas outlet is open toward the direction along the opening direction of the exhaust gas inlet. The method according to claim 1,
The exhaust gas outlet passage has a sidewall flow passage formed on the other side wall forming the gas-liquid separation chamber and an internal flow passage formed in a bent shape formed by a flow path forming member mounted to the gas-liquid separation chamber side opening of the sidewall flow passage. ,
An exhaust gas analysis device in which one opening of the inner flow passage communicates with the side wall flow passage, and the other opening of the inner flow passage serves as the exhaust gas outlet. The method according to claim 3,
The block forming the gas-liquid separation chamber is divided into a first block element including the one side wall and a second block element including the other side wall,
The exhaust gas introduction passage is formed in the first block element, the side wall flow passage and the drain passage are formed in the second block element, and the gas-liquid separation chamber side opening of the side wall flow passage formed in the second block element. Exhaust gas analysis device is mounted to the flow path forming member. As a drain separator used in the exhaust gas analyzer,
A gas-liquid separation chamber for separating moisture contained in exhaust gas,
An exhaust gas introduction passage having an exhaust gas introduction port provided on one side wall side forming the gas liquid separation chamber, and introducing the exhaust gas into the gas liquid separation chamber;
An exhaust gas discharge passage having an exhaust gas outlet provided on the sidewall of the other side forming the gas-liquid separation chamber, and leading the exhaust gas separated by the gas-liquid separation chamber to an analyzer;
It has a drain hole provided below the exhaust gas outlet from the side wall forming the gas-liquid separation chamber, and provided with a drain passage for discharging the water separated by the gas-liquid separation chamber to the outside,
The exhaust gas outlet port side of the exhaust gas outlet path is bent upward from the inside of the gas-liquid separation chamber, and the exhaust gas outlet port is opened toward the side or the bottom.

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