Patent Grant
7326169
The present disclosure relates to a full-jacket helix-type centrifuge.
Such a centrifuge is known from German Patent Document DE 43 20 265 A1. The full-jacket helix-type centrifuge disclosed in that document is provided with a weir on the fluid outlet side, which weir has a port which may be formed by several grooves originating from the inside diameter of the weir or by openings provided in the walls of the weir. A throttle disk, which stands still relative to the drum during the rotation of the drum and can be axially displaced by way of a threaded bush, is assigned to the port.
The distance between the weir and the throttle disk can be changed by the rotation of the threaded bush. As a result, the discharge cross-section changes for the fluid discharging from the centrifugal drum, which discharge cross-section is composed of the overall length of the overflow edge of the port and the distance between the weir and the throttle disk.
The change of the discharge cross-section causes a change of the fluid level in the centrifugal drum, so that a continuous adjustment of this liquid level becomes possible by displacing the throttle disk.
The displacing of the throttle disk in the axial direction can also be implemented in that the throttle disk is linked on its outer circumference and is swivelled, which virtually causes an axial displacement between throttle disk and the weir in the area of the weir.
The publication “Patent Abstracts of Japan”, Number 11179236 A shows that baffle plates can be assigned to a port, which provide the fluid discharging from the drum with a swirl, whereby the occurring recoil effect is to be utilized for saving energy.
The construction according to German Patent Document DE 43 20 265 A1 has been successful per se since it offers a solution to the problem occurring in the case of the construction in German Patent Document DE 41 32 029 A1 which is that the devices for adjusting the overflow diameter on the weir rotate along with the drum during the operation, which requires a relatively high-expenditure and cumbersome transfer of actuating forces to the rotating centrifugal drum.
It is nevertheless desirable to create an additional adjusting possibility of the weir of the full-jacket helix-type centrifuge to variable inflow capacities for different usage purposes by simple devices. The present disclosure addresses this possibility.
The present disclosure relates to a full-jacket helix-type centrifuge that includes a drum and at least one weir having a port. A throttle disk is assigned to the port, and the throttle disk is located at a variable distance from the port. The at least one nozzle rotates with the drum, and the at least one nozzle is assigned to an outlet for discharging clarified liquid from the drum.
Accordingly, at least one or more nozzles rotate along with the drum and are assigned to the port for the discharge or diversion of the clarified fluid.
In this manner, the centrifuge permits the diverting of a basic quantity of liquid from the drum through the nozzles, which quantity is fixed during an operation of the centrifuge. A precise regulating or precise adjusting of the liquid level in the full-jacket centrifuge is possible by a variable throttling device, particularly the throttle disk.
Nozzles on full-jacket centrifuges and their effect with respect to saving power when correspondingly directed in an inclined manner relative to the drum axis are known per se, for example, from German Patent Document DE 39 004 151 A1. The present disclosure's combination of these nozzles with a throttling device at the liquid discharge is not known. The throttling device is used for regulating the fluid level in the centrifuge. An increasing flow resistance at the gap through which the fluid exits at the throttling device requires a higher fluid pressure at the port, which results in a rise of the fluid level in the centrifuge. Since, as a result of this pressure change, the amount of the fluid quantity flowing out through the nozzles also changes, these two effects add up; that is, the achievable control range becomes larger and the control characteristic is favorably influenced. This effect does not occur according to the state of the art, since no throttling device with nozzles connected on the input side is provided there, only nozzles with an overflow opening on the output side are provided. According to the state of the art, as a result of the nozzle, power will be saved and the conditions at the solids discharge will be improved.
The nozzles of the present disclosure may be constructed to be changeable in order to be able to carry out a preadjustment of the discharging fluid amount in a simple manner, for example, in the event of strongly varying amounts of throughput. Additionally, the exchange of the nozzles for other nozzles with a different diameter provides a simple additional possibility of changing the control characteristic and adjusting characteristic. “Nozzles” with blind holes (closed holes) can also be used, whereby the number of nozzles and the characteristic can also be changed.
In an embodiment, the nozzles are connected behind the port, and the throttling device, in turn, is connected behind the nozzles.
In an embodiment, the nozzle chamber also has a diameter which corresponds to the diameter the outer edge of the port. As a result, favorable flow conditions are ensured in the nozzle chamber which largely or completely prevent an accumulation of dirt. In that case, broaching elements are no longer required in the nozzle chamber.
In order to avoid clogging, the nozzles may have a diameter of more than 2 mm. In particular, the nozzles can be provided with such a large diameter if, relative to the lagging, they are arranged radially offset toward the interior such that, in a plane perpendicular to the drum axis, the nozzles have or are at a distance of from 25 to 75% of the drum radius from the outer drum radius. Their diameter can be selected to be the larger, the farther the nozzles are arranged toward the interior, in order to implement a consistent discharge output. The arrangement farther toward the interior basically allows the nozzles to be designed such that clogging is reliably avoided. This was not recognized in the state of the art. Also for this reason, those nozzles have not been significantly successful in practice.
Arranging the nozzles farther in the interior toward the axis of rotation makes it possible to change a ring chamber, as provided according to German Patent Document DE 43 20 265 A1 where it is called a ring duct. Therefore, the broaching tools provided and arranged there in the ring duct, which are necessary for avoiding the accumulation of dirt, can be eliminated.
In addition to the good adjustability and adaptability of the amount of the discharging fluid from the full-jacket helix-type centrifuge, the openings of the nozzles are directed correspondingly inclined with respect to the axis of symmetry or rotation of the drum. Thus, the fluid exiting from the nozzles reduces the driving power and energy of the full-jacket helix-type centrifuge to be applied. This saving of energy is not inconsiderable and can lead to a noticeable lowering of the power consumption of the full-jacket helix-type centrifuge.
Relative to the rotating direction of the drum, the openings of the nozzles are directed to the rear in order to save energy.
Relative to a tangent in a plane perpendicular to the axis of rotation on the drum surface, the openings of the nozzles are preferably directed such that they have an inclination of between 0° and 30°. An inclination of 0° results in a maximal gain of energy. Values larger than 0° and smaller than 30° can easily be implemented constructively.
If an embodiment with a radial alignment of the nozzle openings is implemented, a saving of energy during the actuating of the drum may be eliminated. However, the easy adaptability to different amounts passing through is maintained, so that such an embodiment offers a favorable comparison to the state of the art.
The gain of energy in the case of full-jacket helix-type centrifuges of the present disclosure is such that the circumferential speed of the drum at the outside diameter of the drum during the operation is more than 70 m/s because the gain of energy has a particularly clear effect in the case of such centrifuges.
These and other aspects of the present invention will become apparent from the following detailed description of the invention, when considered in conjunction with accompanying drawings.
An axially extending centric inflow tube 7 is used for feeding the material to be centrifuged by way of a distributor 9 into the centrifugal space 111 between the helix 5 and the drum 3.
If, for example, a sludgy mush is guided into the centrifuge 1, coarser solid particles are deposited on a drum wall. A fluid phase is formed farther toward an interior of the centrifuge 1.
The helix 5 rotates at a slightly lower or higher speed than the drum 3 and delivers centrifuged solids toward the conical section out of the drum 3 to a solids discharge 13. In contrast, the fluid phase flows to the larger drum diameter at the rearward end of the cylindrical section of the drum 3 and is diverted there through or by way of a weir 15.
According to
The nozzles 21 are constructed as screwing bodies inserted into directed openings 23 of a stepped ring attachment 25. The openings 23 are further developed radially or inclined with respect to a drum axis S. Holes, bores or inlet openings 27 of the screwing bodies are aligned perpendicularly or at an angle with respect to the drum axis S of the drum 3.
In the area or section adjoining the port 17, the ring attachment 25 has an inside diameter which corresponds to an outside diameter of the port 17. A nozzle chamber 33 also has a diameter which corresponds to the diameter at the outer edge of the port 17. Also, the inlet openings 27 of the nozzles are situated flush with the diameter of the overflow-type port 17. This prevents the accumulation of dirt in the nozzle chamber 33.
At its end facing away from the port 17, the ring attachment 25 forms an axial outlet 29 on whose output side the throttle disk 31 is connected. A distance between the throttle disk 31 and the outlet 29 is variable, for example, in the manner described in German Patent Document DE 43 20 265 A1 by different actuating devices (not shown here).
The distance between the throttle disk 31 and the outlet 29 may be changed by an axial movement, for example, by an axial displacing or by a swivelling of the throttle disk 31, which stands still relative to the rotating drum 3. As an alternative, it is also conceivable that the throttle disk 31 rotates along with the drum 3 in the operation (not shown). However, the rotating alternative may require higher constructive expenditures than the embodiment in which the throttle disk 31 does not rotate along.
The term “nozzle” is to be understood such that the bore or inlet opening 27 may have a diameter which is constant or variable along an axial dimension of the opening 27. The nozzle 21 may also be constructed as a bore in the ring attachment 25; however, the screwing bodies offer changeability and preadjustment of a discharge quantity.
In the inner nozzle chamber 33, ribs (not shown here) may be included and may improve delivery of fluid.
Through the nozzles 21, a basic quantity of fluid may be preadjusted, depending on the design and diameter of the openings 27 of the changeable screwing bodies, and diverted from the drum 3. An optimal alignment of the nozzles 21 for a maximal saving of energy can be determined by simple tests.
For example, in a case of an embodiment of a full-jacket helix-type centrifuge for thickening a sludge at the ratio of 1:10 with an inflow capacity of 300 m3/h and a removal of solids of 30 m3/h, a nozzle design for 200 m3/h as well as a diversion of 70 m3/h is recommended for regulating the level by way of the throttle disk 31.
When lower capacities of, for example, 200 m3/h inflow are implemented, a quantities of solids of, for example, 20 m3/h is obtained. In the case of this quantity, a nozzle design for 110 m3/h as well as a diversion of 70 m3/h would be recommended for regulating the level by way of the throttle disk 31.
For an adaptation to different capacities, the nozzles 21 are simply exchanged for those of a different diameter. A high-expenditure exchange of expensive and complicated components is not required.
The nozzles 21 may be arranged in a plane perpendicular to the drum axis S at a distance from an outer drum radius or circumference of from 25 to 75% of the drum radius. That is because a gain of energy is larger the closer the nozzles 21 are to the drum circumference. However, an arrangement farther toward an interior may be more favorable when the diameter of the nozzles 21 or their opening cross-section are larger than in the case of an arrangement farther toward the outside, so that they clog less rapidly. The above-mentioned range represents a compromise.
As in German Patent Document DE 43 20 265 A1, a change of the discharge cross-section by adjusting the distance between the throttle disk 31 and the outlet 29 causes a change of the fluid level FS in the drum 3. In this case, the fluid level FS in the full-jacket helix-type centrifuge is precisely adjusted by the throttle disk 31.
The following applies in the case of the full-jacket helix-type centrifuge of
P(Qw)=p×Qw×U2w.
In contrast, in the case of the centrifuge of the present disclosure, the largest portion of the volume flow at the diameter dw is diverted through the nozzles (volume flow QD), and another partial flow is diverted through the outlet 29 of throttle disk 31.
If, as a result of the throttle disk 31, the fluid level FS in the chamber 33 is held at the weir diameter dw, the capacity as a result of the throughput fraction QD flowing off from the nozzles 21 amounts to:
P(QD)=p×QD×U2w×A.
In the case of a nozzle inclination angle between 0 and 30°, a clear power demand reduction is computed from this formula. Distance A is a function of the diameter dw and of a shape of the cross-section of the nozzle 21, of the level FS in the drum and of an emission angle of the nozzle 21. The geometry of the cross-sections of the nozzles 21 may have an arbitrary design; thus, it may be round or square or of a different shape.
In contrast,
Although the present disclosure has been described and illustrated in detail, it is to be clearly understood that this is done by way of illustration and example only and is not to be taken by way of limitation. The scope of the present invention is to be limited only by the terms of the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102 03 652 | Jan 2002 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP03/00776 | 1/27/2003 | WO | 00 | 3/15/2005 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO03/064054 | 8/7/2003 | WO | A |
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