DE102005004592B4 - Storage and / or pressure increasing device for hydrogen - Google Patents

Abstract

Storage and / or pressure increasing device for hydrogen, which consists of at least one pressure-resistant vessel (12), which contains a hydrogen under hydrogen (8) or -abfuhr (9) de-absorbing or absorbent material, wherein the substance by heat removal ( 9) and hydrogen supply (23) is pressurized with hydrogen under a lower gas pressure and is caused by heat supply (8) for hydrogen release (24) under higher gas pressure, cyclically alternately at least a portion of the hydrogen absorbing substance is subjected to a higher temperature, wherein the cyclic hydrogen de-absorbent or absorbent material is present under normal conditions in a liquid state, characterized in that the pressure-resistant vessel (12) is divided into at least two sub-housings (17, 18) connected in series by a first and a second connecting line as a circuit and of which a first sub-housing (17) during operation bs the pressure increasing device always has the higher temperature and that at least the hydrogen de or absorbent material on the sub-housing (17, 18) and the connecting lines circumferentially occupying a position in the first (17) or in the second sub-housing (18) or in the connecting lines ,

Description

The invention relates to a storage and / or pressure increasing device for hydrogen according to the preamble of the first claim. In particular, the pressure increasing device is used in a fuel supply device of a motor vehicle which can be operated with hydrogen, the hydrogen extraction device of which comprises a container, in particular a cryotank, the pressure increasing device for gaseous hydrogen.

It is already known to store hydrogen, for example as a condensed gas in a container, in particular in a motor vehicle. For this liquefied storage special pressure-resistant containers are necessary, which should have a very good insulation due to the low storage temperatures. It is known to use to avoid heat input from the environment, double-walled, vacuum-insulated container.

Furthermore, hydrogen can also be stored in compressed gas storage tanks or in hydride storage tanks. However, if the storage takes place in the form of cryogenic, liquefied hydrogen, as condensed gas, an advantageously high range is achieved, for example, for vehicles, since in this state a high energy density is achieved, for example compared with storage of warm, compressed hydrogen gas.

The cryogenic, liquid hydrogen supply is stored in a boiling state in a thermally very well insulated, pressure-tight container. The energy density of the boiling hydrogen is by storage at a temperature slightly above the boiling point at ambient pressure, about 20 K, maximum. In the storage tanks technically converted today, the hydrogen is typically present at temperatures of about 21 K to about 27 K and the corresponding boiling pressures of about 2 bar (abs.) To about 5 bar (abs.).

In the lower part of the reservoir, the boiling hydrogen is present as a more dense liquid phase (also referred to below as LH2) and lying above it as a gaseous phase (also called GH2 in the following).

The direct promotion of hydrogen (hereinafter also referred to as H2) from the storage container into a supply line, towards a consumer, takes place in the simplest case via the static pressure gradient between the tank interior and the surroundings, or through targeted pressurization of the storage container. In principle, it is possible by the geometric design of the starting inside the tank flow line, primarily LH2 or only GH2 to promote.

Stored H2 is generally taken from the gas phase as GH2. If H2 is removed from the liquid phase as LH2, in a mobile application the following conditioners, e.g. Booster, or the mode of operation of a consumer nevertheless designed for the promotion of GH2. This is necessary because due to the possible deviations from the normal position of the mobile container, or dynamic, accelerated states, the inlet opening of a sampling line for LH2 can be systematically washed around even at high levels of gas phase temporarily. This is possible in the time course of the emptying of the mobile container, in particular long before the time at which the gas phase in an identical immobile container reaches the inlet opening of the LH2 removal line by pure removal. For this reason, in mobile applications H2 is mainly taken from the gas phase.

The reservoir is supplied during the H2 removal heat, which leads to the evaporation of LH2 in the container and thus to maintain a required for the promotion tank pressure that would otherwise decrease by the removal to the extent that a promotion would no longer be possible. This heat supply required for pressure maintenance via a separate heater, the z. B. can be designed as an electrically operated heating element or e.g. directly by supplying heated, gaseous H2, which is diverted targeted a heated flow stream and in the inner container (back) is passed.

The aim is, in an internal combustion engine, the fuel in the gaseous state at least partially by Hochdruckeinblasung in the or a compressed gas containing combustion chamber or combustion chambers supplied to the combustion, as this minimizes the risk of flashback and the power density and the efficiency of the engine can be increased can.

To implement such high pressure injection, the pressure in the stored fuel must ultimately be high enough. This high-pressure fuel is used for the direct injection into the already compressed gas or air-fuel mixture containing engine combustion chambers, which in time, however, only works as long as there is still a sufficiently large amount of fuel in the pressure tank. However, if a certain amount of fuel is removed from this, the pressure in this pressure tank inevitably drops to such an extent that direct fuel injection under high pressure is no longer possible.

Thereupon, the still contained and only present under reduced pressure fuel, at least to some extent, the internal combustion engine can be supplied under low pressure for combustion, in particular under external mixture formation. However, the amount of fuel provided in this method of the internal combustion engine is not sufficient for full-load operation, that is to say that at a certain degree of emptying of the pressure tank, only partial-load operation is possible with low load requirements.

The DE 103 01 159 A1 shows a remedy for this described problem and describes a sampling system in which the available amount of fuel as long as possible for Hochdruckeinblasung available. A motor vehicle is described with an internal combustion engine that can be operated with a fuel which is gaseous under normal conditions by passing part of the fuel, in particular for partial load operation of the internal combustion engine, under low pressure, in particular lower external mixture formation, into the combustion chamber of the internal combustion engine and another part of the fuel, in particular for full-load operation of the internal combustion engine, is supplied for combustion by high-pressure injection into the combustion chamber, which already contains compressed gas. In this case, the fuel pressure required for the high-pressure injection is ultimately provided by the fuel pressure prevailing in a pressure tank of the motor vehicle and is therefore only available up to a certain degree of emptying of the pressure tank. Therefore, at least two pressure tanks are installed in the motor vehicle, from which the internal combustion engine is alternatively or jointly supplied with fuel.

As a result, a larger part of the total filling quantity of the pressure tanks is available for the operation of the internal combustion engine, in comparison with a motor vehicle having a pressure tank. However, only one supply pressure can be achieved, which is less than or equal to the operating pressure of the pressure tank.

The patent application JP 62-150093 A describes a pressure booster for hydrogen, in which the pressure is generated with metal hydride compressors, which are filled with so-called classic metal hydride.

These classic metal hydrides have gravimetric storage densities typically below 2%.

The metal hydride is used in finely pulverized form and placed in rotatable pressure-resistant containers, with connections for H2 supply and removal in a heat exchanger housing with a high and a low temperature range.

The metal hydride is cyclically charged with gaseous hydrogen and discharged. The control of this process is carried out by cyclically supplying and removing heat by rotating the containers in the heat exchanger housing. The loading of the metal hydride with hydrogen is carried out by absorbing the hydrogen molecules with heat release, the discharge of the metal hydride by desorbing with heat absorption.

Due to this mode of operation, the term metal hydride compressor will be replaced by sorption-hydride compressor. This should include all types of cyclable hydrides, regardless of their other material properties.

Characteristic of the prior art is that at any time in the pressure-resistant metal hydride compressor housing, the rotatable pressure-resistant containers, exactly one pressure and temperature and that the metal hydride is powdered as a solid, which slows, inter alia, the heat transfer.

In the prior art cycle times are typically several minutes. High compression pressure ratios are determined by the serial i. achieved multi-stage arrangement. Continuous promotion, i. an approximately Förderdruckschwankungsfreie hydrogen delivery is achieved by parallel arrangement of individual sorption beds and their time-delayed operation.

These prior art hydrogen promoting sorption hydride compressors have both systematic drawbacks due to their basic cyclical operation and those currently precluding automotive applicability with increased delivery pressures and mass flow rates in the relevant range of several kilograms per hour.

The weight of a Sorptionshydridkompressors including all components required for its operation is according to the prior art at delivery pressures of up to 350 bar and delivery rates of up to 25 kg / h several hundred kg. The construction volume including all components is then several 10 liters.

The cycle times in the range of several minutes do not allow adaptation to rapidly changing operating point changes of an internal combustion engine.

During the cyclic operation, the sorption bed is heated in each case via the heat exchanger to the desorption temperature of the metal hydride or cooled to absorption temperature. Not only the amount of heat required for desorbing and absorbing the H2 in the metal hydride, but also the amount of heat needed to change the temperature of the pressure-resistant container structure. This heat flow component attributable to the structure of the sorption bed is not negligible and may be several tenths of the total heat flow at higher feed pressures which require a relatively stronger pressure-resistant structure. Therefore, it systematically reduces a possible reduction of the cycle time by, for example, improved geometric design of the sorbent bed.

Furthermore are still the EP 1 000 291 B1 and the EP 0 688 417 B1 to call the state of the art.

Object of the present invention is to show remedies for the disadvantages mentioned. In addition, supply pressures to the consumer can be achieved, which are well above the operating pressure level of the hydrogen storage. This object is solved by the features of the claim 1 , Advantageous embodiments and further developments are content of the dependent claims.

According to the invention, there is a storage and / or pressure increasing device for hydrogen at least from a pressure-resistant vessel containing a cyclically hydrogen de absorbing or absorbing under Wärmezu- or removal, in particular a hydride-forming metal alloy, wherein the substance by heat removal and hydrogen supply Hydrogen is applied under a lower gas pressure and is caused by the supply of heat to the release of hydrogen at a higher gas pressure, to which cyclically changing at least a portion of the hydrogen absorbing substance is subjected to a higher temperature. The invention is characterized in that the cyclic hydrogen de- or absorbent material is present under normal conditions in liquid state.

One in standard condition according to DIN 1343 Liquid substance to hydrogen absorb or absorb has the advantage that the cyclic heat transfer is not hindered by a porous structure and thus runs faster, which advantageously reduces the cycle time. For this purpose, of course, further advantageous if the hydrogen de or absorbent material remains liquid over the entire application temperature range. In an automotive application, this is especially a temperature range of at least twenty to forty degrees Celsius, which may be advantageously extended to substantially minus sixty to plus one hundred degrees Celsius due to extreme environmental conditions and the usual automotive waste heat temperature level. Such, in the standard state according to DIN 1343 and in the latter automotive application, liquid which de-absorbs or absorbs hydrogen may, among others, be, for example, aluminum borohydride, Al (BH 4) 3.

In a preferred embodiment of the invention, the storage and / or pressure increasing device consists of at least two pressure-resistant vessels, which are connected in series and / or parallel to increase the pressure of the gaseous hydrogen gradually and / or with a time delay. This has the advantage that the supply of gas to the consumer is reliably ensured. Furthermore, very high discharge pressures can be generated, which are significantly larger than the demand of the consumer.

In a further preferred embodiment of the invention, the pressure-resistant vessel of the memory and / or pressure increasing device is divided into at least two sub-housing, which are connected in series as a circuit by a first and a second connecting line and of which a first sub-housing during operation of the pressure increasing device always the has higher temperature. In this case, at least the hydrogen absorbing or absorbing substance via the sub-housing and the connecting lines circumferentially occupies a position in the first or in the second sub-housing or in the connecting lines.

This leads to a further reduction of the weight and the volume, as well as to a further improvement of the dynamics in an even greater extent. A further reduction of the heat quantities required for the cyclical operation and a continuous compression operation are achieved.

In a further advantageous embodiment of the invention, a pressure-increasing device is characterized in that it serves at least for the pro rata supply of a gas burning in a combustion chamber fuel consumer with hydrogen, in particular an internal combustion engine of a motor vehicle, the high pressure side of the pressure increasing means via a connecting device to the combustion chamber of the Consumers is connected and the low pressure side of the pressure increasing device with a hydrogen storage, in particular a cryotank is connected and wherein the pressure increasing at least in front of the combustion chamber, the pressure of the gaseous hydrogen at least temporarily increased so that the gaseous hydrogen below Utilization of a pressure gradient flows into the combustion chamber.

Such a pressure increasing device enables methods for internal mixture formation in the combustion chamber of an internal combustion engine, is very low wear and thus advantageously reduces maintenance costs. It can be reached very high life and very low failure rates, with a sudden collapse of the hydrogen supply can not occur because no abrupt error conditions are to be expected. A vibration-, vibration- and noise-free operation increases comfort and the operating point adaptation can also take place independently of the state of the consumer by varying the delivery pressure.

A particularly simple pressure-increasing device is characterized in that the connecting device consists of at least one pressure line which connects an output of the pressure-increasing device with an input of the combustion chamber. If the connecting device contains at least one compressed gas storage, this can be loaded as a buffer, for example, during the downtime of the consumer and not only during its operation.

An advantageous embodiment of the pressure increasing device is characterized in that the first portion of the vessel or the first sub-housing for heat supply waste heat of the consumer, in particular via the exhaust or its cooling device is supplied.

This has the advantage that no exergetic drive power is required for operation compared to mechanically acting compressors, compressors or pumps for the pressure booster. The operation can be carried out with anergetic waste heat and therefore have a favorable effect on the overall energy efficiency.

In a further preferred embodiment of the invention, a control device is provided for the pressure increasing device, which generates output data based on input data from the consumer and / or from the pressure gas storage and / or the pressure increasing device and / or the hydrogen storage, at least for operating point adaptation of the pressure booster and / or Consumer and / or the compressed gas storage and / or the pressure booster and / or the hydrogen storage can be used.

In the following the invention will be further explained by means of embodiments. 1 shows a schematic representation of a basic arrangement of a Sorptionshydridkompressors as pressure increasing means for operating an internal combustion engine. The 2 and 3 illustrate two different embodiments of Sorptionshydridkompressoren according to the invention.

In a not shown motor vehicle is according to 1 a hydrogen storage or generator 1, in particular a not shown cryotank for storing liquid hydrogen, installed. The hydrogen serves as fuel for supplying an internal combustion engine driving the motor vehicle 2 as a consumer. An unshown withdrawal device for gaseous hydrogen from the hydrogen storage 1 supplied via a sampling line 3 the internal combustion engine 2 with hydrogen.

For printing and conveying the gaseous hydrogen leads the sampling line 3 to a pressure increasing device, which is a Sorptionshydridkompressor 5 used. On the output side with its pressure side this is via a connecting device 4 to the combustion chamber of the internal combustion engine 2 connected. Alternatively or in addition to the internal combustion engine 2 , however, fuel cells not drawn could also be supplied with printed hydrogen.

The sorption hydride compressor 5 is also suitable for the supply and removal of heat flows suitable lines 6 . 7 connected. The to operate the Sorptionshydridkompressors 5 required operating heat flows can be generated or provided in any way, but here are for heat 8th Waste heat streams of the internal combustion engine 2 used from exhaust flow and / or engine cooling.

The heat supply 8th and -abfuhr 9 can also be done by any other hydraulic or pneumatic transport heat-carrying media, such as heat 8th About exhaust streams or heat dissipation 9 by fan cooling. Or by exploiting evaporation and / or condensation enthalpies (eg by means of a so-called heat pipe). Or by any form of radiation (eg laser, microwave, UV, IR, otherwise electromagnetic waves). Or by mechanical heat of reaction (eg frictional heat) or by transmission of pressure disturbances (eg by mechanical impulses, sound pressure). Or by electric heating or cooling (eg by Peltier element). Or in particular by using absorption or Desorptionswärmeströmen, which can arise when changing the loading or saturation state of a hydride with hydrogen. Or from any combination of different, functionally integrated procedures. For heat dissipation 9 in particular, the cooling system of the internal combustion engine 2 and / or the used to maintain pressure of a cryogenic tank supplied heat flow.

In the sorption hydride compressor 5 For example, the sorbent hydride is present in the liquid state throughout the range of application temperatures, from substantially minus sixty to plus one hundred degrees Celsius. This liquid hydride has no mechanical self-inhibiting property when expanded due to hydrogen absorption and therefore can not damage a pressure-resistant vessel. It can be easily promoted if necessary, in particular pumped.

The delivery pressure of the sorption hydride compressor 5 can be in the range of 2 bar abs. up to 350 bar abs. move. With intermediate storage of the delivered hydrogen in one or more between the sorption-hydride compressor 5 and the internal combustion engine 2 arranged compressed gas storage 10 can also delivery pressures up to 800 bar abs. be achieved. The compressed gas storage 10 can also during the downtime of the internal combustion engine 2 be loaded by the Sorptionshydridkompressor 5, for example, also for storing amounts of hydrogen lost from the hydrogen storage 1 come, in particular so-called boil-off gases. This is the compressed gas storage 10 to the connection device 4 , for example via a pressure line 11 , connected. In the pressure line 11 may be installed a not shown control device. The control device can, for example, at least one between compressed gas storage 10 and connection device 4 switched pressure control valve consist.

By the in the compressed gas storage 10 stored hydrogen gas can be the internal combustion engine 2 operated over periods of time, for example, a Sorptionshydridkompressor 5 needed to reach the operating pressure, or which requires a catalytic converter to reach its operating temperature. Or via which a hydrogen storage system is filled, which stores hydrogen as resource reserve ("reserve canister"). Furthermore, over periods of time in which liquid or gaseous media are heated in such a way that the period up to the parts of the internal combustion engine 2 or parts of an air conditioning device reach a favorable operating temperature, shortened.

In the sorption hydride compressor 5 It is possible to use both sorption hydrides according to the prior art and those which can be operated beyond this at elevated temperature levels, in particular also during the desorption phase. This is especially true at such temperature levels when supplying the internal combustion engine 2 by using this typical waste heat streams eg from the exhaust or cooling water are possible. Thus, compared to the prior art, significantly increased gravimetric storage densities are possible, as a result of which significantly lower weights and construction volumes of a sorption-hydride compressor are possible 5 can be achieved at a given flow rate.

The construction of the sorption hydride compressor 5 can be different. All combinations of a sorption bed in the pressure-resistant vessels are conceivable which result from single-stage or multistage interconnection and / or single-row or multi-row interconnection of pressure-resistant vessels. Also, constructions and operations that serve, for example, the operating point adaptation and / or the reduction of cyclically required amounts of heat for cycling a contained hydride.

The 2 shows a Sorptionshydridkompressor 5 with a sorption bed of the same pressure and two different temperatures.

The printable container 12 of the sorbent bed 13 is in a hot part 14 and in a cold part 15 subdivided. The liquid sorption hydride 16 is inside the vessel 12 between the hot part 14 and the cold part 15 movably arranged. For cycling the sorption hydride 16 this flows between the hot part 14 that is the sorption hydride 16 heated to desorption temperature TDesorb and holds, and the cold part 15 that is the sorption hydride 16 on absorption temperature TAbsorb cools and stops, each back and forth. At any given time lies in the whole vessel 12 only a pressure p before, which moves cyclically between desorption and adsorption pressure. At any time lie in the vessel 12 but always two temperatures before. Therefore, to cyclically heat and cool the sorption hydride 16 essentially only the heat flows required for the temperature adjustment of the sorption 16 yourself are required. For the adaptation of the temperature of the housing structure systematically no heat flows are needed.

The movement of the sorption hydride 16 , by transport or flowing, between the hot and the cold part, can be carried out in various ways, for example by gravity, for example by cyclic turning or everting the Sorptionshydridkompressors 5 ,

Or by means of electromagnetic or other field forces, directly or through one or many moving intermediate bodies on the sorption 16 act. Furthermore, by means of pneumatic or hydraulic transmission of kinetic energy, which passes directly or via one or many intermediate bodies or via other media or by means of pressure disturbances or pulse transmissions, for example by mechanical shock waves or sound.

Furthermore, any type of mixing or circulation or rearrangement of the sorption 16 take place either during a phase of the sorption cycle in which the sorption 16 in the hot part 14 or in the cold part 15 of the sorption hydride compressor 5 or in which the sorption hydride 16 between hot part 14 and cold part 15 is relocated. In this case, the mixing, as already described above, be carried out in many ways.

Inside the sorption hydride compressor 5 can in the transition region between hot 14 and cold part 15 or at any position be arranged any kind of not subscribed built-in part or mold element, the thermal insulation or the above-mentioned mixing of the sorption 16 serves.

sorption 13 of this type may also be serial and parallel in their printable vessels to a sorption-hydride compressor 5 be interconnected. In this case, the movement of the sorption can 16 in the sorption bed 13 can also be caused by an effect on several or all sorption beds at the same time 13 a sorption hydride compressor 5 acts. For example, a sorption hydride compressor assembly in which individual sorbent beds 13 are aligned with their printable containers against each other arbitrarily position twisted, rotated as a whole cyclically or slipped.

3 shows the basic design of a Sorptionshydridkompressors 5 with a sorption bed 13 in which two temperatures and two pressures prevail.

The printable container 12 of the sorbent bed 13 is in two sub-housings 17 . 18 subdivided in which during operation always with respect to temperature and pressure Desorpstionsbedingungen (Heissteil 14 ) or the absorption conditions (cold part 15 ) for the sorption hydride 16 present and over two pipelines 19 . 20 are connected, in each case a control valve or a throttle 21 and a pressure-increasing conveyor 22 located. The pipelines 19 . 20 with the arranged facilities 21 . 22 are to promote the sorption used 16 suitable designed. The liquid sorption hydride 16 is always in the Heissteil at all times 14 , as well as in the cold section 15 , and to a small extent in the mentioned pipelines 19 . 20 ,

In the hot part 14 becomes the sorption hydride contained therein 16 continuously discharged from the hydrogen (desorption) and the discharged hydrogen discharged under desorption pressure pdesorb to the outside. In the cold part 15 becomes the sorption hydride contained therein 16 continuously charged with hydrogen (absorption) and the absorbed hydrogen fed with absorption pressure pAbsorb from the outside.

So that these two simultaneous processes do not come to a standstill, the liquid sorption is 16 between hot part 14 and cold part 15 constantly over the pipelines 19 . 20 from the conveyor 22 between both sub-housings 17 . 18 circulated. This is where the H2-reduced sorption hydride passes 16 from the hot part 14 preferably by using the pressure gradient to the cold part 15 in the same. From the cold part 15 passes the H2-loaded sorption hydride 16 by means of the conveyor 22 , For example, a pump, which raises it to desorption pressure level pDesorb, back into the hot section 14 , Different modes of operation are possible. The sorption hydride 16 can be circulated in a constant or quasi-constant mass flow, but this can also be batchwise or depending on any state variables or input variables in Sorptionshydridkompressor 5 or in the supplied H2 consumer or in the motor vehicle.

hot part 14 and cold part 15 may, of course, relative to each other and relative to the environment have any spatial arrangements and orientations that allow the supply and removal of hydrogen and the circulation of the sorption.

At any time during operation are in the two sub-housings 17 . 18 of the sorption hydride compressor 5 locally approximately constant overall both pressures associated with the sorption cycle and the corresponding temperatures. Therefore, also here for cyclic heating and cooling of Sorptiopnshydrids 16 essentially only the heat flows required for the temperature adjustment of the sorption 16 yourself are required. For the adaptation of the temperature of the housing structure systematically no heat flows are needed.

The movement and mixing of the sorption hydride 16 within a pressure-resistant vessel or the pressure increase between the hot part 14 and cold part 15 can be done in a variety of ways. For example, by gravity, for example by cyclically turning or siphoning the Sorptionshydridkompressors 5 , Or by means of electromagnetic or other field forces, directly or through one or many moving intermediate bodies on the sorption 16 act. Furthermore, by means of pneumatic or hydraulic transmission of kinetic energy, which passes directly or via one or many intermediate bodies or other media or by means of pressure disturbances or pulse transmissions, for example by mechanical shock waves or sound.

sorption 13 of this type, or the associated printable vessels, can also be serial and parallel to a sorption hydride compressor 5 be interconnected. In this case, the movement of the sorption can 16 in the sorption bed 13 can also be caused by an effect on several or all sorption beds at the same time 13 a sorption hydride compressor 5 acts. For example, a sorption hydride compressor assembly in which individual sorbent beds 13 are aligned against each other arbitrarily position rotated, are rotated as a whole cyclically.

Claims (8)

Storage and / or pressure increasing device for hydrogen, which consists of at least one pressure-resistant vessel (12), which contains a hydrogen under hydrogen (8) or -abfuhr (9) de-absorbing or absorbent material, wherein the substance by heat removal ( 9) and hydrogen supply (23) is acted upon under lower gas pressure with hydrogen and by heat supply (8) for hydrogen release (24) under higher gas pressure, cyclically changing at least a portion of the hydrogen absorbing material is subjected to a higher temperature, said cyclic hydrogen de-absorbent or absorbent material is present under normal conditions in a liquid state, characterized in that the pressure-resistant vessel (12) is divided into at least two sub-housings (17, 18) connected in series by a first and a second connecting line as a circuit and of which a first sub-housing (17) during the Betri ebs the pressure increasing device always has the higher temperature and that at least the hydrogen de or absorbent material via the sub-housing (17, 18) and the connecting lines circumferentially occupies a position in the first (17) or in the second sub-housing (18) or in the connecting lines , Storage and / or pressure increasing device for hydrogen after Claim 1 , characterized in that the hydrogen absorbing or absorbing material is a hydride-forming metal alloy. Storage and / or pressure increasing device for hydrogen according to one of Claims 1 or 2 , characterized in that this (r) of at least two pressure-resistant vessels (12), which are connected in series and / or in parallel together to increase the pressure of the gaseous hydrogen gradually and / or with a time delay. Pressure increasing device according to one of Claims 1 to 3 , Characterized in that said burning at least for the proportional supply of a gaseous in a combustion chamber fuel consumer with hydrogen, in particular an internal combustion engine (2) of a motor vehicle, is used, wherein the high pressure side of the pressure increasing device via a connection means (4) is connected to the combustion chamber of the consumer and the low pressure side of the pressure increasing device with a hydrogen storage (1), in particular a cryotank is connected, and wherein the pressure increasing means at least in front of the combustion chamber, the pressure of the gaseous hydrogen at least temporarily increased so that the gaseous hydrogen flows into the combustion chamber by utilizing a pressure gradient. Pressure Booster after Claim 4 , characterized in that the connecting device (4) consists of at least one pressure line which connects an output of the pressure increasing device with an input of the combustion chamber. Pressure increasing device according to one of Claims 4 or 5 , characterized in that the connecting device (4) contains at least one compressed gas reservoir (10). Pressure increasing device according to one of Claims 1 to 6 , characterized in that the first portion (14) of the vessel (12) or the first part housing (17) for heat supply (8) waste heat of the consumer, in particular via the exhaust or its cooling device is supplied. Pressure increasing device according to one of Claims 1 to 7 , characterized in that a control device is provided which generates output data based on input data from the consumer and / or the compressed gas reservoir (10) and / or the pressure increasing device and / or the hydrogen storage (1), at least for operating point adaptation of the consumer and / or the compressed gas reservoir (10) and / or the pressure booster and / or the hydrogen storage (1) are used.

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