JPH0723264U - Cooling device for dehumidification - Google Patents

Abstract

(57) [Abstract] [Purpose] To obtain a dehumidifying cooling device that can reliably drain water in a sample gas and reduce the load on the electronic cooler due to air cooling. In a dehumidifying cooling device equipped with an electronic cooler 4 and a drain separator 8 on the upstream side thereof for removing water in the sample gas, a sample gas outlet end 7 is connected to the drain separator 8. 9 is arranged at the exhaust port 11 of the air cooling fan 10 of the electronic cooler 4.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 In the present invention, for example, when the sample gas such as flue gas is supplied to the analyzer using a heating pipe, the sample gas is cooled in advance to drain (dehumidify) the water in the sample gas. The present invention relates to a dehumidifying cooling device.

[0002]

[Prior art]

When analyzing a high temperature sample gas such as flue gas using an analyzer such as a SO ₂ or NO _x analyzer, a heating pipe is used to measure the component that causes dissolution loss in the drain.

In this case, it is necessary to cool the sample gas to the outside air temperature in the exposed part of the pipe arranged in the outside air atmosphere between the heating pipe and the analyzer to drain the water in the sample gas. However, when the exposed environment is high due to radiant heat in the environment where the analyzer is installed, cooling is insufficient, and the residual moisture in the sample gas remains. Will be drained in the analyzer. Therefore, due to the dissolution of SO ₂ and NO ₂ and the re-evaporation of drain, anomalous readings will occur.

Further, the sample gas that has passed through the drain separator enters the electronic cooler in an insufficiently cooled state for the above-mentioned reason, and thus this electronic cooler requires a large cooler load for drain processing.

The present invention has been made in consideration of the above-mentioned matters, and an object thereof is to dehumidify the water in the sample gas surely as drain and reduce the load of the electronic cooler by air cooling. Is to obtain a cooling device for.

[0006]

Means for Solving the Problems To achieve the above object, a dehumidifying cooling device according to the present invention includes an electronic cooler and a drain separator upstream of the electronic cooler to remove water in sample gas. In the dehumidifying cooling device, a sample tube whose outlet end is connected to the drain separator is arranged at the exhaust port of the air cooling fan of the electronic cooler.

Further, from another aspect, the present invention provides a dehumidifying cooling device including an electronic cooler and a drain separator upstream of the electronic cooler to remove water in the sample gas. There is provided a dehumidifying cooling device provided with a drain pot for storing the drain of the above, and a flexible pipe arranged in the drain pot and having a sample gas outlet end thereof connected to the drain separator.

In the present invention, the air cooling fan of the electronic cooler used in the analyzer for draining the water in the sample gas is operated all the year round. It is used for cooling the sample gas, and since the drain discharged from the electronic cooler has a temperature close to the cooling temperature, drain water close to this cooling temperature is used for cooling the sample gas. . In this case, in any case, a sample gas is used as a serpentine tube having a large contact area with exhaust air or drain water.

In short, the present invention uses the conventional cooling means configured to drain water in the sample gas by natural heat dissipation and cooling by the electronic cooler and send the sample gas to the analyzer as the above-mentioned cooling means. It is configured such that the one described in, is provided separately and it functions as a cooling unit.

[0010]

[Action]

 A cooling device with a flexible tube structure is provided at the exhaust port of the air-cooling fan of the electronic cooler used in the analyzer. Since the air-cooling fan of the electronic cooler is operating all year round, by using this discharged air for cooling, the flexible pipe with a large contact area is forcibly air-cooled by the air-cooling fan. The gas temperature can be lowered and the water in the sample gas can be drained. At this time, since the air-cooled sample gas is further sent to the detector via the electronic cooler, the load on the electronic cooler due to air cooling can be reduced.

Further, since the drain water discharged from the electronic cooler close to the cooling temperature is stored in the drain pot, and a serpentine tube having a large contact area is provided in the drain pot to flow the sample gas, The water in the sample gas can be drained by cooling the coil with water. Even in this case, since the cooled sample gas is further sent to the detector via the electronic cooler, the drain processing load of the electronic cooler can be reduced.

[0012]

【Example】

 Embodiments of the present invention will be described below with reference to the drawings. However, the present invention is not limited thereby. In FIG. 1 and FIG. 2, the dehumidifying cooling device cools the sample gas to the outside air temperature in the pipe exposed portion 3 provided in the outside air atmosphere between the heating pipe 1 and the analyzer 2, and then the analyzer When the electronic cooler 4 provided inside 2 further drains the water in the sample gas and sends the sample gas to the detector 5, the sample gas inlet end 6 is connected to the heating pipe 1 on the upstream side, and the sample gas outlet Exhaust of the air-cooling fan 10 for cooling the thermo-tube radiating fin 4a of the electronic cooler 4 at a constant temperature through the flexible pipe 9 whose end 7 is connected to the drain separator 8 provided on the upstream side of the electronic cooler 4. It is arranged at the mouth 11. Reference numeral 12 is a sample gas outlet connected to the electronic cooler 4, and 13 is a drain outlet. Further, reference numeral 14 is a cooling cover having an air exhaust port 14a after the flexible tube 10 is forcibly air-cooled by the air cooling fan 10 and a lower opening 14b provided at a position facing the exhaust port 11, and 15 is a constant pressure. It is a trap.

Since the air-cooling fan 10 of the electronic cooler 4 is operating all the year round, since the air-cooling fan 10 of this embodiment has the above-described configuration, the exhausted air is used for cooling. By forcibly cooling the flexible tube 9 having a large contact area with the air cooling fan 10, the temperature of the sample gas can be lowered, and the water in the sample gas S can be drained. At this time, the air-cooled sample gas is further sent from the drain separator 8 to the detector 5 via the electronic cooler 4, so that the load on the electronic cooler 4 due to air cooling can be reduced.

As described above, in the present embodiment, since the exhaust air from the air cooling fan 10 is converged on the flexible pipe 9 and the exhaust port 14a for the air passing through the flexible pipe 9 is provided, the flexible pipe is controlled by the exhaust air of the air cooling fan 10. 9 can be forcibly air-cooled and the sample gas can be cooled. The drain formed inside is separated by the drain separator 8 and can be discharged in a water seal.

FIG. 3 shows a second embodiment of the present invention. In FIG. 3, the dehumidifying cooling device is arranged in the drain pot 26 for storing the cooling drain D from the drain outlet 25 of the electronic cooler 24, the drain pot 26, and the sample gas inlet end 27 upstream. Side heating pipe (not shown), and the sample gas outlet end 28 is mainly composed of a flexible tube 30 connected to a drain separator 29 provided upstream of the electronic cooler 24. Reference numeral 31 is a sample gas outlet connected to the electronic cooler 24, and 32 is a drain outlet. Further, reference numeral 33 is an outlet of the cooling drain D 1 in the drain pot 26 which is automatically discharged through the discharge pipe P, and 34 is a heat insulating material for preventing the temperature rise of the cooling drain D 1.

Since this embodiment has the above-mentioned configuration, the drain water D discharged from the electronic cooler 24, which is close to the cooling temperature, is stored in the drain pot 26, and the drain pot has a large contact area. Since 30 is provided and the sample gas is caused to flow, it is possible to drain the water in the sample gas by cooling the flexible pipe with the drain water D. Also in this case, since the cooled sample gas is further sent from the drain separator 29 to the detector via the electronic cooler 24, the drain processing load of the electronic cooler 24 can be reduced.

As described above, in the present embodiment, the drain D discharged from the electronic cooler 24 is temporarily stored in the drain pot 26, the flexible pipe 30 is provided in the drain pot 26, and the sample gas is made to flow, so that the temperature is close to the cooling temperature. The water in the sample gas can be drained by cooling the flexible tube 30 with the drain water D.

In short, in each of the above-described embodiments, energy saving can be achieved, and since no other air cooling device is used, the cost is low. Further, it is possible to reduce the drain processing load of the drain separator and the electronic cooler in the subsequent stage.

[0019]

[Effect of device]

 As described above, according to the present invention, the air-cooling fan of the electronic cooler is provided with a flexible pipe at the exhaust port, and the air-cooling fan of the electronic cooler is operating all year round. By using the air for cooling, the temperature of the sample gas can be lowered by forcibly air-cooling the spiral tube having a large contact area with the air-cooling fan, and the moisture in the sample gas can be drained. At this time, since the air-cooled sample gas is further sent to the detector via the electronic cooler, the load on the electronic cooler due to air cooling can be reduced.

Further, drain water discharged from the electronic cooler close to the cooling temperature is stored in the drain pot, and a serpentine tube having a large contact area is provided in the drain pot to flow the sample gas. The water in the sample gas can be drained by cooling the coil with water. Even in this case, since the cooled sample gas is further sent to the detector via the electronic cooler, the drain processing load of the electronic cooler can be reduced.

Therefore, energy saving can be achieved, and since no other air cooling device is used, the cost is low.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an overall configuration showing a first embodiment of the present invention.

FIG. 2 is an explanatory diagram of a configuration in the above embodiment.

FIG. 3 is an explanatory diagram of an overall configuration showing a second embodiment of the present invention.

[Explanation of symbols]

1 ... Heating pipe, 2 ... Analyzer, 3 ... Pipe exposed part,
4, 24 ... Electronic cooler, 5 ... Detector, 6, 27 ... Sample gas inlet end, 7, 28 ... Sample gas outlet end, 8, 2
9 ... Drain separator, 9, 30 ... Flexible pipe, 10 ... Air cooling fan, 11 ... Electronic cooler exhaust port, 26 ... Drain pot, D ... Drain water.

Claims (2)

[Scope of utility model registration request] 1. A dehumidifying cooling device comprising an electronic cooler and a drain separator upstream of the electronic cooler for removing water in the sample gas, wherein a sample tube outlet end of which is a flexible pipe connected to the drain separator. A dehumidifying cooling device arranged at an exhaust port of an air cooling fan of the electronic cooler. 2. A dehumidifying cooling device comprising an electronic cooler and a drain separator upstream of the electronic cooler to remove water in the sample gas, and a drain pot for storing drain from the electronic cooler, A dehumidifying cooling device arranged in a drain pot, and provided with a flexible pipe whose sample gas outlet end is connected to the drain separator.