FR2975728A1 - PNEUMATIC-THERMAL HYBRID ENGINE - Google Patents

Abstract

The invention relates to a pneumatic-thermal hybrid engine comprising a cylinder head (1) and a cylinder (2) accommodating a piston thus defining a combustion chamber, means for storing pressurized gas, said storage means comprising a reservoir ( 8) connected to the combustion chamber through a conduit (9) passage, characterized in that the pressurized gas storage means further comprise a catalytic device for oxidation of hydrocarbons.

Description

Hybrid pneumatic-thermal engine

TECHNICAL FIELD OF THE INVENTION The present invention relates to a pneumatic-thermal hybrid engine, which recovers energy via an air compressor and stores this energy in the form of compressed air and where the compression is made using the cylinders.

Technological background The new engines must respond to a problem that is becoming more and more restrictive, in particular to regulatory limits on pollutant emissions and 002 emissions that are becoming increasingly severe.

These constraints push us to optimize the heat engine in its operation, and this, for all its phases of life.

One of the primary functions of the conventional heat engine is to provide torque to the wheels of the vehicle to move it forward. This torque is used primarily to overcome the various resistive forces of friction and to overcome the inertia of the vehicle. The energy provided in the form of torque by the engine is converted in part into kinetic energy.

On the deceleration and braking phases, the engine no longer provides torque to the wheels. The deceleration of the vehicle is naturally thanks to the various friction on the legrest and thanks to the braking systems for stronger braking. During these braking phases, the kinetic energy of the vehicle is transformed by the brakes in heat dissipated in the near environment.

There are systems for recovering kinetic energy during braking. These systems have the principle of recovering the kinetic energy of the vehicle on the deceleration phases and store this energy in a new form for reuse in other phases of life of the vehicle, during an acceleration for example. We can cite for example:

- KERS (or kinetic energy recovery system in English) which recovers the kinetic energy of the vehicle and stores this energy in the form of rotating kinetic energy, - the electrical hybridization which recovers the kinetic energy of the vehicle via an electric generator and which stores this energy in electrical form, - the pneumatic hybridization which recovers the kinetic energy of the vehicle via an air compressor and which stores this energy in the form of compressed air. The concept of pneumatic hybridization consists in using the resistive torque at the input of the powertrain for example on braking phases to compress air and store it in a tank.

This compression can be done using the engine cylinders provided that there is a valve dedicated to charging and discharging compressed air. One embodiment of this concept is known for example from document FR2865769. On the acceleration and low speed taxiing phases, the compressed air stored in the tank can be used to produce a positive torque. A principle representation of a pneumatic-thermal hybrid engine using the engine cylinders as compression means is proposed in FIG. 1.

The hybrid pneumatic-thermal engine shown diagrammatically in FIG. 1 comprises, in a conventional manner, an engine block comprising a cylinder head 1 and cylinders 2. Each cylinder comprises in the case represented here two air intake valves 3, an air valve exhaust 4, and a valve for charging and discharging compressed air. The intake and exhaust valves 4 cooperate with a dispensing device, for example by camshaft, not shown, which allows the opening and closing of these valves depending on the position of the piston in the cylinder 2. The compressed air charging and discharging valve cooperates with a clean dispensing device, not shown, which allows it to be opened and closed according to the needs of charge and discharge of pressurized gas, which needs do not depend essentially the position of the piston in the cylinder 2. The engine further comprises an intake air distributor 6 for the distribution of intake air into the cylinders 2 via the intake valves 3, a manifold exhaust system 7 for exhausting the exhaust gases from the cylinders 2 via the exhaust valve 4.

As further shown in FIG. 1, such a hybrid pneumatic-thermal engine also comprises means for storing pressurized gas. These pressurized gas storage means mainly comprise a pressurized gas storage tank 8 and a network 9 of pipes connecting the pressurized gas storage tank 8 to the cylinders 2 at their charge and discharge valve 5. gas under pressure.

For this concept where the compression is made using the cylinders 2, the maximum pressure in the tank directly depends on the compression ratio of the engine. For example, for a gasoline engine with a compression ratio of 11, the maximum pressure reached in the tank will be of the order of 20 bar. Beyond this pressure, the motor in pneumatic pump mode, that is energy recovery by air compression, will no longer be able to drive air to the compressed air tank.

At these pressure levels and for reservoir volumes that are compatible for a light vehicle-type automotive application, for example less than 50 liters, the storage capacity is of the order of magnitude of the kinetic energy available on a small braking system ( 30 km / h at 0 km / h). Since the amount of energy stored is low, this concept proposes to recover and use energy in very short times. This technology relies on the responsiveness and ability of the system to quickly switch from a heat engine mode to a pneumatic pump mode or from a pneumatic motor mode to a heat engine mode.

For gasoline engines operating in homogeneous mode at richness 1, there are two ways to inject the fuel: indirect injection in the intake ducts (or IIE for the acronym of Indirect Injection Petrol) and direct injection into the engine. combustion chamber (or IDE for the acronym of Direct Injection Petrol). For gasoline direct injection engines, the fuel injected during a cycle is consumed during this cycle and then exhausted as exhaust gas. For indirect fuel injection, the fuel is injected into the intake ducts. This fuel forms a liquid film on the walls. This liquid film is persistent and evolves at a much longer time scale than the engine cycle. Thus, we find during load transients, for example, a shift between the amount of fuel injected and the amount of fuel actually admitted into the cylinder. In addition, after an injection cutoff IIE, a significant amount of fuel continues to enter the cylinders as the liquid film continues in the intake ducts.

During a transition between the thermal engine mode and the pneumatic pump mode for an IIE engine, the liquid film will continue to diffuse fuel into the intake air. This fuel-laden air will potentially be stored in the compressed air tank and will create a risk of dangerous self-ignition for the vehicle, its passengers and its surrounding environment.

A first solution envisaged would be to wait a number of engine cycles without injecting fuel and leaving the butterfly open to dry the fuel contained in the liquid films. This fuel would be sent directly to the exhaust where it would be treated by the 3-way catalytic system of the exhaust line. However, with this solution, as long as the liquid film is not dried, we can not start the energy recovery, which penalizes the energy recovery time in pneumatic pump mode and therefore the amount of energy recovered. .

The aim of the invention is to propose a solution making it possible to overcome the problem of hydrocarbons that can be stored together with air in the compressed air reservoir of a pneumatic hybrid engine, while keeping the capacity to pass through. quickly from a heat engine mode to a pneumatic pump mode.

The invention thus relates to a hybrid pneumatic-thermal engine comprising a cylinder head and a cylinder accommodating a piston thus defining a combustion chamber, pressurized gas storage means, said storage means comprising a reservoir connected to the chamber of combustion by a conduit for the passage of gases under pressure, characterized in that the pressurized gas storage means further comprise a catalytic device for oxidizing the hydrocarbons. Thus, by disposing a catalytic device for oxidizing the hydrocarbons in the storage means, we are no longer forced to wait for the elimination by evaporation of the hydrocarbons prior to the implementation of a pneumatic pump mode, these hydrocarbons will be eliminated. directly in the storage means, this time saving allows us to quickly switch from a heat engine mode to a pneumatic pump mode and provides a recovered energy gain.

In a variant, the catalytic oxidation device for hydrocarbons comprises a catalytic oxidation unit disposed in a part of the duct outside the cylinder head.

In another variant, the catalytic device comprises a catalytic oxidation unit disposed in the tank. Advantageously, the catalytic oxidation unit is arranged at the inlet of the tank, in order to treat the entire stream of pressurized gas entering the tank.

In yet another variant, the conduit comprises a collector portion integrated with the cylinder head.

In a variant, the catalytic oxidation device for hydrocarbons comprises a catalytic oxidation unit arranged in the duct, as close as possible to the combustion chamber.

Preferably, the storage means comprise a heat insulation. The heat engine is preferably of the indirect fuel injection type, because with this type of engine liquid hydrocarbon films are present after an injection cutoff and a significant amount of fuel continues to enter the cylinders. 15

BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages will appear on reading the following description of a particular embodiment, not limiting of the invention, with reference to the figures in which:

- Figure 1 shows a block diagram of a hybrid pneumatic motor according to the prior art. FIG. 2 shows a schematic diagram of a first embodiment of a pneumatic hybrid engine according to the invention comprising a conduit for the passage of gases under pressure common to the various cylinders and a catalytic block for the oxidation of hydrocarbons in the duct for passing gases under pressure. FIG. 3 is a block diagram of a second embodiment of a pneumatic hybrid engine according to the invention, comprising a conduit for the passage of gases under pressure per cylinder and a catalytic block for the oxidation of hydrocarbons in each conduit. passage of gases under pressure. - Figure 4 shows a block diagram of a pneumatic hybrid engine according to the invention comprising a catalytic block of oxidation of hydrocarbons in the tank. 35

DETAILED DESCRIPTION FIG. 2 presents a first exemplary embodiment of a hybrid pneumatic-thermal engine according to the invention. In this first exemplary embodiment, the pneumatic-thermal hybrid engine comprises an engine block comprising a cylinder head 1 and at least one cylinder 2, in this case four in the example illustrated in FIG. 2. Each cylinder 2 accommodates a piston (no shown), each defining with the cylinder head 1 a combustion chamber. Each cylinder 2 comprises in the case represented here at least one air intake valve 3, in this case two in the example illustrated in FIG. 2, at least one exhaust valve 4, and a charge valve and discharge 5 of gas under pressure. The intake and exhaust valves 4 cooperate with a dispensing device, for example by camshaft, not shown which allows the opening and closing of these valves depending on the position of the piston in the cylinder 2. The charge and discharge valve 5 cooperates with a clean dispensing device, not shown, which allows its opening and closing according to the needs of charge and discharge of pressurized gas, needs which do not depend essentially on the position of the piston in the cylinder 2.

The distribution device of the charge and discharge valve 5 may be a mechanical device (pure mechanical, hydraulic, pneumatic), electric, magnetic or employ the combination of at least two aforementioned devices.

As further shown in FIG. 2, the pneumatic-thermal hybrid engine also comprises an intake air distributor 6 for the distribution of intake air into the cylinders 2 via the intake valves 3, a exhaust manifold 7 for exhausting the exhaust gases from the cylinders 2 via the exhaust valve 4.

The engine also comprises pressurized gas storage means. These pressurized gas storage means mainly comprise a tank 8 for storing pressurized gas and a conduit 9 for the passage of gas under pressure connecting the tank 8 for storing pressurized gas to the combustion chamber at their charge valve. and discharge 5.

The invention consists in placing a hydrocarbon treatment device in the storage means. The hydrocarbon treatment device is preferably a catalytic oxidation device. Indeed, such catalytic oxidation device converts carbon monoxide, CO and hydrocarbons, HC, carbon dioxide, CO2, and water under conditions of excess oxygen also called lean conditions. The catalytic oxidation device may consist of one or more catalytic oxidation units arranged in various locations for storage means.

In this first exemplary embodiment, and in accordance with the invention, the pressurized gas storage means comprise a catalytic oxidation unit 10 (which will also be referred to as "oxidation catalyst") of hydrocarbons. . In known manner, the oxidation catalyst 10 may, for example, be in the form of a ceramic block 100 comprising channels through which the gases to be treated circulate, the block serving as a substrate on which an active agent is deposited, such as platinum and / or palladium. The oxidation reaction needs a priming temperature generally between 120 ° C and 150 ° C to be initiated. In operation in pneumatic pump mode, this priming temperature is advantageously ensured by the heating of the gases due to their compression in the cylinders 2.

The conduit 9 for the passage of pressurized gases has a first portion 91 of pressurized gas connecting the combustion chambers and a second portion 92 external to the cylinder head 1. Advantageously, the first portion 91 collector is integrated in the cylinder head 1, by directly to the foundry, and opens out of it by a common outlet 11. The second part 92 connects the common outlet 11 to the tank 8.

In this first exemplary embodiment, the hydrocarbon oxidation catalyst 10 is placed in the second portion 92 of the external passage duct 9 to the cylinder head 1. This configuration is advantageous for reasons of compactness and ease of implantation in the cylinder. engine.

In the case of a hybrid pneumatic-thermal engine whose engine is of the indirect fuel injection engine type, it comprises fuel injection means (not shown) in the intake air, upstream of the engines. cylinders 2, advantageously in the air distributor 6.

When the hybrid pneumatic-thermal engine makes a transition from the thermal mode to the pneumatic pump mode, that is to say the recharge of the tank 8, the operation is as follows for a so-called four-stroke engine:

-The fuel injection is cut off. Immediately after the injection cutoff, however, fuel is present on the walls of the distributor 6 in the form of a liquid film. 30 - The air admitted into the cylinders 2 during their intake phase is compressed during the compression phase. This admitted air comprises hydrocarbons resulting from the evaporation of the liquid film. -The charge and discharge valve 5 opens and closes at appropriate times allowing the transfer of the intake air with the evaporated hydrocarbons from the combustion chamber of the cylinder 2 to the storage means and the pressurized holding of the gases transferred to the storage means, the oxidation catalyst 10 oxidizes hydrocarbons from the liquid films and present in the intake air and converted into flue gases. The oxidation of the hydrocarbons being moreover exothermic, it contributes to increase the pressure and the energy stored in the tank 8.

Figure 3 shows a second embodiment. This embodiment differs from the first embodiment in that each of the four cylinders 2 is connected to the reservoir 8 by a separate conduit 9a, 9b, 9c, 9d. Each of the conduits 9a, 9b, 9c, 9d comprises an oxidation catalyst 10a, 10b, 10c, 10d. Advantageously, the oxidation catalysts 10a, 10b, 10c, 10d are placed as close as possible to their combustion chamber, in order to benefit as much as possible from the temperature of the compressed gases and thus to reach their initiation temperature as quickly as possible. The oxidation catalysts 10a, 10b, 10c, 10d may be arranged in the cylinder head 1 or outside the cylinder head 1, but as far as possible closer to their combustion chamber.

Figure 4 shows a third embodiment. This embodiment differs from the first embodiment in that the oxidation catalyst 10 'is placed directly in the tank 8. Preferably the oxidation catalyst 10' is placed at the inlet 12 of the tank 8. This configuration has the advantage of limiting the congestion of the complete system. This configuration is not preferred if there are high heat losses upstream of the tank 8 because then the thermal conditions of catalyst priming may not be reached quickly. It may then be advantageous to provide heat insulating means for storing pressurized gas, that is to say the tank 8 and the conduit 9 for the passage of pressurized gas connecting the reservoir 8 for storing gas under pressure to the combustion chamber . In this case, the insulation of the tank also isolates the oxidation catalyst 10 '. Thermal insulation makes it possible, by limiting the heat losses, to reach the thermal conditions of initiation of the oxidation catalyst 10 'more quickly and to preserve them. Insulation of the pressurized gas storage means may also be provided for the other examples of embodiment mentioned above.

The invention is not limited to the embodiments described. The invention also includes the exemplary embodiments combining one or more hydrocarbon treatment devices from the previously described embodiments. For example, by combining the first example with the third example so as to place an oxidation catalyst in the duct 9 for passing the pressurized gases and another in the tank 8. Arranging a plurality of oxidation catalysts in the storage means has the effect of advantage of reducing the unit size of each of the oxidation catalysts which facilitates their implantation. Their shape can also be adapted to the space constraints around the engine.

The dimensioning (volume, developed area of gas / catalyst contact, concentration of precious metals, etc.) of the catalytic block or blocks present in the storage means may be based on the expected maximum flow rate of hydrocarbons to be treated. The dimensioning can also take into account the pressure drops in order to remain as permeable as possible.

The invention is particularly suitable for an indirect injection gasoline engine, but it may be suitable for other types of engines such as a diesel engine, gasoline direct injection, natural gas, from the moment when unburned hydrocarbons are present during a transition from the thermal mode to a passage in pneumatic pump mode.

The invention has the advantage of reducing the risks associated with the use of pneumatic hybridization, in particular on an indirect injection gasoline engine. It allows a rapid transition from thermal mode to pneumatic pump mode, which improves the energy recovery compared to other envisaged solutions such as waiting for the drying of the fuel contained in the liquid film to the walls in the case of a pump. The invention also has the advantage of upgrading these unburnt hydrocarbons which, without the invention, remain unused and are discharged into the exhaust line. With the invention, these hydrocarbons are converted into enthalpy by the oxidation catalyst. This increase in enthalpy will help to increase the pressure and the energy stored in the tank. This energy will be converted into mechanical energy during operation in pneumatic motor mode.

Claims (8)

REVENDICATIONS1. Hybrid pneumatic-thermal engine comprising a cylinder head (1) and a cylinder (2) accommodating a piston thus defining a combustion chamber, means for storing gas under pressure, said storage means comprising a reservoir (8) connected to the combustion chamber through a conduit (9) passage of pressurized gas, characterized in that the pressurized gas storage means further comprise a catalytic device for oxidation of hydrocarbons. 2. Engine according to claim 1, characterized in that the catalytic device for oxidation of hydrocarbons comprises a catalytic oxidation unit (10) disposed in a portion (92) of the duct (9) external to the cylinder head (1). 3. Engine according to claim 1 or claim 2, characterized in that the catalytic device comprises a catalytic oxidation unit (10 ') disposed in the reservoir (8). 4. Engine according to claim 3, characterized in that the catalytic oxidation block is disposed at the inlet (12) of the reservoir (8). 5. Motor according to any one of the preceding claims, characterized in that the duct (9) comprises a collecting portion (91) integrated with the cylinder head (1). 6. Engine according to any one of claims 1 to 4, characterized in that the catalytic device for oxidation of hydrocarbons comprises a catalytic block of oxidation (10a, 10b, 10c, 10d) disposed in the conduit (9a, 9b). , 9c, 9d), closer to the combustion chamber. 7. Motor according to any one of the preceding claims, characterized in that the storage means comprise a heat insulation. 8. Motor according to any one of the preceding claims, characterized in that the engine is of the indirect fuel injection type.