DE288131C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVe 288131 - CLASS 36 c. GROUP

RUDOLF FIALA in VIENNA, Austria.

Patented in the German Empire on July 16, 1914.

The subject of the invention relates to such heating systems connected to temperature regulators, in which a constant circulation of steam through the system is generated with the aid of a jet nozzle and live steam is only added to the extent necessary to maintain the circuit and replace the condensate.
The subject of the invention differs from the similar devices known so far in that the regulator influenced by the return steam influences not only the cross section of the jet nozzle, but also its suction cross section, whereby not only the amount of live steam supplied to the line, but also that of the entrained steam Return steam is adapted to the respective temperature of the heating steam.
Another the subject of the invention

A further improvement lies in the arrangement of a pressure reducing device at the transition point the return steam line in the return steam tank, so that the prevailing in the latter Pressure is reduced to a certain minimum; as a result of this pressure reduction The re-evaporation of the condensate does not take place after the drain from the steam tank, as in previous systems, but still held in the container itself, so that the entire, bound in the post-evaporation Heat can be used again for heating purposes.

The prevailing pressure in the container can be due to the arrangement made in certain Cases are also below atmospheric pressure; according to the invention is in these The condensate trap built into the condensate drainage system falls through one of its lower end provided with a non-return valve downpipe of such length replaced that the Pressure of the water column created above the check valve, increased by the tank pressure, exceeds atmospheric pressure, causing the water to be periodically expelled from the container.

Fig. Ι of the drawing shows a vertical section through one of the invention executed according to Steam heating system in working position.

Fig. 2 shows the position of the injector and regulator in the initial position.

FIG. 3 is a horizontal section along AA of FIG. 1.

The circulation device consists of the re-steam tank h, at the lowest point of which a condensation trap or the downpipe k closed by a check valve s is connected. Above the container h there is a jet nozzle, the suction chamber u of which is connected to the nozzle f of the container h, the transition nozzle w of which is connected to the heating line and the housing part ζ connected to the suction chamber is connected to the main steam line through the nozzle b. The regulation of the cross-section of the steam nozzle q and of the cross-section lying between the latter and the suction nozzle υ is carried out by moving the steam-tightly guided nozzle q in the housing part ζ on the

wall 7 of the injector housing rigidly attached needle p.

The movement required for this regulation is given to the steam nozzle q by a temperature controller of any type, e.g. B. through the curved tube in which is arranged in a housing c through which the return steam flows; the right end of this tube m is connected through the tube ο with the screwable spindle y in the housing wall, while the left, freely movable end is attached to a spindle η guided in the tube ο , which extends through the wall 7 into the injector housing and in the same carries a fork 8 on which the injector nozzle q sits. The housing c of the controller carries two nozzles d, g, of which nozzle d connects to the return steam line, nozzle g connects to the tube i leading into the return steam container h , which is closed off from the container by a pressure reducing valve α ; behind the mouth of the latter, a condensation separator t of known design is arranged in the container h.
The steam nozzle is q at the start of heating by screwing the spindle y to the position shown in Fig. 2 position set, in which its circumferential surface υ adjoins the inner surface of the suction nozzle, h whereby the connection between the steam container and the suction space u is interrupted. When the steam line is opened, the live steam flows in the direction of arrows 1 and 2 through the nozzle b and the nozzle q into the nozzle w connected to the heating line, entraining the air drawn in through the valve r.

After flowing through the heating system, the steam arrives in the direction of arrow 3 in the controller housing c and from there through the pressure reducing valve α and the condensate separator t into the container h.

Since, as mentioned above, when the heating begins, the suction chamber u of the injector is blocked from the nozzle w by the steam nozzle q , the condensates entering the container h in large quantities at the beginning of the heating cannot be sucked in by the injector; Only when the entire system is at a certain temperature and the steam flowing back into the container h approaches the temperature set during operation does the controller m come into action and pull the steam nozzle q out of its blocking position into that shown in FIG Position, which on the one hand reduces the effective cross section of the steam nozzle q and on the other hand also establishes the connection between the suction chamber u and the nozzle w of the injector, matt steam and condensate vapors from the container h through the. Live steam can be sucked in and fed back into the heating cable.

The regulating activity of the injector is twofold; because the displacement of the nozzle q under the influence of the matt steam temperature through the pipe m not only regulates the amount of live steam flowing through the nozzle q , but also the suction cross-section of the injector and thus the quantity of the matt steam that is carried away from the container h, whereby the lowest possible pressure is obtained in the container h.

The same purpose of achieving the lowest possible pressure in the container h and therefore also the greatest possible re-evaporation of the condensates in this container is also served by the pressure reducing valve a arranged at the mouth of the return steam line.

If the exhaust steam were allowed to reach the steam container h directly, the hot condensate, which is at the temperature of the steam, would only evaporate slightly there and would have to be discharged from the container h at this high temperature; the post-evaporation would then only occur outside of the container h , whereby all the heat bound in the post-steam would be lost for the heating.

Through the interaction of the pressure reducing valve α with the regulating activity of the injector, if these parts are set correctly , the pressure in the container h can be brought to a certain minimum. As a result of this low pressure, the entire post-evaporation of the hot condensate takes place in the container h , and the entire amount of heat bound in this post-steam is returned to the heating line because this steam is sucked in by the injector.

Another advantage offered by the negative pressure prevailing in the container h is that the arrangement of a condensate trap adjoining the latter can be omitted. It is sufficient if a downwardly reaching downpipe k is arranged at the lowest point of the container k , which is provided at its lower mouth with an outwardly opening check valve s; the height of this downpipe k must be chosen so that the pressure of the water column forming in the downpipe k periodically becomes large enough to periodically open the check valve s and allow the condensate to flow away , combined with the negative pressure prevailing in the container h.

In order to draw attention to the incorrect position of the regulator or pressure reducing valve in the event of a rise in temperature, an alarm device is provided on the re-steam tank h , which is activated when the maximum pressure that is most advantageous for the system is exceeded; these

The alarm device can consist of a spring-loaded adjustable valve 9 in a known manner and a steam whistle attached to it.

Claims (5)

Patent Claims: i. Steam heating system in which the steam circulates continuously through the system is generated with the help of a jet nozzle, the cross-section of which is through one of the return steam influenced controller is determined, characterized in that the controller also influences the effective suction cross section of the return steam nozzle. 2. Embodiment of the device according to claim 1, characterized in that the steam nozzle (q ) comprising a stationary needle (p) is arranged displaceably in the likewise stationary suction nozzle and is connected to the controller (m) , so that the movement of the controller between the inner surface of the steam nozzle (q) and the needle (p) as well as the cross section between the outer surface of the steam nozzle (q) and the suction nozzle (w) can be changed at the same time. 3. In a device according to claim 1, the arrangement of a relaxation device (a) between the steam return line (i) and the re-steam tank (A), through which the re-evaporation of the condensate is caused in the container (A). 4. In a device according to claim 1 to 3, the arrangement that at the lowest point of the re-steam tank (A) has a non-return valve (s) at its lower end Downpipe (Ä) is arranged, the height of which is chosen so that the pressure in the Downpipe resulting water column, increased by that in the container (A) Pressure that can overcome atmospheric pressure. 5. In a device according to claim 1, the arrangement of a condensate separator (t) at the mouth of the return steam line (i) in the return steam container (A). 1 sheet of drawings.