The field of the invention is the field of reactor coolant pump sets for nuclear pressurised water reactors (PWR).
The invention relates more particularly to a passive shutdown sealing device (SSD) capable of controlling a reactor coolant leak resulting from a failure in the system of seals present on the reactor coolant pump set.
Shutdown sealing devices (SSD) have been developed in new generation nuclear pressurised water reactors to cope with a failure of the reactor coolant pump set seal system following an accidental situation, called Station Black Out.
Thus, in this accident situation and after the reactor coolant pump has stopped, shutdown sealing devices must be capable of controlling and stopping a reactor coolant leak resulting from a failure of the reactor coolant pump set seal system.
Conventionally, this type of device is activated by an auxiliary source (for example such as a pressurised nitrogen circuit) and triggering is controlled by information output by the reactor instrumentation control, in case of losses of the cooling sources of the reactor coolant pump set.
A passive shutdown sealing device has been developed for which no auxiliary activation system, and no output of triggering information from the reactor instrumentation control are necessary in order to eliminate the need to use an activation source. Such a passive shutdown sealing device is disclosed in document WO 2010/068615.
However, the sealing device disclosed is a cumbersome device and its installation in a sealing system of a reactor coolant pump set is relatively complex.
In this context, the invention proposes to improve such a sealing device in order to reduce its size and thus its installation on shaft seal systems of reactor coolant pump sets in service.
To achieve this, the invention discloses a passive shutdown sealing device for a reactor coolant pump shaft seal system comprising:
a split sealing ring with an inactive position and an active position;
a separator made from a fusible material capable of changing state above a temperature threshold called the state change threshold, said separator holding said split sealing ring in its inactive position when the temperature of the device is less than the threshold state change temperature;
said device being characterised in that it comprises circular elastic means positioned around the split sealing ring, said elastic means being adapted to bring said sealing ring into its active position when the temperature is greater than or equal to the threshold change state value of said separator.
The expression “change state” means a modification to the mechanical properties of the fusible material.
With the invention, it is possible to stop a reactor coolant leak resulting from a failure of the reactor coolant pump set seal system without requiring an auxiliary activation source.
The design of the device according to the invention enables simplified installation on architectures of reactor coolant pumps already in service.
With the device according to the invention, it is also possible to adjust the device to operating constraints of each type of nuclear reactor by adjusting the self-activation temperature of the device, and more precisely by modifying the composition of the fusible element.
It is also possible to define a first temperature threshold of the material state change starting from which the fusible material separator changes state, in other words its mechanical properties change and an activation temperature threshold of the shutdown sealing device that might be different from and greater than the threshold state change temperature, starting from which the separator can no longer resist the force applied by the elastic means, thus bringing the sealing ring into its active position.
The passive shutdown sealing device according to the invention may also have one or several of the following characteristics taken individually or in any technically possible combination:
said elastic means bring said sealing ring into its active position when the temperature is greater than or equal to the value of an activation threshold of the device, the activation threshold temperature being greater than the threshold state change temperature;
said device is adapted to form part of a system of seals of a shaft in a reactor coolant pump set in service;
said split sealing ring is made from polymer resistant to temperatures exceeding 300° C.;
said split sealing ring is made from polyetheretherketone, or a composite with a polyetheretherketone matrix containing glass or carbon fibres;
said circular elastic means apply a compression force on said split sealing ring;
said split sealing ring comprises a peripheral annular groove capable of holding said circular elastic means;
said separator made from a fusible material is capable of mechanically resisting the force applied by the elastic means up to a temperature threshold of between 80° C. and 260° C., advantageously equal to 150° C.;
said separator and the split sealing ring are made in a single-piece;
said separator may be formed by a part independent from the split sealing ring and added onto the opening of the ring by attachment means.
Another purpose of the invention is a reactor coolant pump set comprising:
a system of seals adapted to create a controlled leak forming along a leakage path formed along the shaft of the reactor coolant pump set;
a passive shutdown sealing device according to the invention adapted to at least partially close off said leakage path of said seal system when said seal system is defective and when said sealing ring is brought into its active position by said circular elastic means so as to create a controlled leak.
Other characteristics and advantages of the invention will become clearer after reading the following description given for information and in no way limitative with reference to the appended figures among which:
For more clarity, identical or similar elements are marked with identical references in the figures.
Coolant pumps of pressurised water reactors are of the centrifugal type with vertical axis. The dynamic leak tightness at the shaft outlet 10 (
The first stage is called seal No. 1. Seal No. 1 reference J1 is a hydrostatic seal with a controlled leak. During normal operation, a leakage flow represented by arrow F1 forms along the shaft 10.
In an accident situation, the coolant temperature at the entry to seal No. 1 rises very quickly to reach a value close to the temperature of the reactor coolant system, namely about 280° C. At this temperature, the performances of seal No. 1 are degraded which very quickly increases the leakage flow that can exceed 10 m3 per hour. Passive shutdown sealing devices (SSD) are intended to block off the leakage flow F2 in this situation downstream from seal No. 1 without using an activation source.
Advantageously, the SSD device 20 according to the invention is placed on the leakage path F2 and more precisely in the zone represented by the reference Z, so as to be able to block off the leakage flow along the shaft 10 during an accident situation.
Furthermore,
The shutdown sealing device 20 according to the invention comprises:
a split sealing ring 23 placed concentrically around the shaft 10 of the reactor coolant pump set;
elastic means 22 adapted to circumferentially stress the split sealing ring 23 in compression;
a separator 27 shown in
The shutdown sealing device 20 according to the invention may also comprise a first contact ring 24 formed between the bushing 15 of the seal No. 1 and the split sealing ring 23 and a second contact ring 26 located at the contact of the split sealing ring 23 and that can come into contact with the support part of the floating assembly of seal No. 1.
For example, the first contact ring 24 is made from steel or a nickel alloy. The second contact ring 26 has a chrome-plated face in contact with the sealing ring 23. The chrome-plated coating of the face in contact with the sealing ring 23 reduces the coefficient of friction between the sealing ring 23 and the second ring 26. If the pumps are stopped due to a power supply failure (SBO), the shutdown device 20 may be triggered by an increase in the temperature before the pump shaft is completely stopped. Consequently, such a chrome-plated coating will prevent damage to the second sealing ring 26.
The sealing ring 23 has a peripheral groove 25 around its external periphery, the shape and dimensions of which are adapted to hold the elastic means 22.
The split sealing ring 23 is held in its inactive position as shown in
The choice of the polymer for the fusible separator and its dimensions are chosen as a function of the required degradation temperature. Advantageously, the separator 27 is characterised so as to be able to resist the force applied by the elastic means 22 up to a temperature threshold of between 80° C. and 260° C. and advantageously equal to 150° C.
In the embodiment shown in
Thus, under normal operation conditions (
Under accident conditions (
Depending on the nature of the fusible material used, it is also possible to define a first threshold state change temperature of the material starting from which the fusible separator 27 begins its state change, in other words when its mechanical properties are modified, and a threshold activation temperature of the shutdown sealing device starting from which the fusible separator 27 collapses because it is no longer capable of resisting the force applied by the elastic means 22, thus bringing the sealing ring 23 into its active position.
Thus, in a first embodiment, the device 20 trips (corresponding to the threshold state change of the fusible separator 27 being exceeded) at the same time as the device is activated. In this variant embodiment, losses of mechanical properties take place almost instantaneously.
In a second variant embodiment, there is a delay between when the device is activated due to the threshold state change temperature being exceeded and when the device 20 is activated. In this variant, losses of mechanical properties take place progressively and lead to a collapse of the fusible separator 27 at a different moment and/or at a higher temperature than the threshold state change temperature.
The fusible separator 27 advantageously has notches 28 or zones in which the material is thinned, capable of guiding buckling and deformation of the fusible separator 27. Such notches 28 can for example be used to guide deformation of the separator along the axial direction or along the radial direction of the sealing ring 23.
According to one example embodiment shown in
It might be necessary to provide a free space in the vicinity of the fusible separator to avoid hindering deformation of the separator so as to facilitate deformation by buckling of the fusible separator 27 and so that the shutdown device 20 is satisfactory activated. For example, this space may be a notch (not shown) in the bushing 11 of the seal No. 1 facing the circumferential position of the fusible separator 27 in the case of a radial deformation of the fusible separator 27.
Since the sealing ring 23 is no longer held in its rest position, the force applied by the elastic means 22 surrounding the sealing means 23 modifies the diameter of the sealing ring 23 such that the sealing ring is pressed in contact with the shaft of the rotor 10.
Thus, under accident conditions, the sealing ring 23 blocks the leakage path F1 due to the circumferential force applied by the elastic means 22 combined with the loss of mechanical properties of the separator that no longer performs its separation function.
Secondly, the leak is blocked in addition by the autoclave effect induced by the increase in pressure upstream from the sealing device 20 in the active position.
According to one example embodiment, the sealing ring 23 of the shutdown device 20 may be made from a polymer material resistant to high temperatures (i.e. higher than 300° C.), for example such as polyetheretherketone (PEEK) or a PEEK composite containing glass or carbon fibres. The use of such a material can result in a sealing ring that changes to a rubbery state at high temperature in which it can deform to match the geometry of its environment and thus give a better sealing quality. In this embodiment, the nature of the fusible separator 27 and the nature of the body of the sealing ring 23 are the same and they are advantageously made of a single piece.
According to a second embodiment shown in
Thus, for example, the fusible separator 127 can be made from PEEK containing carbon fibres and the sealing ring 123 can be made from graphite.
This second embodiment can simplify the design of the sealing ring 123 and can form an overlap at the opening of the ring 123 so as to increase the efficiency of the seal. The fusible separator 127 may be assembled on the sealing ring 123 using various methods; preferably, the assembly is of the mortise and tenon type.
Number | Date | Country | Kind |
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1256005 | Jun 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2013/051473 | 6/25/2013 | WO | 00 |