EP3553376A1 - Method for generating steam and a steam generator - Google Patents

Abstract

The invention relates to a method for generating steam from a liquid by means of a steam generator (2) which has at least one heating element (4) and at least one pressure vessel (6) with an outlet opening (8) and an outside (12), the liquid (a) is heated in the pressure vessel (6) by means of the heating element (4) and (b) exits the pressure vessel (6) through the outlet opening (8), a first part of the liquid evaporating and a second part of the liquid remaining liquid , wherein the steam generator (2) has a deflection hood (10), which the second part of the liquid meets and from there is guided to the outside (12).

Description

The invention relates to a method for producing steam from a liquid by means of a steam generator having at least one heating element and at least one pressure vessel having an outlet opening and an outer side, wherein the liquid is heated in the pressure vessel by means of the heating element and through the outlet opening from the pressure vessel exits, wherein a first part of the liquid evaporates and a second part of the liquid remains liquid. The invention also relates to a steam generator for carrying out such a method.

Steam is needed and used in a variety of technical applications. In most cases, water vapor is used, which is produced when water evaporates. However, vapors of other liquids, such as organic liquids or liquid mixtures, possible and useful for technical applications.

Steam is used, for example, in autoclaves for sterilization. Also as a heat exchanger in technical facilities or as the operating medium of a turbine, for example, to generate electricity, water vapor is used. In addition, it is possible to use steam in the production of ultrapure water, especially distilled water, which is used for a variety of different requirements, such as for injection purposes. In the process, steam is first generated, which is subsequently recondensed to liquid water.

Various methods and devices are known from the prior art with which steam, in particular water vapor, can be produced. For example, in a vacuum distillation, the lowering of the boiling point under reduced pressure is utilized. The boiling point of a liquid depends on the pressure surrounding the liquid. The higher the pressure, the higher the boiling point. The opposite effect is used in so-called flash evaporation or flash evaporation. The liquid is placed under a high pressure and heated to a temperature above the boiling point at atmospheric pressure is. Subsequently, the so superheated liquid escapes, for example, through a nozzle or an outlet opening from the pressure vessel, and evaporates abruptly by the sudden change in the pressure surrounding it and the resulting relaxation.

Both methods lead to a rapid evaporation, which, however, is usually not complete. In particular, in a flash evaporator not only steam occurs because only a first part of the liquid evaporates and a second part of the liquid remains unvaporized, that is liquid.

In an alternative evaporation technology, a volume of water under normal pressure is heated. The resulting steam is collected and used. Due to the large amount of water that needs to be heated at the same time, this process is very time consuming and energy consuming.

The present invention is therefore based on the object to propose a method for producing steam, with the fast, cost and energy efficient steam can be produced, which contains no or only very little unvaporized liquid.

The invention solves the stated object by a method for generating steam according to the preamble of claim 1, which is characterized in that the steam generator has a Umlenkhaube, which meets the second part of the liquid and is directed from there to the outside.

The liquid, in particular the water, is therefore initially heated in the pressure vessel by means of the heating element. The heating element may be, for example, an electric heating element, in which heat energy is generated from electrical energy. Of course, other heating elements are possible. The heating element itself may be formed, for example, as a pipe or pipe arrangement, wherein a heat transfer medium, for example a heated liquid, a heated gas or another energy source is passed therethrough. For example, thermal oils or a hot gas generated by, for example, a combustion process may be used. These media can transmit high temperatures.

Since the liquid in the pressure vessel is under a greater pressure than the ambient pressure outside the steam generator, the liquid within the pressure vessel can be heated to a higher temperature without causing any evaporation. These Overheated liquid then exits the pressure vessel through the outlet opening, whereby the first part of the liquid evaporates and the second part remains liquid. In particular, the second part of the liquid strikes the Umlenkhaube and is directed to the outside of the pressure vessel.

The pressure vessel is preferably designed so that the heated and heated liquid located in its interior releases a portion of the heat to the pressure vessel, so that the outside of the pressure vessel is heated. Preferably, the outside of the pressure vessel has a temperature which is higher than the evaporation temperature or boiling temperature of the liquid which is directed to the outside.

In a preferred embodiment of the method, the liquid is passed continuously through the pressure vessel. Consequently, liquid is continuously introduced into the pressure vessel, which is heated by the at least one heating element to such an extent that, when it reaches the outlet opening of the pressure vessel, it has a temperature which leads to as complete a vaporization as possible due to the relaxation occurring. The second part of the liquid, which passes through the outlet unevaporated, should be as small as possible.

Preferably, the outside is heated exclusively by means of the heating element, in particular via the liquid within the pressure vessel. In this embodiment, it is not necessary to further heat the outside in addition to the heat energy transferred from the inside of the pressure vessel. As a result, the steam generator is structurally simplified and designed structurally small. In addition, it is not necessary to provide an additional source of energy and heat so that the process can be carried out efficiently.

The liquid preferably exits through the at least one outlet opening into a vapor space, which is delimited by a steam space housing of the steam generator. The pressure within the vapor space is preferably less than a pressure within the pressure vessel and greater than an ambient pressure outside the steam generator. The pressure within the vapor space should be less than the pressure inside the pressure vessel. Only then does it come at the outlet of the heated liquid from the outlet to a relaxation and partial evaporation. In addition, by judicious choice of the different pressures can be achieved that the temperature of the outside of the pressure vessel is sufficient to evaporate the liquid that is passed to this outside. However, the pressure within the vapor space should be greater be as its ambient pressure, so that the resulting steam flows out through an outlet opening of the steam generator without that additional pumps or devices are necessary.

The at least one heating element advantageously reaches temperatures of over 200 ° C, preferably over 300 ° C. The liquid in the pressure vessel can advantageously also temperatures above 100 ° C, preferably above 150 ° C can be increased. The temperature of the liquid, which increases in the direction of the outlet opening in the continuous flow method, is advantageously below the pressure-dependent boiling point. Advantageously, the boiling temperature of the liquid within the pressure vessel at the prevailing pressure is exceeded by more than 1 ° C. For efficient steam generation, however, it is advantageous to heat the liquid within the pressure vessel to the highest possible temperature, which is as close as possible, but below the boiling point. A maximum distance of 1 ° C is sufficient, but also advantageous to ensure that there is no evaporation within the pressure vessel.

Advantageously, the temperature to which the liquid is heated within the pressure vessel, therefore less than 10 ° C, advantageously less than 5 ° C is less than the boiling temperature of the liquid at the pressure prevailing in the pressure vessel.

However, as an alternative to this embodiment, the temperature can also be adjusted so that partial evaporation occurs inside the pressure vessel. This is achieved, for example, in that the quantity of heat fed in is so great that the liquid to be evaporated reaches a temperature which is above the evaporation temperature prevailing in the pressure vessel at the prevailing pressure. For this purpose, it is advantageous if the at least one heating element is designed to withstand the resulting mechanical and in particular thermal stresses. If the temperature is adjusted so that it comes to a partial evaporation, small gas bubbles arise in the interior of the liquid in the pressure vessel. Since the wall of the pressure vessel, which limits the throughflow volume, has a significantly lower temperature than the heating element, the gas volume just formed is preferably recondensed as soon as the gas bubbles come into contact with the wall of the pressure vessel. In this way, a particularly good thermal contact between the heating element and the wall of the pressure vessel is achieved, so that the temperature of the outside of the pressure vessel can be increased particularly efficiently and quickly in this way. This can be a Part of the liquid to be evaporated, which flows down in liquid form on the outside of the pressure vessel as a falling film, can be increased, whereby the overall performance of the evaporation can be increased.

The invention also achieves the stated object by means of a steam generator for carrying out such a method which has at least one heating element, at least one pressure vessel with an outlet opening and an outside and at least one deflection hood, which is arranged and constructed in such a way that liquid emerging from the outlet opening the outside is conducted.

Preferably, the at least one heating element is located in the pressure vessel, which is advantageously designed as an annular gap, in particular with an annular flow-through cross-section. The smaller the thickness of the annular gap is formed, the better the thermal contact between the heating element in the interior of the pressure vessel and the wall of the pressure vessel. At the same time the most homogeneous possible temperature distribution of the liquid inside the pressure vessel is achieved in this way.

Preferably, the steam generator has a vapor volume bounded by the outside of the pressure vessel and by a vapor space housing. In this vapor space, the superheated liquid from the outlet opening of the pressure vessel enters, wherein the deflection hood is arranged so that it is advantageously in the vapor space. Preferably, it is arranged so that in the liquid state emerging from the outlet opening liquid strikes the Umlenkhaube and is directed by her to the outside of the pressure vessel. It is advantageous if the largest possible proportion, for example more than 85%, preferably more than 90%, of the liquid emerging from the outlet opening of the pressure vessel in the liquid state reaches the deflection hood. Preferably, the entire exiting liquid is passed through the Umlenkhaube on the outside of the pressure vessel.

Preferably, the vapor space has at least one drain through which liquid can be discharged from the vapor space. The liquid conducted by the deflection hood onto the outside of the pressure vessel preferably runs as a film along this outside, following the force of gravity. Since the outer wall has a temperature which is advantageously above the evaporation temperature of the liquid, it comes to evaporation here. Nevertheless, it is not necessary that the liquid evaporates completely. Liquid that remains in the liquid state in the vapor space can be removed via the drain.

In a preferred embodiment, the steam generator has an electrical control, in particular an electronic data processing device which is set up, at least one operating variable of the steam generator, in particular a flow rate of liquid, which is passed through the pressure vessel, a heating line and / or a heating temperature of the at least one To control and / or regulate heating element. Preferably, the steam generator has at least one flow rate sensor, a temperature sensor, a voltmeter, an ammeter and / or a pressure sensor. With the help of one or more of these sensors, data is transmitted, which is transmitted to the electrical control. On the basis of these data, the electrical control controls and / or regulates the at least one operating variable of the steam generator.

It is important in the control and / or regulation, for example, to ensure that on the one hand the amount of water flowing through is so large that it is not due to the heat energy, which is introduced by the at least one heating element in the liquid, to an evaporation in the interior Pressure vessel comes. On the other hand, the flow rate should also be adjusted so that the temperature of the liquid at the outlet opening as close as possible to the valid evaporation temperature, but does not exceed.

Figur 1

- die schematische Darstellung eines Dampferzeugers gemäß einem Ausführungsbeispiel der vorliegenden Erfindung.

With the aid of the accompanying drawings, an embodiment of the invention will be explained in more detail below. It shows:

FIG. 1

- The schematic representation of a steam generator according to an embodiment of the present invention.

The in FIG. 1 illustrated steam generator 2 has a cylindrical heating element 4, which is designed as an electric heating element 4. It is located in a pressure vessel 6, which is formed so that there is an annular annular gap between the pressure vessel 6 and the heating element 4. In the upper area there is an outlet opening 8, around which a deflecting hood 10 is arranged. This is designed so that a liquid emerging second portion of the medium to be evaporated at least largely meets the Umlenkhaube 10 and is directed by her to the outside 12 of the pressure vessel 6. Preferably, the deflecting hood 10 is designed and arranged in such a way that the entire outflowing liquid strikes the deflecting hood 10 and is guided onto the outer side 12 of the pressure vessel 6.

Between the outer side 12 of the pressure vessel 6 and a pressure chamber housing 16, which is the housing of the steam generator in the embodiment shown, there is a vapor space 14. In it prevails when operating the device, a higher pressure than the ambient pressure surrounding the steam generator 2, and a smaller pressure than it acts in the annular gap between the heating element 4 and the pressure vessel 6.

Via a supply line 18, liquid is supplied to a supply container 20. The inflow via a valve 22 is controllable. Via a level gauge 24, the incoming amount of liquid is detected and via a control line 26 corresponding control signals can be transmitted to the valve 22. The liquid is fed via a pump 28 to the actual steam generator 2. The volume flow itself is controllable via a further valve 30. In the corresponding line a flow indicator 32 is integrated, which can also be designed as a flow sensor.

The liquid is pressed in the steam generator in the annular gap between the heating element 4 and the pressure vessel 6 in the illustrated embodiment upwards and thereby heated. The heating element 4 is supplied via an electrical supply line 34 with power.

The liquid then exits through the outlet opening 8, wherein the liquid portion is passed through the deflection hood 10 on the outer side 12 of the pressure vessel 6. Since this is heated by the upwardly moving liquid inside, at least a portion of this second part of the liquid evaporates and can leave the steam generator through an outlet nozzle 36. The part of the liquid which has not evaporated even after contact with the outer side 12 of the pressure vessel 6 is withdrawn via an outlet 38 to the steam generator and fed back to the circuit. The amount is controllable via a valve 30.

In the corresponding pipeline is a pressure measuring sensor 40, which measures the current pressure and transmits the corresponding measured values to an electrical control, not shown.

LIST OF REFERENCE NUMBERS

2

steam generator

4

heating element

6

pressure vessel

8th

outlet opening

10

deflection hood

12

outside

14

steam room

16

Steam room housing

18

supply

20

feed tank

22

Valve

24

level meter

26

control line

28

pump

30

Valve

32

Flow indicator

34

Electrical supply

36

outlet connection

38

procedure

40

By measuring sensor

Claims (10)

A method of producing vapor from a liquid by means of a steam generator (2) comprising at least one heating element (4) and at least one pressure vessel (6) having an outlet opening (8) and an exterior (12), the liquid (A) is heated in the pressure vessel (6) by means of the heating element (4) and (b) exiting the pressure vessel (6) through the outlet opening (8), whereby a first part of the liquid evaporates and a second part of the liquid remains liquid, characterized in that
the steam generator (2) has a deflection hood (10), on which the second part of the liquid impinges and from there to the outside (12) is passed. A method according to claim 1, characterized in that the liquid is passed continuously through the pressure vessel (6). A method according to claim 1 or 2, characterized in that the outer side (12) exclusively by means of the heating element (4), in particular via the liquid within the pressure vessel (6) is heated. Method according to one of the preceding claims, characterized in that the liquid exits through the at least one outlet opening (8) into a steam space (14) bounded by a steam space housing (16) of the steam generator (2), wherein a pressure within the vapor space (14) is less than a pressure within the pressure vessel (6) and greater than an ambient pressure outside the steam generator (2). Steam generator (2) for carrying out a method according to claims 1 to 4, the (a) at least one heating element (4), (B) at least one pressure vessel (6) having an outlet opening (8) and an outer side (12), and (C) at least one deflecting hood (10) which is arranged and designed such that from the outlet opening (8) leaking liquid is passed to the outside (12). Steam generator (2) according to any one of claims 5, characterized in that the at least one heating element (4) in the pressure vessel (6), which is preferably formed as an annular gap, in particular with an annular cross-section through which can flow. Steam generator (2) according to any one of claims 5 and 6, characterized in that the steam generator (2) has a vapor volume (14) bounded by the outside (12) of the pressure vessel (6) and by a steam space housing (16). Steam generator (2) according to one of claims 5 to 7, characterized in that the steam space (14) has a drain through which liquid can be discharged from the steam space (14). Steam generator (2) according to one of claims 5 to 8, characterized in that the steam generator (2) has an electrical control, in particular an electronic data processing device, which is set up, at least one operating variable of the steam generator (2), in particular a flow rate of liquid, which is passed through the pressure vessel to control and / or regulate a heating power and / or a heating temperature of the at least one heating element (4). Steam generator (2) according to claim 9, characterized in that the steam generator (2) has at least one flow rate sensor, a temperature sensor, a voltmeter, an ammeter and / or a pressure sensor.

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