WO2016139015A1

WO2016139015A1 - Rail vehicle with traction cooling system

Info

Publication number: WO2016139015A1
Application number: PCT/EP2016/051621
Authority: WO
Inventors: Rudolf-Gerhard Volle
Original assignee: Siemens Aktiengesellschaft
Priority date: 2015-03-02
Filing date: 2016-01-27
Publication date: 2016-09-09
Also published as: ES2733584T3; DE102015203668A1; EP3242824B1; RU184315U1; EP3242824A1; CN209521693U

Abstract

The invention relates to a rail vehicle with at least one traction component, which can be cooled by means of a traction cooling system (1), and with an air conditioner, which is provided for air conditioning an interior passenger compartment of the rail vehicle and has an outgoing air channel (9) fluidically connected to the interior passenger compartment and leading out of the rail vehicle, wherein the traction cooling system (1) comprises a heat exchanger (2) at which ambient air (5) drawn in by means of a fan module (3) is guided from an air intake side (6) of the heat exchanger (2) out to an air outlet side (7) of the heat exchanger (2) for cooling the heat exchanger (2), wherein an outlet end (10) of the outgoing air channel (9) of the air conditioner is arranged on the air inlet side (6) of the heat exchanger (2) of the traction cooling system (1) in such a way that the fan module (3) draws in the outgoing air located in the outgoing air channel (9) so that the traction cooling system (1) effects an outgoing air mass flow rate and functions as an outgoing air device.

Description

description

Rail vehicle with traction cooling system

The invention relates to a rail vehicle according to the preamble of claim 1.

After that is a rail vehicle with at least one

Traktionskomponente, which is cooled by means of a traction cooling system, and known with an air conditioner, which is provided for Kli ^¬ matization of a passenger compartment of the rail vehicle and having a fluidic connected to the passenger compartment and leading out of the rail vehicle exhaust air duct, the traction cooling system comprises a heat exchanger to which by means of a

Fan module sucked ambient air from an air inlet ^¬ side of the heat exchanger to an air outlet side of the heat exchanger for cooling the heat exchanger vorbeige ^¬ leads.

As described above, in a conventional rail vehicle for the heat dissipation of the at least one traction component on the one hand and the discharge of room air from the passenger compartment of the rail vehicle are thus different devices. Thus, typically under the floor is arrange ^¬ te traction cooling system by means of which heat exchanger cooling fluid for the traction component is cooled is used, the upright attitude ^¬ the operation of the traction component. This can be, for example, a power converter, but also a transformer.

In contrast, the exhaust air device sucks air from the Fahrgastin ^¬ nenraum and guides it to the outside of the vehicle.

Against this background, the general task is to reduce the complexity of the fluidic equipment in a rail vehicle. This object is achieved by the characterizing features of claim 1 ge ^¬ triggers in the aforementioned rail vehicle ^¬ . Thereafter, it is provided in the rail vehicle that an off ^¬ lassende the exhaust air duct of the air conditioner on the Luftein ^¬ lassseite the heat exchanger of the traction cooling system is arranged such that the fan module sucks in the exhaust duct be ^¬ sensitive exhaust air, so that the traction cooling system causes a mass flow of exhaust air and as Exhaust air device ^¬ beitet ar.

According to this procedure, the exhaust air device used in the prior art is omitted as a separate component of the

Rail vehicle. Rather, the traction cooling system takes over the function of the exhaust air device for the discharge of exhaust air from the passenger compartment of the rail vehicle. This may require that the traction cooling system be sized larger than conventional traction cooling systems in terms of the performance of their fan / their fan assembly.

This results in the advantage that space is saved in the underfloor area of the rail vehicle. It is also expected that a total mass, an electrical energy consumption and a total cost of the rail vehicle will be reduced.

Preferably, at a predetermined minimum speed of the

Fan module of the exhaust duct so geometrically designed and arranged with its outlet end to the air inlet side of the heat exchanger of the traction cooling system that a required according to the requirements of the air conditioning of the vehicle interior to the air conditioning exhaust air mass flow at the minimum speed can be discharged. This ensures even in the event that the electric traction component currently has no cooling demand and the fan module is operated at the predetermined minimum speed that sufficient exhaust air from the vehicle interior can be discharged. Advantageously, the exhaust air mass flow in the exhaust air line can be controlled. This makes it possible to respond to any such short notice occurring particularly high Anforderun ^¬ gen cooling capacity for traction component. In this case, the exhaust air mass flow can be lowered so that more ambient air is sucked in by the fan module so that a higher heat dissipation of electrical ^¬ rule traction component by the traction cooling system can ^¬ follow.

The exhaust air mass flow can be controlled, for example, by means of a rotatable air damper, which is integrated into the exhaust air duct for realizing various free cross sections of the exhaust air duct. If, for example, a temperature of the electric traction component to be cooled is monitored and this monitoring leads to the detection of an increased cooling requirement, the rotatable air damper can reduce the free cross section within the exhaust air duct in such a way that the exhaust air mass flow remains essentially the same despite the increased speed of the fan module.

Generally speaking, the exhaust air mass flow may be controlled depending on an operational cooling requirement of the at least one traction component to the traction cooling system.

A monitoring of the exhaust air mass flow in the exhaust duct can be done by means of an air flow sensor. An embodiment of the invention will be explained in more detail with reference to the drawings. The only peo ^¬ ge figure shows a schematic block diagram representations of a traction cooling system with cooperating components of a rail vehicle.

As shown in the figure, a Traktionskühlanlage used for example in a rail vehicle 1 includes a heat exchanger 2 and a fan module 3. The fan module 3 wiest in the present embodiment, a fan 4, the ambient air 5 in the direction of a Lufteinlasssei te 6 of the heat exchanger 2 sucks and past the heat exchanger 2, after which the heated ambient air leaves the heat exchanger 2 on an air outlet 7.

The heat exchanger 2 may be an air / fluid heat exchanger, wherein the fluid is the cooling fluid for an electrical

Traction component (e.g., power converter, transformer) and the cooling fluid flows through a traction cooling circuit

By suitable flow guidance the Wärmetau exchanger 2 passing ambient air leaves the traction cooling system in a blown air stream. 8

The traction cooling system 1 also acts as exhaust air device. To this end carries a exhaust air duct 9 of a passenger compartment of the rail vehicle to the air inlet side 6 of the heat exchanger 2. An outlet 10 of the exhaust air duct 9 is UNMIT ^¬ telbar at the air inlet side 6 of the heat exchanger 2 is ^¬ arranged so that the fan module 3 at the outlet 10 the exhaust air duct 9 generates a negative pressure which causes sucked air 11 from the passenger compartment also passes through the heat exchanger 2 and the air stream 8 is added to blown air. For this purpose it may be necessary for a conventional traction cooling system towards ^¬ clearly the performance of their fan module 3 in such aufzurüs ^¬ th that parallel the heat exchanger 2 entwärmt for the electric drive component and the exhaust air from the vehicle interior can be removed.

For the operation of the traction cooling system, in principle, the function of cooling the electric drive component has priority. For example, when suddenly increased cooling demand for the electric drive component, an exhaust air mass flow can be kept unchanged despite increased performance of the fan module 3. For this purpose is in the Outgoing air duct 9, an air flow sensor 12 is provided, with the aid of a size of the exhaust air ^mass flow in the exhaust duct 9 is monitored and measurable. With the help of an air damper 13 inserted into the exhaust duct 9, the size of the exhaust air mass flow can be suitably controlled, in which a remaining free cross section of the exhaust air duct 9 is a ^¬ adjustable. For this purpose, the air flap 13 is rotatably suspended and, depending on a cooling requirement for the electric drive component, controllable.

The fan module 3 is in terms of the speed of his

Fan 4 controlled depending on a cooling demand of the electric drive component. In general, these Steue ^¬ tion takes place such that a rotational speed of the fan 4 is lifted so far with increased cooling requirements that can be met parallel functionali ^¬ nen "exhaust air device" and "traction cooling system". When the cooling request of the electric drive component is so high that an excessively high exhaust air would result in mass flow, the air damper 13 is driven to be ^¬ Verrin- delay of a free cross section of the exhaust air duct. 9

For the fan module 3, a minimum speed is specified, which is applied even when there is no cooling requirement for the electric traction component. In this case, the traction cooling system 1 acts primarily as exhaust air device. For this purpose, the exhaust air duct 9 is designed geometrically (flow resistance of the channel) that the predetermined minimum speed ^{¬ of} the fan module is sufficient to meet requirements of the air conditioning of the vehicle interior to the air conditioning, ie a required exhaust air mass flow is generated by the fan module 3.

Claims

claims

1. Rail vehicle with at least one traction component, which is cooled by means of a traction cooling system (1), and with an air conditioning system, which is provided for air conditioning of a passenger ^¬ interior of the rail vehicle and a fluidically connected to the passenger compartment and out of the rail vehicle exhaust duct (9) on ^¬ , wherein the traction ^cooling system (1) comprises a heat exchanger (2), on which by means of a fan module (3) sucked ambient air (5) from an air inlet side (6) of the heat ^¬ exchanger (2) from an air outlet side (7) the Wärmetau ^¬ exchanger (2) for heat dissipation of the heat exchanger (2) by GE ^¬ leads is

characterized in that

an outlet end (10) of the exhaust air duct (9) of the air conditioner at the air inlet side (6) of the heat exchanger (2) of

Traktionskühlanlage (1) is arranged such that the

Fan module (3) in the exhaust air duct (9) sucks exhaust air located, so that the traction cooling system (1) causes a exhaust air mass flow and works as exhaust air device.

2. Rail vehicle according to claim 1,

characterized in that

at a given minimum speed of the fan module (3) the

Outgoing air duct (9) designed geometrically and with its outlet end (10) on the air inlet side (6) of the Wärmetau ^¬ shear (2) of the traction cooling system (1) is arranged, that according to the requirements of the air conditioning of the vehicle interior to the air conditioning required Exhaust air mass flow at the minimum speed can be dissipated.

3. Rail vehicle according to one of claims 1 or 2, characterized in that

the exhaust air mass flow in the exhaust air line is controllable.

4. Rail vehicle according to one of claim 3,

characterized in that

the exhaust air mass flow is controllable by means of a rotatable air flap (13), which is used to realize various free cross sections of the exhaust air duct (9) in the exhaust air duct (9).

5. Rail vehicle according to one of claims 3 or 4, characterized in that

the exhaust air mass flow is controlled as a function of an operational cooling requirement of the at least one traction component to the traction cooling system (1).

6. Rail vehicle according to one of claims 3 to 5, characterized in that

the exhaust air mass flow is monitored by means of an air quantity sensor (12).