SU994892A1 - Rotation mixing condenser - Google Patents

Description

The invention relates to energy and can be applied in mixing-type heat exchangers for condensing vapor and heating a liquid.

A contact heat exchanger is known, comprising a housing with a steam supply pipe arranged therein and a coolant supply collector, the lower end of which is perforated and located coaxially inside the cup. The vapor condensation is carried out on streams of liquid 1 flowing out of the holes of the perforated collector.

The disadvantage of this heat exchanger is the low efficiency of the vapor condensation process and, in addition, possible liquid entrainment with suction non-condensing gases, as there is no organized separation of the liquid phase.

Also known is a rotary smg-yuni condenser, comprising a housing. With branch pipes for supplying steam and draining fluid and coaxially mounted rotary atomizer fitted with a centrally located one.

perforated piping dl. coolant supply C 2.

The disadvantage of a lime condenser is the low intensity of heat exchange due to the insufficiently developed interfacial surface of the interaction of the contacting media, as well as due to the short time of contact of steam with coolant.

ten

The aim of the invention is to intensify heat exchange by creating a developed interfacial surface of contacting media.

The goal is achieved

15 - in the case of a rotational mixing capacitor containing a housing with nozzles for supplying steam and liquid outlet and a coaxially mounted rotary atomizer equipped with

20 in its central part with a perforated coolant supply pipe, the centrifugal atomizer is made in the form of a hollow perforated drum with bundles of elastic threads attached to its outer surface.

The perforated coolant supply pipe is made straight and installed along the axis

30 drums.

FIG. 1 shows a general view of the device; in fig. 2 is a section A-A in FIG. one.

The centrifugal mixing condenser comprises a cylindrical case 1 with a pipe 2 for removing non-condensable gases and a pipe 3 for draining liquid. In case 1 a perforated drum 4 is coaxially arranged with bunches of elastic threads 5 fixed on its outer surface, which is connected to shaft 6. A perforated coolant supply pipe 7 is coaxially located inside perforated drum 4. Steam is supplied to the condenser through a pipe 8 connected to the internal cavity of the perforated drum 4.

The rotary mixing capacitor operates as follows.

The cooling fluid flows to the perforated line 7 and flows out of it in the form of separate jets. When the perforated drum 4 is rotated, the liquid falling on its inner wall is evenly distributed over its entire surface in the form of a film, which is continuously broken by the intermittent wall. perforated drum 4 and is ejected through its openings due to centrifugal forces to the outside. In the zone of location of the elastic strands 5, the liquid is divided into small droplets. At the same time, the elastic threads 5 themselves are wetted and, under the influence of centrifugal forces, the centers of generation of liquid droplets, which penetrate the space formed by the free ends of the elastic threads 5 and the cylindrical body 1, and are separated on its wall. The steam supplied through the pipe 8 is in contact with the coolant when passing through the holes in the wall of the perforated drum 4 and partially condenses. Next, steam condensation occurs when it contacts with moistened bundles of elastic threads 5.

At a high density of the arrangement of the bundles of elastic threads 5 on the perforated drum 4, a contact surface between the wetted and the threads and the steam is created, thanks to

The steam condensation process is very intense. The resulting condensate is separated by centrifugal forces on the cylindrical wall of the housing and flows into the bottom of the housing 1 as film, where the liquid is discharged through pipe 3, the liquid is drained, and non-condensable gases are sucked out from pipe 2. The proposed device allows

0 significantly intensify the process of heat exchange due to the developed interfacial surface of the contacting media and uniform distribution of the vapor and liquid flows in their zone

5 mixes

In such a condenser, due to the effective separation of the liquid phase, the removal of droplets with waste noncondensing gases is practically eliminated, and therefore the device can be effectively used with a sufficiently large amount of non-condensing gases contained in the vapor.

Claims (2)

1. Rotational capacitor cftely, comprising a housing with nozzles for supplying steam and draining liquid and coaxially mounted rotary atomizer, provided with a perforated conduit located in its central part for supplying coolant. Different; the fact that, in order to intensify heat transfer by creating a broken interfacial surface between the contacting media, the centrifugal atomizer is designed as perforated drum with bundles of elastic threads attached to its outer surface. 2. A condenser according to claim 1, characterized in that the perforated coolant supply pipe is straight-line and installed along the axis of the drum. Sources of information 0 taken into account in the examination 1. Author's certificate of the USSR 589529, cl. F28 3/06, 1978. 2. USSR author's certificate number 192229, cl. T28 3/08, 1967.