CZ1663U1 - Countercurrent disk-type heat-exchange apparatus - Google Patents

Description

Technical field

The technical solution relates to a disc heat exchanger which utilizes the counter-current direction of both media, ie the medium that transfers heat and the media that receives heat. The heat transfer medium is outside the disc housing, while the heat receiving medium is located within the disc housing. The most commonly used medium will be water, with pure liquid flowing in the labyrinth circuit within the hollow disk set, while contaminated liquid flows around the outer surface of the hollow disk set.

BACKGROUND OF THE INVENTION

Most of the wet processes in laundries, textile mills, tanneries, distilleries, paper mills, starch mills, the food industry, especially in the textile industry, use heat-containing media, with energy prices constantly rising. For this reason, it is necessary to ensure the economical use of heat already absorbed in order to achieve the lowest possible heat losses. To save a significant part of this energy and to. To reduce the cost of its acquisition, different types of heat exchangers are used, which, according to their degree of efficiency and quality, contribute to meeting the lowest possible heat losses. There are also specially designed and built exchangers for certain exchange media used, for example, under specific physical conditions.

The solution according to the technical solution _K - which is - the object. The utility is based, in principle, on the CS publication of the invention, in November 1991, the designation PV 2144-90.C entitled Disc heat exchanger, class F 28 DS / 00. According to the present invention, the exchanger consists of a vertical cylindrically horizontally divided shell enclosed on both sides with inlet and outlet ports. Inside the housing, a disc insert consisting of several concentric circular interconnected hollow discs is fixed in the days. The inlet and outlet of the medium into the hollow disk system is led outside the top and bottom of the exchanger shell. The second medium flows between the outer surface of the hollow disk assembly and the shell of the exchanger. The individual hollow plates are still attached to the shell of the exchanger. The disadvantage here is the vertical arrangement of the entire exchanger and the impossibility to rotate the hollow disk system and in relation to the anticipated requirements. on,. by exchanging-to- the low pattern ·.

Another solution is contained in CS Copyright Certificate No. 271865 of 1988 entitled Rotating Heat Exchanger Installation of Tray Dryer, class F 26 B 17/28, application filed PV 4894-88.Z. The heat exchanger assembly of the trough dryer consists of individual mutually separated hollow heated disks mounted on a rotating horizontally arranged hollow shaft which rotates in a closed trough provided with an inlet and outlet of dried material that surrounds the hollow heated disks and is displaced gradually therefrom from the inlet to the outlet of the trough dryer while drying the material. In order to set a constant passage time of the individual parts of the material through the drier, the individual heated disks are progressively interrupted in the direction from the outlet to the inlet of the trough dryer so that the front leading walls of the recesses of adjacent hollow heated disks are gradually in the direction rotated relative to each other in the sense of rotation of the hollow shaft. The solution according to the author's certificate is predetermined and designed for use in an oven and is not suitable as a heat exchanger.

The essence of the technical solution

Using a large part of the heat energy from the waste medium, a countercurrent disc heat exchanger according to the present invention has been proposed which is capable of handling both contaminated and turbid media without the risk of fouling or operating disturbances due to sludge deposits.

The essence of the countercurrent heat exchanger solution is that it consists of a closed tub, in which at least one hollow shaft or tube is arranged individual hollow disks, the inner space of which is interconnected, the set of hollow disks being placed in waste medium, eg warm water in the bathtub. The hollow shaft or tube is soaked in a rotatable closed tub and further provided with connection ports for inlet and outlet of the input medium, e.g. cold and clean water, the cold clean water flowing in the labirinto circuit inside the hollow disks. The closed tub has two connecting flanges, one for the inlet and the other for the outlet of the waste medium. The connecting flange at the waste medium inlet is covered by a diaphragm inside the closed tank, reaching through its outlet below the level of the waste medium in the tank. The connecting flange at the outlet of the waste medium from the tub is located below the level of the waste medium in the closed tub and is covered by an overflow inside the closed tub whose open mouth determines the level of the waste medium in the closed tub.

Each hollow disk is formed from a pair of shaped discs in the form of discs. The pairs of shaped slats are connected to each other on the outer periphery of the disks and on the other hand in a plurality of indentations, each of which are made opposite to each other on at least one selected diameter of the disks. The contoured lamellas of adjacent hollow disks are interconnected at their small diameter into the hollow disk system by means of spacers, which at the same time provide better rigidity of the entire interconnected hollow disk system. The two outer slats of the hollow disk assembly are also connected with a small diameter to the spacer ring, to which the disc cover is connected with its outer periphery, the smaller inner periphery of which is connected to the hollow shaft or pipe on which the entire hollow disk assembly is provided.

Within each hollow disk, a labyrinth circuit is formed for passing the medium through the disk from a lamella partition interposed between pairs of shaped lamellas. The lamella baffle is connected, in the indentations, to a pair of shaped lamellas and, secondly, to a hollow shaft or pipe supporting a system of hollow disks.

To direct the flow of the heat transfer medium in the closed tub, a baffle extends between the individual hollow disks, fixed to the opposite inner walls of the closed tub and arranged alternately against each other by the spacing of the hollow disks.

On the hollow shaft or tube carrying the hollow disk system, a sprocket is connected by means of a chain to the drive unit to ensure a constant rotation of the tube or of the tube. hollow shaft.

The hollow shaft or tube supporting the array of hollow disks is mounted rotatably in hollow bodies provided with seals before and after the bearings ¹ . The hollow bodies are rigidly connected to the machine frame and into their cavity is connected a connecting throat. The hollow shaft or tube is provided at both ends extending into the cavity of the hollow bodies with at least one opening opening into the interior of the first hollow disk and into the interior of the last hollow disk from the hollow disk array.

Such an exchanger arrangement as described above is functionally very reliable and prevents sludge settling. The hollow disk shaft is submerged in a contaminated waste medium that flows through a closed tub and rotates continuously, creating a turbulent flow in the hollow disks, which is advantageous because the liquid medium flows around the hollow disks from their center towards the outer edge of the hollow disks and from there back to their center, which spontaneously cleans the hollow discs.

The heat exchanger according to the present invention is capable of working with a contaminated medium in a closed tank which can contain other physical and chemical impurities without the need for a filter. The capacity of the exchanger can be changed by regulating the amount of flowing media through both parts of the exchanger.

Picture in the drawing

The drawing shows an exemplary schematic arrangement of a disc heat exchanger according to the present invention *

Example of technical solution

In the closed tub 1, which is covered by the lid 30, individual hollow disks 4 are provided on the tube 3, the inner space 5 of which is interconnected. A hollow shaft 2 is connected from both sides to the tube 3. It is fixedly connected to the tube 2. The hollow shaft 2 is blinded at the end which is inserted into the tube 3 and rotatably supported in bearings 21 which are seated in the hollow bodies 20 of the interior space of the closed tub 1. The hollow bodies 20 are fastened, for example by screws (not shown), to the wall of the closed bathtub 1 and sealed with a seal 32. From the outside of the closed tub 1, the hollow bodies are covered by a cover 31, under which the seal 32 is again located. In the cover 31, the connection socket 6 of the cold and clean medium, eg water, is fixed. The bearings 21 are covered with gaskets 22 on both sides in the hollow bodies 20.

In the vicinity of the hollow body 20 on the right side of the figure, a sprocket 17 driven by the chain 18 from the drive unit 19 is fixedly connected to the hollow shaft.

Two connecting flanges 1 are connected to the interior of the closed bath 1 for the entry and exit of warm and contaminated medium, for example water, which is located in the closed bath 7 and surrounds the system of hollow disks 4 from their outside. The connecting flange 7 on the left side of the closed bath 7 is an inlet for warm contaminated water whose level 28 is above the circumferences 2 of the hollow disks From the interior of the closed bath 1 the inlet connecting flange 7 is covered by an orifice 24. The connection flange 1 on the right side of the closed bath 1 is an outlet for warm contaminated water. From the interior of the closed bath 1, the outlet connection flange 2 is covered by an overflow 25, the upper open mouth 27 of which determines the level 28 of the hot polluted water in the closed bath I. » warm contaminated water in a closed bathtub 2 ·

Each hollow disc 6 of the hollow disc assembly 6 is formed from a pair of shaped discs 10 in the form of discs which are connected to one another in the indentations 1B and on the other side 2 of these discs. The joints between the individual hollow disks 4, 3 and 4, respectively. between the individual shaped slats 10 belonging to the adjacent hollow disks 4, they are provided by spacers 13 which surround the tube 2. The inner space 2 of the hollow plates 2 is divided by lamellar partitions 15, thereby forming inside the hollow disks 4.

Labirint space for cold clean medium. The lamellar baffles 15 are mounted on the one hand between the embossments 13 of the pairs of shaped slats 10 and on the other hand to the fastening rings 29 which are threaded on the pipe 3 and are fixedly connected to the pipe. All fastening joints of the hollow disks 6 are made by welding or scoring.

The first outer shaped lamella 11 and the last outer shaped lamella 12 of the hollow disk assembly 8 are also connected to a spacer ring 13 and circumferentially 9 to the opposite shaped lamella 10. At the same time, the first outer shaped lamella 11 and the last outer shaped lamella 12 are joined in the recesses. A plate 14, whose smaller circumference is connected to the tube carrying the assembly, is also connected with its larger circumference to the spacer ring 13, in addition to the first outer shaped lamella 11 and the last outer shaped lamella 12. hollow disks £. All fastening joints relating to the first outer shaped lamella 11, the last outer shaped lamella 12 and the plate caps 14 are made by welding or spot welding.

The hollow shaft 2, rotatably mounted, fixedly connected to the tube 3 and supporting the tube 6, is terminated at one end into the cavity of the hollow body 20. The other end of the hollow shaft 2 is partially inserted into the tube 6 and the cavity formed in the axis of the hollow shaft 2 is not continuous. This central cavity of the hollow shaft 2 is followed by openings 23, which are led into the inner space 4 of the first outer shaped lamella 11 and into the inner space 4 of the last outer shaped lamella 12 from the hollow disk assembly.

Between the individual hollow disks 4 extend the baffles 16 arranged zig-zag for both spacing of the hollow disks 6. The baffles 16 are fastened alternately to the opposing inner walls of the closed tub 4 and extend at most to the central axis of the hollow disk assembly 6. The bath partitions 16 fulfill the function of directing the flow of warm contaminated water through the closed bath 6.

The disc heat exchanger is designed as counterflow. Pure cold water enters through the connection neck 6 in the direction of the first arrow 33 into the cavity of the hollow body 20 and from there through the hollow shaft 2 and the holes 23 at its end into the interior space of the first outer shaped lamella 11 belonging to the hollow disk system. From there, the clean cold water continues in the direction of the second arrow 34 to the other hollow disks 6.

From the interior space 8 of the last outer shaped lamella 12 belonging to the hollow disk system 8, clean and heated water enters through openings 23 into the hollow shaft cavity 8 and further from the hollow body cavity 20 into the connection socket 8 in the direction of the third arrow 35.

Through the flow of pure water through the set of hollow disks 6, the heat contained in the warm contaminated water present in the closed bath 6 was transferred to this clear water. The heat transfer efficiency is increased by constantly rotating the hollow disk assembly. The entering of clean water into the interior of the hollow disk 4 can also be pressurized.

Outside the surface of the hollow disk assembly 8, there is warm contaminated water flowing through the closed bathtub 8, which enters through the connection socket 8 in the direction of the fourth arrows 36. The incoming warm contaminated water enters the closed bathtub 24 and impinges 26 from the shutter 24 below the surface. 28 mixes with other warm contaminated water. Through the overflow 25 over its upper open mouth 27, the warm contaminated water is discharged in the direction of the arrows 5 through the connecting flange 6 from the closed exchanger tank 6.

The counter-current disk heat exchanger according to the invention is connected to a system, which generally consists of a collecting sump for the input of hot polluted water, eg from production machines, behind which it is located, a recuperation exchanger into which water is pumped from the collecting sump. Polluted water, deprived of part of its heat energy, is discharged from the exchanger to waste. Clean, heated water is taken from the exchanger into an accumulation tank, from which the required amount of water is pumped back to eg production machines.

Claims (9)

Counter-current disc heat exchanger, characterized in that it consists of a closed tub (1) in which individual hollow discs (4) are provided on at least one hollow shaft (2) or tube (3), the inner space (5) of which is provided ) are interconnected and which are disposed in a waste medium, e.g. hot water, wherein the hollow shaft (2) or tube (3) is seated in a rotatable closed bath (1) and is provided with connection ports (6) for inlet and the inlet of the inlet medium, eg cold water, and the closed tub (1) is provided with connection flanges (7) for the inlet and outlet of the waste medium. Counter-current disc heat exchanger according to claim 1, characterized in that the hollow disc (4) is formed from a pair of shaped discs (10) in the form of discs connected to one another in several indentations (8) on at least one selected disc diameter. on the other hand, on the circumference (9) of these discs, the shaped lamellas (10) of adjacent hollow plates (4) being interconnected by means of spacers (13). A counter-current disc heat exchanger according to claim 2, characterized in that the first outer shaped lamella (11) and the last outer shaped lamella (12) of the hollow disk assembly (12) are formed. 4) is also connected to a spacer ring (13), to which at the same time a disc cap (14) is connected to one of its peripheries, the other periphery of which is connected to a hollow shaft (2) or tube (3) carrying a hollow disk assembly (4) . * · Ί ~ 4. Counter-current disc heat exchanger according to claim 2, characterized in that a lamella partition (15) is interposed between the pair of shaped plates (10), connected on the one hand to the pair of shaped plates (10) and the hollow shaft (2). or a pipe (3) supporting the array of hollow disks (4). Counter-current disk heat exchanger according to claim 1, characterized in that on the hollow shaft (2) or the tube (3) supporting the hollow disk system (4) there is a sprocket (17) connected by means of a chain (18) to the drive unit. 19). Counter-current disk heat exchanger according to claim 1, characterized in that between the individual hollow disks (4) there are bath partitions (16) arranged in opposite and alternating manner to both spacing of the hollow disks (4). Counter-current disc heat exchanger according to claim 1, characterized in that the hollow shaft (2) or the tube (3) supporting the hollow disk assembly (4) is supported at both ends with a rotation capability in the hollow body (20) provided before and after bearing (21) with plugs (22) and firmly connected to the machine frame, the hollow body (20) is connected to the connection socket (6) and the hollow shaft (2) or tube (3) is provided with at least one hole ( 23), resulting in an interior space (5) of the first hollow disk (41) and an interior space (5) of the last hollow disk (42) from the array of hollow disks (4). Counter-current disk heat exchanger according to claim 1, characterized in that the connecting flange (7) at the waste medium inlet of the closed bath (1) is covered on the inner wall of the closed bath (1) by an orifice (24) extending through its orifice (26). ) below the level of the waste medium in the closed tub (1). Counter-current disc heat exchanger according to claim 1, characterized in that the connection flange (7) at the outlet of the waste medium from the closed bath (1) is located below the waste medium level in the closed bath (1) and on the inner wall of the closed bath (1) ) covered by an overflow (25), whose upper open mouth (27) determines the level of waste medium in a closed tub (1)