This application is a national stage application (filed under 35 § U.S.C. 371) of PCT/SE2018/050110, filed Feb. 6, 2018 of the same title, which, in turn, claims priority to Swedish Application No. 1730035-1 filed Feb. 8, 2017; the contents of each of which are hereby incorporated by reference.
The present invention relates to an apparatus and a method for cleaning smelt spouts and smelt discharge openings in the wall of a chemicals recovery furnace or boiler.
The method and device are advantageously used in an essential step in the production of chemical pulp. More specifically, said essential step relates to the recovery of pulp cooking chemicals from what is called black liquor, which is a rest product from such production in order to achieve chemical pulp with different specified properties. The chemical composition of these chemicals may, as a consequence, vary. The recovery takes place in a boiler wherein the temperature during the recovery process normally is in the order of about 1000° C. (1832° F.). At said temperature, the remaining wooden fiber is burnt and the pulp cooking chemicals may be recovered. Before its introduction into the boiler, the black liquor is concentrated to a water solution which contains about 65-90 percent of solid material. This solution is then sprayed into the recovery boiler, which is a kind of a chemical reduction furnace. A chemical reduction furnace is a reactor wherein processes of evaporation, gasification, pyrolysis, oxidation and reduction, occur mutually dependency during recovery of the chemicals. Organic materials such as lignin and other wood extracts maintain the combustion in the furnace, and the heat that is produced dries the spent cooking chemicals as they fall to the floor or bottom of the boiler. Here the dried chemicals pile up into a char bed. The char bed is further heated to form a liquid smelt that is discharged through one or more discharge openings and smelt spouts in a lower part or bottom of the boiler.
The combustion process requires the introduction of large volumes of air into the boiler. This air amounts to about 80 percent of the material introduced in the boiler.
The air is forced into the boiler from wind boxes or ducts disposed at several levels in surrounding relationship to the boiler, through a plurality of air inlet ports in the walls of the boiler, viz.: primary, secondary and tertiary air inlet ports. The primary air inlet ports, through which about 40 to 50 percent of the air is introduced, are disposed in the side walls in a lower portion of the boiler, close to the char bed. The secondary air inlet ports, through which about 35 percent of the air is introduced, are disposed around the boiler at higher level than the primary air inlet ports, and below the entry through which the black liquor is sprayed into the boiler. While the primary air inlet ports provide a relatively large volume of air with considerable turbulence for maintaining a fireball in the char bed, the secondary air inlet ports provide a finer control and distribution of air above the char bed and distribute the air evenly in the black liquor spray to support the combustion thereof. The black liquor sprayed into the boiler, having a consistency similar to heated oil, swirls, burns and falls towards the bottom of the boiler in the form of combustion products comprising char material and smelt.
Some of the smelt and char material that comes into contact with the wall of the boiler will be cooled by the inflowing air, thus building up deposits around the periphery of the air inlet ports. In accordance with customary practice, the char buildup is periodically dislodged, either manually by a worker inserting a rod into the air inlet ports, or by a mechanical cleaning apparatus. The dislodged char material falls into the smelt pool in the bottom of the boiler. A mechanical cleaning apparatus for cleaning air inlet ports in a recovery boiler is previously known from U.S. Pat. No. 4,423,533.
Smelt spouts are on the other hand designed to drain the smelt from the boiler, and to keep the smelt pool at a safe level. If the smelt spout is not cleaned periodically, the smelt will oxidize and form a crust which will clog the smelt spout. Clogged smelt spouts can cause the level of smelt inside the boiler to rise, resulting in inefficient and unpredictable operation, resulting in a reduction in the amounts of chemicals that can be recovered, a decrease in the amount of steam produced per unit of fuel, and increased emission of noxious gases such as carbon monoxide and sulfur dioxide.
Smelt spouts of soda recovery boilers are often cleaned manually by a worker inserting a long metal rod into the spout. Vigorous lateral and reciprocating movements of the rod by the worker dislodges any char or oxidized encrusted smelt that will be clogging the spout. Such manual rodding of the smelt spout is inefficient and also extremely unsafe. The temperature of the smelt amounts to an order of 1000° C., and although the rods utilized to clean the spouts are usually up to six meters long or more, there is great danger that a worker who manually rods such smelt spouts can be burned. Smelt spout openings are, due to the high temperature, cooled by water circulating in jackets surrounding both the discharge opening of the boiler and the spout, and during rodding the water jackets can be ruptured by the manual rodding operation, A broken water jacket may result in an explosion of the boiler because of the volatility of the smelt in the presence of water. One cubic meter of water released results in 8000 cubic meters of steam released in just a moment of time. A mechanical device for cleaning a smelt spout and discharge opening in the wall of a soda recovery boiler is previously disclosed in WO 2008/044984. A rod-shaped cleaning tool is rotationally arranged about its longitudinal axis in a carrier that is movably supported on wheels. The carrier and tool can be driven in reciprocating motion for moving the cleaning tool back and forth through the discharge opening and along the path of the smelt spout, which extends at a downwards slanting angle from the discharge opening in the boiler wall.
The present invention refers to an apparatus comprising a cleaning rod driven in reciprocating, axial extension and retraction movements upon cleaning a smelt discharge opening of a chemicals recovery boiler, wherein a linear actuator is controllable for driving the cleaning rod in the axial movements.
A cleaning apparatus of similar kind is previously known from U.S. Pat. No. 5,542,650 A (see FIGS. 25-30). In a cleaning sequence of dislodging encrusted material from the smelt spout, the cleaning rod is freely pivoting on a trunnion mount to allow the rod to move upwardly or downwardly along the spout while the rod is extended or retracted by the linear actuator. In an attempt to avoid contact of the cleaning rod with the bottom of the smelt spout, U.S. Pat. No. 5,542,650 A suggests that the cleaning rod be guided from a roller assembly that runs on edges of side walls to the smelt spout. It can however easily be foreseen that this solution may suffer badly from the harsh environment including high temperatures and splashes that would in practice hamper the operation of the roller assembly.
It is an object of the present invention to provide an alternative and improved apparatus for cleaning smelt spouts and discharge openings in the wall of a chemicals recovery boiler.
Another object of the present invention is to provide a not only improved but fully safe method for cleaning smelt spouts and discharge openings in the wall of a chemicals recovery boiler by use of a cleaning apparatus that is installable for operation in alignment with a smelt spout and smelt discharge opening.
Another object of the present invention is to provide an improved cleaning apparatus and method aimed for increasing the operational stability of a chemicals recovery boiler. Still another object of the present invention is to provide an improved cleaning apparatus and method aimed for reducing the exposure of workers to hazardous areas of a chemicals recovery boiler.
Yet another object of the present invention is to provide an improved cleaning apparatus that is safe to operate, and virtually eliminates the risk of rupturing the smelt spout during cleaning.
Still another object of the present invention is to provide an improved cleaning apparatus that is relatively light in weight and which can be manually installed or removed from a chemicals recovery boiler, quickly and easily as compared to prior art solutions.
It is finally an object of the present invention to provide a cleaning apparatus for installation in fixed or temporarily fixed relation to the smelt spout and discharge opening in the wall of a chemicals recovery boiler. Misalignment or dislocation caused by thermal expansion of the boiler body is thereby avoided or reduced to a minimum.
At least some of these objects are met in an apparatus comprising a cleaning rod driven in reciprocating, axial extension and retraction movements upon cleaning a smelt discharge opening of a chemicals recovery boiler, wherein a linear actuator is controllable for driving the cleaning rod in the axial movements. A pivot actuation means is controllable for pivoting the cleaning rod about an axis upon cleaning a smelt spout associated with the smelt discharge opening. One or more sensors are arranged to provide control basis for correlation of the axial movements with the change in pivot angle during pivoting of the cleaning rod.
The combination of movements and actuator control built into the cleaning apparatus so defined provide the technical and operative conditions required for automation, thus offering the possibility for avoiding hazardous, manual cleaning work. In that sense, the cleaning apparatus may be seen as an automatic or at least semiautomatic robot which only requires, at its utmost, a start signal from an operator to initiate a cleaning sequence. If a fully automatic procedure is aimed for, this can be achieved by arranging the start of the cleaning sequence dependent on certain conditions relating to the chemicals recovery process. One such condition that can be monitored and forming a basis for commencement of cleaning is, e.g. the temperature in the smelt spout which can be monitored by a temperature sensor.
In one embodiment, the cleaning apparatus comprises one or more sensors monitoring at least one of the rod axial and pivoting movements, wherein the operation of at least one of the linear actuator and the pivot actuation means is based on output from the one or more sensors.
In one embodiment, the pivot actuation means is arranged for adjusting the speed of the pivoting movement based on readings from a rod axial motion sensor monitoring the axial movements during pivoting of the cleaning rod. A rod axial motion sensor can be realized as one of: a proximity sensor; one or more limit switches or an end position sensor; or an encoder in a servomotor of the linear actuator, e.g.
The linear actuator is in one embodiment arranged for adjusting the speed of axial movement based on readings from an angle position sensor which is monitoring the change in pivot angle during pivoting of the cleaning rod.
An angle position sensor can be realized as one of: a set of light sensors or photo cells monitoring the pivot area of the cleaning rod; a fixed position video camera with associated image processing software; or an encoder in a servomotor of the pivot actuation means, e.g.
The axial and pivoting movements can thus both be actively controlled and balanced such that speed or amount/length of axial travel is proportionate to applied speed or amount of change in angular position during pivoting. In this disclosure, the coordination of axial and pivoting movements is defined as “correlation”, in order to underline that each movement depends on the other. This correlation between axial and pivoting movements provides the technical effect and advantage that damage to the smelt spout can be avoided by ensuring that the cleaning rod travels along the smelt spout under maintenance of a clearance to the metallic bottom of the smelt spout. The cleaning apparatus may be arranged for supporting the cleaning rod in permanent or temporary alignment with the smelt spout and the smelt discharge opening. These features provide the optional implementation of one cleaning apparatus per each smelt spout/discharge opening in the boiler, or the choice of successively cleaning the smelt spouts/discharge openings by use of a movable cleaning apparatus that can be shifted from one smelt spout to the other.
In one embodiment, the cleaning apparatus is supported in a fixture that is connectable to the boiler. In alternative embodiments the cleaning apparatus may be supported in a fixture which is freestanding from the boiler, although it may be located in fixed relation to the boiler.
These features can be alternatingly applied in set-ups where boiler movement caused by thermal expansion needs to be accounted for. Thus, in the first mentioned alternative the cleaning apparatus is arranged to follow any movement of the boiler that is due to thermal expansion, whereas in the second alternative thermal expansion is not allowed to affect the suspension and alignment of the cleaning apparatus. In one embodiment a fixture frame comprises, in a side facing the boiler, positioning means mating with corresponding positioning means arranged on an adapter that is connectable to the boiler.
This embodiment ensures a correct alignment with the smelt spout and discharge opening through a forced mating between the cleaning apparatus and a docking member attached to the boiler.
The following features and details define advantageous embodiments of the cleaning apparatus:
The cleaning rod is supported in a swing that is pivotally arranged between a couple of arms, one end of which, respectively, is anchored in the fixture or the boiler wall.
In one embodiment, the swing comprises a rack and pinion drive, or a ball-screw, or a trapezoidal threaded bar mechanism operable for moving a driver, in which the cleaning rod is anchored for axial movements in extension and retraction.
In one embodiment, the change in angular position of the cleaning rod is monitored by an angle position sensor which is operatively coupled to a pivot axis of the cleaning rod or the swing.
The pivot actuation means may be an angular actuator or a linear actuator.
The cleaning apparatus may be pivotally connected to the boiler.
In one embodiment, the cleaning rod is pivotally supported in the outer ends of a couple of arms, the inner ends of which are pivotally journaled at the boiler.
The latter embodiment provides overload protection for the cleaning apparatus, in particular for the components of a cleaning rod drive mechanism included in the cleaning apparatus.
A pivotal connection of the cleaning apparatus to the boiler further adds to the protection of the smelt spout by permitting the cleaning apparatus to “lift” from the spout in case the cleaning rod, accidentally, would hit heavily against the bottom of the smelt spout.
The objects of the invention are likewise met in a method of cleaning a smelt spout and a smelt discharge opening of a chemicals recovery boiler by using a cleaning apparatus comprising a cleaning rod driven in reciprocating, axial extension and retraction movements, wherein the method comprises: sequentially extending and retracting the cleaning rod in a step of cleaning the smelt discharge opening; and pivoting the cleaning rod in a step of cleaning the smelt spout, wherein axial movements are correlated with the change in pivot angle during pivoting of the cleaning rod based on readings from one or more sensors.
The method may further comprise the steps of:
More precisely, in one embodiment, the speed of the axial movement is increased progressively with increasing pivot angle.
In an alternative embodiment, the method comprises the steps of:
During the pivoting motion, the tip of the cleaning rod is advantageously maintained at a distance within about 1 mm to 50 mm from the bottom of the smelt spout, or at a minimum distance of about 1 mm to 20 mm from the bottom of the smelt spout. In a further step of automation of the cleaning process, initiation of a cleaning session is based on readings from a temperature sensor that monitors the temperature in the smelt spout.
The invention will be further explained below with reference made to the accompanying, schematic drawings, wherein
With reference to
In
An apparatus 7 arranged for cleaning and removing encrusted material from the discharge opening 5 and from the smelt spout 4 will now be described with reference made to the left and right-hand perspective views of
The fixture frame 10 is a box-like design comprising left and right support sections 12 and 13, defining between them a central slot 14 which is dimensioned to receive an upper end of the smelt spout 4 as the fixture frame 10 and cleaning apparatus 7 are aligned with the smelt spout and the discharge opening 5.
Each support section 12 or 13 comprises a set of reinforcement elements 15 designed to take up the load from the cleaning apparatus via a sub-frame 16, by which sub-frame the inner end of each arm is journaled pivotally in the fixture frame 10, on a pivot 17 respectively. To be more specific, the sub-frames 16 extend below the arms 8 and 9 so as to support the cleaning apparatus 7 in a mainly horizontal position from which the cleaning apparatus is permitted to move pivotally upwards, for reason which will be discussed below.
As disclosed herein, basically, the arms 8, 9 can be designed as self-supported or cantilever members. However, in alternative embodiments, the free outer ends of the arms 8 and 9 may be supported from the boiler building, such as suspended in ropes hanging down from a structural element in the building. If appropriate, suspension of the outer ends of the arms 8 and 9 may include a degree of elasticity, such as through tension springs inserted in supporting ropes, e.g.
The cleaning apparatus 7 can be arranged for permanent or temporary alignment with the smelt spout 4 and the discharge opening 5. In this connection, alignment refers on one hand to the orientation of the cleaning apparatus in parallel with the smelt spout as seen in a horizontal plane, and to the positioning of the cleaning apparatus with respect to the vertical height of the smelt discharge opening on the other hand. In permanent alignment, the fixture frame 10 can be mounted to the boiler wall or to any structural element which is attached to the boiler wall. Permanent alignment may alternatively foresee that the cleaning apparatus is stationary supported in a structure that is freestanding from the boiler. An example of the latter is given in
In temporary alignment, the cleaning apparatus may be movably supported in a structure that is freestanding from the boiler, or movably supported in a structure that is connectable to the exterior of the boiler. In a case where the cleaning apparatus is to be moved from one smelt spout to another in sequential cleaning operations, e.g., the cleaning apparatus may be arranged movable on a rail that runs horizontally at a fixed distance from the boiler. Such a rail can be supported in structural parts of the boiler building, or supported on the exterior of the boiler.
Albeit there are several options available for a skilled person to adapt the suspension of the cleaning apparatus to a specific boiler application through a corresponding design of supporting structures, an essential aspect and requirement in any application is the correct alignment between the cleaning apparatus on one hand, and the smelt spout and discharge opening in the boiler wall on the other hand. Affordable tolerances in this respect should preferably be defined in millimeters in order to avoid harmful contact with the boiler wall and the smelt spout during the cleaning operation.
In the embodiment of
In the outer end of the arms 8 and 9, the drive mechanism 11 for a cleaning rod is arranged to pivot about an axis S which is defined by a couple of pivot pins (invisible in
The linear actuator 33 advantageously includes a servomotor with encoder that provides feedback on the revolutions of the motor axis to a control system that correlates the operation of the linear actuator with the operation of a pivot actuation means, as will be further described hereinafter. The driver 26 further includes structural members in the form of a couple of plates 34 and 35, which are interconnected through the housings 36 and 37 that accommodate the slide bearings 29 and 30. As is best seen in
In this connection, it can be pointed out although not explicitly illustrated in the drawings, that the cleaning rod 38 may be anchored in the driver 26 by means of elastic elements, such as rubber or polymer bushings, in order to prevent shocks from impact with encrusted material to be transferred to the components of the drive mechanism. It serves also to be mentioned, although not being an essential part of the present invention, that the cleaning rod may be arranged for carrying exchangeable cleaning tools in its forward end or tip 38′.
Pivoting of the cleaning rod drive mechanism 11 is accomplished and controlled through a pivot actuation means. In the embodiment of
However, the readings made by the angle position sensor 40 are also used for controlling the speed or amount by which the cleaning rod 38 is retracted or extended upon pivoting of the cleaning rod 38.
In this connection, reference is made to
An example of the correlation between the axial and pivotal movements of the cleaning rod is illustrated in the diagram of
The diagram of
In all cases, the correlation is computed in a control unit running a software coded routine which uses the dynamic inputs from one or more sensors or detectors together with, e.g., static data, such as the spatial coordinates and inclination of the smelt spout and the maximum extension of the cleaning rod, which can be used to initiate the pivoting motion. Instead of static data or in combination therewith, proximity sensors may be used to define continuously the position of the cleaning rod in extension and retraction modes.
The readings from the sensors or detectors are thus used for controlling the operation of the linear actuator 33 and/or the pivot actuation means 39, 41 in order to correlate and synchronize the axial and pivotal movements of the cleaning rod. This correlation may include not only a controlled retraction of the cleaning rod, but also a controlled extension of the cleaning rod if required, depending on the subject geometries. In typical cases, the correlation includes controlling the power supply, running time and rotational direction in the linear and/or pivot actuator means so as to maintain the tip of the cleaning rod at a minimum distance of about 1 mm to about 20 mm from the bottom of the smelt spout. In some cases, the distance may vary within about 1 mm to about 50 mm from the bottom of the smelt spout (depending, e.g., on the amount and status of the encrustations which are blocking the smelt spout).
For example, readings by sensors for detecting the angular and axial position of the cleaning rod can be recorded in the control unit during a first setup run wherein the cleaning rod is pivoted along the smelt spout at defined force. The recorded data is thereafter used for controlling the linear actuator 33 and the angular actuator 39 in successive strokes wherein the cleaning rod is pivoted along the smelt spout with controlled motion and force.
The operation of the cleaning apparatus during a cleaning session is schematically illustrated in the sequential views of
This motion is mainly horizontal, meaning that the orientation of the cleaning rod preferably lies within a few degrees' interval over or under the horizontal plane. In fact, the expression “mainly horizontal” shall be understood to include a deviation from the true horizontal of less than +/−45°, such as within an interval of +/−30°, or even more preferred in the interval of +/−15° of elevation.
During the cleaning sequence depicted in
An overload protection for the cleaning rod drive mechanism may alternatively include a resilient and elastic anchoring of the inner arm ends in the fixture frame 10, or as a third alternative, a resilient and elastic attachment of the console elements 22 and 23 to the outer ends of the arms 8 and 9.
During this sequence, the angular actuator 39 is operated for pivoting the cleaning rod as shown by the arrow φ, whereas the linear actuator 33 is controlled for retraction x of the cleaning rod, in synchronization with the pivoting motion as previously explained.
In this connection it should be observed that the speed of the pivoting motion may be adapted to the flow velocity of the smelt in the smelt spout in order to avoid splatter. After completed cleaning, the cleaning apparatus is returned to its initial position by reversed operation of the angular actuator 39 as illustrated by the arrow R in
The same modus operandi is performed by the slightly modified embodiment shown in
The linear and angular actuators 33, 39 and 41 may be realized as double-acting or reversible operation drives, powered by air, hydraulic fluid or electricity. The angular actuator 41 may alternatively include a single acting, spring return piston/cylinder unit.
In yet an alternative, an external spring may be applied outside the angular actuator, and more specifically for either of two alternative purposes: i) external spring(s) applied and dimensioned for returning the cleaning apparatus to its initial position, or ii) external spring(s) applied and dimensioned to provide a more even load and thus avoiding load peaks in the angular actuator as the cleaning rod tip travels down an unevenly encrusted smelt spout. In
With reference to
With further reference to
From the above description it will be realized, that the present cleaning apparatus and method shall not be strictly limited to use and application in connection with recovery of pulp cooking chemicals from black liquor in soda recovery boilers, but that the apparatus' structure and operation is likewise useful in connection with any similar process performed in chemicals recovery furnaces and boilers in general.
It should also be noted that, in prior art, spout cleaning has involved driving the cleaning tool upwards along the spout. Although not being a preferred practice, an upwards cleaning of the spout would still benefit from the correlation between rod pivoting and axial movements as provided by the cleaning apparatus of the present invention. The invention is thus not limited to correlation between pivoting and retraction applied in downwards cleaning mode, but is likewise applicable to pivoting during extension of the cleaning rod in upwards cleaning mode.
Number | Date | Country | Kind |
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1730035-1 | Feb 2017 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2018/050110 | 2/6/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/147788 | 8/16/2018 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4423533 | Goodspeed | Jan 1984 | A |
4706324 | Goodspeed | Nov 1987 | A |
4822428 | Goodspeed | Apr 1989 | A |
5542650 | Abel et al. | Aug 1996 | A |
8424150 | Higgins et al. | Apr 2013 | B1 |
20080282486 | Pingel | Nov 2008 | A1 |
20090066169 | Schweiher et al. | Mar 2009 | A1 |
Number | Date | Country |
---|---|---|
1914477 | Apr 2008 | EP |
560129 | Mar 1944 | GB |
WO03093747 | Nov 2003 | SE |
WO2006126929 | Nov 2006 | SE |
03093747 | Nov 2003 | WO |
2006126929 | Nov 2006 | WO |
2008044984 | Apr 2008 | WO |
2013071008 | May 2013 | WO |
Entry |
---|
Mats Bertilsson Förvaltning AB, International Application No. PCT/SE2018/050110, International Search Report, dated Mar. 14, 2018. |
Mats Bertilsson Förvaltning AB, International Application No. PCT/SE2018/050110, Written Opinion, dated Mar. 14, 2018. |
Mats Bertilsson Förvaltning AB, European Application No. 18751368.4, Extended European Search Report, dated Dec. 11, 2020. |
Mats Bertilsson Förvaltning AB, International Application No. PCT/SE2018/050110, International Preliminary Report on Patentability, dated Aug. 13, 2019. |
Number | Date | Country | |
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20200025373 A1 | Jan 2020 | US |