DE2306211A1 - Sampling system for radioactive or corrosive liqs or vapours - partic water or steam in a nuclear power plant - Google Patents

Abstract

In a sampling system for radioactive or aggressive liq. or vapour media flowing in pipelines (main pipe) from which a tap-off pipe leads to a sampling table where a tap-off point as well as at least one measuring device is provided, a return flow pipe is provided from the sample table to the main pipe and at least one tap-off path with quick acting coupling (self closing plug couplings) on both pipes for the connection of a sample vessel or measuring device is provided between the tap-off and return pipes, and is bridged by a by-pass pipe.

Description

Sampling device for radioactive or aggressive liquids and The invention relates to a sampling device for in pipes (Main line) flowing radioactive or aggressive liquid and vaporous media, in which a dispensing line from the main line to a sampling board is performed, at which a tap and at least one measuring device is provided.

In various fields of technology, the task is often liquid and vaporous media for constant physical and chemical properties to investigate. You need to take samples of these media. Special Sampling facilities are required if there is pressure, temperature and radioactivity direct removal of the liquid or vapor samples to be analyzed not allow.

This is especially true for nuclear power plants, which are subject to ongoing controls the water and steam circuits for conductivity, value, oxygen and chemical Impurities etc.

is essential. Other areas of application can be found in the chemical industry Industry, paper industry and others

In a known manner, the sampling is carried out in an open system Sampling probes are introduced into the lines of the circuits, leads to them Sampling cooler connects, which has the task of bringing the water to a suitable To cool the temperature value or to condense the steam. Rinter the cooler are the necessary measuring sections are switched with the appropriate encoders. Via a shut-off valve the output of the line containing the Me3 lines is connected to a drain, the one.

represents an open collecting basin. Next to the test section line is a tap available that also. into the drain via a shut-off valve flows out. In this process, samples are taken by means of open vessels to be used in the laboratory to be analyzed This known sampling device that has proven itself particularly in conventional power plant technology, however, it is not very suitable for radioactive media. The dispatch of open sampling points leads to an increase in aerosol activity in radioactive water and vapors.

A spillage of radioactive water cannot be ruled out quite apart from the fact that the flow of the lines containing the measuring sections, so that the flow can be measured, is practically always open and therefore water constantly leaks into the measuring room. In addition to increasing the aerosol activity the risk of postponing activities, not to mention the fact that it is being phased out Water additionally pollutes the wastewater treatment plant in terms of quantity.

The invention is therefore based on the object of the sampling device of the type mentioned in such a way that the samples from a closed Systems can be taken out to ensure safety from radioactive leakage Increase water.

This object is achieved according to the invention in that a return line is provided from the sampling panel to the condenser, and between the dispensing line and the return line at least one towards both lines Quick-release couplings (self-closing plug-in couplings) for connecting a Sampling container or the measuring device provided tapping line is provided, the is bridged by a bypass line.

The sampling device according to the invention can now be used in A sample can be taken through a closed system. The bypass line ensures that a representative range of tíedium is always available. The self-closing Couplings ensure that no radioactive liquid can escape.

Various devices can also be connected.

In terms of function, the sampling device according to the invention is of this type developed that in the bypass line at least one Ießgerqt firmly connected is. In this further development, the baskets at a certain sampling point permanently necessary measuring devices, such as flow meters, conductivity meters, etc. be built into the bypass line, which is constantly monitored by the person to be examined Medium is flowing through.

The sampling board can be in different ways depending on the task to be performed Extensive equipment, but this does not affect the external appearance and change the controls, d. H. the basic structure is the same for all sampling boards the same and the adaptation to the various measurement needs is carried out by a Art modular system. This has a very relieving effect on the operating personnel the end. Through a favorable selection of fittings and an inexpensive laying of the lines a contact design is achieved that ensures a space-saving installation.

An exemplary embodiment of the invention is explained with the aid of the drawing.

It show: -Fig. 1 in a schematic representation of the invention Sampling direction, Fig. 2 the structural design of the sampling panel.

The medium to be investigated flows in line 1, the main line, see e.g. water or steam in the direction of the arrow. The term main line is literally true to be understood as a single line; he should z. 3. also the main cycle of a Power plants include. The medium is radioactive, e.g. B. when the line 1 is the main steam line or represents the coolant circulation line of a nuclear reactor. To the main line 1, a dispensing line 2 is connected, which is opened by means of a shut-off valve 3 respectively.

can be closed. The shut-off valve 3 is followed by a sampling cooler 4, through which cooling water flows in the lockable ventilation system 5 and the water to be examined cools to the appropriate temperature or the water to be examined Steam condenses and adjusts to the appropriate temperature.

Behind the sampling cooler there is a reducing valve 6 in the dispensing line switched on. A temperature meter 7 is attached to the outlet line of the valve 6 and a pressure gauge 8 connected. The output line then forks of the valve o. One branch runs over a shut-off valve 9, a tapping line 10, with quick-release couplings on both sides, including self-closing ones Called plug-in couplings, a pressure holding valve 12 and the return line 13 back in Main line 1. The other branch 18 leads via the Shut-off valve 14, the conductivity meter 15, the flow meter 15 and the Pressure holding valve 17 in the return line 13, d. H.

also back to the main line 1. You can see that this branch 18 bridged the tapping line 10 in the bypass. The connection point of the return line to the main line depends in particular on the pressure conditions. Performs e.g. B. the main line high pressure (main steam line in the power plant), so the pressure in the sampling device, the pressure is reduced by means of a pump would have to increase if you reconnect the return line to the steam line would. The return line is then expediently led to a location with low pressure a, z. 3. in the condenser of the power plant in the main circuit.

A sampling container, for example, can now be attached to the tapping section 10 connected to the valves in the quick-release couplings through the corresponding nipples opens and lets water enter the sampling container. Take the sampling container out of the tapping line, the valves close automatically. Such Quick connect couplings are known in the art; they are e.g. Kurt Walther Company, Wuppertal, Bahnstr. 43ç51 delivered the quick release couplings prevent radioactive water from escaping from the tap, even if accidentally the shut-off valve 9 was not closed. The appearance of aerosol activity is thus avoided, since the sampling takes place in a closed container and there is open water in a small part of the system. Because the bypass line before the sampling is opened and the meduim is flowing through, one has A representative sample is always available at the tap 10. With the invention it is therefore possible to take a sample in the flow in a closed system perform.

The elements 3-18 are expediently central on a sampling board arranged from which then the dispensing line, 2 and the return line 13 to the Main line 1 leads 4. This sampling panel can be fixed as well as can also be used as a mobile sampling device. The sampling board is expediently designed in the modular system, as later with reference to FIG. 2 should be explained.

The necessary instruments and fittings depend on the to fulfilling measuring tasks, with some fittings in each case. So include the shut-off valve 3, the reducing valve 6, the shut-off valves 9 and 14, the dispensing line 10 and the pressure control valve 12 for basic equipment. Must also the temperature and the pressure are monitored, the measuring devices 7 and 8 are added. In the case of a donut-shaped medium or if the water to be examined is in the Main line unO 1 does not have the desired temperature, i, st the switch on of the heater 4 necessary. In Fig. 1 there is also e.in conductivity meter 15 and a flow meter 16 shown.

In addition, other measurements often have to be carried out, e.g. B. Investigation of the oxygen content, the contamination by solids and Like. For example, in the case of testing for contamination by solids a filter can be connected to the Zanfstrecken 10, in addition to this in this circle a second tapping line is provided in which a volume counter is switched on, so that you can later by comparing the solids deposited in the filter the measured flow rate can determine how large the specific Pollution is. In the case of Oxygen, a special steel bottle can be used Sampling can be connected to the tapping line 10.

With reference to FIG. 2, the structural design of the sample table is now intended explained. This Fig. 2 shows a rear view of the sample panel 19. Im The cooler is arranged on the left-hand side of the rear side of the panel 19, for reasons of clarity is not shown. The location of the cooler on the back of the sampling board brings inter alia with the advantage that the sampling board itself acts as a shield works because the cooler is generally weakly active. The sample water comes from the cooler to the regulating valve G, which has detachable pipe connections.

You can see the temperature and pressure of the sample water on the thermometer 7 or on the pressure gauge 8 can be read. rcer pieces 20 and 21 can now be the water flow in two pipe systems. Once it can enter the Typassleitung 18 flow in which the conductivity meter 15 and the flow meter 16 is connected, the pressure holding valve 17 (FIG. 1) not being shown in FIG. 2 is. In the other case, it can flow through the shut-off valve 9 into the tapping line 10, which opens into the return line 13 via the pressure holding valve 12. Through the shut-off valves 9 and 14 - the two branches can be released alternately. The Zapfstrecse 10 is used in the case of a nuclear power plant to take samples for O2 -) CI -, SiO2 - and Cu - determination and for solid-state analysis using a Millipore filter. For the 02 measurement becomes a 300 milliliter Stainless steel collecting cylinder with the not quick couplings shown, which are located on the front of the sampling panel are connected to the tapping line 10.

The water flows from the bottom up in the cylinder and fills it Completely. After the cylinder is filled, it is equipped with three-way stop valves locked at both ends of the cylinder and taken out of the line. To the Steel cylinder is welded to a nozzle, in which a multilayer silicone rubber membrane is screwed in. Through this rubber band you can use indection syringes the reagents for the O2 determination according to Winkler or Schumann are injected. After the reaction has taken place, the water from the steel cylinder is poured into an Erlenmeyer glass filled and titrated. This can be done directly at the measuring point or in the laboratory. A 500 milliliter plastic collecting cylinder is also used for the other determinations connected to the tapping line with quick-release couplings and filled. The water can taken from this collecting cylinder in the laboratory for the various determinations will. Since when using the plastic cylinder, a certain pressure is not may be exceeded is the pressure maintaining safety valve 12 in the line intended.

For the solid-state analysis, a Millkiporefiltration device is attached to the Tapping line coupled. The lower part is used to determine the filter throughput A small oval gear meter is coupled to the sampling panel in a manner not shown. In this case, the line after the valve 12 does not open directly into the return line 13, but ends in the oval gear counter, which is at the bottom approximately in the middle of the table is arranged. Of the The output of the counter is then with the return line 13 connected.

Is there a sampling point where there are no conductivity measurements have to be carried out, the devices 13 and 16 can be omitted. It leads in In this case, a line from the valve 14 directly into the return line 13, as shown in dashed lines in the lower part of the table ii.

The volume counter can be connected via a second, also with quick-release couplings equipped tapping line can be connected.

For all sampling points there will be only one steel cylinder, one Plastic cylinder, a filtration device and a Cva1radzähler required, the short-term to be connected to the respective sampling panel for sampling.

The structure of the sampling panel 19 is made so that the sampling devices look essentially the same regardless of how they are fitted on the front to have. Production can then take place in series. This is essentially due to this ensures that fittings or pipelines with detachable pipe fittings (Fittings) can be selected. These pipe fittings have proven themselves many times and they are also used as gas-tight fittings in gas chromatographs. Is z. B. the thermometer 7 is not required at a sampling point, so can From the T-piece 20 a line provided for this is led directly to the valve 6 and are screwed. If the ranometer 8 is not necessary, you can either on the top Part of the T-piece 21 has a corresponding Screw the plug or you can ire½t leaving out the T-piece screw a line from the T-piece 20 to the valve 19. To the standard equipment a sampling panel therefore includes the valves 6, 9 and 14, the T-piece 20 and the tapping line 10 with the corresponding couplings and pipelines. The sampling board has only 3 valves 6, 9 and 14 to be detached from each other, which are at the same height are arranged, regardless of the respective equipment.

The sampling board is very compact. It takes up little space and can therefore be connected anywhere. Furthermore, as already mentioned, it can also be used as a transportable sampling device.

Claims (12)

Claims 1. Sampling device for in lines (main line) flowing radioactive or aggressive liquid and vapor media, in which a dispensing line is led from the outlet line to a sampling board at which a tap and at least one measuring device is provided, d a d u r c h e k e n n n z e i c n e t that a return line (13) from the sampling panel to the condenser (1) is provided and between the Zacfuno return line (2, 13) at least one after both lines with quick-release couplings (self-closing plug-in couplings 11) tapping section provided for connecting a sampling container or the measuring device (10) is provided, which is bridged by a bypass line (18). 2. Sampling device according to claim 1, d a d u r c h g e k e n It is not indicated that in the bypass line - (18) at least one measuring device (15-17) is firmly connected. 3. Sampling device according to claim 1 or claim 2, d a d u r c h g e k e n n n z e i c h n e t that in the line branch receiving the tapping line and / or a pressure holding valve (12, 17) is arranged in the bypass line (18). 4. Sampling device according to claim 1 or one of the following, d a d u r c h e k e n n n z e i c h n e t that in which the tapping line takes up Line branch and in the bypass line (18) each have a shut-off valve (9, 14) is. 5. Sampling device according to claim 1 or one of the following, d a d u r c h e k e n n n z e i c h n e t that in the Zatfleitung (2) before the junction the line receiving the tapping line from the bypass line (18) has a shut-off device (3) and a reducing valve (6) is provided. 6. Sampling device according to claim 5, d a d u r c h g e k e n It is not indicated that a thermometer (7) is located between the branch and the reducing valve. and a pressure gauge (8) are connected to the dispensing line. ?. Sampling device according to claim 5 or 6, d a du r c h £ e it is not indicated that between the shut-off valve (3) and the reducing valve (6) a sampling cooler (4, 5) is switched on. 8. Sampling device according to claim 7, d a d u r c h g e 1 = e It is noted that the sampling cooler (4, 5) is on the back of the sampling panel ~ no order. is. 9. Sampling device according to claim 1 or one of the following, d a d u r c h g e k e n n n z e i c h n e t that two tapping routes are provided in series are. 10. Sampling device according to claim 9 and 3, d a d u r c h g e it is not indicated that the pressure holding valve of the tapping sections Line branch is arranged between the two dispensing lines. 11. Sampling device according to claims 4 and 5 or one of the the following, noting that the basic equipment forming shut-off valves (9, 14) and the reducing valve (6) and the tapping line (10) Regardless of the additional equipment on the sampling board at the same location the valves are preferably arranged at the same height on the sampling panel. 12. Sampling device according to claim 11, d a d u r c h g e k e n n z e i c h II e t that the pipe sections for the bypass line (18) and the line receiving the tapping line and the fittings connected in between Have detachable pipe screw connections (sittings). L e r s e i t e