JPH0447672Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] This invention relates to a sampling system equipped with a moisture extractor that separates and extracts moisture in a sampling gas using a refrigeration cycle.

[Technical background of the invention and its problems] Generally, in nuclear reactor facilities such as nuclear power plants, it is extremely important for safety management to measure the amount of tritium contained in the exhaust gas. Since tritium is contained in the moisture in the exhaust gas, it is necessary to extract the moisture from the exhaust gas in order to measure the amount of tritium.

Therefore, conventionally, there are sampling systems shown in FIGS. 3 and 4 that are equipped with a moisture extractor that separates and extracts moisture in a sampling gas using a refrigeration cycle. Such a conventional sampling system includes a first water extraction device 1
It consists of two systems, the first and second moisture extractor 2, which are independent of each other and have exactly the same configuration. One system always samples the sampling gas from the sampling line piping, and the other system always samples the sampling gas from the previous sampling. The water that has been frozen and separated from the sampling gas is heated and recovered.

The sampling method is to cool the sampling gas sucked from the sampling line piping 4 by the sampling pump 3 to below the dew point in the evaporators 5 and 6 of the moisture extraction devices 1 and 2, and to condense the moisture in the sampling gas and freeze it. The water is separated from the sampling gas.

Here, whether the sampling gas sucked from the sampling line piping 4 by the sampling pump 3 passes through the first or second moisture extraction device 1 or 2 is determined by the first sampling switching valve 7, 8, the second sampling switching valve 9, or the second sampling switching valve 9. This is done by 10 switchings. Further, which of the evaporators 5 and 6 is to be operated is determined by switching the refrigerant switching valves 11 and 12.
Further, the refrigerant flowing through the evaporators 5 and 6 is cooled to a constant temperature by the refrigerator 13.
Furthermore, heaters 14 and 15 are used to melt the water frozen in the water extractors 1 and 2. 16
is a flowmeter and measures the flow rate of the sampling gas. Furthermore, each moisture extractor 1, 2 has a recovery valve 1.
7 and 18 are connected to the drain pipe 19, and a water recovery tank 20 is connected to this drain pipe 19.
is connected, and a water collection valve 21 is further provided.

The water frozen in the water extraction devices 1 and 2 by the evaporators 5 and 6 is removed by the heaters 14 and 15.
The water is heated and melted, and the melted water accumulates in the portion of the drain pipe 19 from the recovery valves 17 and 18 to the water extraction device 12. Thereafter, by opening the recovery valves 17 and 18, the accumulated water flows into the water recovery tank 20 through the drain pipe 19. When a certain amount is reached, the water in the water recovery tank 20 is recovered by opening the water collection valve 21.

To explain the operation of a conventional sampling system with such a configuration, Figs.
As shown in the figure, the first water extractor 1 side is in the sampling mode, and the second water extractor 2 side is in the heating mode in FIG. 3 and in the recovery mode in FIG. 4. Then, on the side of the first water extraction device 1 in the sampling mode, the first and second sampling switching valves 7 and 9 are opened, and the sampling gas is sucked from the sampling line piping 4 by the driving of the sampling pump 3, and the first water extraction device 1 is in the sampling mode. Leads to extraction device 1. In the evaporator 5, the refrigerant switching valve 11 is open and refrigerant is passed from the refrigerator 13 to cool the sampling gas in the first water extraction device 1 and condense and freeze the water contained therein. .

The water that has condensed and frozen in the second water extraction device 2 due to the previous sampling mode is removed by the heater 15 in the heating mode shown in FIG.
To become ON, it is melted into water and this second
The water accumulates in the water extraction device 2 and the recovery valve 18 of the drain pipe 19.

Next, in the recovery mode shown in FIG. 4, one recovery valve 18 of the drain pipe 19 is opened, and the melted water is discharged from the second water extraction device 2 to the water recovery tank 20. When a certain amount of water is stored in the water recovery tank 20, the water collection valve 21 is opened and the water is recovered.

However, in such a conventional sampling system, the pressure on the secondary side is increased by the action of the sampling pump 3, and this pressure extends to the water recovery tank 20. Therefore, when the water collection valve 21 was opened, not only extracted water but also harmful sampling gas would be blown out, which could harm the water collection work.

[Purpose of the invention] This invention was made in view of such conventional problems, and aims to provide a sampling system that prevents harmful sampling gas from accumulating in a water recovery tank.

[Summary of the idea] This idea installs a bypass pipe between the drain pipe leading to the water recovery tank and the suction side of the sampling pump, and at the same time installs a check valve in the water recovery tank to replace atmospheric pressure. This is a sampling system in which the sampling gas in the recovery tank is recovered to the primary side of the sampling pump to prevent it from being ejected from the water collection valve.

[Embodiment of the invention] Hereinafter, an embodiment of the invention will be described in detail with reference to the drawings. 1 and 2 show an embodiment of this invention. In this embodiment, parts with the same reference numerals as in the conventional example described above have the same structure and function.

A pressure displacement piping 22 is provided between the portion of the drain piping 19 that reaches the water recovery tank 20 and the upper part of each moisture extraction device 1, 2, and a pressure displacement valve 23 is further provided in this pressure displacement piping 22. ing.
Further, a bypass pipe 24 is connected to the pressure replacement pipe 22 to prevent harmful sampling gas from accumulating in the water recovery tank 20, and the other end of the bypass pipe 24 is connected to the suction port side of the sampling pump 3. This bypass piping 24 is further provided with a pressure relief valve 25, which allows the bias passage to be opened and closed. Further, a check valve 26 is provided in the drain pipe 19.

The operation of the sampling system having the above configuration will be explained next. As shown in FIG. 1, it is assumed that the first moisture extraction device 1 side is in the sampling mode and the second moisture extraction device 2 side is in the heating mode. In the sampling mode, the sampling pump 3 operates, and the moisture contained in the sampling gas sent to the first moisture extraction device 1 by the action of the evaporator 5 is condensed, frozen, separated, and stored there. On the side of the second water extractor 2 in the heating mode, the frozen water stored in the water extractor 2 that had frozen during the previous sampling mode is warmed and melted by the heater 15. The molten water is then stored in a drain pipe 19 between the water extraction device 2 and the recovery valve 18.

When the recovery mode is entered, the heater 15 is turned off and the recovery valve 18 is opened, as shown in FIG. At the same time, the pressure displacement valve 23 is also opened, and the pressure displacement piping 22 is communicated. By doing this, the water accumulated in the drain pipe 19 flows into the water recovery tank 20 through the recovery valve 18 and is stored there. At this time, the inside of the water recovery tank 20 is at atmospheric pressure, and the water extraction device 2 is pressurized by the sampling pump 3, so water flows into the water recovery tank 20 at once due to pressure. However, after a certain period of time has passed, the pressure in the water recovery tank 20 and the water extraction device 2 reach equilibrium, and if there is residual water in the water extraction device 2,
Since the pressure is difficult to replace, the remaining water may not fall into the water recovery tank 20. Therefore,
By opening the pressure displacement valve 23, the pressure inside the water extraction device 2 is replaced, and all the water is recovered into the water recovery tank 20.

After that, with the recovery valve 18 closed, the pressure relief valve 2
5 is opened, the pressure inside the water recovery tank 20 is sucked by the sampling pump 3 and becomes below atmospheric pressure. For this purpose, the recovery valve 18, the pressure displacement valve 23, and the pressure release valve 25 are opened, and the water collection valve 21 is opened.
When the valve is opened to collect water, the inside of the water recovery tank 20 is not pressurized, so that the harmful sampling gas in the water recovery tank 20 does not come out from the water collection valve 21. Furthermore, water recovery tank 20
Since the check valve 26 is provided at the upper part of the water collection tank 20, the pressure inside the water collection tank 20 is replaced with the atmosphere, and there is no problem that water does not fall through the water collection valve 21.

Note that even when the sampling mode between the first moisture extraction device 1 and the second moisture extraction device 2 is switched, the same operation can be performed.

[Effects of the invention] In this invention, as described above, a bypass pipe is connected to the drain pipe between the water extraction device and the water recovery tank, and the upper end of the bypass pipe is connected to the suction side of the sampling pump. Therefore, the sampling gas accumulated in the water recovery tank can be returned to the suction side of the sampling pump, which has a negative pressure, and harmful sampling gas will not be blown out from the water collection valve together with the extracted water during water recovery. water can be collected safely. In addition, the water recovery tank is equipped with a check valve, which allows the water to be taken out from the water collection valve by natural fall at atmospheric pressure inside the water recovery tank, which has the advantage of allowing smooth recovery of moisture. There is also.

[Brief explanation of the drawing]

FIG. 1 is a system diagram of an embodiment of this invention, FIG. 2 is a system diagram of the same embodiment in recovery mode, and FIGS. 3 and 4 are system diagrams of a conventional example. 1... First moisture extraction measure, 2... Second moisture extraction device, 3... Sampling pump, 4... Sampling line piping, 5, 6... Evaporator,
7, 8...first sampling switching valve, 9, 10...
...Second sampling switching valve, 11, 12... Refrigerant switching valve, 13... Refrigerator, 14, 15... Heater, 17, 18... Recovery valve, 19... Drain piping, 20... Water recovery tank, 21...Water collection valve,
22...Pressure displacement piping, 23...Pressure displacement valve,
24...Bypass piping, 25...Pressure relief valve, 26
……non-return valve.

Claims (1)

[Scope of utility model registration request] Sampling gas is sent from the sampling line piping to at least one of the plurality of moisture extraction devices provided by a sampling pump, and after the moisture contained in the moisture extraction device is frozen and extracted, the sampling gas is returned to the sampling line piping. In a sampling system that heats frozen water that has already been extracted by another water extraction device and collects it in a water recovery tank, the pressure in the water recovery tank provided at the top of the water recovery tank is replaced with atmospheric pressure. and bypass piping that connects the water recovery tank and the sampling pump via a pressure relief valve. A sampling system characterized by lowering the pressure to below atmospheric pressure.