The invention relates to screw presses used in the compaction of solid waste for disposal, for example, in bags or other waste collection containers, i.e. presses for example of the type used in machines which the same Applicant produces for compacting plates, cutlery and bottles made of plastic, food and beverage left-overs, napkins or serviettes used, for example, in catering activities.
For this purpose, the state of the art teaches the use of frustoconical screw presses, with helices having a diameter and pitch decreasing towards the discharge mouth. Presses of this type are described, for example, in the German patent DE 3,429,848 and in the European patents EP 239,858, EP 790,122 and EP 1,193,045. All the presses of the known type are arranged with their axis horizontally, so that they occupy a considerable volume in plan view and must be positioned at a considerable distance from the ground in order to be able to position directly underneath their discharge mouth a container sufficiently high and with a big enough capacity to receive the compacted material. The screw of the presses is supported projecting at the end where it is motor-driven, usually by means of bearings which are subject to high concentrated radial forces due to their significant weight and the considerable length of the said screw when the latter is not supported by the material to be compacted.
In order to reduce the dimensions of the press, in particular the longitudinal dimensions of the machine which uses such a press, the Applicant is the proprietor of the Italian industrial model registration No. 257,243 filed on Aug. 1, 2003, in which the screw press is inclined upwards with its discharge mouth, so that its longitudinal axis forms with the bottom horizontal surface an angle greater than 20°, for example in the region of 40°-60°. With this solution the longitudinal plan dimensions of the press are reduced, large-capacity high containers may be positioned underneath its discharge mouth, and the flexural stresses of the screw on the support bearings are reduced, thereby reducing the radial load concentrated on these bearings. With this solution it is possible to limit the dimensions of a compacting machine with screw press of the type mentioned above to about 1 meter in terms of the length and about 650 mm in terms of the width.
Since several screw presses must be arranged alongside each other in order to form a compacting machine which can be used for sorted-waste collection, the dimensions of such a machine increase considerably and limit the positioning thereof in spaces. The invention intends to limit substantially the lengthwise dimensions of a screw press for compacting machines, with the solution according to Claim 1) and the subsequent dependent claims, based on the following proposed idea. The current screw presses are formed by an initial large-diameter section with wide-pitch helices, which communicates laterally with the loading hopper and comprises a successive small-diameter section with a gradually decreasing pitch, which is about as long as the first section and is completely surrounded by the internally scored body of the press. The first section of the screw must move and grip the material fed loose inside the hopper and must feed it to the second section which performs compaction thereof. In order to solve the problem mentioned above, the proposed solution consists in separating the two screw sections and arranging them parallel one above or around the other one, so as to form overall a screw which no longer has as its length the sum of the lengths of the two sections, but has a length corresponding to the length of the longer of the two sections. With this solution it is possible to provide compacting machines with a length of about 650 mm and width of about 650 mm, with the obvious advantages arising therefrom when several presses must be arranged alongside each other in order to perform sorted-waste collection. This solution also has the advantage that the two screws may be operated at different speeds and in particular the first large-diameter and wide-pitch screw may be operated at a speed which is less than that of the smaller-diameter compacting screw, so that the said first screw is able to grip slowly and gradually the material to be fed, even though the latter is pushed downwards with a limited force. According to a preferred embodiment of the invention, the first feeder screw has only helical vanes and is axially hollow so as to surround a section of the second compacting screw, preferably arranged coaxially. According to one variant, the feeder screw is situated laterally and above a section of the compacting screw.
Further characteristic features of the invention and the advantages arising therefrom will become clearer from the following description of some preferred embodiments thereof, illustrated purely by way of a non-limiting example, in the figures of the four accompanying sets of drawings in which:
From
The outer screw 3 is, for example, of the type with two threads and is formed by only the two helices 103, 103′ which are offset by 180° with respect to each other and which each cover half the pitch and are welded with their ends to a pair of circular and parallel plates 203, 203′ provided with respective axial and concentric holes 303, 303′. The plate 203, as shown in detail in
The pinion 9 and the said flange 108 are designed to support the outer ring of axially/radially acting bearings 11, 11′ which rotatably support the end of the shaft 104 of the inner screw 4, and the outer end of this same shaft has, keyed thereon, a pinion 12 of suitable diameter. The pinions 9 and 12 derive rotation for example from a centralized gear motor unit 13 which is fixed, for example, to a lateral and bottom extension 401 of one of the end walls 201, 301 of the hopper 1 and the slow shaft of which has, keyed thereon, pinions 109, 112 which by means of respective chains 209, 212 transmit the necessary rotation to the said pinions 9, 12 and to the parts kinematically associated with them. In
The direction of the screws 3 and 4 is the same and the direction of rotation thereof will be such that the material is displaced towards the plate 203′. The material introduced into the hopper 1 is dislodged and moved towards the bottom by the slow outer screw 3 so as to be taken up by the helices of the inner screw 4 which, owing to the relative movement of the two screws, moves the material in the direction of the axial hole of the plate 203′ of the said outer screw. The screw section 4 which operates inside the hopper 1 uses the internal diameter of the outer screw 3 as a reaction chamber so as to be able to start axial discharging and compaction of the waste fed by the said outer screw 3. The operating speeds of the two screws can be easily determined experimentally, also depending on the type of material to be compacted, and so they are not indicated in detail here.
From
The inner screw 4 has a single cylindrical helix with a pitch decreasing towards the discharge outlet or more simply constant as shown in the drawings and has a length such as to project over a suitable section from the central hole of the plate 203′ of the outer screw 3 and this projecting section operates inside a short tubular stator 15, the discharge mouth 115 of which has a “flute tip” form with a downwards inclination and this stator is provided with an intermediate flange 215 which is fixed on the end wall 301 of the hopper 1 and with its section passes through a hole provided in this wall and rotatably engages the central hole of the said plate 203′, so as to emerge inside the hopper 1. The inner side surface of the stator 15 is provided with longitudinal recessed and/or raised scoring 16 which is necessary for ensuring that the screw imparts the axial feeding component to the compacted material, and similar scoring (not shown) may also be provided inside the hopper 1.
A constriction device of the known type 17 acts on the discharge mouth 115 of the stator 15; such a device is described, for example, in Italian patent application No. BO2005A-693 in the name of the same Applicant and assists the compression and compaction of the material discharged by the inner screw 3.
The bottom of the hopper 1 may be provided with a grilled zone 18 which is constantly cleaned by the helices of the outer screw 3 and which communicates with a small box 118 fixed on the outside of the said hopper and provided with a pipe 218 for discharging any liquid which, owing to the presence of the step existing between the said bottom of the hopper and the lowest part of the compaction stator 15, would tend to stagnate inside the said hopper. As an alternative to this solution it is possible to use the solution which is described in Italian Utility Model application No. BO2004-U78 in the name of the same Applicant and which envisages an orifice for discharging the liquids, situated in the bottom part of the wall 201 of the hopper, namely in the bottom part of the flange 106 and closed with suitable play by an extension of the plate 203 of the feeder screw 3, which will be provided with scrapers for constant cleaning of the said play and the said liquid discharge orifice.
Purely by way of a non-limiting example, as shown in
With reference to
The screw presses have been illustrated in the drawings with a horizontal arrangement, but it is understood that they may be suitably inclined with their longitudinal axis directed upwards or downwards. It is also understood that the description relates to a preferred embodiment of the invention to which numerous variations and modifications, in particular of a constructional nature, may be made, these consisting, for example, in the fact that in both solutions the larger-diameter feeder screw 3 or 3′ may have two helices or only one helix which are/is integral in a projecting manner with the single conveyor plate 203 which will be supported by suitably sized bearing boxes.
Number | Date | Country | Kind |
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BO2007A0021 | Jan 2007 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/050498 | 1/17/2008 | WO | 00 | 7/2/2009 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2008/087183 | 7/24/2008 | WO | A |
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Number | Date | Country |
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11 66 460 | Mar 1964 | DE |
34 29 848 | Feb 1986 | DE |
239858 | Oct 1987 | EP |
0 790 122 | Aug 1997 | EP |
1 721 728 | Nov 2006 | EP |
792 870 | Apr 1958 | GB |
1 282 959 | Jul 1972 | GB |
BO2004-U78 | Sep 2004 | IT |
WO 0202867 | Jan 2002 | WO |
WO 2004062900 | Jul 2004 | WO |
WO 2007057293 | May 2007 | WO |
Number | Date | Country | |
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20100083850 A1 | Apr 2010 | US |