EP3176534A2 - Device and method for cleaning a heat exchanger - Google Patents

Abstract

A device for cleaning a heat exchanger will be described. According to an embodiment of the invention, the cleaning device has an evaporation module which is arranged in the vicinity of the heat exchanger, so that it is exposed to the same gas flow as the heat exchanger. The cleaning device further comprises a supply line, which is connected to the evaporation module and via which a liquid can be passed into the evaporation module. The evaporation module has outlet nozzles which are arranged so that the vapor, which is formed in the evaporation module by evaporation of the liquid, can exit through the outlet nozzles in the direction of the heat exchanger.

Description

TECHNICAL AREA

The invention is in the field of heat exchangers and relates in particular to the purification of heat exchangers which come into contact with flue gases.

BACKGROUND

The direct use of the hot flue gases from biomass incinerators for combined heat and power plants means a dramatic system simplification compared to, for example, a wood gas combined heat and power plant. The latter require a carburetor, a gas cooling and a Teerkondensationsanlage before the resulting gas can be supplied to a gasoline engine. Apart from the fact that due to the gas cooling, the overall electrical efficiency decreases, the amount of maintenance and repair costs increases due to the number of system components. However, other fuels, such as landfill or sewage gases (lean gases) contain residues that lead to deposits on the heat exchanger during combustion. Typical examples are siloxanes in sewage gases, which precipitate on combustion in the form of silica.

A combined heat and power by means of Stirling engines has the advantage that the hot flue gases (eg flue gases produced in biomass combustion plants) are separated from the process gas of the engine and the heat transfer to the process gas takes place via a heat exchanger to which However, accumulate for the reasons described above, ash particles and other particles contained in the flue gas, which deteriorates the heat transfer in the heat exchanger.

There are various cleaning devices for cleaning heat exchangers known, for example, act mechanically or operated with compressed air or steam. The essay Marinitsch et al .: "Development of a hot gas heat exchanger for a 35 kWel hermetic four cylinder stirling engine for solid biomass", in: Proceedings of the 12th ISEC, Sept. 2005 , describes the automatic cleaning of a heat exchanger by means of compressed air. Elsewhere, the detrimental influence of siloxanes precipitated by fumed silica in internal combustion engines is reported and lead to considerable damage, at any rate to increased repair costs. In the publication EP 1 988 352 A2 describes a system in which the heat exchanger is mechanically cleaned with a kind of brush.

The object underlying the invention can be seen to provide an improved apparatus and an improved method for cleaning a heat exchanger in a cogeneration machine.

SUMMARY

The above object is achieved by a device according to claim 1 and 8 and by a method according to claim 12. Various embodiments and further developments of the invention are the subject of the dependent claims.

A device for cleaning a heat exchanger will be described. According to an embodiment of the invention, the cleaning device has an evaporation module which is arranged in the vicinity of the heat exchanger, so that it is exposed to the same gas flow as the heat exchanger. The cleaning device further comprises a supply line, which is connected to the evaporation module and via which a liquid can be passed into the evaporation module. The evaporation module has outlet nozzles which are arranged so that the vapor, which is formed in the evaporation module by evaporation of the liquid, can exit through the outlet nozzles in the direction of the heat exchanger.

Furthermore, a Stirling engine will be described. This has, according to an embodiment of the invention, a heat exchanger (heater), which is flowed through by hot hot gas, so that the heating gas gives off heat to the heat exchanger. The Stirling engine further includes the above-described cleaning device located near the heat exchanger.

Finally, a method for cleaning a heat exchanger will be described. For this purpose, an evaporation module is used, which is arranged in the vicinity of the heat exchanger, so that it is exposed to the same gas flow as the heat exchanger. According to one example of the invention, the method comprises the method of feeding a defined amount of liquid into the evaporation module, wherein the liquid in vaporizes the evaporation module and steam exits through outlet nozzles of the evaporation module in the direction of the heat exchanger.

BRIEF DESCRIPTION OF THE FIGURES

• Figur 1 zeigt das Reinigungssystem in tlw. vereinfachter Darstellung.
• Figur 2 zeigt beispielhaft eine Anwendung der Erfindung an einer Stirling-Maschine in Alpha-Konfiguration.
• Figur 3 zeigt einen Längsschnitt durch die Stirling-Maschine gemäß Fig. 2.
• Figur 4 zeigt das Beispiel aus Fig. 1 mit einer alternativen Wasserversorgung.

The invention will be explained in more detail with reference to the examples shown in the figures. The illustrations are not necessarily to scale and the invention is not limited to the aspects presented. Rather, emphasis is placed on representing the principles underlying the invention. To the pictures:

• FIG. 1 shows the cleaning system in partly simplified representation.
• FIG. 2 shows an example of an application of the invention to a Stirling machine in alpha configuration.
• FIG. 3 shows a longitudinal section through the Stirling machine according to Fig. 2 ,
• FIG. 4 shows the example Fig. 1 with an alternative water supply.

In the figures, like reference characters designate like or similar components of like or similar meaning.

DETAILED DESCRIPTION

The embodiments of a cleaning device described here are designed to generate high-pressure steam within an evaporation module of the cleaning device and to direct it via outlet nozzles to the heat exchanger to be cleaned. The embodiments described here relate to a cleaning device for cleaning a heat exchanger of a Stirling engine. However, the cleaning device can also be used in other environments for cleaning heat exchangers.

The evaporation module of the cleaning device can be arranged, for example, where the heating gases that heat the heat exchanger, leaving this. In operation, after a certain period of time, the module assumes the temperature of the exiting hot gases, which in the case of Stirling machines or other thermodynamic machines can be up to 700 degrees Celsius. According to the embodiments described here, a defined amount of liquid (eg water) is supplied to the hot module, which is abruptly converted to steam in channels which are provided within the module. The steam then exits the module at high pressure on nozzles with the nozzles aligned so that the steam is directed onto the surface of the heat exchanger to be cleaned. This process can be cyclically controlled, for example, time-dependent or depending on the degree of contamination of the heat exchanger. In addition, the cleaning device described here offers the possibility of pivoting the evaporation module about its longitudinal axis in order to gradually spray the surface of the heat exchanger with only a limited number of nozzles, which causes a particularly intensive partial cleaning. The cleaning can be done without interrupting the operation of the machine and the superheated steam jet does not cause a damaging temperature shock at the heat exchanger.

The invention is eminently suitable for removing dust and particulate deposits from the heat exchanger without the use of external energy. Rather, the temperature level of the flue gases is used when exiting the heat exchanger to heat the evaporation module of the cleaning device. While the hot gases (flue gases) can flow with temperatures of over 1200 degrees Celsius on the heat exchanger, they cool at the surfaces of the heat exchanger whose temperatures are about 600 to 650 degrees C, to about 700 degrees C from. Depending on the design of the Stirling engine as a medium or high-temperature machine, this value can still vary significantly upwards or downwards. In any case, however, it is a temperature level at which on the one hand materials such as steels are still available with considerable strengths, on the other hand, a highly superheated steam with pressures of more than 100 bar can be generated.

The evaporation module is, for example, a cuboid or cylindrical body comprising a housing, for example of heat-resistant steel. The housing is filled with a material with high heat capacity, for example made of alloy steel, and is immediately (relative to the flow direction of the hot gases) arranged behind the heat exchanger, so that the evaporation module is heated by the hot gases over time substantially to their temperature. Inside the cylinder are located in the region of the material with high heat capacity channels with the highest possible surface, the input side are connected to a water supply line and the output side with one or more outlet nozzles. The nozzles may be arranged in rows and are directed to the heat exchanger.

The evaporation module is supplied via a pipe, in the course of which is a check valve, cyclically supplied via a water supply device with a defined amount of water. The check valve protects the water supply device against pressure surges (shock waves) that may arise during the evaporation process in the evaporation module. The water supply may optionally comprise a high-pressure line, a pump or a pump cylinder, which emits the defined amount of water to the evaporation module. A high-pressure shut-off valve may allow the controlled supply of certain amounts of water at certain time intervals, which are adapted to the cleaning requirements of the heat exchanger. In the case of the application of a pump cylinder, a high-pressure shut-off valve (solenoid valve 3.2) is unnecessary, since the supply of a defined amount of water depends directly on the stroke of the pump cylinder.

The number of exit nozzles on the evaporation module and their orientation can be chosen so that they cover the entire heat exchanger. It may be advantageous in view of a short-term Heizgasumkehr to clean only a portion of the heat exchanger. The concomitant reduction in the number of nozzles can be used for faster pressure build-up and higher final pressure resulting in significantly more concentrated cleaning. To operate the entire heat exchanger surface, it may be provided to pivot or displace the evaporator continuously or stepwise. The water supply can be done via a flexible hose or a rotary feedthrough. Such are known per se and therefore need no further explanation here, as well as a pivoting or Verschubmechanismus for the evaporation module by step or pivot motors here requires no further explanation.

Depending on the application, it may be advantageous that cleaning the heat exchanger does not require service interruption and that the purge jet is superheated steam, so that there is no thermal shock on the heat exchanger surface is triggered, as would be the case for example with cold compressed air or even with cold liquids.

FIG. 1 schematically shows a simple example of the cleaning device 3.0 generally described above, which is in the vicinity of a heat exchanger 1.7 (which may be part of a Stirling machine 1.0, for example, see also Fig. 2 ). The hot fuel gas 2.2 is generated by a furnace 2.0, not shown. FIG. 1 shows right longitudinal section through the evaporation module 3.5 of the cleaning device 3.0 and left a corresponding cross-section. As mentioned above, the evaporation module 3.5 has a housing 3.9, which can be made of heat-resistant steel, for example. The housing 3.9 is filled with a material 3.10 high heat capacity (eg alloy steel), are provided in the channels 3.6. During operation, the water supplied via the supply line 3.4 to the evaporation module 3.5 is vaporized while the channels 3.6. flows through abruptly, and the resulting steam exits through the outlet nozzle 3.7, in which the channels open 3.6, from. The resulting steam jet 3.8 is directed to the heat exchanger 1.7 and frees it from the aforementioned deposits.

Via the supply line 3.4, water will be conducted from a pressure connection of a water supply device 3.1 to the evaporation module 3.5. The volume of water supplied to the evaporation module 3.5 is determined via the valves 3.2 and 3.3 connected in series. The valve 3.2 may be, for example, a solenoid valve which is driven at regular intervals to open the valve for a short time. The second valve 3.3 is a check valve, which closes due to the resulting in the sudden evaporation of the supplied water pressure wave in the supply line 3.4 and prevents backflow of the water in the supply line 3.4. At the same time the solenoid valve 3.2 and the water supply is protected from the pressure wave. The water supply 3.1 can also consist of a pump cylinder 3.11, which is cyclically actuated and a metered amount of water to the evaporation module 3.5 supplies (see also Fig. 4 ).

In the Figures 2 and 3 the application of the cleaning device 3.0 is shown in a Stirling machine 1.0 in alpha configuration, wherein Fig. 2 shows a longitudinal section along the cylinder axes and Fig. 3 a corresponding cross section through the cleaning device 3.0. The Stirling engine 1.0 includes two cylinders 1.3 and 1.4, in each of which a piston is guided. The pistons are mechanically coupled to the crankshaft 1.2 so that the linear motion of the pistons is converted into rotational motion of the crankshaft. The pistons move linearly along the cylinder axes, which are approximately parallel in the present example (which need not necessarily be the case). The cylinder 1.3 is "hot" and the cylinder 1.4 is "cold", wherein the cold cylinder 1.3 lags the hot by a certain phase angle (based on the rotation angle of the crankshaft 1.2). The crankshaft 1.2 is arranged in a housing, the crankcase 1.1.

At the cylinder end of the cold cylinder 1.4, a low-temperature heat exchanger 1.5 and subsequently (on the side facing away from the cylinder of the heat exchanger 1.5) a regenerator 1.6 is arranged. Between the regenerator 1.6 and the hot cylinder 1.3, the high-temperature heat exchanger 1.7 (heater) is arranged, which comes into operation during operation with the hot fuel gas 2.2 (eg over 1000 ° C.) and thus by deposits of dust, ash and other particles , which carries the fuel gas 2.2 with it, is charged. The heating gas 2.2 gives heat to the heat exchanger 1.7, thereby cooling to e.g. around 700 ° C. The cooled, but still warm fuel gas is designated by the reference numeral 2.3. Around the heat exchanger 1.7 around a heating gas 2.1 is arranged, which ensures that the heating gas flows through the heat exchanger 1.7. The operation of a Stirling machine in alpha configuration is known per se and will not be explained further here.

The heater or heat exchanger 1.7 extends arcuately (approximately semicircular in longitudinal section Fig. 2 ) between the two cylinders 1.3 and 1.4, and consists of several channels, which are traversed by the process gas of the Stirling engine. Other than arcuate compounds may be advantageous in specific applications, but do not affect the idea of the invention. The cleaning device 3.0 is arranged in the immediate vicinity of the heat exchanger 1.7, that it is flowed around by the warm (cooled to eg about 700 ° C.) heating gas and heated. In operation, therefore, the cleaning device 3.0 has approximately the same temperature as the warm fuel gas 2.3. As already mentioned, the heat exchanger 1.7 extends arcuately in such a way that at least partially surrounds the cleaning direction 3.0. In a (around a center) semicircular designed heat exchanger 1.7, the longitudinal axis of the cleaning device 3.0 is approximately in the center of the arc. By a simple rotation of the cleaning device thus the entire heat exchanger 1.7 can be cleaned. The outlet nozzles (see Fig. 1 ) of the cleaning device are oriented toward the heat exchanger 1.7, so that the exiting steam flows directly onto the surface of the heat exchanger 1.7.

FIG. 4 shows the same example Fig. 1 with an alternative water supply instead of a pressure port of the check valve 3.3 is preceded by a pump cylinder 3.11. The solenoid valve 3.2 can be omitted in this case. Upon actuation of the pump cylinder 3.11 the evaporation module 3.5 a defined amount of liquid via the check valve 3.3 is supplied. This defined amount of liquid depends directly on the geometry (cross-sectional area and stroke) of the pumping cylinder 3.11, which can be matched to the evaporation module 3.5. As mentioned above, the cleaning process may be cyclically controlled (for example, time dependent or depending on the degree of fouling of the heat exchanger), with the pump cylinder being operated once in each cycle to inject the defined amount of liquid into the evaporation module 3.5. Apart from the water supply is Fig. 4 identical with Fig. 1 ,

Claims (12)

Apparatus for cleaning a heat exchanger (1.7), comprising an evaporation module (3.5) located near the heat exchanger so as to be exposed to the same gas flow as the heat exchanger (1.7); a supply line (3.4) which is connected to the evaporation module (3.5) and via which a liquid can be passed into the evaporation module (3.5), wherein the evaporation module (3.5) has outlet nozzles (3.7) which are arranged so that the vapor which is formed in the evaporation module (3.5) by evaporation of the liquid can escape through the outlet nozzles (3.7) in the direction of the heat exchanger (1.7). Device according to claim 1,
wherein the evaporation module (3.5) has a housing (3.9) in which high heat capacity material (3.10) in which channels (3.6) are provided, the liquid supplied via the supply line (3.4) being conveyed via the channels (3.6) is transported to the outlet nozzles (3.7). Device according to claim 1 or 2,
wherein in the supply line (3.4) a check valve (3.3) is arranged. Device according to one of claims 1 to 3,
wherein in the supply line (3.4) in series with the check valve (3.3) an electrically controllable solenoid valve (3.2) is arranged. Device according to one of claims 1 to 3,
wherein the supply line (3.4) is connected to a pump cylinder (3.11). Device according to one of claims 1 to 5,
wherein the cleaning device (3.0) is mounted displaceably or pivotably. Apparatus according to claim 4 or 5, further comprising: a mechanical drive adapted to rotate or displace the evaporation module (3.5) step by step, wherein the mechanical drive and the solenoid valve (3.2) are controlled so that in each step in which the evaporation module (3.5) is rotated or shifted, a defined amount of liquid is supplied to the evaporation module (3.5). Stirling engine comprising: a heat exchanger (1.7), which is heated by hot heating gas (2.2), so that the heating gas (2.2) gives off heat to the heat exchanger (1.7), a cleaning device (3.0) according to one of claims 1 to 7. Stirling engine according to claim 8, wherein the cleaning device (3.0) adjacent to the heat exchanger (1.7) is arranged so that the heating gas (2.2) flows first to the heat exchanger (1.7) and then the cleaning device (3.0). Stirling engine according to claim 8 or 9, further comprising: two cylinders (1.3, 1.4), wherein the heat exchanger (1.7) between the two cylinders (1.3, 1.4) is arranged arcuately, wherein the cleaning device (3.0) is arranged so that the heat exchanger (1.7) encloses them at least partially. Stirling engine according to claim 8 or 9, further comprising: two cylinders (1.3, 1.4), wherein the heat exchanger (1.7) between the two cylinders (1.3, 1.4) is arranged arcuately about a center, wherein the cleaning device (3.0) is arranged so that its longitudinal axis extends through the Mitteilpunkt. A method of cleaning a heat exchanger (1.7) with an evaporation module (3.5), which is arranged in the vicinity of the heat exchanger so that it is exposed to the same gas flow as the heat exchanger (1.7); the method has;
Supplying a defined amount of liquid into the evaporation module (3.5), whereby the liquid evaporates in the evaporation module (3.5) and steam exits through outlet nozzles (3.7) of the evaporation module (3.5) in the direction of the heat exchanger (1.7).

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