WO2009043669A2

WO2009043669A2 - Device for cooling an energy accumulator

Info

Publication number: WO2009043669A2
Application number: PCT/EP2008/061557
Authority: WO
Inventors: Peter Eckert; Michael Meinert; Karsten Rechenberg
Original assignee: Siemens Aktiengesellschaft
Priority date: 2007-09-27
Filing date: 2008-09-02
Publication date: 2009-04-09
Also published as: WO2009043669A3; EP2201293A2; CN101878394A; DE102007046369A1; US20100205982A1

Abstract

The invention relates to a device for cooling an energy accumulator (1) in a rail vehicle. According to the invention, the energy accumulator (1) has a direct thermal connection to an evaporator (2) and the evaporator (2) and a condenser (5) form part of a circuit of a refrigerator.

Description

Device for cooling an energy storage device

The invention relates to a device for cooling an energy store in a rail vehicle.

Energy storage can be present in rail vehicles for different purposes. In particular, powerful energy storage devices are necessary in order to be able to operate a rail vehicle, for example a tram, at least in sections without external energy supply. Track sections without catenary or track are desired when a tram is to be passed through a narrow street or through a pedestrian zone.

In an energy storage, especially in such a powerful energy storage, as is necessary for the operation of a tram, it comes through internal power losses to a warming of the energy storage. This heat input leads to a shortening of the lifetime of the energy storage.

It has already been proposed to provide air cooling or water cooling for cooling an energy store. Such cooling is not effective enough for electrically and thermally heavily loaded energy storage.

The invention has for its object to provide a device for cooling an energy storage in a rail vehicle, which allows more effective cooling than before.

The object is achieved according to the invention in that the energy storage is thermally directly connected to an evaporator and that the evaporator and a capacitor are components of a circuit of a refrigerator. With the chiller, the advantage is achieved that the heat generated in the energy storage is dissipated quickly and reliably. Due to the cycle of the chiller is always sufficient coolant available. It is therefore possible to reliably cool even electrically and thermally heavily loaded energy storage devices. There is also the advantage that several energy storage with much less distance than was previously possible, can be set up and that there is still a good cooling possibility. An additional advantage is the fact that such a refrigerator operates quietly, so that less disturbing noises than z. B. arise in a coolant fan.

For example, the evaporator is part of a compression refrigerating machine via a compressor with the condenser and the condenser is connected via a throttle to the evaporator.

According to another example, the evaporator is part of an absorption chiller via a compressor with the condenser and the condenser is connected via a thermal compressor with the evaporator.

Both with a compression refrigeration machine and with an absorption refrigeration machine, the advantage is achieved that even electrically and thermally heavily loaded energy storage devices can be reliably cooled.

The compression refrigeration machine and the absorption refrigeration machine are known as such. While in the compression refrigeration machine, the condensed refrigerant is only compressed by a throttle and then supplied to the evaporator, the absorption chiller provides a thermal compressor which is a solution cycle. There, the coolant is first dissolved in a liquid, whereby heat is released. Thereafter, the dissolved refrigerant is expelled from the solution by supplying external heat. The coolant has a higher density after this process than before. For the removal of heat energy from the thermal compressor this is thermally, for example, with a heating circuit for the passenger compartment heating of the rail vehicle in conjunction. The resulting heat is thus used to advantage.

For the supply of heat energy to the thermal compressor this is thermally in connection for example with a Abwärmelei- the rail vehicle. For the expulsion of the coolant from the solution namely the external supply of heat energy is necessary. By utilizing the waste heat pipe of the rail vehicle, this heat energy advantageously does not need to be generated separately.

The energy storage is, for example, an electrical energy storage such. As an UltraCap or a double-layer capacitor.

According to another example, the energy storage is a e- lektrochemischer energy storage, such. B. a battery. Such a battery can, for. B. be a nickel-cadmium battery.

For example, several energy storage devices are connected to only one evaporator. Since the power of only one chiller is sufficient to dissipate the heat generated from a plurality of energy storage, cooling of several energy storage in a small space is advantageously possible.

For example, the condenser is thermally in communication with a heating circuit for the passenger compartment heating of the rail vehicle. This heat is used advantageously in the condenser of the refrigerator.

For controlling / regulating the cooling process in the rail vehicle, for example, a control unit is present. This will be the Advantage that the cooling process can be adapted to the requirements.

For example, the control unit consists of several units, which may optionally be distributed in the rail vehicle.

The energy storage devices to be cooled can be located in the rail vehicle in the vehicle head, at another point within the vehicle, on the roof or under the corridor. The rail vehicle may be in addition to a tram and a light rail or a long-distance train. The device for cooling the energy storage but can also in a locomotive, z. As a shunting locomotive, or in a track-guided rubber-tired vehicle use.

With the device according to the invention, in particular the advantage is achieved that even electrically and thermally highly loaded energy storage and correspondingly a number of closely juxtaposed energy storage can be cooled reliably and quietly. As a result, the life of the energy storage is significantly increased. The device is to be arranged particularly well in a tram train, which should at least partially drive without energy from the outside.

Exemplary embodiments of a device for cooling an energy store in a rail vehicle are explained in more detail with reference to the drawing:

FIG. 1 shows a device with a compression refrigeration machine,

Figure 2 shows an apparatus with an absorption chiller.

According to Figure 1, an energy storage device 1, which is located in a rail vehicle and may be a battery or an electrical capacitor, directly with a thermally Evaporator 2 a compression refrigeration machine 3 connected. In the compression refrigeration machine 3, the evaporator 2 is connected via a compressor 4 to a condenser 5, which is connected to the evaporator 2 via a throttle 6 forming a circuit. While the evaporator 2 from

Energy storage 1 absorbs heat, the capacitor 5, the heat from the environment. The coolant flows in gaseous form from the evaporator 2 to the condenser 5 and liquid from the condenser 5 to the evaporator 2.

According to Figure 2, the energy storage 1 is also thermally connected directly to the evaporator 2. The evaporator 2 is part of an absorption refrigeration machine 7, in which, as in the case of the compression refrigeration machine 3 (FIG. 1), the evaporator 2 is connected to a condenser 5 via a compressor 4. The condenser 5 is in the absorption chiller 7 but via a thermal compressor 8 forming a circuit back to the evaporator 2 in connection. This thermal compressor 8 is a solution cycle. There, the coolant within an absorber 9 in a

Liquid dissolved and then expelled within an expeller 10 again from the liquid. As a result, the coolant is compressed. The expeller 10 must be supplied with heat energy while the absorber 9 gives off heat energy. For supplying heat, the expeller 10 is thermally in communication with a waste heat pipe 11 of the rail vehicle. The absorber 9 is to use the heat given off by him thermally connected to a heating circuit 12, the z. B. the passenger compartment heating of the rail vehicle supplies. The solution passes through a first line 13, in which a solution pump 14 and the secondary side (cold side) of a heat exchanger 15 is integrated, from the absorber 9 to the expeller 10. The freed of the coolant liquid passes through a second line 16, in which the primary side (warm side) of the heat exchanger 15 is integrated, from the expeller 10 back to the absorber 9. Both in the embodiment according to FIG. 1 and in the embodiment according to FIG. 2, the condenser 5 is thermally connected with the heating circuit 12 for use of the heat emitted by it, for example supplying the passenger compartment heating of the rail vehicle.

With the device for cooling the energy storage device 1, a large energy storage device 1 or more energy storage devices can be cooled simultaneously, so that a large storage capacity for electrical energy is possible in a rail vehicle. Powerful rail vehicles with such energy storage devices 1 can be operated over long distances without external power supply.

Claims

claims

1. Device for cooling an energy store (1) in a rail vehicle, characterized in that the energy store (1) thermally directly with an evaporator (2) in

Connection is and that the evaporator (2) and a condenser (5) are components of a circuit of a refrigerator.

2. Apparatus according to claim 1, characterized in that the evaporator (2) as part of a compression refrigeration machine (3) via a compressor (4) to the condenser (5) and the condenser (5) via a throttle (6) with the evaporator (2) are connected.

3. Apparatus according to claim 1, characterized in that the evaporator (2) as part of an absorption refrigeration machine (7) via a compressor (4) with the condenser (5) and the condenser (5) via a thermal compressor (8) with the Evaporator (2) are connected.

4. Apparatus according to claim 3, characterized in that for the removal of heat energy from the thermal compressor (8) of this thermally with a heating circuit (12) for the passenger compartment heating of the rail vehicle is in communication.

5. Device according to one of claims 3 or 4, characterized in that for the supply of heat energy to the thermal compressor (8) this is thermally connected to a waste heat pipe (11) of the rail vehicle in connection.

6. Device according to one of claims 1 to 5, characterized in that the energy store (1) is an electrical energy storage.

7. Device according to one of claims 1 to 5, characterized in that the energy store (1) is an electrochemical energy store.

8. Device according to one of claims 1 to 7, characterized in that a plurality of energy storage (1) with only one evaporator (2) are in communication.

9. Device according to one of claims 1 to 8, character- ized in that the capacitor (5) thermally with a

Heating circuit (12) for the passenger compartment heating of the rail vehicle is in communication.

10. Device according to one of claims 1 to 9, character- ized in that for controlling the cooling process in the

Rail vehicle, a control unit is present.

11. The device according to claim 10, characterized in that the control unit consists of several units.