DE50049C - Chamber boiler - Google Patents

Description

IMPERIAL

PATENT OFFICE.

Chamber boiler.

In order to create a large evaporation surface for the heating surface of the boiler tubes the setup described below must be made.

Chamber AA , Figs. 1 to 5, is in direct connection with its full cross-section with a comparatively large cylindrical upper chamber B, the axis of which (viewed in outline) lies perpendicular to the tube bundle, and the axial extent of which is equal to or greater than the width of the chamber. The partition C of the chamber A is extended through the upper boiler B and is interrupted at χ χ , Fig. 2, 4 and 5. In the immediate extension of the chamber A itself there are funnels D D, which are open at the top and bottom, and their top edge is slightly above the highest water level. Only at one point at yy is a funnel wall made lower, and in such a way that its upper edge, Figs. 1 and 3, lies below the lowest water level.

The circulation of the water is now as follows in Fig. 1 and 2: The water that has entered the feed pipe flows around the steam funnel D, which protrudes above the water level, in the right half of the upper boiler B , and enters the left half of the at χ χ through the interrupted partition C Upper boiler and flows, flowing around the funnel, over the low funnel wall yy into the water half of chamber A. From this the narrow circulation pipes lead the water into the boiler pipes, where the evaporation takes place. From the latter the steam and the water carrying the steam rise into the steam part of chamber A and are passed through the steam funnel to above the water level. The steam now passes from the right half of the upper boiler B through χ to the left half, at the other end of which the steam is withdrawn to the dome (dotted in the outline of Fig. 2).

In order to enlarge the water and steam space of the upper boiler B , it can be connected to one, two or more upper kettles EE lying perpendicular to it, Figs. 3 to 5, which either communicate directly with it, or their water and steam spaces (as in Fig 3 indicated by dotted lines) are connected to B by pipes. These upper boilers EE can either, FIG. 4, only with B, or also, FIG. 5, communicate with each other through connecting stubs F. The water and steam circulation indicated by the arrows is achieved through a wall G built into the upper boiler jB and through the wall H attached in E. The purpose of the long water and steam paths is to deposit the scale in the upper kettles BB and EE and to ensure that the steam is well dried. In two-chamber boilers, too, as shown in FIG. 6, the chambers AA with their full cross-section are in direct connection with upper boilers BB , the front of which receives the steam funnel D protruding above the water level, while the rear one is provided with the low water funnel

through the edges of which the feed water enters the pipe system. In two-chamber boilers, the steam chambers of the upper boilers BB can communicate through one or more connecting stubs, or, as shown in dotted lines in Fig. 6, the water and steam chambers of the upper boilers BB are connected by correspondingly wide stubs JJ . The arrangement of one or more upper boilers jB, which run parallel to one another, is also possible in single-chamber boilers, in a manner similar to that shown in FIG. 6 for two-chamber boilers. The upper boilers BB and EE, as well as the connecting pieces F and / J can be coated with the heating gases as well as be withdrawn from the effects of the fire.

Claims (1)

Patent claim: On chamber kettles with a partition of the chamber by a separating plate (C) that accommodates the circulation tubes and continues in the upper chamber: one funnel (D) on each side of this plate, which forms an extension of the chamber wall and, with the exception of one narrow side, only extends to the lowest water level, goes up to the ■ highest water level. For this purpose ι sheet of drawings.