DE83912C - - Google Patents

Description

IMPERIAL

PATENT OFFICE. \ t

The effect of systems for heating with exhaust steam could be increased by the fact that the exhaust steam, before it enters the plant, is passed through regenerators, which in housed the fire trains of the steam boiler and heated there by the evacuating fire gases will. But this arrangement has the disadvantage that it has an unequal effect the heating system can occur if, on the one hand, the amount of heat to be consumed and, on the other hand, that from the exhaust gases from the boiler the amount of heat to be given off is different. In the case of the present system, a perfect Compensation can be achieved.

For this purpose, it is not the exhaust steam, but the live steam from the boiler that is passed through the Regenerator passed, in the latter overheated and in this state for heating the exhaust steam used. In this way, compensation occurs to the extent that it comes from the boiler more steam flows in, "if the overheated live steam due to increased heat consumption must give off more heat, and vice versa. Since the voltage in the boiler is now is to be assumed constant, an approximately constant temperature of the exhaust steam will also be to be expected in the heating system. The use of live steam is less of a concern than in many industries, z. B. the sugar industry, live steam in general is used for heating purposes.

The exhaust steam is passed through a steam collector S to the points of use, which are indicated in the drawing by the evaporation devices V ¹ V ' ² and the drying devices T ¹ T- (FIG. 3). The live steam passes from the boiler K through the valve DV into the pipe R and from here through the pipe R ^B to the regenerator E ¹ E '*, .. in which the overheating takes place. The latter is expediently arranged in such a way that it is heated by the exhaust gases from the boiler firing emerging through the fox, thereby ensuring that the firing material is used to a large extent. From the regenerator, the superheated live steam flows through the pipe R ² into the thin tubes of the exhaust steam collector S, which provide the heating surfaces for the exhaust steam circulating around them. The live steam already cooled in the exhaust steam collector goes to further apparatus A ¹ A ² , to which heat is to be given off, and where it is cooled down until it is compressed. The steam water collects in the container A and can be brought back from here after opening the tap C ¹ through the line B into the boiler. Instead of tap C ¹ , a steam water drain C specially designed for this purpose can be switched on.

Is in the exhaust steam collector due to increased heat demand from the overheated Live steam emits an amount of heat exceeding the normal amount, then occurs Voltage drop of the live steam in the steam collector, and live steam will continue to flow from the boiler as long as until a settlement has taken place. The same process takes place when in the fire puffs the heat of the exhaust gases is not sufficient,

to achieve normal overheating of the live steam. In this case, even with normal heat emission in the exhaust steam collector S, the voltage will decrease, which again results in an increased flow of live steam from the boiler.

, Instead of the apparatus of FIG ι is the following apply:. The container A along with line B comes in omission, and the tube R ¹ is converted directly into the tube R ^3. The effect will be essentially the same. If the line B is dimensioned accordingly, the tap C can be dispensed with, since an uninterrupted water flow through the line B then sinks. It is clear that in this case line B can also be omitted, that is to say, in other words, that pipe R ^{1 should} pass directly into pipe i? ^{3 is} possible. However, the steam water is now not returned to the boiler, but instead passes directly into the regenerator. The circulation remains secured, however, since the live steam coming from R will only ever go to the regenerator because the pressure of the water falling from above does not allow the steam to rise.

With the device just described, the entire system can expediently be dimensioned in such a way that normally no live steam enters from the boiler K , ie that valve DV is closed during normal heat emission. In this case, only the superheated steam obtained in the regenerator by evaporation of the steam water and overheating of the steam is used to heat the exhaust steam. Only when the heat output is increased does the valve DV open and fresh boiler steam flows in.

But since, conversely, too high a voltage within the line for the live steam can occur if z. If, for example, the heating in the regenerator becomes too high when the heat requirement is minimal, if the water content is sufficient, a device must also be present in order to prevent excessive stresses, which in this case also ensures a connection with the boiler. The peculiarly constructed valve DV (Fig. 2) is provided for this purpose. It consists of two valves, one of which opens after the boiler, the other after the pipe. The latter has the purpose of opening in the case of a negative pressure in the heating system and admitting fresh boiler steam, while the former has the purpose of opening in the case of overpressure in the heating system in order to establish a connection with the inside of the boiler. Usually, ie with normal heat emission, both valves are closed. This double valve thus brings about the tension equalization for each case.

Claims (1)

Patent claim: ■ ■ .. ■ ..; Exhaust steam heating system, characterized in that the exhaust steam by means of one with the Steam boiler at both ends communicating high pressure line, into which fitting a regenerator heated by flue gases is switched on, is heated in such a way that at normal heat emission from the boiler by means of a suitable regulating device from the high-pressure line is completed, but that live steam if the heating system is used more frequently from the steam boiler enters the high-pressure line and heats the exhaust steam, for the purpose, in this way a completely to achieve a uniform heating effect. 1 sheet of drawings.