GR1010351B - Vessel for mechanical composting - Google Patents

Abstract

The composting vessel shows a U-shape horizontal vessel (100) and a U-shape inclined vessel (200) where said inclined vessel is welded in parallel to the horizontal vessel and connected to said horizontal vessel at the bottom with the configuration 110 and at the top with the inclined surface 106. An intermittent screw conveyor mixes and drives forward the material to be composted. Facilitated by the configuration 110, the material reaches the bottom of the inclined vessel 200. The material is then lifted to the top of the inclined vessel (200) by means of a screw lift. Diverter gate 300 at the top of the inclined vessel (200) regulates by means of the diverter gate 301 whether the material will return to the horizontal vessel (100) or exit the apparatus through the discharge port 303. The biowaste recirculation through the inclined vessel (200) allows better mixing of biowaste and control of the residence time of the composting vessel. The drop and tumble of bio-waste from through the inclined surface 106 allows better aeration of biowaste, resulting in a more efficient aerobic composting process. The apparatus makes better use of the volume of the tank for the entry and processing of materials.

Description

CLOSED MECHANICAL COMPOSTING TANK

Description

The present invention relates to a closed mechanical composting tank according to the main concept of claim 1 of the invention.

Composting is a natural aerobic biological degradation process in which aerobic microorganisms break down organic materials such as crop residues, biowaste and food waste, consuming much of their nutrients while reducing their bulk. During composting, microbial activity raises the temperature of the materials naturally, resulting in the final product being sanitized and biostabilized. In nature, composting takes place at a slow rate as optimal conditions for the action of microorganisms are difficult to maintain. A closed mechanical composter takes care of maintaining optimal moisture and ventilation conditions so that composting can take place effectively over a period of about 3 to 6 weeks.

In closed mechanical composters, the main part of the composting takes place while the materials are sitting in a composting tank. In composting tanks such as those described by US5981269A and US7520457B1 significant problems are observed. First, the aeration of the materials is often deficient, with the result that the composting process does not have sufficient oxygen to carry out the aerobic processes and artificial heating is required to sanitize and biostabilize the materials, as suggested in the case of US5981269A and US7520457B1. Second, in said tanks, materials can move in only one direction from an entry point to an exit point, as suggested in US7520457B1 , with the result that their mixing is incomplete if the input materials are highly inhomogeneous. This element in question also prevents the introduction of materials at different points of the tank, with the result that the complete closed composting system has construction limitations regarding the location of the inlet port. Third, the residence time depends only on the rotation rate of the drum (US7520457B1) or the rotation rate of the stirring/mixing shaft (US5981269A), resulting in the user having no management flexibility and having to manually re-introduce the materials that do not have undergone complete composting. Fourth, in rotating drums such as those described in US7520457B1 , the useful volume is smaller than the volume of the drum to allow space for aeration and introduction of materials.

The purpose of the present invention is to find means by which (a) to achieve better aeration of the materials, (b) to allow the recirculation of the materials in the composting tank in a limited space and without their exit from the tank, resulting in better mixing and residence time control and (c) better utilization of tank volume for input and processing of materials. In this way, the aerobic composting process benefits and the space and user intervention in the system is limited.

The above advantages of the present invention are described below based on technical descriptions and figures. In the present case, said advantages are considered essential parts of the invention although it is not necessary to use them universally in the invention.

Figure 1 shows an isometric illustration of the horizontal U-section composting vessel (100) where the composting of the materials takes place. The stirring, mixing and transport of the materials in said vessel is achieved through a conveyor screw (not shown). Parallel to said horizontal vessel, there is an inclined vessel of cross-section U (200). The advancement of the materials to the upper part of said vessel is done by means of a screw elevator (not shown). The diverter valve 300 regulates whether the material will return to the horizontal composting vessel or exit the tank.

In the shown embodiment, the composting tank is described as the space where the materials are composted and consists of welded stainless steel sheets, preferably of AISI-SAE 304L quality. The horizontal vessel 100 can have a variable length (L) depending on the volume requirements of the composting machine. Accordingly, the slope (S) and the length of the elevator screw (200) can be variable so that the diverter valve (300) is always above the horizontal vessel 100.

In the horizontal shaft (101) of the horizontal vessel 100 there is a hole 102 through which the shaft of a conveyor screw passes (not shown). Said hole (102) seals with a sealing gasket or mechanical seal to prevent leaks. Said conveyor screw may be intermittent, or have fins, or ribbon, etc. depending on hardware requirements. The arrangement of said auger is such that during its clockwise rotation the materials are advanced to the front of the horizontal vessel 100. In a preferred embodiment, at the beginning and end of said auger the direction of arrangement of the auger or wings or of the ribbon is reversed so that the material is diverted from the front and back of the tank.

Shown in Figure 2 is the specially shaped piece 110, which connects the front of the horizontal boat to the bottom of the inclined boat and leads to the accumulation of materials in the lower part of the elevator boat auger (200). A suitable transmission system (not shown) transmits motion from an electric motor or hydraulic system to the shaft (101) of said auger and allows said auger to move the biowaste to the front or rear of the tank depending on the direction of rotation. The specifications of the motor in question depend on the dimensions of the device. The direction and speed of rotation of said motor (and by extension said auger) is regulated using a PLC unit (not shown) in such a way that composting conditions remain optimal.

In the inclined shaft (201) of the inclined vessel (200) there is a hole 202 through which the shaft of a screw elevator passes (not shown). Said hole (202) seals with a sealing gasket or mechanical seal to prevent leaks. Elevator screw can be conventional or serrated etc. depending on material requirements. In a preferred embodiment, at the top of said auger the direction of the auger arrangement is reversed so that the material is diverted from the top of the vessel to the diverter valve (300). A suitable transmission system (not shown) transmits motion from an electric motor or hydraulic system to the shaft (201) of said auger and allows it to move the biowaste to the top or bottom of the inclined vessel (200) depending on the direction of rotation. The specifications of the motor in question depend on the dimensions of the device. The direction and speed of rotation of said motor (and by extension said auger elevator) is regulated using a PLC unit (not shown) in such a way that composting conditions remain optimal.

The diverter valve (300) consists of the port (301) and a rotating shaft (302) attached accordingly. Said gate (301) moves between two positions as shown in Figure 3: (a) closed and (b) open, thereby diverting the biowaste fed by the auger elevator into the inclined vessel (200). In the closed position (figure 3a), the material returns into the composting vessel through the inclined surface 106. In the open position (figure 3b), the material is diverted into the diverter valve (300) and exits the tank through the discharge hole (303 ).

From the discharge hole, material can be collected via a container or bag (not shown). A suitable transmission system (not shown) transmits motion from an electric motor or hydraulic system to the shaft (302) of said diverter valve and allows it to move between the two aforementioned positions. The specifications of the motor in question depend on the dimensions of the device. The rotation or movement of said motor or actuator (and by extension said diverter valve) is regulated using a PLC unit (not shown) such that the material returns to the composting vessel or exits the tank.

Shown in figure 4 is the path of the material. After the biowaste enters the horizontal vessel (100) from any point above said vessel, the biowaste is gradually moved by the conveyor auger to the front of the horizontal vessel (Figure 4 path A). The screw elevator gradually guides the material through the inclined vessel (200) to the diverter valve (300) along path B. Depending on the position of the port (301), the material is diverted back to the horizontal vessel (100) along path C , or exits the tank along path D. Path ABC is advantageous because it allows material to be recirculated in the smallest possible space. Following this mode of operation, route BC is beneficial to the composting process because the fall of biowaste from a height causes more effective aeration than the simple agitation that occurs during route A.

The horizontal composting vessel (100) has additional holes (illustrated 103, 104) where sensors (not shown) can be installed. These sensors give information (eg temperature, biowaste level) to a PLC unit (not shown) for the purpose of automatically adjusting the mechanical movements, providing updates to the user and being able to intervene in the programmed operation.

The tank rests on a metal frame and is surrounded by a thermally insulated enclosure, either solid or with transparent sections, or any other enclosure that can accommodate the tank and motors and allow controlled air flow (eg controlled ventilation and filtered ventilation). . For example, there may be a horizontal lid that seals the tank or a transparent superstructure that allows simultaneous solar drying of materials. Biowaste is added from any opening on the tank casing as long as it is above the upper level of the horizontal vessel (100) or the inclined vessel (200) and is removed using the diverter valve (300).

Claims (2)

Claims 1. A closed mechanical composting tank with a horizontal U-section vessel (100) and an inclined U-section vessel (200) welded parallel to the horizontal vessel, characterized in that the inclined vessel (200) is connected to the horizontal vessel (100) at the bottom part with the specially shaped block 110 and at the top with the inclined surface (106). 2. A closed mechanical composting tank according to claim 1, characterized in that in the upper part of the inclined vessel 200 there is a diversion valve 300 which regulates through the port 301 whether the material will return to the horizontal vessel (100) or whether it will exit from the arrangement through the discharge hole 303.