HU195687B - Apparatus for superpressure steam systems for supplying the condensed water of forward steam conduit into return water conduit - Google Patents

Abstract

The invention relates to an apparatus for super-pressurized steam systems, for feeding the condensed water of a forward-going steam pipe 1 into a returning drain pipe and thus for increasing the efficiency of the heat utilization of the heat system. A water collector 2 arranged at the dewatering points of the forward-going steam pipe is in communication via condensation fittings provided with control means with the input of a heat and pressure reducing tank, and the steam system is provided with a returning drain duct. The heat and pressure reduction takes place in a buffer tank 10 at the bottom of which there is an outlet coupled to one branch of the heat- exchanger 9 which is connected to a drain pipe 8 at a connection point 13 formed downstream of the heat- exchanger 9 as viewed in the direction of flow of the condensed water. The drain pipe 8 is passed through the other branch of the heat- exchanger 9 in heat exchange with the condensed water. <IMAGE>

Description

The present invention relates to an apparatus for a pressurized steam system for supplying condensate from a forward steam conduit to a return condensate conduit and thereby increasing the efficiency of the heat utilization of the steam system. ₅

It is known that dewatering points should be established at a given distance in the steam pipeline, where the water from the wall film condensation formed in the steam pipeline is removed from the steam pipeline to prevent water vapor from striking the steam system.

Depleted condensate is discharged in various ways according to the state of the art: a / A separate conduit is constructed to collect the discharged water at the drainage points and to recycle it to the heat center. A major disadvantage of this solution is the cost of constructing a separate conduit, which requires the construction of a third conduit besides the steam conduit j and the return condensate conduit, i.e. the condensate drain conduit.

b / Hot water discharged from the dewatering points of the steam pipe is utilized locally. An example of such an option is the use of water 20 for heating purposes in horticulture. Although this solution is useful, it is only possible in a very limited number of cases.

cl The discharged hot water is drained into a dewatering shaft. This solution results in the most unfavorable energy balance. The heat of the drained condensate is completely lost, but the very expensive deionized water is also lost. It is common experience that the c / point solution is the most common.

The aforementioned ways of discharging condensate from the steam power line can be found in manuals and technical books. These include:

dr. Róbert Kiss: District Heating Pocket Book. Technical Publisher 1977.

Marcell Korach: High-rise and underground construction of district heating networks. Technical Publication 1978.

Commonly used and points (a) to (c) above. A common feature of the solutions of the present invention is that the pressure of the fresh steam carried in the steam pipeline is almost one order of magnitude higher than the pressure of the condensate recycled from the place where the steam is used in the condensation pipeline. For this reason, it has not been possible so far to connect saturated-state water discharged from the steam pipes directly to the return condensate water pipe. This saturated state would immediately evaporate at the connection point of the lower pressure condensation line and gravity would break the return line. This is the reason why if the water in a saturated state cannot be used locally for heat recovery, this hot water will be released into the open air 50 unless otherwise available. However, the resulting heat loss and the environmental impact of hot water can be very significant.

Our aim is to eliminate the above-mentioned drawbacks and to provide a device which enables it; to reduce the pressure and heat of the saturated condensate at the dewatering points of the steam pipeline so that the condensate from the steam pipeline and the water flowing in the condensate of the steam system can be mixed, in other words, be connected. In addition to eliminating the drawbacks of known equipment and methods, it is an object of the present invention to utilize all of the heat content of the dewatering water 65, except for the insulation losses, to increase the efficiency of heat utilization of the entire steam system.

An embodiment of the apparatus of the present invention is the discovery that the dewatering water discharged from the steam mains may be cooled by a heat exchanger comprising refrigerant in the return pipe as condensation water.

FIELD OF THE INVENTION The present invention relates to an apparatus for supplying condensed water from a pressurized steam pipe to a returning condensate pipe for pressurized steam systems, thereby increasing the efficiency of steam utilization in a steam system.

The steam system has a backflow condensate line. The novelty of the apparatus according to the invention is that the heat and pressure relief container is formed by a buffer tank, the bottom outlet of which is passed through a branch of a heat exchanger whose cooled outlet is connected to condensate at a point downstream of the heat exchanger. On the other side of the heat exchanger is the condensate water pipe.

Between the inlet of the heat exchanger connected to the buffer tank and the outlet of the heat exchanger there is provided an organ, sensing and regulating a temperature difference, preferably without auxiliary energy, the actuator of which is connected to the edge of the heat exchanger inlet.

In a preferred embodiment of the heat exchanger used in the apparatus according to the invention, one branch of the heat exchanger is formed by a condensate conduit and the other branch is a conduit conduit coiled several times. In this way, it is preferable to use the condensate flowing in the condensate as a refrigerant in order to cool the condensate in the conduit to below the saturation temperature of the condensate. In this case, the two water can be mixed without the risk of gravity. This is made possible by the fact that the condensation flow represents a current of several orders of magnitude higher than that of the otherwise much hotter water of the drainage water of the pipeline.

The great advantage of the device according to the invention is that the total heat content of the condensed water discharged from the steam mains, but also the deionized water itself remains within the system, is not lost.

An exemplary embodiment of the apparatus of the present invention will be described in detail by reference to the drawing, wherein:

Figure 1 is a schematic diagram of a prior art steam supply line with a condensate line included in the system, and Figure 2 is a schematic diagram of the apparatus of the present invention.

Fig. 1 shows a state-of-the-art steam pipe, equipment for drainage of condensate at its dewatering points, and a condensation pipe from the point of use of the steam pipe steam to the direction of steam spinning. As shown in Fig. 1, at the drainage point of one hundred steam pipes 1, a water bag 2 is located, the outlet of which is connected to the inlet of a condensate cabinet 3. The condenser cabinet 3 is equipped with a condensate dispenser 4 whose function is to discharge only the aqueous phase from the steam line. A condition for the operation of the condensate automatic is that the pressure drop in the automatic tube, as a valve, should be within the range of 15-15% of the primary. so the con'f

-21 Operates well even in the case of ¹ densate automatic counterpressure. The condenser 3 is connected to an expander 5 whose function is to direct the gaseous phase of the fluid flowing from the condenser 3 into the open, while the liquid or water phase is discharged through the outlet 6 to a desiccator 7 in the present embodiment. As shown in Fig. 1, in the vicinity of the drainage points of the flow steam line 1, the dewatering elements are not connected to the condensation line 8.

Figure 2 illustrates an embodiment of the structural arrangement of Figure 1 according to the invention.

As shown in Figure 2, the water phase discharged from the condenser automaton 4 in the condenser cabinet 3 is connected to the upper part of a buffer vessel 10 which partially vaporizes into the buffer vessel 10. The lower part of the buffer tank 10 is connected to the inlet 11 of a heat exchanger 9 mounted on the condensation pipe 8 via a temperature controller known per se, the actuator 14 of which is located in front of the inlet 11 of the heat exchanger 9. In the heat exchanger 9, the water phase flowing from the buffer tank 10 cools to the condensation return water temperature so that this liquid can be introduced into the conduit 8 at the connection point 13 formed after the heat exchanger 9 with respect to the flow direction of the water flowing therein.

Returning to the saturated-state pressure and temperature conditions removed from the feed steam line 1, the temperature conditions were first described:

Part of the temperature of the condensate water discharged from the flow steam line 1 is lost in the condenser cabinet 3, through the condenser automaton 4 and the buffer tank 10. Further significant temperature reduction occurs in the heat exchanger 9, after which the temperature difference between the water in the return line and the water already discharged from the flow steam line 1 is maintained such that this partially cooled water is introduced into the condensation pipe 8. The maximum temperature of the water in the room is less than .10 degrees, which is useful for the system's heat management.

For safety reasons, use a temperature regulator whose actuator 14 is connected to the inlet 11 of the heat exchanger 9. This temperature controller prevents an unacceptable increase in temperature at the outlet 12 of the heat exchanger 9, in which case the actuator 11 will choke the inlet 11 of the heat exchanger 9.

With respect to the circuit arrangement of Fig. 2 and its pressure conditions, the pressure in the steam pipeline> 687 2 of saturated state discharged at the dewatering points of the flow steam line 1 first falls during the passage through the condenser 3 and through the condenser In the large-volume buffer vessel 10, the pressure is further reduced in the tubes, and finally, the required level of pressure is controlled by a temperature controller, preferably consisting of a valve system known per se.

For the heat exchanger 9 shown in Fig. 2, any known self-contained heat exchanger θ used in the steam supply systems, which corresponds to the given pressure and technical conditions (water value, currents) can be used.

A possible preferred exemplary embodiment may be formed by draining the condensation pipe 8 with a pipe snake at one of its sections in which the pipe drainage water is flowing through the pipe snake.

In this way, the simplest and most economical embodiment of the heat exchanger 9 can be created. Of course, it is expedient to solder the tube coil to the condensation pipe 8 and provide it with an insulating cover.

Claims (3)

1. / Apparatus for pressurized steam systems, for supplying condensate water from the forward steam conduit to the return condensate conduit, and thereby increasing the efficiency of the steam system's heat utilization, wherein the water sump is connected to a condenser and condensate the steam system has a back-condensation conduit, characterized in that the heat and pressure reducing means is formed by a buffer tank (10) having a bottom outlet through a branch of the heat exchanger / 9 / a cooled outlet of the branch / 12 / / 9 / is connected to the condensation line / 8 / while the other part of the heat exchanger / 9 / is connected to the condensation line / 8 /. Device according to Claim 1, characterized in that a temperature difference sensor, preferably requiring no auxiliary energy, is arranged between the heat exchanger / 9 / to the buffer tank / 10 / its connecting inlet / 11 / and / / 12, which is actuated in front of its actuator / 14 / inlet / 11 / of the heat exchanger / 9 /. Apparatus according to any one of claims 1 or 2, characterized in that it is a branch of the heat exchanger. one part of the condensation pipe / 8 / and the other part is a snake coiled around this section.