FR2670906A1 - MEASURING DEVICE FOR DETERMINING GAMMA ACTIVITIES IN GASEOUS MEDIA. - Google Patents

Abstract

Measuring device comprising a large number of sampling vessels (2) provided with means, such as filters, for fixing a radioactive substance transported by a gaseous medium to be tested. The sample containers are placed one by one, using a trolley (1) in a detection installation (3), equipped with a removable bell (4). They are placed in contact with the gaseous medium to be controlled after closing the installation, for the appropriate time, then evacuated by a discharge installation (5).

Description

Measuring device for determining gamma activities

in gaseous media.

  The invention relates to a measuring device for determining gamma activities in gaseous media. Such devices are generally known and consist of a detection installation on which, or in which, a dusty filter is introduced. This is used, for detecting radioactive iodine in the gaseous discharges from installations nuclear energy, activated carbon sampling containers, which are introduced into the detection installation to measure gamma activity In the case of aerosols, filter strips are moved through the detection installation, and, during the discontinuous movement of the band, the filter band in the detector is dusted, that is to say that the gaseous rejection is pumped through the filter band, the gamma radioactivity is measured and interpreted Then the filter strip advances a length, so that a new free element is in

place for the next measurement.

  All these devices have in common that, in the event of an incident, that is to say for a gamma activity multiplied by a high factor, they are not able to measure exactly this quantity

  increased over a relatively long period of time.

  The invention has therefore set itself the aim of improving the measuring device of the type described at the start so that, when an increase in radioactivity occurs, as, for example, in the case of incidents in nuclear technology installations, radioactivity is measured by this device on a

longer period of time.

  This problem is solved according to the invention, by providing that the device is equipped with a magazine receiving a large number of sampling containers and a carriage which can move back and forth with different, adjustable speeds, and having an opening for each time receiving a sampling container. 5 According to the advantageous methods, the sampling container is placed between a detection device, a closing bell which can be raised or lowered, and seals, so that the closing bell 10 rests in a gas-tight manner. , on the detection device, the trolley is equipped with an electropneumatic control piston, which rejects the sampling container so that it is evacuated by a

  exhaust pipe so as to have no further influence on the measurements of the device.

  There is shown schematically in the drawing, by way of example, an embodiment of the material of the invention.20 The measuring device consists of a carriage 1, guided and mounted so as to be able to move horizontally , comprising an opening la, for receiving the sampling containers 2, as well as a detection installation 3, which is equipped with a bell 4 which can be raised or lowered electropneumatically, and a rejection station 5 provided with a discharge conduit, through which the sampling containers 2 are discharged The sampling containers 2 are arranged, "stacked" one above the other, in a magazine 6, an electropneumatic barrier 7 now in a fixed position the stack of sampling containers, so that only one container of these can "fall" at a time into the opening la The sampling container 2 is kept fixed in the opening la trolley 1 to by means of an electropneumatic control piston 8, such that seals 9 and 10, placed between the detection installation 3 and the closing bell 4,

  are not damaged during movement of the carriage 1. Thanks to the seals 9 and 10, the closing bell 4 rests in a sealed manner on the detection installation 3.

  The sampling vessels 2 are equipped with filters, not shown, these filters being defined as a function of the type of gamma activity to be highlighted, such as, for example, an activated carbon filter for the

determination of radioactive iodine.

  The closing bell 4 is equipped with a bore II which can be supplied, via a line 12 and an electro-valve 13, with the gaseous medium, which must be controlled A bypass line 14, is connected in front of the solenoid valve 13 This bypass line 14 is also connected, by means of an electro-valve 15, to the pump 16 The pump 16 is likewise connected by a solenoid valve 17 and a line 18, with the detection installation 3 of 20 such that the gaseous medium which must be controlled, can be pumped towards the evacuation pipe passing through the solenoid valve 13, the line 12, the bore 11, the closure bell 4, the sampling container 2, the detection installation 3, the

line 18, pump 16.

  The carriage 1 is driven, by means of an endless screw 19, itself driven, by means of a toothed belt 21, by an electric motor 20 with two directions of rotation, and the speed of rotation of which is adjustable. in stages The different positions of the carriage 1 are indicated on the drawing completely to the left, by "LOADING", that is to say brought from the sampling container 2; in the middle, by "MEASUREMENT", that is to say that the sampling container 2 receives through the gaseous medium, which must be controlled, and that the gamma activities are measured; and, completely to the right, by "REJECT", that is to say that the sample container 2 is rejected by means of the control piston 8 Both the closing bell 4 and also the detection installation 3 are protected from external influences by

a lead coating.

  The operating mode of this measuring installation is as follows: In order to avoid current voltage spikes during the operation of the installations, the pump 16 operates at constant speed of rotation As long as no sample container 2 is is placed in the "MEASUREMENT" position, the valve 15 is open and the valves 13 and 17 are closed The pump 16 sucks, by the by-pass pipe 14, the gaseous medium, which must be measured, and discharges it into the reject line not shown If, then, the electropneumatic barrier 7 of the magazine opens, a sample container 2 falls into the openings la of the carriage 1 (as shown) The electropneumatic control piston 8 blocks this sample container 2 in the opening la of the carriage 1, while the electropneumatic barrier 7 of the store, once again closed, prevents the next container 2

"descend lower".

  By means of an endless screw 19 which is driven, by means of a toothed belt 21, by an adjustable speed motor 20, the carriage 1 can move horizontally, with an adjustable speed, forwards and backwards , in such a way that it can be moved to the "MEASUREMENT" position, to the right in the drawing. This position is reached when the sample container 2 is placed between the closing bell 4 and the detection installation 3 , so that the closing bell 4 lowers down and closes this

gas tight area.

  The valve 15 is closed. The valves 17 and 13 are opened, so that the pump 16 then delivers the gaseous medium, which must be controlled, via the line 12 and the connection 11, through the sample container 2, and , through line 18 and pump 16, it is

  again pushed back into the reject line.

  In this operation, it is obvious that the pump 16 never works against a closed member, that is to say that the valves 13, 15 and 17 are always open and closed so that the pump 16 works in a

free pipe network.

  The detection installation 3 then measures the gamma activities of the medium to be checked, which are now carried by the sampling container 2, and analyzes them, in a manner known per se, by means of a

  electronic data processing, not shown.

  After the end of this measurement, and the closing of the valves 13 and 17 and the opening of the valve 15, the carriage 1 is made to move to the "REJECT" position. The electropneumatic control piston 8 is actuated so that the sample container 2 is rejected, as shown diagrammatically, and sent to the discharge pipe of the reject station 5 The direction of rotation of the electric motor 20 is then changed. Therefore, the carriage 1 is pushed back to the left until 'until it has again reached the "LOADED" position, below the magazine 6 The next sample container 2 can then be taken over by the carriage 1, and the operation

  be restarted, as described.

Claims (3)

  1 measuring device for determining gamma activities in gaseous media, characterized in that it is equipped with a magazine (6) receiving a large number of sampling containers (2) and a carriage (1) capable of move back and forth with different speeds, adjustable, and having an opening (la) to receive each time a sampling container (2). 2 Measuring device according to claim 1, characterized in that the sampling container (2) is arranged between a detection device (3), a closing bell (4) which can be raised or lowered, and seals sealing (9 and 10), so that the closing bell (4) rests in a sealed manner against   gas, on the detection device (3).   3 Measuring device according to claim 1, characterized in that the carriage (1) is equipped with an electropneumatic control piston (8), which rejects the sampling container (2) so that the latter is evacuated by a conduit evacuation so as not to exert   no further influence on the measurements of the device.