EP0423469A1 - Control device for stopping an internal combustion engine - Google Patents

Abstract

In the case of Diesel internal combustion engines it is desirable to stop them rapidly when switching them off. For this purpose a control device is used with which, through a reversing valve (12), the intake chamber (33) of the fuel injection pump (11) is rapidly emptied by the feed pump (13). The reversing valve (12) has at least one valve element (16) provided with a seat valve closing body (18), which element acts in concert with associated valve seats (19, 21) and which has the characteristic that it is insensitive to contamination. As a result the use of a filter (31) on the intake side of the feed pump (13) can be dispensed with, giving the fuel injection pump (11) greater functional reliability, especially at low operating temperatures. The insensitivity to contamination of the reversing valve (12) is achieved by elastomer coating of at least one seat valve closing body (18). This control device has applications especially on fuel injection pumps for Diesel internal combustion engines. <IMAGE>

Description

State of the art

The invention is based on a control device according to the preamble of claim 1. From DE-A-30 14 712, a control device is already known in which the direction of action of the feed pump is reversible by means of a reversing valve by interchanging the lines to stop the internal combustion engine, and The suction chamber of the fuel injection pump is connected to the suction side of the feed pump and the pressure side of the feed pump to the tank. As a result, fuel is suddenly withdrawn from the suction chamber of the fuel injection pump, so that the fuel injection pump can no longer deliver fuel due to the negative pressure which has arisen and the associated internal combustion engine stops. The reversing valve is designed as a 4/2-way valve to achieve this functional sequence.

In this and other known solutions, e.g. B. according to US-A-43 19 550, the reversing valve contains a spool as a valve member, and it must therefore be ensured that only filtered fuel flows to the control valve, thereby causing both on the suction side as well as on the pressure side of the feed pump, as seen in the flow direction, in each case before the reversing valve, a fuel filter must be present.

The need to protect the reversing valve on the suction side of the feed pump by a fine filter against dirt particles has the functional disadvantage that this upstream filter, which is only exposed to the suction pipe vacuum, clogs due to paraffin precipitation at low temperatures.

This leads to a disability and, in extreme cases, to an unwanted interruption in fuel delivery.

From EP-A-0 124 504 a control device of a similar type is known, in which in a first embodiment the combination of a 4/2-way valve with a 3/2-way valve and in a second embodiment a 6/2-way valve is required . This control device also requires an additional fine filter with the disadvantages mentioned above.

Advantages of the invention

The control device designed according to the invention with the characterizing features of patent claim 1 realizes a solution which increases the operational and functional reliability of the control device, in particular during a cold start, with little construction effort, since a fine filter is no longer required on the suction side of the feed pump and is off dirt particles sucked into the tank cannot hinder the operation of the valve.

Through the in the following dependent claims Measures taken, advantageous developments and improvements of the control device specified in claim 1 can be achieved, which will be discussed in more detail below and also in the description of the exemplary embodiments.

Thus, with the features of claim 2, a valve member that is inexpensive to manufacture and securely guides the seat valve closing body is provided, and the reversing valve designed according to claim 4 as a 5/2-way valve can be used particularly advantageously in injection pumps that achieve a so-called cross-flushing in the individual partial suction chambers are provided with throttles in the inlet, it being advantageous for all pump types that the suction on the outflow side does not result in a reversal of the flow direction even when it is switched off.

According to the features of claims 5 and 6, a dirt-insensitive reversing valve is realized which, by the combination of two seat valves, does not require a filter for its operation either on the inflow or outflow side and thus has a high level of functional reliability.

With the features of claim 8, an inexpensive reversing valve that is easy to assemble with simplified piping can be produced, and according to the features of claim 9, the required vacuum tightness of the valve seats is ensured even with inevitable manufacturing tolerances.

drawing

Four embodiments of the invention are shown in section in the drawing.

The first embodiment with a normally rinsed suction chamber and a combined seat / slide valve is shown in a simplified manner in FIG. 1 in the conveying position and in FIG. 2 in the switch-off position; 3 and 4 represent the second exemplary embodiment with a flushed suction chamber and a combined seat / slide valve, FIGS. 5 and 6 the third exemplary embodiment with a double double-seat valve and FIGS. 7 and 8 the fourth exemplary embodiment a combined seat / slide valve.

FIG. 9 shows a seat / slide valve in constructive detail, the design of the associated elastomer-coated seat valve closing body being shown in an enlarged view in FIG. 10.

Description of the embodiments

The basic structure is common to all four exemplary embodiments shown in FIGS. 1-8. This shows z. B. in Figures 1 and 2 an inserted into the fuel circuit of a fuel injection pump 11, a reversing valve 12 and a feed pump 13 containing control device 14, wherein the reversing valve 12 is designed as a solenoid valve and the valve member 16 against the force of a return spring 17 in a delivery position Operation of the internal combustion engine and with spring force in a switch-off position to stop the internal combustion engine.

In a first exemplary embodiment in FIG. 1, the reversing valve 12 is designed as a 4/2-way valve, the valve member 16 being shown in the conveying position. At its end facing the return spring 17, the valve member 16 carries a seat valve closing body 18 which is designed as a double seat valve closing body and which cooperates with a first valve seat 19 and a second valve seat 21, which lie opposite one another and are located in a valve housing 22. The seat valve closing body 18 is supported and guided at the same time by a control slide 23 positioned at the end of the valve member 16 facing away from the return spring 17, the control slide 23 having at least one, preferably circular segment-shaped recess 25, which has the fuel flow between the connections switched through by the control slide 23 enables.

In the conveyed position of the valve member 16, the first valve seat 19 is open and the seat valve closing body 18 lies sealingly against the second valve seat 21, with which a valve chamber 24 receiving the return spring 17 is closed and a tank line 27 connected to a tank 26 with a to the suction side of the Feed pump 13 leading suction line 28 is connected.

A filter 31, which is designed as a fine filter, is inserted downstream of the feed pump 13 in a pressure line 29. In the delivery position of the valve member 16, the pressure line 29 is separated by the control slide 23 from a connecting line 32 which enters a suction chamber 33 of the fuel injection pump 11. An overflow line 34 leading to the tank 26 emerges from the suction chamber 33, into which an overflow valve 26 opening to the tank 26 and limiting the pressure in the suction chamber 33 is inserted.

The tank line 27, suction line 28, pressure line 29 and connecting line 32 are connected in this order to the valve housing 22 via four connections 35a-d.

In Figure 2, the first embodiment is shown with the valve member 16 in the switch-off position. The seat valve closes Body 18 lies sealingly on the first valve seat 19, as a result of which the second valve seat 21 is open and opens the connection, starting from the connecting line 32 via a permanently open connecting channel 37 to the suction line 28 which is arranged in the valve housing 22 and leads to the valve chamber 24.

Via the pressure line 29, the feed pump 13 can deliver the fuel to the tank line 27 connected to the pressure line 29 by the position of the control slide 23 and thus into the tank 26.

The second exemplary embodiment is shown in FIG. 3 in the conveying position and in FIG. 4 in the switch-off position. The second embodiment has a 5/2-way valve as a reversing valve 12, which, in addition to the four connections 35a, b, c and d for the tank line 27, suction line 28, pressure line 29 and connecting line 32, also has a fifth connection 41 for a downstream side of the Overflow valve 36 has suction line 42 connected to suction chamber 33 and opening into valve chamber 24.

In the delivery position according to FIG. 3, the suction line 42 is blocked by the valve chamber 24 which is closed by the seat valve closing body 18 against the second valve seat 21, while in the switched-off position according to FIG in the first exemplary embodiment, the fuel is conveyed from the valve chamber 24 to the tank 26 in the manner described. The suction space 33 is connected to the valve space 24 by the suction line 42 in such a way that the connection point of the suction line 42 to the suction space 33 is approximately diametrically opposite the connection point of the connecting line 32 to the suction space 33.

The third exemplary embodiment is shown in FIG. 5 in the conveying position and in FIG. 6 in the switch-off position. In this exemplary embodiment, the reversing valve 12 is designed as a 5/2-way valve with the valve member 16, which, in addition to the seat valve closing body 18, eliminating the control slide 23, has a second seat valve closing body 46, which is also designed as a double seat valve closing body and has two opposing valve bodies 22 located in the valve housing 22 Valve seats 47, 48 cooperate, of which one valve seat 47 in the conveyed position of the reversing valve 12 keeps the connection from the pressure line 29 to the connecting line 32 open and closes it in the switch-off position, and of which the other valve seat 48 in the switched-off position of the reversing valve 12 connects holds the pressure line 29 to the tank line 27 open and closes it in the delivery position. The valve member 16 of the reversing valve 12 is held in the region of each of the two seat valve closing bodies 18, 46 by a first diaphragm 51 or second diaphragm 52, which radially encompasses, is resiliently designed and has an openwork contour and the valve member 16 is axially movable and radially leading.

In a departure from the two previously described exemplary embodiments, the filter 31 is not inserted between the feed pump 13 and the reversing valve 12 in the pressure line 29, but, since there is only required to protect the fuel injection pump 11, is connected downstream of the reversing valve 12 in terms of flow and inserted into the connecting line 32.

The fourth embodiment is shown in FIG. 7 in the conveying position and in FIG. 8 in the switch-off position. In the fourth exemplary embodiment, the reversing valve 12 is designed as a 6/2-way valve and, as in the case of the first two exemplary embodiments, is constructed as a seat / slide valve.

On its valve housing 22, in addition to the four connections 35a-d for the tank line 27, suction line 28, pressure line 29 and connecting line 32, it also has the fifth connection 41 for a first subsection 81 of the overflow line 34 and connected downstream of the overflow valve 36 to the suction chamber 33 a sixth connection 83 for the second subsection 82 of the overflow line 34 leading to the overflow valve 36, both subsections 81, 82 of the overflow line 34 being connected to one another both in the delivery position of the reversing valve 12 and in its switch-off position.

An embodiment variant of the fourth exemplary embodiment described in relation to FIGS. 7 and 8 is shown in FIGS. 9 and 10 in constructive detail with the valve member 16 and the associated valve seats 19, 21, the valve member 16 being shown in an enlarged view in FIG.

The seat valve closing body 18 is partially encased on its outer contour with an elastomer part 56 and each has a sealing lip 59 or 61, which is directed against the valve seat 19 and the second valve seat 21 and embodied by the elastomer part 56. These sealing lips 59, 61 have a slight projection 62 axially relative to the end face 57 and 58. The part of the end faces 57 and 58 which is not provided with the elastomer part 56 forms a metallic stop when the valve seat 19 or 21 is positively engaged. The elastomer-coated seat valve closing body 18 is preferably also used in the exemplary embodiments shown in simplified form in FIGS. 1-4.

The second valve seat 21 is formed by an inner region of a bottom-shaped end face 66 of a pot-shaped insert part 67, as shown in FIG. 9, which with its inner wall corresponds to the Valve space 24 limited. The insert 67 is advantageously made of sheet metal as a deep-drawn part. It is axially secured by a spring washer 71 for the return spring 17, which acts on the valve member 16 and which seals the valve chamber 24, and is detachably fastened to the reversing valve 12.

The valve member 16 also contained in FIGS. 7 and 8 has a guide collar 72, a second guide collar 73 and an intermediate valve slide 74, which controls the connection from the pressure line 29 to the connecting line 32 and corresponds to the control slide 23 of the first exemplary embodiment .

The arrangement described above has the following functional and operational sequence.

Based on the known manner of operation of a reversing valve, the reversing valve 12 of the first embodiment (FIGS. 1 and 2) has the special feature that the valve member 16 is provided with a dirt-resistant seat valve closing body 18, so that the tank line 27 does not need to have a filter. The pressure line 29 following the feed pump 13 contains the filter 31 required for the operation of the control slide 23 and the fuel injection pump 11.

As a further special feature, the reversing valve 12, which operates as a 4/2-way valve, contains the internal connecting channel 37, through which the suction chamber 33 of the fuel injection pump 11 is emptied by the feed pump 13 when it is switched off.

Deviating from this, the fifth connection 41 is provided instead of the connecting channel 37 in the second exemplary embodiment according to FIGS. 3 and 4, the same sequence of action taking place with a reversing valve 12 designed as a 5/2-way valve.

In a modification of this, the reversing valve 12, also designed as a 5/2-way valve, in the third exemplary embodiment (FIGS. 5 and 6) of the control valve 16 has the two seat valve closing bodies 18, 46, so that the reversing valve 12 has no filter at all because of the dirt sensitivity of the seat valves is connected upstream and the filter 31 is only used directly in front of the suction space 33 to maintain the operational safety of the fuel injection pump 11 in the connecting line 32.

The fourth exemplary embodiment according to FIGS. 7-10 shows, by way of example, that a simplified line routing can be achieved with a 6/2-way valve, the structural configuration according to FIGS. 9 and 10 showing how a perfect sealing function of the reversing valve provided with the seat valve closing body 18 12 can be reached.

When the seat valve closing body 18 strikes the end face 66 forming the valve seat 21, the second sealing lip 61 first reaches the end face 66, forming a frictional connection. The second sealing lip deforms elastically until the protrusion 62 is pressed back and the metallic stop by positive engagement with the end face 66 ends the axial movement of the valve members 16.

Claims (10)

1. Control device for stopping an internal combustion engine, in particular a diesel internal combustion engine, with a fuel via a tank line (27) and a suction line (28) from a tank (26) and via a pressure line (29) and a connecting line (32) Input of a suction chamber (33) of a feed pump (13) delivering a fuel injection pump (11), with one in its delivery position connecting the tank line (27) with the suction line (28) and the pressure line (29) with the connecting line (32) as a second -Position multi-way valve designed reversing valve (12), which has a valve member (16) axially movably guided in a valve housing (22) and can be switched from the conveying position for operating the internal combustion engine into a switch-off position for stopping the internal combustion engine, in which the suction chamber 33 Fuel injection pump (11) with the suction line (28) of the feed pump (13) and its pressure line (29) with a tank line (27) is connected and with an overflow valve (36) which limits the pressure in the suction chamber (33) and is inserted into an overflow valve (36) returning the fuel from the suction chamber (33) to the tank (26), characterized in that the valve member (16) of the Reversing valve (12) at least for controlling the connection from the tank line (27) to the suction line (28) of the feed pump (13) with a seat valve Closing body (18) is provided, which in the conveying position of the reversing valve (12) holds an associated valve seat (19) located in the valve housing (22) and closes it in the switch-off position. 2. Control device according to claim 1, characterized in that the valve member (16) with a seat valve closing body (18) supporting and at the same time serving as its guide part control slide (23) is provided, which connects the pressure line (29) to the connecting line (32 ) and to the tank line (27) controls (Figures 1 - 4 and 7 - 10). 3. Control device according to claim 2, characterized in that the reversing valve (12) working as a 4/2-way valve has a connecting channel (37) which is delimited from the connecting line (32) to one of the second valve seat (21) and from the seat valve closing body ( 18) closable valve chamber (24) leads (Figures 1, 2,). 4. Control device according to claim 2, characterized in that the reversing valve (12) is designed as a 5/2-way valve and on its valve housing (22) in addition to four connections 35a - d for the tank, suction, pressure and connecting line ( 27, 28, 29, 32) also has a fifth connection (41) for a suction line (42) connected upstream of the overflow valve (36) to the suction chamber (33), which is delimited in a by the second valve seat (21) and in the Conveying position of the reversing valve (12.) from the seat valve closing body (18) opens the valve chamber (24) via which, in the switched-off position, the suction chamber (33) can be connected via the suction line (42) to the suction line (28) of the feed pump (13) (Figures 3 - 6). 5. Control device according to claim 1, characterized in that the seat valve closing body (18) is designed as a double seat valve closing body and cooperates with two opposite valve seats (22) located valve seats (19, 21), of which the second valve seat (21) in the Switch-off position of the reversing valve (12) keeps the connection from the suction chamber (33) of the fuel injection pump (11) to the suction line (28) of the feed pump (13) open and closes it in the conveying position, and that the valve member (16) of the reversing valve (12) also The first seat valve closing body (18) assigned to the suction line (28) also has a second seat valve closing body (46), which is also designed as a double seat valve closing body and cooperates with two opposite valve seats (47, 48) located in the valve housing (22), of which the a valve seat (47) of the second seat valve closing body (46 ) in the conveying position of the reversing valve (12) keeps the connection from the pressure line (29) to the connecting line (32) open and closes it in the switch-off position, and of which the other valve seat (48) in the switch-off position of the reversing valve (12) connects the holds the pressure line (29) to the tank line (27) open and closes it in the delivery position (FIGS. 5, 6). 6. Control device according to claim 5, characterized in that the valve member (16) of the reversing valve (12) in the region of each of the two seat valve closing bodies (18, 46) of a radially elastic, elastically formed, having an openwork contour and the valve member (16 ) axially movable and radially leading membrane (51, 52) is held (Figures 5, 6). 7. Control device according to claim 2, characterized in that in the basic form of cylindrical control spool (23) on its circumference at least one, preferably circular section-shaped, the fuel flow from the pressure line (29) to the connecting line (32) or to the tank line (27) serving Has recess (25) (Figures 1-4 and 7-9). 8. Control device according to claim 2, characterized in that the reversing valve (12) is designed as a 6/2-way valve and on its valve housing (22) in addition to the four connections 35a - d for the tank line (27), suction line (28), Pressure line (29) and connecting line (32) also a fifth connection (41) for the first partial section (81) of the overflow line (34) connected upstream of the overflow valve (36) to the suction chamber (33) and a sixth connection (83) for has the second partial section (82) of the overflow line (34) leading to the overflow valve (36), both partial sections (81, 82) of the overflow line (34) being connected to one another both in the conveying position and in the switch-off position (FIGS. 7-10) . 9. Control device according to claim 2, characterized in that at least the second valve seat (21) is embodied in the bottom-shaped end face of a cup-shaped insert (67) delimiting the valve chamber (24) (Figure 9). 10. Control device according to claim 2, characterized in that at least the seat valve closing body (18) is partially elastomer coated with the valve seats (19, 21) directed, resilient sealing lips (59, 61) (Figure 10).

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