DE308648C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

Among the previously known radiators there are also those which consist of two spirally bent sheet metal strips, which are connected by strips and the like between them. Form the top and bottom closed narrow space of approximately rectangular cross-section as a heating channel. Between these spiral-shaped flat corridors produced in this way, a space corresponding to their spacing is provided for the stay of the liquid to be heated or evaporated. From the outside, the radiator has the appearance of a relaxed clock spring.
■ 'If such a radiator is heated with steam, only the horizontal installation is possible,

'because · only with this the condensate that forms in the heating channel from the heating surfaces as quickly as possible run off, collect on the ground and

· ..; flow towards an exit point with a slight gradient can.

In addition, the wide side of the heating channel should also be used as the height and the upper side should be narrow Side be designated as the thickness. So practical * otherwise such flat spiral heating coils also because of the good circulation of the evaporating liquid and because of the lightness Cleaning options, so far they have had the disadvantage that they evaporate all the more poorly. the wider the heating channels in the. Ratio to their thickness will be about 5: 1, and that at a ratio of around 20: 1, hardly 60 percent of the amount of steam is generated, which, according to the size of the heating surface, is to be expected

■ · ■: ■; -was. ■ '' ■. ■ '■■ ·. ■' ^x ■

The steam flow does not cling to the narrow heating channel, it forms one or more Strands that leave air-filled zones, islands, sacks and the like next to them and thereby release them affect the evaporation at these points outside.

However, it is important to use these radiators in order to create a very large heating surface for a given Base area as high as possible with aisles 500 to 750 mm wide and 10 to 20 mm thick to build because the production costs only grow a little and because then the Radiators with their other properties with low pressure steam, 0.25 to 0.35 atm. Overpressure, which can be easily achieved by throttling ■ exhaust steam or compressing vapors can be produced in vaporizers, can develop vapor well.

According to the present invention, these flat spiral heating elements can be brought to the performance expected from the size of the heating surface by preforming the heating steam flow through the heating steam supply pipe as an Έand with the cross-section and the direction of the channel before it enters the heating channel, and this for displacement of the air is maintained up to the end of the channel by excess steam and one-sided narrowing of the heating channel with finally removal of the ■ excess steam with the condensate. According to the accompanying drawings, FIG. 1 shows the radiator in elevation, FIG. 2 in plan; α and δ 'denote the spirally curved wide heating walls, which

limit the heating duct with the narrow strips c and d on the floor and ceiling. Between the corridors α, b, c, d is't e the space for the evaporation liquid flowing in from below or from the side. For a better understanding of the internal devices, the heating element is shown in a coiled state in FIGS. 3 and 4. The heating steam is fed through pipe f , it condenses on the walls of the heating duct when the heat is emitted, its condensate collects on the floor and runs at the end to a hanging pipe g located here, through which it is conveyed out at the pressure prevailing in the radiator. The narrowest cross-section of this pipe is slightly larger than the amount of condensate, so that air brought along by the heating steam can also be removed, which is shown in the drawing by the in the tube g rising bubbles

is interpreted. ■ ·

In the case of steam ducts, the width of which exceeds the thickness by five times, the heating • Steam does not completely fill the heating duct, so that the air remains and this the effective heating surface is reduced.

In order to force the steam according to the present invention to touch the entire heating surface, the heating steam supply pipe f is guided inside the radiator from the ceiling to the floor and laterally provided with openings j at every height, which are opposite the channel entrance.

A displacer h is installed in pipe f or the pipe cross-section is tapered downwards so that the amount of steam that is as uniform as possible flows out at every altitude. Furthermore, it is necessary to direct this resulting lateral damping flow through the walls of the openings j so that it enters more or less tangential to the walls α, b and parallel to the walls c, d of the heating duct. According to FIG Walls of the openings j for this purpose drilled obliquely or bent obliquely according to FIG the air escapes from the Einhähgerrohr g.

This means only a very small loss because ι kg of steam at z. B. 0.25 atm, overpressure occupies an approximately i35omal larger space than ι kg of water ^ This excess steam strives with the last heating steam long before the end of the channel, in the shortest possible way by detaching from the upper walls and contracting at increased speed To reach drain pipe g ! To avoid 'an air bag on the deserted places, a vapor take-off pipe is further to i. the suspension pipe g is arranged, which also extends almost to the ground and which also has openings k in the direction of the channel at all altitudes (Fig. 7) through which the air and the excess steam can get into the pipe g when pipe i is a little further is protruded as tube g and also the latter a little below. Maintaining the steam band on the entire heating surface also requires a certain horizontal narrowing lm, the channel thickness I, m, after the end, in which, however, condensation and resistance of the heating steam and the amount of excess steam and condensate must be taken into account. With more or less excess steam you are able to avoid harmful deviations: and to bring the radiator to full evaporation even at heights of up to 750 mm and a clear horizontal width (thickness) of 10 to 20 mm, if all means mentioned here be applied.

Claims (7)

Patent Claims: 8S 1. Method for avoiding the accumulation of non-condensing gases, such as air, in winding flat heating ducts or spiral heating elements, characterized in that the steam flow already before entering the heating duct (α, δ, t, ä) through the mouth openings (/ ) of the steamζμ guide tube (f) maintains the cross-section of the heating duct and the direction in it. 2. To carry out the method according to claim I, a heating steam supply pipe (f), characterized in that it is guided transversely to the heating channel to the bottom (c) and that from this extension the heating steam laterally through openings (j) in the jacket into the heating channel is pressed, the walls of these openings through. corresponding position give the steam flow the direction in the duct. 3. To support a uniform lateral exit of the heating steam, the arrangement of a steam displacer Qi) in the steam supply pipe for all heights of the heating duct. 4. In a method according to Claim. 1 · the supply of excess steam in the heating duct with the walls (α, b, c, d), which steam at the end of the heating channel to the non-condensing gases, such as air, carbon dioxide and, the like, is let out again. 5. To carry out the method according to claim 1 and 4, the arrangement of an air and excess steam removal pipe (i) at the end of the Heizkarials with inflow openings in the jacket to maintain the band shape of the heating steam in the heating steam channel. 6. acceptance pipe according to claim 5, characterized by the arrangement of a narrower pipe (g) used in the latter and provided with an opening at the bottom (c) through which the gases collected in the surrounding pipes (i) are pressed out with the condensate to the outside. 7. To carry out the method according to claim 1, a heating channel, which according to his Becomes too narrow at the end. For this purpose ι sheet of drawings.