CH622588A5 - - Google Patents

Description

The invention relates to an injection valve on a reciprocating internal combustion engine, with a valve body protruding into the combustion chamber of the cylinder, which inside has a valve needle interacting with a valve seat and has a plurality of nozzle bores distributed over its circumference, through which the fuel is intermittently released by lifting the valve needle from the valve seat emerges into the combustion chamber.

Injectors are generally dimensioned such that good fuel jet formation and therefore good, smokeless combustion take place in the combustion chamber of the cylinder when the engine is at full load. When dimensioning, there is either a row of nozzle bores with a relatively large diameter or the nozzle bores are arranged in two rows, the bore diameter being chosen to be correspondingly smaller. If the internal combustion engine is operated at partial load, there are no longer optimal conditions with regard to jet formation and combustion, which has previously been accepted.

The invention has for its object to provide an injection valve of the type mentioned, which allows to drive with the same number of nozzle bores at all loads without the jet formation and the combustion of the fuel are significantly impaired at part load.

This object is achieved according to the invention in that the injection valve is provided with a device which releases part of the cross section of each nozzle bore at part load of the machine and releases the entire cross section of each nozzle bore at full load.

With this device, it is possible in a simple manner to reduce the cross-section of all nozzle bores during part-load operation of the machine in such a way that good jet formation and thus good combustion of the fuel are retained. When the machine is at full load, the device is actuated so that the full cross section of the nozzle bores is released.

Two embodiments of the invention are explained in more detail in the following description with reference to the drawing. Show it:

1 is an axial section through an injection valve according to the invention,

2 and 3 each a detail on a larger scale than Fig. 1 in the region of the nozzle bores,

Fig. 4 is an axial section through a modified injection valve and

5 shows a section on a larger scale than in FIG. 4 in the region of the nozzle bores.

1, the injection valve has a valve body 1, which consists of an upper part 2 and a lower part 3, which are held together by a union nut 4. The valve body 1 rests with a flange 5 on the cylinder head 6, which closes off the combustion chamber 8 of the cylinder of the reciprocating piston internal combustion engine. The valve body penetrates the cylinder head 6 and, with the lower end of its part 3, which has a plurality of nozzle bores 7, projects into the combustion chamber 8.

For the fuel supply, the valve body 1 has a channel 10 which initially extends radially through the flange 5 and is then guided essentially in the longitudinal direction of the valve body through the parts 2 and 3, into the region of the lower end of the part 3. The Channel 10 ends there in an annular space 11. In the center of valve body 1, an axially displaceable valve needle 12 is provided, which is supported with its upper end via a spring plate 13 on a compression spring 14. At the lower end of the valve needle 12, this has a conical seat surface 15, which cooperates with a correspondingly conical seat surface in a sleeve 16 which surrounds the needle 12 and is axially displaceably mounted in part 3 of the valve body 1.

In the area of the annular space 11, the sleeve 16 has a plurality of bores 17 which serve to transfer the fuel from the annular space 11 into an annular space 19 which is left free between the sleeve 16 and a section 18 of the valve needle 12. The annular space 19 adjoins the seat surface 15 at its lower end. Below the bores 17, the sleeve 16 has a conical valve seat surface 20 which interacts with a corresponding seat surface in part 3 of the valve body 1. Below the valve seat surfaces 20 and 15, the sleeve 16 has an outer cylindrical projection 21, which forms a control edge 22 at its lower end, which with the s

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Nozzle holes 7 cooperate and change the cross section of the nozzle holes 7 depending on the height of the control edge 22.

The sleeve 16 is supported with its upper end on a piston-like intermediate piece 25, which slides in a cylinder bore of part 2 of the valve body 1 and which bears with its upper end on a further sleeve 26. The piston-like intermediate piece 25 as well as the further sleeve 26 likewise surround the valve needle 12. The sleeve 26 in turn is supported via a spring plate 27 on a compression spring 28 which rests with its upper end on a spring plate 29 which is located in the valve body 1 between the spring plate 13 of the compression spring 14 is arranged. The spring plate 29 is fixed in the valve body 1 via a spacer sleeve 30 and a hollow screw 31 which is screwed into the flange 5. The hollow screw 31 surrounds the upper end of the compression spring 14, which rests against a screw 32 screwed into the hollow screw.

In the cylinder space receiving the piston-like intermediate piece 25, a channel 36 opens, which extends essentially in the longitudinal direction through the valve body 1 and begins radially in the flange 5 at its upper end. The channel 36 is connected to a pressure medium source, not shown, which is connected to the flange 5 with the interposition of a valve. The upper boundary surface 35 of the cylinder space mentioned forms a stop for the movement of the intermediate piece 25, which stop can, if desired, be made adjustable, wherein mechanical or hydraulic means can be used for the adjustment.

The injection valve described works as follows: When the internal combustion engine is at full load, the supply of pressure medium via the channel 36 is shut off, so that the sleeve 16 is only under the pressure of the compression spring 28. The fuel, which is supplied in cycles and under high pressure via the channel 10, passes through the bores 17 into the annular space 19, where the valve needle 12 is first raised against the pressure of the spring 14. The valve seat surface 15 thus lifts off the corresponding seat surface in the sleeve 16 and the fuel reaches the space in front of the nozzle bores 7. Since only the pressure of the spring 28 acts on the sleeve 16, the sleeve 16 is also replaced by the pressure of the fuel shifted upward, so that its control edge 22 releases the nozzle bores 7 and the fuel reaches the combustion chamber 8 of the cylinder over the full cross section of the bores 7 without being obstructed by the control edge 22 (FIG. 3). Thereafter, because of the falling fuel pressure, the sleeve 16 and the valve needle 12 return to the starting position shown in FIG. 1.

If the internal combustion engine is to be operated at partial load, the pressure medium supply via the channel 36 is switched on, so that in addition to the pressure of the spring 28, the pressure of the pressure medium acts on the sleeve 16 via the piston-shaped intermediate piece 25 and blocks the sleeve 16 in its lower position . The fuel supplied via the channel 10 in turn passes into the annular space 11 and via the bores 17 into the annular space 19, where it counteracts the needle 12

622588

pushes the pressure of the spring 14 upwards so that it can continue to flow into the space in front of the nozzle bores 7. From this space, the fuel then reaches the combustion chamber 8 of the cylinder via the bores 7, the cross section of all the bores 7 being reduced because the control edge 22 of the sleeve 16 covers part of the inlet cross section of the nozzle bores 7 (FIG. 2).

If - as already mentioned - the stop surface 35 is adjustable, it can be achieved that intermediate positions of the control edge 22 are also assumed when the fuel is injected, so that the change in the cross section of the nozzle bores can be somewhat less than that shown in FIG. 2 .

4 and 5, the valve needle is designed as a hollow needle 52 and the function of the sleeve 16 in FIG. 1, which changes the cross section of the nozzle bores, is performed by a rod 56 mounted in the hollow needle 52. The hollow needle 52 is provided at its lower end with a conical seat surface 55 which cooperates with a corresponding conical surface in the lower part 3. The hollow needle 52, like the sleeve 16 in FIG. 1, is pressed downwards against the seat surface by a spring 14. The fuel channel 10 in turn opens into an annular space 11, which, however, directly surrounds the hollow needle 52.

Below the nozzle bores 7, the rod 56 forms a flange 57, the upper limit of which forms the control edge 22 for changing the cross section of all the nozzle bores.

The rod is supported on the base of the nozzle body 1 by means of an extension 58. The rod 56 has, above the flange 57, a section 56 ′ with a smaller diameter, which is provided over its entire length with axial grooves 53 which run into an annular groove 54 in the rod 56 at the upper end. Similar to the valve needle 12 in FIG. 1, a compression spring 28 is supported at the upper end of the rod 56 via a spring plate 13, the upper end of which rests on the screw 32. This screw 32 is penetrated by a screw 60 which abuts the spring plate 13 with its lower end and with which the stroke of the rod 56 is limited.

In the position of the rod 56 shown in FIG. 4, the machine is operated at full load because the screw 60 presses the rod 56 into its lowest position, in which the control edge 22 of the flange 57 releases the entire cross section of all nozzle bores 7. If part load is to be driven, the screw 60 is unscrewed slightly upward, so that a certain distance is created between the screw 60 and the spring plate 13, which corresponds to the desired stroke of the rod 56. After each lifting of the hollow valve needle 52 from the seat surface, fuel flows via the grooves 53 into the space in the hollow needle 52 surrounding the annular groove 54, as a result of the fuel pressure, which acts on the section of larger diameter of the rod 56 located above the section 56 ′ acts, this is raised up to the stop on the screw 60. The control edge 22 of the flange 57 thereby reduces the cross section of all nozzle bores 7, as shown in FIG. 5.

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2 sheets of drawings

Claims (9)

622588 1.Injection valve on a reciprocating piston internal combustion engine, with a valve body projecting into the combustion chamber of the cylinder, which inside has a valve needle interacting with a valve seat and has a plurality of nozzle bores distributed over its circumference, through which the fuel is intermittently lifted off the valve needle from the valve seat into the Combustion chamber emerges, characterized in that the injection valve is provided with a device (16) which is separate from the valve needle (12, 52) and which releases part of the cross section of each nozzle bore (7) at part load of the machine and the entire cross section of each nozzle bore (7) at full load , 56) is provided. 2. Valve according to claim 1, characterized in that the device (16, 56) in the valve body (1) is arranged axially displaceable and with a control edge (22) changes the cross section of each nozzle bore (7) on its inlet side. 2nd PATENT CLAIMS 3. Valve according to claim 2, characterized in that the device is designed as a surrounding the valve needle (12) and relative to this axially displaceable sleeve (16). 4. Valve according to claim 3, characterized in that the sleeve (16) has the inside with the valve needle (12) cooperating valve seat and is provided upstream of this valve seat with passage openings (17) for the fuel, which open into an annular space (19) which is formed between the sleeve (16) and a reduced diameter section (18) of the valve needle (12). 5. Valve according to claim 4, characterized in that the sleeve (16) is provided on the outside with a conical sealing surface (20) which cooperates with a corresponding seat in the valve body (1) upstream of the nozzle bores (7). 6. Valve according to claim 5, characterized in that a compression spring (28) is provided which presses the sleeve (16) with its outer sealing surface (20) against the seat surface in the valve body (1). 7. Ventü according to claim 6, characterized in that means (25) are provided which in addition to the compression spring (28) press the sleeve against the seat in the valve body (1). 8. Valve according to claim 7, characterized in that the means consist of a piston (25) attached to the sleeve (16) and movable in the valve body (1) and a pressure medium supply (36) which can be activated and deactivated on the piston. 9. Valve according to one of claims 2 to 8, characterized in that the axial movement of the device (16, 56) is limited by a preferably load-dependent adjustable stop (35, 60).