SE0802541A1 - Device at a tube heat exchanger - Google Patents

Abstract

The invention relates to a device in a tubular heat exchanger (1) particularly intended for products containing fibres or particles. The device comprises a product flow insert (5) consisting of a number of heat transfer tubes (3) with a tube plate (6) fixedly secured in each end (10) of these heat transfer tubes (3). In order that fibres and particles pass the tube plates (6) without being accumulated in an undesirable manner, at least that one of the tube plates (6) which constitutes the inlet to the heat transfer tubes (3) is provided with flow distributors (11) which have a convex surface facing towards the flow direction and which have a portion (12) which partly covers the inlets to the heat transfer tubes (3).

Description

10 15 20 25 30 35 2 the accumulation restarts and in this way an uneven distribution of the fibers in the liquid. Heavy accumulations of fibers can also give rise to production disruptions and cleaning problems. Large particles can also cooperate to form plugs in the inlets to the individual heat transfer pipes.

A device to get out of these problems is described in it European patent specification EP 865 601. Flow distributors are arranged on the tube plates, so that the flow advantages completely or partially surround the ends of the heat transfer tubes. The flow advantages have convex surfaces towards the product so that you get funnel-shaped inlets to the heat transfer pipes. One device as described above works excellent pre-juicers with long fibers, but has the disadvantage that the flow advantages take up a lot of space, which limits the number of heat transfer tubes. Because the number of heat transfer tubes is limited, this device is also not suitable for use regeneratively.

An object of the present invention is to design the tube plates so that more heat transfer tubes can be connected to the tube plate with the retained diameter of the tube plate.

Another object of the present invention is to provide an increased number of heat transfer tubes per product insert gets a more efficient heat exchanger, too for products with long fibers.

Another object of the invention is to increase the number of heat transfer tubes can be adapted so that the device according to the invention can be used regeneratively.

These and other objects have been achieved according to the invention by the device of the type initially described, the characteristics are given that the flow advantages partially cover the inlets to the heat transfer pipes.

Preferred embodiments of the invention have further been given the requirements of the subclaims.

A preferred embodiment of the invention will now become more apparent described with reference to the accompanying drawings of which: Fig. 1 shows the principle of a tube heat exchanger Fig. 2 shows, partly in section, a tube plate with possible number heat transfer pipes according to prior art Fig. 3 shows the principle of flow distributor according to prior art Fig. 4 shows, partly in section, a tube plate with possible number heat transfer pipes according to the invention Fig. 5 shows the principle of flow distributor according to the invention.

The drawings show only those essential for the understanding of the invention the details. 10 15 20 25 30 35 3.

Fig. 1 shows the principle of a tube heat exchanger 1, where one or usually one a plurality of heat exchanger elements 2, are connected to a flow unit. Each heat exchanger element 2 consists of a number of heat transfer tubes 3 surrounded by one outer jacket pipe 4. The heat transfer pipes 3 in each jacket pipe 4, are joined to a product insert 5 in that at each end 10 of the heat transfer tubes 3 are arranged a tube plate 6. The product inserts 5 with their heat transfer tubes 3 are intended to circulate the product to be treated in the heat exchanger 1. They different product inserts 5 are connected to each other by means of product bends 7 and the outer product inserts 5 are connected by inlet and inlet respectively outlet lines for the product. Such a large number is sought heat transfer tube 3 which can be enclosed in the jacket tube 4, taking into account taken to the product to be circulated. A product containing particles or fiber requires a pipe diameter on the heat transfer pipes, 2-2.5 times the particle size of the product. The more and the smaller heat transfer tube 3 that gets space in the jacket pipe 4, the more efficient heat transfer is obtained.

It is enclosed in the product tube 4 surrounding the product inserts 5 heat transfer media used, i.e. water or other liquid of various temperatures, alternatively water vapor or other gas. The jacket pipes 4 connected in turn with communicating perpendicular pipe sections 8, alternatively with inlet or outlet connections for the heat transfer medium. The product efforts 5 are fitted in the jacket pipe 4 with seals 9 so that product and heat transfer media are kept separate.

When the product reaches a product insert 5, either via a product bend 7 or a inlet line, the product at the tube plate 6 must be distributed into the different ones heat transfer tubes 3. The ends 10 of the heat transfer tubes 3 are fixed in tube plate 6. For products with particles and elongated fibers, such as orange juice, flow distributor 11 is required so that the fibers of the product do not peel "Hang" between the ends 10 of the heat transfer pipes 3. The flow advantages 11 allows the fibers to orient and distribute before accompanying the product in the heat transfer tubes 3.

Without flow distributor 11, when processing a product with long fibers, production must be stopped regularly and the plant washed, and that during the washing process, reverse the flow direction through the tube heat exchanger 1 for to thus wash away fibers that "hung".

Fig. 2 shows a tube plate 6 according to prior art. The flow benefits 11 are not drawn, but the drawing shows only the number of heat transfer pipes 3 that is possible to connect to a tube plate 6 of a certain diameter. In Fig. 3 which is a partial enlargement of Fig. 2 shows the flow advantages 11 which occupy a certain surface 10 15 20 25 30 35 4 tube plate 6 and thus limits the number of heat transfer tubes 3 possible to connect. As shown in Fig. 2, only three heat transfer tubes 3 can fit along the diameter of a given tube plate 6.

Fig. 4 shows a tube plate 6 according to the invention. The flow benefits 11 are not drawn but the drawing only shows the number of heat transfer tubes 3 that are possible to connect to a tube plate 6 of the same diameter as the tube plate in Figs. Fig. 5, which is a partial enlargement of Fig. 4, does not show the flow advantages 12 occupies an equal area and thus does not limit the number of heat transfer pipes in to the same extent.

Fig. 4 shows five heat transfer tubes 3 along the diameter of the tube plate 6.

The invention can also be used for tube plates 6 with up to seven heat transfer tube 3 along the diameter. This is a big advantage because the more and smaller heat transfer tube 3 which can fit in the jacket tube 4, the larger heat transfer surface you get and thus a more efficient heat exchanger 1.

As shown in Fig. 5, the flow advantages 11 have been designed so that a part 12 of them partially cover the inlets to the heat transfer pipes 3.

The flow benefits 11 have convex surfaces facing the flow direction.

The parts 12 of the flow manifolds 11 which surround the ends of the heat transfer pipes 3 10, are softly rounded, so that no "sharp" or sharp edges are present where the product flows past. The flow advantages 11 have a "sponge-shaped" appearance in side view.

The flow advantages 11 according to the invention allow one to process one product with long fibers, without having to stop production regularly and reverse the flow direction through the tube heat exchanger 1 so as to flush out fibers that "hung".

Because you sometimes want to use a tube heat exchanger regeneratively, have this has not been possible in the case of fiber products because the number heat transfer tube 3 is limited by the previously used flow advantages 11. Regenerative use of a tube heat exchanger 1 means making a sound product flow both in the heat transfer pipes 3 and in the surrounding area the jacket pipe 4. An already heated product can then heat an incoming cold product, while the heated product cools down. This means one energy saving and is often used where possible. However, the product should flowing in the heat transfer tubes 3 relate to the product in which flows in the jacket pipe as 1: 1. Then the flow advantages 11 according to the invention enables a larger number of heat transfer tubes 3, product inserts 5 can be selected which provides a relationship between the heat transfer tubes 3 and the casing tube 4 lying close to 1: 1. 10 15 20 5 Experiments have shown that fibers in, for example, ape | sinjuice preferably “hang ”at the entrance to the heat transfer pipes 3 located in the center of the tube plate 6. Thus, one can design the tube plate 6 in relation to the product which the tube heat exchanger 1 should be used for, so that only the middle ones the ends 10 of the heat transfer tubes 3 are provided with flow distributors 11.

As stated in the above description, the device according to the invention an opportunity to use a tube heat exchanger and more heat transfer tubes per tube plate for products containing particles and long fibers. The invention allows the fibers to be smoothly and efficiently guided into heat transfer tubes, without the risk of the fibers accumulating on the tube plate.

The invention also allows the tube heat exchanger to be run regeneratively products with long fibers.

Claims (4)

10 15 20 25 PATENT REQUIREMENTS Device at a tube heat exchanger (1), comprising a product flow insert (5) consisting of a number of heat transfer tubes (3), with a tube plate (6) arranged at each end (10) of the heat transfer tubes (3), where at least that of the tube plates ( 6), which constitute inlets to the heat transfer tubes, are formed with flow distributors (11), which surround the ends (10) of the heat transfer tubes (3), and that the flow distributors (11) are designed so that the surface of the flow distributors (11) facing the flow direction is convex , characterized in that the flow advantages (11) partially cover the inlets to the heat transfer pipes (3). Device at a tube heat exchanger (1) according to claim 1, characterized in that the flow advantages (11) have a sponge-shaped appearance. Device at a tube heat exchanger (1) according to claim 1, characterized in that the flow advantages (11) have a softly rounded part (12) which partially covers the inlets of the heat transfer pipes (3). Device at a tube heat exchanger (1) according to claim 3, characterized in that only the heat transfer tubes (3) located in the middle part of the tube plate (6) are provided with flow distributors (11).