JP2653530B2 - Tritium concentration measuring device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a tritium concentration measuring device for measuring tritium concentration in exhaust gas.

(Prior Art) Generally, in nuclear facilities such as nuclear power plants and nuclear fuel reprocessing plants, it is obligatory to measure the tritium concentration in exhaust gas. In measuring tritium concentration, for example, as shown in FIG. The concentration was measured using a tritium concentration measuring device. In FIG. 1, a sample gas that has passed through a filter 1 is sent to a moisture recovery unit 4 by a pump 2 through a flow control valve 3. This water recovery unit 4
Then, the sample gas is reduced by −15 by the refrigerant supplied from the refrigerator 5.
In order to recover the moisture in the gas by cooling to about ℃, two coolers 6a and 6b are provided so that continuous operation can be performed even if the pipeline is blocked due to freezing of the moisture.
The three-way solenoid valve 5 alternately switches a and 6b to enable continuous operation.

Pipes are connected to the outlets of the coolers 6a and 6b,
The water in the gas condensed in a and 6b is stored in the water recovery container 7 through each pipe. Further, an exhaust pipe 11 is connected in the middle of the pipe via a three-way solenoid valve 10, and the sample gas flowing out of the coolers 6a and 6b receives the three-way solenoid valve 10,
The gas is returned to an exhaust gas line (not shown) through an exhaust pipe 11, a back pressure regulating valve 12, and a flow meter 13. An analyzer 9 is connected to the bottom of the water recovery container 7 via an outlet valve 8, and the analyzer 9 is configured to analyze tritium contained in the moisture in the gas to measure the tritium concentration. ing.

(Problems to be Solved by the Invention) However, the conventional tritium concentration measuring device configured as above requires two coolers 6a and 6b, and thus has a problem that the device becomes large. . Further, in the conventional tritium concentration measuring device, the moisture in the gas is reduced by the coolers 6a and 6a.
In some cases, the water is discharged without being frozen in b, and the condensed liquid recovered in the water recovery container 7 evaporates again, resulting in low recovery efficiency.

The present invention has been made in view of the above circumstances,
It is an object of the present invention to provide a tritium concentration measuring device capable of reducing the size of the device and preventing re-evaporation of the condensate collected in the water collecting container.

[Means for Solving the Problems] In order to solve the above problems, a tritium concentration measuring apparatus according to the present invention provides a pressurizing pump for pressurizing a sample gas so that its dew point temperature is higher than a freezing point. A cooler that cools the sample gas pressurized by the pressurizing pump to the dew point temperature, a thin tubular water recovery container that stores the water in the gas condensed by the cooler, and a water recovery container that collects the water. And an analyzer for analyzing the concentration of tritium in the condensate.

(Operation) In the present invention, since the sample gas is pressurized by a pressure pump so that the dew point of the sample gas becomes higher than the freezing point and introduced into the cooler, the dew point of the sample gas can be made higher than the freezing point. Thus, the moisture in the gas can be recovered without using two coolers, and the size of the apparatus can be reduced. Further, since the water recovery container is formed in a thin tube, the contact area between the sample gas and the condensate can be reduced, thereby preventing the condensate from evaporating.

(Embodiment) An embodiment of the present invention will be described below with reference to FIG.

FIG. 1 is a diagram showing a configuration of a tritium concentration measuring apparatus according to the present invention. A pressure pump 22 is connected to an outlet of a filter 21 for removing dust and the like in a sample gas. The pressurizing pump 22 pressurizes the sample gas to, for example, about 4 kg / cm ³ , and a cooler 24 is connected to an outlet of the pressurizing pump 22 via a flow control valve 23. A pipe 25 for cooling the sample gas is provided in the cooler 24, and a pipe 26 for guiding the water in the condensed gas to a first water recovery container 27 is connected to an outlet of the pipe 25. ing.

An analyzer 30 is connected to the bottom of the first moisture recovery container 27 via a pipe 28 and an outlet valve 29, and the analyzer 30 is configured to analyze tritium contained in the condensate. In addition, a branch pipe is provided at the bottom of the first moisture collecting container 27.
The second water collecting container 33 is connected via the check valve 31 and the check valve 32. The second water recovery container 33 is for storing a part of the water condensed in the cooler 24 when much water is condensed, and a vent pipe 34 is connected to an upper part of the second water recovery container 33. An electromagnetic valve 35 is provided in the vent pipe 34, and the electromagnetic valve 35 is opened by a signal from a level switch 36 provided in the first moisture recovery container 27. The first water recovery container 27 is formed in a thin tube shape in order to minimize the contact area between the sample gas and the condensate, thereby preventing the condensate from evaporating.

An exhaust pipe 37 for returning the sample gas to an exhaust gas line (not shown) is connected to the outlet of the pipe 25. The exhaust pipe 37 has a pressure gauge 38, a back pressure regulating valve 39, and a flow meter 40.
A pressure gauge measures the pressure of the sample gas flowing out of the cooler 24.
The pressure is detected by 38 and the back pressure adjusting valve is
It is configured to adjust the opening degree of 39.

According to such a configuration, the sample gas that has passed through the filter 21 is pressurized to about 4 kg / cm ^{3 by the} pressurizing pump 22, and is introduced into the cooler 24 through the flow control valve 23. In the cooler 24, the sample gas is cooled to the dew point temperature, and the moisture in the gas is condensed. At this time, the sample gas was 4 kg /
Since the sample gas is pressurized to about cm ² , the dew point temperature of the sample gas is about 1 ° C. Therefore, by cooling the sample gas introduced into the cooler 24 to about 1 ° C., water in the gas can be condensed.

The water in the gas condensed in the cooler 24 in this way is recovered in the first water recovery container 27 through the pipe 26. On the other hand, the sample gas discharged from the cooler 24 is returned to an exhaust gas line (not shown) through an exhaust pipe 37. Then, the condensate recovered in the first water recovery container 27 is sent to the analyzer 30 through the pipe 28 and the outlet valve 29, where the concentration of tritium contained in the condensate is analyzed.

When the level of the condensed liquid collected in the first water recovery container 27 reaches the level set by the level switch 36, the signal from the level switch 36 opens the solenoid valve 35. As a result, the pressure in the second water recovery container 33 becomes the atmospheric pressure, and when the water in the gas is large, a part of the condensate collected in the first water recovery container 27 is used as the second water recovery container. 33 can be transferred.

Thus, in the above embodiment, the sample gas is supplied to the pressurizing pump 22
Then, the dew point temperature of the sample gas can be raised to about 1 ° C. Therefore, the moisture in the gas can be recovered without cooling the sample gas to about −15 ° C. as in the prior art, and two coolers are not required to enable continuous operation. Can be reduced in size. Further, in the above embodiment, the first water collecting container 27 for storing the water in the condensed gas is formed in a thin tube, so that the contact area between the condensed water and the sample gas can be reduced, whereby the water evaporates. Can be prevented.

In the above embodiment, when the gas contains a large amount of water,
A second water recovery container 33 is provided for storing a part of the condensate collected in the water recovery container 27 of the first embodiment, but the first water recovery container 27 is the same in volume as the conventional water recovery container. If it is, the second moisture collecting container 33 is not necessarily required. Further, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention.

〔The invention's effect〕

As described above, the tritium concentration measuring device according to the present invention includes a pressurizing pump that pressurizes a sample gas, a cooler that cools the sample gas pressurized by the pressurizing pump to a dew point temperature, It is provided with a thin tubular water recovery container for storing the water in the condensed gas, and an analyzer for analyzing the concentration of tritium in the condensate recovered in the water recovery container. Therefore, the dew point temperature of the sample gas can be increased, and the moisture in the gas can be recovered without cooling the sample gas to about -15 ° C., so that the apparatus can be downsized. In addition, the contact area between the condensate collected in the water collecting container and the sample gas can be reduced, thereby preventing the evaporation of the water, so that the water in the gas can be efficiently collected.

[Brief description of the drawings]

FIG. 1 is a block diagram of a tritium concentration measuring device showing one embodiment of the present invention, and FIG. 2 is a block diagram of a conventional tritium concentration measuring device. 21 ... Filter, 22 ... Pressure pump, 23 ... Flow control valve, 24 ... Cooler, 27 ... First moisture recovery container, 30 ...
An analyzer 33, a second water recovery container 36, a level switch 37, an exhaust pipe.

Claims (1)

(57) [Claims] (1) The dew point temperature is higher than the freezing point.
A pressurizing pump for pressurizing the sample gas, a cooler for cooling the sample gas pressurized by the pressurizing pump to a dew point temperature, and a thin water recovery container for storing the water in the gas condensed by the cooler. An analyzer for analyzing the concentration of tritium in the condensate recovered in the water recovery container.