EP3194241B1 - Door system with sensor unit and communication element - Google Patents

Description

The present invention relates to a door system for a public transport vehicle with at least one door opening and a door closing the door opening. Furthermore, the application relates to a method for monitoring and controlling such a door system.

Door systems are used particularly in rail and road vehicles, but also on boats and airplanes. Such door systems are monitored in many ways and controlled depending on a wide variety of conditions. On the one hand, the safety of passengers getting on and off must always be guaranteed, and on the other hand, doors or door leaves should open and close reliably and only under certain conditions. It must also be prevented that people or objects become trapped between two door leaves or a door leaf and a door frame.

In addition, boarding and alighting processes are often delayed because passengers or objects prevent the doors from opening or closing.

For the purposes of the invention, the term door systems also includes access aids, such as sliding steps or steps. Their function and use must also be monitored and controlled, as there are, for example, obstacles on them that pose a danger to passengers. It must also be ensured that no people or objects are trapped between the boarding aid and the platform and that the boarding aid does not collide with people.

1. 1. Verschiedene Taster für die Bedienung der Tür.
2. 2. Druckwellen/Schaltleisten zur Hinderniserkennung. Diese werden meist in einer Hauptschließkante, vereinzelt aber auch zusätzlich in Nebenschließkanten der Türen oder Türflügeln eingesetzt.
3. 3. Lichtgitter im Fahrzeuginnenraum zur Offenhaltung gerade verwendeter Türen (zur Steuerung automatisch schließender Türen).
4. 4. Trittsensoren (Schaltmatten, Dehnungsmessstreifen oder ähnliches) zur Erkennung von Lasten auf Trittsystem und Zustiegshilfen.
5. 5. Schaltleisten an Trittsystemen zur Erkennung von Kollisionen beim Ausfahren mit dem Bahnsteig oder Fahrgästen.
6. 6. Ultraschallsensoren in Trittsystemen zur Vermessung des Abstands zum Bahnsteig und dessen Höhe.

Various sensors are used in door systems for these numerous monitoring and control tasks. These include:

1. 1. Various buttons for operating the door.
2. 2. Pressure waves/safety edges for obstacle detection. These are usually used in a main closing edge, but occasionally also in secondary closing edges of the doors or door leaves.
3. 3. Light grid in the vehicle interior to keep doors in use open (to control automatically closing doors).
4. 4. Step sensors (safety mats, strain gauges or similar) to detect loads on the step system and access aids.
5. 5. Safety strips on step systems to detect collisions when exiting the platform or passengers.
6. 6. Ultrasonic sensors in step systems to measure the distance to the platform and its height.

The sensors mentioned require numerous components, complex cabling and careful maintenance and repair. The implementation of complete and satisfactory monitoring and control of a door system is therefore complex and involves relatively high costs.

From the US 6,341,563 B1 a control device for a door system is known, which monitors a door area with the help of sensors. In particular, information about the area adjacent to the door system is used, for example the height of the platform in relation to the door or the distance of the platform from the door.

The US 2013/0125468 A1 also describes such a system in which dangerous situations are recognized with the help of current camera recordings of the door area and a comparison of the image data with stored image data.

The object of the invention is, on the one hand, to provide a door system in which the above-mentioned monitoring and control tasks can be solved with as little effort as possible. Installation, maintenance and servicing should be simple and possible at low cost. In particular, the number of components required should be reduced. On the other hand, the door system should be suitable for optimizing boarding and alighting processes and averting dangers for passengers at an early stage.

Furthermore, the object of the invention relates to providing a corresponding method for monitoring and controlling such a door system.

The object is achieved according to the invention by a door system with the features of the independent device claim and a method with the method steps of the independent method claim.

• Bewegungsgeschwindigkeit und Bewegungsrichtung von Fahrgästen,
• der Position und Geschwindigkeit von Extremitäten der Fahrgäste,
• der Bewegungsgeschwindigkeit und Bewegungsrichtung zusätzlicher Objekte,

ausgeführt und eingerichtet, wobei die Sensoreinheit zur Überwachung eines Raums zwischen den Türflügeln oder des Bereichs unmittelbar innerhalb eines Türrahmens zwischen einer Hauptschließkante der Tür und dem Türrahmen, an die Steuerung der Tür oder der Türflügel gekoppelt und derart ausgeführt und eingerichtet ist, dass sie in der Lage ist, jeweils die aktuelle Türposition oder die Türflügelposition auszulesen.Accordingly, a door system according to the invention has at least one communication element for context-based communication in the form of instructions or information to passengers based on measurement results from a sensor unit, wherein the instructions or information come from the door system and are generated when certain measurement results are available and the communication is carried out by the Door system itself is automatic. The sensor unit is designed and set up in such a way that it scans a passenger compartment in the area of the door opening in a three-dimensional, non-contact manner to determine distances and shapes within the passenger compartment. The sensor unit is used to determine the

• speed and direction of movement of passengers,
• the position and speed of passengers' extremities,
• the speed and direction of movement of additional objects,

executed and set up, wherein the sensor unit for monitoring a space between the door leaves or the area immediately within a door frame between a main closing edge of the door and the door frame, is coupled to the control of the door or the door leaves and is designed and set up in such a way that it is in the is able to read out the current door position or the door leaf position.

• Berührungsloses dreidimensionales Abtasten eines Fahrgastraumes im Bereich einer Türöffnung (44) mit einer Sensoreinheit (26),
• Ermitteln
  • von Abständen, Formen sowie Bewegungsgeschwindigkeit und Bewegungsrichtung von Fahrgästen,
  • der Position und Geschwindigkeit von Extremitäten der Fahrgäste,
    • der Bewegungsgeschwindigkeit und Bewegungsrichtung zusätzlicher Objekte
  durch Auswertung der Ergebnisse der berührungslosen dreidimensionalen Abtastung,
• Auslesen einer aktuellen Türposition oder Türflügelposition aus der Steuerung der Tür oder der Türflügel durch die die Sensoreinheit zur Überwachung eines Raums zwischen den Türflügeln oder des Bereichs unmittelbar innerhalb eines Türrahmens zwischen einer Hauptschließkante der Tür und dem Türrahmen,
• Ausgabe zumindest einer kontextbasierten Information aus der nachfolgenden Gruppe durch das Türsystem selbst in Form von Anweisungen oder Informationen an die Fahrgäste, wobei die Information auf Messergebnissen der Sensoreinheit und der aktuellen Türposition oder Türflügelposition basiert, und
  • aus- und einsteigende Fahrgäste ermittelt und gezählt werden und eine Information an Fahrgäste erfolgt, die auf dem Füllungsgrad des Fahrzeugs basiert, oder
  • die Sensoreinheit die Zustiegshilfe abtastet, wobei dann, wenn Hindernisse wie beispielsweise eine Schnee- oder Eisdecke ermittelt werden, eine entsprechende Information an die Fahrgäste erfolgt, oder
  • die Sensoreinheit ermittelt, ob ein Objekt, insbesondere ein Fahrgast, an der Tür oder an einem Türflügel lehnt, während diese geöffnet werden soll und falls notwendig eine entsprechende Information an die Fahrgäste erfolgt, wobei die Tür solange für die Öffnung gesperrt bleibt, bis die potentielle Gefahr beseitigt ist, oder
  • die Sensoreinheit ermittelt, ob sich ein Objekt, insbesondere ein Fahrgast von außen zu dicht an einer ausschwenkenden Tür steht ein Objekt, insbesondere ein Fahrgast, an der Tür oder an einem Türflügel lehnt, während diese geöffnet werden soll und falls notwendig eine entsprechende Information an die Fahrgäste erfolgt, wobei die Tür solange für die Öffnung gesperrt bleibt, bis die potentielle Gefahr beseitigt ist, oder
  • die Sensoreinheit ermittelt, ob sich Fahrgäste auf eine Tür zubewegen, die als defekt markiert ist, und falls notwendig eine entsprechende Information an die Fahrgäste erfolgt, oder
  • die Sensoreinheit ermittelt, ob Fahrgäste das Schließen einer Tür dadurch verhindern, dass sie zu nah an dieser Tür stehen, und falls notwendig eine entsprechende Information bereits vor dem Schließen der Tür an die Fahrgäste erfolgt, oder
  • die Sensoreinheit ermittelt, ob Fahrgäste ein Fahrrad mitführen, ein Abgleich mit Informationen über das jeweilige Fahrzeug in Hinblick darauf erfolgt, ob in diesem Fahrzeug ein Fahrradstellplatz zur Verfügung steht, und falls dies nicht der Fall ist, eine entsprechende Information an die Fahrgäste erfolgt, oder
  • die Sensoreinheit (26) die Position und Geschwindigkeit von Extremitäten ermittelt und daraus Rückschlüsse auf die Absicht eines Fahrgastes zieht.

The method according to the invention has the following process steps:

• Non-contact three-dimensional scanning of a passenger compartment in the area of a door opening (44) with a sensor unit (26),
• Determine
  • distances, shapes as well as speed and direction of movement of passengers,
  • the position and speed of passengers' extremities,
    • the speed and direction of movement of additional objects
  by evaluating the results of non-contact three-dimensional scanning,
• Reading out a current door position or door leaf position from the control of the door or the door leaves through the sensor unit for monitoring a space between the door leaves or the area directly within a door frame between a main closing edge of the door and the door frame,
• Output of at least one context-based information from the following group by the door system itself in the form of instructions or information to the passengers, the information being based on measurement results of the sensor unit and the current door position or door leaf position, and
  • Passengers getting off and on are determined and counted and information is provided to passengers based on the filling level of the vehicle, or
  • the sensor unit scans the boarding aid, whereby if obstacles such as a layer of snow or ice are detected, corresponding information is sent to the passengers, or
  • the sensor unit determines whether an object, in particular a passenger, is leaning against the door or a door leaf while it is to be opened and, if necessary, appropriate information is sent to the passengers, whereby the door remains blocked from opening until the potential Danger has been eliminated, or
  • the sensor unit determines whether an object, in particular a passenger, is standing too close to a swinging door from the outside, an object, in particular a passenger, is leaning against the door or a door leaf while it is to be opened and, if necessary, sends corresponding information to the passengers, with the door remaining blocked from opening until the potential danger has been eliminated, or
  • the sensor unit determines whether passengers are moving towards a door that is marked as defective and, if necessary, appropriate information is sent to the passengers, or
  • the sensor unit determines whether passengers are preventing a door from closing by standing too close to this door and, if necessary, appropriate information is sent to the passengers before the door is closed, or
  • the sensor unit determines whether passengers are carrying a bicycle, and a comparison is made with information about the respective vehicle with regard to whether there is a bicycle parking space in this vehicle is available, and if this is not the case, appropriate information is provided to the passengers, or
  • the sensor unit (26) determines the position and speed of extremities and draws conclusions about the intention of a passenger.

The passenger or entrance area is therefore detected or scanned three-dimensionally using a sensor unit inside and/or outside the vehicle. This three-dimensional scanning can be carried out on the basis of known optical systems such as infrared sensors, infrared laser scanners or suitable camera systems with optical image data evaluation; scanning with ultrasound is also conceivable. With the help of the data determined, tests can then be carried out for possible collisions of the door and step systems with the surroundings or passengers. Predefined points in the room can also be used as virtual buttons to control the door and step systems.

An essential aspect of the invention is that, according to the invention, the context-based information is output directly to the user concerned. Information is therefore given out where it is needed, for example at a specific door to a specific passenger. This prevents the affected passenger from feeling unaddressed due to generally formulated information that is displayed at all doors. Context-based communication is particularly advantageous when certain potential dangers have been detected by the sensors. For example, if there is snow on a sliding step or there is a gap between the sliding step and the platform, according to the invention, exactly those passengers in the area of the corresponding door who are affected by the danger are informed. Communication can take the form of an announcement or an indication on a display on the corresponding door. The communication can be carried out by the driver himself, who has previously been made aware of the danger by the system, but according to the invention an automated announcement or display in the area of the corresponding door is also possible.

The sensor unit therefore determines a specific relevant state or corresponding data, passes this on to a computer unit, which then outputs context-based, locally relevant information.

The term “context-based information” means that it is not distributed automatically and across the board everywhere, but rather that it is based on the data determined by the sensor unit and is specifically adapted to the conditions on site. The context-based information according to the invention therefore includes, on the one hand, the factual information content, for example a specific danger at a specific place or location, and on the other hand, the context decides which passenger or passengers are affected and who the information should reach. The latter in turn contains information about which door or doors the information is relevant and is issued on. Communication does not take place across the board at all doors.

In a particularly advantageous embodiment variant, the sensor unit is formed by a laser scanner unit which is arranged in the area of the door opening. The laser scanner unit creates a type of point cloud, which is used to scan the passenger compartment in all three dimensions, i.e. in the x-direction, y-direction and Z-direction. Preferably, the laser scanner unit uses infrared light, which is not visible to the human eye. With the help of the emitted point cloud, a distance measurement is carried out, which is based on the so-called Time-Of-Flight (ToF) principle. This means that the laser scanner emits light pulses and measures the delay until the reflection of the corresponding light pulse arrives. The measured delay in reflection can be used to determine the distance between the scanned point and the sensor unit. The distance measurement or monitoring of the passenger compartment is more precise the more scans are carried out per unit of time.

The scanning resolution should be large enough to reliably detect even the smallest objects that are to be detected. To evaluate the results, the sensor unit contains an evaluation unit with a computer/processor and suitable software. Alternatively, the evaluation unit can also be arranged externally to the sensor unit, for example in the driver's compartment on a train.

The sensor unit should be arranged in such a way that the passenger compartment can be optimally scanned, i.e. no unwanted elements protrude into the beam paths. Although these can be ignored by the sensor unit, but cast a shadow. In the case of double-leaf doors, the central position above the two door leaves on the outside of the vehicle, i.e. in the area of the abutting main closing edges, has proven to be particularly advantageous. The point cloud is radiated downwards from this upper position.

According to the invention, mounting the sensor unit in the middle above the door is particularly favorable, since the passenger compartment can then be optimally scanned. In the case of double-leaf doors in the interior, an arrangement to the side next to and above the door has proven to be particularly advantageous because, with the central arrangement, the support arms of the door would restrict the view of the laser scanner.

According to the invention, it is possible to generate virtual buttons using the sensor unit according to the invention. This means that an area can be defined at any point in which, for example, a passenger's hand movement can be evaluated as pressing a button. If a passenger's hand moves at the location of the virtual button in the direction of, for example, a sticker or a marking on or next to the door of a door wing, the sensor unit detects this and triggers an opening or closing signal for the doors.

When calibrating such a virtual button, an object is held in the point cloud at the desired location where the virtual button is to be created. If the object is held still long enough and only this one object is recognizable to the laser scanner, the center of the object is determined, the position of which is then used as the center for the virtual button. Since the speed of elements is also measured during this calibration, objects that are too fast in this area are not accepted. In the next step, a radius is defined around this center, which allows the size of the virtual button to be determined. If this virtual button is activated, the distance of all scanned objects that are detected within the passenger compartment to the center of the virtual button is determined. If the distance of an object, for example a passenger's hand, to the center of the virtual button is smaller than the previously determined radius, the virtual button is considered activated. Preferably, the area of the point cloud that is closest to the door opening is used for detection and activation. This ensures that only movements that are up to very close to the door or vehicle wall. Ideally, passengers have to touch the sticker or marking to activate the button.

The main advantage of such virtual buttons is that they can be positioned and set up anywhere. No additional wiring is necessary and changes to the vehicle or position can be made at any time. It is still possible without any problems and involves only insignificant additional costs to provide several buttons in a door system. It is conceivable, for example, to additionally set up buttons for children or wheelchair users.

When calibrating the sensor unit and the sensor environment, the entire environment visible to the laser unit or laser scanner is scanned and saved taking tolerances into account. In addition, the dimension of the door portal is integrated into the calibration in order to be able to hide relevant objects beyond the door. Calibration then makes it possible to adapt to different environments such as different platform heights or given obstacles. The sensor unit easily detects additional objects or elements within the monitored passenger compartment.

According to the invention, the sensor unit is coupled to the control of the door or door leaf and is able to read out the current door or door leaf position. The information is used to monitor the space between the door leaves; the wider environment can be ignored for this application. If there is only one door, the area immediately inside the door frame or the gap between the main closing edge and the door frame is monitored.

According to the invention, it is also possible to monitor the space between the door leaves, independently of the control of the door or door leaves or the door or door leaf position derived therefrom, exclusively with the aid of the sensor unit.

It has been shown that, particularly when the data from the control of the door or door leaf is used, according to the invention an area in front of the door opening should also be scanned. This is necessary because the determination of the door or door leaf position is often based on the door control is inaccurate and prone to errors, there may be deviations from a position output by the encoder of the door drive motor to the real position of the main closing edges of the door leaves. In addition, a deformation of the door rubbers in the area of the main closing edge can then reveal gaps that are large enough for narrow objects such as dog leashes or fingers, but are not monitored. These gaps or openings are then monitored when the area immediately in front of them, i.e. in front of the door or the door leaves, is also scanned. This point cloud in front of the door opening preferably overlaps with the door leaves.

The essential aspect of the invention is that communication with passengers is always possible. The sensor unit uses the measurement results not only to control the doors, but according to the invention the measurement results can also be used for direct communication with the passengers. For example, passengers can be asked to change their position, find another car or vehicle or even take objects out of danger areas. Corresponding instructions or information to passengers can be issued automatically by the door system itself, but they can also be given by a driver of the vehicle or an external control center. In the first case, according to the invention, information is automatically generated when certain measurement results are available. For example, if a person is in the closing or opening area of a door or a door leaf, according to the invention information can be provided automatically, for example in the form of an announcement via a loudspeaker, asking the person to leave the danger area.

Loudspeakers, monitors or lamps are particularly suitable as communication elements. Only a single communication element can be provided, but alternatively different or several identical means of communication can also be used. In a particularly simple variant, for example, a light source can use the colors red and green to signal whether a door will be opened or not. For more extensive information, speakers or monitors are more suitable. The communication elements are preferably arranged directly in the area of the door opening.

In a further development according to the invention, it is taken into account that the virtual button can be covered by larger objects, particularly at busy train stations, and therefore cannot be used. The sensor unit takes this case into account and, according to the invention, a warning is issued via the communication element. This warning can be sent to the directly affected passenger at the corresponding door, for example via loudspeakers, or initially to the train or vehicle driver, who then passes this information on to the passenger if necessary.

In order to avoid injury to passengers standing in front of the vehicle due to opening doors or door leaves, the invention provides that the relevant area within the moving door is also monitored by the sensor unit. When objects are detected within this area, a signal is generated which can be used, for example, to stop or reverse the door or door leaf. Advantageously, it is also possible to generate a signal before the door is opened, which can be used to issue a warning to the passengers. In particular, the signal can only inform those passengers who are affected. For example, a loudspeaker announcement can be made at the door that is being stopped or reversed. There are no announcements or notices at the other doors.

The door system and method according to the invention is also used according to the invention to detect extremities and their position and speed. By using one or more point clouds, a movement speed in the direction of the door opening or away from the door opening can be determined. From this data, immediate conclusions can be drawn about a passenger's intention, for example a request for opening or access.

According to the invention, even movement flows of passengers in the area of the doors can be determined and used. In practice, it is often common practice to use certain doors either for exiting only or for entering only. By detecting the direction of movement of a passenger, a door can be locked or opened to direct the flow of passengers in one direction. For example, if a passenger has passed the door in the permitted direction of movement and no other passenger is following behind, the door can be closed directly to prevent the door from passing in the opposite, wrong direction complicate. If a passenger moves towards the door in the wrong direction, if no one is in the area of the moving door or wants to get out, it can be closed more quickly if necessary and advantageously depending on the distance and speed of the passenger in order to allow use in the wrong direction. For these applications, a space in front of the door opening is advantageously monitored, which can extend, for example, up to 10 m, preferably 2 to 5 m, from the door in the direction of the platform or the street. Passengers are therefore recognized early on and a timely reaction can be made.

Before closing individual doors, it is possible to inform passengers who are in the boarding area of exactly that door that it will close. This information is only displayed at the doors in front of which passengers are located.

Scanning the passenger compartment makes it possible to provide the passenger with context-based information or to warn them of potentially dangerous situations. For example, if a passenger leans against the door or a door leaf from the inside while it is about to be opened, this passenger can be warned in advance. The same applies to a disturbing object leaning against the door. The door can remain blocked from opening until the potential danger has been eliminated. Here too, specific information can be sent to passengers in the area of this door or object.

The same applies if a passenger covers a virtual button. In this case, the speaker or monitor or alternative signals can be used to stop it from changing its position so that the button can be used again. This information is also only addressed to this passenger; no information is sent to the other doors.

Even if a passenger or an external object is too close to a door that swings out, you can be warned of the danger and wait before opening the door until the swing-out area is free of obstacles. Advantageously, people can be identified who are on an boarding aid, so that an entry process can be prevented or stopped. Accordingly, exactly these passengers are asked to change their position.

A significant advantage for the applications mentioned is, in particular, that a passenger does not have to have contact with a moving door in order to interrupt the opening or closing process and/or initiate a reversing door. With conventional sensors that are arranged in the main closing edge, the main closing edge must be touched by the passenger, if necessary even pressed in, so that a signal is generated. Such contact is often perceived as unpleasant and can, in particular, dirty the passenger's clothing. These disadvantages can be effectively avoided through the non-contact scanning of the relevant passenger compartment according to the invention.

The design of the door system according to the invention or the process according to the invention for monitoring the passenger compartment enable further advantageous monitoring and control options. For example, if a door is marked as "defective" and a passenger approaches such a door, he or she can be informed of the status of the door via the means of communication, for example the loudspeaker. This is advantageous because passengers are known to often overlook defect notices in the form of stickers or only notice them when the door does not work. Driving can also be accelerated and made easier if passengers who prevent a door from closing by standing too close to the door are asked to step back before the door is closed. In sensor systems according to the state of the art, the passengers are only prompted by the driver of the vehicle when he notices a malfunction in the door, for example if it cannot be closed. Such a failed attempt can be avoided by detecting the position of the passengers beforehand.

According to the invention, it is even possible to recognize a bicycle on one side of a passenger and to immediately check whether there is a parking space for bicycles at the entrance chosen by the passenger. The passenger can be informed about the result via the means of communication and, for example, receive an indication of which alternative boarding option he can choose.

Furthermore, it is possible to inform boarding passengers about the degree of filling, in particular about the seat occupancy, of a specific car and to inform them communicate via the communication elements in which carriage there are still free seats available.

In principle, with the help of the door system according to the invention and the method according to the invention, it is possible to inform the driver of the vehicle about the movement and use of doors in order to be able to control them optimally. In particular, unused doors can be closed earlier or automatic doors can be released in front of which passengers are waiting to get out. Closing doors as quickly as possible is particularly advantageous for air-conditioned or heated cars. In the prior art, passengers are checked, for example on a platform or at a stop, exclusively via the driver's rear-view mirror and therefore depends on the driver's concentration and attention.

According to the invention, the use of three-dimensional scanning on the outside of the vehicle can be used to detect and report a blanket of snow that has formed, for example when you step on it. Passengers can be made immediately aware of the impending danger via the communication elements.

According to the invention, it is also possible to determine the distance between the door opening and a platform in order to optimally extend the step or boarding aid. This is particularly advantageous if the distances between the door opening and the platform differ from station to station. Corresponding sensors on the boarding aids themselves can therefore be dispensed with. For example, if a gap remains between the boarding aid and the platform despite the sliding step being fully extended, passengers can be informed of this immediately via the communication elements. This information can also be automatically output by the system itself if the corresponding measurement results are available.

By using three-dimensional scanning, not only the speed but also the number of passing passengers can be determined; passenger counting is possible without any problems.

Furthermore, with the help of suitable algorithms, conclusions can be drawn about the shape and movement of passengers and objects. This means that objects such as suitcases can be distinguished from passengers. This information can be used to provide precise and easy-to-understand information to passengers via communication means.

Fig. 1:

Ein erfindungsgemäßes Türsystem von außen in vereinfachter Prinzipdarstellung,

Fig. 2:

ein erfindungsgemäßes Türsystem von innen in vereinfachter Prinzipdarstellung,

Fig. 3:

eine Prinzipskizze zur Funktion eines virtuellen Tasters,

Fig. 4:

eine Prinzipskizze zur Hindernisüberwachung zwischen zwei Türflügeln.

The door system according to the invention is explained in more detail in the following figures. These are only to be understood as first exemplary embodiments and are not intended to limit the invention to these. The drawings are not to scale. Show it:

Fig. 1:

A door system according to the invention from the outside in a simplified schematic representation,

Fig. 2:

a door system according to the invention from the inside in a simplified schematic representation,

Fig. 3:

a schematic sketch of the function of a virtual button,

Fig. 4:

a schematic sketch for obstacle monitoring between two door leaves.

The Figures 1 and 2 show a greatly simplified schematic representation of a door system 20 for a vehicle 42 (see Figure 5) of public transport. This points one in the Figures 1 and 2 unrecognizable door opening 44, which in the exemplary embodiment shown can be closed by a door formed from two door leaves 22. An access aid 24 is arranged below the door and is intended to make it easier to get in and out of the vehicle 42. This access aid 24 can be designed, for example, as an extendable step or step plate.

Both figures also show a sensor unit 26. This is arranged centrally above the door leaves 22 on the outside of the vehicle 42. On the inside of the vehicle 42, however, the sensor unit 26 is positioned laterally above the two door leaves 22, since otherwise support arms not shown would possibly restrict the view of the sensor unit 26. Basically The sensor unit 26 can be arranged at any suitable position depending on the type of sensor.

The sensor unit 26 generates a point cloud within the passenger compartment to be monitored, via which the passenger compartment is scanned. For this purpose, the sensor unit 26 can, for example, have an optical sensor, preferably a laser, in particular an infrared laser.

The sensor unit 26 also has an evaluation unit, not shown, for evaluating the measured data. This can be integrated into the sensor unit or arranged externally.

Furthermore, they show Figures 1 and 2 symbolically different variants of communication means, namely a loudspeaker 50, a monitor 52 and a light source 54, all of which are arranged in the area of the door opening 44.

Figure 3 illustrates the use of the door system 20 according to the invention to create a virtual button 36. A virtual button 36 simulates an otherwise wired, real button. In order to make it clear to a passenger where this virtual button 36 is positioned, a sticker or a corresponding symbol painting can be provided in the door area.

When calibrating or setting up such a virtual button 36, an object is held in the point cloud at the desired position of the virtual button 36. If it is held still long enough, its position can be used as the center point 38 for the virtual button 36. In addition, a radius 40 is defined and stored in the associated evaluation software. For example, if a passenger's hand approaches the virtual button 36 through the point cloud within the defined radius 40, this movement is interpreted as the passenger's wish to trigger. As an alternative to the passenger's hand, any object in this area is recognized and taken into account.

Figure 4 illustrates another example of the use of the door system 20 according to the invention. An indicated vehicle 42 with a door opening 44 can be seen. In front of it there are two door leaves 22 in a slightly open position. A first Point cloud area P1 monitors a space between the two door leaves 22 and is limited to this; it ignores the wider environment. A second point cloud area P2, on the other hand, scans the space immediately in front of the two door leaves 22 and is spread out a little further so that it overlaps in extent with the door leaves 22. If there is now an obstacle in the monitored or scanned rooms, it is reliably detected and closing or moving of the door can be interrupted; if necessary, the door is automatically reversed. The point cloud area P1 thus monitors a space between the main closing edges 46 of the two door leaves 22. The same principle can be used for a single-leaf door; the space between the main closing edge 46 of the single door and the door frame is monitored.

The invention is not limited to the exemplary embodiments described and shown; rather, other possible uses of the door system 20 according to the invention are also possible. Communication with passengers can take place not only via loudspeakers, but also via monitors or other visual signals, such as warning lights. Instead of door openings 44, passages or windows can of course also be monitored using the method described. The invention is also suitable in conjunction with other sensor elements, for example ultrasonic sensors. Furthermore, the sensor unit 26 can be designed and aligned in such a way that not only the passenger compartment is monitored directly in the area of the door opening, but, for example, a significantly larger space on the outside of the vehicle 42 is included in the monitoring. This makes it possible to recognize flows of people and their direction at an early stage and to react to them by opening or closing doors. The passenger compartment can only be monitored outside, only inside and preferably on both sides of the door.

According to the invention, it can also be provided that the sensor unit 26 or the associated evaluation unit is connected to an external display device. This can be provided, for example, by the driver or in a control center, preferably in the train station or near a stop. The results of the scanning by the sensor unit 26 can then be evaluated and further processed there.

Claims (12)

1. A door system (20) for a public transport vehicle (42) with a sensor unit (26), at least one door opening (44) and a door closing the door opening (44) and at least one communication element for a context-based communication in the form of instructions or information to passengers on the basis of measurement results of the sensor unit (26), wherein the instructions or information originate from the door system and are generated when specific measurement results are present, wherein the communication automatically takes place by the door system (20) itself, and the sensor unit (26) is constituted and designed such that it scans a passenger compartment in the region of the door opening (44) a three-dimensional non-contact manner to determine distances and shapes inside the passenger compartment,
   characterised in that the sensor unit (26) is constituted and designed to determine

   - movement speed and movement direction of passengers,

   - the position and speed of extremities of the passengers,

   - the movement speed and movement direction of additional objects,

   wherein the sensor unit (26) is coupled to the control of the door or the door leaves (22) in order to monitor a space between the door leaves (22) or the region directly inside a door frame between the main closing edge of the door and the door frame, and is constituted and designed such that it can read out respectively the current door position or the current door leaf position.
2. The door system (20) according to claim 1, characterised in that the sensor unit (26) performs distance measurements on the basis of an emitted point cloud in which the delay of a reflection of a pulse is evaluated.
3. The door system (20) according to claim 1 or claim 2, characterised in that the sensor unit (26) contains an optical sensor.
4. The door system (20) according to claim 1 or claim 2, characterised in that the sensor unit (26) comprises an evaluation unit.
5. The door system (20) according to any one of claims 2 to 4, characterised in that the sensor unit (26) comprises a laser scanner unit.
6. The door system (20) according to any one of claims 1 to 5, characterised in that the passenger compartment comprises an interior space of the vehicle (42) and/or an exterior space outside the vehicle (42).
7. The door system (20) according to any one of claims 1 to 6, characterised in that the sensor unit (26) is constituted and designed such that a space outside the vehicle is also scanned, which extends from the door opening (44) up to 5 m, preferably 2 m from the latter.
8. The door system (20) according to any one of claims 1 to 7, characterised in that a space, through which the door or the door leaves (22) move, is monitored by the sensor unit (26) for the prevention of injury, wherein opening of the door or the door leaves (22) is interrupted if an obstruction is present in this area.
9. The door system (20) according to any one of claims 1 to 8, characterised in that the communication element is constituted as a loudspeaker (50) in the region of the door.
10. The door system (20) according to any one of claims 1 to 9, characterised in that the communication element is constituted as a monitor (52) in the region of the door.
11. The door system (20) according to any one of claims 1 to 10, characterised in that the communication element is constituted as a light source (54) in the region of the door.
12. A method for the monitoring and control of a door system (20) of the public transport vehicle (42) with the method steps:

    - contactless three-dimensional scanning of a passenger compartment in the region of a door opening (44) with a sensor unit (26),

    - determining

    - the distances, shapes and movement speed and movement direction of passengers,

    - the position and speed of extremities of passengers,

    - the movement speed and movement direction of additional objects by evaluation of the results of the contactless three-dimensional scanning,

    - reading out of a current door position or current door leaf position from the control of the door or the door leaf (22) by the sensor unit (26) for monitoring a space between the door leaves (22) or the region immediately inside a door frame between a main closing edge of the door and the door frame,

    - outputting of the at least one context-based piece of information from the following group by the door system itself in the form of instructions or information to the passengers, wherein the information is based on measurement results of the sensor unit (26) and the current door position or current door leaf position, and

    - alighting and boarding passengers are determined and counted and information is communicated to the passengers, which is based on the level of occupancy of the vehicle, or

    - the sensor unit (26) scans the boarding aid (24), wherein when obstacles such as a snow or an ice covering for example is determined, corresponding information is communicated to the passengers, or

    - the sensor unit (26) determines whether an object, in particular a passenger, is leaning against the door or against a door leaf when the latter is to be opened and if need be corresponding information is communicated to the passengers, wherein the door remains blocked for opening until the potential hazard is removed, or

    - the sensor unit (26) determines whether an object, in particular a passenger from outside is standing too close to an outswinging door, an object, in particular a passenger, is leaning against the door or against the door leaf, whereas the latter should be opened and if need be corresponding information is communicated to the passengers, wherein the door remains blocked from opening until the potential hazard is removed, or

    - the sensor unit (26) determines whether passengers are moving towards a door which is marked as defective, and if need be corresponding information is communicated to the passengers, or

    - the sensor unit (26) determines whether passengers are preventing the closing of a door due to the fact that they are standing too close to the door, and if need be corresponding information is communicated to the passengers before the closing of the door, or

    - the sensor unit (26) determines whether passengers are carrying along a bicycle, a comparison takes place with information concerning the vehicle in question with regard to whether a bicycle parking place is available in this vehicle, and if this is not the case, corresponding information is communicated to the passengers, or

    - the sensor unit (26) determines the position and speed of extremities and draws conclusions therefrom regarding the passenger's intention.

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