DE605126C - Boiler blow-down device, consisting of blow-down valve and emergency shut-off piston - Google Patents

Description

The blowdown device is a particularly highly stressed part of the boiler's equipment because not like with other valves or the like. Steam or pure water flows through it, but an emery mud broth that also contains pieces of scale. There this mud broth through at a high speed of 30 to 40 m per second the valve flows through it, while with other valves only water velocities of about ι occur up to 2 m per second, there is an unusually high rate with blowdown valves Stress on the sealing surfaces instead, and there is an increased risk of Leaks. However, especially with a blow-down device, it is very dangerous if it leaks because the boiler can then run dry. To prevent the heating surfaces or In such cases, to prevent a boiler explosion, the fire must be torn out immediately and the boiler will be shut down, resulting in considerable malfunctions and costs connected is.

Emergency shut-off devices have already become known, through which also from below such a blowdown device can be completed, in which the actual blowdown valve is constructed so that the main shut-off means used for blowdown can be removed from the housing. If the emergency shut-off device is closed, this shut-off device can even be used pressurized boiler can be removed so that it can be repaired at any time is.

However, these known designs have the disadvantage that the final safety of the emergency shut-off device is not reliable. It must be taken into account that such an emergency shut-off device is only very rarely used once, Perhaps only once every year, since it is only then in operation occurs when any failure occurs in the master shut-off valve. Experience has shown that it crusts now over time on the sealing surfaces of the emergency shut-off device Kesselstein and the sealing surfaces are also corroded by chemical effects, so that in the event of an emergency such an emergency shut-off device does not even provide a tight seal is to be brought and the intended effect cannot be achieved.

The present invention avoids these difficulties in that the emergency shut-off piston is provided with a blade-shaped, sharp sealing ring, which consists of a very hard, corrosion-resistant building material. Is according to the invention on the other hand, the sealing surface, against which the emergency shut-off piston seals, consists of one soft building material, in which the hard, sharp edge of the sealing ring of the Pressing in the emergency shut-off device deeply. This training ensures that encrusted Scale is simply cut through smoothly and is also removed by corrosion.

^v any serrations of the sharp sealing ring are harmless, as the edge presses into the soft sealing ring, which compensates for the unevenness caused by corrosion. So that the encrusted scale is easily cut through, the sealing edge of the sharp sealing ring on the emergency shut-off piston is designed with an acute flank angle, so that there is a cutting effect.

A design is already known in which a shut-off valve with a sealing ring great hardness is provided, which has a sharp edge, but is with this known execution, the flank is not acute-angled, but executed at right angles and no soft counter seal available.

In Fig. 1, an embodiment of this invention is shown, α is the housing of the Abschlammventües, c the main shut-off means designed as a valve cone in this example and b the associated seat. This main shut-off means is operated in the usual way, either by threaded spindle or by operating lever. Instead of the valve cone, a slide or some other locking device can of course also be selected as the main shut-off means. According to the invention, the emergency closure is now arranged below the main shut-off means or in front of it, which in this example consists of a piston-like valve cone β, the threaded spindle h and the cover i . The piston-like valve cone e, which is prevented from rotating by a guide groove g, can be moved axially up and down by means of the threaded spindle h. If the main blow-down valve, i.e. the cone c, is leaky, the valve cone e of the emergency closure is screwed up by means of the threaded spindle h and pressed against its sealing surface d. He then takes over the sealing of the valve without it being necessary to put the boiler out of operation. If such an emergency seal is only put into operation in exceptional cases, i.e. when a leak has occurred, it is normally unused and exposed to the influence of the sludge and the boiler water which forms the scale. So that a tight seal can be achieved even when the sealing surfaces are encrusted with scale and sludge, the piston-like valve cone e is provided according to the invention with a blade-shaped sealing ring f. The sealing ring f consists of a hard special building material of more than glass hardness, so that when the valve cone e is screwed on, this knife-edge seal cuts encrusted scale smoothly. This effect is supported by the fact that the seat d of the emergency seal consists of a soft bronze so that the sharp sealing edge of the ring f can press into the seat. In this way, a completely perfect, tight seal is achieved even with encrusted sealing surfaces.

The piston-like design of the valve cone of the emergency shut-off device has the advantage that the interior of the shut-off device, that is to say the threaded spindle, etc., is protected from siltation. A further protection against silting is achieved according to the invention in that the emergency shut-off cone e is provided with a rear sealing surface k which, when the emergency shut-off device is open, i.e. when the emergency shut-off cone is withdrawn, blocks the interior from the sludge water. Since the interior is removed from the effects of the sludge, the emergency shut-off device is always operational.

In Fig. 2 is a further embodiment of the emergency shut-off device according to Invention shown in application to a locomotive blowdown device. at a Lokomotivabschlammvorrichtung require the tight space conditions special structural measures. It can therefore not be the emergency shut-off device in the same Install in the same way as with blowdown devices for stationary boilers. In the case of the one shown in Fig. 2 The embodiment is therefore the actual valve housing, which is the main shut-off means contains, combined with a manifold which is part of the valve housing, in which the valve cone of the main blowdown device dips into the cavity of the manifold. In this case, according to the invention, the emergency shut-off device is on the main shut-off cone opposite side arranged in the manifold, in such a way that when withdrawn Emergency shut-off cone no obstruction of the flowing sludge jet occurs. How the emergency shut-off device works is otherwise the same as described in Fig. 1.

Fig. 3 shows a further embodiment in which the main shut-off means is inserted into the housing in such a way that it can be removed from the valve housing after closing the emergency lock at full boiler pressure. For this purpose an insert I is provided which seals against the valve housing a. The seat d of the emergency seal is located in the partition wall of the valve housing a, so it is independent of the insert I,

Fig. 4 shows how the main shut-off device is removed when the emergency lock is closed while the boiler is under pressure. It can then be repaired the main shut-off device during operation, so that it is no longer necessary is to shut down the boiler.

Claims (1)

Claim: Boiler shut-off device, consisting of a blow-down valve and emergency shut-off piston, characterized in that the sealing ring of the emergency shut-off piston with a acute flank angle of the sealing edge and made of a building material of particular hardness and the seat ring of the emergency shut-off device are made of a soft building material, in which the hard, sharp edge of the sealing ring can be pressed deeply. For this purpose I sheet drawings