DE1103360B - Steam condenser - Google Patents

Description

Steam condenser The invention relates to a steam condenser with a steam chamber in which in addition to heat exchange devices at a distance from each other located electrodes are provided, the electrical discharge devices form and serve to generate condensation nuclei.

Normally, condensation of water vapor only takes place when the following two conditions are met: 1. The relative humidity the air or the carrier gas is more than 100%, i.e. that is, the steam is oversaturated.

2. There are condensation nuclei on which the steam condenses can.

It was recognized earlier that the efficiency of a capacitor is significantly improved if the number of condensation nuclei is artificially increased will.

There are devices known in the capacitor -additional Generate condensation nuclei by ionizing the steam. With a well-known For this purpose, the steam condenser is irradiated by means of an X-ray tube made, whereby the vapor is ionized. In other known steam condensers the vapor is passed between two electrodes connected to a high DC voltage or a high-frequency alternating voltage. The electrodes are so far away from each other that no flashover, just a corona discharge takes place. The corona discharges ionize the vapor.

In all of these known devices, ions are present in the vapor generated, which serve as additional condensation nuclei.

But it has been shown that an ionization of the steam by Irradiation, corona discharge or the like. Only then an effectively improved condensation results when the relative humidity is over 400%. Since this value for many Applications, for example with the usual steam condensers in steam turbine systems, is usually not achieved, are the previously described known facilities in these cases completely or largely ineffective.

The aim of the invention is therefore a steam condenser in which condensation cores be introduced into the capacitor in such a way that even with low supersaturation of the steam a significantly improved condensation occurs.

This is achieved according to the invention in that the distance between the electrodes is so small that evaporation of the electrode material takes place during the discharge.

The main difference between the steam condenser according to the invention and the known devices is that the additional condensation nuclei not by vapor ions, but by the vaporized particles of the electrode material are formed. In the event of an arc discharge, these surround them in a very high concentration the electrodes, and they: have a radius in the range of 10-8 to 10-4 cm, mainly between 10-7 and 10-0 cm This size is particularly suitable for condensation nuclei.

It was found that from the vaporized metal particles existing condensation nuclei even with a slight oversaturation of the steam take full effect. In contrast to the known devices, it can be used for the steam condenser according to the invention, the condensation rate also then can be increased considerably if the relative humidity of the steam is far below 400%. The invention therefore results in numerous practical applications, in which the known facilities were completely or almost ineffective, for example in steam condensers in steam turbine plants, a considerable improvement of condensation.

Embodiments of the invention are shown in the drawing. 1 shows a section through a steam condenser according to the invention, Fig. 2 is an enlarged view of part of the steam condenser of FIGS. 1 and 3 another embodiment of the part of the steam condenser shown in FIG.

The steam condenser 1 shown in Fig. 1 consists of a chamber 2, into which an evaporated liquid, e.g. B. water vapor is introduced. At the A steam inlet 3 is provided on the top of the chamber 2. over which the water vapor is introduced under reduced pressure. The steam inlet 3 is for example connected to the exhaust pipe of a turbine. At the lower section of the chamber 2 are two lines 5 connected, with which air residues and uncondensed steam residues can be removed from the condenser. At the bottom of the capacitor is an outlet 6 is provided through which the condensate can drain.

Inside the chamber 2: Metal pipes 7 are arranged, which extend in the axial direction over the entire length of the chamber 2. They are of cooling water flowed through so that they condensation at least part of the in the chamber cause the steam present. Two lines 8 serve as cold water inlet and two pipes 9 near the top of the condenser as a hot water outlet for the cooling water flowing through the pipe 7.

Furthermore, devices 10 for the periodic generation of condensation nuclei are provided in the chamber 2. An embodiment of the device 10 is shown in FIG. The condensation core generator 10 has a terminal board 11 which is fastened to the wall of the chamber 2 at the level of the inlet 3. On the terminal board 11 two standing insulators 12 made of ceramic or porcelain are attached, through which conductors 13 run, which merge into a pair of spaced apart discharge electrodes 14, between which there is a discharge path. The conductors 13 are connected to a voltage source via a pair of insulating sockets 15. The electrodes 14 are so close to one another that a spark discharge occurs between the electrodes at the voltage supplied by the voltage source. As a result, part of the electrode material evaporates and the evaporated metal particles form the condensation nuclei.

The voltage source consists of a high-voltage transformer 16 with a primary winding 17 and a secondary winding 18. The primary winding 17 is connected to an alternating current source 19, which is the usual 220 V 50 Hz network can be. The secondary winding 18, which is connected to the conductors 13, has a very large number of turns, and transforms that fed to the primary winding 220 V voltage goes up to a voltage high enough to cause an arc discharge between the electrodes 14, for example to 2000 V. By the arc discharge Then the condensation nuclei are created, which are made of small particles of the electrode material exist. Since the alternating voltage supplied to the electrodes 12 has a frequency of 50 Hz produces 100 discharges per second, each one of which large number of condensation nuclei to support the condensation rate generated by the steam.

Around the electrodes 14 and the discharge path is a; hollow, slotted tube 20 arranged, which allows the diffusion of the vaporized electrode material in the air prevents and ensures that this vaporized material to relatively large condensation nuclei reunited by these particles be kept close together and increase the likelihood of reunification will. This makes it possible to a certain extent to change the size of the in the vapor space of the Capacitor introduced condensation nuclei and thereby in turn the effectiveness to control the device.

Another embodiment of the condensation nucleus generator 10 is shown in FIG. 3. In this embodiment, the electric arc discharges are generated by an electromagnetic relay operating a pair of contacts periodically. The device 10 shown in FIG. 3 has a terminal board 31 which is also fastened to the wall of the chamber 2 at the level of the steam inlet 3. A plurality of clamps 32, 33, 34 and 35 are attached to the top of the terminal board 31. The terminal 32 is electrically connected to a fixed contact member 36 which is attached to the terminal board 31, while the terminal 35 is connected to a spring-loaded armature 38 to which a contact member 37 is attached. An electromagnet 39 is attached to the terminal board 31 opposite the armature 38. He actuates the armature 38 so that the contacts 36 and 37 are periodically closed. The connections of the electromagnet 39 are connected to the terminals 33 and 34. The terminals 32, 33, 34 and 35 are connected via an insulating bushing 40 to two external electrical circuits 41 and 42, one of which is used to actuate the electromagnet 39 and the other as a load circuit for the contact members. The load circuit 41 connected to the contact terminals 32 and 35 contains an impedance 43 which limits the flow of current through the circuit when the contacts 36 and 37 are closed.

The excitation circuit 42 connected to terminals 33 and 34 is energized the electromagnet 39 periodically to actuate the contact members 36 and 37. The Terminals 46 of the excitation circuit 42 are connected to one for actuating the electromagnet 39 connected to a suitable voltage source. The current is fed to the coil by means of a Time switch arrangement fed periodically. For this purpose a switch 44 of a cam 45 periodically closed. The time switch device 44, 45 can so be such that any desired operating frequency can be set. Through this the contact elements inside the capacitor can each be actuated with the frequency in which the number of condensation nuclei generated for increasing the The condensation rate of the steam in the condenser is most favorable.

In the preferred embodiments shown in FIGS. 1 to 3 the condensation core generator is attached inside the condensation chamber 2. It however, it is apparent that the core sources are located outside the chamber can, in which case the cores are introduced into the vapor space by means of a pipe system will. In certain circumstances, especially where maintenance is difficult, such an arrangement may be preferable.

The invention was made in connection with a water vapor condenser described, but it is obvious that in addition to the water vapor condensation in Turbines many other areas of application are possible, e.g. B. Distillation plants, Cooling devices, drying chambers of dishwashers and many other similar facilities in which steam condensation is carried out will.

Of course, liquids other than water can also be condensed using the introduction of condensation nuclei according to the invention, e.g. B. evaporated oil or refrigerant for cooling systems. PATENT CLAIMS: 1. Steam condenser with a steam chamber, in which in addition to heat exchange devices spaced electrodes are provided which form electrical discharge devices and serve to generate condensation nuclei, characterized in that the distance between the electrodes is so small that evaporation during discharge of the electrode material takes place.

2. Steam condenser according to claim 1, characterized in that the electrical discharge devices are operated periodically.

3. Steam condenser according to claim 1 or 2, characterized in that that the electrodes of the electrical discharge devices contacts a spark gap that are alternately closed and opened. Considered publications: German Patent No. 268 283; U.S. Patent No. 2,015,364.