DE258378C - - Google Patents

Description

IMPERIAL

PATENT OFFICE

The subject matter of the present invention is a device for rapid pressure-free closing of the nozzle of free-jet high-pressure turbines with needle control.
The operating conditions of a modern electrical power station require the turbines to be adapted to the respective load condition of the generators as quickly as possible. That is why the turbines have to move very quickly

ίο effective speed control provided which, however, generate dangerous pressure increases when the turbines are closed. Since then, attempts have been made to avoid these pressure increases by using special pressure regulators.

The present device for the rapid, pressure-free closing of free-jet high-pressure turbines with needle control also avoids these pressure increases, achieves this but by a far simpler construction.

The combination of pressure control with speed control is new and peculiar in the nozzle manifold including the control port (see Fig. 2, 5 and 6) or the nozzle adapter (see Fig. 1, 2, 3 and 4) or the nozzle of high-pressure free jet turbines with needle control.

From Fig. I, 2 and 3, a type of control can be seen. Point 1 is the attack of the controller, whose movements by the double lever 2 and the tabs 3 on the Needle shaft 4 are transferred. In certain cases the regulator can also be used as a water pressure regulator be formed, or the oil pressure regulator can also be used without the interposition of Double lever and tabs act directly on needle shaft 4. The latter wears the Piston 5 of a liquid brake 6, the housing 7 of which is slidable in the connector 8 of the Inlet manifold 9 is mounted. Furthermore, the housing 7 is the liquid brake 6 still rigidly connected, on the one hand, to the push-back piston 10 and, on the other hand, able the rods 11 with the idle slide 12, which is shown in Figs. 1 and 3, for example is arranged outside the nozzle adapter. This idle slide can also arranged inside the nozzle adapter (see. Fig. 4) or the nozzle itself be; it can also be attached directly to the control port, either as an outer slide, as illustrated by FIG. 5, for example, or as inner slide (see. Fig. 6). As long as the liquid in the space 15 behind the Piston 5 of the brake 6 is completely enclosed, the parts 17 and 12 are rigid connected with each other; the needle 17 as well as the slide 12 follow the same time Final movements of the regulator, in which the slide 12 to pressure surges in the pipeline to avoid simultaneously allowing as much water to escape through the openings 16, how the needle 17 closes. But in order to avoid wasting water, you have to do it be ensured that the slide 12 is closed again in a controllable time. this is made possible by the retraction piston 10 and the small overflow opening 18 of the fluid brake 6. As soon as the idle slide 12 has moved away from its seat 20, seeks the water pressure acting on the retraction piston to close it again, namely

the speed at which this closing process takes place depends on the extent in which the opening 18 allows liquid to escape. This speed can therefore go through Increasing or reducing the opening 18 can be regulated.

During an opening process, the slide 12 remains closed, and the rapid movement the needle 17 is made possible by an overflow valve 21 in the space 22 no Creates pressure. This overflow valve 21 is shown in all figures, for example arranged on the piston 5, but can also be arranged on the cylinder 7.

The regulation process takes place in the described regulation as follows:

The turbine is relieved; so the regulator closes. Because this regulation movement happens very quickly, the liquid in space 15 has no time to to escape through the small opening 18; there is pressure there, which the fluid brake body 7 together with the slide linkage 11 moved to the right, whereby the Idle slide 12 is opened. If the closing movement of the controller has now ended, then so serves the needle shaft 4 with the fluid brake piston 5 as an abutment, and the Water pressure on the retraction piston 10 closes the idle valve 12 to the extent that than the liquid can escape from space 15 into space 22 ..

opens the turbine, the slide 12 is prevented by the seat 20 from moving. Furthermore, since the fluid brake 6 by virtue of the overflow valve 21 an opening movement If there is no resistance, the needle can follow the opening movements of the regulator unhindered.

Claims (5)

Patent Claims: 1. Regulation of free-jet high-pressure turbines with a needle, characterized in that that both speed and pressure control in the nozzle manifold, including the nozzle adapter, the nozzle or the control connection of the nozzle manifold, are housed in such a way, that when regulating the turbine, the idle slide valve from the body of a fluid brake, the piston of which is fixed is connected to the needle shaft, is moved directly or with the interposition of a lever transmission. 2. Apparatus according to claim 1, wherein the idle slide as an outer Nozzle slide (Fig. 1, 2 and 3) is formed. 3. Apparatus according to claim 1, wherein the idle slide as an outer Slider of the control port (Fig. 2 and 5) is formed. 4. Apparatus according to claim 1, wherein the idle slide as an inner Nozzle slide (Fig. 2 and 4) is designed such that the slide and the needle cross, which is used to guide the needle serves, are united. 5. The device of claim 1, wherein the idle slide as an inner Slide of the control port (Fig. 2 and 6) is formed. 1 sheet of drawings.