DE19602213C2 - Nuclear reactor with a cooling circuit - Google Patents

Description

The invention relates to a nuclear reactor with a cooling circuit.

There is usually a primary cooling circuit in a nuclear reactor provided for cooling the reactor core. That in primary cooling The cooling medium provided for the circuit depends on the type of reactor and can be water, in particular in a pressurized water reactor.

Radiolytic decomposition of the flowing in the cooling circuit Counteracting the cooling medium is usually fumigation of the cooling medium provided with hydrogen. For this purpose for example from the book "VGB Nuclear Power Plant Seminar 1970", especially page 41, a volume for a pressurized water reactor known control system that for feeding chemicals, especially hydrogen, in the cooling circuit of the nuclear reactor suitable is.

In the known system, the hydrogen is converted into a Vo volume expansion tank belonging to the lumen control system ben. The water entered is in the volume expansion tank substance as part of a gas cushion above the liquid level of the cooling medium. The hydrogen partial pressure in The gas cushion is made according to the desired water substance concentration set in the cooling medium.

Especially with regard to the control of the hydrogen concentrations However, such a system is inflexible in the cooling medium bel. The hydrogen concentration in the cooling medium is only be limits and can only be controlled according to delay times, as from the hydrogen concentration in the cooling medium the hydrogen partial pressure prevailing in the gas cushion only slowly settle out.  

A further development of the system described is from the Patent DE 28 28 153 known. The hydrogen fumigation of the Cooling medium takes place in the described in this document feed system additionally by means of a parallel to the Volume expansion tank switched bypass line. A Further training of this feed-in system is also from the Pa tent 28 28 153 granted additional patent 29 48 297 known, whereby the hydrogen is conveyed in a liquid jet compressor who works with the primary coolant as a liquid.

However, these systems are complex and therefore vulnerable feed system for the hydrogen. In particular on due to the possible formation of explosive gas mixtures at aus Hydrogen exiting the feed system must be the feed system are continuously checked for leaks.

From the published patent application DE 31 05 168 A1 is a core freak Gate system known in which a supply line of the cooling circuit directly to an electrolysis device for generating supply of hydrogen is connected.

The invention is based, with a nuclear reactor specify a cooling circuit in which a quick and exact Setting the hydrogen content in the cooling circuit coolant with a particularly simple and reliable Infeed system is guaranteed.

This object is achieved by the cooling circuit a hydrogen genera trained as a membrane electrolyzer Tor arranged for generating hydrogen for the cooling medium is.

A membrane electrolyzer is, for example, from the DE 31 23 665 A1 known.  

The invention is based on the consideration, the transfer routes for hydrogen to be particularly short. A  a suitable shortening of the transmission paths can be achieved by no central hydrogen storage and what hydrogen is produced near the place where its on supply is provided in the cooling circuit.

In the hydrogen genes designed as membrane electrolyzers rator is by variation of one conducted through the water Electricity makes the production of hydrogen particularly easy Way controllable. The resulting in addition to the hydrogen Oxygen can be used further, for example for a recombination of excess hydrogen in one ab gas system.

The amount of hydrogen generated is particularly flexible to be able to adapt the requirements in the cooling circuit and thus egg ne particularly reliable adjustment of the hydrogen content in the Ensuring the cooling medium is advantageously a number of hydrogen generators arranged decentrally such that ih re spatial distribution to the spatial distribution of water Material requirements in the cooling circuit is adjusted. The spatial distribution development of the hydrogen requirement is expediently on based on time averages of the hydrogen requirement selected positions of the cooling circuit.

To influence the what with particularly simple means To enable the cooling medium to contain hydrogen is described in partial configuration, the generation rate of the or each what Serstoffgenerators controllable, with a control in another advantageous embodiment based on electrical signals follows.

For a particularly reliable and flexible setting of a Predeterminable hydrogen content in the cooling medium is further advantageous embodiment of the or each hydrogen generator connected to a controller unit which is used to receive what Actual hydrogen values is connected to a hydrogen sensor.  

For this, a separate reg unit or one common to all hydrogen generators same controller unit can be provided.

In a further advantageous development, the cooling circuit comprises a volume expansion tank and a Um assigned to it Rolling loop in which one ver with a hydrogen generator  tied hydrogen feed point and one with this rule technically connected hydrogen sensor are switched.

Around the volume expansion tank and thus also its gas volume It is also advantageous to be able to lay out men particularly small a bypass line for the volume expansion tank intended.

The advantages achieved with the invention are in particular in that the hydrogen genes arranged on the cooling circuit rator the hydrogen to be supplied to the cooling medium in immediate bar near its feed in the cooling circuit can be produced. This makes complex storage and more prone to failure Transport of the hydrogen over long distances is not required Lich, so that maintenance work is minimized. In particular by a decentralized arrangement of a number of Hydrogen generators on the cooling circuit is also a special one flexible hydrogen that can be adapted to current requirements production possible.

An embodiment of the invention is based on a drawing tion explained in more detail. The figure shows schematically one Fumigation device for the primary coolant of a nuclear freak tors.

The gassing device 1 according to the figure is switched via a first wiring harness 2 and a second wiring harness 4 in a cooling circuit of a nuclear reactor, not shown in detail. The line 2 , which can be shut off with a valve 6, opens into a volume expansion tank 8 , which is filled up to a level 10 with water in the cooling circuit as the cooling medium K ge. A gas space 12 above the level 10 in the volume compensation tank 8 is connected via a nitrogen line 14 to a nitrogen supply and via an exhaust line 16 to an exhaust system.

The volume expansion tank 8 is connected via a coolant line 18 , in which a high-pressure pump 20 is connected to the two-th line 4 . To connect the first Lei line 2 with the second line 4 bypassing the volume expansion tank 8 , a bypass line 22 is arranged parallel to this, which can be shut off with a valve 24 and is closed at an opening 26 to the coolant line 18 .

Downstream of the junction 26 in the coolant line 18, a feed point 28 is provided, in which a connected to a What serstoffgenerator 30 and with a valve 31 from lockable hydrogen line 32 opens into the coolant line 18 .

On the high-pressure side of the high-pressure pump 20 , a line branch 34 branches off from the coolant line 18 and is connected to the volume compensating tank 8 via a hydrogen sensor 36 in the manner of a circulation loop.

The hydrogen generator 30 is a membrane electrolysis device in which a membrane arranged between two electrodes acts as a solid electrolyte. The hydrogen production of such an electrolyser is particularly easy to control by varying the electrical current supplied from a power supply 38 via the cables 37 . The oxygen thus generated O₂ is a to the hydrogen generator 30 to closed oxygen line 39 of a use, example, for a recombination of excess hydrogen in the exhaust system can be fed. The generated hydrogen H₂ can be fed into the cooling circuit via the hydrogen line 32 if necessary. However, it can also have a processing to the Wasserstofflei 32 connected, shut off by a valve 40 hydrogen branch line an alternative use be fed to the 42nd

The hydrogen sensor 36 is connected via a signal line 44 , into which a controller unit 46 is connected, to the power supply 38 of the hydrogen generator 30 in a control-technical connection.

During operation of the gassing device 1 , the concentration of hydrogen H₂ in the cooling medium K is continuously monitored by measuring the hydrogen content of a partial flow of the cooling medium K via the line branch 34 by means of the hydrogen sensor 36 . The measured values are supplied to the controller unit 46 as actual hydrogen values and compared with setpoints stored or predefinable there. If the actual value deviates from the target value, the controller unit 46 sends a control signal to the power supply 38 of the hydrogen generator 30 . On the basis of the control signal, an electrical current is generated by the power supply 38 and supplied to the hydrogen generator 30 . The latter then produces that amount of hydrogen, when it is fed into the coolant K, whose hydrogen content reaches the setpoint within predefined tolerances.

In addition to the hydrogen generator 30 further water generators can be provided, which are arranged in such a decentralized manner that their spatial distribution is adapted to the spatial distribution of the hydrogen requirement in the cooling circuit. Thus, each hydrogen generator 30 is arranged directly at the location of the hydrogen consumption. There is therefore no need to store hydrogen H₂ or to transport it over long distances.

Claims (5)

1. Nuclear reactor with a cooling circuit on which a hydrogen electrolyser designed as a membrane generator ( 30 ) for generating hydrogen for a cooling medium provided in the cooling circuit (K) is arranged. 2. Nuclear reactor according to claim 1, characterized in that a number of hydrogen generators ( 30 ) are arranged decentrally such that their spatial distribution is adapted to the spatial distribution of the hydrogen requirement in the cooling circuit. 3. Nuclear reactor according to claim 1 or 2, characterized in that the generation rate of one or each hydrogen generator ( 30 ) is electrically controllable. 4. Nuclear reactor according to one of claims 1 to 3, characterized in that each What serstoffgenerator ( 30 ) to a controller unit ( 46 ) is ruled out, which is connected to receive hydrogen actual values with a hydrogen sensor ( 36 ). 5. Nuclear reactor according to one of claims 1 to 4, characterized in that the cooling circuit comprises a volume expansion tank ( 8 ) and a circulation loop associated therewith, in which the hydrogen generator ( 30 ) and the control technology associated with this What serstoffsensor ( 36 ) are switched.