LU83884A1 - CELL WHEEL LOCK - Google Patents

Description

<· - il - "rotary valve"

The invention relates to a rotary valve according to the preamble of claim 1.

Cell locks for the optionally metered feeding of bulk material into pneumatic conveying systems have been well known since lart--, both in the form of the discharge lock, with the bulk material fed vertically from above after being carried out by just under half a turn of the cell wheel from the lock housing below fails again vertically (see e.g. DE-PS 608765) as well as in the form of the blow-through lock, in which the bulk material fed in the same way after just under half a turn of the cell wheel by means of the conveying air blown horizontally into one of the flange covers directly into the air from the opposite flange cover outgoing delivery line is blown (see. DE-OS 19 26 915).

Both types of locks have specific advantages and disadvantages. The discharge lock enables a high load, I can be adapted to almost any delivery line diameter by means of suitable transition pieces between the lock outlet and the delivery line and is relatively low-wear.

In the case of bulk goods which tend to cake, however, the cells are incompletely emptied, as is the case with a large pressure difference between the inlet and outlet sides. Conversely, due to the compressed air discharge, the blow-through gate is less sensitive to easily adhering bulk goods and to higher pressure differences between the inlet and outlet, but only allows a relatively low loading, a free choice of the delivery line diameter only within narrow limits and is particularly susceptible to wear on the outlet side. If there are no difficult conditions, the discharge lock is usually preferred.

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Mixed forms of both types of locks are already known. For example, DE-PS 597 ** 92 shows a discharge lock in which, in order to improve the emptying of the cells and to keep the gaps between the lock housing and the cellular wheel clean, the latter is designed to be closed on the end face and a channel opening on the cell bottom is provided in the two end walls of each cell , which, when the cell rotates in the discharge position, coincides with a compressed air feed duct arranged in the lower part of the two housing flange covers, so that the product located in the cell is discharged by gravity with the assistance of the blown-in compressed air.

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From CH-PS 339 963 a discharge lock of the type specified in the introduction is known, in which the cell wheel is open at the front to improve the discharge of bulk material which tends to stick and the individual cells are each in their discharge position for covering with one in the flange cover of the lock housing come horizontally opening pipe, through which all the compressed air required for the subsequent VJeitertransport is blown into the cell.

It is common to all known cellular wheel sluices that the discharge of the bulk material is not uniform because of the portioned feed into the discharge area caused by the cells, but with a frequency dependent on the speed of the cellular wheel and the number of its cells he follows. Although this pulsating discharge is meaningless for most applications, it can be used in certain areas, e.g. in the metered supply of burners with powdered fuels such as coal dust, because an economical combustion requires a stable flame.

The invention has for its object to develop a rotary valve of the generic type in such a way that a largely uniform (constant) flow of bulk material is obtained while maintaining the typical advantages of a discharge lock at the lock outlet.

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This object is achieved in that the discharge cross-section swept by the cells is smaller than the clear cross-section of the discharge shaft.

So far, consequently, in the interest of the fastest possible and complete emptying of the cells that pass over the discharge shaft one after the other, the discharge cross-section is as large as possible, i.e. With regard to the structural conditions, to make the clear cross-section of the discharge chute equal, it has now surprisingly been shown that a conscious reduction in the discharge cross-section in connection with the compressed air blown into the respective cell in the discharge position has been observed so far Pulsations and the resulting temporal fluctuations in the bulk material loading in the subsequent delivery line are completely or at least almost completely eliminated even at relatively low speeds of the cellular wheel.

The exact causes of this effect are not yet known in detail.

Both the type and location of the air injection into the cells and the shape of the free discharge cross-section affect the degree of uniformity of the bulk material discharge. The subclaims are directed to this.

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Particularly noteworthy here is the embodiment according to claim 5, in which the compressed air is blown in from both flange covers, because not only is a particularly intensive swirling of the bulk material achieved but the bulk material is also from the end faces of the cellular wheel (if it is close to the axis Area with end walls provided cell wheel) and largely kept away from the inner surfaces of the flange cover, so that the wear in these areas is greatly reduced.

Also particularly preferred is the symmetrical design of the free discharge cross-section, particularly in connection with a compressed air inlet on both sides. Blow, because in this way an optimal equalization of the bulk material flow at the lock outlet is achieved, even if a cellular wheel with relatively few cells is used and is driven at low speeds.

In the drawing, a cellular wheel sluice according to the invention is shown schematically simplified in, for example, selected embodiments. It shows:

Figure 1 - A first embodiment in perspective

Reproduction,

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FIG. 2 shows a longitudinal section through a cellular wheel sluice similar to FIG. 1,

Figures 3 - 7 - different views "X" of the lock

Figure 2 to illustrate several expedient designs of the discharge cross-section.

1 consists of a lock housing 1 with an inlet shaft 2, an outlet shaft 3, two flange covers 5 and a cell wheel, designated overall by 6, onto which the webs 8 delimiting the individual cells are welded onto the shaft 7 mounted in the flange covers 5 are. The cellular wheel 6 rotates in the direction of the arrow 9. The cells filled with bulk material from above sweep over the area of the outlet shaft 3 in succession.While in the previously known cellular wheel sluices, the entire clear cross section of this outlet shaft 3 forms the discharge cross section, in the cellular wheel sluice it is after Invention of the discharge chute partially covered so that the opening 10 remains only as a free discharge cross section. The bulk material is blown out via this free discharge cross section by means of compressed air V ^ which is blown in via an opening 11 in the flange cover 5 in the direction of arrow 1¾, with the aid of gravity.

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The longitudinal section according to FIG. 2 shows that the opening 11 is designed as a compressed air connection piece. The left half of FIG. 2 also shows a rotary valve that is somewhat modified compared to FIG. 1, and that the flange cover 4 opposite the flange cover 5 with the opening 11 is equipped with an opening 12 for blowing in compressed air, the axis of this opening 12 being so is oriented that the compressed air flow against the cellular wheel shaft 7j is thus directed toward the bottom area of the respective cell. Furthermore, the cellular wheel is provided here in its region near the axis with an end wall 13 which, together with a recess in the flange cover 4, delimits a chamber 14 with which the opening 12 is connected on the one hand and into which a clean air connection 15 opens on the other hand, so that the compressed air supplied via this connection first flushes the bearing of the cellular wheel shaft 7 from bulk material dust or builds up an excess pressure in the chamber 14 which prevents the access of bulk material dust and then supports the bulk material discharge from the cell in question via the opening 12.

3 - 7 show a rotary valve according to FIG.

2 in the view "X", ie a view of the lock outlet 3, the arrows each indicating the direction of rotation of the cell wheel. As can be seen from this, the various, partly symmetrical, partly asymmetrical shapes of the discharge cross section can be obtained by appropriately shaped covers 3a - 3f of the lock outlet 3, these covers either being an integral part of the lock outlet 3 or (see FIG. 1) of the Lock housing 1 can be. 5 - 7 are preferably used in conjunction with compressed air injection from both flange covers. In any case, the dimension "a" of the free discharge cross section in the direction of rotation of the cellular wheel, that is to say perpendicular to the cellular wheel shaft 7j, should correspond at least at one point approximately to the available width of the lock outlet 3, while the dimension "b" at most

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v - 9 - is equal to the width of the lock inlet 3 or the lock housing 1, but remains smaller than its width in the predominant part of the clear cross section of the lock outlet 3. It is crucial for the time equalization of the bulk material flow carried out that the width b 'changes at a right angle to the cellular wheel shaft, that is to say along dimension a, by a relatively large amount. It depends on the design and operating parameters whether - in relation to the direction of rotation of the cell wheel - optimal results with a width increasing from a minimum value to a maximum value (see Fig. 3 to 6), initially increasing and then decreasing again Width (cf. FIG. 7) or a width decreasing from a maximum value (that is to say according to FIGS. 3 to 6, but with the opposite direction of rotation of the cell wheel).

Claims (11)

2. Rotary feeder according to claim 1, characterized in that the air flow blown through the opening (11) is directed to the bottom of the cell which in each case sweeps over the discharge cross section. 3 · rotary valve according to claim 1 or 2, characterized in that the opening is designed as a slot. 4. rotary valve according to claim 3j, characterized in that the slot extends at least approximately parallel to the circular arc described by the cellular wheel webs (8). 5. rotary valve according to one of claims 1 to * 1, characterized in that the flange cover (5) provided with the opening (11) opposite flange cover (* 1) has a similar opening (12). -2- f - 2 - * 6. rotary valve according to one of claims 1 to 5, characterized in that the opening (s) (11, 12) previously used for flushing the bearings of the rotary valve shaft (7) in the chute caps (4, 5) is supplied. 7. rotary valve according to one of claims 1 to 6, characterized in that the width of the free discharge cross-section (10) parallel to the rotary valve shaft (7) at least, = less in some areas than the clear width of the lock housing (1) between the chute caps (4, 5) and at right angles to the cellular wheel shaft (7) is approximately the same as the dimension given by the width of the outlet shaft (3). 8. rotary valve according to one of claims 1 to 7, characterized in that the width of the free discharge cross-section (10) in the direction of rotation of the rotary valve (6) seen from a maximum value continuously decreases to a minimum value (Pig. 3-6). 9. rotary feeder according to one of claims 1 to 7, characterized in that the width of the free discharge cross-section (10) in the direction of rotation of the rotary feeder (6) seen from I a minimum value increases continuously up to a maximum value corresponding to the clear width of the lock housing and then again decreases to a minimum value * (Pig. 7). 10. rotary valve according to one of claims 1 to 8, characterized in that the free discharge cross-section (10) has at least approximately the shape of a triangle (Fig .'- 3 »4,6). 11. rotary valve according to one of claims 1 to 7 or 9, characterized in that the free discharge cross-section (10) has at least approximately the shape of a rhombus (Fig. 7). -3- - 3 - 12. rotary valve according to one of claims 1 to 11, characterized in that the free discharge cross-section (10) is symmetrical to a perpendicular to the rotary valve shaft (7) center line (Pig. 5 - 7). J