DE102020003813A1 - vehicle - Google Patents

Abstract

The invention relates to a vehicle, comprising a battery (3) for driving the vehicle (1) and a PCM heat storage device (9, 35) as an air conditioning battery. In the case of a vehicle whose range is optimized with simultaneous reliable climate regulation of the vehicle interior, the battery (3) for driving the vehicle (1) extends flat along a floor (5) of a vehicle cabin (7), the PCM heat storage device (9, 35) is arranged flat above the battery (3) and forms an air duct (25) which can be ventilated substantially parallel to the battery (3) and the PCM heat accumulator (9, 35)

Description

The invention relates to a vehicle, comprising a battery for driving the vehicle and a PCM heat storage device as an air conditioning battery.

High-voltage batteries that are used to drive electric vehicles not only have an influence on the range of the vehicle, but are also responsible for the climate in the vehicle cabin. The more energy the high-voltage battery has to provide for climate control, the shorter the range of the vehicle.

From the DE 10 2014 017 989 A1 a high-voltage battery arrangement with a latent heat storage device for a motor vehicle is known. The PCM material of the latent heat storage enables an improved battery capacity via a better temperature battery.
However, storage heat losses occur with long transport routes.

It is also known to use a PCM heat storage unit as an air conditioning battery.

The object of the invention is to specify a vehicle whose range is optimized with simultaneous reliable climate regulation of the vehicle interior.

The invention results from the features of the independent claims. The dependent claims relate to advantageous developments and refinements. Further features, possible applications and advantages of the invention emerge from the following description and the explanation of exemplary embodiments of the invention which are shown in the figures.

The object is achieved with a vehicle in that the battery for driving the vehicle extends flat along the floor of a vehicle cabin, the PCM heat storage being arranged flat above the battery and one essentially parallel to the battery and the PCM heat storage Forms planar, ventilated air duct. Such positioning of the battery and the PCM heat storage means that there is hardly any storage heat loss over long transport routes, so that both air conditioning of the vehicle cabin and an increase in the range of the vehicle are possible, since energy is saved through the air duct when heating the vehicle.

The battery is advantageously integrated into the floor of the vehicle cabin. This compact design means that less installation space is required and, at the same time, direct contact is made for heating the vehicle cabin.

In one embodiment, the floor of the vehicle cabin is perforated for the air-side connection to the air duct. As a result, the air heated by the PCM heat accumulator can enter the vehicle cabin unhindered.

In one variant, a heating wire connected to a power source runs through the PCM heat store. This design enables the heat storage state of the PCM heat store to be maintained continuously.

In one embodiment, the PCM material of the PCM heat storage device has strip-shaped PCM cells which are formed in one plane and form ventilation channels, through which the heating wire runs in a meandering manner. The numerous ventilation channels allow good heat transport from the PCM heat storage device into the vehicle cabin through the air circulating in the ventilation channels.

It is advantageous if the PCM heat store has several Peltier elements that are connected in series to the external power source. The PCM material of the PCM heat storage device is reliably charged by means of these Peltier elements.

In a further embodiment, the Peltier elements can be switched between summer and winter operation. By reversing the direction of the current, the Peltier elements can either be used for heating or cooling, so that, depending on the current season, cold or heat can be stored in the PCM heat storage and exchanged with the vehicle cabin.

In a further variant, the air is circulated in the PCM heat store and / or from the PCM heat store to the vehicle cabin by means of an aerator. This ventilator can suck in air from the vehicle cabin or fresh air from the outside and feed it into the air ducts for air circulation in the PCM heat accumulator.

In a further embodiment, an engine hood can be used as an energy absorber, which is connected to the PCM heat storage device via a ventilation system in order to pass on the warm air collected under the engine hood. In this way, the energy resources around the vehicle, such as the sun and outside temperatures, are used to operate the air conditioning battery.

Further advantages, features and details emerge from the following description, in which - optionally with reference to the drawing - at least one embodiment is described in detail. Described and / or graphically represented features can form the subject matter of the invention individually or in any meaningful combination, optionally also independently of the claims, and in particular can also be the subject matter of one or more separate applications. Identical, similar and / or functionally identical parts are provided with the same reference symbols.

• 1 ein Ausführungsbeispiel des erfindungsgemäßen Fahrzeuges,
• 2 ein erstes Ausführungsbeispiel des PCM-Wärmespeichers,
• 3 ein zweites Ausführungsbeispiel des PCM-Wärmespeichers,
• 4 ein Ausführungsbeispiel zur Anbindung einer Motorhaube an den PCM-Wärmespeicher.

Show it:

• 1 an embodiment of the vehicle according to the invention,
• 2 a first embodiment of the PCM heat storage,
• 3 a second embodiment of the PCM heat storage,
• 4th an embodiment for connecting a hood to the PCM heat storage.

In 1 an embodiment of a vehicle according to the invention is shown. With this vehicle 1 it is an electric vehicle in which the energy to drive the vehicle is provided by a high-voltage battery 3 provided. The high-voltage battery 3 is along a floor 5 a vehicle cabin 7th , in which the passengers take a seat, designed flat. Above the high-voltage battery 3 is also a flat PCM (phase change material) heat storage 9 arranged, which with an aerator 11 for drawing in fresh air from outside or circulating air from the vehicle cabin 7th connected is. The floor 5 the vehicle cabin 7th is in the area of the vehicle seats 13th , 15th for the energy output of the air, which comes from the PCM heat storage 9 outlet, perforated.

The PCM heat storage 9 Forms a climate battery due to the filling with PCM material for energy storage. 2 shows a first embodiment of the PCM heat store 9 . The PCM material is in PCM cells 17th divided, which are strip-shaped and are arranged parallel and spaced from one another. By the distance between the individual PCM cells 17th become ventilation ducts 19th created in which the by the aerator 11 in the air duct 21st of the PCM heat storage 9 sucked in air 23 circulates. The PCM cells give 17th Energy in the air 23 off that in another air duct 25 , which one to the, the first air duct 21st remote ends of the PCM cells 17th is formed, is collected and via an air passage 27 such as the perforation in the floor 5 the vehicle cabin 7th , is issued to this. To always have enough heat in the PCM cells 17th to save, these are held by a meandering heating wire 29 interspersed with an external power source 31 connected is. The current flow through the heating wire 29 leads to warming of the PCM cells 17th . This heat is in the PCM cells 17th stored and carried on the surface of the PCM cells 17th circulating air 23 discharged again. For better heat exchange, the surfaces of the PCM cells are made of metal 33 , preferably copper wire.

A second embodiment of the PCM heat storage 35 is shown in FIG. This is different from 2 in that instead of the heating wire in the air duct 21st several Peltier elements 37 are spaced apart in series. These Peltier elements 37 are connected in series to the external power source 39 connected. The one from the aerator 11 sucked in air 23 flows through the Peltier elements 37 . These Peltier elements 37 have the advantage that they can be switched to cold mode in summer time, so that the PCM cells receive cold 17th which is stored in these and, if necessary, by the PCM cells 17th cooled air 23 through the air outlet 27 is forwarded to the vehicle cabin. When the current direction is switched, the Peltier elements arrive 37 in heat mode, where heat is sent to the PCM cells 17th is issued, with which the vehicle cabin can be heated. In summer, the Peltier elements 37 the warm air and in winter the cold air are directed outside.

To use natural resources to warm the PCM cells 17th can, as in 4th shown is the hood 41 can be used as an energy absorber. It shows 4a a cut through the hood 41 and 4b a plan view The rear ventilation warmed by the sun 43 the hood 41 becomes a ventilation system 45 supplied, which with the PCM heat storage 9 connected is. This means that the sun's energy is used to charge the PCM heat storage system 9 used what both while driving the vehicle 1 as well as when the vehicle is stationary 1 can be done.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102014017989 A1 [0003]

Claims (10)

Vehicle, comprising a battery (3) for driving the vehicle (1) and a PCM heat storage (9, 35) as an air conditioning battery, characterized in that the battery (3) for driving the vehicle (1) is flat along a floor ( 5) a vehicle cabin (7), the PCM heat storage (9, 35) being arranged flat above the battery (3) and a substantially parallel to the battery (3) and the PCM heat storage (9, 35) Forms a planar, ventilatable air duct (25). Vehicle after Claim 1 characterized in that the battery (3) is integrated into the floor (5) of the vehicle cabin (7). Vehicle after Claim 1 or 2 characterized in that the air duct (25) is connected on the air side to bodywork areas that can be ventilated. Vehicle after Claim 3 , characterized in that the floor (5) of the vehicle cabin (7) is perforated for the air-side connection to the air duct (25). Vehicle according to at least one of the preceding claims, characterized in that the PCM heat storage device (9) is traversed by a heating wire (29) connected to a power source (31). Vehicle after Claim 5 , characterized in that the PCM material of the PCM heat accumulator (9) has strip-shaped PCM cells (17) formed in a plane and forming ventilation channels (19) through which the heating wire (29) runs in a meandering manner. Vehicle according to at least one of the preceding Claims 1 to 4th , characterized in that the PCM heat accumulator (35) has several Peltier elements (37) which are connected in series to the external power source (39). Vehicle after Claim 7 , characterized in that the Peltier elements (37) can be switched between summer and winter operation. Vehicle according to at least one of the preceding claims, characterized in that the air circulation in the PCM heat store (9, 35) and / or from the PCM heat store (9, 35) to the vehicle cabin (7) takes place through a ventilator (11) . Vehicle according to at least one of the preceding claims, characterized in that an engine hood (41) can be used as an energy absorber, which is used to convey the warm air (43) collected under the engine hood (41) via a ventilation system (45) to the PCM heat store (9 ) connected is.

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