DE19646786A1 - Pressure-relief valve fitted to supercharged diesel engine - Google Patents

Abstract

The valve discharges a current of air from the induction manifold (20) into the exhaust manifold (15). The valve (5) can be opened and shut by a hydraulic mechanism (25) associated with a control system (45). The mechanism comprises a cylinder (26) divided by a piston (30) coupled to the valve into chambers (35,36) supplied with the fluid. The valve can have a gas passage (9) shut by a mushroom-shaped valve head (7) coupled to the valve stem or piston rod (8). There can be a coolant passage (31) with a throttle in the piston connecting the chambers together, the pressures in the latter being different.

Description

The invention relates to a relief valve according to the preamble of the claim 1.

A relief valve of this type is used in internal combustion engines to control Gas flows, the relief valve in operation at least on one side with a Hot gas line is connected and if necessary - depending on the application and controlled by the blow-off valve - a gas flow through a blow-off opening into the hot gas line should be let in or let out of the hot gas line. Typical with such Blow-off valves equipped hot gas lines on internal combustion engines are for example Exhaust pipes or charge air pipes for supercharged diesel engines. Various Applications of such relief valves are known, for example in diesel engines Turbo charging to take a gas stream in the form of compressed charge air certain operating conditions from the charge air line into the exhaust pipe of the engine controlled transfer and thus an improvement in the operating behavior of the engine achieve, or in the case of supercharged diesel engines with exhaust gas recirculation, around which the charge air combustion gases to be mixed controlled from the main exhaust gas return line in Blow off detour lines and so, for example, in certain operating conditions Guide the charge air cooler past.

A relief valve according to the preamble of claim 1 is from the German Interpretation DT 14 51 904 known. In this example, the relief valve  used to blow off exhaust gases from the exhaust gas turbine in a turbocharger system can. With the help of the relief valve, it is possible to regulate the charge air pressure, for example in that the charge air pressure rises above a maximum limit counteracted by blowing off the exhaust gases in the exhaust gas turbine. A cylinder with a separating piston is provided for actuating the relief valve, wherein the separating piston is moved by a gas pressure, the size of which Charge air pressure, possibly with the help of a pressure relief valve around a predetermined Amount modified, determined.

Because of the direct thermal contact to the hot gas line and the high heat conduction of the Commonly used materials is a blow-off valve of known design in operation exposed to high thermal loads. Related to it undesirable signs of wear. At typical operating temperatures is special the actuating device for opening or closing a relief valve is endangered. In the case of a cylinder provided with a piston, as hydraulic or with a gas pressure The cylinder seals can be actuated, for example damaged or necessary oils are caused to accelerate aging.

The invention has for its object a structurally simple relief valve to propose the type mentioned, in which the resistance to the thermal load by the hot gases interacting with the valve or the thermal contact with the the blow-off valve connected hot gas line is improved.

This object is achieved by the entirety of the features of claim 1.

The relief valve according to the invention has a liquid cooling. This Liquid cooling can be designed so that the temperature is particularly high temperature-sensitive parts does not exceed a maximum permissible temperature. The circulation of the coolant is carried out accordingly and the cooling capacity to the occurring heat flows adjusted.

In a preferred embodiment of the relief valve according to the invention is a hydraulic actuating device for opening and / or closing the relief valve provided, the hydraulic fluid of the actuating device the cooling fluid of liquid cooling. This embodiment is structurally particularly simple,  because the hydraulic actuation of the relief valve and the cooling with a single, shared fluid supply is achieved. A hydraulic one Actuator has the advantage of responding to using electronic means electronic sensors detectable events to be controlled.

As a simple embodiment of the hydraulic actuation device is a Hollow cylinder with a dividing the cylinder interior into two cylinder chambers, in Longitudinal direction of the hollow cylinder movable and connected to the relief valve Separating piston conceivable, with at least one of the cylinder chambers with the Hydraulic fluid can be filled under pressure. A flow control for the Hydraulic fluid is used to form predetermined hydraulic fluid pressures in the Cylinder chambers provided. Depending on the direction of the pressure differential between the two The relief valve can be opened or closed in cylinder chambers. In training this Embodiment it is provided that the separating piston is separable with the relief valve connect. This version has manufacturing advantages and enables one maintenance-friendly operation.

To open or close the valve, the flow of hydraulic fluid in different variants can be controlled. For example, hydraulic fluid optionally pressurized in one or the other cylinder chamber to the pressure drop between the two cylinder chambers if necessary to reverse. The supply of this version of the actuator with Hydraulic fluid becomes particularly easy if a return spring is provided which counteracts the opening or closing of the relief valve. In this case only one of the cylinder chambers to be filled with hydraulic fluid under pressure open or close the relief valve against the action of the return spring. In An embodiment of the relief valve according to the invention provides that a Return spring normally keeps the relief valve closed and if necessary the Separating piston for opening the relief valve acts hydraulically moved. To this end the return spring is housed in one of the cylinder chambers and so with the Separating piston connected that it counteracts the opening of the relief valve. This Construction is particularly advantageous when under normal operating conditions the relief valve is usually closed and only exceptionally Hydraulic fluid must act on the separating piston under pressure.  

Another preferred further development of the relief valve according to the invention is noteworthy characterized in that the liquid cooling in at least one coolant channel Separating piston includes which coolant channel as one of the two cylinder chambers connecting throttle bore through which the hydraulic fluid can flow is. Hydraulic fluid is pressurized in one of the cylinder chambers and If there is a pressure drop to the neighboring cylinder chamber, hydraulic fluid flows through the coolant channel. Because both the open position and the closed position of the relief valve with a pressure drop between the two cylinder chambers is compatible, has such a modified hollow cylinder in any position of the Blow-off valve a permanent flow of hydraulic fluid through the Coolant channel on. The hydraulic fluid becomes constant by taking suitable measures Extracted of heat, the hydraulic fluid has a cooling effect on the walls of it flowed through cavities, for example on the separating piston and indirectly on the the separating piston related components of the relief valve. Will the Separating piston by a return spring in a basic position, corresponding to either the Open position or the closed position of the relief valve, held, so must Do not operate the valve in the direction of the pressure differential between the Cylinder chambers are reversed, but only the size of the pressure drop varies will. In this way, the design of the hydraulic system is simplified. Farther the coolant flow is in the various limit positions of the relief valve through the coolant channel and thus the cooling effect of the liquid cooling be different strengths. In this way there is the possibility of the cooling effect Appropriate adjustment by controlling the pressure gradient should be when blowing hot Gases vary the thermal load on the relief valve, for example as a function the time or the switching position of the relief valve.

In a further embodiment of the relief valve according to the invention it is provided that the blow-off valve is a through-channel that can be closed with a valve disk for the Gas stream and includes a piston rod connected to the valve plate and the Separating piston is connected to the piston rod. The separating piston can, for example be placed on the end of the piston rod facing away from the valve plate or the Surround the piston rod in a ring. It is also provided that in at least one of the Cylinder chambers a tube connected to the separating piston essentially coaxially is arranged with the piston rod. This arrangement of the tube has the advantage that the total surface of the materials connected to the relief valve and  Heat can be given off to the coolant to increase the surface area of the pipe is. The installation of a pipe in one or both cylinder chambers improved hence the efficiency of liquid cooling. The tube can also be used as a stroke limiter Blow-off valve must be designed by appropriately selecting the pipe dimensions: After going through a maximum stroke, the tube hits the inside wall of the Hollow cylinder and thus limits the stroke of the relief valve. Manufacturing technology A tube with a bottom at one end offers advantages. The floor allows one single fastener, such as a screw, the pipe together with the Fix the separating piston coaxially to the piston rod.

The installation of at least one pipe of the type mentioned enables further advantageous Further developments of the relief valve according to the invention. For example, the Return spring can be designed as a spiral spring with turns around the tube, the end facing away from the separating piston being connected to the hollow cylinder. So is realized a bracket and a guide for the return spring in a simple manner. Furthermore, the tube can be designed so that the piston rod at least partially in the pipe protrudes and between the piston rod and pipe for the hydraulic fluid continuous gap is formed and the coolant channel opens into the gap. Of the Gap acts as an extension of the coolant channel and determines the side Limiting the coolant flow. By channeling the coolant flow cooling is particularly effective along the surfaces to be cooled.

In the following an embodiment of the relief valve according to the invention in one Connection pipe between charge air pipe and exhaust pipe based on the following Drawing explains:

The drawing shows a partial sectional view of a portion of a supercharged diesel engine 1 with two hot gas lines, an exhaust line 15 and a charge air line 20 for compressed charge air. In order to enable a controlled blow-off of a gas flow from the charge air line 20 into the exhaust line 15 , a controllable blow-off valve 5 , a connecting channel 16 between the exhaust line 15 and the blow-off valve 5 and a connecting channel 21 between the charge air line 20 and the blow-off valve 5 are provided. The relief valve 5 is designed as a poppet valve with a through channel 9 connecting the connecting channels 16 and 21 for the gas flow to be blown off, a valve seat 6 which can be closed with a movable valve plate 7 and is adapted to the shape of the valve plate edge at one end of the through channel 9 and with a guided piston rod 8 , one end of which is connected to the valve plate 7 and the other end of which is connected to a hydraulic actuating device 25 for opening and / or closing the relief valve 5 . With the aid of the actuating device 25 , the piston rod 8 can be moved such that the valve plate 7 is either pressed against the valve seat 6 in the closed position of the relief valve 5 or assumes a second limit position at a predetermined distance h from the valve seat 6 in the open position of the relief valve.

The actuating device 25 is designed as a hydraulically operated actuating device and comprises a hollow cylinder 26 with a guide bore 27 arranged in the cylinder bottom and aligned in the longitudinal direction of the hollow cylinder 26 for the piston rod 8 and a separating piston 30 dividing the cylinder interior into two cylinder chambers 35 and 36 with one in the piston jacket recessed sealing ring 32 . The end of the piston rod 8 facing away from the valve plate 7 is guided in the guide bore 27 , projects into the interior of the hollow cylinder 26 and is detachably fastened to the separating piston 30 with a screw 29 . The separating piston 30 can be moved together with the piston rod 8 to open and close the relief valve 5 in the longitudinal direction of the hollow cylinder 26 . For the hydraulic actuation of the relief valve 5 , hydraulic fluid can be introduced under pressure into the cylinder chambers 35 and / or 36 or can be discharged from the cylinder chambers 35 or 36 by means of a flow control 45 via channels 51 , 52 or 53 . Connected to the flow control is a conventional type of cooling unit, not shown in FIG. 1, for cooling the hydraulic fluid.

In both cylinder chambers 35 and 36 , a pipe 40 and 42 connected to the separating piston 30 is arranged coaxially with the piston rod 8 . The tubes 40 and 42 each have a bottom abutting the separating piston with a central bore, which are used to fasten the tubes 40 and 42 together with the separating piston 30 to the piston rod 8 by means of the screw 29 . The length of the tubes 40 and 42 is selected so that the tube 42 is at a distance from the wall of the hollow cylinder 26 in the closed position of the relief valve 5 and the tube 40 is in contact with the wall of the hollow cylinder 26 in the open position of the relief valve 5 . The pipe 40 thus acts as a stroke limiter for the relief valve 5 . The inner diameter of the tubes 40 and 42 is chosen so that there are gaps 41 and 43 which are continuous between the piston rod 8 and the tubes 40 and 42 for the hydraulic fluid. The gaps 41 and 43 have a continuous connection for the hydraulic fluid, which is formed by a throttle bore 31 in the separating piston and by openings in the bottoms of the tubes 40 and 42 abutting the throttle bore 31 and forms a coolant channel through which the hydraulic fluid can flow continuously. A pre-tensioned spiral spring 33 with turns around the tube 41 connects the separating piston 30 to the inner wall of the hollow cylinder 26 and acts as a return spring which counteracts the opening of the relief valve 5 .

During operation of the diesel engine 1 , a difference ΔP of the hydraulic fluid pressures in the cylinder chambers 35 and 36 is built up by means of the flow control 45 for the hydraulic fluid and a permanent flow of the hydraulic fluid into the cylinder chamber 35 , through the coolant channel 31 into the cylinder chamber 36 and back from the cylinder chamber 36 generated in the flow controller 45 . If AP is less than the pretension of the return spring 33 , the relief valve 5 remains in its closed position. An increase in ΔP beyond the bias of the return spring 33 leads to an opening of the relief valve 5 with a maximum stroke h. Regardless of the position of the relief valve 5, there is a permanent flow of the hydraulic fluid through the coolant channel, the flux density increasing with increasing pressure gradient ΔP. Since heat is extracted from the hydraulic fluid flowing through the hollow cylinder 26 by the cooling unit already mentioned, the actuating device 25 and the blow-off valve 5 connected to it are permanently cooled.

The device shown in Fig. 1 is a specific example. A poppet valve is shown. However, the invention is applicable to all types of valves in which mechanical parts are moved hydraulically. It is also possible to reverse the flow direction of the hydraulic fluid in each case when opening or closing the relief valve. Furthermore, the arrangement of the return spring can be modified. It can also be housed in any of the cylinder chambers and biased under tension in addition to pressure. The direction of flow of the hydraulic fluid must be adjusted accordingly.

Reference list

1

Diesel engine with turbocharging

5

Blow-off valve

6

Valve seat

7

Valve plate

8th

Blow-off valve piston rod

9

Blow-off valve through-channel

15

Exhaust pipe

16

Connection channel between the exhaust pipe and the relief valve

20th

Charge air line

21

Connection channel between the charge air line and the relief valve

25th

Actuator for opening and closing the relief valve

26

Hollow cylinder of the actuator

27

Guide hole for the piston rod of the relief valve

29

screw

30th

Separating piston

31

Coolant channel

32

Sealing ring

33

Return spring

35,

36

Cylinder chambers

40,

42

Pipes on the separating piston

41,

43

Gap for hydraulic fluid

45

Flow control for hydraulic fluid

51,

52

,

53

Channels for the inflow and / or outflow of the hydraulic fluid
h Valve plate stroke in the open position of the relief valve

Claims (11)

1. blow-off valve ( 5 ) for an internal combustion engine ( 1 ) for blowing off a gas stream into or from a hot gas line ( 15 , 20 ), characterized in that a liquid cooling ( 45 ) for the blow-off valve ( 5 ) is provided. 2. Blow-off valve according to claim 1, characterized in that a hydraulic actuating device ( 25 ) for opening and / or closing the blow-off valve ( 5 ) is provided and that the hydraulic fluid of the actuating device ( 25 ) forms the cooling liquid of the liquid cooling. 3. Blow-off valve according to claim 2, characterized in that the actuating device ( 25 ) has a hollow cylinder ( 26 ) with a cylinder interior dividing into two cylinder chambers ( 35 , 36 ), movable in the longitudinal direction of the hollow cylinder ( 26 ) and with the blow-off valve ( 5 ) connected separating piston ( 30 ) and a flow control ( 45 ) for the hydraulic fluid to form predetermined hydraulic fluid pressures in the cylinder chambers ( 35 , 36 ). 4. relief valve according to claim 3, characterized in that the relief valve ( 5 ) with a valve plate ( 7 ) closable through channel ( 9 ) for the gas flow and a with the valve plate ( 7 ) connected piston rod ( 8 ) and the separating piston ( 30 ) is connected to the piston rod ( 8 ). 5. blow-off valve according to one of claims 3 or 4, characterized in that the liquid cooling comprises at least one coolant channel ( 31 ) in the separating piston ( 30 ), which coolant channel ( 31 ) as one of the two cylinder chambers ( 35 , 36 ) connecting and from the hydraulic fluid flowable throttle bore is formed, and that the predetermined hydraulic fluid pressures in the two cylinder chambers ( 35 , 36 ) are different to cause the formation of a permanent coolant flow through the coolant channel ( 31 ). 6. blow-off valve according to one of claims 3-5, characterized in that the separating piston ( 30 ) with the blow-off valve ( 5 ) is separably connected. 7. Blow-off valve according to one of claims 3-6, characterized in that the separating piston ( 30 ) with an opening of the blow-off valve ( 5 ) counteracting return spring ( 33 ) are connected. 8. relief valve according to one of claims 4-7, characterized in that in at least one of the cylinder chambers ( 35 , 36 ) with the separating piston ( 30 ) connected tube ( 40 , 42 ) is arranged substantially coaxially with the piston rod ( 8 ) . 9. Blow-off valve according to claim 8, characterized in that the return spring ( 33 ) is designed as a spiral spring with turns around the tube ( 40 , 42 ), the end facing away from the separating piston ( 30 ) being connected to the hollow cylinder ( 26 ). 10. relief valve according to claim 8 or 9, characterized in that the tube ( 40 ) as a stroke limiter (h) of the relief valve ( 5 ) is formed. 11. Blow-off valve according to one of claims 8-10, characterized in that the piston rod ( 8 ) protrudes at least partially into the tube ( 40 , 42 ) and between the piston rod ( 8 ) and tube ( 40 , 42 ) a continuous gap for the hydraulic fluid ( 41 , 43 ) is formed and the coolant channel ( 31 ) opens into the gap ( 41 , 43 ).