EP2113732A1 - Mixer-heat exchanger - Google Patents

Abstract

The exchanger (40) has a set of heat exchanger pipes (16) arranged in a flow channel (22) in longitudinal axis (x). The heat exchanger pipes cross static mixing elements positively over openings, where the mixing elements are pair-wisely crossed bar plates. The heat exchanger pipes and the mixing elements are movable relative to each other in the longitudinal direction to produce scraping movement on the surface of the heat exchanger pipes. The mixing elements are back and forth movable over a common operating unit (30) in the longitudinal axis of the flow channel.

Description

Technical area

The invention relates to a mixer heat exchanger for heating and cooling of flowable materials, arranged in a flow channel in a longitudinal axis of heat exchanger tubes and static mixing elements, wherein the heat exchanger tubes pass through the mixing elements substantially form-fitting openings.

State of the art

Heat exchange devices are known in many designs and common in the industry. Most heat exchangers have turbulent flow conditions.

Known heat exchangers are tube bundle heat exchangers which are additionally equipped with static mixing elements on the inside in order to additionally improve the heat transfer at the tube wall.

Thanks to static mixer heat exchangers, viscous liquids can be continuously processed with basic operations such as mixing, heat and mass transfer or chemical reaction technology. The high heat transfer capacity of static mixer heat exchangers and the excellent mixing performance in the laminar flow range allow use as a heat exchanger or reactor.

Due to the achieved, very high Nusselt number and the large surface through the tube bundle, the mixer heat exchanger has an excellent volume-related heat transfer capacity. Another special feature of the mixer heat exchanger is the setting of a perfect temperature profile when exiting the heat exchanger, even for liquids with a viscosity>1'000'000 mPas. The reason lies in the very high mixing performance, which far exceeds the mixing performance of conventional heat exchangers.

• Heizen und Kühlen im laminaren Strömungsbereich.
• Heizen und Kühlen von Ölen bei grösseren Betriebsdrücken.
• Zur Verarbeitung und Herstellung von Klebstoffen und Harzen.
• Kühlen von Schmelzen für die Chemiefaserindustrie.
• Zur Temperierung von Polyol und Isocyanat.
• Zur Temperaturüberwachung von Kunststoffschmelzen und Kunststoffschäumen.
• Zur Herstellung von Nahrungsmittel, hauptsächlich aus der Süsswaren- und Milch verarbeitenden Industrie.
• Zur externen Kühlung von gerührten Tankreaktoren.
• Zur kontinuierlichen Reaktionsführung.

Mixer heat exchangers are used, among others, for the following applications:

• Heating and cooling in the laminar flow range.
• Heating and cooling of oils at higher operating pressures.
• For processing and manufacturing adhesives and resins.
• Cooling of melts for the chemical fiber industry.
• For temperature control of polyol and isocyanate.
• For temperature monitoring of plastic melts and plastic foams.
• For the production of foodstuffs, mainly from the confectionery and milk processing industry.
• For external cooling of stirred tank reactors.
• For continuous reaction.

It is known that substances can change under the influence of temperature or during the residence time in the mixer-heat exchanger. The changing substances can lead to deposits in the form of a thin layer on the heat exchanger tubes. Such deposits, also known as "fouling", can only insufficiently remove a static mixer heat exchanger itself. The increase in the deformation rate by briefly increasing the flow rate is often not sufficient because the deformation rate can not be increased as desired due to increasing pressure loss. In many applications, it is therefore essential dismantle the mixer-heat exchanger from time to time and remove the fouling on the heat exchanger tubes, thereby again improving the heat transfer capacity.

Presentation of the invention

The invention has for its object to provide a mixer-heat exchanger of the type mentioned in the deposits on the surface of the heat exchanger tubes can be removed mechanically without disassembly of the heat exchange device in a simple manner.

To the inventive solution of the problem results in that the heat exchanger tubes and the mixing elements for generating a scraping motion on the surface of the heat exchanger tubes are displaceable relative to each other in the longitudinal axis.

The mixer heat exchanger comprises at least one heat exchanger tube and a mixing element. The mixing elements are for example pairs of crossed web plates.

In a preferred embodiment, the mixing elements are movable back and forth via a common actuating rod in the longitudinal axis of the flow channel.

Suitably, the heat exchanger tubes are closed on one side, wherein in the heat exchanger tubes protruding lances are provided for a heat exchange medium. However, the heat exchanger tubes can also be returned in a U-shape to the beginning of the tube; in this case, no lances are required.

To produce the cleaning scraping effect, slidable cleaning bodies can additionally be placed on the heat exchanger tubes.

Instead of the mixing elements and the heat exchanger tubes in the longitudinal axis of the flow channel can be moved back and forth.

But the mixing elements can also be moved back and forth by changing the flow direction in the longitudinal axis of the flow channel.

A device for heating and cooling flowable materials may also comprise a multiplicity of parallel mixer heat exchangers.

Short description of the drawing

Fig. 1

eine Schrägsicht auf ein Rohrbündel mit aufgesteckten Mischeinsätzen eines Rohrbündelwärmetauschers;

Fig. 2

einen Längsschnitt durch einen erfindungsgemässen MischerWärmetauscher;

Fig. 3

ein Detail von Fig. 2 in vergrösserter Darstellung;

Fig. 4

eine Prinzipskizze einer Anordnung mit parallel geschalteten, erfindungsgemässen Mischer-Wärmetauschern.

Further advantages, features and details emerge from the following description of an embodiment and with reference to the drawing; this shows in

Fig. 1

an oblique view of a tube bundle with plugged mixing inserts a tube bundle heat exchanger;

Fig. 2

a longitudinal section through a mixer according to the invention heat exchanger;

Fig. 3

a detail of Fig. 2 in an enlarged view;

Fig. 4

a schematic diagram of an arrangement with parallel, inventive mixer-heat exchangers.

Description of exemplary embodiments

Four in Fig. 1 shown, in its longitudinal axis m adjacent one another Length L having mixing inserts 10, 12 for flowing in a flow channel media are traversed by a tube bundle 14 with parallel to the longitudinal axis m arranged heat exchanger tubes 16. Each mixing insert 10, 12 has a plurality of intersecting web plates 18 A, 18 B. The web plates 18 A, 18 B all have an equal width and lie in parallel to each other with the same intermediate or web spacing a arranged planes that form two intersecting plateaus. The planes each include an equally large angle of 45 ° with the longitudinal axis m. The adjoining mixing inserts 10, 12 are arranged alternately rotated by an angle of 90 ° about its longitudinal axis m against each other.

Out Fig. 1 is readily apparent that each in the longitudinal axis m performed relative movement of a heat exchanger tube 16 to a web plate 18 A, 18 B, which is traversed by the heat exchanger tube 16 via an opening 20, because of the virtually positive engagement of the opening edge of the opening 20 on the heat exchanger tube 16 a scraping process leading to the pipe surface.

To produce the cleaning scraping action, in addition to the web plates 18 A, 18 B, provided with a corresponding opening, slidable plates can be placed as a cleaning body on the heat exchanger tubes 16.

Fig. 2 shows a mixer-heat exchanger 40. The mutually rotated by an angle of 90 ° about its longitudinal axis m mixing inserts 10, 12 are arranged in a tubular flow channel 22 with an inner circumferential surface 24 with a circular cross-section and a pipe or Strömungskanallängsachse x of the mixer-heat exchanger 40 , In this case, the longitudinal axes m of the mixing inserts 10, 12 lie in the longitudinal axis x of the flow channel 22.

All web plates 18 A, 18 B extend within each mixing insert 10, 12 via their respective through the end faces of the mixing inserts 10, 12 and limited by the inner circumferential surface 24 of the flow channel 22, maximum possible length, wherein the contour of the web plates 18 A, 18 B is adapted to the circular cross-section of the flow channel 22 so that the web plates 18 A, 18 B with a small clearance to the inner circumferential surface 24 of the flow channel 22 adjacent.

The heat exchanger tubes 16 pass through the web plates 18 A, 18 B via arranged in these openings 20 which have according to the angle between the web plate 18 A, 18 B and heat exchanger tube 16 an elliptical edge boundary. The web plates 18 A, 18 B are connected at their intersections at least partially via soldering or welding points.

When assembling the mixer-heat exchanger 40, the individual mixing inserts 10, 12 by the crossed arrangement of the corresponding number of web plates 18 A, 18 B prefabricated. The prefabricated mixing inserts 10, 12 are rotated by 90 ° against each other in their longitudinal axis m strung together. Subsequently, the heat exchanger tubes 16 are pushed parallel to the longitudinal axis m through the openings 20 of the web plates 18 A, 18 B therethrough. Two diametrically opposite fixing rods 26 - these may also be formed by heat exchanger tubes 16 - are soldered or welded points on the web plates 18 A, 18 B attached and used to fix the mixing inserts 12, 14, so that they by appropriate actuation of the fixing rods 26 together in the flow channel longitudinal axis x back and forth are displaced. The two fixing rods 26 are connected at one end via a crossbar 28. On the crossbar 28 centrally centrally arranged in the flow channel longitudinal axis x actuating rod 30 is fixed. The insert thus manufactured is inserted from one side of the mixer-heat exchanger 40 in the flow channel 22, wherein the actuating rod 30 is led out on the other side via a fluid-tight passage 32 in an end wall 34 of the mixer-heat exchanger 40 from this.

How out Fig. 3 As can be seen, the heat exchanger tubes 16 are open at one end and closed at the other end via a bottom 17. The heat exchange medium is here via one in each heat exchanger tube 16 used lance 36 whose free end is led to just before the closed bottom 17 of the heat exchanger tube 16, via a flanged on an end face of the mixer-heat exchanger 40 inlet pipe stub 42 via a gap 43 at the same time introduced lances 36 and flows back after exiting the lances 36 at the bottom 17 of each heat exchanger tube 16 within the lance 34 and inner wall of each heat exchanger tube 16 in the opposite direction, exits from the open ends of the heat exchanger tubes 16 in a second space 44 and leaves the mixer-heat exchanger 40 via a preferably laterally on the intermediate space 44 arranged outlet pipe 46. In U-shaped course of the Wärmetauscherrohre16 the outlet pipe socket 46 may also be arranged centrally.

The mixture to be mixed in the mixer heat exchanger 40 and / or brought to a reaction mixture is introduced via a laterally arranged on the mixer heat exchanger 40 inlet pipe socket 48 and flows through the flow channel 22 on the web plates 18 A, 18 B of the mixing inserts 10, 12 passing the Heat exchanger tubes 16 along the d the inlet pipe stub 48 remote end wall 34 of the mixer-heat exchanger 40 and exits there through a laterally arranged outlet pipe stub 50 as a reaction product from the mixer heat exchanger 40. For better flow control of the inlet pipe stub 48 in the flow channel 22 and to avoid a dead volume opposite the inlet port 48, a corresponding volume part is provided as a deflecting 38.

The ends of the lances 36 with the inlet openings for the heat exchange medium are fluid-tightly inserted into a common bottom plate 52, which is sealed by a seal 53 against the second gap 44. Likewise, the heat exchanger tubes 16 are fluid tightly inserted at their open ends into a common end plate 56 defining the gap.

To remove, for example, decomposition products which form deposits adhering to the outer surface of the heat exchanger tubes 16, the mixing inserts 10, 12 which are connected to one another via the fixing rods 26 are moved back and forth by means of the actuating rod 40 from time to time. Here, the heat exchanger tubes 16 over the edge of their openings 20 practically form-fitting enclosing web plates 18 A, 18 B pulled over the surface of the heat exchanger tubes 40 and pushed. By scraping movement of the opening edges of the openings 20 in the web plates 18A, 18B entering this mixing back and forth of the mixing inserts 10, 12, the deposits are mechanically removed from the pipe surfaces. This process can be done without disassembly of the mixer-heat exchanger 40 and in most cases, even without interruption to be performed manually or automatically.

It should be mentioned here that in principle no mechanical aids such as fixing and operating rods are required for the reciprocating movement of the mixing inserts 10, 12. The movement can also be effected solely by the pressure loss or a brief reversal of the flow direction.

Fig. 4 schematically shows an arrangement with two parallel mixer heat exchangers 40 a, 40 b. The mixture of substances to be treated is supplied to the individual mixer heat exchangers 40 a, 40 b via a central supply line 56 and via branching off of these distribution lines 58 a, 58 b. In each of the manifolds 58 a, 58 b is a valve 60 a, 60 b for individually opening and closing the manifolds 58 a, 58 b provided. Temperature sensors T at the output of each mixer heat exchanger 40 a, 40 b, the temperature of the reaction product is measured continuously. With increasing deposits on the heat exchanger tubes 16, the temperature of the reaction product changes, so that the exceeding or falling below a predetermined temperature limit for the output of a signal or directly used for the automatic triggering of the cleaning process can.

So that a cleaning can be made without malfunction, for example, only one mixer-heat exchanger 40 a, 40 b after previous closure of the corresponding valve 60 a, 60 b cleaned.

The outlet lines 62 a, 62 b of the individual mixer heat exchangers 60 a, 60 b are combined to form a central drain line 64 for the reaction product. In the central drain line 64, a mixer 66 is connected to compensate for different temperatures. A temperature control of the reaction product after passing through the mixer 66 via a further temperature sensor T.

In the example of Fig. 4 The device shown is merely illustrative and is not limited to two parallel mixer heat exchangers 40 a, 40 b. Depending on the desired capacity or frequency of the cleaning intervals, a device with three and more parallel mixer heat exchangers may be displayed.

LIST OF REFERENCE NUMBERS

10

mixed use

12

Mixing insert, turned 90 °

14

tube bundle

16

Heat exchanger tubes

17

ground

18 A, B

wall sheets

20

openings

22

flow channel

24

Inner surface area

26

fixing bars

28

crossbar

30

actuating rod

32

execution

34

bulkhead

36

lances

38

deflecting

40, 40 a, b

Mixer-heat exchanger

42

Inlet pipe connection

43

first gap

44

second space

46

outlet connector

48

Inlet pipe connection

50

outlet connector

52

baseplate

53

poetry

54

endplate

56

feed

58 a, b

distribution lines

60 a, b

valves

62 a, b

outlet lines

64

drain line

66

mixer

L

Length of 10, 12

T

temperature sensor

a

Intermediate distance (distance between bars)

m

Longitudinal axis of 10, 12

x

Longitudinal axis of 22

Claims (9)

Mixer heat exchanger for heating and cooling of flowable materials, with in a flow channel (22) in a longitudinal axis (x) arranged heat exchanger tubes (16) and static mixing elements (18), wherein the heat exchanger tubes (16) the mixing elements (18) substantially positive fit pass through openings (20),
characterized in that
the heat exchanger tubes (16) and the mixing elements (18) for generating a scraping movement on the surface of the heat exchanger tubes (16) relative to each other in the longitudinal axis (x) are displaceable. Mixer heat exchanger according to claim 1, characterized in that it comprises at least one heat exchanger tube (16) and a mixing element (18). Mixer heat exchanger according to claim 1 or 2, characterized in that the mixing elements (18) are pairwise crossed web plates (18 A, 18 B). Mixer heat exchanger according to one of claims 1 to 3, characterized in that the mixing elements (18) via a common actuating means (30) in the longitudinal axis (x) of the flow channel (22) are movable back and forth. Mixer heat exchanger according to one of claims 1 to 4, characterized in that the heat exchanger tubes (16) are closed on one side and in the heat exchanger tubes (16) projecting lances (36) are provided for a heat exchange medium. Mixer heat exchanger according to one of claims 1 to 5, characterized in that for generating the cleaning scraping effect on the heat exchanger tubes (16) additionally slidable cleaning body are placed. Mixer heat exchanger according to one of claims 1 to 3, characterized in that the heat exchanger tubes (16) in the longitudinal axis (x) of the flow channel (22) are movable back and forth. Mixer heat exchanger according to one of claims 1 to 3, characterized in that the mixing elements (18) by changing the flow direction in the longitudinal axis (x) of the flow channel (22) are reciprocally movable. Device for heating and cooling of flowable materials, comprising a multiplicity of parallel-connected mixer heat exchangers (40a, 40b) according to one of the preceding claims.

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