JPS6141997A - Boiling-water type reactor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention has a turbine condenser and a waste gas system connected to the turbine condenser and configured in a redundant structure, and this waste gas system has two parallel It relates to a boiling water nuclear reactor having a steam jet pump, a shutoff valve, a preheater, a recombiner, a condenser and a gas outlet located in sequence in a branch pipe.

[Conventional technology]

Such boiling water reactors are described, for example, in the document
Cologne Craft Welks Seminar 1970 J
(VGB-Kern-kraftwerks-Se+
5inar 1970), page 111, and shown in FIG. 15 thereof. Among the redundant branch pipes of the waste gas system, one is operated normally and the other is stopped as a so-called standby device.

In this case, it has been confirmed that there are dangerous operating conditions when switching from one branch pipe to the other, especially when starting or switching on the standby device.

[Problem that the invention seeks to solve]

Starting from the above-mentioned problem, the object of the invention is to provide a boiling water reactor of the type mentioned at the outset, in order to further minimize the risk of ignitable mixtures forming in the waste gas system. The aim is to improve the operational readiness of the equipment.

[Means for solving problems]

According to the invention, this object is achieved in that a device for supplying steam and air in a quantity ratio of 1:10 or more is connected between the shutoff valve and the recombiner.

[Function and effect of the invention]

By starting the device according to the invention immediately before shutting down the branch pipe, which is in operation until it is re-energized, continuous cleaning occurs, reliably preventing the collection of hydrogen, and furthermore, continuous functional monitoring is possible. Become. In particular, the preheating can then be controlled by measuring the outlet temperature and the discharge of condensate by monitoring the filling level. The atomic hydrogen and atomic oxygen components contained in the vapor are inertized by the addition of air according to the invention. It is thus reliably prevented that the ignition limit of the 82102-air mixture is reached.

The device according to the invention preferably supplies air at a pressure less than half atmospheric pressure. The pressure is preferably 0.2-0
．． It is 4 bar.

Advantageously, the device comprises a steam jet pump which sucks in air and mixes it with steam. The above-mentioned type of steam jet pump in the branch piping of the waste gas system is generally used as shown in Figure 15 of the above-mentioned document, but the steam jet pump adopted in the present invention is significantly more advanced than this. small.

A steam jet pump can be connected to the preheat steam line leading to the preheater. This steam jet pump can also be supplied with drive steam together with another steam jet pump in the waste gas system.

An electrically operated shutoff valve may be provided on the suction side of the air line of the device. In that case, the air line can also be operated as a circulation path. This is made possible by connecting the suction side of the air line of the device to the gas outlet.

〔Example〕

The present invention will be described in detail below based on embodiments shown in the drawings. FIGS. 1 and 2 show different embodiments of one branch pipe in the exhaust gas system, which is the main part of the present invention, as shown in FIG. 15 of the above-mentioned document. Identical parts are given the same reference numerals.

The steam jet pump 3 is supplied with driving steam from a driving steam line 1 having a shutoff valve 2 and has an outlet 5 of the pump 3 which sucks waste gas from a turbine condenser (not shown) via a cooler 4. is connected via a pipe 7 with a check valve 8 to a water separator 9, which is connected before the preheater 10. Piping 11 connects preheater 10 to recombiner 1
In this recombiner 12, a catalytic reaction between hydrogen and oxygen takes place.

Piping 13 leads from recombiner 12 to condensate 514 with condensate outlet 15 . A recooler 16 is connected downstream of this condenser 14 . A pipe 17 comes out from this recooling 516, and this pipe 17 is connected to the cutoff valve 1-8 and the check valve 1.
9 leads to an outlet 20 to a common waste gas pipe 21 for two parallel branch pipes leading to separate waste gas treatment devices as shown in FIG. 15 of the above-mentioned document. ing. The gas outlet 20' of the other branch line is shown in broken lines.

The piping 7 includes the rear of the check valve 8 and the front of the recombiner 12,
In this embodiment, a steam jet pump 24 is connected in front of the water separator 9.

This pump 24 has a driving steam pipe 2 with a shutoff valve 25.
Driving steam is supplied from a preheating steam line leading to the preheater 10 via 3. The steam jet pump 24 is equipped with an electric shutoff valve 28 and a pressure-responsive control valve 2 operated with a specific medium.
Room air is sucked in via 9 in the direction of arrow 30, which room air is mixed with the driving steam at a pressure of 0.2 to 0.4 bar and conveyed via connection 31 to line 7. The mixing volume ratio is adjusted to a ratio of 1:25 between hydrogen (H2) and air in the steam by the cross-sectional areas of the steam nozzle and air nozzle (not shown) of the steam jet pump 24, thereby creating an ignitable mixture of hydrogen and oxygen. occurrence is definitely avoided.

A steam jet pump 24 is available to evacuate the preheater lO. Therefore, a degassing pipe 33 is provided between the upper part of the preheater 10 and the driving steam pipe 23 of the steam jet pump 24.
is provided.

In FIG. 1, the driving steam piping 1 of the steam jet pump 3
A line 35 shown in broken lines between the drive steam line 23 of the steam jet pump 24 and the drive steam line 23 of the steam jet pump 24 indicates that the connection to the preheating steam line 26 can be omitted.

In the embodiment in FIG. 2, the steam-air mixture supplied from the steam jet pump 24 to the line 7 is not generated by drawing in room air; the oxygen-free gas mixed with the steam is in the common waste gas line 21. The gas is extracted from the gas pipe 37 through the gas pipe 37. This line 37 is connected via two electrically controlled valves 38, 39 connected in series to an adjustable nozzle 40 at the inlet of the steam jet pump 24. In this embodiment, the steam jet pump 24 is supplied with driving steam from the pipe 1 via the pipe 35. However, it is also possible to use preheater steam in accordance with the embodiment of FIG.

Specifically, according to the present invention, H contained in the incoming steam is
Regardless of the catalytic reaction of the 2/02 components, the formation of ignitable mixtures is essentially prevented by mixing the corresponding inert gas components. This essentially prevents H2102 from concentrating in the event of a recombiner malfunction, as well as H2102 concentrating upstream of the recombiner in the flow direction.

Optimum heating of the entire recombiner-standby branch line is achieved continuously by the steam flow. At the same time, it is possible to continuously monitor functions such as the temperature and filling amount of the condensate discharge device and preheating device. For this purpose, existing measuring devices are used, namely a liquid level meter 42 and a temperature measuring device 43 (first
(see figure).

If the steam jet pump 3 is stopped, the steam supply reliably prevents the formation of an undesired vacuum and, even in the case of leakage points, a backflow to the turbine condenser.

If a previously inert recombiner branch line is introduced, no volume peaks with corresponding pressure shocks occur.

Furthermore, the inerted air only slightly increases the waste gas flow rate (approximately 2%).

[Brief explanation of drawings]

1 and 2 are system diagrams of waste gas piping of a boiling water reactor according to the present invention, respectively. 1: Steam piping, 3: Steam jet pump, 8: Shutoff valve,
10: Preheater, 12: Recombiner, 20: Gas outlet, 24
: Steam jet pump, 26: Preheating steam piping, 28: Shutoff valve.

Claims (1)

[Claims] 1) It has a turbine condenser and a waste gas system connected to the turbine condenser and configured in a redundant structure, and the waste gas system is sequentially located in two parallel branch pipes. steam jet pump,
In a boiling water reactor having a shutoff valve, a preheater, a recombiner, a condenser and a gas outlet, steam and air are provided between the shutoff valve (8) and the recombiner (12). 1:10
A boiling water nuclear reactor characterized in that a device (24) for supplying at the above quantity ratio is connected. 2) Boiling water nuclear reactor according to claim 1, characterized in that the device (24) supplies air at a pressure less than half atmospheric pressure. 3) Boiling water reactor according to claim 2, characterized in that the pressure is between 0.2 and 0.4 bar. 4) Boiling water type according to any one of claims 1 to 3, characterized in that the device comprises a steam jet pump (24) for sucking air and mixing it with steam. Reactor. 5) Boiling water reactor according to claim 4, characterized in that a steam jet pump (24) is connected to a preheating steam line (26) leading to a preheater (10). 6) Boiling water nuclear reactor according to claim 4, characterized in that the steam jet pump (24) is connected to a steam line (1) leading to another steam jet pump (3). . 7) The boiling device according to any one of claims 1 to 6, characterized in that the air pipe of the device (24) is equipped with an electric shutoff valve (28) on the suction side. Water reactor. 8) Boiling water type according to any one of claims 1 to 7, characterized in that the suction side of the air pipe of the device (24) is connected to the gas outlet (20). Reactor.