The present invention relates to a device for injecting highly pressurized fuel into a combustion chamber in an internal combustion engine, as per the preamble of patent claim 1.
A device of said type is known from WO 2007/009279 A1. In said known high-pressure accumulator injection system for an internal combustion engine, each injection valve is assigned an accumulator chamber and a non-return valve with bypass throttle connected parallel thereto. The injection valves are connected by means of fuel lines to a high-pressure feed device. By virtue of each injection valve being assigned a non-return valve with bypass throttle connected parallel thereto, it is possible with said high-pressure accumulator injection system to realize stable and reproducible injection processes with an expedient pressure profile during every injection process, even if the discrete accumulator chambers have an unusually small volume. Said high-pressure accumulator injection system makes do without a large-volume common rail.
A further injection device is known from EP 1 108 886 A. The cylinder head of an internal combustion engine has inserted into it one injection valve for each combustion chamber. A bore runs through the cylinder head to each injection valve, in which bore is laid a pressure pipe. The housing of the injection valve has, at the side, a high-pressure sealing surface against which the pressure pipe bears by means of its high-pressure counterpart sealing surface integrally formed on the end at this side. The high-pressure supply line to each pressure pipe is formed by a single common rail which is fastened directly to the cylinder head by means of screws and brackets. The brackets form a structural unit with the common rail, which structural unit can be pressed for sealing against the pressure pipe by means of screws. A flow restrictor may be provided between the common rail and each pressure pipe, which flow restrictor is fastened to the common rail by means of a thread and bears, by means of its end facing away from the common rail, against the pressure pipe. The common rail, which forms the high-pressure supply line, forms an accumulator, which is common to all the injection valves, for the highly pressurized fuel. Common rails are dependent on the number of cylinders of the internal combustion engine, the configuration of the internal combustion engine and the power of the latter, and are therefore specific to every engine type.
To eliminate the associated disadvantages, it is proposed in EP 1 485 609 B1 that each injection valve, which has an accumulator chamber, have attached to it by means of a screw connection a tubular high-pressure connection piece which forms a further accumulator chamber. At the other side, the high-pressure connection piece is connected by means of a supply throttle to a duct for the fuel.
In a fuel injection system known from WO 03/027485 A1, a number of fuel injectors are charged with highly pressurized fuel by means of a high-pressure collecting chamber via high-pressure lines. The fuel injectors comprise an annular chamber into which a connection piece which holds the high-pressure line opens out. Held so as to be situated upstream of the injector as viewed in the flow direction, and assigned to the high-pressure supply line, is a secondary volume which comprises a hydraulic decoupling element at its side facing toward the distributor.
JP 2000-205081 A discloses an accumulator injection system in which fuel is supplied at high pressure to a common rail by means of a high-pressure pump. An auxiliary accumulator is connected between a distributor line, which is arranged downstream of the common rail, and a nozzle holder. The auxiliary accumulator has a capacity of 3 to 20 times the fuel quantity required for a full-load injection.
The fuel injection system known from DE 10 2004 055 266 A1 also provides, between a high-pressure fuel pump and the injectors, one pressure accumulator for each injector.
WO 03/076794 A1 discloses an injection system which has feed units for feeding fuel from a fuel reservoir for the supply of at least one high-pressure line to the cylinders of an internal combustion engine. A number of fuel injectors are supplied by means of the at least one high-pressure line, with said fuel injectors comprising line sections by means of which the individual fuel injectors are connected to one another. The injector bodies comprise an integrated accumulator chamber.
In the common rail injection system known from EP 0 921 303 A, the accumulator is connected directly by means of a bracket and a pressure pipe to the injector. Should relatively significant leakages occur in the injection system, a flow restrictor may be connected between the accumulator and bracket.
EP 1 353 063 A2 discloses a fuel injection system in which at least one injection nozzle, which is connected to a feed system, is provided for each cylinder of the internal combustion engine. The feed system has an associated fuel pressure accumulator for each cylinder.
The fuel injection system disclosed in DE 101 14 219 A1 for supplying fuel to the combustion chambers of an internal combustion engine has a high-pressure pump which charges a number of fuel injectors with highly pressurized fuel. The individual fuel injectors is assigned in each case an accumulator volume which is charged directly by the high-pressure pump via a high-pressure supply line.
Taking said prior art as a starting point, it is an object of the present invention to create a generic device which operates reliably while having a space-saving design.
Said object is achieved by means of a device having the features of patent claim 1.
A filter retains solid particles in the fuel, which prevents blockage of in particular narrow flow cross sections and therefore increases the reliability of the injection device. Since the filter also serves as a stop for limiting the opening movement of a valve member of a non-return valve, a particularly simple, space-saving design is possible.
Preferred embodiments of the device according to the invention are specified in dependent claims 2 to 11 and 13 and 14.
With the refinement of the injection device according to claim 12, it is possible in a simple manner for a further injection valve to be supplied with fuel. A supply line connection and a clamp may be arranged on a housing of the injection valve itself or of a pressure connector.
A device according to claim 15 can be produced cheaply while being functionally reliable. As a result of the separation of the valve member into a plunger and a piston element, greater tolerances between the guide for the piston element and the seat for the plunger are admissible without reliability being impaired.
Optimum injection processes without a common rail are also made possible by means of an injection device in which a pressure connector assigned to an injection valve has an accumulator housing and a pressure pipe fastened to said accumulator housing for example by means of a screw connection. The accumulator housing is connected to a high-pressure supply line for the fuel and delimits a discrete accumulator chamber for the fuel.
The pressure connector forms a stable, self-supporting structural unit which can be pre-assembled. If the pressure connector has an accumulator housing and a pressure pipe fastened thereto by means of a screw connection, it is possible for the pressure chamber to be formed in a particularly simple manner.
Moreover, the formation of the device with a screw connection enables further components, such as a non-return valve, a filter, in particular edge-type filter, and a flow restricting valve to be installed into the pressure connector in a particularly simple manner.
The discrete accumulator chambers in the pressure connector permit optimum injection processes even if the high-pressure supply line has a small accumulator volume. It is possible for each injection valve itself to be provided with a further accumulator chamber.
With regard to the dimensioning of the accumulator chambers and the mode of operation of the accumulator chambers viewed together with the accumulator chambers, which are assigned to the other injection valves of the device, of the pressure connector in question, reference is made to WO 2007/009297 A. In terms of function, the discrete accumulator chambers described therein are identical in terms of effect to the accumulator chambers in the pressure connectors.
The present invention will be described in more detail on the basis of exemplary embodiments illustrated in the drawing, in which, in each case purely schematically:
Each of the identically designed injection valves 10, which are also shown in
As viewed in the direction of the longitudinal axis 28, the generally known injection valves 10 have firstly nozzle openings for injecting the fuel and secondly connections for the electrically controlled actuator and if appropriate the fuel return line. The actuator controls a hydraulic control device for intermittently injecting the fuel.
Each injection valve is assigned a pressure connector 30 whose longitudinal axis 32 runs preferably at least approximately, in the present case exactly perpendicular to the longitudinal axis 28 of the injection valve 10 and intersects said longitudinal axis 28. The pressure connectors 30 have in each case one pressure pipe 34 and one accumulator housing 36 which are fixedly connected to one another by means of a screw connection 38.
A preferably conical or spherical high-pressure counterpart sealing surface 40 is formed on the pressure pipe 34 at that free end region of the latter which faces away from the accumulator housing 36. The pressure pipe bears with its high-pressure counterpart sealing surface 40 against the high-pressure sealing surface 24 of the valve housing 22. If the high-pressure counterpart sealing surface 40 is formed so as to taper conically to the end of the pressure pipe 34 or spherical at the end, the pressure pipe 34 engages into the valve housing 22, which leads to automatic centering of the pressure pipe 34 with respect to the injection valve 10.
As indicated in
The accumulator housings 36 have, at their free end facing away from the pressure pipe 34, a supply line connection 42 arranged concentrically with respect to the longitudinal axis 28. A high-pressure supply line 44, illustrated in
Adjacent to the supply line connection 42, each accumulator housing 36 is engaged around by a clamp 48. In the region of the clamp 48, each accumulator housing 36 has a radial connecting passage 50—see FIGS. 3 to 5—for the supply of fuel via a further high-pressure supply line 44′ to the pressure connector 30 of the next injection valve 10. The connecting passage 50 of the pressure connector 30 assigned to the last of the row of injection valves 10 is sealingly closed off by means of a closure peg 52 inserted into the clamp 48. In this way, all the accumulator housings 36 and clamps 48 can be of identical design. If the internal combustion engine 12 is an in-line engine, then the respective further high-pressure supply lines 44′ may if appropriate also be of identical design.
As is particularly clear from
Adjacent to the threaded section, the bore 54 narrows via two small shoulders—discussed in more detail in conjunction with the description of FIG. 6—to form a discrete accumulator chamber 68 for storing fuel. The accumulator chambers 68 are adjoined by a filter section 70 in which the bore is cylindrical with a smaller diameter than in the cylindrical region of the accumulator chamber 68. Between the cylindrical region of the accumulator chamber 68 and the filter chamber 70, the bore 54 has a conical section which is relatively short in the axial direction. The filter section 70 has arranged in it a filter 72 and a non-return valve with throttle passage 74 which will be described in more detail in conjunction with
From the filter section 70 to the supply line connection 42, the bore 54 runs cylindrically and, as also shown in
At the end at this side, the bore 54 widens conically so as to form a connection sealing surface 76 for the high-pressure supply line 44 or further high-pressure supply line 44′. The end of the high-pressure supply line 44 or further high-pressure supply line 44′ is held in a known way against a connector-like projection of the accumulator housing 36 by means of a sleeve nut 78.
As can be seen in particular from a juxtaposition of
The volume of the discrete accumulator chamber 68 corresponds preferably to four to twenty times the volume of the fuel for an engine full load injection. At this juncture, it is also mentioned that the volume of the accumulator chamber 68 is also greater than, preferably two to three times as great as, the accumulator volume for fuel in the pressure pipe 34.
The design of the substantially cylindrical accumulator housing 36 with the bore 54 which widens in one direction or tapers in the other direction, and the formation of the guidance connection 82 with a clamp 48 which can be placed onto the accumulator housing 36, is extremely simple and permits the design of the accumulator chamber 68, the fixed connection to the pressure pipe 34 and the installation of further components which are described in conjunction with
As can be seen in particular from
Furthermore, the non-return valve 74 with throttle passage is arranged in the filter section 70 on the side facing away from the accumulator chamber 68. An annular, planar valve seat 98 of the non-return valve 74 is formed on the accumulator housing 36 by a shoulder 98′ of the bore 54 at the supply-line-connection-side end of the filter section 70. A valve member plate 100′, on which the throttle passage 102 is formed centrally, serves as a valve member 100. The valve member plate 100′ is held, in such a way that it can be repelled, in contact against the valve seat 98 by means of a helical spring 104 which is supported at the other end against the edge-type filter 72′. That end of the edge-type filter 72′ which faces toward the valve member plate 100′ forms a stop 106 for the valve member plate 100′ in order to limit the opening movement of the latter. The purpose and mode of operation of the non-return valve 74 with throttle passage 102, in conjunction with an at most small discrete accumulator chamber 68, is described in detail in WO 2007/009279 A. Firstly, a rapid flow of fuel into the accumulator chamber 68 and into the respective injection valve 10 is ensured, and secondly, the dynamic pressure waves from one injection process of the injection valve to the injection process of the next injection valve are dampened to such an extent that all the injection processes take place under practically identical conditions. For the sake of completeness, it is also mentioned here that the design of the accumulator chambers 68 and the interaction of the accumulator chambers 68 of the row of injection valves 10 is discussed in detail in said document.
Dashed lines in
The longitudinal bore 108 extending through the pressure pipe 34 in an axial direction—see in particular FIG. 6—is flared in its end region 108′ facing toward the accumulator housing 36 in order to hold a flow-restricting valve 110. The seat 112 of said flow-restricting valve 110 is formed by a conical design of the longitudinal bore 108 at the transition from the cylindrical section of small diameter into the cylindrical end region 108′ of relatively large diameter. A plunger 114 which acts as a valve member interacts with the seat 112, which plunger 114 is preloaded by means of a further helical spring 116 in the direction of the open position of the flow-restricting valve 110. In
On the side facing away from the seat 112, the plunger 114 bears, as a result of the force of the further helical spring 116, against a sleeve-shaped piston element 118 into which an aperture element 120 is inserted. The piston element 118 is arranged, and mounted so as to be movable in the direction of the longitudinal axis 32 in the pressure pipe 34, with a relatively close sliding fit 122 of for example 1/100 mm to 3/100 mm. The aperture element 120 is sealingly pressed into the piston element 118 and has an aperture passage 120′ in the axial direction. At the end facing toward the piston element 118 and aperture element 120, the plunger 114 has radial bores 124 which run in a crossed fashion and which permit the throughflow of fuel from the accumulator chamber 68 and the aperture passage 120′ to the associated injection valve 10.
The piston element 118 has, on its end side facing toward the plunger 114, a depression 126, with the aperture element 120 being arranged recessed in relation to said depression 126 and with said depression 126 serving to center the plunger 114 which engages therein with play. On the side facing away from the plunger 114, the piston element 118 has a further depression 126′ so as to form an encircling stop bead 128 radially at the outside. Said stop bead 128 interacts with a stop disk 130 which, at the other side, is supported by means of an annular spring disk 132 against a support shoulder 134 of the accumulator housing 36. At the other side, the pressure pipe 34 bears with its end side at this end against the stop disk 130 and presses the latter against the annular spring disk 132. Recessed in relation to said end side, the pressure pipe 34 has on its radially outer side a sealing shoulder 136 against which a sealing ring 138 bears. At the other side, said sealing ring 138 bears against a counterpart sealing shoulder 140 of the accumulator housing 36. As the screw connection 38 between the accumulator housing 36 and the pressure pipe 34 is tightened, the sealing ring 138 is sealingly compressed.
The cross section of the aperture passage 120′ is significantly smaller than all the other passages, encountered in the inflow direction to the injection valve 10, of the flow path for the fuel in the pressure connector 30. As a result, during normal injection processes, the piston element 118 moves together with the plunger 114 in the direction of the seat 112, but the plunger 114 does not come into contact with the seat 112 even during full-load injections. After the end of an injection process, the plunger 114 moves together with the piston element 118 in the direction of the stop disk 130 again, assisted by the force of the further helical spring 116.
However, if as a result of a defect downstream of the flow-restricting valve 110 the pressure drop across the piston element 118 and the aperture element 120 lasts for a longer time than during a full-load injection, the plunger 114 moves into the closed position and prevents the inflow of further fuel to the respective injection valve 10.
The installation of the flow-restricting valve 110, of the filter 72 and of the non-return valve 74 with throttle passage into the pressure connector 30 permits a simpler and space-saving design of the injection valves 10 otherwise fitted with said elements if appropriate. It is self-evidently also possible for the pressure connector 30 to be formed only with some or none of said elements. In any case, however, said pressure connector 30 has an accumulator chamber 68.
The two-part design of the housing of the pressure connector 30, specifically by means of a pressure pipe 34 and an accumulator housing 36, permits simple and cheap production of the pressure connector 30 with the integrated accumulator chamber 68 and if appropriate further elements—as discussed above. For the sake of completeness, it is mentioned that a part of the accumulator chamber 68 may also be formed on the pressure pipe 34.
It is also possible for the aperture element 120 to be integrally formed on the piston element 118. The separation of the piston element 118 and plunger 114 is advantageous in production terms in that little attention need be paid to the concentricity tolerances between firstly the outer lateral surface of the piston element 118 and the sealing surface of the plunger 114 and secondly the inner lateral surface of the pressure pipe 34 in the region of the sliding fit 122 and the seat 112.
In the variant of the device according to the invention indicated in
One section of the connecting passage 50 is formed on the connection part 142 and a further section is formed on the accumulator housing 36. To ensure the connection between said sections, the connection part 142 has a circumferential groove 146.
Between said circumferential groove 146 and the wide screw connection 144, sealing shoulders 148 are integrally formed on the connection part 142 and on the accumulator housing 36, which sealing shoulders 148 bear sealingly against one another.
That end side of the connection part 142 which faces toward the filter 72 forms the valve seat 98 for the valve member 100 or valve member plate 100′. Between said end side and the circumferential groove 146, either a sealing element or a relatively close fit is provided between the connection part 142 and the accumulator housing 36 in order to prevent or minimize leakage.
This variant which is shown has the advantage that the filter 72 or edge-type filter 72′ can be inserted into the filter section 70 from the end of the accumulator housing 96 at this side. To position the filter 72 or edge-type filter 72′, the accumulator housing 36 may have a stop bead 150 at the transition of the bore 54 from the filter section 70 into the accumulator chamber 68.
It is also conceivable for the accumulator housing 36 and the pressure pipe 34 to be formed together in one piece. In this case, the filter section 70 may have a diameter which corresponds to the diameter of the bore of the accumulator chamber 68 and the bore is closed off by means of a correspondingly simply matched connection part 142.
Furthermore, the illustrated and described embodiment of filter 72, non-return valve 74, flow-restricting valve 110 and connection part with supply line connection 42 and clamp 48, individually and in combination, is also suitable for use directly in injection valves 10. Here, the accumulator housing 36 and if appropriate pressure pipe 34 is replaced by the valve housing 22.
Running through the connection piece 150 in the direction of the longitudinal axis 28 is the bore 54 with the filter section 70 and the adjoining bore section 54 which is smaller in cross section and which leads to the connection sealing surface 76. The filter section 70 opens out into the accumulator chamber 68 integrally formed on the housing body 152, with the filter 72 in the form of an edge-type filter 72′ being inserted into the filter section 70 from the side facing toward the accumulator chamber 68. Said filter 72 has, as already described further above, the longitudinal grooves 92, 92′, with the longitudinal grooves 92 being practically sealed off by means of the axial end region 94, which bears sealingly against the connection piece 150, in the direction of the non-return valve 74 and in the direction of the supply line connection 42 with a close fit. Correspondingly, the longitudinal grooves 92′ which are open in the direction of the non-return valve 74 and in the direction of the supply line connection 42 are sealed off in the direction of the accumulator chamber 68 by the axial end region 94′, as is also the case in the embodiments described further above. In the embodiment according to
While the longitudinal grooves 92 open out into the circumferential groove 154 and end there, the longitudinal grooves 92′ are separated from said circumferential groove 154. For the sake of completeness, it is mentioned here that the circumferential groove 154 is covered radially at the outside by the connection piece 150.
That end region of the edge-type filter 72′ which projects beyond the connection piece 150 in the direction of the accumulator chamber 68 is, so as to form a flange 160, of greater diameter than that part of the edge-type filter 72′ which is arranged in the filter section 70. The flange 160 bears with its surface facing toward the connection piece 150 against an end-side counterpart shoulder 162 of the connection piece 150 and is engaged around by a sealing bead 164, which projects with respect to said connection piece 150 in the axial direction, of the connection piece 150. At the level of the free end of the sealing bead 164, the flange 160 has integrally formed on it a narrowing, which forms an encircling shoulder 166, of the outer diameter to the clear cross section of the accumulator chamber 68. The shoulder 166 and the free end of the sealing bead 164 bear against a seal ring 168 which bears at the other side against a sealing shoulder 170 of the housing body 152 and which is supported radially at the outside by the housing body 152 and radially at the inside by the flange 160. With its free end section, the flange 160 engages into the section, which forms the accumulator chamber 68, of the axial bore in the housing body 152. The seal ring 168, which preferably has a rectangular cross section, may be composed of a soft material and, when the screw connection 172 is tightened, is compressed between the connection piece 150 and the housing body 152 in order to ensure reliable sealing even at very high pressures.
The valve seat 98 for the valve member 100, which is designed as a valve member plate 100′, of the non-return valve 74 is integrally formed on the connection piece 150. At the transition from the filter section 70 to that section of the bore 54 which leads to the connection sealing surface 76, the connection piece 150 has an encircling axial undercut 174 such that an annular bead which is exposed in the axial direction is formed with the annular valve seat 98.
The valve member plate 100′ with the centrally arranged throttle passage 102 is held, in such a way that it can be repelled, in contact against the valve seat 98 by means of the helical spring 104, with the helical spring 104 being supported at the other end against the edge-type filter 72′. Said helical spring 104 engages into a centering recess 176 of the edge-type filter 72′ at this end, which centering recess 176 has a sleeve-shaped projection which projects with respect to the axial end region 94 in the region of the valve member plate 100′ and whose free end forms the stop 106 for limiting the opening travel of the valve member plate 100′.
The clamping bracket 18 engages with its pressure shoulder 64 on that end side of the housing body 152 which is situated at the connection piece 150 side and which forms the counterpart shoulder 66.
For the sake of completeness, it is mentioned that the injection valve 10 may also be designed as disclosed in WO 2007/009279 A. Furthermore, it is also possible for the connection piece 150 to be designed according to
In the embodiment shown in
On the side facing away from the non-return valve 74, the edge-type filter 72′ is supported in the axial direction on an encircling support shoulder 182. The edge-type filter 72′ as per
The sealing plug 178 is provided with a fuel duct 184 which is connected at one side to the high-pressure supply line 44 and at the other side to the further high-pressure supply line 44′ and leads to the non-return valve 74. Said fuel duct 184 is formed by a blind bore 186 which is engaged around by the annular valve seat 98, a radial bore 190 which intersects said blind bore 186, and an encircling connecting groove 192 which is outwardly open in the radial direction with respect to the longitudinal axis 28, in the base region of which connecting groove 192 the radial bore 190 opens out. For the sake of completeness, it is mentioned that, between the connecting groove 192 and that end side of the sealing plug 178 which faces toward the accumulator chamber 68, the sealing plug 178 is held in the housing body 152 with a relatively close fit in order to prevent or at least minimize leakage of fuel from the connecting groove 192 to the edge-type filter 72′. In the direction of the free end of the housing body 152, a seal 194 prevents the escape of fuel to the environment.
In the connecting groove 192, the connecting passage 50 runs through the housing body 152, which connecting passage 50 widens conically at both sides in the radially outward direction so as to form the sealing surfaces 80 with which the corresponding sealing surfaces 80 of the high-pressure supply line 44 and further high-pressure supply line 44′ come into contact. The sealing end sections 90 of said high-pressure supply lines 44, 44′ are held in sealing contact against the sealing surfaces 80 in a known way by means of pressure screws 88 which are screwed into the housing body 152.
Fuel supplied via the high-pressure supply line 44 to the injection valve 10 can therefore flow practically unhindered to the further high-pressure supply line 44′ and can at the same time be supplied via the non-return valve 74 and the edge-type filter 72′ to the accumulator chamber 68. The injection valve 10 may otherwise be designed for example as disclosed in WO 2007/009279 A. Furthermore, the embodiment shown in
In the embodiment of the injection valve 10 shown in
The bore 54 runs through the housing body 152 at right angles to the longitudinal axis 28 and laterally offset with respect to the latter. Said bore 54 intersects the connecting bore 196 such that the bore 54 is flow-connected to the discrete accumulator chamber 68. The bore 54 could however also be arranged such that its axis 54′ intersects the longitudinal axis 28.
The bore 54 is formed so as to narrow in a stepped fashion, with said bore 54 widening conically from its narrowest part, which forms an inflow section 200, in the outward direction so as to form a high-pressure sealing surface 24. A pressure pipe connector 202 bears by means of its high-pressure counterpart sealing surface 40 against said high-pressure sealing surface 24. The pressure pipe connector 202 is of generally known design and, in the present case, does not have a discrete accumulator chamber 68. Said pressure pipe connector 202 may however fundamentally be provided and constructed with an accumulator chamber of said type, as described further above.
At the other end, the bore 54 is sealingly closed off by means of a sealing plug 178 which is screwed into the housing body 152. For this purpose, a seal ring 168 acts between the sealing plug 178 and the housing body 152.
The edge-type filter 72′ is integrally formed on a plug shank 204 which projects from and is formed in one piece with the sealing plug 178, which edge-type filter 72′ is otherwise of exactly the same design as described further above and shown for example in
Between the axial end region 94 and the sealing plug 178, the plug shank 204 is provided with a reduced cross section in order to produce an adequate flow cross section to the connecting bore 196.
That end side of the edge-type filter 72′ which faces toward the inflow section 200 forms the stop 106 for the valve member 100, which is designed as a valve member plate 100′, of the non-return valve 74. Said valve member 100 has, on its side facing toward the edge-type filter 72, the centering projection 180 which is engaged around by the end of the helical spring 104 at this side, with said helical spring 104 engaging into the centering recess 176 of the edge-type filter 72′ and being supported against the base of said centering recess 176. The helical spring 104 holds the valve member plate 100′, in such a way that it can be repelled, in contact against the valve seat 98 which is formed by a step-like narrowing of the bore 54. Here, too, the central throttle passage 102 through the valve member plate 100′ permanently connects the high-pressure supply line 44 to the accumulator chamber 68 even in the closed position of the non-return valve 74. Here, too, the injection valve 10 may otherwise be designed correspondingly to WO 2007/009279 A.
The mode of operation and action of the non-return valve 74 with bypass throttle is the same in all the embodiments and is as described further above.
Number | Date | Country | Kind |
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01428/07 | Sep 2007 | CH | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CH2008/000375 | 9/5/2008 | WO | 00 | 3/10/2010 |