The present invention generally relates to a multiple hearth furnace (MHF).
Multiple hearth furnaces (MHFs) have been used now for about one century for heating or roasting many types of material. They comprise a plurality of hearth chambers arranged one on top of the other. Each of these hearth chambers comprises a circular hearth having alternately a central material drop hole or a plurality of peripheral material drop holes therein. A vertical rotary shaft extends centrally through all these superposed hearth chambers and has in each of them a rabble arm fixing node. Rabble arms are connected in a cantilever fashion to such a rabble fixing node (normally there are two to four rabble arms per hearth chamber). Each rabble arm comprises a plurality of rabble teeth extending downwards into the material on the hearth. When the vertical rotary shaft is rotated, the rabble arms plough material on the hearth with their rabble teeth either towards the central drop hole or towards the peripheral drop holes in the hearth. Thus, material charged into the uppermost hearth chamber is caused to move slowly downwards through all successive hearth chambers, being pushed by the rotating rabble arms over the successive hearths alternately from the periphery to the center (on a hearth with a central material drop hole) and from the center to the periphery (on a hearth with peripheral material drop holes). Arrived in the lowermost hearth chamber, the roasted or heated material leaves the MHF through a furnace discharging opening.
In a MHF, the vertical rotary shaft as well as the rabble arms are tubular structures that are cooled by a cooling fluid, usually a gaseous cooling fluid as ambient air (for the sake of simplicity, the gaseous cooling fluid will be called herein “cooling gas” even if it is a mixture of several gases). The vertical rotary shaft includes a cooling gas distribution channel for supplying the cooling gas to the rabble arms. From this cooling gas distribution channel, the cooling gas is channeled through the connection between the rabble arm and the rabble arm fixing node into the tubular structure of the rabble arm. As the cooling system of the rabble arm is normally a closed system, the cooling gas returning from the rabble arm must be channelled through the connection between the rabble arm and the rabble arm fixing node into an exhaust gas channel in the vertical rotary shaft.
The connection between a cantilever rabble arm and the vertical rotary shaft must fulfil at least following requirements. It must be strong enough to support not only the weight of the arm but also the considerable torque and shearing forces generated when the rabble teeth plough through the material on the hearth. It must be reliable at operating temperatures of the MHF, i.e. temperatures up to 1000° C., and when the rabble arm is subjected to vibrations. It must be capable of channeling the cooling gas from the vertical rotary shaft to the rabble arm and vice versa, with reasonable pressure loss and without cooling gas leakage into a hearth chamber and between the supply flow and the return flow of the cooling gas. Last but not least, it should allow an easy exchange of the rabble arm, preferably without having to completely cool down the MHF.
In the last hundred years, there have been described many different connections between the cantilever rabble arm and the vertical rotary shaft. For example:
U.S. Pat. No. 1,164,130 and U.S. Pat. No. 1,468,216 both describe a MHF in which the rabble arm is provided with a tubular coupling end that fits into a socket provided in the vertical rotary shaft. The tubular coupling end of the rabble arm is basically a cylindrical body but it may be slightly tapered. In order to secure the rabble arm in proper position, its tubular coupling end is provided with a locking lug, adapted to pass through a slot provided in a rim at the entrance of the socket and to engage a sloping inner edge of a locking shoulder or cam surface provided on the inner wall of the socket. The tubular coupling end of the rabble arm is introduced into the socket and then given a 90° turn to engage the locking lug behind the locking shoulder and draw the tubular coupling end of the rabble arm into the socket. A stop shoulder is provided on the inner wall of the socket to prevent further turning movement of the rabble arm when the parts have been brought into proper position. Such a prior art locking system may easily loosen during operation of the MHD. Furthermore, giving a 90° turn to the rabble arm to secure it within the socket is not an easy operation within a hearth chamber.
FR 620.316 describes a MHF in which the rabble arm is provided with a tubular cylindrical coupling end that fits into a cylindrical socket provided in a rabble arm fixing node of the vertical rotary shaft. A bent tie rod extends over the whole length of the rabble arm through one of two superposed channels in the rabble arm. The end of the tie rod that protrudes eccentrically out of the tubular cylindrical coupling end of the rabble arm supports a dove-tail head to engage a dove-tail groove in an internal wall of rabble arm fixing node. The end of the tie rod protrudes axially out of the front end of the rabble arm and supports a thread on which is screwed a nut. Tightening this nut axially presses the tubular cylindrical coupling end of the arm into its cylindrical socket in the rabble arm fixing node. It is obvious that it will be not very easy to engage the dove-tail head of the tie rod into the dove-tail groove in the rabble arm fixing node.
U.S. Pat. No. 1,687,935 describes a MHF in which the rabble arm is provided with a tubular conical coupling end engaging an adapter member on the shaft. The tubular conical coupling end has two spaced convex cylindrical bearing portions thereon. The smaller convex cylindrical bearing portion located at the front end of the tubular conical coupling end engages a cylindrical coupling sleeve of a conduit inside the adapter member. The bigger convex cylindrical bearing portion located at the rear end of the tubular conical coupling end engages a cylindrical coupling sleeve at the entrance of the adapter member. A radial securing pin is used to secure the tubular conical coupling end of the rabble arm within the adaptor member. Such a rabble arm locking system may easily loosen when the rabble arm is subjected to vibrations. Furthermore, one can easily imagine that it will be not very easy to mount or dismount the securing pin without entering into the MHF. Last but not least, the adapter member as described in U.S. Pat. No. 1,687,935 is most probably too bulky to be integrated into a normal sized vertical rotary shaft.
U.S. Pat. No. 3,419,254 describes a MHF in which the fixing system for the cantilever rabble arms is similar to the system described in U.S. Pat. No. 1,687,935. The rabble arm is provided with a tubular conical coupling end engaging an opening in the shaft. The tubular conical coupling end has two spaced convex cylindrical bearing portions thereon. The smaller convex cylindrical bearing portion located at the front end of the tubular conical coupling end engages an opening in an inner tubular member of the vertical rotary shaft. The bigger convex cylindrical bearing portion located at the rear end of the tubular conical coupling end engages a cylindrical coupling surface surrounding an opening within an outer tubular member of the shaft. A radial securing pin is used to secure the tubular conical coupling of the rabble arm within the shaft. Such a rabble arm locking system may loosen when the rabble arm is subjected to vibrations. Furthermore, one can e.g. easily imagine that it will be not very easy to mount or dismount the securing pin without entering into the MHF. Last but not least, the integration of cylindrical bearing openings for the tubular conical coupling end directly into the inner and outer tubular member of the vertical rotary shaft necessitates considerable local reinforcement of this inner and outer tubular member and causes moreover problems as far as gas tightness is concerned.
U.S. Pat. No. 1,732,844 describes a MHF in which the rabble arm is provided with a tubular coupling end that fits into a socket provided in big diameter vertical rotary shaft. A concave conical seat surface is arranged around the inlet of the socket and a convex conical counter-seat surface formed by a shoulder on the tubular coupling end of the rabble arm. The tubular coupling end is secured in its socket by means of a pawl that can be operated from the interior of the shaft and that is engaging a shoulder formed on the tubular coupling end of the rabble arm. It is obvious that such a rabble connecting system is only possible for a MHF having a big diameter vertical rotary shaft, which permits securing the rabble arms from the inside of the vertical rotary shaft.
DE 350646 describes a MHF which has been conceived to be used with air and water as cooling fluid. The rabble arm is provided with a tubular coupling end that fits into connecting box of a big diameter vertical rotary shaft. The connecting box comprises inlet opening surrounded by a first concave conical seat surface and an internal partition wall with a second opening therein. The inlet opening gives access to a first connection chamber and the opening in the internal partition wall gives access to a second connection chamber, which is separated from the first connection chamber by the internal partition wall. The tubular coupling end of the rabble arm has a shoulder forming a convex conical counter-seat surface sitting on the first concave conical seat surface surrounding the inlet opening of the connecting box. A conical extension of the tubular coupling extends in a sealed manner through the second opening into the second connection chamber. The conical extension of the tubular coupling supports a threaded rod that extends in sealed manner into the inside of the shaft, where it is secured by means of a nut. It is obvious that such a rabble connecting system is only possible for a MHF having a big diameter vertical rotary shaft for integrating therein a rather huge connecting box and allowing to secure the rabble arms from the inside of the vertical rotary shaft.
DE 263939 describes a rabble arm fixed to a vertical rotary hollow shaft. The rabble arm includes a tubular structure of cast iron, which is designed for circulating therethrough a cooling gas. A cylindrical tubular coupling end of the rabble arm is received in a cylindrical socket arranged in the vertical rotary hollow shaft. A shoulder surface of this coupling end sits on a seat surface surrounding the socket on the vertical shaft. A seal ring is arranged between the shoulder surface of the coupling end and the seat surface on the vertical shaft. A clamping bolt, which extends from the coupling end of the rabble arm to the front end of the rabble arm, is provided for securing the rabble arm with its coupling end in the socket. This clamping bolt protrudes out of the coupling end of the rabble arm, where it has a bolt head that can be brought by rotation of the clamping bolt about its central axis into and out of hooking engagement with an abutment surface on the arm fixing node. At the front end of the rabble arm, a threaded sleeve is screwed onto a threaded end of the clamping bolt for exerting a clamping force onto the clamping bolt. In an alternative solution, the bolt head is designed as a screw-nut. It will be noted that the rabble arm securing means described in DE 263939 has major drawbacks. Already a slight mechanical deformation or an overheating of the rabble arm may indeed deform, damage or even rupture the clamping bolt extending through the rabble arm. It will in particular be noted that already small plastic elongations of the clamping bolt, due e.g. to an overheating of the rabble arm, will reduce the clamping force to zero. Last but not least, it will be very hard to dismount a rabble arm, once its clamping bolt has only slightly been deformed.
DE 268602 describes a tubular rabble arm which is said to overcome the drawbacks of the rabble arm disclosed in DE 263939. The rabble arm with its cylindrical coupling end form a one piece cast tube, with a cast-in central partition wall. The latter separates a first path for the cooling gas flowing to the front end of the rabble arm, from a second path for the cooling gas flowing back to the coupling end. A short length clamping bolt is arranged in a tubular socket axially protruding into the tubular coupling end. A first end of the clamping bolt protrudes out of the coupling end of the rabble arm, where it has a bolt head that can be brought by rotation of the clamping bolt about its central axis into and out of hooking engagement with an abutment surface on the arm fixing node. A threaded sleeve is screwed onto a threaded end of the clamping bolt protruding out the tubular socket. This threaded sleeve bears onto the end face of the tubular socket for exerting a clamping force onto the clamping bolt. The middle portion of the cast-in partition wall is curved over its whole length in order to provide free access to the threaded sleeve from the front end of the rabble arm; so that the threaded sleeve may be tightened or loosened with a key mount on a bar. The cooling gas supply means comprises an opening, which is arranged in the cylindrical wall of the tubular extension to communicate with said first path. The cooling gas return means comprises an opening, which is arranged in a base plate of the tubular extension to communicate with said second path.
In modern MHFs, the rabble arm comprises most often a connecting branch with a ring-flange for connecting a rabble arm thereto. The rabble arm comprises at its rear end a tubular coupling body with a counter-ring-flange that is bolted onto the ring-flange of the connecting branch. Such a flange-connection warrants high mechanical resistance, even at high operating temperatures of the MHF and does hardly loosen when the rabble arm is subjected to vibrations. However, exchanging a rabble arm with a flange-connection necessitates that workers penetrate into the hearth chamber for separating or renewing the flange-connection between the rabble arm and the connecting branch. This requires of course that the MHF is first cooled down prior to exchanging the rabble arm.
The invention provides a MHF with a compact system for connecting the rabble arms to the vertical rotary shaft, which warrants that the rabble arms are reliably secured to the rotary shaft but can nevertheless be easily exchanged, and in which the rabble arm securing means are relatively well protected against mechanical deformations and overheating of the rabble arm.
The invention proposes a MHF comprising a vertical rotary hollow shaft with at least one rabble arm. This at least one rabble arm includes a tubular structure for circulating therethrough a cooling fluid and a coupling end that is received in a socket arranged in an arm fixing node of the vertical rotary hollow shaft. This coupling end includes at least one cooling fluid supply channel and at least one cooling fluid return channel therein. A securing means is provided for securing the rabble arm with its coupling end in the socket. This securing means includes a clamping bolt for pressing the plug body into the socket. The clamping bolt protrudes out of the coupling end of the rabble arm, where it has a bolt head that can be brought by rotation of the clamping bolt about its central axis into and out of hooking engagement with an abutment surface on the arm fixing node. A threaded sleeve is screwed onto a threaded end of the clamping bolt for exerting a clamping force onto the clamping bolt. In accordance with one aspect of the present invention, the coupling end is formed by a solid plug body, which is connected to the tubular structure of the rabble arm and has a front end and a rear end. A through boring extends axially from the front end to the rear end, wherein the at least one cooling fluid supply channel and the at least one cooling fluid return channel are arranged in the plug body around the through boring. The clamping bolt is rotatably fitted in the through boring and its threaded end sticks out of the through boring at the rear end of the plug body. The threaded sleeve, which is screwed onto the threaded end, bears on an abutment surface at the rear end of the plug body for exerting the clamping force onto the clamping bolt. The tubular structure of the rabble arm comprises an arm support tube, which is connected to the rear end of the plug body, and a gas guiding tube, which is arranged inside the arm support tube and cooperates with the latter to define between them a small annular cooling gap for channelling the cooling gas from the shaft to the free end of the rabble arm. The interior section of the gas guiding tube forms a return channel for the cooling gas. The cooling fluid supply and return means include at least one cooling fluid supply channel and at least one cooling fluid return channel arranged in the solid plug body around the through boring. At the rear end of the solid plug body, the at least one cooling fluid supply channel is in communication with the small annular cooling gap, and the at least one cooling fluid return channel is in communication with the return channel.
A preferred embodiment of the bolt head has for example the form of a hammer head defining a shoulder surface on each side of the shank, wherein the hammer head bears with both shoulder surfaces against the abutment surface on the rabble arm fixing node. However the bolt head may of course also have the form of a simple hook defining only a single shoulder surface. It may also have a more complicated form, provided that it is still capable of being brought by rotation of the clamping bolt about its central axis into and out of hooking engagement with an abutment surface on the arm fixing node.
For easily tightening or loosening of the threaded sleeve bearing on the abutment surface at the rear side of the plug body and for easily checking that it has e.g. not loosened, the securing means further comprises an actuation tube secured with a first end to the threaded sleeve and extending through the entire rabble arm up to the free end of the latter, where its second end supports a coupling head for coupling thereto an actuation key for transmitting a torque to the threaded sleeve via the actuation tube. Alternatively, the coupling head for coupling thereto an actuation key could be directly secured to the threaded sleeve, i.e. without actuation tube permanently secured to the threaded sleeve. This alternate solution would however make more difficult coupling an actuation key to the sleeve and checking that the threaded sleeve is sufficiently tightened.
The clamping bolt is advantageously connected to a positioning tube extending through the entire rabble arm up to the free end of the latter. The positioning tube allows to easily position the clamping bolt, to hold the latter in place when a torque is exerted onto the threaded sleeve and to check the angular position of the bolt head. The positioning tube is advantageously co-axial to and rotatably supported within the actuation tube, i.e. it takes no further place within the tubular structure of the rabble arm.
The tubular structure of the rabble arm normally includes an arm support tube, wherein the plug body is connected to one end of the arm support tube and its other end is closed by an end-cup. The actuation tube then axially extends through the arm support tube and its free end is rotatably supported in a sealed manner in a through hole of the end-cup. This arrangement allows e.g. to visually inspect the position of the coupling head of the actuation and positioning tube, without gas leakage through the front end of the arm.
Instead of having a tubular coupling end, as in all prior art rabble arms, the rabble arm has solid plug body that is advantageously a cast body secured to the tubular structure of the rabble arm, wherein the hole in which the cylindrical shank portion is fitted and the at least one cooling fluid supply channel and the at least one cooling fluid return channel are provided as bores in said solid cast body (comprising straight through bores and composite bores). It will be appreciated that such a plug body, which can be manufactured without necessitating complicated casting moulds, is a particularly compact, strong and reliable connection means for connecting the rabble arm to the vertical rotary shaft.
In a preferred embodiment of the MHF, the socket has therein a first or inner concave conical seat surface located in proximity of its bottom surface and a concave cylindrical guiding surface located closer to the entrance opening of the socket, and the plug body has thereon a first convex conical counter-seat surface and a convex cylindrical guiding surface cooperating with said concave conical seat surface, respectively said concave cylindrical guiding surface in the socket. More particularly, the cylindrical guiding surfaces cooperate with one another for guiding the plug body of the rabble arm axially into and out of a position in which the plug body sits with its first convex conical counter-seat surface on the first concave conical seat surface. It will be appreciated that axial guidance provided by the two cylindrical guiding surfaces and considerably reduces the risk of damaging the plug body or the socket during the final coupling operation. When the plug body sits in its socket, its first convex conical counter-seat cooperates with the first concave conical seat surface to provide a first sealing function between the plug body and the socket near the bottom of the socket. This first sealing function allows e.g. to provide a cooling gas connection in the front end of the plug body.
The socket has advantageously therein a second or outer concave conical seat surface, the concave cylindrical guiding surface lying between the first concave conical seat surface and the second concave conical seat surface. The plug body has then thereon a second convex conical counter-seat surface, the convex cylindrical guiding surface lying between the first convex conical counter-seat surface and the second convex conical counter-seat surface. During introduction of the plug body into the socket, the outer concave conical seat surface first guides the plug body into axial alignment with the cylindrical guiding surface. When the plug body sits in its socket, its second convex conical counter-seat cooperates with the second concave conical seat surface to provide a second sealing function between the plug body and the socket near the entrance of the socket. This second sealing function allows e.g. to provide a cooling sealed gas connection in the cylindrical guiding surfaces.
Thus, with the configuration described in the preceding paragraph, at least one cooling gas channel is advantageously arranged in the rabble arm fixing node that has an opening in the concave cylindrical guiding surface; and at least one cooling gas channel is then arranged in the plug body of the rabble arm that has an opening in the convex cylindrical guiding surface, wherein the openings are overlapping when the plug body is seated on its seats in the socket.
The rabble arm fixing node comprises advantageously a ring-shaped cast body made of refractory steel, the sockets being radially arranged in the ring-shaped cast body. It will be appreciated that such a rabble arm fixing node is a particularly compact, strong and reliable connection means for connecting the rabble arm to the vertical rotary shaft.
The shaft advantageously includes a support structure consisting of the rabble arm fixing nodes and of intermediate support tubes that are interposed as structural load carrying members between the rabble arm fixing nodes described in the preceding paragraph. The rabble arm fixing nodes and the intermediate support tubes are preferably assembled by welding. It will be appreciated that such a shaft can be easily manufactured at relatively low costs using standardized elements. It provides however a strong, long-lasting support structure that has a very good resistance with regard to temperature and corrosive agents in the hearth chambers.
At least one section of the shaft extending between two adjacent hearth chambers comprises: a intermediate support tube fixed between two arm fixing nodes to form an outer shell; an intermediate gas guiding jacket arranged within the intermediate support tube so as to delimit an annular main cooling gas supply channel between both; and an inner gas guiding jacket arranged within the intermediate support tube so as to delimit annular main cooling gas distribution channel between both, the inner gas guiding jacket further defining the outer wall of a central exhaust channel. Such a shaft section with three concentric passages for the cooling gas, warrants an excellent cooling of the outer wall of the shaft section, i.e. the load bearing intermediate support tube. The latter forms indeed the outer wall of the main cooling gas supply channel, through which the whole cooling gas supply flow is channeled before it is distributed on the rabble arms.
The arm fixing node advantageously comprises a ring-shaped cast body including: at least one of the sockets for receiving therein the plug body of the rabble arm; a central passage forming the central exhaust channel for the cooling gas within the arm fixing node; first secondary passages arranged in a first ring section of the cast body, so as to provide gas passages for cooling gas flowing through the annular main cooling gas distribution channel; second secondary passages arranged in a second ring section of the cast body, so as to provide gas passages for cooling gas flowing through the annular main cooling gas supply channel; a first channel means arranged in the cast body, so as to interconnect the annular main cooling gas supply channel with a gas outlet opening within the at least one socket; and a second channel means arranged in the cast body, so as to interconnect a gas inlet opening within the at least one socket with the central passage. The first channel means advantageously comprises at least one oblique bore extending through the ring-shaped cast body from the second ring section into a lateral surface delimiting the socket. The second channel means advantageously comprises a through hole in axial extension of the socket. This embodiment of an arm fixing node combines a low pressure drop cooling gas distribution in the shaft and a solid fixing of the rabble arm on the shaft with a very compact and cost saving design. With its integrated gas passages, it substantially contributes to the fact that the vertical rotary shaft, which includes three co-axial cooling channels therein, can be manufactured using a very small number of standardized elements. It also essentially contributes to warranting a strong, long-lasting shaft support structure with a very good resistance with regard to temperature and corrosive agents in the hearth chambers.
A micro porous thermal insulation layer is advantageously arranged on the arm support tube; and a metallic protecting jacket is covering the micro porous thermal insulation. Metallic rabble teeth are in this configuration advantageously directly welded to the metallic protecting jacket, wherein anti-rotation means are then arranged between the arm support tube and the metallic protecting jacket.
Further details and advantages of the present invention will be apparent from the following detailed description of a preferred but not limiting embodiment with reference to the attached drawings, wherein:
The MHF as shown in
Reference number 20 identifies a vertical rotary hollow shaft coaxially arranged with the central axis 21of the furnace 10. This shaft 20 passes through all hearth chambers 12, wherein a hearth without central material drop hole 18—such as e.g. hearth 142 in FIG. 1—has a central shaft passage opening 22 to allow the shaft 20 to freely extend therethrough. In a hearth with a central material drop hole 18—such as e.g. hearth 141 in FIG. 1—the shaft 20 extends through the central material drop hole 18. It will be noted in this context that the central material drop hole 18 has a much bigger diameter than the shaft 20, so that the central material drop hole 18 is indeed an annular opening around the shaft 20.
Both ends of the shaft 20 comprise a shaft end with a journal rotatably supported in a bearing (not shown in
Now follows a brief description of material flow through the MHF 10. In order to heat or roast material within the MHF 10, this material is discharged from a conveying system (not shown) through a furnace charging openings 32 into the uppermost hearth chamber 121 of the MHF. In this chamber 121 material falls onto the hearth 141, which has a central material drop hole 18. As the shaft 20 is continuously rotated, the four of rabble arms 26 in the hearth chamber 121 push the material with their rabble teeth 30 over the hearth 141 towards and into its central material drop hole 18. Through the latter material falls onto the hearth 142 of the next hearth chamber 122. Here, the rabble arms 26 push the material with their rabble teeth 30 over the hearth 142 towards and into its peripheral material drop holes 16. Through the latter, material falls onto the next hearth (not shown in
As known in the art, both the shaft 20 and the rabble arms 26 have internal channels through which is circulated a gaseous cooling fluid, usually pressurized air, which will be called hereinafter for the sake of simplicity “cooling gas”. The object of this gas cooling is to protect the shaft 20 and the rabble arms 26 against damage due to the elevated temperatures in the hearth chambers 12. Indeed, in the hearth chambers 12 ambient temperature may be as high as 1000° C.
The flow diagram of
Reference number 42 in
The shaft 20 includes three concentric cooling gas channels within an outer shell 50. The outermost channel is an annular main cooling gas supply channel 52 in direct contact with the outer shell 50 of the shaft 20. This annular main supply channel 52 surrounds an annular main distribution channel 54, which finally surrounds a central exhaust channel 56.
It will be noted that between hearth chambers 124 and 125, i.e. approximately in the middle of the shaft 20, a partition means, as e.g. a partition flange 58, partitions the annular main supply channel 52 and the annular main distribution channel 54 in a lower half and an upper half. This partitioning does however not affect the central exhaust channel 56, which extends from the lowermost hearth chamber 128 through all hearth chambers 128 to 121 to the top of the shaft 20. If it is necessary hereinafter to make a distinction between the lower and upper half of the annular main supply channel 52, respectively between the lower and upper half of the annular main distribution channel 52, the lower half will be identified with the superscript (′) and the upper half with the superscript (″)
The lower cooling gas inlet 44′ is directly connected to the lower half 52′ of the annular main supply channel 52. The cooling gas supplied to the lower cooling gas inlet 44′ consequently enters beneath the lowermost hearth chamber 128 into the lower annular main supply channel 52′ and is then channeled through the latter up to the partition flange 58 between hearth chambers 125 and 124, wherein the flow rate of the cooling gas remains unchanged over the whole length of the lower annular main supply channel 52′. This constant flow rate of cooling gas over the whole length of the lower annular main supply channel 52′ warrants that the outer shell 50 of the shaft 20 is efficiently cooled in the four lower hearth chambers 128 . . . 125.
Just below the partition flange 58, there is a lower cooling gas passage 60′ between the lower annular main supply channel 52′ and the lower annular main distribution channel 54′. Through this lower cooling gas passage 60′, the cooling gas enters into the lower annular main distribution channel 54′. Via at least one cooling gas supply channel 625 . . . 628 in its rabble arm fixing node 285 . . . 288 each rabble arm cooling system 26′5 . . . 26′8 in the lower half of the MHF 10 is in direct communication with the lower annular main distribution channel 54′. Via at least one cooling gas exhaust channel 645 . . . 648 in its rabble arm fixing node 285 . . . 288, each rabble arm cooling system 26′5 . . . 26′8 in the lower half of the MHF 10 is also in direct communication with the central exhaust channel 56. Consequently, in the rabble arm fixing node 285, a secondary cooling gas flow is branched off from the main cooling gas flow in the lower main distribution channel 54′ and rerouted through the rabble arm cooling system 26′5 to be thereafter directly evacuated into the central exhaust channel 56. In the rabble arm fixing node 286, another part of the gas flow in the annular main distribution channel 54′ passes through the rabble arm cooling system 26′6 and is thereafter also evacuated into the central exhaust channel 56. Finally, in the last rabble arm fixing node 288, all the remaining gas flow in the lower main distribution channel 54′ passes through the rabble arm cooling system 26′8 and is thereafter evacuated into the central exhaust channel 56.
The flow system in the upper half of the shaft 20 is very similar to the flow system described above. The upper cooling gas inlet 44” is directly connected to the upper half 52″ of the annular main supply channel 52. The cooling gas supplied to the upper cooling gas inlet 44″ consequently enters into the upper annular main supply channel 52″ above the uppermost hearth chamber 121 and is then channeled through the latter down to the partition flange 58 between hearth chambers 124 and 125, wherein the flow rate of the cooling gas remains unchanged over the whole length of the upper annular main supply channel 52″. This constant flow rate of cooling gas over the whole length of the upper annular main supply channel 52′ warrants that the outer shell 50 of the shaft 20 is efficiently cooled in the four upper hearth chambers 121 . . . 124.
Just above the partition flange 58, there is an upper cooling gas passage 60″ between the upper main supply channel 52″ and the upper annular main distribution channel 54″. Through this upper cooling gas passage 60″, the cooling gas enters into the upper main distribution channel 54″. The connection of each rabble arm cooling system 26′4 . . . 26′1 in the upper half of the furnace 10 to the upper main distribution channel 54″ and the central exhaust channel 56 is as described above for rabble arm cooling systems 26′4 . . . 26′1 in the lower half. Consequently, in the rabble arm fixing node 284, a secondary cooling gas flow is branched off from the main cooling gas flow in the upper main distribution channel 54″ and rerouted through the rabble arm cooling system 26′4 to be thereafter directly evacuated into the central exhaust channel 56. In the rabble arm fixing node 283 another part of the gas flow in the upper main distribution channel 54″ passes through the rabble arm cooling system 26′3 and is thereafter also evacuated into the central exhaust channel 56. Finally, in the uppermost rabble arm fixing node 281 all the remaining gas flow in the upper main distribution channel 54″ passes through the rabble arm cooling system 26′1 and is thereafter evacuated into the central exhaust channel 56. From the central exhaust channel 56 the exhaust gas stream is then either directly evacuated into the atmosphere or evacuated by means of a rotary connection into a pipe for a controlled evacuation of the gas (not shown).
The outer shell 50 of the shaft consists mainly of intermediate support tubes 68 interconnected by the rabble arm fixing node 28. Such a rabble arm fixing node 28 comprises a ring-shaped cast body 70 made of refractory steel. The intermediate support tubes 68 are made of thick walled stainless steel tubes and are dimensioned as structural load carrying members between successive rabble arm fixing nodes 28. The intermediate support tubes 68 interconnected by massive rabble arm fixing nodes 28 constitute the load bearing structure of the shaft 20, which supports the rabble arms 26 and allows to absorb important torques when the rabble arms 26 are pushing the material over the hearths 14. It will further be noted that—in contrast to prior art shafts—the outer shell 50 described herein is advantageously a welded structure, the ends of the intermediate support tubes 68 are welded to the rabble arm fixing nodes 28, instead of being flanged thereon.
As explained above, the section of the shaft extending between adjacent hearth chambers 124 and 125 (i.e. the central shaft section) is rather particular because it comprises the partitioning flange 58, as well as the cooling passages 60′, 60″ between the annular main supply channel 52 and the annular main distribution channel 54. Before describing this particular central shaft section, a “normal” shaft section will now be described, also with reference to
As can be seen in
To complete thermal protection of the shaft 20, the latter is advantageously recovered with a thermal insulation (not shown). Such an insulation of the shaft 20 is advantageously a multilayer insulation including e.g. an inner refractory layer of micro-porous material, a thicker intermediate refractory layer of insulating castable material and an even thicker outer refractory layer of dense castable material.
A preferred embodiment of a rabble arm fixing node 28 is now describe with reference to
Considering now more particularly
When securing a new rabble arm 26 to the shaft 20, the plug body 110 of the rabble arm 26 has to be introduced into the socket 100 of the rabble arm fixing nod 110. During this introduction movement, the outer concave conical seat surface 114 first guides the plug body 110 into axial alignment with the cylindrical guiding surface 116. Thereafter both cylindrical guiding surfaces 116 and 116′ cooperate with one another for axially guiding the plug body 110 into its final seat position in the socket 100. It will be appreciated that axial guidance provided by the two cylindrical guiding surfaces 116 and 116′ considerably reduces the risk of damaging the plug body 110 or the socket 100 during the final coupling operation.
The rabble arm 26 further comprises an arm support tube 120 welded with one end to a shoulder surface 122 on the rear side of the plug body 110. This arm support tube 120 has to withstand the forces and torques acting on the rabble arm. It advantageously consists of a thick walled stainless steel tube extending over the whole length of the rabble arm 26. A gas guiding tube 124 is arranged inside the arm support tube 122 and cooperates with the latter to define between them a small annular cooling gap 126 for channeling the cooling gas to the free end of the rabble arm 26. The interior section of the gas guiding tube 124 forms a central return channel 128 through which the cooling gas flows back from the free end of the rabble arm 26 to the plug body 110.
It will be noted that one end of the gas guiding tube 124 is welded to a cylindrical extension 130 on the rear side of the plug body 110. The diameter of this cylindrical extension is smaller than the internal diameter of the arm support tube 120, so that an annular chamber 131 remains between the cylindrical extension 130 and the arm support tube 120 surrounding the cylindrical extension 130. This annular chamber 131 is in direct communication with the small annular cooling gap 126 between the gas guiding tube 124 and the arm support tube 122.
As already explained above, the plug body 110 is a solid cast body comprising several bores that will now be described. In
Referring now to
When one of the rabble arms 26 is dismounted, the clamping bolt 150 is extracted with rabble arm 26, i.e. it remains in the plug body 110 of the rabble arm 26. In order to be able to extract the hammer head 154 through the through hole 104 in the bottom of the socket 100, this through hole has the form of a key hole having a form corresponding roughly to the cross-section of the hammer head 154. It follows that by rotating the hammer head 154 by 90° about the central axis of the bolt shank 152, the hammer head 154 can be brought from the “hooked position” shown in FIG. 6″, into an “unhooked position”, in which it can be axially extracted through the keyhole 104 into the socket 100. Similarly, when a new rabble arm 26 is mounted, the hammer head 154 is first in a position in which it can axially pass through the key hole 104. Once the plug body 110 is seated in its socket 100, the hammer head 154, which is now located on the other side of key hole 104, can be brought into the “hooked position” shown in
The clamping device shown in
After removing the blind flange 188 and the thermally insulating plug 190, one has access to the coupling heads 174, 176 of the actuation tube 170 and the positioning tube 172. The actuation tube 170 is used to tighten the threaded sleeve 160. The positioning tube 172 mainly serves as an indicator of the position the hammer head 154 has with regard to the key-hole 104. Its coupling head 176 is therefore provided with an adequate positioning mark. It will be noted that the positioning tube 172 may also be used for fixing the clamping bolt 150 while loosening the threaded sleeve 160 by means of the actuation tube 170. Finally, the coupling head 174 of the actuation tube 170 may also have marks thereon, which in combination with the marks on the coupling head 176 of the positioning tube allow to check whether a sufficient tightening torque has been applied to the clamping device. It remains to be noted that the blind flange 188 may be removed during operation of the cooling system without a substantial gas leakages. Indeed, the threaded sleeve 160 seals the rear end of the actuation tube 170 and the front end of the actuation tube is sealed within the central through-hole 178 in the end-cup 180.
The aforementioned metallic protecting jacket 186, which is seen on
Number | Date | Country | Kind |
---|---|---|---|
91312 | Feb 2007 | LU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP08/51908 | 2/15/2008 | WO | 00 | 8/13/2009 |