DE102014214556A1 - Tank system and method for refueling - Google Patents

Abstract

A tank system (10) with a pressure tank (12) for receiving a fluid and a filling line (14) is described, with an outflow opening (18) through which the fluid flows into the pressure tank (12). Furthermore, a control element (20) is provided in the filling line (14) and / or at the outflow opening (18) which controls the mass flow of the fluid in such a way that the fluid at least partially flows into the pressure tank (12) like a ring vortex. Furthermore, a method for refueling a pressure tank (12) of a tank system (10) is described.

Description

The invention relates to a tank system and a method for refueling a pressure tank of a tank system for a motor vehicle.

Automotive vehicles with a tank system having a pressurized tank for, for example, natural gas, LPG or hydrogen are becoming increasingly popular nowadays as they represent an alternative to purely conventional motor vehicles with an internal combustion engine. Such motor vehicles can be hybrid vehicles which have a further drive in addition to a conventional internal combustion engine, as well as motor vehicles which are operated exclusively with a fluid such as natural gas, LPG or hydrogen. In such a motor vehicle, the fluid is introduced into the pressure tank pressurized, so that a large amount of the fluid can be compressed stored in the pressure tank. The fluid is supplied to the pressure tank via a filling line of the tank system, wherein the filling line has an outflow opening, which opens directly into the pressure tank. The pressure tank has a much larger volume compared to the filling line, with the result that the filled fluid flows into the pressure tank relatively uncontrolled.

It has been found that, depending on the geometry of the pressure tank, local accumulations of the filled, compressed fluid may occur, resulting in excessive heating of the housing wall of the pressure tank. These local collections are also referred to as "hot spots". The "hot spots" heat the pressure tank and its housing wall inhomogeneous, which can lead to a partial damage to the pressure tank. Furthermore, the service life of the pressure tank is reduced due to the thermal stresses associated with these localized heating.

A further disadvantage is that the filling quantity of the pressure tank is calculated via the temperature, which is why local heating falsifies the calculated result of the filling quantity. Due to this, incomplete filling or even overfilling of the pressure tank can occur. Waiting until the local warming has subsided delays the refueling process, which is also undesirable.

The object of the invention is to provide a tank system and a method for refueling, with which it is possible to fill the pressure tank evenly and to guarantee a long service life.

The object is achieved by a tank system, with a pressure tank for receiving a fluid and a filling line with an outflow opening, through which the fluid flows into the pressure tank, wherein a control element is provided in the filling line and / or at the outflow opening, the mass flow controls the fluid such that the fluid flows at least partially annular vortex in the pressure tank.

The basic idea of the invention is to control the mass flow of the inflowing fluid so that local heating of the compressed fluid in the pressure tank is avoided. For this purpose, vortex-shaped flows of the fluid are generated, which enable stable transport of the fluid through the pressure tank. A generated ring vortex is formed toroidal, wherein the fluid forming the ring vortex rotates poloidally around the torus volume, so that the ring vortex is stable and can move through the volume of the pressure tank. In this way, a local accumulation of the fluid in the pressure tank is avoided, since the ring vortices can pass through the pressure tank substantially uniformly until its end.

One aspect of the invention provides that a control is provided which activates the control in a pulsating manner, so that the fluid at least partially flows into the pressure tank in a ring-vortex-like manner. The pulsating activation ensures that several ring vertebrae can form at predefined intervals. Furthermore, a different pulsation can be set via a controller, so that the generation of ring vortices with different fluids is possible. Different fluids can have a different density, which can lead to different properties with respect to the generation of ring vortices. The controller can react to these differences so that the controlled control element can be used universally.

In particular, the control is a valve. Via the valve, the mass flow of the fluid in the filling line or at the outflow opening can be opened and closed in a pulsating manner, so that the fluid, when entering the pressure tank, generates a ring vortex, which is also called vortex. This principle corresponds in a figurative sense to the production of so-called smoking rings in smokers, where the mouth of the smoker corresponds to the valve.

According to a further aspect of the invention, the control element may be a section of the filling line or the outflow opening, which is oscillating and oscillates during fluid flow such that the fluid at least partially flows in the form of a vortex into the pressure tank. hereby an alternative embodiment is provided which automatically enables ring vortex generation of the fluid in the pressure tank since the pulsation of the control is provided due to the vibrating properties. This principle is similar to that of a paddling whistle, a reed or generally used for sound generation in wind instruments mechanisms. For example, in a trumpet, the lips would correspond to the vibrating section described above. Depending on the selected elasticity of the section can be adjusted to appropriate fluids.

The object of the invention is further achieved by a method for refueling a pressure tank of a tank system with a fluid, wherein the tank system comprises a filling line with an outflow opening and a control, wherein the control restricts the mass flow of the fluid for a first period, in particular interrupts, and for a second period of time, wherein the ratio of the two periods is such that the fluid at least partially flows like a ring vortex into the pressure tank. By temporarily restricting and releasing the mass flow, it is achieved that the inflowing fluid can form the ring vortices needed to allow refueling of the pressure tank without local accumulation. This avoids localized heating in the pressure tank, increasing the life of the pressure tank. In extreme cases, the mass flow can even be interrupted, for example in the case of a valve or a very elastic section.

According to a further aspect of the invention, it is provided that the control restricts or releases the mass flow of the fluid in a pulsating manner. This ensures that a plurality of sequentially successive ring vortices are generated in the pressure tank, so that a uniform refueling or filling of the pressure tank over a longer period of time is possible.

In particular, the fluid which flows at least partially in a vortex-like manner into the pressure tank generates toroidal ring vortices which have a torus axis which is essentially parallel to the longitudinal axis of the pressure tank. Due to this orientation, the ring vortices can propagate along the main orientation of the pressure tank so that they reach the end of the pressure tank that is repellent from the filling line. This is particularly important in the case of elongate pressure tanks in which the filling line is arranged on an end face of the pressure tank, because especially in the latter, strong heating is to be expected at the tank areas further away from the filling opening.

A further aspect of the invention provides that inflowing fluid flows through the generated torus of the ring vortex. This accelerates the filling or refueling of the pressure tank, since the fluid is not only vortex-shaped filled in the pressure tank, but in addition in a conventional manner. Due to the poloidial rotation of the ring vortices is also achieved that the inflowing fluid is guided by the ring vortices in the pressure tank. This additionally prevents local accumulation of the fluid in the pressure tank.

Further advantages and features of the invention will become apparent from the following description and the drawings, to which reference is made. In the drawings show:

1 a schematic representation of a tank system according to a first embodiment,

2 a schematic representation of a generated ring vortex, and

3 a schematic representation of a tank system according to a second embodiment.

In 1 is a tank system 10 according to a first embodiment, showing a pressure tank 12 as well as a filling line 14 having. The filling line 14 has an inlet opening 16 on, over which a fluid enters the filling line 14 can be introduced. That over the inlet opening 16 introduced fluid flows through the filling line 14 to an outflow opening 18 in the pressure tank 12 flows, so that the pressure tank 12 can be filled with the fluid.

Furthermore, in the embodiment shown, a control element 20 in the filling line 14 provided, which is designed as a valve and with a controller 22 is coupled.

The control 22 controls the control 20 such that the mass flow of the filled fluid as it flows through the control 20 restricts or even interrupts and releases again, whereby the inflowing fluid in the pressure tank 12 ring vortices 24 trains ( 2 ).

Such a ring vortex 24 is characterized by the fact that it has a torus shape, which is the ring vortex 24 forming fluid poloidal rotates around the torus volume of the ring vortex 24 train. Due to the poloidal rotation is the ring vortex 24 stable and can move further. Furthermore, the poloidal rotation creates a central opening 26 in the ring vertebra 24 through which inflowing fluid can flow.

The control 22 controls the control 20 also pulsating, so that the control 20 restricts or interrupts the mass flow of the fluid for a first period of time and releases it for a second time period, the two periods being selected such that a ring vortex 24 is produced. Due to the pulsating control, several ring vortices 24 formed in sequential repetition. This results in several successive ring vertebrae 24 as well as intermediate phases, in which the inflowing fluid through the openings 26 the previously generated ring vortices 24 can flow. The poloidal rotation of the fluid thereby represents a guide of the inflowing fluid, so that local accumulations are avoided.

The control 20 is in the filling line 14 arranged so that the generated ring vortices 24 with its torus axis T substantially parallel to the longitudinal axis L of the pressure tank 12 form and thus parallel to the longitudinal axis L through the pressure tank 12 run. This ensures that the pressure tank 12 is filled evenly and continuously with the fluid. Furthermore, it is ensured that the fluid is up to the filling line 14 opposite end spreads.

Due to the formation of the ring vertebrae 24 and the associated opening 26 , through which the inflowing fluid can flow, local accumulations of the fluid in the pressure tank 12 avoided, the pressure tank 12 Nevertheless, can be filled in a short time with the fluid.

An alternative embodiment is in 3 shown at the control 20 a section of the discharge opening 18 is, which is designed swinging.

In this case, the section is formed from an elastic material which vibrates in the fluid flow in such a way that the fluid is at least partially annularly vortex-shaped into the pressure tank 12 flows. Due to the vibrations of the section, a pulsation of the inflowing fluid can take place, as a result of which several ring vortices 24 form. This is done in an analogous manner to so-called smoke rings, a cushion pipe, a reed or generally in wind instruments, where the lips serve as a vibrating body.

The elastic portion may be so elastic that it interrupts the mass flow of the fluid in the meantime.

Claims (9)

Tank system ( 10 ) with a pressure tank ( 12 ) for receiving a fluid and a filling line ( 14 ) with an outflow opening ( 18 ), via which the fluid in the pressure tank ( 12 ) flows, with a control ( 20 ) in the filling line ( 14 ) and / or at the outflow opening ( 18 ) is provided, which controls the mass flow of the fluid such that the fluid at least partially annular vortex-shaped in the pressure tank ( 12 ) flows. Tank system ( 10 ) according to claim 1, characterized in that a controller ( 22 ) is provided which the control ( 20 ) pulsating, so that the fluid at least partially ring-shaped in the pressure tank ( 12 ) flows. Tank system ( 10 ) according to claim 1 or 2, characterized in that the control element ( 20 ) is a valve. Tank system ( 10 ) according to claim 1, characterized in that the control element ( 20 ) a section of the filling line ( 14 ), which is designed to oscillate and vibrates at fluid flow in such a way that the fluid is at least partially ring-shaped in the pressure tank ( 12 ) flows. Tank system ( 10 ) according to claim 1, characterized in that the control element ( 20 ) a section of the outflow opening ( 18 ), which is designed to oscillate and vibrates at fluid flow in such a way that the fluid is at least partially ring-shaped in the pressure tank ( 12 ) flows. Method for refueling a pressure tank ( 12 ) of a tank system ( 10 ) with a fluid, wherein the tank system ( 10 ) a filling line ( 14 ) with an outflow opening ( 18 ) as well as a control ( 20 ) comprises, with the following steps a) the control ( 20 ) restricts the mass flow of the fluid for a first period of time, in particular interrupts the mass flow, b) the control element (FIG. 20 ) releases the mass flow for a second time period, wherein the ratio of the two time periods is such that the fluid is at least partially ring-shaped in the pressure tank ( 12 ) flows. Method according to claim 6, characterized in that the control element ( 20 ) Pulsing the mass flow of the fluid limits or releases. A method according to claim 6 or 7, characterized in that the at least partially annular vortex-shaped in the pressure tank ( 12 ) flowing fluid toroidal ring vortices ( 24 ) having a Torusachse (T), which is substantially parallel to the longitudinal axis (L) of the pressure tank ( 12 ). A method according to claim 8, characterized in that inflowing fluid through the generated torus of the ring vortex ( 24 ) flows.

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