BRPI0800284A2 - waste disposal system with compaction and pocketing - Google Patents

Abstract

<UM> FINAL DESTINATION SYSTEM FOR WASTE WITH COMPACTION AND PACKAGE <MV>, comprising a set of operations used to determine the best way to dispose of waste in general (garbage), using a system with or without recycling, and using high compaction to reduce the voids and liquids from the compaction, existing in the garbage, aiming its subsequent pocket for packaging and appropriate places.

Description

Final disposal system with compacting and repayment

Technical field

The following descriptive report of the present application relates to the development of a compacted and pocketed waste disposal system comprising a set of operations employed to determine the best way to dispose of general waste (waste) using with or without recycling, and using high compactness to reduce voids from this process and existing in the waste, aiming its subsequent pocketing for packaging and final destination in appropriate places.

Waste or garbage is considered to be any useless, superfluous, and / or worthless material generated by human activity and which needs to be disposed of. Any material whose owner deletes, wants to delete, or needs to delete.

The term waste generally applies to solid-state materials. Liquids or gases considered useless or superfluous are, meanwhile, generally called waste (liquid or gaseous). However, the terms waste and waste may also be used to describe solid fluids respectively.

There are several types of waste that can be classified by composition, for example:

- Organic waste, the main component of which is highly hazardous human waste, as it can easily harbor and transmit a wide variety of disease-causing worms, bacteria, fungi and viruses. Organic ash can be selectivized and used as fertilizer (from composting) or used for the production of certain fuels such as biogas, which is rich in methane (from biogasification).

- Inorganic waste, which includes all material which has no origenological origin, or which has been produced by human means, such as plastics, metaise alloys, glass, etc.

Much of inorganic waste has a major problem: when thrown directly into the environment, without prior treatment, it takes a long time to decompose. Plastic, for example, is made up of a complex structure of tightly linked molecules, which makes their degradation and subsequent digestion by decomposing agents (primarily bacteria) difficult. To solve this problem, many inorganic products are biodegradable.

- Toxic waste, including batteries, which contain heavy emetal acids in their composition, certain types of ink (such as that used on printers), and industrial waste.

- Highly toxic waste consisting of nuclear and hospital waste

- Household waste, formed by solid waste produced by residential activities and has around 60% organic composition and restorative formed by plastic packaging, cans, glass, paper, etc.

- Urban solid waste, which includes domestic waste as well as waste produced in public facilities (eg parks), commercial facilities, as well as construction and demolition debris.

- Industrial waste generated by industries and is generally highly destructive to the environment or human health.

Several types of waste disposal are known, for example:

- Landfills are considered a practical, inexpensive way to dispose of urban and industrial waste, as well as untreated sewage. Therefore, they are the most used form for waste treatment. They use large areas of land where waste is deposited. However, they render various materials that could be recycled useless, as well as being a source of pollution of the soil, rivers and lakes and donating. The pollution is due to the process of decomposition of organic matter that generates huge amounts of biogas, which contains methane and other toxic components, and slurry, a liquid containing toxic components that flows from the waste to the soil and water bodies (such as rivers and lakes). region.

- Incinerators literally incinerate the waste, reducing it to ashes. They are highly polluting, generating huge amounts of pollutants such as gases that contribute to the aggravation of the greenhouse effect. It is the method used for the disposal of hospital waste, which may contain potentially fatal disease causing agents.

Composting is an aerobic treatment through which organic matter decomposes in compost or compost.

- Biogasification or methanization is an anaerobic decomposition treatment that generates biogas, which is made up of about 50% methane and can be burned or used as a fuel. The solid residue from biogasification can be aerobically treated to form compound.

- Permanent confinement is mainly destination of nuclear waste.

- Recycling is the process of reusing organic and inorganic waste material. It is considered the best method of waste treatment in relation to the environment, as it reduces the amount of waste sent to landfills, and reduces the need to extract more raw materials directly from nature. However, many materials cannot be recycled continuously (fibers in particular). Recycling of certain materials is feasible, but little or not practiced because it is economically unfeasible. Some forms of waste, in particular highly toxic waste, cannot be recycled and must be disposed of.

In searches carried out in the state of the art pertinent to the technical field of the invention (B09B 3/00, B65F 9/00 and B65F 1/14) we found several systems that deal with recycling, treatment, composting, storage and disposal of urban, industrial waste etc.

ZULAF document BRPI0.100.745 describes a selective collection system, implementation of a recycling center and waste disposal for sorting and processing of urban, rural, commercial, industrial and service waste, including health and sanitary and industrial landfills, recycling, waste sorting baling units, anaerobic composting units (optional) and aerobic composting, biogas recycling and thermal energy (optional), as well as dead animal cemetery, heat treatment of solid health waste and pre-treatment facilities. conditioning of waste for processing and disposal in landfills and treatment (or evaporation) of process and slurry wastewater.

Another waste recycling procedure is disclosed by ULIANA's BRPI9.402.243, which comprises a dump area in a manual waste disposal area, a wash area, and waste pickup trucks unload waste at the horizontal shorelines of the waste area. conveyed waste to a feeder coffin that feeds the inclined conveyor belts that carry the waste to a container (9) that will be diverted to the collection area, or into a large-capacity container and proper rational transport to the landfill in the storage area. garbage collection is carried by the conveyor belt from where the responsible staff separates the recyclable materials.

Also exemplary is BRPI 9.504.827 LIBARDI, where organic waste is transported by truck to landfill dumps, waste incinerators or composting plants, and inorganic waste is transported to one or more depots, with an inclined conveyor belt that launches it into the hopper. and where it will be launched on a main conveyor belt, with a plurality of short professional separate sewage disposal conveyor belts, said conveyor belts with selected refuse collection buckets, the unselected waste being disposed of in a bucket placed at the other end of the main conveyor belt.

Another document that deals with the process of treating industrial, urban and hospital waste through sorting, recycling, composting and incineration through a pyrolytic process is revealed by BRPI 9,816,124 by BENTO et alii, which presents the principle of waste incineration by the process called pyrolysis. , where waste itself is fuel from incinerators employed in the process, thus eliminating the need to create landfills.

It is also known the power generation plant from household solid waste transformation, described in BRPI 0.204.673; and DEBR 9,806,421, which describes an advanced waste processing plant.

Technique Problems

As can be seen from the prior art disclosed, all known solutions employ sorting, recycling, pyrolysis, composting and landfilling, with some variations. However, pyrolysis generates a large environmental impact due to the CO2 emission that only contributes to the increase of the greenhouse effect, and the other processes end up in undesirable sanitary landfills. Some processes revealed by art are harmful to the environment, such as burning of garbage or landfills. Composting is an advanced and far less environmentally friendly treatment where residual methane gas from anaerobic bacteria activity can be harnessed. However, in order to be able to use biogas, a confinement structure has to be built, generating an additional cost to the waste.

Waste confinement is performed only for nuclear and hospital waste due to the risk of nuclear and biological contamination. Nevertheless, this confinement is extremely expensive and permanent.

Thus, due to the considerations pertaining to the state of the art discussed above, it is one of the objectives of the present application to develop a composting and waste disposal system, where it employs the collection and compaction means described in documents Pl. 0.206.617 (Collector and coupled compact for household waste collection) and Pl 0.300.535 (Compacted waste compactor and bagger1 in general), and these two waste collection devices employ the packing of highly compacted waste in suitable high strength plastic bags. These plastic bags, then decompressed at high pressure, are sent to a suitable landfill.

Description of the figures

The characterization of the present proposed patent document is made by means of representative drawings of the final disposal system with compaction and pocketing, such that the proposed method can be fully reproduced by suitable technique, allowing full characterization of the functionality of the claimed object.

From the elaborated figures, which express the best way or preferential way of realizing the product now idealized, is based on the descriptive part of the report, through a detailed and consecutive numbering, which clarifies aspects that may be understood by the adopted representation, in order to clearly determine the protection now intended.

These figures are merely illustrative and may vary, provided they do not depart from the original claim.

In this case we have that: -Figure 1 illustrates a schematic representation of the plant of the waste disposal system with compaction and pocketing, without the application of recycling, consisting of two compactors fed by the same hopper (optional, individual hoppers), with estimated capacity for pocket up to 100 T / day. Another option is to employ only one compactor capable of pocketing up to 50 T / day;

Fig. 2 illustrates a schematic top view of the system disclosed in Fig. 1;

Figure 3 presents a schematic view of the proposed system, with compaction and pocketing, but with recycling process;

Figure 4 shows a plan of a landfill for the disposal of the pockets after the compaction step from one of the solutions proposed above;

Figure 5 shows in a perspective view the installation plan of the garbage packer without any unloading trucks.

Detailed Description of the Preferred Embodiment of the Invention

The proposed system comprises two solutions:

(a) The system without recycling consists of:

- A concrete ramp (1) for access of the truck that collected the axle in the homes, being dumped by a cargo portal (11);

- A metal or hopper (2) which receives the truck waste protected by an expanded sheet metal grating (4) and a hood (6) that demands the hopper's material for the compactor;

- Compactor (3 and 3a) that receives the garbage from the hopper, hopper (2), performs high pressure compaction (10,00 Kg / cm2) reducing the initial waste volume by more than four times through the compactor plate (7). which in turn is actuated by the hydraulic cylinder (8), and is subsequently pocketed in laminated and waterproof polypropylene pouches, with one or two pockets (5 and 5a) of adequate diameter and length, and closed by means of a

a hydraulic system (9) and the bag is demanded for the posterior opening, whose

The drive is performed by another hydraulic system (10).

(b) The recycled system consists of:

- A concrete ramp (12) for access of the truck that collected the garbage in the households;

- A first hopper (13) that receives the garbage from the truck;

- A conveyor belt (14) which receives the garbage from the first hopper and transfers it to a second conveyor belt;

- A second belt (15) mounted on a metal platform (16), where the pickers separate the value-added solid into specific carts (20);

- A second hopper / shredder (17) that receives waste from the second conveyor belt (organic waste);

- One compactor (18) for up to 50 T / day or two compactors for up to 100T / day, which receives the waste in containers (second hopper / shredder) and performs high pressure compaction (10.00 Kg / cm2) reducing the initial volume of waste more than four times and subsequently pocketing it in impermeable laminated polyethylene pouches (19) of adequate diameter and length. The bag is closed by means of a hydraulic system (9) and the bag is demanded by the opening of the rear door, which is activated by another hydraulic system (10).

Pocket system

The bags (5 and 5a) are produced in stationary compactors (3,3a or 18) that receive the organic material (without economic value) from the screening (15) and hopper (17) mats. The waste is compacted under high pressure and pocketed in waterproof laminated polypropylene pouches (19), the weight of which may vary from 120, 160 to 180g / cm2, depending on the type of waste to be refunded.

The garbage pocketed has no contact with air which prevents the spread of unpleasant odors, proliferation of insects and bacteria that produce many diseases. It is also not in contact with the rain, avoiding the formation of the slurry and the consequent contamination of the water table.

The compactor is equipped with a hydraulic device that allows the elaboration and replacement of the own bag refill, allowing in each refill the

elaboration of several scholarships.

The bags may vary in weight (with a predominance of organic waste) which may exceed 4.5 tonnes, but with a lot of mixed dry waste you may

reach from 3,5 to 4,0 tonnes.

Fully filled pouches store 5m3 of compacted garbage, so they can absorb up to 20m3 of natural garbage as their

compression can reach 4 to 1.

According to data from the bag fabric manufacturer, if they are covered (without contact with ultraviolet rays), it is 200 years old. However exposed to the sun, its duration is 6 months. If longer exposure to the sun is required, the fabric can be protected with anti-U.V layers.

The bags can be moved and / or transported conveniently and safely with the aid of a device specially designed for movement, coupled to a vehicle crane or the like.

FnRMA nF nESpOSITION OF CLEAR WASTE BAGS AND PORHECTARE STORAGE CAPACITY

Landfill in pouches can be done in three different ways:

- Negative. When the layers of pockets are below sun level, ie fully buried.

- Positive. When the layers of pockets are placed from the ground upwards, ie, no pockets buried.

- Semi positive. When part of the pockets are buried, and part above ground.Ex: In three layers of pockets, the first layer is below ground and the other two above ground.

For the purpose of calculation, let's consider a positive landfill, where the bags will be arranged side by side, with a maximum distance between pockets of 0.15 meters. Above the base, we are projecting two more pyramid-shaped bag heights, a total of approximately 5 meters in height. This way, we can store 6,318 bags or 31,590 tons in one hectare.

Considering the first layer of bag with 56 bags in one direction (with clearance) and 39 bags in the other direction (with clearance), we deposited a total of 2,184purses.

Similarly, we consider the second layer, forming a pyramid, 54 χ 39 = 2,106 pockets. Third layer, 52 χ 39 = 2,028 pockets. Total pockets deposited on one hectare = 6,318 pockets. In this way, approximately 31,590 tons of compacted waste can be stored in one hectare.

It is also usual to dig a ditch with a depth of 0.80 meters, which is half the diameter of the pocket (1.60 meters). The earth from davala is later used to cover the pockets of the last layer, thus avoiding the transport of covering earth.

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Claims (8)

1.- Final disposal system with compacting and repacking, characterized by the fact that it comprises two solutions: a) the system without recycling consists of: - a concrete ramp (1) for access of the truck that collected the waste in the households, being dumped by a cargo hatch (11); - a metal or hopper (2) which receives the garbage from the truck protected by an expanded sheet metal grating (4) and a hood (6) which demands the hopper material into the compactor; compactor (3 and 3a) receiving garbage from the hopper (2) compacts at high pressure (10.00 Kg / cm2) reducing the initial waste volume by more than four times through the compactor plate (7) which in turn it is actuated by the hydraulic cylinder (8), and is subsequently pocketed in laminated and impermeable polypropylene bags, with one or two bags (5 and 5a) with adequate diameter and length, being closed by means of a hydraulic system (9) and demanded by opening the rear door whose drive is performed by another hydraulic system (10), (b) the recycled system consists of: - a concrete ramp (12) for access by the truck that collected the rubbish in the households, - a first hopper (13) that receives the rubbish - a conveyor belt (14) which receives the waste from the first hopper and transfers it to a second conveyor belt (15) - a second conveyor belt (15) mounted on a metal platform (16) from which the pickers separate the valuable solid aggregate into specific trolleys (20) - a second hopper / shredder (17) which receives the waste from the second conveyor (organic waste) - a compactor (18) or two for 50T / day or 100T / day which receives (m ) the trash compacts at a high pressure (10.00 Kg / cm2) reducing the initial volume of the trash by more than four times and subsequently pocketing it in impermeable laminated polyethylene pouches (19), with adequate diameter and length, being the closure of the bag is performed by means of a hydraulic system (9) and the demanded by opening of the rear end, cujoacionamento is performed by another hydraulic system (10). 2.- Final disposal system with compacting and repayment. Claim 1 and characterized in that the bags are produced in stationary compactors (5, 5a or 18) and receive the organic material (without economic value) from the sorting mats (15). 3. The compacted and undercut end-destination system according to claim 2 and characterized by the fact that the high-pressure compacted lumpser is pocketed in the impermeable polypropylene pouches (19), the weight of which may vary depending on the type of rubbish. get pocketed. 4.- Ultimate flow destination system with compacting and repayment. according to claim 3 and characterized in that the waste garbage has no contact with air or rain. 5.- Final disposal system with compacting and refunding. according to claim 1 and characterized in that the compacting device is provided with a hydraulic device that allows the elaboration and reposition of the pouch refill itself, allowing in each refill the elaboration of several pouches. 6. Final disposal system with compacting and refunding according to claim 3 and characterized in that the pockets may vary in weight (with a predominance of organic waste) which may exceed 4.5 tonnes but with a lot of dry mixed waste. , could reach around 3.5 to 4.0 tons. 7. Final disposal system with compacting and repacking waste according to claim 1 and characterized in that the bags can be moved and / or transported in a practical and safe manner, with the aid of a device specially developed for their movement, coupled to a vehicle crane or the like. 8. The compacted and undercut end-flow system according to claim 1 and characterized in that the pouch earth can be realized in three different ways: - negative when the pouch layers are below sun level, or be fully buried: - positive, when the layers of pockets are placed from the ground upwards, ie no pockets buried; semi-positive, when part of the pockets are buried, and part above ground, for example, in three layers of pockets, the first layer is below ground and the other two above ground.