The present invention concerns improvements to an apparatus for treating organic waste of various types, like vegetables, fruit and other food waste. By using the apparatus of the invention fine grinding and compacting of the waste occurs before the waste is delivered to a public collection centre. Consequently, the volume of the waste is reduced, which limits the environmental impact, limits the remaining humidity of the ground waste to avoid bacteria, and avoids fermentation and bad odours. Furthermore, the apparatus makes it possible to accomplish differentiated collection of the waste and to produce compost.
An apparatus of this type needs to be suitable for a practical use, which comprises the steps of introducing the waste to be ground, grinding the waste, compacting and squeezing the ground waste to extract the residual liquids, therefore to reduce the volume and achieve the dehumidification of the waste. Finally, the treated waste needs to be discharged without manually intervening on it.
The apparatus of DE 317 788 mixes and possibly breaks portions of substances with agitator 17. This apparatus is not suitable for treating ground waste that is cut by using cutting blades.
The apparatus needs to be easily emptied of the waste, when the apparatus needs to be stopped for long periods of inactivity.
The movement mechanisms of the apparatus need to be reliable and simple to guarantee a long life of the apparatus and a minimum amount of maintenance operations.
Furthermore, the apparatus needs to allow facilitated cleaning to remove remaining waste, when the apparatus is emptied for long periods of inactivity. This problem is particularly felt when compacting organic kitchen waste present in homes, refectories, restaurants, etc., where frequent disinfection of the machine is necessary to avoid bad odour and bacterial presence.
It is therefore an object of the invention to provide an apparatus for treating waste, in particular organic waste, which overcomes the above mentioned problems.
It is a further object of the invention to provide an apparatus for treating waste, which is capable of improving the compacting step and the dehumidification of the waste, thereby achieving an optimal separation of the liquid parts from the solid parts.
It is a further object of the invention to provide an apparatus for treating waste in which compacting and extraction of remaining liquids occurs and that can be easily emptied of the waste when the apparatus needs to be stopped for long periods.
It is also an object of the invention to provide an apparatus for treating waste where ordinary maintenance can be easily carried out and allowing facilitated extraction and cleaning of the parts where passage of the waste occurs.
These and other objects are achieved by the apparatus and the method for treating the waste according to claims 1, 10, 15 and 19.
Further characteristics are defined by the dependent claims.
Further characteristics and advantages of the apparatus and the methods according to the invention will result more clearer from the description which follows of
a to 6f are partial section views of area 6 of
With reference to
A possible succession of working steps of the apparatus starts when the loading section 11 is opened for introducing the waste 15 to be treated (see
The loaded waste 15 falls into the grinding section 12. This section is provided with grinding means 16, for example a series of blades located on the periphery of two drums which rotate opposite to each other, like those described in Italian Application PI 2007A000050, to accomplish e fine grinding of the waste. Below the grinding means 16, the ground waste falls through aperture 15′ of casing 18 into the vanes 17′ of a helical screw device 17.
Helical screw device 17 is provided with a longitudinal axis 17′ within casing 18 and is capable of rotating around this longitudinal axis. The rotation of helical screw device 17 conveys ground material against and in front of a wall 19a of a closure 19 (see
As the material M progressively accumulates against the closure 19, relative movement of the closure 19 occurs with respect to the helical screw device 17 along a path that is substantially parallel to the axis of the helical screw device 17.
In the embodiment of
In this way, the material M in front of closure 19 undergoes a compression action, which compacts and squeezes it to cause residual liquid to be extracted. During compacting no discharge of the compacted waste occurs.
For these reasons, a bored casing 20 is provided inside the final portion of casing 18 where the material M accumulates to allow liquid to be extracted as the squeezing occurs.
Casing 18 is provided with an exit 50 connected to a conveying duct 21′ through which liquid 21 is discharged from the apparatus.
Closure 19 is provided with a rear part 19′ (see
Therefore pins 25′ and 25″ have the possibility of moving in the plane that is perpendicular to the plane containing
Closure 19 is guided by the engagement of its external surface against the internal surface 23′ of cover 23 as the latter moves in directions T and T′, as shown in
The two opposite forces obtained in this manner accomplish squeezing extraction of liquid 21 and compacting of material M.
During this sequence of forces, see
When pin 25′ or pin 25″ are in the transverse parts 22c, a situation signalled by a sensor not shown in the figures, the rotation of the screw device 17 is stopped. At the same time pins 25′ and 25″ become located in the position that causes an engagement connection of the closure 19 to cover 23, see the position of pin 25′ shown in
As a result, closure 19 is no longer free to move with respect to cover 23 due to engagement of pins 25′ and 25″ in the seat portion of groove 22c, which renders closure 19 and cover 23 connected and integral, as shown in
At this point cover 23 can be opened and closure 19 moves with it to free the exit opening 18′ of casing 18 to discharge the compacted material M, as shown in
Then, screw device 17 translates in direction T to push the compacted material M through the exit opening 18″ out of casing 18, as shown in
During the translation, screw device 17 is guided by the internal surface of casing 18. At the end of the travel of the screw device 17 in direction T, end 27 of the screw device reaches the position that extends beyond the edge of the end of casing 18, as shown in
Once material M has been unloaded, cover 23 is closed to start a further step of squeezing and compacting. During the travel of cover 23 to be closed, closure 19 engages the end 27 of screw device 17. During this engagement and the travel of cover 23 to become closed, pins 25′ and 25″ become free from the seats of the transverse parts like 22c of shaped grooves 22′ and 22″, and consequently closure 19 becomes disconnected from cover 23.
At this point, cover 19 follows the backward movement of screw device 17 in direction T′ because closure 19 is being pushed by springs 24, whilst the end 27 of screw device 17 acts like a moving engagement surface to withhold uncontrolled backward movement of closure 19.
During the backward movement in direction T′, pins 25′ and 25″ relatively move in stretches like 22d and 22a.
For the steps described in the foregoing where the cover 23 is opened and closed to remove, or replace closure 19 a drive mechanism 55 (dash line representation in
The complete closure of lid 23 and the backward movement of the screw device 17 in direction T′ bring closure 19 in the most forward position (see
With reference to
Drum 32 is assembled in a fixed manner on the end of exit shaft 31 of motor gear drive 30, visible in
The free wheel 33 is assembled between drum 32 and end 34 of screw device 17, as shown in
During the opposite rotation of the motor reduction drive 30 (opposite rotation in the following), the freewheel 33 remains idle, which makes drum 32 idle with respect to end 34 of the screw device 17. Therefore no rotation torque is transmitted, thereby excluding rotation of screw device 17 during opposite rotation of motor reduction drive 30.
The free wheel 33′ is assembled between drum 35 and the exit shaft 31 of motor reduction drive 30. The external surface of drum 35 is provided with groove 36, which has a cam profile. The motor reduction drive 30 is provided with bars 38 (see
The roller 39 of an arm fixed to the frame of the apparatus can engage the internal surfaces of groove 36 (see
Based on the principles described above and with reference to
The possibility of being able to remove closure 19 favours access to the area of casing 18 where the compacting and the squeezing of residual liquid occurs. In this way the operations to remove remaining waste and cleaning becomes facilitated.
As shown in
By means of particular movements of closure 19 or force reactions of closure 19 produced by actuator 41, and which are programmed and controlled by unit 42, it is possible to optimize compacting of the material M and squeezing of liquid 21.
In the above mentioned description, the movement of closure 19 with respect to screw device 17 has been created in opposition to the force of preloaded spring 24, or by the force exerted using actuator 41. Other equivalent means are available in the art for generating the force opposing the movement of closure 19, for example viscous dampers, or elastic dampers or a combination of these.
A sprinkler device 70 and detergent dispenser devices 71 can be assembled on the lid 90 of loading section 11 as shown in
Detergent D can also be dispensed by detergent dispenser devices 71 on the walls of loading section 11, as shown in
When the submerging level sensed by sensor 77 and controls 80 has been reached, or a predetermined level of liquid has been fed through sprinkler 70 sensed by flow sensor 77′ in combination with controls 80, and after a certain period of waiting time, grinding means 16 and screw device 17 can be rotated to favour cleaning and detachment of waste from the surfaces of the apparatus. Once this step of rotation has been terminated, valve 82 can be opened and pump 85 activated to discharge the liquid. After this discharge has occurred, screw device 17 can be rotated to convey any detached waste against closure 19. Then screw device 17 can be caused to travel in direction T to push closure 19 in direction T and cause it to become connected to cover 23 by means of pins 25′ and 25″, as described in the foregoing. This situation can allow cover 23 to be opened so that screw 17 can move further in direction T to discharge the detached waste.
The foregoing description of a specific embodiment will so fully reveal the invention according to the conceptual point of view, so that others, by applying current knowledge, will be able to modify and/or adapt for various applications such an embodiment without further research and without parting from the invention, and it is therefore to be understood that such adaptations and modifications will have to be considered as equivalent to the specific embodiment. The means and the materials to realise the different functions described herein could have a different nature without, for this reason, departing from the field of the invention. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation.
Number | Date | Country | Kind |
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PI2011A000001 | Jan 2011 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB11/54710 | 10/21/2011 | WO | 00 | 11/28/2012 |