EP3532793B1 - Installation setup and method for automated cleaning of finned heat exchangers - Google Patents

Description

The invention relates to a method for the automated cleaning of lamellar heat exchangers. The invention also relates to an installation arrangement with a lamellar heat exchanger and a cleaning device for the lamellar heat exchanger.

Various methods are known and available for cleaning lamellar heat exchangers and other sensitive surfaces. For the automatic cleaning of these lamellar heat exchangers, mostly water jet nozzles are used, which are installed next to one another and are automatically guided over the surfaces to be cleaned with a pressure of, for example, 50 bar or more. For the operation of the nozzles, relatively large amounts of water are required, which must be provided and disposed of or treated. Due to the relatively low speed of the water as it exits the nozzle and the high density of the water, there is also a braking effect in the narrow channels of the lamellar heat exchanger. It leads to the fact that the water shows a good cleaning effect on the front side. The cleaning effect decreases with increasing Entry into the heat exchanger, that means more and more with greater depth. As a result, the front is clean. The cleaned lamellar heat exchanger, however, has poor passage values. This leads to greatly increased cleaning costs or to the fact that, because of the lack of heat dissipation through the lamellar heat exchanger, the output of a unit that interacts with the lamellar heat exchanger, for example a turbine output, has to be throttled. In addition, if the water jet hits the finned heat exchangers, the sensitive fins can be damaged.

From the DE 10 2012 014 605 A1 and the EP 2 877 806 A1 processes are known in which air is used as the carrier gas and a small amount of liquid added to the carrier gas is used as a blasting agent for cleaning heat exchangers. The jet nozzles used here are preferably designed as convergent-divergent Laval nozzles. The high jet speed, which can reach supersonic speed, ensures that the jet medium penetrates the entire depth of the heat exchanger. In addition, if the speed is adjusted, an additional cavitation effect can occur. This leads to a complete or almost complete removal of existing dirt residues.

From the EP 2 317 274 A2 a cleaning device for a heat exchanger is known which provides a longitudinally displaceable conductor and a nozzle assembly with a plurality of nozzles provided between the conductor and an upper side of the heat exchanger to be cleaned. The nozzle assembly with the nozzles is held displaceably along the ladder.

From the WO 2016/020705 A1 a cleaning device for a condenser of a heat exchanger is known. Here, the cleaning device itself provides a receptacle for a cleaning tool, which is held displaceably along a traverse of the cleaning device. The traverse is also held displaceably on two longitudinal bars of the cleaning device.

The object of the present invention is to provide an improved method for the automated cleaning of lamellar heat exchangers as well as a Specify installation arrangement with a lamellar heat exchanger and a cleaning device.

The method according to claim 1 and the installation arrangement according to claim 8 serve to solve the problem.

The invention provides a method for the automated cleaning of lamellar heat exchangers or other sensitive surfaces, a movement device preferably moving on rollers or runners, to which a support arm is attached, being moved up and down on a guide unit consisting of at least one and preferably two guide rails the at least one and preferably a plurality of jet nozzles are attached so that they are preferably via the movement device by means of an additional drive unit A roller attached to another end or a toothed wheel next to the guide unit are moved, whereby a carrier gas, preferably compressed air, and a liquid, preferably water, as a blasting agent, are supplied through supply hoses at a pressure of at least 2 bar, whereby the amount of water supplied is less than 1% , is preferably less than 0.30% of the amount of air supplied

The particular advantage of the invention is that the automated cleaning of the lamellar heat exchangers or other sensitive surfaces can be carried out quickly, completely, inexpensively and with a high quality. A blasting medium with the carrier gas and the blasting agent ensures a good cleaning effect. At the same time, cleaning is very resource-efficient due to the small amount of water.

The cleaning is preferably carried out with a maximum pressure for the carrier gas of 16 bar. A volume flow essentially depends on the pressure and a smallest cross section of the jet nozzle. It is, for example, 6 m ³ / min at a pressure of 6 bar. The travel speed is preferably in the range from 10 to 450 mm / sec. The pressure of the liquid supplied as blasting agent is above the pressure of the carrier gas. The jet nozzle is designed, for example, as a convergent-divergent jet nozzle and then preferably as a Laval nozzle. For example, the nozzle can provide an annular opening gap for the blasting medium as well as a mixing chamber for the carrier gas and the blasting medium and a blasting medium distribution space surrounding the mixing chamber in sections in an annular manner. The provision of the mixing chamber and the blasting agent distribution space, which in any case is in the form of a ring segment, promote thorough mixing of the carrier gas with the blasting agent. The good mixing ensures an improved homogeneity of the blasting medium and improves the cleaning effect.

According to a preferred embodiment of the invention, the guide unit with the guide rails is fixed to a stair or bridge unit that can be rolled or pushed over the length of the exchanger. In particular, large lamellar heat exchangers that are inclined relative to the horizontal are advantageously often equipped with stair or bridge units, for example for inspecting the heat exchangers. These can be in a longitudinal direction of the The heat exchanger can be moved. The method can be carried out very easily and inexpensively if the existing structural components are reused and the mobility or displaceability of the stair or bridge unit is used to move the movement device with the jet nozzles attached to it.

According to a further development of the invention, the jet nozzles are attached to a vertically and laterally adjustable holder on the support arm. The cleaning method can advantageously be adapted to different local conditions through the height adjustment or the lateral adjustment. For example, it may be necessary to adapt a cleaning device only in the area of the holder.

According to a further development of the method, a control for carrying out the method is operated in an automated manner in such a way that the guide unit moves together with the staircase or bridge unit and, for this purpose, coordinates the movement device via the drive unit in the guide rails of the guide unit so that the jet nozzles are moved up and down Thoroughly clean the entire surface of the finned heat exchanger. A movement in particular of the movement device in the guide rails can preferably take place continuously at a constant or variable speed. The stair or bridge unit can be moved step by step or continuously. For this purpose, a pulling device is preferably actuated by the control, which moves the stair or bridge unit in the longitudinal direction of the lamellar heat exchanger, for example via a pull rope. For example, the staircase or bridge unit can be designed to be self-propelled and provide a drive that interacts with the controller.

According to a further development of the invention, the control can simultaneously vary the pressure and the amount of the blasting medium (carrier gas and blasting agent) and in particular also coordinate the travel speed of the movement device in the longitudinal direction of the lamellar heat exchanger and perpendicular thereto. To control the pressure and the amount of the blasting medium or at least individual components of the blasting medium, safety or control devices, in particular sensors, can be provided. Likewise, the When moving the stair or bridge unit or movement device, the mechanical (tensile) forces are monitored by sensors.

According to a further development of the invention, a plurality of jet nozzles are used for cleaning the lamellar heat exchanger and different jet media are used for the various jet nozzles. For example, a preferably water-soluble cleaning agent is added in addition to the water in a jet nozzle at the front in relation to a travel direction of the staircase or bridge unit. For example, small amounts of liquids such as surfactants and / or enzymes and / or bacteria and / or neutral, alkaline or acidic liquid additives are used as blasting agents. The jet nozzle at the rear in relation to the direction of travel then sits in, for example, water as the blasting agent and removes residues of the previously used blasting agent.

When using different different blasting media, different blasting nozzles adapted to the different blasting media can be used. The travel speed or the advance of the can be selected in such a way that repeated treatment of the surfaces of the heat exchanger is ensured.

According to a further development of the invention, the lamellar heat exchanger is cleaned in two stages. In a first cleaning stage, a first partial surface of the lamellar heat exchanger is cleaned at a first, low speed by two or more jet nozzles that are spaced apart from one another. In a second cleaning stage, the speed is then increased and another, second partial area of the lamellar heat exchanger is cleaned. In the first and the second cleaning stage, individual cleaning nozzles can be switched off at least optionally. Two-stage cleaning is preferred if, due to the length of the jet nozzles, they have to be installed on the side of the stair or bridge unit and, due to the limited mobility of the stair or bridge unit, full-surface cleaning of the lamellar heat exchanger is only possible if on both opposite long sides the stair or bridge unit has at least one jet nozzle installed. It can be provided in the two-stage cleaning process that during the first Cleaning stage all jet nozzles are activated to clean the lamellar heat exchanger. The first cleaning stage lasts until the rear jet nozzles in relation to the direction of travel of the staircase or bridge unit in the longitudinal direction of the heat exchanger are guided into the area of the lamellar heat exchanger that has already been cleaned by the jet nozzles in the direction of travel. The second stage of cleaning is then activated, with in any case individual jet nozzles, namely preferably the jet nozzles at the rear in the direction of travel, being deactivated and cleaning being carried out solely by the front jet nozzles. It is particularly advantageous here if the number of front jet nozzles is greater than the number of rear jet nozzles. The cleaning in the second cleaning stage can then be carried out at a greater speed than in the first cleaning stage. Overall, this reduces the time required for cleaning.

On the device side, the invention provides an installation arrangement with at least one lamellar heat exchanger device, which has a horizontally lying, vertically oriented or inclined at an acute angle to the horizontal lamellar heat exchanger with two opposite passage surfaces and a plurality of passage channels, which from a first passage surface of the lamellar heat exchanger a second passage surface are performed. Furthermore, a cleaning device is provided comprising a guide unit with at least one guide rail, which is arranged to extend parallel or approximately parallel to the first passage surface and / or to the second passage surface, comprising a movement device guided on the guide rail with a support arm, with at least one on the support arm attached jet nozzle, which is oriented so that a blasting agent emerging from the jet nozzle hits the passage surface of the lamellar heat exchanger facing the jet nozzle at an angle of ± 20 ° to the surface normal, and with a drive unit for moving the movement device along the guide rail and comprising a feed device with at least one supply hose for the blasting medium supplied to the blasting nozzle, which provides a carrier gas and a small amount of the carrier gas supplied as blasting medium liquid. Furthermore, the installation arrangement has a controller for controlling the movement of the movement device and / or a quantity throughput for the blasting medium.

In this case, the guide unit with the movement device fixed in the guide unit is provided movably in a longitudinal direction of the lamellar heat exchanger and the control of the movement of the movement device is operated in such a way that all passage channels of the lamellar heat exchanger are exposed to the blasting medium and cleaned. The longitudinal direction preferably extends horizontally.

The particular advantage of the invention is that the automated cleaning of a lamellar heat exchanger of a heat exchanger device can take place in a particularly simple, quick and economical manner. For this purpose, a movement device with the jet nozzles attached is guided horizontally and perpendicularly over the lamellar heat exchanger in such a coordinated manner that the passage channels of the lamellar heat exchanger are cleaned by the blasting medium (carrier gas + blasting agent).

The cleaning device of the installation arrangement according to the invention can be designed to be exchangeable in such a way that it is temporarily attached to a heat exchanger device with a stair or bridge unit to clean the heat exchanger device. This reduces the investment costs and the amortization period.

According to a preferred embodiment of the invention, the horizontal movement of the movement device takes place in the longitudinal direction of the lamellar heat exchanger with the aid of a stair or bridge unit, which is often provided as part of the heat exchanger device anyway. For this purpose, the guide unit is fixed to the stair or bridge unit. The guide rails of the guide unit are preferably extended transversely to the longitudinal direction of the lamellar heat exchanger. To this extent, the movement device can be guided over the surfaces of the lamellar heat exchanger in two orthogonal directions and independently of one another.

Since the jet nozzles used to carry out the method according to the invention are preferably designed as flat nozzles for the required area performance, these jet nozzles are typically very long because of the required flow guidance. This complicates the automated use as well as that for the generation and supply of compressed air required relatively stiff supply hoses. The jet nozzles are therefore preferably moved next to the guide unit. The guide rails of the guide unit can consist, for example, of U-rails in which the movement device is guided longitudinally on rollers, for example. The movement device can be moved, for example, by means of a winch with a cable pull, by means of a driven toothed belt, a toothed rack or a pull chain. In addition, the entire guide unit can be guided over the surface to be cleaned using a further pulling device. For this purpose, the guide unit can be attached to the staircase or bridge unit or to another process unit, which is then drawn, including the guide unit, over the entire length of the heat exchanger.

For example, the heat exchanger device is designed in the manner of a V heat exchanger device or an inverted V heat exchanger unit with two lamellar heat exchangers positioned at an acute angle to one another. For example, the heat exchanger device can provide a horizontal, that is to say horizontally extending, lamellar heat exchanger or a vertically extending heat exchanger. In the case of the horizontally extending heat exchangers in particular, struts or profiles can be provided which extend between individual cells of the heat exchanger and support the longitudinally displaceable staircase or bridge unit.
According to a further development of the invention, a plurality of jet nozzles is provided on the movement device, with at least one jet nozzle preferably being installed on each of the opposite longitudinal sides of the staircase or bridge unit. By installing the jet nozzles accordingly, complete cleaning of the lamellar heat exchanger can also be achieved if the stair or bridge unit cannot be moved beyond it in the longitudinal direction of the lamellar heat exchanger and thus the area of the long sides of the stair or bridge unit next to it installed jet nozzles can only clean a partial area of the lamellar heat exchanger. The spaced arrangement of at least two jet nozzles ensures that the lamellar heat exchanger, despite the geometric restrictions or the limited mobility of the staircase or bridge unit can be completely cleaned.

Further advantages, features and details of the invention can be gathered from the further subclaims and the following description. Features mentioned there can be essential to the invention either individually or in any combination. Features and details of the installation arrangement described according to the invention naturally also apply in connection with the method according to the invention and vice versa. In this way, mutual reference can always be made to the disclosure of the individual aspects of the invention.

The drawings serve only by way of example to clarify the invention and are not of a restrictive nature.

Fig. 1

eine perspektivische Prinzipansicht einer Installationsanordnung,

Fig. 2

eine Längsseitenansicht der Installationsanordnung nach Fig. 1,

Fig. 3

eine Stirnseitenansicht der Installationsanordnung nach Fig. 1,

Fig. 4

eine vergrößerte Darstellung eines Details X nach Fig. 3,

Fig. 5

eine Vorderseitenansicht einer Reinigungseinrichtung der Installationsanordnung nach Fig. 1,

Fig. 6

eine Rückseitenansicht der Reinigungseinrichtung nach Fig. 5,

Fig. 7

eine Längsseitenansicht der Reinigungseinrichtung nach Fig. 5,

Fig. 8

eine Aufsicht auf die Reinigungseinrichtung nach Fig. 5 und

Fig. 9

eine zweite Ausführungsform der erfindungsgemäßen Installationsanordnung.

Show it:

Fig. 1

a perspective principle view of an installation arrangement,

Fig. 2

a longitudinal side view of the installation arrangement according to Fig. 1 ,

Fig. 3

an end view of the installation arrangement according to Fig. 1 ,

Fig. 4

an enlarged view of a detail X according to Fig. 3 ,

Fig. 5

a front view of a cleaning device of the installation arrangement according to Fig. 1 ,

Fig. 6

a rear view of the cleaning device according to Fig. 5 ,

Fig. 7

a longitudinal side view of the cleaning device according to Fig. 5 ,

Fig. 8

a supervision of the cleaning device after Fig. 5 and

Fig. 9

a second embodiment of the installation arrangement according to the invention.

An installation arrangement according to the invention according to the Figs. 1 to 3 comprises an inverted V-type heat exchanger device with two lamellar heat exchangers 13 installed at an acute angle 11 to the horizontal and an acute angle 12 to one another. The lamellar heat exchangers 13 have two opposed passage surfaces 14, 15 as well as a plurality of passage channels 16 which lead from a first passage surface 14 to a second passage surface 15 are guided. The lamellar heat exchangers 13 are used, for example, to cool an air flow passed through them.

Accessibility of the lamellar heat exchangers 13 is provided on the one hand by horizontally extending webs 17 and on the other hand by a stair or bridge unit 3. The stair or bridge unit 3 covers the lamellar heat exchanger 13 in the area of the first passage surface 14. It is movably arranged in a longitudinal direction 18 of the lamellar heat exchanger 13 and is preferably guided in the area of the webs 17 via guide means (not shown).

A guide unit 9 with two guide rails 1 that are parallel to one another and arranged at a distance is fixed to the staircase or bridge unit 3. The guide unit 9 carries a movement device 10, which is supported on the guide unit 9 by way of example via rollers 4 and can be moved longitudinally along the guide rails 1 of the guide unit 9. The movement of the movement device 10 along the guide rails 1 takes place via a drive unit 2, a pulling means (cable, pull chain, toothed belt, toothed rack or the like) and a deflecting means (roller or toothed wheel 8). Jet nozzles 6 are fixed on the movement device 10. To fix the jet nozzles 6, an exemplary horizontally extending support arm 5 and a holder 7 for height and lateral adjustment of the jet nozzles 6 are used.

A jet medium for cleaning the lamellar heat exchanger 13 is provided by means of the jet nozzles 6. The orientation of the jet nozzles 6 is provided in such a way that the jet medium impinges perpendicularly on the first passage surface 14 of the lamellar heat exchanger 13 and passes through the passage 16, compare Fig. 4 . Since the jet nozzles 6 in the present exemplary embodiment of the invention are comparatively long and therefore not can be positioned between the stair or bridge unit 3 on the one hand and the passage surface 14 on the other hand, they are preferably installed adjacent to the stair or bridge unit 3. A carrier gas, preferably compressed air, which is provided at at least 2 bar, and a liquid which is fed to the carrier gas serve as the blasting medium. For example, water is used as the liquid. The amount of liquid supplied is less than 1% and preferably less than 0.3% of the amount of carrier gas supplied.

The blasting medium is supplied via a supply device with at least one supply hose 19 and preferably a plurality of supply hoses 19. Separate supply hoses 19 are provided for each jet nozzle 6. The supply hoses 19 are guided in the region of the guide rails 1 by means of an energy chain 20.

The guide unit 9 with the guide rails 1, the movement device 10 and the feed device with the at least one feed hose 19 belong to a cleaning device of the installation arrangement according to the invention. The cleaning equipment is in the for essential details Figures 5 to 8 shown. In the present case, the cleaning device provides a total of five jet nozzles 6, which are installed in two groups 21, 22 on opposite longitudinal sides 23, 24 of the staircase or bridge unit 3. A clear distance 25 between the groups 21, 22 is selected such that the stair or bridge unit 3 is arranged between the groups 21, 22. The cleaning device provides fastening means 26 for this purpose, which are used to fix the guide rails 1.

In relation to a travel direction of the staircase or bridge unit 3 in the longitudinal direction 18 of the lamellar heat exchanger 13, the three jet nozzles 6 belonging to the first group 21 are arranged in front of the two jet nozzles 6 belonging to the second group 22.

According to the invention, the lamellar heat exchanger 13 is cleaned by means of the cleaning device in such a way that the movement device 10 with the jet nozzles 6 is moved over the guide unit 9 with the stair or bridge unit 3 in the longitudinal direction 18 of the lamellar heat exchanger 13 and, in addition, the movement device 10 is moved perpendicular to the longitudinal direction 18 the first passage surface 14 is moved up and down. The cleaning process is preferably carried out in two stages such that in a first cleaning stage a first partial area of the lamellar heat exchanger 13 is cleaned at a low first speed. The first cleaning stage runs until the jet nozzles 6 of the second group 22 of jet nozzles 6 is moved in the longitudinal direction by the clear distance 25 of the groups 21, 22 of jet nozzles 6. The first cleaning stage serves to clean a sub-area of the lamellar heat exchanger 13 originally assigned to the staircase or bridge unit 3. As soon as the first sub-area of the lamellar heat exchanger 13 is cleaned, the jet nozzles 6 of the second group 22 can be deactivated and the remaining second sub-area of the lamellar heat exchanger 13 through the Jet nozzles 6 of the first group 21 are cleaned by jet nozzles 6. The speed of cleaning can hereby be selected to be greater due to the larger number of jet nozzles 6 arranged in parallel. For example, the movement device 10 can be moved continuously along the guide rails 1 of the guide unit 9. For example, the movement in the longitudinal direction 18 of the lamellar heat exchanger 13 can take place gradually.

The movement of the jet nozzles 6 along the first passage surface 14 of the lamellar heat exchanger 13 takes place via a control (not shown). The control can be provided at the same time for controlling and in particular for activating and deactivating the jet nozzles 6 and can control or regulate a pressure of the jet medium or a quantity of the jet medium.

According to an alternative embodiment of the invention according to FIG Fig. 9 If the installation arrangement is otherwise essentially the same, only a first group 21 with three jet nozzles 6 is provided, which is installed on one side of the staircase or bridge unit 3. The second embodiment of the installation arrangement is particularly useful when the staircase or bridge unit 3 in very wide areas outside of the Lamellar heat exchanger 13 can be moved horizontally and moved. The associated lamellar heat exchanger 13 can then preferably be cleaned in one stage.

According to a further embodiment of the invention, not shown, the jet nozzles 6 as a whole or at least a group 21, 22 of jet nozzles 6 can be provided on a side of the stair and bridge unit 3 facing away from the heat exchanger 13. The heat exchanger 13 can then be cleaned in a particularly simple manner over the entire travel path of the stair and bridge unit 3.

According to a further embodiment of the invention, not shown, the movement device 10 can be moved in a first direction of movement via a first traction means by a first drive unit 2 and via a second traction means by a second drive unit 2. In particular, this solution can be used for horizontally installed heat exchangers 13.

The same components and component functions are identified by the same reference symbols.

Claims (12)

1. Method for automated cleaning of finned heat exchangers (13) and other sensitive surfaces, a carrier gas, preferably compressed air, and a liquid as an abrasive medium, preferably water, being supplied at a pressure of at least 2 bar through feed tubes (19), the supplied water amount being less than 1 %, preferably less than 0.30 %, of the supplied air amount, characterised in that, at a guide unit (9) consisting of at least one and preferably two guide rails (1), a movement device (10) preferably moved on rollers (4) or runners is moved up and down, to which device a carrier arm (5) is attached on which at least one, preferably a plurality of blast nozzles (6) are attached in such a way that they are moved alongside the guide unit (9) via the movement device (10) by way of an additional drive unit (2), preferably via a roller or toothed wheel (9) attached to the other end.
2. Method according to claim 1, characterised in that the guide unit (9) is adapted to a stair or bridge unit (3) which can be rolled or slid over the exchanger length.
3. Method according to either claim 1 or claim 2, characterised in that the blast nozzles (6) are fixed on the carrier arm (5) by way of a vertically and laterally adjustable holder (7).
4. Method according to any of claims 1 to 3, characterised in that the entire guide unit (9), together with the stair or bridge unit (3) which can be rolled and/or slid and/or is self-propelled over the exchanger length, is guided over the surface to be cleaned by a suitable pulling device, preferably a cable pull, in an automated manner by way of a control system, in such a way that the blast nozzles (6) clean the entire surface without gaps.
5. Method according to any of claims 1 to 4, characterised in that the pressure and amount of carrier gas and blasting material and the displacement speed of the movement device (10) and guide unit (9) can be regulated.
6. Method according to any of claims 1 to 5, characterised in that, on opposite longitudinal faces (23, 24) of the stair or bridge unit (3), at least one blast nozzle (6) is installed in each case, and in that the finned heat exchanger (13) is cleaned in two steps, a first sub-surface of the finned heat exchanger (13) being cleaned in a first cleaning step in that the guide unit (9) is moved in a longitudinal direction (18) of the finned heat exchanger (13) at a first speed until the guide unit (9) is moved in the longitudinal direction (18) by an opening dimension (25) of the blast nozzles (6) installed on opposite longitudinal faces (23, 24) of the stair or bridge unit (3), and another, second sub-surface of the finned heat exchanger (13) subsequently being cleaned in a second cleaning step in that the guide unit (9) is subsequently moved in the longitudinal direction (18) of the finned heat exchanger (13) at a second speed in a second step, the second speed being greater than the first speed.
7. Method according to claim 6, characterised in that in the first cleaning step and/or in the second cleaning step at least some individual blast nozzles (6) are deactivated.
8. Installation arrangement comprising at least one heat exchanger device, which has a finned heat exchanger (13), orientated horizontally or vertically or inclined at an acute installation angle (11) to the horizontal and comprising two mutually opposite through-surfaces (14, 15) and a plurality of through-ducts (16) which pass from a first through-surface (14, 15) to a second through-surface (14, 15), comprising a cleaning device

   - comprising a guide unit (9) comprising at least one guide rail (1) which is arranged extending parallel to the first through-surface (14) and/or to the second through-surface (15),

   - comprising a movement device (10), guided on the guide rail (1) and comprising a carrier arm (5), comprising at least one blast nozzle (6) attached to the carrier arm (5) and orientated in such a way that a blasting material exiting the blast nozzle (6) strikes the through-surface (14, 15), facing the blast nozzle (6), of the finned heat exchanger at an angle of ± 20° to a surface normal, and comprising a drive unit (2) for moving the movement device (10) along the guide rail (1), and

   - comprising a feed line device comprising at least one feed tube (19) for the blasting medium supplied to the blast nozzle (6), said tube providing a carrier gas and a small amount of liquid added to the carrier gas as a blasting material

   and comprising a control system for controlling the movement of the movement device (10) and/or a throughput for the blasting medium, the guide unit (9) being provided movably in a longitudinal direction (18) of the finned heat exchanger (13) using the movement device (10) fixed to the guide unit (9), and the control system operating the movement of the movement device (10) in such a way that the blasting medium passes through all of the through-ducts (16) of the finned heat exchanger (13).
9. Installation arrangement according to claim 8, characterised in that the heat exchanger device is formed in the manner of a V heat exchanger device or an inverted V heat exchanger device comprising two finned heat exchangers (13) arranged at an acute installation angle (12) to one another.
10. Installation arrangement according to either claim 8 or claim 9, characterised in that the guide unit (9) is fixed on a stair or bridge unit (3) which is displaceable in a longitudinal direction (18) of the finned heat exchanger (13), the guide rail (1) of the guide unit (9) extending transverse to the longitudinal direction (18) of the finned heat exchanger (13).
11. Installation arrangement according to any of claims 8 to 10, characterised in that a plurality of blast nozzles (6) are provided on the movement device (10), at least one blast nozzle (6) being installed on mutually opposite longitudinal faces (23, 24) of the stair or bridge unit (3).
12. Installation arrangement according to any of claims 8 to 11, characterised in that the control system is formed to carry out a method according to any of claims 1 to 7.

Images