DE19527285A1 - Circulatory cooling for engine valve - has valve containing compression inlet and compression channel - Google Patents

Abstract

The circulatory cooling requires channels (4,7) in the valve (1) on the compression side, connected on the induction side to channels (15,12) via the dish cavity. The coolant comes in via the annular compression channel (6) and goes out via the annular induction channel (13). The height of the annular channels corresponds to the max. lift of the valve. This ensures a continuous supply of coolant. Due to the offset position of the annular channels, the coolant also rotates the valve.

Description

The invention relates to a device for cooling valves according to the preamble of Claim 1 mentioned type.

Valves of this type are manufactured in a variety of technologies and designs.

The device of the type mentioned differs in relation to the prior art primarily because the sodium, which is hermetically sealed in the valve, does not oscillate Coolant acts, but that means a continuous cooling of the valve during valve operation a circulating coolant is made possible.

Starting from the aforementioned prior art, the invention is based on the object Reliable and inexpensive valve cooling according to the type mentioned in the preamble of claim 1 To be able to use valve circulation cooling.

This problem is solved by the characterizing features of claim 1. Advantageous Further developments of the invention are characterized by the claims dependent on this claim.

In the following the invention based on a preferred embodiment in conjunction with a Drawing described. It shows

Fig. 1 is a simplified sectional drawing of the valve ( 1 ) with the pressure channel inlet ( 4 ), the pressure channel ( 7 ), which is connected via the plate cavity ( 17 ) with the suction channel ( 15 ) and the suction channel outlet ( 12 ) such that the on the pressure side and in the valve guide ( 3 ) elements in the form of the pressure line ( 5 ), coolant pressed into the pressure ring channel ( 6 ), as engine oil or other coolant, after flowing through and cooling the previously mentioned spaces, on the suction side via the suction ring channel ( 13 ) and the suction line ( 14 ) exits again in order to be fed back into the cooling circuit. The height of the pressure ring channel ( 6 ) and the suction ring channel ( 13 ) are at least as high as the maximum valve stroke is long in order to ensure ongoing cooling during valve operation. Since the surface of the valve seat ( 16 ) and the wall of the valve stem ( 11 ) are subject to severe wear and tear and an additional ongoing cleaning of these surfaces is desired, the valve according to the prior art rotates during operation via a valve rotating device. Therefore, a separation of the inlet and outlet of the circulation cooling in the form of the offset pressure ring channel ( 6 ), compared to that of the suction ring channel ( 13 ) is provided.

Reference list

1 valve
2 valve stem seals
3 valve guide
4 pressure channel inlet
5 pressure line
6 pressure ring channel
7 pressure channel
8 plates
9 shaft ends
10 punctures
11 valve stem
12 suction channel outlet
13 suction ring channel
14 suction line
15 suction channel
16 valve seat
17 plate cavity

Claims (6)

1. All-round cooling for valves of engines, compressors and air motors, characterized in that the valve ( 1 ) contains the pressure channel inlet ( 4 ) and the pressure channel ( 7 ) through which the cooling medium via the plate cavity ( 17 ), the suction channel ( 15 ) and Suction channel outlet ( 12 ) leaves the cooling section within the valve ( 1 ) again, the coolant supply on the pressure side via the pressure line ( 5 ) integrated in the valve guide ( 3 ) and the pressure ring channel ( 6 ), while on the suction side the coolant outflow via the Suction ring channel ( 13 ) and the suction line ( 14 ) happens. The respective height of the pressure ring channel ( 6 ) and the suction ring channel ( 13 ) is dimensioned such that with a maximum stroke of the valve ( 1 ) the pressure channel inlet ( 4 ) and the suction channel outlet ( 12 ) always have their full cross section within the pressure ring channel ( 6 ) and the suction ring channel ( 13 ), the position of the pressure ring channel ( 6 ) relative to the suction ring channel ( 13 ) being interchangeable. 2. All-round cooling for valves according to claim 1, characterized in that the pressure ring channel ( 6 ) and the suction ring channel ( 13 ) are an integral part of the valve stem ( 11 ) or a separate sleeve and in their position with each other and in relation to their position in the valve ( 1 ) can be placed anywhere, then the pressure line ( 5 ) and the suction line ( 14 ) are in turn placed so that a supply of the ring channels with coolant is ensured during the entire valve lift. 3. All-round cooling for valves according to claim 1 and 2, characterized in that valve ( 1 ) contains more than one pressure channel inlet ( 4 ) or suction channel outlet ( 12 ) or pressure channel ( 7 ) or suction channel ( 15 ), each of which is a round, semicircular , may have oval or concentric cross sections and can also be combined with one another. 4. All-round cooling for valves according to one of claims 1 to 3, characterized in that the pressure channel ( 7 ) and the suction channel ( 15 ) on the surface or on the edge of the plate cavity ( 17 ) are each placed so that an optimal cooling situation of the Tellers ( 8 ) is reached. 5. All-round cooling for valves according to one of claims 1 to 4, characterized in that one or more pressure lines ( 5 ) and suction lines ( 14 ) are an integral part of the motor housing wall or according to their respective valve-related design from the motor housing wall or the respective valve guide for each valve , are supplied via a separate pressure and suction line system. 6. All-round cooling for valves according to one of claims 1 to 5, characterized in that the pressure ring channel ( 6 ) and the suction ring channel ( 13 ) are introduced in a motor housing integrated or attachable protuberance above the motor housing by means of a separate sleeve and the valve springs are seated on this protuberance or be surrounded by them, whereby the valve guide ( 3 ) can also be included in this protuberance.