SE530998C2 - Apparatus and system for controlling temperature in a fluidized bed combustion boiler - Google Patents

Description

A thermocouple placed near the bottom of the boiler will sense an incipient coarsening of the bed earlier than a high thermocouple can detect.

If you can get this information at an early stage, several measures can be taken.

For example, you can increase the filling of new fine sand to the bed at the same time as you increase the discharge of bed material from the bed bottom. You can also increase the primary airflow to improve the fl uidization effect.

The fluidized bed often has fl your bed outlets. It is normal for there to be at least one temperature gauge near each bed outlet. If the temperature deviates from this part of the bed, the outlet flow from this part of the bed can be increased.

The supply of air to the nozzles can also take place with different air ducts for different groups of nozzles, for example the group of nozzles that are close to a bed outlet.

A complementary measure can therefore be to increase the air flow to this group of nozzles where deviating temperatures have been detected.

The temperature is measured via thermocouple wire. This is normally encapsulated in a metallic casing with a diameter of about 2-4 mm. To further protect this, it protrudes into the bed in a heat-resistant tube, either from the walls of the boiler or from the bottom of the boiler. To further protect it from the erosive environment, there is normally an external wear protection that can be easily replaced. All in all, it will be a relatively rough pipe construction. Each such insert for the thermocouples adversely affects the id uidisation of or the ash transport in the bed, which is why efforts are made to reduce the number of temperature sensors.

For large boilers with fluidized beds, you must use thermocouples that sit in the bottom of the boiler as long plugs from the boiler walls mainly do not withstand the great mechanical stresses, but also to some extent prevent fl uidisation and in themselves risk building unburned material. The thermocouples in the bottom of the boiler are very exposed to the erosive effect of the fl uldising currents in the bed, and its attachments to the bottom of the boiler are quickly worn down. WO 2005/038420 discloses various types of thermocouples for fluidized beds. Figure 1 shows how a short or long thermocouple is located in the bottom of the boiler. Figure 2 shows how a number of thermocouples can be arranged in the wall of the boiler at different heights.

Object of the invention A first object of the invention is to obtain a better measurement of the temperature in a fluidizing bed, where the thermocouple has a better and more protected position against the eroding influence of the fluidizing bed.

A second purpose is to facilitate the transport of coarser contaminants in the bed.

A third purpose is to avoid the formation of unidentified zones adjacent to the thermocouples.

The above objects are achieved with a device according to the characterizing part of claim 1 and with a system according to the characterizing part of claim 6.

Description of the figures Figure 1 shows a combustion boiler with an external bed seen in section in its bottom part with thermocouples integrated with the air nozzles according to the invention; Figure 2 shows a detailed drawing of a first embodiment of an air nozzle according to the invention with integrated thermocouple; Figure 3 shows a detailed drawing of a second embodiment of an inventive air nozzle with integrated thermocouple; DETAILED DESCRIPTION OF THE OPENING IN FIG. 1 shows a combustion boiler 1 with an exhaust bed 10, containing a duct system for combustion air, containing an air fan 7 and an air distribution duct 5. A number of air nozzles 4 with air outlets are connected via air outlets. the air distribution duct 5. of the duct system These air nozzles 4 are arranged in the bottom of the boiler for the supply of combustion air and the establishment of a fluidized bed. These air nozzles are fitted with integrated sensors 2a / 2b for determining the temperature inside the bed.

The sensors 2a / 2b are rod-shaped thermocouples which are integrated with at least one of the air nozzles 2a / 2b which are arranged in the bottom of the boiler. The rod-shaped thermocouple being fixedly arranged at its first end with the air nozzle and at its second end is arranged at a distance from the air nozzle.

The sensors 2a / 2b are connected to a detection device via suitable means for signal transmission. The clock shows that the sensors 2a / 2b are connected to a control unit 8 via lines 9a / 9b, but the signal transmission can also take place wired.

As shown in more detail in Figure 2, the air outlet 41 of the air nozzle 4 is arranged directed away from the first end of the thermocouple, in a direction of fate F and preferably directed 90 degrees away from the extent of the rod-shaped thermocouple. A shorter rod-shaped thermocouple corresponding to the sensor 2a in Figure 1 is shown here.

The thermocouple is arranged on the upper part of the air nozzle 4 and directed vertically upwards in the fluidized bed.

The thermocouple is usually formed as a tube 26 with the detecting part 25 of the thermocouple attached to the other end of the tube, the top end, and the signal lines 9a to the thermocouple inside the tube 26.

The rod-shaped thermocouple is provided with a surrounding insulation between the first and second ends of the thermocouple. The thermocouple 25 is integrated in a measuring body 24 which in turn is stripped downwards with an insulating plate 22 and a masonry 23. The masonry 23 is in turn stripped with an insulating plate 22 against a lower part 24 'which is preferably welded to the air nozzle 4 itself. with a weld 50.

The connection 9a of the thermocouple is arranged at least in part by its wiring inside the duct system 6/5 for the transport of combustion air. In this way, the pipes can be kept protected and continuously cooled by supplied air. Figure 3 shows a second embodiment of air nozzle 4 with your detecting parts 25, 25 ', 25 "of the thermocouples integrated in the sensor. A longer rod 15 thermocouple corresponding to the sensor 2b in Figure 1 is shown here. also another air nozzle with several outlets 41 distributed around the periphery of the nozzle.In this embodiment the air outlet 41 of the air nozzle 4 is arranged directed away from the first end of the thermocouple, in a direction F and preferably 90 degrees away from the extent of the rod-shaped thermocouple. arranged on the upper part of the air nozzle 4 and directed vertically upwards in the fluidized bed.

The thermocouples are usually formed as a tube 26 with the detecting part 25 of a first thermocouple 25 molded into the other end of the tube, the top end, and the signal lines 9a to the thermocouple inside the tube 26.

The detecting part 25's and 25 "to a second and third thermocouple are fixed at the respective pipe ends, and the signal lines 9b and 9c to the respective thermocouple element are arranged inside the pipes 26's and 26".

The detecting part 25,25 ', 25 "of the thermocouples are integrated in the respective measuring body 24, 24', 24" which in turn is stripped apart with a layered structure consisting of an upper insulating board 22 and a masonry 23,23 'and a lower insulating plate 22. A lower part 24 "'is preferably welded to the air nozzle 4 itself with a weld joint 50. The connections 9a, 9b and 9c of the thermocouple are arranged inside the duct system 6/5 for conveying combustion air.

In this way, the pipes can be kept protected and continuously cooled by supplied air.

The embodiment of the air nozzle in Figure 2 is mainly used for combustion boilers where there may be a lot of scrap and stones in the material to be burned and a stronger air flow is desired directed towards discharge openings in the fluidizing bed.

The embodiment of the thermocouple in figure 3 with fl your thermocouples at different levels can also be used on other types of air nozzles.

With the device according to the invention, it is possible to have a system for determining the temperature in a combustion boiler with a flowing bed, containing a duct system for combustion air and a number of air nozzles connected to the duct system and arranged at the bottom of the boiler for supplying combustion air and establishing a combustion air. With a rod-shaped thermocouple integrated with at least two of the air nozzles arranged in the bottom of the boiler, a measuring system which is less sensitive to the eroding environment in the iseridising bed can be obtained. Preferably, at least one of the thermocouples has a first length A and the second thermocouple has a second length B which is at least 100% longer than the first length, and where the thermocouples are connected to a detection device via means for signal transmission. In the system, a rod-shaped thermocouple can be integrated with at least three of the air nozzles arranged in the bottom of the boiler, the third thermocouple having a third length C which is at least 50% longer than the second length.

Each thermocouple may have its own rod-shaped body in which it is integrated, corresponding to Figure 2, or a number of thermocouples may sit in the same rod-shaped body, corresponding to Figure 3, and arranged at different heights into the fluidizing bed.

The invention is not limited to the embodiments shown above, but your variants are possible within the scope of the following claims.

Claims (1)

10 15 20 25 30 530 'B98 7 PATENT REQUIREMENTS Device for determining the temperature in a combustion boiler (1) with an fl-indicating bed (10), containing a duct system (5,6) for combustion air and a plurality of air nozzles (4) with air outlets (41) connected to the duct system and arranged at the bottom of the boiler for supplying combustion air and establishing a fluidized bed, characterized in that a rod-shaped thermocouple (2a, 2b) is integrated with at least one of the air nozzles (4) arranged in the bottom of the boiler, where the rod-shaped thermocouple is fixedly arranged in its first end with the air nozzle and at its second end is arranged at a distance from the air nozzle, and where the thermocouple is connected to a detection device (8) via means for signal transmission (9a, 9b, 9c). . Device according to claim 1, characterized in that the air outlet (41) of the air nozzle is arranged directed away from the first end of the thermocouple, and preferably directed 90 degrees away from the extent of the rod-shaped thermocouple. . Device according to Claim 2, characterized in that the rod-shaped thermocouple (Za, 2b) is arranged on the upper part of the air nozzle and is directed vertically upwards into the unidentified bed (10). . Device according to Claim 3, characterized in that the rod-shaped thermocouple element (2a, 2b) is provided with a surrounding insulation (22, 23) between the first and second ends of the thermocouple. Device according to claim 4, characterized in that the connections (9a, 9b, 9c) of the thermocouple are arranged at least partially inside the duct system (5.6) -. System for determining the temperature in a combustion boiler (1) with fluidizing bed (10), containing a duct system (5,6) for combustion air and a number of air nozzles (4) connected to the duct system and arranged in the bottom of the boiler for supply of combustion air and the establishment of an unidentified bed characterized in that rod-shaped thermocouples (2a, 2b) are integrated with at least two of the air nozzles (4) arranged in the bottom of the boiler, one thermocouple (2a) having a first length (A ) and the second thermocouple (2b) has a second length (B) which is at least 100% longer than the first length, and where the thermocouples are connected to a detection device (8) via means (9a, 9b) for signal transmission. . System according to claim 6, characterized in that rod-shaped thermocouples (2a, 2b) are integrated with at least three of the air nozzles (4) arranged in the bottom of the boiler, the third thermocouple having a third length (C) which is at least 50% longer than the other length, and is connected to a detection device (8) via means (90) for signal transmission.