DE396877C - Combined heat and power system - Google Patents

Description

Combined heat and power system. The invention relates to combined heat and power systems, in-those behind, the superheater a heat accumulator for low pressure in the from the hot gases flowing off from the superheaters. In such systems, the high pressure steam can only be used to advantage in the amount that is adapted to the performance. at With a lower output, only a smaller amount of steam can enter the low-pressure accumulator trespass; if not reduced by boiler voltage, boiler steam to. Low pressure accumulator is allowed, which would be very uneconomical.

The invention overcomes this deficiency in that the high pressure steam is stored on its own, namely in a known high-pressure storage device, that in the withdrawing hot gas flow between the 'superheaters and the low-pressure accumulator and, with regard to the steam routing, lies between the boiler and the heaters. Through this it is possible to introduce the boiler steam into the high-pressure accumulator without throttling.

An exemplary embodiment is shown in the drawing.

The jacket superheater socket r connects to the high-pressure boiler a, in which the hot gases first flow through the high-pressure steam superheater b and then through the post-superheater f for exhaust steam. The superheated boiler steam goes through the line cl to the high pressure cylinder d and from here back to the exhaust steam or intermediate steam superheater f, from where. it is passed through the line la to the low-pressure cylinder i . At l , a line branches off from line h, which leads the exhaust steam or intermediate steam to a low-pressure heat accumulator k, which is heated by the heating gases flowing through the channels v1. A high-pressure steam accumulator ki is connected between the superheaters and the low-pressure steam accumulator k. .

With regard to its steam routing, the high-pressure steam accumulator is intermediate Boiler a and superheater b switched on because it -received through line q the pipeline leading from the boiler to the t% heater b. u saturated steam and passes through the (line turns off the same pipe and steam again.

If the power requirement changes, this arrangement has particular advantages. If the performance is low, then. flows through both superheaters b. and f only a small amount of steam. There is thus a larger amount of saturated steam from the boiler a available for storage in the high-pressure heat accumulator kl, and this steam is fed through the lines u and q to the accumulator in the lower part. In this way, the boiler can be loaded evenly, since the sum of steam output for power generation and storage can always remain the same. Under these conditions, the temperature of the hot gases withdrawn from the boiler is always the same. The amount of steam flowing through the superheater is small and draws little heat from the heating gases. The heating gases leave the superheater at a higher temperature and can consequently have a stronger effect on the heat accumulator.

With high power output, no steam is stored at all, but the steam from the heat accumulators is fed to the superheaters. Take the superheaters larger amounts of heat from the heating gases and cool them down. Hence is then the effect of the heating gases on the heat accumulator because of their lower temperature reduced. This reduction is harmless if there is no steam storage takes place.

Superheaters and high-pressure accumulators thus form an automatic one, so to speak Control device for the uniform utilization of the heating gases. Your greater exploitation the superheater b corresponds to their lower utilization by the high-pressure heat accumulator k, and vice versa.

The temperature of the heating gases for the low-pressure device k therefore remains almost the same in all cases of fluctuating power requirements, and this is essential because this system is preferably intended to compensate for force fluctuations.

Claims (1)

PATEN T-AxSPRUcIi combined heat and power steam engine system with superheater connectors and a low-pressure and intermediate steam heat accumulator, which is arranged behind the merheater and which absorbs the heating gases flowing out of it, characterized by a high-pressure steam accumulator (k,) of a known type, which is in the withdrawing heating gas flow between the superheater (b) and the low-pressure accumulator (k) lies between the superheater (b) and the boiler (a) with regard to the steam supply and takes up the high-pressure steam from this as saturated steam for storage.