DE746827C - Self-regulation of the low-pressure steam heating in a vehicle, especially a rail vehicle - Google Patents

Description

The invention relates to a self-regulation of the low-pressure steam heating in a vehicle, in particular a rail vehicle, on which a low-pressure steam boiler is arranged.

In the previous heating systems of this type, not only the low-pressure steam boiler was maintained with automatic devices for steam pressure control or monitoring, for example to equip the furnace or the water refill, etc., but the heating itself was also self-regulating for the steam pressure and thus for the heating surface temperature. Such Systems are multi-part and require a great deal of support from the train escort during commissioning and decommissioning.

The aim of the invention is to create a system that is as simple as possible, which only requires very little maintenance and still has a high degree of operational safety owns.

To solve this problem, the invention regulates itself for self-regulation Heating only the boiler output when the heating is connected to the boiler steam room without the interposition of radiator throttles. Since the performance of the Boiler depends on the strength of its firing and the respective water filling, suitable control devices are arranged for this, which generate the steam of the boiler so that the radiators connected to the boiler steam room always be kept filled with steam. Since the boiler pressure, as was said earlier, fluctuates only within very small limits, so are the fluctuations in the radiator temperature accordingly low.

To regulate the boiler output, for example, one exposed to the steam pressure can be used

Membrane box are arranged, which via a linkage the Heizmittelizufluß to the boiler so controlled that when the steam generation and with it the steam pressure in the boiler increases, the firing increases more and more is throttled. Furthermore, when the water level in the boiler drops to a predetermined minimum, a swimmer can do this open a boiler filler leading from the water storage tank to the boiler room, whereby cold water flows from the storage tank to the boiler until the desired Water level is reached again. In this way the water filling > 5 degrees of the boiler regulated.

The regulation of the degree of firing and the water level can also be effected by a float alone, if this is allowed to act on the boiler firing by mechanical or electrical means in such a way that it turns off the firing when the minimum water level is reached and only turns it on again when by means of make-up of water from the storage tank the highest water level has been reached again. If too much steam is generated, the steam pressure in the boiler increases and lifts water out of the boiler via the riser pipe into the storage tank. The water level drops, and when the minimum water level is reached, the float switches off the furnace and thus the steam generation. At the same time, the float also causes the shut-off element in the boiler filling path to open, whereupon the boiler is refilled up to the maximum water level and the float turns on the firing again. Two forms of embodiment of heating systems according to the invention are shown in general in Figs. 1 , 2 and 3 of the drawing.

In the heating system according to Fig. 1, the low-pressure steam boiler is arranged under the vehicle floor. The lines 31 and i8 connect the steam space of the boiler 1 without the interposition of throttle regulators with the radiators 19, which are to be kept filled with steam at the same pressure as the boiler pressure. The pressure in the boiler is always limited by the height of the riser pipe 5, whereby the shut-off element 6 that controls its passage is for the time being unimaginable. The riser pipe 5 leads from a minimum water level from the point χ U-shaped upwards to above the water level of a water storage container 24.

In the Kesseldampfratim a membrane can 14 is arranged, which with increasing boiler pressure their liquid contents, z. B. glycerine, presses a spring-loaded piston in the cylinder 12 via the line 13 so that the lever 16 is finally pivoted so that it switches off the fuel supply from the container 25 and the line 27 to the burner 29. Fig. 2 shows the cylinder 12 and the lever 16 in a side view. The boiler firing is switched on again when the steam pressure in the boiler drops and the diaphragm box 14 expands. The electrically driven fan 10 supplies the necessary combustion air.

The steam generation regulated in this way can only work appropriately if the boiler water filling is regulated at the same time. The float 2 and a shut-off element 3 are therefore arranged in the boiler filling path 4 leading from the container 24 to the boiler water space. The shut-off element 3 is connected to the float 2 in such a way that the boiler filling path 4 is opened when the boiler water level has dropped to the minimum level.

The heating system works as follows: When it is started up, water is poured into the storage tank 24 poured, and the hand tap 23 in the boiler filling path 4 is opened. The float 2 initially holds the shut-off piston 3 open, and therefore water flows from the container 24 via the filling path 4 to the boiler 1. The fuel is ignited and heats the water. The developing steam drives the air through the lines 31 and iS via the heating elements 19 and the open steam water drains arranged at their drainage points. The connected radiators fill with steam, and finally it turns on a pressure in the system which is determined by the height of the riser pipe 5. Increases the pressure in the boiler 1, the diaphragm box 14 is compressed and acts over the linkage 13, 12, 16 throttling on the Add fuel.

When water evaporates, the boiler water level drops. Also can under Circumstances due to the pressure in the boiler 1 water via the riser 5 into the container 24 to be lifted up. When the minimum water level is reached, the opens Float 2 the shut-off element 3, and cold water flows out of the reservoir no 24 into boiler 1 until the maximum water level is reached again is reached. These repetitive processes ensure that the boiler output is regulated in the sense that that the heating is kept regulated with steam.

The precipitation water flowing out of the radiators via the aforementioned steam drains leads the collecting line 20 into the container 15, from which it is via the line 36, the pump 11 and the line 35 is pumped back into the boiler.

33 is the mandatory safety valve. 7 and 8 are drain valves for the water after the system has been shut down. These two valves can be connected to the shut-off valve g so that, when this is closed, the two valves 8 and 9 open and drain the water into the open, thus providing security against freezing of the. Plant is created. The ίο .Hahn 23 is expediently closed when it is shut down in order to be able to hold back the water in the container 24, which is also used for other purposes. This is useful when the 5 radiators 19 are connected through the line 32 to the locomotive steam leading under the vehicle line 30 to operate the heating with high pressure steam from this line. The tap 23 can also be brought into such a position that the water flows off via the line 37, which is useful when the car is completely shut down in the cold season.

If many radiators 19 are to be supplied with steam, it is possible that the pressure is not sufficient because the vehicle height in the riser 5 is limited. In this case it is advantageous to install a shut-off member 6 in the riser pipe 5, which with the float 2 is tied in such a way that the riser pipe is only opened when the minimum water level is reached 5 is opened by the shut-off member 6 to prevent the water from flowing out of the container 24 via the open at the same time To reach boiler filling path 4.

In the heating system according to Fig. 3, sot Probably the regulation of the water level as well as that of the boiler is taken care of by the float 2 ". This is in one to den.Kessel ι attached Ratim between Springs 55 and makes when the water level fluctuates between the permitted Limits only a short distance from z. B.

10 mm.

It acts on a bridge contact switch45 through a rod attached to its upper end. Both the boiler firing and the shut-off element 40 in the water refill path 47, 4 are controlled electrically here. The "control current" is supplied by the battery 41 via the main switch 42 and the auxiliary automatic switch 46. When the maximum water level h max · is reached , the bridge contact switch 45 switches over so that the solenoid valve 40 is de-energized and the boiler _{filling path 47, 4 is blocked.} ie the fuel supply to the burner 29, which takes place from the container 25 ″ with an electrically driven pump, is opened and the fan 10, which is expediently driven by the same motor as the pump, is switched on.

After the boiler water level has dropped to the minimum height h _min , the bridge contact switch 45 is switched over, the circuit being closed via the solenoid valve 40 and this opening. At the same time, the burner 29 is switched off and water flows from the container 24 to the boiler 1. The riser pipe here forms the pipe socket 56 together with the part 4 of the boiler filling path and the Rahrteil 4 'adjoining it at the top, which opens into the container 24 above the water level. To simplify the return of the precipitation water that forms in the heating element 19 to the boiler, the return line 48 falling to the boiler 1 is arranged.

The further -in the drawing basically Auxiliary facilities shown are described at the same time as the mode of operation of the system.

The start-up takes place again by filling water into the container 24 and of the fuel into the container 25. After closing the main switch 42 opens the solenoid valve 40 by control current closure and lets water through the boiler filling path 47, 4 drain to boiler 1. At the same time, some water flows over the still open, at the bottom of the Kettle attached drain valve 44 to the outside. However, this is under the influence a thermostat 43, which it after heating by a heating coil in a short time closes.

If the boiler 1 is filled to the level h _max , the float 2 switches the bridge contact switch 45 and interrupts the control circuit of the valve 40, and this closes. At the same time, the control circuit of the burner motor is switched on via the auxiliary switch 46, the furnace starts up and evaporation begins. The steam flows through the line 31 to the radiators 19 and presses the air out of the system via a valve 50 which is also thermostatically controlled and is still open. After the thermostat has been heated by the steam, the valve 50 is closed. The same pressure now prevails in the radiators 19 and in the return line 48 as in the boiler 1.

In the riser pipe 4, 4 ', a column of water appears as the boiler pressure increases. Increases If the boiler pressure exceeds the riser pipe height, water is lifted into the container 24. Because the water level drops as a result, the float 2 · aJb, to also falls when reaching the minimum water level /; ",, ·" the control circuit of the burner

engine turns off and the circuit of valve 40 closes. The flame goes out, that Valve 40 opens, and cold water flows to the boiler water space and prevents it further increase in boiler pressure.

If this continues to rise anyway, when the boiler water level falls below the lowest level, the boiler water level will be the steam through the connecting line 56 counter to that from the valve to 40 outflowing water blown through the pipe 4, 4 '. The processes described repeat themselves in constant change, the radiators 19 with low-pressure steam evenly be kept fulfilled. '5 In the Hes Motors control circuit for the Fuel pump and the fan 10 is also a time and with the auxiliary switch 46 Circuit breaker 51 connected in series. When the heater is switched on, it is initially closed. After about a minute after its temperature sensor 51 ', especially an expansion or bimetallic body, which is arranged in the chimney flue 52 of the furnace, has warmed up, it interrupts the protective circuit, while the control circuit for the motor remains switched on. Is created at the burner 29 z. B. due to lack of fuel in the container 25 or No flame due to blocked nozzles, the circuit breaker interrupts the control current and turns off the engine. A control lamp 53 shows this faulty by lighting State on.

The boiler firing can also be regulated as a function of the temperature of the heated room. At a corresponding point in the room, the room temperature sensor 54 is arranged, which acts on the circuit of the motor for the burner 29 and the fan 10 in such a way that the furnace when a room temperature is reached% ^r on z. B. 20 ° C is turned off. If the temperature in the courageous room falls again, for example to 19 ⁰ C, the sensor ♦ 5 54 switches the burner on again.

Claims (5)

Patent claims: i. Self-regulation of the low-pressure steam heating in a vehicle, in particular Rail vehicle with a low-pressure steam boiler, characterized by only self-regulation of the boiler output and connection of the radiators to the boiler steam room without the interposition of radiator throttles, if necessary also return of the rainwater with a gradient to the boiler water room. 2. Self-regulation according to claim 1, characterized by a diaphragm box (14) which is exposed to the steam pressure of the boiler and which controls the flow of heating medium to the boiler via a linkage (13, 12, 16). 3. Self-regulation according to claim 1 and 2, characterized by a float (2), the boiler filling path after the boiler water level has dropped to a minimum (4) from a water storage tank (24) to the boiler (1) opens (Fig. 1). 4. Self-regulation according to claim 3, characterized in that when it is reached of the minimum water level of the float (2) there is also a shut-off element (6) in the one leading away from the minimum water level Riser pipe (5) opens (Fig. 1). 5. Self-regulation according to claim 1, characterized by a float (2) which mechanically or electrically switches off the boiler when the minimum water level (h, _n ; ") is reached and a shut-off element (40) in the boiler filling path (4, 47) opens, but when Reaching the maximum water level (h _max ) has the opposite effect (Fig. 3). To distinguish the subject of the application from the state of the art, the the following publications have been considered: German patent specification No. 94 094, 410 194, 608281, 611744, 633362, 633363, 668665; USA. Patents .... \. No. 489 141, ι 022 032, ι 036 827, ζ 065 285. For this purpose ι sheet of drawings