EP3805566A1 - Tunnel ventilation system - Google Patents

Abstract

The invention relates to a tunnel ventilation system (100), having: at least one fan (10) for sucking in and / or sucking out air and a motor (20) for driving the fan (10). For this purpose, it is provided according to the invention that the motor (20) is driven with the aid of a fuel (H2).

Description

The invention relates to a tunnel ventilation system according to the preamble of the independent device claim and a method for ventilating tunnels and / or shaft systems with the aid of a corresponding tunnel ventilation system according to the preamble of the independent method claim.

Tunnel ventilation systems are known in principle. The tunnel ventilation systems are usually equipped with fans that suck fresh air into the tunnels and / or suck old air out of the tunnels. Gasoline-powered internal combustion engines are often used to drive fans. The gasoline-powered internal combustion engines, however, have the disadvantage of toxic exhaust gases. Electric motors can serve as an alternative to internal combustion engines. In the area of application of tunnel and / or Shaft systems often lack the necessary electrical connections to supply the electric motors of the ventilation systems with electrical energy.

The invention is therefore based on an object of providing an improved tunnel ventilation system which at least partially overcomes the disadvantages described above. In particular, it is the object of the invention to provide an improved tunnel ventilation system which is simply constructed, which is easy to operate, which can be set up in a mobile manner and / or which can be operated in an environmentally friendly manner. In addition, it is an object of the invention to provide a corresponding method for ventilating tunnels and / or shaft systems.

The above object is achieved by a tunnel ventilation system, which can be used in particular in tunnel and / or shaft construction and / or in areas where work is carried out with substances hazardous to water, as well as in environmental protection areas, with the features of the independent device claim, in particular from the characterizing part. In addition, the object according to the invention is achieved by a method for ventilating tunnels and / or shaft systems with the aid of a corresponding tunnel ventilation system with the features of the independent method claim, in particular from the characterizing part. Further features and details of the invention emerge from the respective subclaims, the description and the drawings. Features and details that are described in connection with individual aspects of the invention naturally also apply in connection with the other aspects of the invention and vice versa, so that with regard to the disclosure, reference is or can always be made to the individual aspects of the invention.

The invention provides a tunnel ventilation system comprising: at least one fan for sucking in and / or sucking out air and a motor for driving the fan. It is provided here that the engine is driven (directly or indirectly) with the aid of a fuel, in particular hydrogen (H _2).

The idea of the invention is that the engine is driven in an environmentally friendly (direct or indirect) way. Being driven directly with the help of a fuel is called im According to the invention, the motor is operated directly with the fuel, for example the motor converts the fuel into another form of energy, in particular mechanical energy. The motor can be designed, for example, as an internal combustion engine that burns the fuel, for example in the form of hydrogen, in order to drive the fan. The thermal energy of the combustion is converted into the mechanical kinetic energy of the fan.

To be driven indirectly with the aid of a fuel means in the context of the invention that the engine is driven indirectly with the fuel. The motor can, for example, be designed as an electric motor that is supplied with electrical energy by a fuel cell unit. The fuel cell unit converts the fuel, for example in the form of hydrogen, and an oxygen-containing reactant, for example in the form of simple ambient air, into electrical energy and water. Here, the electrochemical energy of the conversion is converted into the electrical energy for operating the electric motor and thus for driving the fan.

The fuel can be provided in fuel tanks, which can be designed as replaceable tank bottles and / or which, for example, at a gas station; can be filled or refueled. The tank bottles are pressure bottles (approx. Up to max. 300 bar or max. Approx. 700 bar), bottles with cooling for storing liquid gas and / or metal mesh tanks with heating for binding hydrogen ions.

In this way, an improved tunnel ventilation system can be made available which is simply constructed, which is easy to operate, which can be set up in a mobile manner and which can be operated in an environmentally friendly manner.

Furthermore, in the case of a tunnel ventilation system, the invention can provide that the motor is designed in the form of an electric motor. Here the engine is driven indirectly with the fuel. The advantages of an electric motor are that the electric motor does not produce any exhaust gases and provides the required power quickly, almost without delay. Another advantage of an electric motor is the power electronic control, which can expand the functionality of the tunnel ventilation system. The functionality of the tunnel ventilation system can, for example, be achieved by quickly changing the The direction of flow and / or can be expanded by specifically setting a desired flow rate.

Furthermore, in the case of a tunnel ventilation system, the invention can provide that a fuel cell unit, in particular a modular fuel cell unit, is provided (to generate electrical energy) which uses the fuel, in particular hydrogen, to supply the motor with electrical energy. The greatest advantage of a fuel cell unit is the environmentally friendly generation of energy without harmful exhaust gases. The advantages of a modular fuel cell unit can be that the fuel cell unit can be put together flexibly depending on the desired application and the available installation space, and that the modules can be easily exchanged, for example for maintenance purposes.

The fuel cell unit can advantageously have a water excretion reservoir. With the help of a water excretion reservoir, the product water (also called waste water) from the fuel cell unit can be collected and used as required, e.g. for water management of the fuel cell unit, e.g. B. to moisten the membrane (s) of the fuel cell unit, can be reused. For this purpose, the water excretion reservoir can have a return path to the fuel cell unit.

Furthermore, the invention can provide that the fuel cell unit has at least one electrical connection, in particular in the form of a socket, in order to supply at least one further consumer in addition to the motor with electrical energy. In the area of application of tunnel and / or shaft construction, many machines such. B. drills and compressors operated, which must be supplied as consumers with electrical energy. By means of an electrical connection, the fuel cell unit can offer a simple possibility of easily and conveniently supplying such machines as consumers with electrical energy on site.

In addition, it is conceivable within the scope of the invention that the fuel cell unit can have a temperature control system in order to control the temperature of the fuel cell unit to a suitable operating temperature (ie to warm it up or to cool it). The The temperature control system can advantageously serve to heat the fuel cell unit at low temperatures below a suitable operating temperature and to cool it down to a suitable operating temperature at high temperatures, for example during operation of the fuel cell unit. Reliable and efficient operation of the fuel cell unit can thus be ensured.

In addition, it can be provided that the engine is designed in the form of an internal combustion engine, in particular an Otto engine or a gas turbine, which is driven directly with the fuel. The advantages of an internal combustion engine can be that the internal combustion engine is a simple, inexpensive and robust component.

The motor, in particular in the form of an internal combustion engine, can advantageously have an output shaft which is in a mechanical operative connection, for example via a gear, with an input shaft of the fan or is directly connected to the input shaft of the fan in a rotationally fixed manner. In this way, a simple, inexpensive and space-saving construction of the tunnel ventilation system can be made possible.

According to a further advantage of the invention, a starter generator can be provided for the engine, in particular in the form of an internal combustion engine, in order to accelerate the engine (in its function as a starter) (to crank it when starting and / or to assist in driving the fan during operation ) and / or (in its function as a generator) to charge an electrical energy storage device. This ensures that the engine starts quickly and that the mechanical energy can be converted back into electrical energy when the engine is running down. If the fuel has been used up and / or if the engine cannot provide the required power or cannot provide it on its own, the starter generator can support the engine during operation in driving the fan.

Furthermore, the invention can provide for a tunnel ventilation system that an electrical energy store is provided in order to supply the motor, in particular in the form of an electric motor, for example in the event of failure or when refueling a fuel cell unit, with electrical energy and / or to supply the motor, in particular in Form of an internal combustion engine, accelerated by a starter generator. In this way, the resiliency in the Operation of the tunnel ventilation system can be ensured and the use of electrical energy within the system improved.

Furthermore, the invention can provide for a tunnel ventilation system that a sensor unit is provided in order to sense the fuel content in the air adjacent to the tunnel ventilation system and / or to examine the air quality of the air adjacent to the tunnel ventilation system. In this way it can be ensured that the fuel content in the air adjacent to the tunnel ventilation system is monitored in order to avoid an accumulation of explosive amounts of fuel. By monitoring the air quality, it can also be ensured that the air to breathe is always checked in order not to endanger the health of the miners, or that the air for operating the fuel cell unit meets the requirements of the fuel cell unit.

Furthermore, in a tunnel ventilation system, the invention can provide a fuel tank, in particular with a modular structure, for the fuel, preferably with several exchangeable tank bottles. The fuel tank and / or the tank bottles can be used for the storage of fuel in gaseous form under pressure, e.g. in pressure tanks, for the storage of fuel in liquid form, e.g. in tanks with appropriate cooling, or for the storage of fuel in ionic form , for example. In a metal grille with appropriate heating. The advantage of modular fuel tanks is the flexibility in storing the fuel. The advantage of exchangeable fuel bottles is the ease of exchange and refilling as well as the weight and installation space adaptation to the desired application and the local environment.

At least one fill level sensor for the fuel tank, in particular one fill level sensor for each tank bottle of the fuel tank, can advantageously be provided. In this way, the fill level of the fuel tank and / or the tank bottles of the fuel tank can be monitored in order to be able to ensure that the fuel tank or the tank bottles of the fuel tank are refilled or replaced in good time and that uninterrupted operation of the fuel cell unit can be made possible.

According to a particular advantage of the invention, an oxygen tank can be provided in order, for example, to supply a fuel cell unit with an oxygen-containing reactant. Since building rubble and / or fine dust are often in the air in the area of tunnel and / or shaft construction, this air can be unsuitable for operating the fuel cell unit. By storing the oxygen in an oxygen tank, the operation of the fuel cell unit can always be ensured.

In addition, the invention can provide a control unit in a tunnel ventilation system that is designed to control the tunnel ventilation system as a function of input commands from a user and / or as a function of sensor data from a sensor unit, in particular automatically and / or autonomously. As a result, an intelligent system can be made available which can be operated manually, automatically and / or even autonomously. A user can, for example, set the tunnel ventilation system, in particular the fan, manually for a certain time, for an interval start-up and / or for intermittent ventilation of the tunnel or the like. For this purpose, the control unit can be designed in such a way that the control unit proposes automated programs for operating the fan, for example via a user interface in the form of a touch display and / or a key input field. The user interface can be provided on a fan housing, for example. In addition, it is conceivable that the control unit can be designed in such a way that the control unit gives the user an option, for example via a user interface in the form of a touch display and / or a key input field, various settings for operating the fan, such as z. B. time, duration, interval, operating mode, etc. in detail to be able to carry out manually. Autonomous operation of a tunnel ventilation system can provide that the control unit can communicate with a sensor unit and control the tunnel ventilation system accordingly on the basis of sensor data (fuel content, air quality, etc.).

In addition, the invention can provide a lighting unit or a light unit in a tunnel ventilation system, for example comprising at least one lamp or an LED, in order to illuminate at least one area around the tunnel ventilation system. When building tunnels and / or shafts, it can often be very dark. A light unit can be used to ensure that there is sufficient light for the tunnel and / or shaft construction Construction work is available. The light unit can, for example, be arranged on a fan housing.

Furthermore, it is conceivable within the scope of the invention that the lighting unit can be designed to detect a presence of a user in an area around the tunnel ventilation system. Thus, the advantage can be achieved that the lighting unit saves energy, in particular in different modes, for example in an operating mode for illuminating an environment or at least one area around the tunnel ventilation system and / or in a sensor mode for sensing a user in the vicinity of the tunnel ventilation system , is operated. Only when a user is detected in the vicinity of the tunnel ventilation system can the lighting unit be transferred to the operating mode for illuminating the surroundings or at least one area around the tunnel ventilation system. To detect a user, the lighting unit can be operated in the sensor mode as an optical sensor unit which, for example, can have a light transmitter and a light receiver and, if necessary, corresponding evaluation and / or control electronics within the lighting unit.

Furthermore, the invention can provide a filter unit in a tunnel ventilation system in order to filter the air sucked in by the fan. In this way, sufficient air quality for the air you breathe during mining operations can be ensured.

Furthermore, the invention can provide a further filter unit in a tunnel ventilation system in order to filter the air in accordance with the requirements of a fuel cell unit. Thus, the air can be provided to the fuel cell unit in a sufficient quality (sufficient oxygen content, no harmful dust particles, etc.).

In addition, in the case of a tunnel ventilation system, the invention can provide that the at least one fan is designed to suck the air into a tunnel or to suck the air out of the tunnel. Sucking in air, for example from outside the tunnel into the tunnel, can serve to convey the fresh breathing air into the tunnel. The suction of air, for example from the tunnel to the outside, can serve to remove the dusty air from the tunnel, for example after a blast.

The at least one fan can advantageously have a protective grille. This reduces the risk of injury to the fan blades.

According to a further advantage, the at least one fan can have an adjusting system in order to adjust the air flow direction. Changing the air flow direction can help to switch the fan from suction to suction and to orientate the fan in general.

In addition, the invention can provide for a tunnel ventilation system that the at least one fan is designed to build up a pressure ratio between 1 and 1.3, in particular between 1 and 1.1, preferably 1.03, between an intake side and a pressure side. In this way, a sufficient current flow through the fan for exchanging the air can be ensured and at the same time the flow and noise during operation of the fan can be kept low.

Furthermore, in the case of a tunnel ventilation system, the invention can provide that the at least one fan is designed as an axial fan. An axial fan can be advantageous in order to convey the air along the tunnel or to align the direction of flow of the air along the tunnel.

Furthermore, the invention can provide for a tunnel ventilation system that the at least one fan is designed in such a way, in particular with large-area blades, in order to achieve a high speed at a relatively low speed between 1 to 10 revolutions per minute, in particular 1 to 3 revolutions per minute Volume flow of air from 40 to 100 m ³ per minute, preferably 70 to 100 m ³ per minute, to be conveyed. In this way, efficient operation of the tunnel ventilation system can be made possible with a reduced background noise and an air flow that is not too disruptive. In principle, however, it is also conceivable that the blades can be designed in such a way that the required amount of air at z. B. the number of people and / or devices and / or vehicles can be adjusted, for example increased.

Furthermore, in the case of a tunnel ventilation system, the invention can provide a wheel system, in particular an extendable wheel system, in order to move the fan and / or the motor.

This ensures the mobility and simplified commissioning of the tunnel ventilation system. The wheel system can preferably be designed to drive on rails and / or on, for example, flat roads.

In addition, it is conceivable within the scope of the invention that several fans can be arranged one behind the other. This not only covers the fresh air requirement along the tunnel, but also improves the flow characteristics of the entire system.

One motor can advantageously be provided for each of the plurality of fans. A modular structure of the tunnel ventilation system can thus be made possible, so that a different number of fans can be set up flexibly at different locations. In principle, however, it is also conceivable that a common motor can be provided for several fans.

According to a further advantage, one fuel cell unit can be provided for each of the multiple motors. A modular structure of the tunnel ventilation system can thus be made possible, so that a different number of fans can be set up flexibly at different locations. In principle, however, it is also conceivable that a common fuel cell unit can be provided for several motors. In the case of a fuel cell unit, only one cable has to be laid to the respective motor in order to be able to supply several motors with electrical energy.

If track-bound vehicles are working in the tunnels, the tunnel ventilation system according to the invention can (at least in part) preferably be transported with the aid of a trailer, for example in the form of a trolley. For this purpose, the trailer can have a coupling in order to connect the trailer to a work machine. The trailer can preferably have wheels which are suitable, for example, for driving on rails and / or on roads.

Furthermore, the object according to the invention is achieved by a method for ventilating tunnels and / or shaft systems with the aid of a tunnel ventilation system, which can in particular be designed as described above, comprising: at least one fan for sucking in and / or sucking out air and a motor for driving the fan. For this purpose, it is provided according to the invention that the motor is driven with the aid of a fuel. With the aid of the method according to the invention, the same advantages are achieved that were described above in connection with the tunnel ventilation system according to the invention. Reference is made here in full to these advantages.

Figur 1

eine schematische Darstellung einer Tunnelbelüftungsanlage im Sinne der Erfindung,

Figur 2

eine schematische Darstellung einer Tunnelbelüftungsanlage im Sinne der Erfindung,

Figur 3

eine schematische Darstellung eines Tunnels mit mehreren Tunnelbelüftungsanlagen im Sinne der Erfindung und

Figur 4

eine schematische Darstellung eines Anhängers für eine Tunnelbelüftungsanlage im Sinne der Erfindung.

Further advantages, features and details of the invention emerge from the following description, in which exemplary embodiments of the invention are described in detail with reference to the drawings. The features mentioned in the claims and in the description can be essential to the invention individually or in any combination. Show it:

Figure 1

a schematic representation of a tunnel ventilation system within the meaning of the invention,

Figure 2

a schematic representation of a tunnel ventilation system within the meaning of the invention,

Figure 3

a schematic representation of a tunnel with several tunnel ventilation systems within the meaning of the invention and

Figure 4

a schematic representation of a trailer for a tunnel ventilation system within the meaning of the invention.

In the following figures, the same reference numerals are used for the same technical features from different exemplary embodiments. As a rule, the reference symbols of the same exemplary embodiments are described only once.

The Figures 1 and 2 each show an exemplary embodiment of a tunnel ventilation system 100 according to the invention. The tunnel ventilation system 100 according to FIG the Figures 1 and 2 What is common is that at least one fan 10 for sucking in and / or sucking off air and one motor 20 for driving the fan 10 are provided within the framework of the system. To this end, the invention provides that the engine 20 is powered by a fuel H2, in particular hydrogen, (directly according to FIG Figure 2 or indirectly according to the Figure 1 ) is driven. An environmentally friendly operation of the tunnel ventilation system 100 can thus be made possible.

To drive the motor 20 directly with the aid of the fuel H2 according to FIG Figure 2 For example, the engine 20 can be used as an internal combustion engine 22, e.g. B. in the form of a gasoline engine or a gas turbine. The internal combustion engine 22 burns the fuel H2, for example in the form of hydrogen, directly in order to drive the fan 10.

For the indirect drive of the motor 20 with the aid of the fuel H2 according to FIG Figure 1 For example, the motor 20 can be designed as an electric motor 21 which is supplied with electrical energy by a fuel cell unit 30. The fuel cell unit 30 converts the fuel H2, for example in the form of hydrogen, and an oxygen-containing reactant, for example in the form of simple ambient air, into electrical energy and water.

Like it Figure 1 shows, a cable 33 is passed between the fuel cell unit 30 and the motor 20 in order to supply the motor 20 with electrical energy.

According to the Figure 1 the fuel cell unit 30 can have a modular structure. A fuel cell unit 30 enables environmentally friendly energy generation. A modular fuel cell unit 30 can advantageously be put together flexibly depending on the desired application and / or the available installation space. In addition, in the case of a modular fuel cell unit 30, the modules can easily be exchanged, for example for the purpose of maintenance.

For the fuel cell unit 30 according to FIG Figure 1 A water excretion reservoir 32 can furthermore be provided in order to collect the product water as a result of an electrochemical reaction in the fuel cell unit 30 and to make it available as required, for example to moisten the membrane (s) of the fuel cell unit 30 can. For this purpose, the water excretion reservoir 32 can have a return path, not shown, to the fuel cell unit 30.

With the aid of the fuel cell unit 30 according to FIG Figure 1 At least one electrical connection 31, for example in the form of a socket, can furthermore be provided in order to be able to supply at least one further consumer, for example a drill, in addition to the motor 20 with electrical energy.

Furthermore, the fuel cell unit 30 according to FIG Figure 1 have a temperature control system T in order to control the temperature of the fuel cell unit 30 to a suitable operating temperature, that is to say to heat it up and / or to cool it.

The engine 20 according to the Figure 2 , in particular in the form of an internal combustion engine, can have an output shaft W2, which is in a mechanical operative connection, for example via a gearbox, with an input shaft W1 of the fan 10 or can be connected directly to the input shaft W1 of the fan 10.

In addition, for the motor 20 according to FIG Figure 2 , in particular in the form of an internal combustion engine 22, a starter generator SG can be provided to crank the engine 20 (in its function as a starter) or to support the motor 20 in driving the fan 10 and / or (in its function as a generator) an electrical energy store E to charge, for example. When the engine 20 runs down.

In the context of the invention, according to the Figure 1 and the Figure 2 an electrical energy store E may be provided to the motor 20 in the case of Figure 1 to be supplied with electrical energy in the event of failure or when refueling the fuel cell unit 30 and / or in the case of the Figure 2 to accelerate the engine 20 via a starter generator SG.

In the context of the invention, according to the Figures 1 and 2 a sensor unit 40 can be provided in order to sense the fuel content in the air adjoining the tunnel ventilation system 100 and / or to examine the air quality of the air adjoining the tunnel ventilation system 100 for respiratory quality.

According to the Figure 1 In the case of a tunnel ventilation system 100, a fuel tank 23, in particular of modular construction, can be provided for the fuel H2, preferably with several exchangeable tank bottles. The fuel tank 23 or the tank bottles can be used for storing fuel H2 in gaseous form under pressure, for example in pressure tanks, for storing fuel H2 in liquid form, for example in tanks with appropriate cooling, or for storing fuel H2 in ion form, for example in a metal grid with appropriate heating.

According to the Figures 1 and 2 It is conceivable that at least one level sensor FS for the fuel tank 23, in particular one level sensor FS for each tank bottle of the fuel tank 23, can be provided.

As part of the Figure 1 it is also conceivable that an oxygen tank 24 can be provided in order to supply the fuel cell unit 30 with an oxygen-containing reactant.

For the tunnel ventilation system 100 according to the two Figures 1 and 2 A control unit 50 can be provided which is designed to control the tunnel ventilation system 100, in particular the fan 10 and / or the motor 20, depending on input commands from a user and / or depending on sensor data from a sensor unit 40, in particular automatically and / or autonomously , head for. The control unit 50 can have a user interface (not shown), for example in the form of a touch display and / or a key input field, e.g. B. have on a fan housing. To operate the tunnel ventilation system 100, in particular the fan 10, a user can use the user interface to enter manual commands, select automatic programs or switch to autonomous operation by the control unit 50.

In addition, the tunnel ventilation system 100 can according to the two Figures 1 and 2 have a lighting unit 60 in order to illuminate at least one area around the tunnel ventilation system 100. The lighting unit 60 can also be designed to detect a presence of a user in an area around the Capture tunnel ventilation system 100 around. The lighting unit 60 can be attached to a fan housing, for example. To control the lighting unit 60, a dedicated control unit can be provided for the lighting unit 60 or the control unit 50 of the tunnel ventilation system 100 can be designed.

Furthermore, the tunnel ventilation system 100 according to both Figures 1 and 2 have a filter unit F1 in order to filter the air sucked in by the fan 10 in accordance with the requirements of breathing air.

Furthermore, the tunnel ventilation system 100 according to FIGS Figures 1 and 2 have a further filter unit F2 in order to filter the air according to the requirements of a fuel cell unit 30.

For the fan 10 according to the Figures 1 and 2 A protective grille 11 can be provided in order to reduce the risk of injury to the rotor blades of the fan 10.

Within the scope of the invention, the fan 10 can have an adjusting system (not shown) in order to change the direction of air flow for the purpose of sucking in or sucking in and for orienting the fan in general.

The fan 10 under the Figures 1 and 2 can, for example, be designed as an axial fan in order to convey the air along the tunnel or to align the direction of flow of the air along the tunnel.

Like it Figures 1 and 2 Furthermore, show that the invention can provide a, in particular extendable, wheel system R in a tunnel ventilation system 100 in order to move the fan 10 and / or the motor 20 individually or together.

Like it Figure 3 also shows, several fans 10 can be provided within the scope of a tunnel ventilation system 100 according to the invention, which for example can be arranged one behind the other in order to cover the fresh air requirement along the tunnel and to improve the flow characteristic of the overall system.

According to the Figure 3 For example, a motor 20 can be provided for each of the plurality of fans 10. In principle, however, it is also conceivable that a common motor 20 can be provided for several fans 10.

In turn, one fuel cell unit 30 can be provided for each of the plurality of motors 20. In principle, however, it is also conceivable that a common fuel cell unit 30 can be provided for several motors 20. A cable 33 for each of the plurality of motors 20 can thereby be passed through from the fuel cell unit 30.

Like it Figure 4 indicates, a trailer 101, for example in the form of a trolley, can be provided, which is designed to transport the fan 10 and / or the motor 20 of the tunnel ventilation system 100. For this purpose, the trailer 101 can have a coupling 102 for connection to a work mesh 110 traveling on rails.

The above explanation of the embodiments describes the present invention exclusively in the context of examples. Of course, individual features of the embodiments can be freely combined with one another, provided that they are technically sensible, without leaving the scope of the present invention.

List of reference symbols

10

fan

11

Protective grille

20th

engine

21

Electric motor

22nd

Internal combustion engine

23

Fuel tank

24

Oxygen tank

30th

Fuel cell unit

31

electrical connection

32

Water excretion reservoir

33

electric wire

40

Sensor unit

50

Control unit

60

Light unit

100

Tunnel ventilation system

101

pendant

102

coupling

110

Work mesh

E.

electrical energy storage

FS

Level sensor

F1

Filter unit

F2

further filter unit

H2

fuel

R.

Wheel system

SG

Starter generator

T

Temperature control system

W1

Input shaft

W2

Output shaft

Claims (15)

Tunnel ventilation system (100), comprising: At least one fan (10) for sucking in and / or sucking out air and a motor (20) for driving the fan (10), characterized, that the motor (20) is driven with the aid of a fuel (H2), in particular hydrogen. Tunnel ventilation system (100) according to claim 1,
characterized,
that the motor (20) is designed in the form of an electric motor (21) and / or that the motor (20) is designed in the form of an internal combustion engine (22), in particular an Otto engine or a gas turbine, which is driven directly with the fuel (H2) becomes,
wherein in particular the motor (20) has an output shaft (W2) which is in a mechanical operative connection, in particular via a gearbox, with an input shaft (W1) of the fan (10) or directly with the input shaft (W1) of the fan (10) is rotatably connected,
and / or that a starter generator (SG) is provided for the motor (20) in order to accelerate the motor (20) and / or to charge an electrical energy store (E). Tunnel ventilation system (100) according to claim 2,
characterized,
that a particularly modular fuel cell unit (30) is provided which uses the fuel (H2) to supply the motor (20) with electrical energy,
wherein in particular the fuel cell unit (30) has a water excretion reservoir (32),
the water excretion reservoir (32) preferably having a return path to the fuel cell unit (30) for water management of the fuel cell unit (30),
and / or that the fuel cell unit (30) has at least one electrical connection (31), in particular in the form of a socket, in order to supply at least one consumer in addition to the motor (20) with electrical energy,
and / or that the fuel cell unit (30) has a temperature control system (T) in order to control the temperature of the fuel cell unit (30) to a suitable operating temperature. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that an electrical energy store (E) is provided in order to supply the motor (20) with electrical energy, e.g. in the event of failure or when refueling a fuel cell unit (30) and / or to supply the motor (20) via a starter generator (SG) to accelerate. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a sensor unit (40) is provided in order to sense the fuel content in the air adjacent to the tunnel ventilation system (100) and / or to examine the air quality of the air adjacent to the tunnel ventilation system (100). Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a fuel tank (23), in particular with a modular structure, is provided for the fuel (H2), preferably with several exchangeable tank bottles,
wherein in particular at least one level sensor (FS) for the fuel tank (23), in particular one level sensor (FS) for each tank bottle of the fuel tank (23), is provided. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that an oxygen tank (24) is provided in order, in particular, to supply a fuel cell unit (30) with an oxygen-containing reactant. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a control unit (50) is provided which is designed to control the tunnel ventilation system (100) as a function of input commands from a user and / or as a function of sensor data from a sensor unit (40), in particular automatically and / or autonomously. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a lighting unit (60) is provided to illuminate at least one area around the tunnel ventilation system (100),
wherein in particular the lighting unit (60) is designed to detect a presence of a user in an area around the tunnel ventilation system (100). Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a filter unit (F1) is provided to filter the air sucked in by the fan (10),
and / or that a further filter unit (F2) is provided in order to filter the air in accordance with the requirements of a fuel cell unit (30). Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that the at least one fan (10) is designed to suck the air into a tunnel or to suck the air out of the tunnel,
and / or that the at least one fan (10) has a protective grille (11), and / or that the at least one fan (10) has an adjusting system in order to set the air flow direction. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that the at least one fan (10) is designed to build up a pressure ratio between 1 and 1.3, in particular between 1 and 1.1, preferably 1.03, between an intake side and a pressure side,
and / or that the at least one fan (10) is designed as an axial fan, and / or that the at least one fan (10) is designed in such a way, in particular with large-area blades, to operate at a relatively low speed of between 1 and 10 Revolutions per minute, in particular 1 to 3 revolutions per minute, to convey a large volume flow of air of 40 to 100 m ³ per minute, preferably 70 to 100 m ³ per minute. Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that an especially extendable wheel system (R) is provided to move the fan (10) and / or the motor (20),
and / or that several fans (10) are arranged one behind the other, in particular one motor (20) being provided for each of the several fans (10). Tunnel ventilation system (100) according to one of the preceding claims,
characterized,
that a trailer (101), in particular in the form of a trolley, is provided to transport the fan (10) and / or the motor (20) of the tunnel ventilation system (100),
wherein in particular the trailer (101) has a coupling (102) for connection to a work mesh (110) traveling on rails. Method for ventilating tunnels and / or shaft systems with the aid of a tunnel ventilation system (100), in particular according to one of the preceding claims, comprising: at least one fan (10) for sucking in and / or sucking out air and a motor (20) for driving the fan (10), characterized, that the motor (20) is driven with the aid of a fuel (H2), in particular hydrogen.

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