DE10037577A1 - Closing spring device for gas exchange valve drive in IC engines has pneumatic spring with cup tappet piston, having tappet base to support mechanical return spring of gas exchange valve - Google Patents

Abstract

The gas exchange valve (2) is closed by a mechanical spring and a pneumatic spring (4). The pneumatic spring has a piston (6), formed as cup tappet. The piston has a tappet base (30), for drive-connection to the valve shaft (14) of the gas exchange valve, and for engagement with the mechanical return spring (3) of that valve. A recess (31) in the tappet base on the cam side houses an adjusting plate (32) for the valve clearance.

Description

The invention relates to claim 1 of the main patent (patent application 100 16 878) a closing spring device for the valve train of a gas exchange valve Internal combustion engine in which a mechanical spring and from a predetermined Machine speed range a controlled switchable gas spring in Parallel connection cause the closing movement of the gas valve, the Gas spring comprises a piston which closes a chamber in a stroke-movable manner and the gas spring piston is designed as a plunger with one in one of the Gas spring chamber separate space slidably guided piston shirt as a pump piston of a self-pumping gas spring, which from the with a Pump chamber that can be supplied via a controlled medium Overflow channel the compressed medium at essentially maximum Opening stroke of the gas exchange valve is supplied.

With the design described above, a self-pumping is the task Closing spring device of simple construction achieved. With the additional Proposed development of the closing spring device according to Patent application 100 16 878 will further simplify the structure tracked.  

This is the aim of claim 1 of the additional application achieved that the gas spring piston designed as a cup tappet one for Drive-resistant connection designed with the valve stem of the gas exchange valve and for the mechanical return spring of the gas exchange valve serving plunger base, one on the cam side in the plunger base edged recess of the arrangement of a valve clearance adjusting plate serves.

With the proposed training one directly on the tappet bottom itself supporting mechanical spring of the closing spring device is omitted in advantageously the otherwise usual spring plate. In addition to a simplified The structure here results in a reduction of the moving masses.

To despite the opening in the ram base for the drive-proof connection with the valve stem has a closed sliding surface for the control cam the bucket tappet is equipped with a valve adjustment plate.

The valve lash adjustment plate preferably cooperates by means of a tight fit thread an edge of the tappet together and has facilities for one Tool intervention for valve clearance adjustment.

With this device, a frictional system of the Avoided the tappet on the control cam in its base circle area.

The invention is based on an embodiment shown in the drawing described for example.

A closing spring device ( 1 ) for the valve train of a gas exchange valve ( 2 ) of an internal combustion engine, not shown, comprises a mechanical spring ( 3 ) which, from a predetermined engine speed range, effects the closing movement of the gas exchange valve ( 2 ) in parallel by means of a gas spring ( 4 ) which can be switched on in a controlled manner The gas spring ( 4 ) comprises a piston ( 6 ) which closes a comb ( 5 ) in a stroke-movable manner.

In order to achieve a closing spring device ( 1 ) in a self-pumping configuration, it is proposed with a simple structure that the gas spring piston ( 6 ) is designed as a plunger ( 7 ) with a space ( 8 ) separate from the gas spring chamber ( 5 ) ) Slidably movable piston skirt ( 9 ) as a pump piston of a self-pumping gas spring ( 4 ) which, from the pump chamber ( 8 ) which can be supplied with a medium, supplies the compressed medium via an overflow channel ( 10 ) which can be activated via a controlled maximum opening stroke of the gas exchange valve ( 2 ) is.

For a simplified design of the gas spring ( 4 ), the gas spring piston ( 6 ) is a cylindrical cup tappet ( 7 ) which is fixed in a cup-shaped insert ( 12 ) fixed in a wall ( 11 ) of the internal combustion engine (not shown) and has a bottom ( 13 ) A gas spring chamber ( 5 ) accommodating the mechanical spring ( 3 ) and an annular pump chamber ( 8 ) can be moved in a stroke-movable manner from the shaft ( 14 ) of the gas exchange valve ( 2 ) through which the opening ( 15 ) passes, one or more with the pump chamber ( 8 ). connected overflow channels ( 10 ) are formed as grooves on the outer circumference of the insert ( 12 ) covered by the wall ( 11 ). These overflow channels ( 10 ) open into an annular groove ( 16 ) in the sliding surface ( 17 ) of the insert ( 12 ) corresponding to the outer surface of the piston skirt ( 9 ).

In order to pass on the compressed air in the gas spring chamber ( 5 ), the bucket tappet ( 7 ) in the outer circumferential surface of the piston skirt ( 9 ) has a distributor groove ( 18 ) assigned to the insert-side annular groove ( 16 ) when the gas exchange valve ( 2 ) opens to the maximum, which is connected to overflow openings ( 19 ) in the piston skirt ( 9 ) directed into the gas spring chamber.

As can also be seen from the figure, the overflow channels ( 10 ) are connected to a distributor line ( 20 ) to gas spring chambers ( 5 ) of gas springs ( 4 ) of further gas exchange valves ( 2 ), the distributor line ( 20 ) being connected via a branch line ( 21 ) and an electronically controlled 2/2-way valve ( 22 ) for pressure regulation in the gas springs ( 4 ) is connected to a gas atmosphere.

Furthermore, it can be seen from the figure that the pump chamber ( 8 ) is connected to a separate distributor line ( 23 ) to pump chambers ( 8 ) of gas springs ( 4 ) of further gas exchange valves ( 2 ), the distributor line ( 23 ) on the one hand connected to the respective pump chamber ( 8 ) is connected via an inlet line ( 24 ) which can be controlled by the respective piston / pump piston ( 9 ) and, on the other hand, is connected to a gas atmosphere via an inlet channel ( 26 ) which can be controlled by means of a further electronically controlled 2/2-way valve ( 25 ) ,

The gas atmosphere is preferably the normal atmosphere of the free environment gebung.

When the gas or air spring ( 4 ) is not activated, the inflow channel ( 26 ) to the pump chamber ( 8 ) is closed via the 2/2-way valve ( 25 ), whereas the gas or air spring ( 4 ) including the pump chamber ( 8 ) are vented via the spur line ( 21 ) and the overflow channels ( 10 ) when the 2/2-way valve ( 22 ) is openly controlled. In this position, not shown, of the two directional valves ( 22 and 25 ), the gas or air spring ( 4 ) is practically ineffective.

If, on the other hand, the two directional control valves ( 22 and 25 ) are switched to the positions shown with the inflow channel ( 26 ) open and the stub line ( 21 ) closed, a self-pumping gas or air spring ( 4 ) is achieved. With regard to the possible characteristic curves of the air spring ( 4 ), reference is made to FIG. 2 of the main patent 100 16 878.

For a further simple embodiment of the closing spring device ( 1 ), the cup-shaped insert ( 12 ) is formed in two parts from a tubular sleeve ( 27 ) which is connected to the wall ( 11 ) in a non-positive and form-fitting manner and a plug ( 28 ) fixedly arranged therein by means of a collar ( 29 ) with reduced outer diameter compared to the inner sleeve diameter serves to form the pump chamber ( 8 ).

For a further simplified embodiment, the gas spring piston ( 6 ), which is designed as a cup tappet ( 7 ), has a piston which is designed to be firmly connected to the valve stem ( 14 ) of the gas exchange valve ( 2 ) and to engage the mechanical return spring ( 3 ) of the gas exchange valve ( 2 ) serving plunger base ( 30 ). In order to achieve a smooth contact surface for the control cam ( 36 ) in the tappet base ( 30 ) on the control cam side, a bordered recess ( 31 ) is provided for the arrangement of a valve clearance adjusting plate ( 32 ).

The valve lash adjusting plate ( 32 ) interacts with an edge ( 34 ) of the cup tappet ( 7 ) by means of a tight fit thread ( 33 ) and has devices ( 35 ) for a tool engagement for valve lash adjustment.

Claims (2)

1. closing spring device for the valve train of a gas exchange valve of an internal combustion engine,
in which a mechanical spring ( 3 ) and, from a predetermined engine speed range, a gas spring ( 4 ) which can be switched on in a parallel manner, bring about the closing movement of the gas exchange valve ( 2 ), wherein
the gas spring (4) comprises a chamber (5) in a stroke seal the piston (6), and
the gas spring piston ( 6 ) is designed as a plunger ( 7 ) with a piston skirt ( 9 ) that is movably and tightly guided in a space ( 8 ) that is slidably movable in a space separate from the gas spring chamber ( 5 ) as a pump piston of a self-pumping gas spring ( 4 )
from the pump chamber ( 8 ), which can be supplied with a medium, the compressed medium is supplied via an overflow channel ( 10 ) which can be switched on at a substantially maximum opening stroke of the gas exchange valve ( 2 ) (according to patent application 100 16 878), characterized in that
that the gas spring piston ( 6 ) designed as a bucket tappet ( 6 ) is designed to provide a drive-proof connection with the valve stem ( 14 ) of the gas exchange valve ( 2 ) and serves to support the mechanical return spring ( 3 ) of the gas exchange valve ( 2 ) ( 30 ), where
A recess ( 31 ) with a rim and formed in the tappet base ( 30 ) in the tappet base serves to arrange a valve lash adjusting plate ( 32 ). 2. Closing spring device according to claim 1, characterized in
that the valve lash adjustment plate ( 32 ) cooperates with an edge ( 34 ) of the cup pusher ( 7 ) by means of a tight fit thread ( 33 ) and
Means ( 35 ) for a tool intervention for valve clearance adjustment.