EA002536B1 - Heat exchanger - Google Patents

Abstract

1. A heat exchanger of the type which includes a plurality of heat exchanger elements (1) carried by a frame and interconnected to one another in a flow system with a product flow and flow for a heat transfer medium, each heat exchanger element (1) displaying, on the one hand, one or more heat transfer tubes (3) interconnected by means of tube plates (4) to form product flow inserts (5), and, on the other hand, a casing tube (2) surrounding the heat transfer tubes (3), two adjacent product flow inserts (5) being interconnected with one another by means of product pipe bends, characterized in that two adjacent casing tubes (2) are interconnected by means of a connection member (10); and that the tube plates (4) constitute a part of the frame, flexibly interconnected with adjacent tube plates (4). 2. The heat exchanger as claimed in Claim 1, characterized in that the product pipe bend (6) is of elliptical cross section at the centre of the bend (6). 3. The heat exchanger as claimed in Claim 1, characterized in that the tube plates (4) have grooves (12) in their four corners, said grooves (12) corresponding with substantially cruciform coupling profiles (13). 4. The heat exchanger as claimed in Claim 3, characterized in that the coupling profiles (13) are of a thickness which gives the heat exchanger elements (1) the possibility of moving in their longitudinal direction. 5. The heat exchanger as claimed in Claim 1, characterized in that the connection member (10) consists of a straight tube section with an O-ring (11) in each end. 6. The heat exchanger as claimed in Claim 1, characterized in that the tube plates (4), together with a lower frame section (14), constitute the frame of the heat exchanger.

Description

Technical field

The present invention relates to a heat exchanger comprising a plurality of heat exchange elements supported by a frame and interconnected to each other in a flow system with a product duct and a duct for a heat transfer medium, wherein each heat transfer element is, on the one hand, one or more heat transfer tubes interconnected by means of pipe plates to form flow inserts for the product, and on the other hand, a casing pipe surrounding the heat transfer pipes, with two adjacent x flow inserts for the product are mutually connected to each other by means of pipe elbows for the product.

State of the art

Heat exchangers, of which many types exist at present, are used to heat or cool a certain liquid product, for example, using steam, water or another liquid at various temperatures. Heat exchangers are used in many industries, and have also become commonplace in food industries, such as dairies.

A well-known type of heat exchanger is the so-called tubular heat exchanger, which consists of one or more heat exchange elements interconnected by a flow system with a product duct and a duct for a heat transfer medium. The heat exchange element essentially consists of one or more heat transfer pipes surrounded by a tube of the outer casing. The heat transfer pipes are interconnected by a pipe plate to form a block, i.e. flow insert for the product. In turn, two adjacent flow-through inserts for the product are interconnected by pipe elbows for the product, forming a duct for the product to circulate the product, which is heated or cooled in the process. The tubes of the outer casing are also interconnected to circulate a heat transfer medium, such as water or another liquid, or steam, or, alternatively, other gases.

Recently, attempts have been made to make tubular heat exchangers of the aforementioned type in the form of separate modules in order to realize a simpler unit and to avoid adapting each heat exchanger pipe to this design. The essence of such a tubular heat exchanger is disclosed in the description of Swedish patent 8E 501908.

Objectives of the invention

One objective of the present invention is to further simplify the modular tubular heat exchanger of the type described above in order to make it possible to compete with plate heat exchangers, which are now on the market and much cheaper.

An additional objective of the present invention is the implementation of a tubular heat exchanger, which, despite its compact design, is configured to absorb thermal expansions that are always present in heat exchangers.

Another additional objective of the present invention is the implementation of a tubular heat exchanger, which is economical to manufacture and easy to install and maintain.

Decision

These and other problems were solved in accordance with the present invention due to the fact that a distinctive feature was introduced into the tubular heat exchanger of the type described above, namely, that two adjacent casing pipes are mutually connected by means of a connecting element, and that the pipe plates form part of the frame flexibly interconnected with adjacent pipe plates.

Preferred specific embodiments of the heat exchanger of the present invention are further reflected in the features set forth in the dependent claims.

Brief Description of the Drawings

Now, with reference to the accompanying drawings, a more detailed description will be given of one preferred specific embodiment of a heat exchanger in accordance with the present invention. In the accompanying drawings of FIG. 1 is a side view of a heat exchanger according to the present invention; FIG. 2 is a side view of a portion of a heat exchanger; FIG. 3 is a partial sectional side view of a pipe elbow for a product; FIG. 4 is a side view of a portion of a heat exchange element; FIG. 5 is a plan view of a pipe plate; FIG. 6 is a plan view of a connecting profile; FIG. 7-9 depict various projections of heat exchangers.

The accompanying drawings show only those parts and details that are essential for understanding the present invention.

FIG. 2 and 3 depict the design of a heat exchanger. A tubular heat exchanger according to the present invention consists essentially of one or more heat exchange elements 1. A heat exchanger usually consists of a number of these heat exchange elements 1 interconnected to each other in a flow system. The heat exchange element 1 consists of a pipe 2 of the outer casing, which surrounds one or more heat transfer pipes 3. The heat transfer pipes 3 are mutually connected to each other at each end of the pipes 3 by means of a pipe plate 4. A number of heat transfer pipes 3 with a pipe plate 4 at each end form flow insert 5 for the product. The pipe 2 of the casing at both ends is welded to each corresponding pipe plate 4.

FIG. 1 shows a number of heat exchange elements 1 interconnected to form a heat exchanger. This heat exchanger has a duct for the product, which is shown by white arrows, and a duct for the heat transfer medium, which is shown by black arrows. The heat transfer medium is designed to heat or cool the product, depending on the desired process. The heat exchange medium may consist of water, or another liquid of different temperature, or, alternatively, from steam or another gas. The heat exchanger of the present invention can also be used regeneratively, i.e. use the product in both ducts in such a way that the already heated product will heat the incoming cold product and vice versa.

The product stream circulates in the heat exchange tubes 3, which form the bulk of the product flow inserts 5. Two adjacent product flow inserts 5 are interconnected by a pipe elbow 6 for the product, wherein the product elbow is fastened with a flange to two adjacent pipe plates 4. The product elbow 6 preferably has an elliptical cross section in the center between the two flow inserts 5 for the product at point 7 and a circular cross section at both ends. Alternatively, the pipe elbow 6 for the product may have a circular cross section along its entire length. The elliptical pipe elbow 6 for the product corresponding to the foregoing is described in detail in Swedish Patent Application 8E 9703865-7.

The flow of heat transfer medium circulates through the pipes 2 of the casing. Near both ends of the casing pipes 2 have a circular hole 8 in the surface of the casing, provided with a collar 9. The collar 9 corresponds to the connecting element 10. The connecting element 10, which essentially consists of a straight tubular section, is beveled at both ends and is provided with a gasket or O-ring 11 of circular cross section. The beads 9 abut against the O-rings 11 of circular cross section at both ends of the connecting element 10 and form a sealed and somewhat flexible assembly.

The tube plate 4, which forms the product flow insert 5, is shown in FIG. 5. The plate 4 has modularly adapted overall dimensions, and is provided with grooves 12 in its four corners. The grooves 12 correspond to the connecting profile 13, which is shown in FIG. 6. The connecting profile 13 is essentially cruciform. The connecting profile 13 can connect two, three or four pipe plates 4.

Due to the fact that the pipe plates 4 in the heat exchanger are placed in close proximity to each other and are connected by connecting profiles 13, a stable block is obtained, which is a part of the heat exchanger frame. Various ways of arranging four heat exchange elements 1 are shown in FIG. 7-9. Heat exchange elements 1 are placed on the lower section 14 of the frame provided with adjustable legs 15. The lower section 14 of the frame has grooves 16 corresponding to the grooves 12 in the pipe plates 4. The pipe plates 4 are fixed to the lower section 14 of the frame by means of connecting profiles 13.

As a result of this design and the thickness of the connecting profiles 13, each individual heat exchange element 1 can move in its longitudinal direction. This is necessary because the heat exchange elements undergo strong thermal expansion. The connecting elements 10 to some extent can also move laterally, and experiments have shown that this will result in a tight connection, despite the oblique inclination to the O-rings 11 of circular cross section. A corresponding oblique tilt would not be possible, for example, in a flange connection.

As a result of this shape of the pipe bend 6 for the product with an elliptical cross section in the center of this pipe bend 6, an additional part of the heat exchanger will be obtained that is capable of absorbing thermal stresses, since the shape of the pipe bend 6 for the product acquires some flexibility. The corresponding pipe bend of circular cross-section generally does not have flexibility along its entire length.

Due to the use of modularly adapted pipe plates 4 with which it is possible to connect various pipes 2 of the casing, and due to the use of connecting elements 10 of different heights, a number of tubular heat exchangers with different throughput capacities that can be manufactured with a small number of simple parts will be obtained. Such a heat exchanger will be easy to assemble, and its maintenance will be simplified, since it will not be necessary to dismantle anything other than the heat exchange element 1 to be replaced.

The connecting element 10, located in the assembled heat exchanger, can be easily dismantled everywhere and whenever a certain control opportunity arises. In particular, this is important when the heat exchanger is used regeneratively, i.e. when the product passes to the product. The connecting element 10 can be easily installed, since such an installation is usually associated only with the removal of the sealing rings 11 of circular cross section. The connecting element 10 is also easy to manufacture, and this simplicity is ensured by the fact that the flexibility of the element 10 allows the use of wider tolerances.

In the case of possible cracking due to corrosion associated with mechanical stresses, which is a common situation in tubular heat exchangers with fixed joints between the pipes 2 of the casing, it is necessary to replace two pipes 2 of the casing. In the heat exchanger of the present invention, the risk of cracking is reduced due to the fact that the connecting element 10 can perceive part of the thermal expansion. If cracking does occur, only one pipe 2 of the casing must be replaced.

As is apparent from the foregoing description, the present invention allows for the implementation of a heat exchanger that is simple and economical to manufacture and which has great potential for perceiving the thermal expansion that occurs in the heat exchanger.

Claims (6)

CLAIM 1. A heat exchanger comprising a plurality of heat exchange elements (1) supported by a frame and interconnected with each other in a flow system with a flow FIG. 1 for a product and a duct for a heat transfer medium, wherein each heat exchange element (1) is, on the one hand, one or more heat transfer tubes (3) interconnected by tube plates (4) to form flow inserts (5) for the product, and on the other hand, a pipe (2) of the casing surrounding the heat transfer pipes (3), while two adjacent flow inserts (5) for the product are mutually connected to each other by pipe elbows for the product, characterized in that the two adjacent pipes (2) casing interconnected in the middle Twomey connecting member (10), and in that the tube plate (4) form part of the carcass are mutually flexibly connected to the adjacent tube plates (4). 2. A heat exchanger according to claim 1, characterized in that the pipe bend (6) for the product has an elliptical cross section in the center of this pipe bend (6). 3. The heat exchanger according to claim 1, characterized in that the pipe plates (4) have grooves (12) in their four corners, and the grooves (12) correspond to essentially cruciform connecting profiles (13). 4. The heat exchanger according to claim 3, characterized in that the connecting profiles (13) have a thickness that allows the heat exchange elements (1) to be moved in their longitudinal direction. 5. The heat exchanger according to claim 1, characterized in that the connecting element (10) consists of a straight pipe section with a sealing ring (11) of circular cross section at each end. 6. The heat exchanger according to claim 1, characterized in that the pipe plates (4) together with the lower section (14) of the frame form the frame of the heat exchanger.