DE3127122A1 - "PISTON COMBUSTION ENGINE WITH LIQUID-COOLED VALVE SEAT FOR THE EXHAUST VALVE" - Google Patents

Description

P. 5630 / Wg / IS

Sulzer Brothers, Aktiengesellschaft, Winterthur / Switzerland

Piston internal combustion engine with liquid-cooled valve seat for the exhaust valve

The invention relates to a piston internal combustion engine with a liquid-cooled valve seat for the outlet valve, wherein a, connected to at least one supply line, annular coolant distribution space is provided, the Connect the bores with a likewise ring-shaped cooling space, from which removal lines for the heated Running out of coolant.

In the case of highly loaded piston internal combustion engines, it is advantageous to cool the valve seats of the exhaust valves.

For example, an arrangement of the type mentioned above is known (CH-PS 272 380). Next to you if possible Good heat transfer of the heat to be dissipated from the valve seat to the coolant, the heat dissipation must be as possible take place rotationally symmetrical to the valve seat axis to a uniform, rotationally symmetrical to the valve seat To achieve temperature distribution; because an uneven temperature distribution in the valve seat leads to distortions, which can impair the tightness of the valve.

This largely rotationally symmetrical temperature distribution is known from CH-PS 272 380 Construction not achieved; because in this design the coolant enters the via a tangential bore coolant distribution chamber open to the cooling chamber and

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leaves this after one revolution through an almost radial bore. It occurs in the area of the outlet bore therefore to a stagnation of the coolant and to dead spaces in the coolant flow. As a result, in the area of Adjacent inlet and outlet lines result in a highly asymmetrical temperature distribution, which leads to one-sided distortion of the valve seat.

The object of the invention is to ensure that the temperature distribution in the valve is rotationally symmetrical with respect to the valve axis To improve the seat, whereby a good heat transfer to the coolant should also be ensured. To The present invention, this object is achieved in that the bores or channels between the cooling space and the coolant distribution space as channels distributed over the entire circumference of a wall separating these two spaces are formed which are inclined against the radial direction in the same direction and run essentially horizontally.

The annular coolant distribution space forms a type of pressure chamber from which the coolant flows through the bores flows through it into the actual refrigerator. The inclination of the holes against the radial direction is the A swirl is imposed on the coolant flowing into the cooling space, so that a closed rotating one in the cooling space Coolant ring is created. This is perfect with respect to its axis coinciding with the valve axis rotationally symmetrical; it therefore also absorbs the heat from the valve seat evenly over the circumference.

To avoid possible disturbances of this symmetry through unilateral entry of the coolant into its distribution space or through to avoid its one-sided exit from the cold room,

it can be useful if a large number of supply lines to the coolant distribution space and removal lines from the coolant space, similar to the way the bores or channels are distributed over the circumference of the two spaces, is provided; the supply lines distributed over the circumference also serve as cooling holes for the Cylinder cover.

It is also advantageous if the coolant distribution space is directly connected to the discharge lines via throttle points Connection. Under certain circumstances, an excess of coolant at the valve seat can pass through these lines be escorted by; this bypass connection can also serve as a vent line.

For an intensive cooling effect, it is also advantageous if the flow rate of the coolant is the total cross-section of the channels and the volume of the annular cooling space are coordinated so that one, through the radial Inclination of the channels generated swirl flow, is turbulent in the cooling chamber.

The invention is explained in more detail below using an exemplary embodiment in conjunction with the drawing.

Fig. 1 shows, as a detail from a cylinder cover, an exhaust valve in longitudinal section I-I of Fig. 2;

FIG. 2 is section II-II from FIG. 1.

In the cylinder cover 4, which closes the cylinder 8 (not shown) at the top, there is a vertical bore into which a projection 10 protrudes at the end 9 on the cylinder space side; is based on this

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Valve seat 2, which is held in a valve cage 3. The one concentric with the valve seat 2 and the valve cage The outlet channel 11 running along the path is closed by the plate of a poppet valve 1.

The valve seat 2 and valve cage 3 receiving bore in the cylinder cover 4 is over a certain area of their axial height expanded to an annular coolant distribution space 12, which is triangular in cross section, in which, as shown in FIG. It can be seen that a plurality of supply lines 13 for the coolant, distributed over the circumference, open out from below; the supply lines 13 simultaneously form the Cooling bores for the cylinder cover 4. The coolant distribution chamber 12 is opposed to the cylinder chamber 8 by a seal 14 sealed in valve seat 2.

In accordance with the invention, inclined against the radial direction and also distributed over the circumference, horizontal bores 5 for the coolant from the coolant distribution space 12 in an annular cooling space 6, which is partially in the valve basket and runs partially in the valve seat 2; In turn, routing lines 7 distributed over the entire circumference lead out of the Cooling space 6 back into the cooler, not shown, of the coolant circuit.

At the tip of its triangular cross-section, the coolant distribution space 12 ends in an intermediate valve cage and the cylinder cover 4, the transverse bores 16 through the coolant distribution space 12 and the cooling space 6 the separating wall 17, which is part of the valve cage 3, with the removal lines 7. The gap 15 and the transverse bores 16 form the cooling space 6 short-circuiting, with throttling points for the flow, direct connections from the coolant distribution space 12 into the path

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Guiding lines 7. As mentioned, this connection is used for venting and, under certain circumstances, for draining off excess Coolant quantities. Although the construction shown with a separate valve cage 3 in the cylinder cover 4 is a manufacturing process is expedient, it is also possible to use the coolant distribution space 12 and the removal lines 7 and the bores 5 to be provided directly in the cylinder cover 4, the in this case, it can be manufactured as a cast piece with its cooling system, for example.

The coolant distribution space 12 forms a pressure space for the coolant, from which it can be distributed in a large number of rectified, to generate a twist with a peripheral component affected stream filaments enters the actual cooling space 6. This is how, as already described, 6 is created in the cooling space a rotationally symmetrical to the axis 18 formed liquid ring of coolant, which in a turbulent Flow rotiert.und dissipates the heat from the valve seat 2.

L e r s e i t e

Claims (4)

Claims l ^ l ^ / piston internal combustion engine with liquid-cooled Valve seat for the outlet valve, with an annular coolant distribution space connected to at least one supply line is provided to connect the bores with a likewise annular cooling space from which Exit lines for the heated coolant, characterized in that the bores (5) or channels between the cooling space (6) and the coolant distribution space (12) than over the entire circumference of one of these two spaces (6, 12) separating wall (17) distributed channels are formed which are inclined against the radial direction in the same direction and are essentially horizontal. 2. Piston internal combustion engine according to claim 1, characterized in that that the coolant distribution space (12) via throttle points (15, 16) with the removal lines (7) directly communicates. 3. Piston internal combustion engine according to claim 1 or 2, characterized characterized in that the flow rate of the coolant, the total cross-section of the channels (5) and the volume of the annular Cooling space (6) are coordinated so that one is generated by the radial inclination of the channels (5) Swirl flow in the cooling space (6) is turbulent. 4. Piston internal combustion engine according to claim 1, characterized in that a plurality of supply lines (13) to the coolant distribution space (12) and removal lines (7) from the cooling space (6), similar to the bores or channels (5) via the Scope of the two rooms (6, 12) distributed, is provided.