DE10212551B4 - Device for conveying fluids driven by an internal combustion engine with a free-floating stepped piston - Google Patents

Abstract

A fluid delivery apparatus comprising an internal combustion engine having a symmetrical free-floating stage piston (14) having two piston stages (16, 18) movably disposed in each combustion chamber (28, 30) provided with exhaust ports (46, 48) , which in each case by a channel (38, 40) with a Vorverdichterraum (34, 36) is arranged in the piston stages (16, 18) axially inwardly, between which there is a further chamber (32), in which an additional , on a piston center piece (20) arranged piston stage (22) of the stepped piston (14) is provided, wherein the additional piston stage (22) divides the further chamber (32) into two separate Vorverdichterräume (34, 36), whose to the combustion chambers (28 , 30) running channels (38, 40) open into the combustion chamber end faces, characterized in that the stepped piston (14) has a continuous axial recess (64) which at one end of the stepped piston (14) coaxially a fixed the tubular element (72) surrounds, along which and sealed relative to the stepped piston (14, 18) is reciprocally movable, that the axial recess (64) on the tube side in an outer portion (66) merges with respect to subsequent inner Section (68) has a larger cross-section, and in that in the outer portion (66) or in the transition between the inner portion (68) and the outer portion of the stepped piston (14) a valve (78) is arranged.

Description

The invention relates to a device for conveying fluids, comprising an internal combustion engine with a symmetrical, free-floating stepped piston, which has two piston stages, which are each movably arranged in a combustion chamber provided with exhaust ports, which is in each case connected by a channel to a supercharger chamber, are arranged axially inwardly at the piston stages, between which there is a further chamber in which an additional, arranged on a piston center piece piston stage of the stepped piston is provided, wherein the additional piston stage divides the further chamber into two separate Vorverdichterräume their running to the combustion chambers channels open into the combustion chamber front sides.

With a corresponding for example the CH 640 600 To be taken internal combustion engine, which is also known as Stelzer engine pumps can be driven to deliver water. Since direct delivery of water does not occur, undesirable energy losses occur.

Of the DE 199 48 442 A1 is to be taken from a Plungerpumpemaggregat having two coaxially opposed pump units, between which a designed as a two-stroke internal combustion engine free-piston engine is arranged.

In a two-stroke internal combustion engine after the DE 33 27 334 A1 whose free-flowing stepped piston is connected to the working piston of a hydraulic pump in order to pump hydraulic fluid from a low-pressure line to a high-pressure line during the movement of the stepped piston.

Of the DE 16 53 553 C3 is an induction pump with a one-sided with a suction nozzle and on the other side connected to a discharge nozzle axially flowed casing tube can be seen in which a tubular-shaped and provided with at least one valve axially flowed hollow piston is movable back and forth.

An electromagnetically driven piston pump after the DE 1 290 820 has a stator as exciter part and a piston designed as a hollow cylinder.

The present invention is based on the problem, a device of the type mentioned in such a way that with structurally simple measures energiegünstig fluids of almost any consistency can be conveyed.

To solve the problem, the invention provides that the stepped piston has a continuous axially extending recess and that the recess coaxially surrounds at one end of the stepped piston a fixed tubular element, along which and sealed against this the stepped piston is reciprocable that the axial Recess tube side changes into an outer portion which has a larger cross section with respect to subsequent inner portion and in that in the outer portion or in the transition between the inner portion and the outer portion of the stepped piston, a valve is arranged.

According to the invention, by means of the reciprocating, stepped piston, a negative pressure is generated in the immediate vicinity of the stationary tube element, by means of which the fluid to be delivered is sucked through the stepped piston. At the same time, however, the fluid is forced through the tubular element, so that fluids can be conveyed optimally in terms of energy with a structurally simple construction of the device.

In particular, it is provided that the axial recess on the tube element side merges into an outer section, which has a larger cross-section with respect to the subsequent inner section. Regardless of this, the axial recess is rotationally symmetrical to the longitudinal axis of the stepped piston.

In the outer portion or the transition between the inner and the outer portion, a valve is arranged, which shuts off in the direction of the tubular element movement of the stepped piston, the outer portion relative to the inner portion of the tubular element. This additionally ensures that when conveying the fluid through the tubular element in the outer portion existing fluid can not be displaced from this in the direction of the inner portion. However, it should be noted that at high frequency of the stepped piston a relevant valve does not appear necessary in principle.

The valve can z. B. be a flutter valve or an electrovalve or solenoid valve. In the case of a flutter valve, this may have a valve seat penetrated by the longitudinal axis of the stepped piston. The valve seat itself should have a conical geometry as a sealing surface for membrane-like designed valve element of the flutter valve.

The negative pressure required for the suction of the fluid is generated not only by the increase in volume of the outer portion when moving back the stepped piston, but at the same time that regardless of the movement of the piston, the fluid present in the tubular element continues towards its outlet opening moves, which in turn takes place on the piston side extending volume increase of the merging into the outer portion of the stepped piston end side portion of the tubular element and thus a negative pressure increase is effected.

In order to achieve optimum efficiencies as a function of the fluids to be delivered, it is provided that the cross-section of the tubular element is designed in dependence on the viscosity of the fluid to be delivered such that a low cross section is selected for low viscosity and a small cross section for high viscosity. Here, oil or oily fluid is conveyable as the low viscosity fluid and gas as the high viscosity fluid. In particular, however, it is provided that water is required as the fluid.

For more details, advantages and features of the invention will become apparent not only from the claims, the features to be taken these features - alone and / or in combination - but also from the following description of the drawing to be taken preferred embodiments.

Show it:

1 in schematic representation and in the section of an internal combustion engine with free-floating step piston with fixed pipe and

2 a schematic representation of a portion of the stepped piston according to 1 with fixed pipe.

In 1 is shown in the neckline according to the invention further developed so-called Stelzer engine for conveying fluids. The engine or the two-stroke internal combustion engine has a cylinder 10 with cylinder wall 12 on, in the free-floating a stepped piston 14 is swinging back and forth. The stepped piston 14 has in the exemplary embodiment piston stages 16 . 18 , a piston center piece 20 , another piston stage 22 as well as two piston sections 24 . 26 on. The outer piston stages 16 . 18 have the same diameter, whereas the piston center piece 20 has a significant smaller diameter. The diameter of the additional piston stage 22 , in the middle between the piston steps 16 . 18 on the piston middle piece 20 runs can be equal to or greater than the diameter of the piston stages 16 . 18 be. The two piston sections 24 . 26 have the same diameter, which is slightly larger than the diameter of the piston center piece 20 are. Furthermore, the piston sections 24 . 26 annular end faces 21 on.

The cylinder 10 is with two combustion chambers 28 . 30 equipped, each axially inside the piston stages 16 . 18 are arranged. Another chamber 32 is located between the two combustion chambers 28 . 30 , In the other chamber 32 is the additional piston level 22 movably arranged. The with the piston middle piece 20 a unit forming additional piston stage 22 divide the other chamber 32 in two booster rooms 34 . 36 that ever have a channel 38 . 40 with one of the combustion chambers 28 . 30 are connected. The further chamber 32 is in the middle between the two combustion chambers 28 . 30 arranged and of these in each case by a wall 42 . 44 separated. In the walls 42 . 44 each run the channels 38 . 40 , which are formed hollow cylindrical. The unspecified cylinder walls of the channels 38 . 40 concentrically surround each a portion of the piston center piece 20 , Between the cylindrical outer wall of the piston center piece 20 and the cylinder wall of the respective channel 38 . 40 There is a free space in which a gaseous medium from the corresponding precompression space 34 respectively. 36 to the adjacent combustion chamber 28 respectively. 30 can flow in the in one stroke of the engine by combustion of a fuel-air mixture, the piston stage 16 respectively. 18 is driven, wherein heat energy is converted into mechanical work.

The combustion chambers 28 . 30 are each with exhaust ports passing into exhaust ports 46 . 48 provided, which is before the bottom dead center of the respective piston stage 16 . 18 are located.

Running in the schematic representation of the exhaust ducts perpendicular to the longitudinal axis of the stepped piston 14 , so another geometry is also possible.

The additional chamber 32 contains a suction port 50 in the cylinder wall 12 in the middle between the two end walls of the chamber 32 runs. The diameters of the sections 24 . 26 are at the cross sections of the channels 38 . 40 customized. The diameters are chosen so that the sections 24 . 26 the channels 38 . 40 Close as close as possible, but an axial movement of the sections 24 . 26 in the channels 38 . 40 enable. The sections 24 . 26 each jump from the unspecified end faces of the piston stages 16 . 18 in front. The length of the sections 24 . 26 depends on the bottom dead center of the piston stage 16 . 18 from. In the respective dead center of the piston stage 16 respectively. 18 gives the respective section 24 . 26 the assigned channel 38 respectively. 40 for the supply of the medium to the combustion chamber 28 . 30 free. At the upstroke of the piston stage 16 respectively. 18 seals the appropriate section 24 . 26 after closing the outlet slots 46 . 48 the respective channel 38 respectively. 40 at.

Between the faces of the combustion chambers 28 . 30 and the cylindrical outer walls of the channels 38 . 40 are recesses 60 present, which may have triangular cross-sectional geometries. The recesses 60 are arranged in pairs opposite one another and form chambers that oppose the combustion chambers 28 . 30 zoom in. In the recess 60 can in a configuration of the internal combustion engine as a gasoline engine, the ends of spark plugs 62 protrude.

According to the invention, the stepped piston 14 an axially extending recess 64 on, at one end - in the piston stage 18 - an outer section 66 and an inner section 68 includes, which have different diameter from each other. Here is the outer section 66 larger in diameter than the inner section 68 , The inner section 68 then goes into a middle section 70 over, extending along the piston center piece, the additional piston stage 22 and the piston sections 24 . 26 extends to the piston stage 16 to pass through and pass into a connection for to be sucked fluid, which of the further piston stage 16 emanates. The connection itself can be the piston stage 16 be, which protrudes into a fluid to be pumped.

The piston stage 18 surrounds with its outer section 66 a fixed pipe 72 and is sealed against this (seals 74 . 76 ).

Furthermore, it is located in the transition area between the inner section 68 and outer section 66 a valve, preferably in the form of a flutter valve 78 , one of longitudinal axis 80 of the stepped piston 14 enforced valve seat 82 has in the form of a double cone. On the pipe 72 facing conical surface 84 of the valve seat 82 can then one or more the valve 78 opening or closing valve elements 86 invest. Locked is the valve 78 when the piston 10 in the direction of the pipe 72 (Arrow 88 ) is moved. In opposite direction of movement (arrow 90 ) is the valve 78 open.

Fluid is delivered as follows:
We the piston 14 in the direction of the arrow 88 moves, it reduces the volume of the outer section 66 , During the return movement (arrow 90 ) increases the volume with the result that a negative pressure is created, so that when the valve is open 78 Fluid through the axial recess 70 in the direction of the stationary pipe 76 can flow. In this case, the effective volume generating the negative pressure already in the tube 72 of the fluid increased by that, when the stepped piston 14 in the direction of the arrow 90 is moved, not just the volume of the outer section 66 but also the free volume in the pipe 72 is enlarged, since that in the pipe 72 existing fluid in the direction of the outlet opening of the tube 72 flows. The resulting increase in volume (area 88 in the pipe 72 ) causes a vacuum increase with the result that accelerated fluid can be sucked.

To close the valve 78 to accelerate, goes to its closure element 86 from a circumferential undercut 92 of the outer section 66 the piston stage 18 out. The geometry of the undercut 92 is v-shaped or gutter-shaped. This is caused when the piston in the direction of the arrow 88 vibrates, fluid that is in the outer section 66 located between the closure element 86 and inner surface of the outer portion 66 pressed, causing the closure element 86 accelerates to the valve seat 82 or the area 84 can be applied.

The delivery section of the fixed pipe 72 depends on the viscosity of the fluid to be delivered. If a low viscosity fluid such. As oil or oily water are promoted, is the cross section of the tube 72 relatively large. If, on the other hand, a gaseous fluid is conveyed, the cross section is relatively small.

Typical vibration frequencies of the stepped piston 14 are readily in the range of 1000 and 20,000 vibrations per minute.

Claims (12)

Device for conveying fluids, comprising an internal combustion engine with a symmetrical, free-floating stepped piston ( 14 ), the two piston stages ( 16 . 18 ), which are each movable in one with outlet slots ( 46 . 48 ) provided combustion chamber ( 28 . 30 ), each through a channel ( 38 . 40 ) with a Vorverdichterraum ( 34 . 36 ) is connected to the piston stages ( 16 . 18 ) are arranged axially inwardly, between which a further chamber ( 32 ), in which an additional, on a piston centerpiece ( 20 ) arranged piston stage ( 22 ) of the stepped piston ( 14 ), wherein the additional piston stage ( 22 ) the further chamber ( 32 ) into two separate pre-compression chambers ( 34 . 36 ) to which the combustion chambers ( 28 . 30 ) running channels ( 38 . 40 ) open into the combustion chamber end faces, characterized in that the stepped piston ( 14 ) a continuous axial recess ( 64 ), which at one end of the stepped piston ( 14 ) coaxially a fixed tubular element ( 72 ), along which and sealed against this the stepped piston ( 14 . 18 ) is reciprocable that the axial recess ( 64 ) tube side in an outer portion ( 66 ), which, in relation to the subsequent inner section ( 68 ) has a larger cross-section, and that in the outer portion ( 66 ) or in the transition between the inner section ( 68 ) and the outer portion of the stepped piston ( 14 ) a valve ( 78 ) is arranged. Device according to claim 1, characterized in that the axial recess ( 64 ) rotationally symmetrical to the longitudinal axis ( 80 ) of the stepped piston ( 14 ) runs. Device according to at least one of the preceding claims, characterized in that the axial recess ( 64 ) ( 70 . 68 . 66 ) is trained. Device according to at least one of the preceding claims, characterized in that in the direction of the tubular element ( 72 ) Successful movement of the stepped piston ( 14 ) the outer section ( 66 ) opposite the inner section ( 68 ) is locked. Device according to claim 1, characterized in that the valve ( 78 ) is a flutter valve, an electric or a solenoid valve. Apparatus according to claim 5, characterized in that the flutter valve ( 78 ) one from the longitudinal axis ( 80 ) of the stepped piston ( 14 ) penetrated the valve seat ( 82 ) having. Device according to claim 6, characterized in that the valve seat ( 82 ) a cone geometry as a sealing surface ( 84 ) for at least one membrane-like closure element ( 86 ) having. Apparatus according to claim 7, characterized in that the closure element ( 86 ) of a section V-shaped undercut of the outer portion ( 66 ) of the stepped piston ( 14 ). Apparatus according to claim 1, characterized in that the cross section of the tubular element ( 72 ) is formed in dependence on viscosity of the fluid to be delivered in such a way that at low viscosity, a larger cross-section and at high viscosity, a smaller cross-section is selected. Apparatus according to claim 9, characterized in that oil or oil-containing fluid is conveyed as the fluid of low viscosity. Apparatus according to claim 9, characterized in that gas is conveyed as the high viscosity fluid. Apparatus according to claim 9, characterized in that water is conveyed as the fluid.

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