DE3127122C2 - Liquid-cooled valve seat for an exhaust valve of a reciprocating internal combustion engine - Google Patents

Abstract

A large number of horizontal through-bores (5) lead from the distribution space (12) through the wall (17) separating the distribution space (12) from the cooling space (6) in the valve seat (2). These passage openings (5) are inclined against the radial direction, so that a swirl flow is generated in the cooling space (6) which consists of a liquid ring which is rotationally symmetrical to the valve axis (18) and has a turbulent flow behavior. The turbulence of the flow ensures good heat transfer; Their rotationally symmetrical design ensures a uniform temperature distribution, which prevents warping and warping of the valve seat (2).

Description

In the case of highly loaded piston internal combustion engines
it is advantageous to cool the valve seats of the exhaust valves. In addition to the best possible heat transfer, the partition wall are separated from each other, and that the heat to be dissipated from the valve seat to the cooling, the bores of the channels in the area of the height transfer, the aim is that the heat flow cover both spaces essentially horizontally as rotationally symmetrical as possible to the valve seat axis it continuously follows one another over the entire circumference of the partition in order to achieve a uniform temperature distribution, arranged in a rotational manner relative to the valve seat and symmetrical against the radial direction; because 55 are inclined in the same direction, an unequal temperature distribution in the valve seat leads to

3. Valve seat according to claim 1, characterized in that the coolant Ve .- «eilraum (12) over Throttle lines (15.16) with the removal lines (7) is in direct connection.

goods

Heat transfer to the coolant should be ensured.

According to the present invention, this object is achieved in that the coolant distribution space The outside of the cooling space encloses a ring and at least part of its height at least part of the Covered level of the cooling space, the cooling space and the coolant distribution space by a

to faults, which can impair the tightness of the valve.

An arrangement of the type mentioned for cooling the valve seats of exhaust valves is for example from CH-PS 6 14 014 known. In this construction, the coolant distribution space encloses ring-shaped the shaft guide part of the valve cage. A number of vertical holes lead the coolant

stood that the bores are evenly distributed in the circumferential direction at equal distances from one another are without - as in CH-PS 60 6 14 014 - removal lines are provided in between.

The ring-shaped coolant distribution space, separated from the cooling space by a wall, forms a kind of pressure chamber, in which a kind of "damming up" ensures an even distribution of the coolant in front of the bores.

tel in the cooling space located in the valve seat, of which 65 is made; the coolant therefore flows over the entire

Lead-away lines go out, which with the bores al- zen circumference from the same pressure level through the

ternally distributed in the circumferential direction in the valve cage, evenly distributed and identical bores

are. The refrigerant flowing vertically into the cold room enters the cold room. Due to the inclination of the

against the radial direction, a twist is imposed on the coolant flowing into the cooling chamber, so that a closed rotating coolant ring is created in the cooling space. This is regarding him, with the axis coinciding with the valve axis is designed to be completely rotationally symmetrical; therefore he also takes the heat from the valve seat on the circumference evenly.

To avoid possible disturbances of this symmetry by one-sided entry of the coolant into its distribution space or to prevent it from escaping from the cold store on one side, it may be useful to if a plurality of supply lines to the coolant distribution space or of removal lines from the Cooling space, similar to the pipes or channels distributed over the circumference, in the bottom of the coolant distribution space or is arranged in the ceiling of the cold room continuously one after the other.

It is also advantageous if the coolant distribution space is in direct connection with the routing lines via throttling points. Through these lines Under certain circumstances, an oversupply of coolant can bypass the valve seat; Farther can use this bypass connection as a discharge line to serve.

In the following, the invention will be explained using an exemplary embodiment in conjunction with the drawing explained in more detail.

F i g. 1 shows a section from a cylinder cover with an outlet valve in a longitudinal section along the line I-I in FIG.

Fi g. FIG. 2 shows a cross section along line 11-11 in FIG Fig. 1.

In a cylinder cover 4, which closes a cylinder 8 (not shown) at the top, is located a vertical bore into which a projection 10 protrudes at the end 9 on the cylinder space side; on this is based a valve seat 2 which is held in a valve cage 3. One concentric with the valve seat 2 and the valve basket The outlet channel 11 running 3 is closed by the plate of a poppet valve 1.

The hole in the cylinder cover 4 that accommodates the valve seat 2 and the valve cage 3 is above a certain level Area of their axial height to an annular coolant distribution space 12 with a triangular cross-section, in, as can be seen from FIG. A multiplicity of feed lines 13 distributed over the circumference for the coolant flow in from below. The supply lines 13 simultaneously form the cooling holes for the Cylinder cover 4. The coolant distribution chamber 52 is against the cylinder chamber 8 by a seal 14 in the Valve seat 2 sealed.

Lead horizontal holes 5 for the coolant, inclined against the radial direction and also over the Circumferentially distributed, from the coolant distribution space 12 in an annular cooling space 6, which is partially in the valve cage 3 and runs partially in the valve seat 2. Removal lines 7 again distributed over the entire circumference lead from 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 3 and cylinder cover 4 formed gap 15, the transverse bores 16 through a coolant distribution space 12 separating wall 17 from cooling space 6, which wall is part of valve cage 3, with removal lines 7 associate. The gap! 5 and the transverse bores 16 form the cooling space 6 short-circuited with throttling points Direct connections provided for the flow from the coolant distribution space 12 into the discharge 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 expedient in terms of manufacturing, it is also possible to use the coolant distribution space 12 and the removal lines 7 and the holes 5 to be provided directly in the cylinder cover 4, which in this case with its cooling system for example, can be made as a cast piece.

The coolant distribution space 12 forms for the coolant a pressure chamber, from which there is a multitude of rectified, for swirl generation with a Circumferential component of afflicted stream filaments enters the actual cooling space 6. This is how it arises described, in the cooling space 6 a rotationally symmetrical to the axis 18 designed rotating liquid ring from coolant, which rotates in a turbulent flow and dissipates the heat from the valve seat 2. the Turbulence of the flow is guaranteed by that the amount of cooling water, the cross sections of the bores 5 and the volume of the cooling space 6 accordingly be coordinated. The rotationally symmetrical cooling of the valve seat 2 prevents Faults.

For this purpose 2 sheets of drawings

Claims (2)

Claims: Medium splits up in an uncontrollable manner when it hits the floor of the cooling room and flows off to both sides to the adjacent routing lines. When the coolant is fed in, a locally very different temperature distribution occurs over the circumference of the valve seat, for example through Aa impingement cooling at the feed points. Furthermore, no ring flow is formed in the cooling space, which is essential for a rotationally symmetrical temperature distribution. The CH-PS 6 12 244 discloses constructions in which the coolant supply into the annular cooling space and the removal from the cooling space on one or in a manner not described in more detail on several 1. Liquid-cooled valve seat for an outlet valve of a reciprocating internal combustion engine, wherein a, 5
connected to at least one supply line,
annular coolant distribution space is provided,
the a number of holes with one as well
connecting annular cooling space from which
Removal lines for the heated coolant aus- io
go, characterized in that the
Coolant distribution space (12) the cooling space (6) outside
ring-shaped and with at least one
Part of its height covers at least part of the level of the cooling space (6), with the cooling 15 points taking place without a uniform storage space (6) and the coolant distribution space (12) being provided by division in a coolant distribution space. a partition (17) are separated from each other, and a ring flow as undisturbed as possible and thus also the bores or channels (5) in the plane even temperature distribution can not be achieved with these known coolant systems even when the two spaces (6, L?) overlap in height essentially ¹ · * horizontally over the entire circumference of 20. the partition (17) continuously successively from GB-PS 6 68 962 is another cooling system arranged and known against the radial direction in the same for Auslaßventiie, in which the Kühimittei over Direction are inclined. a tangential bore enters an annulus 2. Valve seat according to claim 1, characterized in that there is also an annular gap, that a plurality of supply lines (13) 25 extends vertically to the valve seat. This gap space becomes to the coolant distribution space (12) or not directly penetrated by the coolant; this circulates pipes (7) from the cooling chamber (6), similar to only in the annulus vad leaves this after one time Bores or channels (5) like to circulate around the circumference through an almost radial bore. in the distributed, in the bottom of the coolant distribution space (12) area of the outlet bore it comes to a or in the ceiling of the cooling space (6), there is a steady accumulation of coolant and subsequent dead spaces in the cooling is arranged. middle flow. This allows in the area of side by side lying inlet and outlet lines result in a strongly asymmetrical temperature distribution, which leads to a one-sided warping of the valve seat 35. Furthermore, the indirect flow is in the gap not suitable for adequate heat dissipation from the valve seat of highly stressed modern exhaust valves to ensure. The object of the invention is to bezeuch the valve The invention relates to a liquid-cooled 40-axis rotationally symmetrical temperature distribution in the valve seat for an outlet valve of a piston-type combustion valve seat, with an additional machine where one is connected to at least one supply line
connected, ring-shaped coolant distribution space
is provided that a number of holes with a
also connect ring-shaped cooling space, of which 45
emanate from removal lines for the heated coolant.