DE102012109679A1 - Vane machine and pressurized gas generating device - Google Patents

Abstract

A vane machine for a gaseous pressure medium comprises a circumferential vane (5) having rotating body (6) which is mounted in a gas space (4) of a stator (1) having at least one inlet bore (2) and one outlet bore (3) (5) divide the gas space (4) into cells (7). The wings (5) can be pivoted under the action of an associated return spring (12) against a stop (11) and against the spring action into a recess (15) in the rotating body (6).

Description

The invention relates to a for a gaseous pressure medium having a peripheral wing having rotary body which is mounted in a at least one inlet bore and an outlet bore having gas space of a stator, wherein the wings divide the gas space into cells.

From practice, a vane pump is known, which has a mounted in a cylinder bore of a stator rotary body, namely a rotor, in which at least one radially oriented guide for slidably mounting a rotary valve is inserted. The rotary valve is located with its free end face due to a spring action against the peripheral wall of the cylinder bore and divides the space between the stator and rotor in two chambers.

The invention has for its object to provide a vane cell machine of the type mentioned, which has a simple and robust construction and is to operate with different fuels.

According to the invention the object is solved by the features of the independent claims.

The subclaims represent advantageous embodiments of the invention.

A vane cell machine for a gaseous pressure medium comprises a rotary body having a circumferential wing, which is mounted in a gas space of a stator having at least one inlet bore and an outlet bore, wherein the wings divide the gas space into cells. The wings are under the action of an associated return spring against a stop and against the spring action in a recess of the rotary body pivotally.

The wings are supported and spring biased so that they force without effort to straighten themselves to form the cells so that they pivot against the stop, which also serves to support the wings when the pressure medium flows through the inlet bore into the gas space of the stator and set the rotary body in rotation. If the direction of rotation counteracts a substantial force, for example due to a change in geometry in the gas space and / or peripheral deposits, then the wings fold against the spring action in the direction of the rotary body until they engage in associated recesses whose geometry corresponds to the shape of the wings , And the effective outer diameter is substantially reduced to the outer diameter of the rotating body. Because of these possible pivotal movements of the wings, the risk of damage to the wings or formation of grooves in the peripheral wall of the gas space, in particular caused by contamination or combustion residues, which may be incurred in the generation of the compressed gas, is substantially reduced. The inlet opening can be connected to any unit for generating the compressed gas. The wings have a fluidically advantageous profile in order to achieve the highest possible efficiency.

Expediently, the rotary body has star-shaped bores in which the return springs cooperating with the wings, in particular tension springs, are inserted. Preferably, each wing has a cylinder-section-shaped foot part, which is pivotally mounted in a corresponding opening of the rotary body, wherein the foot part extends at a point tapering circumferentially to a head part. The cylinder-section-shaped foot part is guided in an axially aligned bearing bore, to which the recess adjoins, in which the wing rests in the folded state.

Preferably, an eccentric cam is attached to the foot, to which the return spring engages. The eccentric cam is located, for example, on an end face of the foot part outside the center of the cylinder portion to effect a pivotal movement of the wing.

For effective support of the wing in the performance of work, the stop in one of the pressure direction of the gas space in the tangential inflowing pressure medium opposite direction is arranged.

In order to increase efficiency, two opposing inlets and outlets are provided. Through the inlets, the pressure medium, for example a pressurized gas, can enter the gas space at the same time or with a time delay in order to set the rotating body in rotation, and escape through the outlets from the gas space.

Alternatively, the object is achieved according to the invention in that a vane cell machine for a gaseous pressure medium comprises a rotary body having circumferential wings, which is mounted in a gas space of a stator having at least one inlet bore and an outlet bore, wherein the wings divide the gas space into cells. The inlet is coupled to a combustor of a pressurized gas generating device, which is connected via a mixer to at least one oxidizer and / or fuel reservoir for generating the pressurized gas.

The vane machine or its associated pressurized gas generating device operates with solid or liquid oxidants to combust a fuel in the combustor that is mixed in the mixer as needed and reacted by ignition at the end of the mixer. When solid fuels and solid oxidizers are preferably used, this is relatively safe even in an accident with uncontrolled combustion, since the oxidizer without the fuel does not react and the fuel with oxygen from the ambient air is very difficult. The oxidizing agent and the fuel can therefore only react where they should also react, namely in the mixer. Of course, if the oxidizer is present in the air, it may be removed from the environment and a special reservoir is not required.

In an embodiment, an arc or an auxiliary gas consisting in particular of hydrogen and oxygen is provided in the combustion chamber for igniting the mixture consisting of the oxidizing agent and the fuel. The arc may be permanent or just for igniting the mixture. If the ignition of hydrogen with oxygen as auxiliary gas, the hydrogen can be produced in a separate electrolyzer.

According to a development of the combustion chamber is associated with a labyrinth-like filter, which essentially comprises metal plates. The expanding pressurized gas flows through the filter composed of metal plates, wherein the metal plates are arranged such that the compressed gas is passed through curves of the labyrinth and not only heat of the pressurized gas is discharged to the metal plates, but also solids are deposited, which are not in one anticipated gap between the filter and the mixer have settled.

Conveniently, the combustion chamber is closed on the outlet side with a pressure-controlled opening valve.

Preferably, the valve comprises at least two spring-loaded valve flaps, which are held in the closed state under magnetic action. It requires a certain pressure until the magnetically held in mutual contact valve flaps are opened. The compressed gas is then introduced under a relatively high pressure in the gas chamber.

In order to prevent an uncontrolled introduction of the oxidizing agent or the fuel into the mixing chamber, at least one check valve is provided between the mixing chamber and the at least one reservoir, which is preferably inserted into a connection line coupling the mixing chamber with the reservoir.

Advantageously, the oxidizing agent used in the pressurized gas generating device is sodium chlorate or sodium perchlorate and the fuel is wood flour, charcoal powder or the like. Sodium chlorate or sodium perchlorate as the oxidizing agent is relatively easy to prepare from common salt, water and direct current, incurring less waste in combustion using sodium perchlorate than in a reaction with sodium chlorate. Essentially any fuel, in particular of an organic material, can be used as the fuel, in particular in a comminuted form, for example ground, shredded or chopped.

Of course, the rotary body coupled to a transmission and the vane machine can be used as a drive motor in a motor vehicle.

Also, the pressurized gas generating device is usable as a separate unit not only for driving vane machines.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination but also in other combinations. The scope of the invention is defined only by the claims.

The invention will be explained in more detail below with reference to an embodiment with reference to the accompanying drawings. It shows:

1 a schematic partial sectional view of a vane machine according to the invention,

2 a schematic partial sectional view of the compressed gas generating device for the vane machine according to 1 and a

3 a partial sectional view of the compressed gas generating device for the vane machine after 2 in an alternative embodiment.

The vane machine includes a stator 1 with an inlet holes 2 and outlet holes 3 having gas space 4 , in which a gaseous pressure medium flows around a peripheral wing 5 having rotary body 6 to rotate, with the wings 5 the gas space 4 in cells 7 divide. Every wing 5 has a cylinder-section-shaped foot part 8th on, in a corresponding axially aligned opening 9 of the rotary body 6 is pivotally mounted. Starting from the foot part 8th runs the wing 5 Tapered tapering circumferentially to a headboard 10 , The wing 5 has a total of a straight line from the footboard 8th to the headboard 10 on its acted upon by the pressure medium side and on the opposite side of a curved course. Around the swiveling wing 5 to keep in an operative or working position in which the side facing away from the printing medium arcuate side of a on the rotary body 6 trained stop 11 is present, is in the rotary body 6 a feather 12 intended for each wing. The feathers 12 are in star-shaped running holes 13 of the rotary body 6 housed and engage an eccentric cam 14 in the area of the foot part 8th the associated wing 5 at. Due to a changing cross section of the gas space 4 swivel the wings 5 positively controlled in a rest position in which they are in corresponding recesses 16 of the rotary body 6 einliegen.

The inlet hole 2 of the stator 1 is with a combustion chamber 16 the compressed gas generating device 28 coupled, over a mixer 17 with at least one storage container, not shown, for a fuel, in particular wood flour or charcoal powder, and an oxidizing agent, in particular sodium chlorate or sodium perchlorate, is connected to produce a pressurized gas as the pressure medium in the vane machine for driving the rotating body 6 Use finds. Between the mixing chamber 17 and the reservoirs is in the connecting lines 18 for the oxidant and the fuel in each case a check valve 19 used, which prevents or allows the transport of the oxidizing agent or the fuel from the respective reservoir into the mixing chamber. To the mixing chamber 17 This is followed by an area in which the mixture comprising the oxidizing agent and the fuel is ignited by means of an electric arc 20 is ignited, so that the compressed gas is formed. Residues arising from this combustion are left in the open air 21 the combustion chamber 16 collected. The compressed gas flows through a labyrinthine metal plates 22 comprehensive filter 23 in which further combustion residues are separated to an outlet 24 the combustion chamber 16 and the associated inlet bore 2 of the stator 1 to reach. Of course, the outlet 24 the combustion chamber 16 with several inlet holes 2 be coupled, with valve controls can be used to enable or close changing flow channels for the compressed gas.

In an alternative embodiment is between the combustion chamber 16 and the outlet 24 a pressure-controlled opening valve 25 with valve flaps 26 present, on the one hand spring loaded and the other with magnetic parts 27 are equipped to achieve a tumbler, which opens only when a certain gas pressure.

LIST OF REFERENCE NUMBERS

1

 stator

2

 inlet bore

3

 outlet bore

4

 headspace

5

 wing

6

 rotating body

7

 cell

8th

 footboard

9

 opening

10

 headboard

11

 attack

12

 feather

13

 drilling

14

 Eccentric cam

15

 recess

16

 combustion chamber

17

 mixer

18

 connecting line

19

 check valve

20

 Electric arc

21

 free space

22

 metal plate

23

 filter

24

 outlet

25

 Valve

26

 valve flap

27

 magnetic part

28

 Compressed gas generating device

Claims (16)

Vane machine for a gaseous pressure medium with a peripheral wing ( 5 ) having rotary body ( 6 ) located in at least one inlet bore ( 2 ) and an outlet bore ( 3 ) having gas space ( 4 ) of a stator ( 1 ), the wings ( 5 ) the gas space ( 4 ) in cells ( 7 ), characterized in that the wings ( 5 ) under the action of an associated return spring ( 12 ) against a stop ( 11 ) and against the spring action in a recess ( 15 ) of the rotary body ( 6 ) are pivotable. Vane machine according to claim 1, characterized in that the rotary body ( 6 ) has star-shaped holes into which the return springs cooperating with the wings (in 12 ) are used. Vane machine according to claim 1 or 2, characterized in that each wing ( 5 ) a cylinder-section-shaped foot part ( 8th ), which in a corresponding opening ( 9 ) of the rotary body ( 6 ) is pivotally mounted, wherein the foot part ( 8th ) Tapered tapering circumferentially to a headboard ( 10 ). Vane machine according to one of claims 1 to 3, characterized in that on the foot part ( 8th ) an eccentric cam ( 14 ) is attached, on which the return spring ( 12 ) attacks. Vane machine according to claim 1, characterized in that the stop ( 11 ) in one of the pressure direction of the gas space ( 4 ) is arranged tangentially inflowing pressure medium opposite direction. Vane machine according to claim 1, characterized in that two mutually opposite inlets and outlets are provided. Vane machine according to claim 1, characterized in that the rotary body ( 6 ) is connectable to a transmission. Vane machine according to the preamble of claim 1, characterized in that the inlet bore ( 2 ) with a combustion chamber ( 16 ) a pressurized gas generating device ( 28 ) which is connected via a mixer ( 17 ) is connected to at least one storage container for an oxidant and / or a fuel to produce a compressed gas. Vane machine according to claim 8, characterized in that for the ignition of the mixture consisting of the oxidizing agent and the fuel, an arc ( 20 ) or a, in particular consisting of hydrogen and oxygen, auxiliary gas in the combustion chamber ( 16 ) is provided. Vane machine according to claim 8, characterized in that the combustion chamber ( 16 ) a labyrinthine filter ( 23 ), which is essentially metal plates ( 22 ). Vane machine according to one of claims 8 to 10, characterized in that the combustion chamber ( 16 ) on the outlet side with a pressure-controlled valve ( 25 ) is closed. Vane machine according to claim 11, characterized in that the valve ( 25 ) at least two spring-loaded valve flaps ( 26 ), which are held under magnetic action in the closed state. Vane machine according to claim 8, characterized in that between the mixing chamber ( 17 ) and the at least one reservoir at least one check valve ( 19 ), which is preferably in a mixing chamber ( 17 ) connecting to the reservoir connection line ( 18 ) is used. Vane machine according to claim 8, characterized in that the oxidizing agent is sodium chlorate or sodium perchlorate and the fuel is wood flour, charcoal powder or the like. Vane machine according to claim 1 or 8 for use as a drive motor in a motor vehicle. Compressed-gas generating device with a combustion chamber ( 16 ), which have a mixer ( 17 ) is connected to at least one oxidizer and / or fuel reservoir to produce a pressurized gas, wherein the oxidizer is sodium chlorate or sodium perchlorate and the fuel is wood flour or charcoal powder.

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