EP3825199B1 - Method and system for controlling the functionality of movable sealing elements of ventilation ducts of rolling stock - Google Patents

Description

TECHNICAL AREA

The invention relates to the field of air distribution and ventilation in rolling stock.

The invention relates more particularly to the field of sealing the ventilation ducts of rolling stock.

PRIOR ART AND DISADVANTAGES OF PRIOR ART

In known manner, air renewal and, where appropriate, air conditioning installations in rolling stock, for example rolling railway stock, include ventilation ducts - or ducts - to ensure the circulation of air on the one hand from the outside to the inside of the rolling stock, and on the other hand from the inside to the outside of the rolling stock. The documents JP S51 160308 U , FR 2 728 526 A1 And US 2019/023121 A1 describe examples of rolling stock including a ventilation device.

In addition, in order to maintain constant the air pressure prevailing inside the rolling stock, the installation also includes mobile motorized sealing elements, typically sealing shutters, at the level of the air inlets in the rolling stock - we then speak of air inlet flaps - and at the level of the air outlets of the rolling stock - we then speak of air extraction flaps. These shutters are motorized and controlled between an opening position of the air inlets and/or outlets and a closing position of said air inlets and/or outlets. The opening position of the shutters is associated with an opening functionality ensuring optimal circulation of air in the ventilation ducts, while the closing position of the shutters is associated with a sealing functionality ensuring the watertight closure of said conduits.

Thus, when the rolling stock approaches an area causing a sudden variation in the air pressure around the rolling stock, such as when crossing a tunnel, the motorized shutters are closed beforehand to avoid pressure gradients inside. rolling stock and thus preserve the eardrum comfort of users. These shutters are also ordered to close when the rolling stock approaches an area where the outside air is or risks being polluted, for example by industrial fumes.

This solution nevertheless has drawbacks. Indeed, if it is possible to detect breakdowns of the shutter motorization means, it is not possible to detect the actual functionality of said shutters. Thus, a shutter can be deformed, which would prevent any correct sealing functionality of the latter, or remain blocked in opening or closing, even if the motorization means operate normally.

OBJECTIVE OF THE INVENTION

The invention therefore aims to propose a method and a system for controlling the functionality of the sealing shutters of ventilation ducts of rolling stock, independent of the motorization means of said shutters.

STATEMENT OF THE INVENTION

1. i. Envoi d'une commande d'ouverture d'au moins une porte d'accès à l'extérieur du matériel roulant, laquelle porte est initialement fermée ;
2. ii. Concomitamment à l'ouverture de la porte, détermination d'au moins un paramètre lié à ladite ouverture de porte ;
3. iii. Une fois la porte d'accès ouverte, enregistrement du paramètre déterminé dans une zone mémoire des moyens de traitement et de commande ;
4. iv. Détermination de la différence entre le paramètre déterminé et un paramètre de référence enregistré dans la zone mémoire ;
5. v. Si la valeur absolue de la différence est supérieure ou égale à un seuil déterminé, génération d'une donnée associée à une fonctionnalité défectueuse d'au moins un élément mobile d'étanchéité.

To this end, the invention relates to a method for controlling the functionality of mobile sealing elements of a ventilation device of rolling stock, which mobile elements are arranged in ventilation ducts of said ventilation device and are motorized between an opening position associated with an opening functionality of said mobile elements ensuring optimal circulation of air in the ducts, and a closing position associated with a sealing functionality of said mobile elements ensuring the watertight closure of the ducts, which method is implemented by processing and control means embedded in the rolling stock and comprises the successive steps of:

1. i. Sending a command to open at least one access door to the exterior of the rolling stock, which door is initially closed;
2. ii. Concomitantly with the opening of the door, determination of at least one parameter linked to said door opening;
3. iii. Once the access door is open, recording of the determined parameter in a memory area of the processing and control means;
4. iv. Determination of the difference between the determined parameter and a reference parameter recorded in the memory area;
5. v. If the absolute value of the difference is greater than or equal to a determined threshold, generation of data associated with defective functionality of at least one mobile sealing element.

• Le procédé comprend une étape de génération d'une alerte associée à la fonctionnalité défectueuse d'au moins l'élément mobile d'étanchéité.
• Les moyens de traitement et de commande déterminent au cours de l'étape ii le temps d'ouverture de la porte d'accès.
• La porte comprend un dispositif d'ouverture motorisé piloté par les moyens de traitement et de commande qui déterminent au cours de l'étape ii une fonction de couples représentant le couple exercé par le moteur durant l'ouverture de la porte d'accès en fonction du temps.
• Le procédé comprend une étape préliminaire d'envoi d'une commande d'ouverture ou de fermeture des dispositifs mobiles d'étanchéité.
• Le dispositif de ventilation comprenant au moins un élément mobile d'entrée d'air dans le matériel roulant et un élément mobile d'extraction d'air hors du matériel roulant, caractérisé en ce qu'il comprend en outre les étapes suivantes :
  • Lorsque le procédé est mis en oeuvre suite à une commande de fermeture étanche des éléments mobiles, génération d'une donnée indiquant que la fonctionnalité d'étanchéité de l'élément mobile d'extraction est défectueuse si la différence entre le paramètre déterminé et le paramètre de référence est supérieure au seuil déterminé, et génération d'une donnée indiquant que la fonctionnalité d'étanchéité de l'élément mobile d'entrée est défectueuse si la différence entre le paramètre de référence et le paramètre déterminé est supérieure au seuil déterminé;
  • Lorsque le procédé est mis en oeuvre suite à une commande d'ouverture des éléments mobiles, génération d'une donnée indiquant que la fonctionnalité d'ouverture de l'élément mobile d'entrée est défectueuse si la différence entre le paramètre déterminé et le paramètre de référence est supérieure au seuil déterminé, et génération d'une donnée indiquant que la fonctionnalité d'ouverture de l'élément mobile d'extraction est défectueuse si la différence entre le paramètre de référence et le paramètre déterminé est supérieure au seuil déterminé.

Le procédé comprend les étapes supplémentaires successives de :

• Envoi d'une commande de fermeture de la porte d'accès ;
• Une fois la porte fermée, envoi d'une commande antagoniste à la commande d'ouverture ou de fermeture des éléments mobiles envoyée durant l'étape préliminaire ;
• Répétition des étapes i à iii et enregistrement d'un second paramètre déterminé ;
• Détermination de la différence entre le paramètre déterminé à l'étape iii et le second paramètre déterminé à l'étape précédente ;
• Si la différence est inférieure à une valeur limite, génération et envoi d'une alerte de dysfonctionnement de la motorisation de la porte d'accès, sinon, génération d'une alerte associée à une fonctionnalité défectueuse d'au moins un élément mobile d'étanchéité.

The process may also include the following optional characteristics considered in isolation or in all possible technical combinations:

• The method comprises a step of generating an alert associated with the defective functionality of at least the mobile sealing element.
• The processing and control means determine during step ii the opening time of the access door.
• The door comprises a motorized opening device controlled by the processing and control means which determine during step ii a torque function representing the torque exerted by the motor during the opening of the access door in operation time.
• The method includes a preliminary step of sending a command to open or close the mobile sealing devices.
• The ventilation device comprising at least one mobile element for entering air into the rolling stock and a mobile element for extracting air from the rolling stock, characterized in that it further comprises the following steps:
  • When the method is implemented following a command for tight closing of the mobile elements, generation of data indicating that the sealing functionality of the mobile extraction element is defective if the difference between the determined parameter and the parameter reference value is greater than the determined threshold, and generation of data indicating that the sealing functionality of the mobile input element is defective if the difference between the reference parameter and the determined parameter is greater than the determined threshold;
  • When the method is implemented following a command to open the mobile elements, generation of data indicating that the opening functionality of the mobile element input is defective if the difference between the determined parameter and the reference parameter is greater than the determined threshold, and generation of data indicating that the opening functionality of the mobile extraction element is defective if the difference between the reference parameter and the determined parameter is greater than the determined threshold.

The process comprises the successive additional steps of:

• Sending a command to close the access door;
• Once the door is closed, sending a command opposing the opening or closing command for the mobile elements sent during the preliminary stage;
• Repeating steps i to iii and recording a second determined parameter;
• Determination of the difference between the parameter determined in step iii and the second parameter determined in the previous step;
• If the difference is less than a limit value, generation and sending of a malfunction alert of the motorization of the access door, otherwise, generation of an alert associated with defective functionality of at least one mobile element of waterproofing.

The invention also relates to a system for controlling the functionality of mobile sealing elements of a ventilation device of rolling stock, which rolling stock comprises at least one access door to the outside, which mobile elements are arranged in ventilation ducts of said ventilation device respectively at an air inlet inside the rolling stock and an air outlet outside the rolling stock and are motorized between a position d opening associated with an opening functionality of said movable elements ensuring optimal circulation of air in the ducts, and a closing position associated with a sealing functionality of said movable elements ensuring the watertight closure of the ducts, which system is provided for be embedded in the rolling stock and comprises processing and control means comprising a memory area and configured to implement the method as described above.

• Les éléments mobiles sont des volets d'étanchéité.

The system may also include the following optional features considered separately or in any possible technical combination:

• The moving elements are sealing flaps.

The invention finally aims at rolling railway equipment comprising at least one passenger car, each car comprising a ventilation device comprising an air inlet inside the car and an air outlet towards the outside of the car, the ventilation device further comprising two mobile sealing elements arranged respectively at the air inlet and the air outlet, the mobile elements being motorized between an open position and a watertight closing position of the air inlet and the air outlet, characterized in that it comprises a system for controlling the functionality of the mobile sealing elements as described previously.

PRESENTATION OF FIGURES

• [Fig. 1] La figure 1 représente une vue schématique de l'intérieur d'une voiture-voyageurs d'un matériel ferroviaire roulant ;
• [Fig. 2] La figure 2 représente une vue schématique de l'intérieur d'une alternative de réalisation de voiture-voyageurs d'un matériel ferroviaire roulant.

Other characteristics and advantages of the invention will emerge clearly from the description given below, for information only and in no way limiting, with reference to the appended figures among which:

• [ Fig. 1 ] There figure 1 represents a schematic view of the interior of a passenger car of rolling railway equipment;
• [ Fig. 2 ] There figure 2 represents a schematic view of the interior of an alternative production of passenger cars of rolling railway equipment.

DETAILED DESCRIPTION OF THE INVENTION

It is firstly specified that in the figures, the same references designate the same elements whatever the figure in which they appear and whatever the form of representation of these elements. Likewise, if elements are not specifically referenced in one of the figures, their references can easily be found by referring to another figure.

It is also specified that the figures essentially represent one embodiment of the object of the invention but that there may be other embodiments which meet the definition of the invention.

The invention can be applied to all types of vehicles equipped with a ventilation device ensuring renewal of the interior air with air from outside the vehicle. vehicle, and applies more particularly to railway rolling stock, and even more particularly to passenger trains traveling at high speeds, such as mainline trains including high-speed trains. In the remainder of the description, we will use the term “train”, knowing that the invention can apply to any type of vehicle, railway or not.

The train comprises at least one passenger car 1, 1' designed to accommodate passengers, and most often, the train comprises a plurality of these passenger cars 1, 1'. The train also includes a ventilation device, which comprises a plurality of ventilation ducts or ducts, most of which communicate with the exterior of the train, to allow an exchange of air between the interior and exterior of the train. Typically, each passenger car 1, 1' comprises at least one air inlet 9 allowing outside air to enter the car 1, 1' via the conduit considered, and at least one air outlet 10 allowing the interior air to be extracted from the car 1, 1' via the conduit in question.

The ventilation device comprises, at each of its air inlets and its air outlets, a mobile sealing element 7, 8 provided in the ventilation duct in question. This mobile element is preferably a sealing flap 7, 8, and will be named thus in the remainder of the description.

By convention, the flap 7 arranged at an air inlet 9 is a so-called air inlet flap 7, while the flap 8 arranged at an air outlet 10 is a so-called d flap. air extraction 8. These flaps 7, 8 are controlled by processing and control means of known type, on board the train, and are movable between an open position allowing the air to circulate in the conduit considered and a tight closing position of the conduit considered.

Under normal operating conditions, the sealing shutter 7, 8 in its open position is associated with a so-called circulation functionality ensuring optimal circulation of air in the ventilation duct considered, while the shutter 7, 8 in its closed position is associated with a so-called sealing functionality ensuring the watertight closure of said conduit. These notions will be developed further, in connection with abnormal operating conditions of shutters 7, 8.

The ventilation device also includes means for circulating air between the interior and exterior of the train, as well as means for air conditioning the air entering the train. The means of air circulation and the means of air conditioning are of known type, distributed in all the passenger cars 1, 1' and controlled by the processing and control means, which we will call for simplicity "control means" in the remainder of the description.

In reference to the figure 1 , which illustrates two adjacent passenger cars 1 of the same train according to a first embodiment, each passenger car 1 comprises a passenger room 2 and an access room 3 to said car, adjacent to the passenger room 2 These two rooms 2, 3 are separated by a door called room 5, operable by travelers. Advantageously, this door 5 is motorized between these two open and closed positions, and controlled by the control means.

The passenger car 1 also includes an access door 4 provided at the level of the access room 3, which allows travelers to enter or exit the car 1. This access door includes an opening device and motorized closing which is controlled by the on-board control means.

In addition, the access door 4 comprises at least a first seal formed on the periphery of the door, which seal is intended to come into contact with a second seal provided on the contour of the door. access opening provided in the chassis of the passenger car 1.

To allow passengers to circulate throughout the train, each car 1 includes a so-called intercirculation door 6 operable by travelers between its open and closed positions, which door 6 is preferably motorized and controlled by the control means. When this intercirculation door 6 is open, the traveler can pass from the access room 3 of a car 1 to the passenger room 2 of the adjacent car 1, and vice versa.

Finally, part of the air circulation and air conditioning means (not shown) are housed in the passenger room 1. These circulation and air conditioning means are connected to a first end of a first ventilation duct, the second of which end opens towards the outside of the train, and at a first end of a second ventilation duct whose second end also opens towards the outside of the train.

The second end of the first conduit is the air inlet 9, so that the flap 7 arranged at this second end is the air inlet flap 7 in the car 1. In addition, the second end of the second conduit is the air outlet 10, so that the flap arranged at this second end is the air extraction flap 8 of the car 1.

An alternative embodiment of the passenger car 1', part of which is represented on the figure 2 . The passenger car has two floors, respectively upper and lower, each including a passenger room. There figure 2 represents the passenger room 2' of the lower floor. The passenger car 1' includes, in addition to the passenger room 2' and the access room 3', a closed technical room 15, not accessible to passengers and adjacent to the passenger room 2'.

The technical room 15 includes part of the air circulation and air conditioning means 14, as well as the first conduit whose second end communicates with the exterior of the train to form the air inlet 9. The air therefore enters in the technical room and circulates in the first conduit towards the air conditioning means 14. The air conditioned air then circulates according to arrows 12 and 13 of the figure 2 towards the passenger room 2' via a third conduit provided in the technical room 15, connected by a first end to the circulation and air conditioning means 14 and a second end of which opens into the passenger room 2'.

Advantageously, the circulation and air conditioning means 14 comprise a fourth conduit provided in the technical room 15, a first end of which is connected to said circulation and air conditioning means 14 and a second end of which opens into the passenger room 2'. This fourth conduit allows the return 11 of part of the air from the passenger room 2' to the circulation and air conditioning means 14. In addition, the circulation and air conditioning means 14 comprise a regulating device (not shown ) which results in the air entering 12 in the passenger room 2' being a mixture between the air coming directly from the outside 9 and the air coming from the air return 11. This regulation device optimizes the energy consumption by the circulation and air conditioning means 14 while guaranteeing air quality in the passenger car 1' adapted to the transport of passengers.

Whatever the type of passenger car 1, 1', the shutters 7, 8 are motorized by appropriate means between an open position ensuring air circulation and a watertight closing position of the ventilation ducts. The shutters 7, 8 being controlled by the control means, it is possible for a user to know at any time the theoretical position of the shutters 7, 8, from the last command sent to the motorization means of said shutters 7, 8.

However, the control means are not able to detect a malfunction of the motorization of the shutters 7, 8. For example, a shutter 7, 8 controlled in closing can remain blocked in the open position, or a shutter 7, 8 controlled in opening can remain blocked in the closed position, without the control means allowing the detection of the problem. The control means are also not able to detect a structural defect of the shutter 7, 8, for example a deformation of said shutter which would prevent any watertight closure even if the motorization of the shutter 7, 8 were operating.

Thus, in the two cases presented above, the planned functionality of the shutter 7, 8 is defective because it is contrary to the expected functionality following the command sent by the control means.

According to the invention, the train comprises a system for controlling the functionality of the flaps 7, 8, independent of the motorization means of said flaps. Indeed, the opening behavior of the access door 4, 4' to the passenger car 1, 1' depends directly on the flap 7, 8 whose functionality is defective.

In particular, following a command to close the shutters 7, 8 and when the sealing functionality of the inlet flap 7 is defective, or following a command to open the shutters 7, 8 and when the circulation functionality of the extraction flap 8 is defective, then the ambient air pressure in the passenger room 2, 2' will increase significantly (since in both cases the extraction flap 8 is closed while the inlet flap 7 is either open or damaged, which allows air to enter the car 1, 1' but not to exit). This overpressure results in a more rapid opening of the access door considered 4, 4' compared to a determined average time, the value of which is recorded in a memory area of the control means. Furthermore, the torque exerted by the motor of the access door 4, 4' is less than a determined torque whose value is recorded in the memory space of the control means.

Similarly, following a command to close the shutters 7, 8 and when the sealing functionality of the extraction flap 8 is defective, or following a command to open the shutters 7, 8 and when the functionality of circulation of the entrance flap 7 is defective, then the ambient air pressure in the passenger room will decrease slightly (since in both cases the extraction flap 8 is either open or damaged while the entrance flap 7 is closed, which allows air to exit the car 1.1' but not to enter). This depression results in a slower opening of the access door considered 4, 4' compared to the determined average time. Furthermore, the torque exerted by the motor of the access door 4, 4' is greater than the determined torque. This particular situation linked to a slight depression of the passenger car 1, 1' is problematic, because it causes premature wear of the seals of the access door 4, 4', of the door guide means 4, 4' and the motorization device, the latter deploying more efforts to open the access door 4, 4'. In addition, in certain special cases such as the parking of rolling stock in a tunnel station, the pressure difference of air between the interior and exterior of the passenger car in question is such that opening of the access door 4, 4' can be prevented, the engine torque not making it possible to overcome this pressure difference.

The control system of the invention makes it possible to determine whether the behavior of at least one access door 4, 4' when it opens reflects defective functionality of at least one of the flaps 7, 8 of the passenger car. considered 1, 1'.

Said control system comprises control means on board the train which are capable of implementing a method of controlling the functionality of the flaps 7, 8 which will be described below. The system of the invention also comprises means for determining a torque function, which is the representation of the torque exerted by the motorization device of the access door considered 4, 4' as a function of time, which means of determination include at least one torque sensor for each access door 4, 4' of the train. In addition, the control system includes means for determining the opening time of the access door considered 4, 4', in particular a stopwatch.

The method for controlling the functionality of the shutters 7, 8 following a command to close the latter will now be described.

During the first stage and for all of the passenger cars 1, 1' of the stationary train, the control means check that the access doors 4, 4' are all closed. If this is not the case, said control means control the closing of the access doors 4, 4' which are still open.

During the second stage, the control means control the closing of all of the intercirculation doors 6, 6' of the train. Thus, the 1.1' passenger cars are isolated from each other.

During the third stage, the control means control the opening of all the room doors 5, 5' to standardize the air pressure between the passenger room 2, 2' and the access room 3, 3' of passenger cars 1, 1'.

During the fourth step, the control means control the closing of all the sealing flaps 7, 8.

During the fifth step, following a determined delay, for example five minutes, the control means send a command to open the access doors 4, 4' of the train, and simultaneously trigger the stopwatch to measure the time 'opening of each access door 4, 4', until the latter are completely opened. In addition, the torque sensors continuously measure the torque exerted by the motorized devices considered for opening the access doors 4, 4', which torque sensors return the acquired data to the control means which record them in its memory space , determine the torque function(s) from these data and associate each torque function and opening time determined with the access door considered 4, 4'.

During a sixth step, the control means determine the difference on the one hand between the opening time of each access door 4, 4' and a determined reference time, and on the other hand between the function opening torque of each access door 4, 4' and a determined reference torque function.

• que le temps d'ouverture de ladite porte d'accès 4, 4' est supérieur au temps d'ouverture de référence, alors les moyens de commande détectent la ou les voiture-voyageurs concernées 1, 1', et génèrent une donnée indiquant que le volet d'extraction 8 au niveau de la voiture considérée 1,1' présente une fonctionnalité d'étanchéité défectueuse, ou
• que le temps d'ouverture de ladite porte d'accès 4, 4' est inférieur au temps d'ouverture de référence, alors les moyens de commande détectent la ou les voiture-voyageurs concernées 1, 1', et génèrent une donnée indiquant que le volet d'entrée 7 au niveau de la voiture considérée 1,1' présente une fonctionnalité d'étanchéité défectueuse.

If the difference between the opening time of at least one access door 4, 4' and the reference time is greater than a determined threshold, for example ten percent of the value of the reference time, and:

• that the opening time of said access door 4, 4' is greater than the reference opening time, then the control means detect the passenger car(s) concerned 1, 1', and generate data indicating that the extraction flap 8 at the level of the car in question 1.1' has defective sealing functionality, or
• that the opening time of said access door 4, 4' is less than the reference opening time, then the control means detect the passenger car(s) concerned 1, 1', and generate data indicating that the entrance flap 7 at the level of the car considered 1.1 'has a sealing functionality defective.

Optionally but advantageously, to confirm this first analysis based on the opening time of the access doors 4, 4', the control means check whether the opening torque function at at least one door d The access has at least one deviation at a given time with the reference torque function which is greater than a determined threshold. This threshold is for example a deviation of ten to twenty percent compared to the reference torque function at a given time. If the differences in torque functions corroborate the differences in opening times, then the first analysis is confirmed and the control means generate an alert indicating that the extraction flap 8 or the entry flap 7 of the car(s) considered 1, 1' has defective sealing functionality. Of course, if this confirmation by comparison of couples is not carried out, the alert is still generated by the control means following the opening time comparisons.

The method of controlling the functionality of the shutters 7, 8 following an opening command for the latter will now be described.

The first six steps described above also apply, except that during the fourth step, the control means control the opening of all the sealing flaps 7, 8.

• que le temps d'ouverture de ladite porte 4, 4' est supérieur au temps d'ouverture de référence, alors les moyens de commande détectent la ou les voiture-voyageurs concernées 1, 1', et génèrent une donnée indiquant que le volet d'entrée 7 au niveau de la voiture considérée 1,1' présente une fonctionnalité de circulation défectueuse, ou
• que le temps d'ouverture de ladite porte 4, 4' est inférieur au temps d'ouverture de référence, alors les moyens de commande détectent la ou les voiture-voyageurs concernées 1, 1', et génèrent une donnée indiquant que le volet d'extraction 8 au niveau de la voiture considérée présente une fonctionnalité de circulation défectueuse.

If the difference between the opening time of at least one access door 4, 4' and the reference time is greater than the determined threshold, and:

• that the opening time of said door 4, 4' is greater than the reference opening time, then the control means detect the passenger car(s) concerned 1, 1', and generate data indicating that the flap d 'entry 7 at the considered car 1.1' has defective traffic functionality, or
• that the opening time of said door 4, 4' is less than the reference opening time, then the control means detect the passenger car(s) concerned 1, 1', and generate data indicating that the flap d The extraction 8 at the level of the car in question presents a defective circulation functionality.

Optionally but preferentially, and as specified above, this first analysis can be confirmed by a comparison of the couple functions openings of access doors 4, 4' with the reference torque function. If the differences in torque corroborate the differences in opening times, then the first analysis is confirmed and the control means generate an alert indicating that the extraction flap 8 or the entry flap 7 of the car(s) considered 1 , 1' has defective circulation functionality. Of course, if this confirmation by comparison of couples is not carried out, the alert is still generated by the control means following the opening time comparisons.

To support the diagnosis, that is to say that the variations in opening time of access doors 4, 4' are indeed due to defective functionality of at least one shutter 7, 8, the method of controlling the The invention is implemented twice in succession, a first time following a command to open or close the shutters 7, 8, and a second time following an opposing command to open or close the shutters 7, 8 Between the two successive implementations of the method on all the cars 1, 1' of the train, the access doors 4, 4' are of course closed by the control means. These two successive implementations are called in the following respectively first test and second test.

Advantageously, the method and the system of the invention make it possible to carry out a third and final optional test, which makes it possible to definitively confirm that the longer or shorter opening time of the access door(s) considered 4 , 4' is due either to defective functionality of the shutter(s) considered 7, 8, or to a malfunction of the motorization of said access doors 4, 4'.

This last test is carried out on one or more passenger cars 1, 1' whose opening time of the access door 4, 4' is significantly longer than the reference time.

The access door 4, 4' of the car 1, 1' of which the flaps 7, 8 are suspected of having defective functionality is previously closed by the control means. The method of the invention is then implemented following a first command to open or close the shutters 7, 8, so as to record a first opening time of the access door 4, 4' as well as 'a first associated couple.

The access door 4, 4' is closed again by the control means, then the process is implemented a second time following a second command to open or close the shutters 7, 8, opposing the first order. In this way, a second opening time of the access door 4, 4' and a second associated torque are recorded by the control means.

The control means then compare the first opening time and the second opening time. If the difference between these two times is greater than a determined value, which value represents for example a difference of ten percent between said first and second times, then the control means generate an alert indicating that the door motorization device 'port 4, 4' is defective. On the other hand, if the difference between the two times is less than or equal to the determined value, then the control means generate another alert indicating which sealing flap 7, 8 has defective functionality. This last result can be confirmed, if necessary, by comparison of the first and second associated torque functions: if the difference at a given moment between the first and second torque functions is greater than a second determined value, which value represents for example a difference of ten to twenty percent between said torque functions at this given instant, then the control means generate an alert indicating that the motorization device of the door 4, 4' is defective. On the other hand, if the difference between the two couples is less than or equal to the determined value, then the control means generate another alert indicating which sealing flap 7, 8 has defective functionality.

Alternatively, instead of implementing the first and second tests, the third test is implemented and repeated for each passenger car 1, 1' of the train. Although more costly in time and energy, this alternative makes it possible to reliably determine the shutters 7, 8 with defective functionality and the access doors 4, 4' whose motorization is defective.

The embodiment described above is in no way limiting, and modifications can be made to it without departing from the scope of the invention. By way of example, the method of the invention can be implemented with any parameter associated with the access door 4, 4' and independent of the motorization means of the shutters 7, 8, and whose value depends directly on the pressure prevailing inside the passenger car 1, 1'. The control system of the invention is then provided with determination means specific to the parameter to be determined. Furthermore, the diagram of the figure 2 can also be applied to a one- or two-level passenger car positioned at the end of the train. Finally, the torque exerted by the motor of each access door can be determined in any other known manner, for example by analyzing the electric current passing through said motor.

Claims (10)

1. Method for checking the functionality of mobile sealing elements (7, 8) of a rolling stock ventilation device, which mobile elements (7, 8) are placed inside ventilation ducts of said ventilation device and are motorized between an open position associated with a functionality whereby said mobile elements (7, 8) are open, providing optimal air circulation in the ducts, and a closed position associated with a functionality whereby said mobile elements (7, 8) are sealed, sealing the ducts closed, which method is implemented by processing and control means carried on board the rolling stock and comprises the successive steps of:

   i. issuing a command to open at least one exterior-access door (4, 4') of the rolling stock, which door (4, 4') is initially closed;

   ii. concomitantly with the opening of the door (4, 4'), determining at least one parameter connected with said opening of the door (4, 4')l

   iii. once the access door (4, 4') is open, recording the determined parameter in a memory zone of the processing and control means;

   iv. determining the difference between the determined parameter and a reference parameter recorded in the memory zone;

   v. if the absolute value of the difference is greater than or equal to a determined threshold, generating a data item associated with a defective functionality of at least one mobile sealing element (7, 8) .
2. Method according to the preceding claim, characterized in that it comprises a step of generating an alert associated with the defective functionality of at least the mobile sealing element (7, 8).
3. Method according to Claim 1 or 2, characterized in that the processing and control means determine, over the course of step ii, the time of opening of the access door (4, 4').
4. Method according to any one of Claims 1 to 3, characterized in that the door comprises a motorized opening device operated by the processing and control means which determine, over the course of step ii, a torque function indicative of the torque exerted by the motor during the opening of the access door (4, 4'), as a function of time.
5. Method according to any one of Claims 1 to 4, characterized in that it comprises a preliminary step of issuing a command to open or to close the mobile sealing devices (7, 8).
6. Method according to the preceding claim, the ventilation device comprising at least one mobile air inlet element (7) admitting air into the rolling stock and one mobile air extraction element (8) extracting air from the rolling stock, characterized in that it further comprises the following steps:

   - when the method is implemented following a command to seal the mobile elements (7, 8) closed, generating a data item indicating that the sealing functionality of the mobile extraction element (8) is defective if the difference between the determined parameter and the reference parameter is greater than the determined threshold, and generating a data item indicating that the sealing functionality of the mobile inlet element (7) is detective if the difference between the reference parameter and the determined parameter is greater than the determined threshold;

   - when the method is implemented following a command to open the mobile elements (7, 8), generating a data item indicating that the opening functionality of the mobile inlet element (7) is defective if the difference between the determined parameter and the reference parameter is greater than the determined threshold, and generating a data item indicating that the opening functionality of the mobile extraction element (8) is defective if the difference between the reference parameter and the determined parameter is greater than the determined threshold.
7. Method according to Claim 5 or 6, characterized in that it comprises the successive additional steps of:

   - issuing a command to close the access door (4, 4');

   - once the door (4, 4') is closed, issuing a command that is the opposite of the command to open or to close the mobile elements (7, 8) that was issued during the preliminary step;

   - repeating steps i to iii and recording a second determined parameter;

   - determining the difference between the parameter determined in step iii and the second parameter determined in the preceding step;

   - if the difference is less than a limit value, generating and issuing an alert that the motorization of the access door (4, 4') is malfunctioning, otherwise generating an alert associated with a defective functionality of at least one mobile sealing element (7, 8).
8. System for checking the functionality of mobile sealing elements (7, 8) of a rolling stock ventilation device, which rolling stock comprises at least one exterior-access door (4, 4'), which mobile elements (7, 8) are placed in ventilation ducts of said ventilation device respectively at an air inlet (9) admitting air into the rolling stock and at an air outlet (10) letting air out of the rolling stock and are motorized between an open position associated with a functionality of opening said mobile elements (7, 8) to allow optimal circulation of air in the ducts, and a closed position associated with a functionality of sealing said mobile elements (7, 8) ensuring sealed closure of the ducts, which system is designed to be carried on board the rolling stock and comprises processing and control means comprising a memory zone and configured to implement the method according to any one of the preceding claims.
9. System according to the preceding claim, characterized in that the mobile elements (7, 8) are sealing flaps.
10. Railway rolling stock comprising at least one passenger carriage (1, 1'), each carriage (1, 1') comprising a ventilation device comprising an air inlet (9) admitting air into the carriage and an air outlet (10) letting air out of the carriage, the ventilation device further comprising two mobile sealing elements (7, 8) arranged respectively one at the air inlet (9) and one at the air outlet (10), the mobile elements (7, 8) being motorized between an open position and a position of sealed closure of the air inlet (9) and of the air outlet (10), characterized in that it comprises a system according to Claim 8 or 9 for checking the functionality of the mobile sealing elements (7, 8).

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