DE1946380A1 - Heat exchange device between solids of different grain - sizes - Google Patents

Abstract

Counter-current plant, for heat exchange between coarse solids and pulverulent solids, is of the rotary type of tubular exchanger with its axis of rotation inclined to the horizontal it is fitted with co-axial Archimedean screw the blades of which are perforated with holes. The dimensions of the latter are larger than the largest dimension of the pulverulent solids and smaller than the smallest dimension of the coarse solids; the pulverulent solids are introduced at the upstream end of the exchanger, at its highest end and are extracted at its downstream end, at the lower level, the coarser solids are introduced at the downstream end and extracted at the upstream end. A number of longitudinal lifting vanes are regularly arranged between the internal wall of the vessel and the screw; each vane has the shape of an angle iron the radial portion of which is fastened by its edge to the internal wall; the circumferential portion has a width such that a gap exists between its edge and the radial portion of the angle iron preceding it circumferentially in the direction of rotation of the cylindrical vessel.

Description

Device for heat exchange between solids of different types Grain sizes The invention relates to a device for countercurrent heat exchange between coarse and powdery solids of the rotating, tubular type Exchanger with an axis of rotation inclined to the horizontal, which has a coaxial screw conveyor has, the flanks of which are pierced by holes, the diameter of which is larger as the largest dimension of the powdery solids, but smaller than the smallest Expansion of the imported, coarse solids is, and in which the powdery Solids introduced into the heat exchanger at its end of the highest part and removed at its end of the deepest part, the coarse solids introduced at the downstream end and at the upstream end Be removed at the end.

As shown schematically in Figures 1, 2 and 3, takes place in one known tube furnace T, which has no screw conveyor and which is a counter the horizontal inclined axis XX 'rotates in the direction of arrow f, the progression movement of a powdery solid, such as sand, only along the surface of the bed the line of greatest inclination ba 'in Figures 1 and 2. Inside the bed the movement takes place along the corresponding straight section a b of the pipe.

A coarse solid released on the surface of the bed which For example, it consists of balls, follow the same path.

On the other hand, if a screw conveyor rotates together with the tube T. Forcing the coarse solid to climb up the pipe, describes the coarse solid during its progression on the bed surface of the powdered pestilence a certain curve cd (Figure 3) by being drawn on by the flank of the screw conveyor formed, helical slope from supports. Only during this phase of the As the coarse solid progresses, there is a relative movement between the two Solid in various sizes of lorn.

As shown schematically in Figure 3, the coarse solid, if he arrives at d, covered by the powdery solid that runs off, and he turns dug into the interior of the latter, to at c on the surface of the Bed of powdery solids to reappear; without any relative movement between the powdery solid or sand, - the coarse solid or balls and the screw conveyor has taken place.

It follows from this that @ a @ on the one hand the balls have the more inclination, along the flank of the screw by draining @@ s pulv @ r @@@ igen solids to be overdone, inhibited there in iln @ r progression to wer @ on and a remarkable one Marks on the surface of the bed allowed, which is not beneficial when it is warm is, un @ da @ on the other hand, the progression, down the pipe, @es powdery Solids due to the presence of the balls on the surface of the descend Bed, which the powdery solid forms, is hindered, what a sennellen From @ all @ your maximum throughput, if the throughput of the rough festival @@@ e @something is increased.

The E @@ indung you @@ Geshal @ @ a device for a heat exchange Awischen Feststo @@ e @ different grain sizes, in which the os @ n a @ s guided, disadvantageous phenomena are eliminated.

Di @ Er @ i @ you @@ @@@@ from a @ r V @@@@@ @@@, @@ r above mentioned- @ en @@ , @. @. the @ in @ @ ylin @ rise @ Einfas @ un @ with @@ gen the H @ ri @@@@ l @@@@@@ he axis of rotation une a conveyor chute unf @@@ whose flange @@ is broken through by L @@ hern, and the coaxial to the @ ylin @@ rischen Ein @assung angsor @ n @@ sici ge @@ insam with this @ rotates, un @ @ denotes si @@ @ by the fact that the through @ ess @ r @er För @ ersc @@@ cke is smaller as the inner diameter @er sylindris @@ en edging that @ ehr @@ e longitudinal Look regularly between the inner wall of the enclosure and the conveyor are arranged, where @ each shovel has the Forn @ine angle iron whose one wing, radial wing, with its edge on the inside wall of the enclosure is attached and its other wing, circumferential wing designated, has such a width that a gap between its Eante and the radial wing of the preceding it circumferentially in the direction of rotation of the cylindrical bezel There is angle iron, and that an intermediate cylinder optionally between the screw and the peripheral vanes is arranged when the width of the gap is greater than that smallest dimension of the coarse solids is, with the screw and the intermediate cylinder pierced by holes whose diameter is greater than the largest dimension of the powdery solids, but smaller than the smallest dimension of the coarse Solids is.

In the preferred embodiment of the invention by the Peripheral wing of each vane with that going through the edges of the vane plane formed angles greater than the angle of the dynamic gradient of the to be treated powdered products.

The invention also includes all devices for the treatment fine or coarse solids in an implementation of a device according to the invention.

The invention is illustrated below with reference to the drawing, for example described; in this show: Figures 1, 2 and 3 in a schematic representation the processes carried out above in a known device FIG. 4 is a perspective Overview view, partially cut away, of a first embodiment of the invention, the downstream end wall of the pipe for greater clarity the drawing is shown transparently, Fig. 5 is a cross section, on a smaller scale, along an orthogonal to the axis of rotation of the device Level, Fig. 8 is a longitudinal section in the same wet rod as Fig. 5 along a through the plane going through the axis of rotation of the device, FIGS. 7, 8 and 9, respectively, views analogous to Figures 4, 5 and, which show a second embodiment of the invention.

The embodiment of the invention shown in the drawing essentially comprises a rotatable cylindrical bezel or rotatable one Cylinder tube 1 with an inclined to the horizontal by a Win @ el α Axis XX ', which has two end walls 2 and 7; the wall 2 of the most elevated Part of the following is referred to as the upstream or upper wall and the wall 3 of the deepest part is called the downstream or lower wall.

The two walls 2 and 3 are each in the middle of an opening 4, 3 perforated, which has a suitable shape and is essential in cross section is greater than the largest expansion of the coarse solids introduced. The powdery one Solid is in the device through the upstream or upper opening 4 according to the arrow F1 and inserted through ciie downstream or lower Opening 5 taken according to the arrow F1 ', while the coarse solids through the the same lower opening 5 can be introduced according to arrow F2, zero through the upper one Opening 4 can be removed according to arrow F2 '.

In the interior of the tube 1 are a suitable number in the longitudinal direction extending, identical blades 8 from the upper wall 2 to the lower wall 3 arranged. Each shovel is shaped like an angle iron, cessen one Wing 7, hereinafter called radial wing with its edge on the inner wall of the Pohres 1 is attached and its other wing @, called peripheral wing, in the Direction of rotation f of the tube 1 is directed.

A screw conveyor 9 with the axis XX 'is in the interior of the volume, which is determined by the cylinder tangent to the circumferential wing 8 of the blades 6 is arranged.

The snail is firmly connected to the wings 8 and its flank is pierced by holes 9A, the cross-section of which is smaller than the smallest dimension the coarse solids, but much larger than the dimensions of the imported, powdery solids isti. In addition, the direction of the helix is in chosen in such a way that the longitudinal F2 introduced into the lower opening 5, coarse Solids climb up the pipe 1 and along the upper opening 4 of the pipe F2 can be found.

On the other hand, the dimensions of the wings 7 and 8 are the angle irons 6 is preferably chosen such that the angle which by the accident wing and the plane containing the two wing edges is greater than the angle the dynamic gradient of the powdery solid.

It exists between the edge of the peripheral wing 8 of each angle iron and the radial wing 7 of the circumference in direction of rotation f the angle iron preceding the cylindrical enclosure 1 is a longitudinal gap 10.

There is a possibility of considering a number of angle irons the inner diameter of the cylinder 1, the diameter of the screw conveyor 9 and the dimensions of the wings of the angle iron 6 to be arranged so that each gap 10 has a width: a) either smaller than the smallest dimension of the imported coarse solids; in this case determine the angle iron 6 with the pipe 1 and the end walls 2 uiid 3 an annular chamber 12 outside the screw), in its interior not the coarse solids, but only the powdery solids can enter. This case is the same as that shown in FIGS. 4, 5 and @ Embodiment before; b) or greater than the smallest dimension of the imported, coarse solids; in this case at least some of the coarse solids would be can enter the outer annular chamber 12.

According to the embodiment shown in FIGS. 7, 8 and 9 is such an occurrence through an arrangement of an inner cylinder 11 between the wings @ the angle iron 8 and the screw conveyor 9 avoided the holes 11A is perforated, the cross-section of which is smaller than the smallest dimension of the imported, coarse solids, however, much larger than the largest dimension of the imported, powdery solids. In this way you can see not the coarse solids but only the powdery solids enter the annular chamber 12.

Finally, the pipe 1, the angle irons 8, the screw conveyor turn 9 and the possibly provided perforated inner cylinder 11 together the inclined axis XX '.

The function of the device according to the invention will now be described; it should be noted that this mode of operation for the two embodiments, which have been described in succession above, remains the same.

The powdery solid or sand fills the lower one at the very beginning Part of the tube 1 by entering the annular volume 12 until it passes through the lower opening 5 runs out, as shown in Figures 6 and 9 doutlich.

While threatening the device in the direction of arrow f will the sand @ is carried along by the angle iron 6, and its surface then increases, in Transverse direction, the course of the line drawn with durc @@@ shown in Figures 5 and @ Kurte bà.

If the angle irons 6 were not present, the surface would @ @@ s Semdbettes the course of the broken line in the same figures 5 and @ shown, i @ take essential straight-line curve b'a '.

It is immediately evident that the presence of the angle iron 6 caused deformation of the surface of the sand bed in relation to the surface without the angle iron, the angle of the transversal fall gradient of the sand bed is enlarged and consequently @ the length of time the balls stay on the surface of the sand bed reduced.

The rain of sand poured out by the angle iron, the higher one Reached level than that of the sand bed, as in Figures 5, 6, 8 and 9 shows the overlap of the balls and thereby increases the heat exchange the two solids.

This sandy rain occurs naturally along the vertical, which makes the sand better to cross the barrier, which is caused by the along the Flanks of the screw conveyor accumulated balls is formed, and thereby also the Progression of the sand from top to bottom is improved.

barm: it follows that for a given ball throughput the maximum permissible sand throughput is much greater than with a known heat exchanger, which is only equipped with a screw conveyor.

During the rotation of the tube 1, the balls are driven by the screw 9 according to one running from downstream of pipe 1 to upstream of pipe 1 Longitudinal movement @ itg @ leads.

It goes without saying that one should avoid giving too much Part of the sand carried by every angle iron in which Win: eleisen remains and so be guided around again in a circular motion without longitudinal progression can. For this reason, the width of the peripheral wing 8 of the angle irons 8 is such chosen that the through this wing and the edges of the wings 3 and 8 containing The angle γ formed is greater than the angle of the dynamic sand slope

Claims (2)

P a t e n t a n s p r ü c h e 1. Device for a heat exchange between solids of different grain sizes in the manner of a rotating, tubular Exchanger with an axis of rotation inclined to the horizontal, which has a coaxial screw conveyor has, the flanks of which are pierced by plates, the diameter of which is greater as the largest dimension of the powdery solids, however, smaller than the smallest Expansion of the imported, coarse solids is, and in which the powdery Solid @ in the heat exchanger at its nnee upstream ees highest raised Part inserted and withdrawn at its end downstream of the deepest part, the coarse solids being introduced at the downstream end -md at taken from the upstream end, thereby g e k e n n n z e i c h n e t that the diameter of the screw conveyor is smaller than the inner diameter the cylindrical, tubular skirt that several longitudinal blades in a regular manner between the inner wall of the tubular enclosure and the Auger are arranged, with each blade having the edge of an angle iron, one wing of which is radial with respect to the axis of rotation of the tubular skirt arranged and attached with its edge to the inner wall of the enclosure, and its other wing in terms of circumference. is arranged on the axis of rotation and has such a width that there is a gap between its edge and the radial wing of him circumferentially in the direction of rotation the cylindrical edging previous angle iron, and that an intermediate cylinder if necessary between the worm and the peripheral wings of the blade is angeor @ ne @, if the width of the gap is greater than the smallest dimension of the coarse solids is, the screw and the intermediate cylinder pierced by holes sin @, whose diameter is greater than the largest dimension of powdery solids @but @ lesser than the @ smallest extension of the @@ above solids. 2. Device nac @ Anspruc @ 1, thereby g e k e n n z e i c h -n e t, that the angle of the surface, that of the circumferential wing of a blade with the E @@ ne is formed by the edges of the two wings of the exhibition, greater than the win @@ l of @ ya @@ ischen G @ fäll @ s of the powdery to be treated Pro @ u @@@ is @. L e r s e i t e