LU88076A1 - Dispenser for spreading even layer of powdered material - comprises pivoted distribution trough on cage rotated by wheels with sealed bearings - Google Patents

Abstract

The dispenser consists of a distribution trough (10) pivoted to a cage (12) at an adjustable angle. The cage is suspended from a ring (22) which is supported vertically and guided laterally by three wheels (24) set at intervals of 120 deg. to one another. The cage also has a peripheral toothed crown wheel (30) which engages with an endless chain (32) used to rotate the cage. The three wheels (24) have recessed rims; they can be moved radially relative to the cage ring (22) to engage or disengage them, and have bearings in sealed housings with a lubricant. In a variant of the design, two of the wheels can be fixed and the third movable by means of a cam and spring mechanism.

Description

The present invention relates to a device for uniform distribution of powdery materials on a circular surface, by means of a distribution chute suspended in a pivoting manner from a rotating cage and whose angle of inclination relative to the vertical axis of said cage is adjustable.

A device of this kind is proposed by document EP-A-0343466. Although not limited thereto, the present invention relates more particularly to the application of this known device for the distribution of lignite powder in a lignite dryer with a fluidized bed. In this application, the chute drive device must meet two criteria that are difficult to reconcile with one another. On the one hand, you must at all costs avoid the penetration of oil or lubricant into the dryer enclosure. On the other hand, the design of a conventional drive, for example with gears, is hardly conceivable without lubrication if one wishes to avoid the risks of seizure under the harmful action of fine particles of lignite powder.

The object of the present invention is to reconcile these two opposite requirements by proposing a device of the type described in the preamble in which the risks of seizing of the moving parts and the risks of penetration of lubricant into the dryer are very reduced.

To achieve this objective, the device proposed by the present invention is essentially characterized in that said cage is suspended from a peripheral annular crown with a vertical axis, said crown having a peripheral edge which is supported vertically and guided laterally by wheels spaced circumferentially d 'an angle of 120 °, the latter being mounted by means of bearings on a support frame of said cage, and in that said cage is provided with a peripheral toothed crown in which engages an endless chain which transmits a rotary movement to said cage.

This drive chain is a chain of the bicycle chain type, that is to say a self-cleaning chain, which does not require lubrication.

Furthermore, each support or guide wheel is mounted by means of lubricated bearings housed in chambers filled with lubricant and isolated from the interior of the frame by a sealing system. This prevents, on the one hand, the ingress of dust into the bearing and, vice versa, the ingress of lubricant towards the interior of the dryer. In view of the reduced dimensions of the support and guide wheels, watertight seals will moreover be easily achievable and their maintenance will not cause problems.

In a first alternative embodiment, the cage is suspended by means of said crown in three grooved wheels spaced circumferentially by 120 ° and which engage with said peripheral edge of the crown. These three wheels therefore provide both a "vertical support" function and a lateral guide function.

The three grooved wheels have a vertical axis and are radially movable relative to the disc of the rotary cage to allow either the disassembly of the pulleys or the disassembly of the rotary cage. This possibility of radial displacement of the pulleys can be achieved by the fact that the bearing of each grooved wheel is housed eccentrically in the cylindrical base of a housing whose rotation causes a radial displacement of the grooved wheel.

The operative position of two grooved wheels is fixed, while the operative position of the third grooved wheel is preferably subjected to the action of at least one positioning spring to allow compensation for thermal expansions and eccentricities of the disk. This third grooved wheel is preferably housed eccentrically in an intermediate sleeve, which is housed, in turn, eccentrically in the cylindrical base of its housing, while the positioning spring acts between a support integral with the housing and support integral with the socket.

In a second variant, the cage rests, via the peripheral edge of the crown, on three identical smooth wheels, the horizontal axes of which are coplanar, form an angle of 120 ° between them and are directed towards the axis of rotation of the crown. In addition, it is guided in a horizontal plane by three other smooth wheels, which have vertical axes and which bear on the lateral edge of the crown, at three places spaced circumferentially by 120 °.

Two of the wheels with a vertical axis are fixed, while the third is mounted so as to have a certain radial elasticity in order to compensate for eccentricities and variations in diameter of the crown.

To guarantee a stable rotational movement of the crown on the support wheels, the chute is preferably balanced statically and dynamically by a counterweight. Other features, advantages and characteristics will emerge from the detailed description of a preferred embodiment, presented below, by way of illustration, with reference to the appended drawings, in which: Figure 1 shows a schematic sectional view vertical of a distribution device according to the present invention, the suspension of the rotary cage comprising three grooved wheels; Figure 2 shows a plan view of the device of Figure 1; Figure 3 shows in a longitudinal section the eccentric suspension of a grooved wheel in its housing; Figure 4 shows in a broken section the elastic suspension in the radial direction of a third grooved wheel; Figure 5 shows an enlarged view of a grooved wheel and its housing; Figure 6 shows a plan view of Figure 5; Figure 7 shows a view corresponding to that of Figure 6 after rotation of 180 °, to place the grooved wheel in the disassembly position; Figure 8 is a view corresponding to that of Figure 6, after a slight rotation caused by thermal expansion or eccentricity of the disc; Figure 9 is a view identical to Figure 1, the suspension of the rotary cage comprising three pairs of smooth wheels and the chute being balanced by a counterweight; Figure 10 is a longitudinal section of the assembly of a pair of wheels supporting and guiding the chute; Figure 11 is a section similar to that of

Figure 10, the guide wheel being mounted resiliently, in order to compensate for eccentricities and variations in diameter.

Figure 1 shows a distribution chute of the kind described in the aforementioned document for distributing powdery materials, in this case lignite powder, uniformly on a circular surface in a lignite dryer. The chute 10 is pivotally suspended from a rotary cage 12 through which the powder is poured onto the chute 10. The cage 12 is surmounted by a fixed supply channel 14 receiving the material from a storage silo. Both the rotary cage 12 and the channel 14 can be provided with deflectors 16 to guide the falling material. The inclination of the trough 10 relative to the vertical axis O is determined by a rod 18 articulated on the rear end of the trough 10 and fixed to the outer wall of the cage 12.

This inclination is preferably manually adjustable by means of positioning nuts 20 on the rod 18.

To allow the rotation of the chute 10, the cage 12 must be rotatably mounted inside its fixed support frame 8 which is placed above the dryer not shown.

As is apparent from FIG. 1, which shows a first mode of suspension of the rotary cage 12 in its frame 8, the upper part of the cage 12 is integral with a peripheral annular crown 22. This crown 22 is supported and guided to its peripheral edge by three grooved wheels 24, 26, 28, arranged in a triangular arrangement in a horizontal plate 36 of the frame 8, surrounding the channel 14. The grooves of the wheels and the peripheral edge of the disc have complementary sections, which can be trapezoidal as shown in Figure 1. It is also possible that these complementary shapes are rounded. These grooved wheels 24, 26 and 28 consequently ensure the vertical support of the crown 22 and its guiding in a horizontal plane and thus allow rotation of the cage 12 around the axis O. To this end, a toothed crown 30 is provided around the cage 12 or a skirt of the crown 22 to cooperate with a drive chain 32 which, according to the present invention, is a chain of the "Gall" type or bicycle chain. The latter is driven by a toothed pinion 34, which is actuated through the plate 36 by means of a motor 38 mounted outside the frame 8. The chain 32 has the advantage of being self-cleaning, in the extent that teeth entering the chain cause self-cleaning. Furthermore, it does not require lubrication, owing to the combination of self-lubricating materials constituting the chain 32 and the ring gear 30.

The reference 40 (see Figure 2) designates a chain tensioner roller 32. It is a tensioner known per se, mounted on a pivoting lever subjected to the action of a spring which applies the tensioner against the chain 32. Instead of the tensioner roller 40, it is possible to mount the engine block 38 in a similar manner on the frame 8, so that it undergoes the action of a spring in the direction diametrically opposite to the rotary cage 12, to exert constant traction on the chain 32. Because of the interpenetration between the grooved wheels 24, 26 and 28 on the one hand, and the peripheral edge of the crown 22 on the other hand, it would be very difficult , or even impossible to disassemble the wheels or the rotating cage. To remedy this, and according to one of the features of the present invention, each of the three grooved wheels 24, 26, 28 is radially displaceable to release them from the crown 22 for assembly or disassembly, either grooved wheels, either of the rotary cage 12 and the chute 10. This assembly will be explained in more detail with reference to Figure 3, which shows a cross section through the grooved wheel 26 and its housing. It remains to be noted that the grooved wheel 28 is mounted in the same way as the grooved wheel 26.

The grooved wheel 26 is integral with a coaxial shaft 42 which is housed by means of a roller bearing 44, known per se, in a cylindrical housing 46 sealed with a lid 48. This housing 46 is fixed by means of bolts 50 in a circular opening 52 of the plate 36. The positioning of the grooved wheel 26 and its bearing is eccentric relative to the opening 52 and to the base 46a of the housing 46 intended to penetrate this opening 52. As a result, the axis 54 of the wheel 26 and its bearing is off-center with respect to the axis 56 of the opening 52 and is located closer to the crown 22. This eccentricity is also visible on the Figure 2.

To disassemble, remove the bolts 50 securing the housing 46 to release it relative to the plate 36. By turning the housing 46 180 ° around the axis 56 of the opening 52, the eccentricity of the wheel 26 causes its axis 54 to rotate about the fixed axis 56 to place the axis 54 in a symmetrical position on the other side of the axis 56. This rotation moves the wheel 26 to the position shown in broken lines and releases it completely from its engagement with the crown 22. In this position it can be withdrawn freely through the opening 52. The mounting of the grooved wheel 26 naturally includes the reverse operations.

The reference 58 designates tight seals intended to ensure a perfect seal between the shaft 42 and the housing 46. This makes it possible to fill the housing of the shaft 42 inside the housing 46 with lubricant to ensure the lubrication of the bearing. . It is even possible to provide means, such as a dipstick or visual indicators to permanently check the level of lubricant in the housing 46.

The description given above applies identically to the grooved wheels 24 and 28, except that the mounting of the wheel 24 is a little more complex to allow compensation for thermal expansions or eccentricities of the crown 22. Indeed, as a result of temperature variations it is possible that the crown 22 expands or retracts or, ultimately, that it is no longer perfectly round. Now, the position of the wheels 26 and 28 being fixed, provision has been made for a certain elasticity in the mounting of the grooved wheel 24 so that the latter can compensate for any irregularity in the crown 22.

Figure 4 shows the details of the elastic mounting in the radial direction of the grooved wheel 24. In this figure we have used the same references to designate the elements corresponding to those of Figure 3. It will be noted that the wheel 24 is also mounted eccentrically in the housing 46 so that its axis 54 is offset from the axis 56 to allow, by a rotation of 180 ° the housing 46, to move the grooved wheel 24 from the position in solid lines to the position in broken lines.

Unlike FIG. 3, an intermediate sleeve 60 is stored between the bearing 44 of the shaft 42 of the grooved wheel 24 and the inner cylindrical wall of the housing 46. This sleeve 60 can rotate, inside the housing 46 around its axis 64. The cutting plane of Figure 4 is such that the axis 64 of the sleeve 60 is coincident with the axis 54 of the wheel 24. However, the shaft 42 is housed eccentrically in the socket 60, so that its axis 64 is offset with respect to the axis 54 of the grooved wheel 24. In a section plane perpendicular to that of FIG. 4, this offset between the axes 54 and 64 would be noted. On the other hand, in this perpendicular cutting plane, the axis 64 would coincide with the axis 56 when the grooved wheel 24 is in the operative position.

This eccentricity between the axis 54 of the grooved wheel 24 and the axis 64 of the sleeve 60 allows, by a rotation of the latter, a radial displacement of the grooved wheel 24 relative to the crown 22, which will be explained in more detail with reference to the following figures.

The housing of FIG. 4 is closed, in a leaktight manner, by a cover 62 which is applied this time to the socket 60 and not to the housing 46 as for the wheels 26 and 28. The cover 62 and the socket 60 undergo the action of a spring, which is supported on the housing 46 and which always keeps the grooved wheel 24 in engagement with the peripheral edge of the crown 22. Any movement of the grooved wheel 24 under the effect of an eccentricity or of a variation in diameter of the crown 22 having to be made against the action of this spring.

Figure 5 shows a side view of the wheel 24 and its housing 46 in the circular opening 52 of the plate 36. The reference 70 designates a powerful spring, for example a coil spring or an air spring stretched between a support 66 secured to the housing 46 and a support 68 secured to the movable sleeve 60. An adjustment screw 72 acting on the support 68 of the sleeve 60 allows the spring preload 70 to be adjusted and the grooved wheel 24 to be correctly positioned during assembly. After mounting the screw 72 can be completely unscrewed since the grooved wheel 24 will be held in place by the spring 70 which presses the grooved wheel 24 against the peripheral edge of the crown 22. As shown in Figure 6, it it is preferable, for reasons of symmetry of the forces, to provide the spring 70 as well as the supports 66 and 68 in duplicate, at diametrically opposite positions. However, all you need is an adjustment screw 72.

Figure 6 shows the eccentric positions of the three axes 54, 56 and 64, which allow the axis 54 to gravitate either around the axis 56 or around the axis 64, depending on whether the eccentricity with respect to the housing 46, or eccentricity with respect to the socket 60.

Figure 7 is a view similar to that of Figure 6 and illustrates the positioning during disassembly. This position is obtained by turning the base 46a of the housing 180 ° in its opening 52, after having unbolted the housing of the plate 36. This rotation is carried out around the axis 56 of the opening 52 and places the two axes 54 and 64 in diametrically opposite positions relative to their respective position in Figure 6. This movement causes a radial displacement of the grooved wheel 24 to release it from the crown 22, which is illustrated by the clearance (a) between the edge of the grooved wheel 24 and the peripheral edge of the crown 22. It should be noted that the mutual angular positions of the axes of the wheel 24 and of the sleeve 60 do not change during this rotation of the housing 46.

Figure 8 is a view similar to that of Figure 6 and serves to illustrate the operation of the second eccentricity between the grooved wheel 24 and the sleeve 60. This can in particular occur during an increase in the external diameter of the crown 22 under the effect of an increase in temperature. Such thrust of the crown 22 on the grooved wheel 24 causes rotation of the sleeve 60 about its axis 64 inside the housing 46. This rotation must take place against the action of the springs 70 which are compressed by the approximation of the supports 66 with respect to the fixed supports 68.

By virtue of the eccentric mounting of the grooved wheel 24 relative to the sleeve 60, the axis 54 of the grooved wheel 24 gravitates clockwise around the axis of rotation 64. This mounting makes it possible by Consequently, the grooved wheel 24 is positioned automatically as a function of the eccentricities or expansions of the crown 22. On the other hand, when the crown 22 retracts, the sleeve 60 rotates anticlockwise under the effect spring thrust 70.

Figure 9 shows a device similar to that of Figure 1. But instead of using three grooved wheels to support and guide said annular ring 22, three pairs of smooth wheels 124, 124 ', 126, 126' and 128, 128 'to obtain the same result.

It will be appreciated that this variant with three pairs of wheels has, with respect to the grooved wheels 24, 26, 28 the advantage of a lower wear of the wheels and of the crown 22. Furthermore, the disassembly of the wheels can in this second variant be made easier than in the first variant.

It will be noted that the first wheels 124, 126, 128 of each pair have a vertical axis of rotation and guide the crown 22 in a horizontal plane by resting on the lateral edge of the crown 2 at three places circumferentially spaced about 120 ° . The second wheels 124 ′, 126 ′, 128 ′ of each pair on the other hand provide the vertical support for the crown 22. They have for this purpose horizontal axes and are arranged below the peripheral edge of the underside of the crown 22 so that their coplanar axes form an angle of 120 ° between them and are directed towards the axis of rotation of the crown 22.

Unlike the grooved wheels 24, 26, 28 which served both as supports and guides, in the present embodiment, the "vertical support" function has been separated from the "lateral guide" function. The first function is performed by the wheels 124 ', 126', 128 'with a horizontal axis, while the second function is performed by the wheels 124, 126, 128 with a vertical axis.

Figure 10 shows the details of mounting a pair of smooth wheels 126, 126 '. The wheel 126 consists of a thick disc 140 which is provided in one of its bases with a blind axial bore 142. This wheel 126 is mounted on the lower end of a fixed vertical shaft 144, using 'a ball bearing 146. The inner ring of this bearing 146 is adjusted on the shaft 144 and is secured against axial displacement by an elastic ring 148. The outer ring is adjusted in said blind bore 142 of the wheel 126, in which it is held in place by a sleeve 150 screwed onto the wheel 126. The sleeve 150 is provided with a circular leaktight seal 152 which is closed radially around the shaft 144, so as to define a sealed chamber for housing the bearing 146, which can be filled with a lubricant. At its upper end, the shaft is screwed onto a support sleeve 154, which is itself mounted in an opening of the plate 36. This support sleeve 154 is extended downwards by a vertical arm 156. In an opening of this arm is fixed with one end a second shaft 158, the horizontal axis of which is oriented in the diametrical direction of the crown 22. This shaft 158 supports at its other end the wheel 126 ', which is mounted by means of a bearing ball, in the same way as the wheel 126. In line with this wheel 126 ', facing the upper face of the ring 22, is integrated an abutment surface 160 in the support sleeve 154. This abutment surface 160 avoids an axial displacement upwards of the crown 22 resting freely on the wheels 124 ', 126 / and 128'. In normal operation, a clearance is provided between the abutment surface 160 and the upper face of the crown 22. Similar stops are also provided directly above the wheels 124 'and 128'.

The second pair of wheels 128, 128 ′ is mounted exactly identically, at an angular distance of 120 ° from the pair of wheels 126, 126 ′ against the peripheral edge of the crown 22.

The third pair of wheels 124, 124 ′ differs only from the other two pairs of wheels by a particular mounting of the wheel 124 with a vertical axis which gives the latter elasticity in the radial direction of the crown 22. The wheel 124 can thus compensate eccentricities and variations in diameter of the crown 22. The mounting of the wheel 124 also works according to the principle that we have studied for the grooved wheel 24. As an alternative embodiment, we have replaced the bushing eccentric bore in the present embodiment by an eccentric shaft.

Figure 11 shows this arrangement in detail. It should be noted (3rd note first of all that the section through the mounting of the upper wheel is a section through a perpendicular plane which has been folded down in the plane of the figure.

It can be seen that the lower end of a shaft 164 supports the wheel 124 in exactly the same way as described for the wheel 126. The upper end of the shaft 164 is however no longer screwed to said support sleeve 154, but is mounted so as to be able to rotate about its axis 166, thanks to an assembly on ball bearings 168 and roller bearings 170, incorporated in a sealed housing 172 which is screwed onto said support sleeve 154. It will be noted that the axis 166 is offset from the axis of the lower end of the shaft 164 supporting the wheel 124.

An arm 174 is integral with the shaft 164, and on this arm 174 is supported with one of its ends a powerful spring 176, which is supported with its other end on the housing 172. The shaft 164 is therefore subjected to a couple who tries to rotate it around its axis 166. However, as the wheel 124 is eccentric with respect to this axis 166, it is subjected to a moment which comes to apply it against the lateral edge of the crown 22. The wheel 124 can therefore follow elastically a variation in diameter or a local eccentricity of the crown 22.

In a horizontal plane, the crown 22 is consequently guided by two wheels 126 and 128 with a fixed vertical axis and by a wheel 124, the vertical axis of which is subjected to an elastic moment which ensures contact between the wheel 124 and the crown 22.

In the preferred embodiment described above, a wheel with a horizontal axis has each time been associated with a wheel with a vertical axis in a mounting on a common support sleeve 154. It is however obvious that the wheels with a horizontal axis and the wheels with a vertical axis could also be mounted independently of each other.

It remains to be noted that the bearing surfaces of the six wheels are preferably slightly curved in order to achieve optimal contact with the corresponding bearing surfaces of the crown 22 for example in the event of manufacturing inaccuracies or deformations.

In Figure 9 we see that the chute 10 is provided with a counterweight. This counterweight is preferably dimensioned so that the center of gravity of the trunking-counterweight assembly is located on the axis of rotation of the crown 22. In this way the vertical bearing forces on the wheels 124 ′, 126 'and 128' are not a function of the position of the chute, which makes it possible to avoid tilting of the crown 22 on its three supports 124 ', 126' and 128 ', when the chute 10 is rotated. In addition, the location of the counterweight is chosen so that the centrifugal forces due to the counterweight on one side and the chute on the other side cancel each other out. In this way the crown 22 is free from all moments and from all forces which could cause an unstable movement of the crown 22 on its support wheels 124, 124 ', 126, 126', 128, 128 '.

It is possible to provide suitable means for supporting the rotary cage 12 by means of the crown 22 in the event of disassembly of one or more wheels, both in the first and in the second variant. To this end, it is possible to provide a peripheral groove 22a in the outer edge of the crown 22 as shown in FIG. 5. Before disassembling one or more wheels, it suffices to engage, at places appropriate through the frame 8 of the pointed head screws, intended to penetrate into the groove 22a to ensure the support of the crown 22 in the absence of wheels.

It is likewise possible to provide means for maintaining a slight overpressure in the region of the crown 22 and of the wheels to keep the dust and powders away.

Claims (15)

1. Device for uniform distribution of powdery materials on a circular surface using a distribution chute (10) pivotally suspended from a cage (12) so that the angle of inclination of the chute (10 ) relative to the vertical axis (O) of said cage (12) is adjustable, characterized in that said cage (12) is suspended from a peripheral annular crown (22) with vertical axis, said crown 22 having a peripheral edge which is supported vertically and guided laterally by wheels spaced circumferentially by an angle of 120, the latter being mounted by means of bearings on a support frame of said cage (12), and in that said cage is provided with 'a peripheral toothed crown (30) in which engages a chain in end (32), which transmits a rotary movement to said cage (12). 2. Device according to claim 1, characterized in that the wheel mounting bearings are all housed in sealed housing chambers which are filled with a lubricant. 3. Device according to claim 1 or 2, characterized in that the peripheral edge of the crown (22) engages with three grooved wheels (24, 26, 28) with a vertical axis, which are circumferentially spaced 120 ° around of said crown (22). 4. Device according to claim 3, characterized in that the three grooved wheels (24, 26, 28) are radially movable relative to the crown (22) of the rotary cage (12) between an operative position and a position d 'extraction. 5. Device according to claim 4, characterized in that the bearings of each grooved wheel (24, 26, 28) are housed eccentrically in a cylindrical base (46a) of a sealed housing (46), the rotation of which causes a radial displacement of the pulley. 6. Device according to claim 3, characterized in that the operative position of two grooved wheels (26, 28) is fixed and in that the operative position of the third grooved wheel (24) is subjected to the action of 'at least one positioning spring (70). 7. Device according to claim 6, characterized in that said third grooved wheel (24) is housed eccentrically in an intermediate sleeve (60) which is housed, in turn, eccentrically in the cylindrical base (46a) of the housing (46) and in that the positioning spring (70) is tensioned between a support (66) secured to the sleeve (60) and a support (68) secured to the housing (46). 8. Device according to claim 7, characterized in that the pretension of the spring (70) is adjustable by an adjustment screw (72), acting on the support (66) of the sleeve (60). 9. Device according to claim 1 or 2, characterized in that the peripheral edge of the crown 22 is supported vertically on three identical smooth wheels (124, 126 ', 128'), whose horizontal axes of rotation are coplanar, between them an angle of 120 ° and are directed towards the axis of rotation of the crown 22, and in that the peripheral edge of the crown 22 is guided laterally by three smooth wheels (124, 126, 128) with vertical axes, arranged has three spaces circumferentially 120 °. 10. Device according to claim 9, characterized in that plumb with the wheels (124 ′, 126 ′, 128 ′) opposite the upper face of the crown 22, an abutment surface 160 is arranged integral with the frame 8 which limits the axial play of the crown 22 upwards. 11. Device according to any one of claims 9 or 10, characterized in that two of the wheels with vertical axis (126, 128) are fixed and in that the third wheel with vertical axis (124) is mounted eccentrically and is subjected to the action of at least one spring (176). 12. Device according to claim 11, characterized in that the wheel (124) is mounted on the eccentric end of a shaft (164) which is mounted by means of bearings in a sealed housing (172) and which is subjected via an arm (174) to the action of a spring (176) bearing on said housing (172). 13. Device according to any one of claims 1 to 12, characterized in that the chute (10) is balanced statically and dynamically by a counterweight (200). 14. Device according to any one of claims 1 to 13, characterized in that the crown (22) has a peripheral groove (22a) intended to receive at least three suspension screws which can be engaged through the frame. 15. Device according to any one of claims 1 to 14, characterized by means for maintaining a slight overpressure in the enclosure of the drive and the wheels.