RU152299U1 - WASTE WASHER CONTAINER FOR WASTE CLEANING RESERVOIRS (OPTIONS) - Google Patents

Abstract

1. A container containing a frame in the form of a horizontal frame and a sheet of permeable material, freely spread over the frame with the formation of the open working volume of the container. The container according to claim 1, characterized in that the area of the expanded web exceeds the area of the frame by 30 ÷ 70%. 3. The container according to claim 1, characterized in that the edges of the canvas are made with rigging holes or loops. 4. A container containing a frame in the form of a frame for forming the outer part of the side walls, a web of permeable material for forming the bottom and the inner part of the side walls, a rigging network, the network being freely spread over the frame and the canvas covering the network at least within the frame. 5 . The container according to claim 4, characterized in that the area of the expanded web exceeds the area of the frame by 30–70%, and the network has an area of 90–110% of the area of the web.

Description

The utility model relates to devices for the treatment of wet waste in the field. This technical solution can be used, in particular, for the collection, storage and transportation of material obtained during the cleaning of surface water bodies mainly from plant mass, as well as from silty bottom soil.

Clearing water bodies and streams is accompanied by the formation of a significant amount of plant debris, in particular, reeds with inclusions of mud and silt. In practice, such garbage is first accumulated on the shore of a cleared water body, and upon reaching dehydration, the resulting material is taken out for disposal outside the work area directly in dump truck bodies or in large bags. However, collecting garbage ashore can lead to damage to the coastal strip, which is, for example, a sown lawn or a beach of clean sand, which in the future will require restoration of the territory.

There are two main options for dehydration:

a) in a natural way, for example, at silt sites;

b) using equipment for mechanical dehydration, in particular, mobile units with vacuum filters.

For works of a local nature or when cleaning small water bodies, silt sites and mechanical dewatering devices are not suitable due to the excessive complexity of the process. For dehydration of sapropel and bottom sludge, the method of geotubing using filter bags made of geotextile high-strength material (K. Bekchiev, Experience in using geotubes for dewatering sludge in the city of Chisinau // Water and Ecology: problems and solutions. 2011, No. 3, is becoming widely used. -4, p. 96-98). The difference of this technology is the ability to quickly erect a production site directly on the shore of the facility.

The closest analogue of the utility model is the container according to patent document US 20060102565 A, made of a permeable material. A disadvantage of the known device is its complex design, which makes it difficult, in particular, to quickly change the size of the working volume of the container based on specific conditions when clearing a pond.

The objective is to increase the processability of wet waste treatment in the field.

The technical result provided by this utility model is to simplify the design of the container.

The specified technical result is achieved due to the fact that in the first embodiment, the container comprises a frame in the form of a horizontal frame and a sheet of permeable material, freely spread over the frame with the formation of an open working volume of the container.

In a particular case, the area of the expanded web exceeds the area of the frame (the area limited by the frame) by 30–70%.

In another particular case, the edges of the web are made with rigging holes or loops.

Also, the technical result is achieved due to the fact that in the second embodiment, the container comprises a frame in the form of a frame for forming the outer part of the side walls, a web of permeable material for forming the bottom and the inner part of the side walls, a rigging network. Moreover, the network is freely spread over the frame, and the canvas covers the network at least within the boundaries of the frame.

In a particular case, the area of the expanded web exceeds the area of the frame by 30–70%, and the network has an area of 90–110% of the area of the web. The utility model is illustrated by the following drawings. FIG. 1: first container design option.

FIG. 2: illustration of waste loading using the inside of the container. FIG. 3: second container design option.

The implementation of the present utility model is illustrated by examples of preferred container implementations.

Example 1. The dewatering container for waste water cleansing ponds contains a frame 1 made of four plastic pipes 2 or similar wooden elements with a size of 150 ÷ 700 mm in cross section. The canvas 3 of a permeable geotextile material is spread freely over the frame 1, due to which it touches the soil inside the frame 1, forming the bottom of the container. The side walls of the container are formed by a part of the web 3 adjacent to the inner part of the frame 1, and the corresponding pipes 2. Thus, the container is characterized by its internal working volume 4, open at the top. The edges of the web 3 with rigging holes 5 are left outside the frame 1, forming outlets from all sides (Fig. 1).

At the beginning of the cleaning work, pipes 2 are laid directly on the soil of the coastal part of the reservoir, creating a closed loop of suitable shape and size. The ends of the pipes 2 are fastened together. On top of the frame 1 spread the web 3, forming the working volume 4 of the container. In the process of clearing the pond, the plant mass, mud and silty soil are loaded from above into the container. After filling the container, leave it for gravitational dehydration of the contents on lines from several days to several months. After the mass becomes substantially dehydrated and dried, grab the canvas 3 by the lifting holes 5 and transfer the waste directly with the truck crane to the canvas 3, which has taken the shape of a bag (Fig. 2), into the truck body for transportation to the place of unloading, temporary storage and disposal . Frame 1 is reused at the same place or pipes 2 are disassembled and moved to a new place where the container is required. The released web 3 can be reused.

Due to the fact that the container is made only of a frame in the form of a horizontal frame and a web of permeable material freely spread over the frame with the formation of an open working volume of the container, the container design is maximally simplified, which increases the manufacturability of wet waste in the field. In particular, a simple design allows you to quickly adapt the shape and size of the container to specific conditions on the shore of the cleared reservoir. In addition, they get a wide open top tank, into which it is easy to unload the waste of plant origin, resulting from clearing hydrotechnical work, thus filling the container without additional grinding waste. Also, thanks to this design, it is possible to easily load the waste for its further transportation, and the dewatering of the waste in the container is accelerated due to the action of direct irradiation of the waste with sunlight and blowing it with air.

The simple design of the container does not imply the use of connecting elements for fastening the web 3 and frame 1. Therefore, to prevent accidental slipping of the edges of the web 3 into the frame 1 when filling the container with waste, the outlets of the web 3 should be left from all sides outside the frame 1. It is advisable to proceed from the condition so that the area of the expanded web 3 exceeds the area of the frame 1 by 30 ÷ 70%.

The implementation of the edges of the canvas 3 with rigging holes 5 or loops simplifies the conversion of the container into a bag when loading waste for their further transportation.

Example 2. The main difference in this design from that presented in example 1 is that the container contains a rigging network 6, freely spread over the frame 1, while the web 3 covers the network 6, protruding beyond the boundaries of the frame 1. In addition, in FIG. . Figure 3 shows an alternative connection of pipes 2 to give the container a larger working volume 4.

The rigging network 6 makes it possible to simplify the design of the container by eliminating the need to use a high-strength canvas 3 if the container is placed partially overhanging on the unevenness of the site, for example, due to the installation of drainage ditches, over which waste having a large weight can break through the usual canvas 3 if there is no network 6 . Also, in the absence of a network 6, waste can break through the usual canvas 3 in the central part of the bag or in the region of holes 5 during loading. The hooks of the lifting device can be conveniently hooked onto the ropes of the extreme cells of the network 6, which makes rigging holes 5 or loops unnecessary. The area of the network 6 is selected from the condition 904 ÷ 110% of the area of the web 3, to provide easy access to the extreme cells of the network 6.

The process of constructing a container according to this utility model is as simple as possible, and the collection of plant waste is effective in the absence of damage to the coastal strip.

Claims (5)

1. A container containing a frame in the form of a horizontal frame and a sheet of permeable material, freely spread over the frame with the formation of an open working volume of the container. 2. The container according to claim 1, characterized in that the area of the expanded web exceeds the area of the frame by 30–70%. 3. The container according to claim 1, characterized in that the edges of the canvas are made with rigging holes or loops. 4. A container comprising a frame in the form of a frame for forming the outer part of the side walls, a web of permeable material for forming the bottom and the inner part of the side walls, a rigging network, the network being freely spread over the frame, and the canvas covering the network at least within the frame . 5. The container according to claim 4, characterized in that the area of the expanded web exceeds the area of the frame by 30–70%, and the network has an area of 90–110% of the area of the web.

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