RU233461U1 - GARBAGE TRAP FOR CLEANING WASTE WATER BY SEDIMENTATION OF PARTICLES - Google Patents

Abstract

The utility model relates to equipment for cleaning wastewater entering a sewerage system. A garbage collector for cleaning wastewater from contaminants that precipitate comprises a tank, the body of which is formed by a bottom and side walls connected to it. Inside the tank, an internal chamber is installed, configured to be extractable, open at the top, containing a bottom and side walls connected to it. The upper part of the internal chamber is provided with support elements on the outside, resting on the corresponding support elements with which the upper part of the tank is provided. Through holes are made in the upper half of the side wall of the internal chamber. A lid is installed on top of the tank body with the possibility of fixing it outside the side walls of the tank. The lid is removable and closes the tank with the internal chamber installed in it. An inlet pipe is installed in the lid, namely in that part of it that is located above the internal chamber. The outlet part of the inlet pipe is located in the cavity of the internal chamber. An outlet pipe is installed in the side wall of the tank body. The technical result is a simplification of the process of cleaning the device from accumulated contaminants. 9 cl., 4 fig.

Description

The utility model relates to water purification equipment, in particular, for cleaning domestic wastewater from dense particles that form bottom sediment, and can be used in the development of the design of garbage collectors used in hairdressing salons, households, hotels, laundries, canteens, cafes, restaurants, etc., for cleaning wastewater entering the sewerage system.

Currently, garbage traps are widely used to protect the sewer system from dense particles (whose specific gravity is greater than the specific gravity of water), such as sand, starch and other debris that form bottom sediment, entering it with household wastewater, as well as from light floating particles (whose specific gravity is less than the specific gravity of water), such as fat and oils that form an oil-fat layer.

Garbage traps can be used to clean wastewater entering the sewer system, for example, from a sink, washing machine, dishwasher, etc. Garbage traps are most often used to clean wastewater entering the sewer system from a sink. Garbage traps are usually installed directly under the sink. The inlet pipe of the garbage trap is connected through a supply pipe to the sink drain, and the outlet pipe is connected to the sewer system.

It should be noted that, as practice shows, in household wastewater (for example, from catering establishments, hairdressers, private homes, etc.) one type of contaminant often predominates: these are either light components that float to the surface, or heavy ones that settle to the bottom of the inclusion. In this regard, many companies specializing in the production of garbage collectors offer separate lines of their products taking into account a specific type of contaminant, for example, for catching contaminants that precipitate (often this type of device is called "sand traps").

It should be noted that both settling and floating contaminants within their type may differ in density (i.e. some are lighter, others are heavier), which may require ensuring a higher or lower speed (intensity) of the purified wastewater outflow. The customer may reflect such a requirement separately, in a specific assignment.

At a lower rate of wastewater outflow from the collection chamber, dense particles with a lower density will have time to settle to the bottom in greater quantities (since their time in the collection chamber will increase). The same can be said about floating particles - during a longer time in the chamber, a greater number of light particles with a higher density will have time to rise to the surface. Thus, a lower rate of wastewater outflow from the collection chamber will contribute to improving the quality of wastewater treatment. However, it should be noted that this will reduce the throughput of the garbage collector. Various solutions are possible in the design of the collection chamber to ensure a lower rate of wastewater outflow, in particular, this can be a decrease in the size (diameter) of the holes, a decrease in the number of holes for wastewater outflow, making holes in a smaller number of chamber walls, etc.

There are also opposite cases, when the design priority is to ensure a higher flow rate.

Thus, when developing a waste collector, many factors are taken into account in order to ensure an optimal ratio of parameters that determine the quality of wastewater treatment (the rate of inflow and outflow of wastewater, the diameter of the inlet and outlet pipes, the volume of the tank and/or collection chamber, etc.).

An urgent task in developing new designs of garbage collectors is to ensure the efficiency of the device, as well as its operational reliability. In addition, it should be noted that an important factor is the technological (simplicity) of servicing the device during operation, including when cleaning the device from accumulated contaminants, which must be done periodically in order to ensure the suitability of the device for further use.

It is known to use absorption filters (adsorbents) to filter various types of contaminants, for example, according to patent No. CN116695560 [“Bridge floor rainwater treatment device”, IPC C02F1/00, E03F5/142, published date 09/05/2023]. However, due to the constant saturation of the filter material, there is a constant gradual decrease in the filter efficiency (neutralization of contaminants), which requires frequent filter replacement and causes high cleaning costs.

A design of a device for separating solid particles from waste water is known [patent No. RU2630546C2 "Waste Water Treatment Plant", IPC B01D21/02, C02F1/52, E03F5/14, published date 11.09.2017]. The separation equipment contains an inlet means and an outlet means, which are essentially located along a common horizontal guide line. Between the inlet means and the outlet means, hydrodynamic wing-shaped profiles are made, forming two selective flow channels, in one of which the smallest particles are separated, and in the other - larger ones. Particles are separated during the passage of a liquid-flowing medium and settle to the bottom in a collecting bin. However, this technical solution is characterized by high design complexity and increased dimensions due to the implementation of two flow channels.

Waste collectors are widely used to clean wastewater from pollutants that precipitate, in which the sedimentation and accumulation of heavy particles occurs in the compartments of the device body formed between the partitions or in separate collection tanks installed inside the body.

A known design of a garbage collector [patent No. RU 222167 U1 "Installation for separating grease from wastewater", IPC C02F 1/40, B01D17/02, published date 13.12.2023] is intended for use in the sewerage networks of restaurants, cafes, private houses and connected through an inlet pipe to the sink drain, and through an outlet pipe to the sewer network. The technical solution under consideration uses a mesh container to retain solid waste from incoming wastewater. When removing the container, it is quick and easy to clean. However, as a disadvantage of the known design, it should be noted that the wastewater treatment efficiency is extremely low, since all the walls and bottom of the container are made of mesh, as a result of which fine sand or other particles smaller than the mesh cell size cannot be retained in the container.

A device is known according to patent No. EP4286027A ["Hydrodinamic separator", IPC B01D 21/00, C02F 1/38, E03F 5/14, published date 06.12.2023], which is a tank containing a housing and a removable cover installed on top. Inlet and outlet pipes are installed in the end walls of the housing. Inside the housing there is a horizontal dividing plate with a central hole, which divides the tank cavity into upper and lower chambers. In the upper chamber, a central chamber is formed, trapping floating particles, and in the lower chamber, heavy contaminants settle, forming a sediment. However, as a disadvantage of the known technical solution, it should be noted that the lower chamber is difficult to access during the cleaning of the garbage collector to remove bottom sediment.

A design of a sand trap is known [web page address: [https://polyfacture.ru/catalog/musorosborniki/?ysclid=lu9pldukkg374564952], designed to purify water contaminated during cleaning of premises before discharging it into the general sewer network. The equipment is a polypropylene tank with a dirt collector placed in it, which is a separate trap chamber (container), which is mounted on limiting plates that prevent the chamber from immersing in water filling the tank cavity. Two opposite walls of the removable trap chamber are perforated over the entire surface (hole diameter less than 2 mm). The tank is closed with a lid from above. After cleaning the room, the tank lid is opened and contaminated water from the bucket is manually drained into the trap chamber (dirt collector), where water flows through the holes into the tank cavity, and debris larger than 2 mm is retained in the chamber. After that, the water enters the sewerage system through the outlet pipe installed in the side wall and connected to the sewer pipe. To clean the catcher chamber from the retained waste, open the tank lid, remove the chamber and clean it, then install the clean chamber back into the tank and close the lid. The disadvantage of the known design is that the chamber is filled with contaminated waste manually (which is not technologically feasible), and also that only waste larger than the perforation holes is retained in the chamber, as a result of which sand and other small dense particles get into the sewerage system, which can lead to blockages.

As a technical solution (prototype) closest to the claimed utility model, a chamber (sludge trap) for cleaning wastewater from contaminants that precipitate is proposed, which is part of a wastewater treatment device that ensures the purification of wastewater from heavy particles and floating contaminants [patent No. DE4119154A1 "Device for treating wastewater, comprises sludge trap chamber for collecting sludge and solids contained in the wastewater, filter chamber for collecting floats and immiscible light liquids, inlet, outlet and coalescence filter box", IPC B01D17/00, C02F1/40, E03F5/16, published date 02.01.1992]. The device contains two chambers (reservoirs), one of which is designed to trap sediment, the other - to trap floating contaminants. The chambers are made in separate housings connected to each other by a pipeline. The body of each chamber contains a bottom and two end and two longitudinal walls connected to it. Inlet and outlet openings are made in the end walls opposite each other, in which the inlet and outlet pipes are installed, respectively. The body is closed from above with a lid having a hatch, which is closed from above with its own lid. Within the framework of the description of the claimed technical solution, the first chamber will be considered - a sediment trapping chamber. Wastewater enters the chamber (reservoir) through an inlet opening made in the end wall. Inside the body, between the inlet opening and the outlet opening, a sediment trapping unit is provided, which is made in the form of a vertical dividing plate made of sheet material, installed in the transverse direction and adjacent to the longitudinal walls of the body with its side edges. The lower edge of the plate adjoins the bottom of the body. When the device (garbage trap) is functioning, the upper edge of the plate should be located above the level of the liquid filling the chamber. The lower part of the plate is made solid (not allowing flow), and in the upper part there are through holes. The lower part of the separating plate does not allow heavy particles contained in the flow to pass beyond the plate boundary, and they settle on the bottom of the housing in the area between the end wall, in which the inlet hole is made, and the separating plate, and the waste water, purified from settled particles, passes further through the holes in the upper part of the separating plate to the outlet and flows out into the discharge pipeline.

With regard to the disadvantages of the known technical solution, it is necessary to note the complexity of the cleaning (maintenance) process of the garbage collector from accumulated contaminants, which must be periodically performed in order to ensure the normal functioning of the device, while in the known design it is necessary to clean the entire cavity of the tank, including hard-to-reach areas, as well as the surfaces of the dividing plate. In addition, to provide access to the cavity of the tank, it is first necessary to disconnect the inlet and outlet pipes, and then remove the garbage collector from under the sink, clean it, and then install it under the sink again and connect the pipes. With repeated disconnection and connection of pipes, mechanical damage may occur at the joints, which can lead to leaks, and therefore reduce the reliability of the device as a whole. In addition, with the lateral supply of wastewater, sedimentation and accumulation of particles of contaminants occurs inside the supply pipe and in the inlet pipe, as a result of which, as practice has shown, the efficiency of wastewater treatment decreases.

The technical result, the achievement of which is ensured by the claimed utility model, is the simplification of the process of cleaning the device from accumulated contaminants (i.e. simplification of the maintenance of the garbage collector).

In order to achieve the above technical result, a waste collector for cleaning wastewater from contaminants that precipitate is proposed, comprising a tank, the body of which is formed by a bottom and side walls connected to it. Inside the tank, an internal chamber with the possibility of its removal is installed, containing a bottom and side walls connected to it. The internal chamber is made open at the top. Through holes are made in the upper half of the side wall of the internal chamber. A cover is installed on top of the tank body, made removable and closing the tank with the internal chamber installed in it. In the cover, namely in that part of it that is located above the internal chamber, an inlet pipe is installed in such a way that the outlet part of the inlet pipe is located in the cavity of the internal chamber. An outlet pipe is installed in the side wall of the tank body.

The garbage collector is made in the form of a tank closed with a lid.

The bottom of the tank body and the side walls connected to it limit the volume of the tank.

The inlet pipe is required to supply wastewater containing contaminants to the waste collector, and the outlet pipe is required to discharge already purified wastewater into the sewer system.

The internal chamber, installed inside the tank with the possibility of its extraction, is designed to receive incoming wastewater and capture contaminants, namely, particles that form sediment, the specific gravity of which is greater than the specific gravity of water (i.e. heavy particles). The volume of the internal chamber is limited by its bottom and side walls. The possibility of extracting the internal chamber from the tank with its subsequent installation back ensures the technological effectiveness (simplicity) of the process of cleaning the chamber from accumulated contaminants.

A removable cover installed on top of the tank body closes (limits) the tank cavity and the internal chamber, while providing access to the chamber for its removal from the tank. The ability to remove the internal chamber from the tank and then install it back ensures the technological process of cleaning the chamber from accumulated contaminants.

The design of the inner chamber open at the top, as well as the installation of a removable cover that closes the cavity of the tank and the inner chamber, allows the inlet pipe to be brought from the top directly into the cavity of the chamber through the part of the cover that is located above the chamber, which eliminates the need to disconnect the inlet pipe when cleaning the chamber from accumulated contaminants (since when the cover is removed, the outlet part of the inlet pipe is no longer inside the cavity of the chamber), thereby simplifying the cleaning of the device. In addition, when feeding wastewater from above during the operation of the garbage collector, the stagnation of garbage in the supply pipe and inlet pipe is reduced, which ensures the efficiency of the garbage collector.

The holes in the inner chamber are necessary for the outflow of purified wastewater from the inner chamber into the cavity of the tank for subsequent discharge into the sewerage system. The holes located in the upper part (in the upper half) of the side wall of the chamber are made because the contaminants, for the capture of which the claimed garbage collector is intended, are particles whose specific gravity is greater than the specific gravity of water, as a result of which these particles settle and form a bottom sediment, which is retained by the lower solid part of the wall, and the upper part of the mass of wastewater filling the inner chamber, already purified from these contaminants, flows (being displaced by new wastewater entering the chamber) through the holes in the side wall of the chamber into the cavity of the tank.

The author conducted experimental studies of the quality of wastewater treatment when making through holes in sections of the side wall of the chamber, having different lengths along the wall height and located at different distances from the lower (or, respectively, upper) edge of the wall. It is advisable to set the position of the holes in relation to the upper or lower edge of the wall, since in general the contaminants either settle down or rise to the surface, therefore it is the height of the holes that is of significant importance, and no special requirements are imposed on their location along the width of the wall (i.e. in relation to the side edges of the wall). Individual restrictions may be due, for example, to specific design features of the garbage collector (chamber or tank).

In general, the preservation of the strength characteristics of the wall is taken into account, and the required throughput of the garbage collector, the intensity of the flow of waste water and a number of other requirements can also be taken into account. The openings located near the edges of the wall are made in such a way that they do not pierce the edge of the wall, and at the same time, a strip of material remains between the boundary points of the openings and the edge of the wall, which would not worsen the strength characteristics of the entire side wall. This is usually verified by engineering calculations or experimentally. In addition, it should be noted that the openings are made in a group, the location of which fits into the boundaries of a certain section of the wall, therefore, when talking about the location of the openings (in particular, relative to any edge of the wall), they mean the location of the section within the boundaries of which these openings are made.

The author conducted experimental studies of prototype waste collectors in order to determine the quality of wastewater treatment depending on the design (location) of the through holes in the inner chamber for the outlet of purified wastewater. Groups of samples were studied with holes made in sections of different lengths and different locations along the wall height - for each wall of the inner chamber. In each group, the holes in the side wall of the inner chamber were made in sections of different lengths in the vertical direction: 10%, 20%, 30%, 40%, 50% of the wall height. In this case, for each section length, samples were made with different locations of this section along the entire height of the side wall of the inner chamber: starting from the location of the section at the upper edge of the side wall and up to its location at the lower edge of the side wall. The change in the position of each section was performed in increments of 5% (for a section length of 10% and 20%) to 10% (for a section length of 30%, 40% and 50%) of the wall height.

As a result of the conducted experimental studies, it was confirmed that by making through holes in the upper half of any of the side walls of the inner chamber, the quality of wastewater purification from dense particles that form bottom sediment will be ensured in accordance with the requirements of regulatory documents (in particular, the "Rules for Cold Water Supply and Sanitation", approved by RF Government Resolution No. 644 of 29.07.2013 (as amended on 28.11.2023), Appendix 5 "List of maximum permissible values of regulatory indicators of general properties of wastewater and concentrations of pollutants in wastewater established in order to prevent negative impact on the operation of centralized wastewater disposal systems").

Thus, the claimed device (garbage trap), which, unlike the prototype, contains an internal chamber installed inside the tank with the possibility of its removal, given that the chamber is made open at the top, and in the removable cover covering the tank and the internal chamber, an inlet pipe is installed, which is fed into the cavity of the internal chamber through the part of the cover located above the internal chamber, provides, in comparison with the prototype (in which a separating plate with holes is fixed inside the tank, installed in the transverse direction, the edges of which are attached to the longitudinal walls and the bottom of the tank body, while the lateral supply of wastewater into the tank is implemented), a simplification of the process of cleaning the garbage trap from accumulated contaminants, i.e. simplification of the maintenance of the garbage trap.

The most technologically advanced design is a removable cover with the ability to secure it outside the side walls of the tank, in particular, using latches. In addition, fixing the cover position using latches is the simplest and most reliable when installing the cover and allows you to quickly remove the cover when cleaning the garbage collector.

The inlet pipe, the outlet part of which is fed directly into the inner chamber, can be made vertically oriented, which ensures the least amount of debris settling in the supply (drain) pipe and in the inlet pipe during operation of the garbage collector, which is confirmed by the results of experimental studies conducted by the author.

The inlet and outlet pipes can be installed with a seal, for example, with a sealing cuff, at the place of their connection - respectively with the cover and the side wall of the tank, which allows to exclude the outflow of wastewater through the places of connection of the pipes with the walls of the housing and with the cover. It should be noted that other design implementations of connections are possible, for example, a connection in which the outlet pipe is welded into the side wall. However, the implementation with a sealing cuff is more technologically advanced, since it provides a high degree of tightness (insulation) and allows to make the connection detachable, which is necessary, for example, when cleaning the garbage collector.

In order to improve the dynamics (increase the intensity) of the outflow of purified wastewater, the outlet pipe can be installed in such a way that its inlet part is located below the end of the outlet part of the inlet pipe (i.e. the outlet pipe is installed closer to the bottom than the inlet pipe).

The most technologically advanced design of the inner chamber is one in which its bottom is rectangular and the side walls connected to the bottom are vertically oriented. In this case, the inner chamber can be installed inside the tank in such a way that its bottom and side walls do not touch the side walls and bottom of the tank, which will improve the circulation of wastewater inside the tank and avoid the appearance of stagnant zones.

For the most convenient and technological installation of the inner chamber (with the possibility of its simplest extraction from the tank when cleaning the garbage collector and subsequent installation of the chamber in the tank), the tank can be equipped in the upper part with horizontally oriented plate elements adjacent to the side walls of the tank. Between the plate elements there is a gap in which the inner chamber is located. Outside the inner chamber, along the upper edges of its side walls, there are flanges by which the inner chamber rests on the free edges of the plate elements.

In order to ensure simplicity and technological effectiveness of the garbage collector assembly, as well as to ensure the best dynamics of the purified wastewater discharged into the sewerage system, the inner chamber can be installed inside the tank in such a way that its side walls are oriented parallel to the side walls of the tank body, and the through holes are made in the side wall of the inner chamber that is most distant from the inlet part of the outlet pipe. In this case, the optimal design of the holes in the side wall of the inner chamber from the point of view of the quality of wastewater treatment, ensuring sufficient throughput capacity of the garbage collector, and performing technological operations (perforating) is such a design of the holes in the side wall of the inner chamber, in which they are made in a section limited by the upper edge of the said side wall and its lower boundary, located from the bottom of the inner chamber at a distance equal to 2/3 of the height of the said side wall. When conducting (as described earlier) experimental studies of the quality of wastewater treatment depending on the design of the holes in the inner chamber, four groups of prototypes were examined. In each group of experimental samples, the holes were made (as described above) in one of the four walls of the inner chamber. It was found that the best indicators of wastewater treatment quality (all other things being equal) are demonstrated by the samples of the group in which the holes were made in the side wall of the inner chamber located opposite the inlet part of the outlet pipe and the farthest from it. In this case, the best efficiency of the device (with an optimal combination of wastewater treatment quality, device throughput, tank and chamber volume, labor costs and other indicators) occurs when the holes are made in a section of the wall limited by the upper edge of this wall and its lower boundary, located from the bottom of the inner chamber at a distance equal to 2/3 of the height of the said side wall. Here, it should be noted that, as the results of experimental studies have shown, a decrease in the length of the perforated section along the height of the side wall will not worsen the quality of wastewater treatment, but will reduce the throughput of the garbage collector. The presence of individual particles of contaminants in the discharged purified wastewater may be due to random turbulence of the flow.

The graphic materials contain an example of a specific implementation of the claimed technical solution.

Fig. 1 shows a schematic representation of a garbage collector, main view, section.

Fig. 2 shows a schematic representation of a garbage collector (with a lid), front view.

Fig. 3 shows a schematic representation of a garbage collector (without a cover), view from above.

Fig. 4 shows section A-A of Fig. 2.

List of positions:

1 - tank;

2 - bottom of the tank body;

3,4. 5, 6 - side walls of the tank body;

7 - inner chamber;

8 - bottom of the inner chamber;

9,10, 11,12 - side walls of the inner chamber;

13, 14 - horizontal plates;

15 - flanges along the upper edges of the walls of the inner chamber;

16 - removable cover;

17 - latches;

18 - inlet pipe;

19 - outlet part of the inlet pipe;

20 - sealing cuff of the inlet pipe;

21 - outlet pipe;

22 - inlet part of the outlet pipe;

23 - sealing cuff of the outlet pipe;

24 - through holes;

S - section of the side wall on which holes are made;

H is the distance from the bottom of the inner chamber to the lower boundary of section S;

L - height of the side wall.

The garbage collector is designed for use, for example, in canteens, cafes, restaurants, hairdressers, private homes, and allows you to separate the contaminants contained in household wastewater that form bottom sediment, in order to prevent them from entering the sewer pipes and causing blockages.

The garbage collector contains a tank 1, the body of which is formed by a rectangular bottom 2 and vertical side walls 3, 4, 5, 6 connected to it.

An internal chamber 7 is installed inside the tank 1, which also contains a rectangular bottom 8 and vertical side walls 9, 10, 11, 12 connected to it, i.e. the internal chamber (like the body of the tank 1) is made in the form of a rectangular parallelepiped. Chamber 7 is made open at the top.

The inner chamber 7 can be installed in the tank 1, for example, as follows.

In the upper part, the tank 1 is provided with two horizontal plates 13, 14, located opposite each other. Each of the plates 13, 14 adjoins the upper edges of the side walls along three of its sides: plate 13 - to walls 3, 4, 6, and plate 14 - to walls 4, 5, 6. The plates do not join each other, there is a gap between them (a separate position is not indicated), intended for placing the inner chamber 7. Outside the inner chamber 7, along the upper edges of the side walls 9-12, there are flanges 15 (for example, along the entire perimeter of the upper part of the chamber 7), with which the chamber rests on the (free) edges of the plates 13, 14 facing it, as well as on the sections of the edges of the walls 4, 6 located between the plates 13, 14. The installation of the chamber 7 inside the tank 1, in which the flanges 15 of the chamber rest on the elements of the body of the tank 1, provides the possibility of easily removing the chamber from the tank and reinstalling it back. The distance between plates 13 and 14 should provide the possibility of installing the inner chamber 7 in the space between the plates. The overall dimensions of chamber 7 are such that when it is installed, the bottom 8 of chamber 7 does not come into contact with the bottom 2 of tank 1, and the walls 9-12 of chamber 7 do not come into contact with the walls 3-6 of tank 1 body, respectively. In this case, the side walls 9-12 of chamber 7 are oriented parallel to the side walls 3-6 of tank 1 body. Such an arrangement of the inner chamber inside the tank allows (as noted above) to ensure optimal flow hydrodynamics and avoid the formation of stagnant zones.

A removable cover 16 is installed on top, which covers the reservoir 1 and the internal chamber 7 installed in it, thereby providing easy access to the chamber. The position of the cover 16 is fixed with four latches 17.

In the cover 16, in the section located above the inner chamber 7, there is an opening into which the inlet pipe 18 is inserted from above. The inlet part (not designated as a separate item) of the inlet pipe 18 is located outside the tank and is intended for connection to the sink drain via the supply pipe (not shown in the Fig.). The outlet part 19 of the inlet pipe 18 is located in the cavity of the inner chamber 7. Such an installation of the inlet pipe 18 facilitates the extraction of the chamber 7 with the cover 16 removed. The inlet pipe 18 is located vertically. It should be noted that the location of the inlet pipe (as well as the supply pipe) can be inclined, but minimal accumulation of sediment in the supply pipe and the inlet pipe (as shown by the results of experiments conducted by the author) is ensured with a vertical location of the inlet pipe, i.e. when feeding the wastewater vertically from above.

To seal the junction of the inlet pipe 18 and cover 16, a sealing cuff 20 is installed.

In the side wall 5 of the body of the tank 1 there is an opening in which the outlet branch pipe 21 is installed. The inlet part 22 of the outlet branch pipe 21 is located in the cavity of the tank 1 (between the side wall 5 of the tank 1 and the side wall 11 of the internal chamber 7) and is located below the end of the outlet part 19 of the inlet branch pipe 18, which facilitates a more intensive outflow of purified wastewater through the outlet branch pipe. The outlet part (not designated as a separate item) of the outlet branch pipe 21 is located outside the tank and is intended for connection to the sewerage system.

To seal the junction of the outlet pipe 21 and the side wall 5 of the tank body 1, a sealing cuff 23 is installed.

The installation of sealing cuffs in the places where the pipes are cut in ensures a high degree of sealing (insulation) of the connection, preventing leaks, and also, if necessary, allows the connection to be disassembled and reassembled.

In the side wall 9 of the internal chamber 7 located opposite the outlet pipe 21 and furthest from its inlet part 22, through holes 24 are made, intended for the exit of purified wastewater from the internal chamber into the cavity of the tank. In the presented example of the garbage collector, the openings 24 are made in the upper half of the wall 9, namely, in the section S of the wall, which is located between the upper edge of the side wall 9 and its lower boundary, located from the bottom 8 of the internal chamber 7 (from the lower edge of the wall 9) at a distance H equal to 2/3 of the height L of the side wall 9. During operation of the garbage collector, heavy particles of contaminants, whose specific gravity is greater than the specific gravity of water, will settle on the bottom of the chamber 7 and be retained by the solid (lower) section of the wall 9, as well as by other side walls (10-12) of the chamber 7, which are made without openings, while the purified flow will flow into the cavity of the reservoir 1 and then through the outlet pipe 21 will be discharged into the sewer system.

The number of holes, their diameter (size), and location are determined experimentally for a specific design of the garbage collector, taking into account the capacity of the device. In practice, they often proceed from the empirical relationship, according to which the total area of the holes S _otv should be from 100% to 200% of the cross-sectional area of the inlet pipe S _in (S _in ≤S _otv ≤2S _in ), since in practice it has been found that with S _otv ≤S _in , the internal chamber will overflow with incoming wastewater, and with S _otv ≥2S _in, the incoming wastewater will flow through the holes at a high speed, without having time to be cleaned. In this case, the parameters of the holes are usually subject to adjustment based on the results of testing prototypes.

The elements of the garbage collector (tank body, inner chamber, cover) can be made of a polymer material, for example, linear low-pressure polyethylene by rotational molding. The inlet and outlet pipes can be made, for example, of PVC. The sealing cuffs can be made, for example, of rubber or silicone.

The operation of the claimed device is carried out as follows.

The garbage collector is installed under the sink. The inlet part of the inlet pipe 18 is connected to the sink drain through the supply pipe. The outlet part of the outlet pipe 21 is connected to the sewer system pipe.

The wastewater containing particles of contaminants whose specific gravity is greater than the specific gravity of water flows from the sink drain through the supply pipe into the inlet pipe 18, the outlet part 19 of which is led into the cavity of the inner chamber 7. The design of the inlet pipe 18 as described above ensures the upper vertical supply of wastewater into the inner chamber 7.

The wastewater containing contaminants fills the inner chamber 7.

In the inner chamber 7, heavy particles of contaminants (sand, starch, small food waste, etc.) settle to the bottom 8 of the chamber 7 and remain there, held by the solid side walls 10-12, as well as the lower solid part of the wall 9. The purified wastewater flows through the openings 24 made in the upper half of the side wall 9, and fills the space (the cavity of the tank) between the side walls 9-12 of the inner chamber 7 and the side walls 3-6 of the tank body 1, as well as between the bottom 8 of the inner chamber 7 and the bottom 2 of the tank body 1, from where it enters the inlet part 22 of the outlet pipe 21 (located lower than the outlet part of the inlet pipe) and is then discharged through the outlet pipe 21 into the sewer system.

During the operation of the garbage collector, the collected contaminants accumulate in the internal chamber 7 - at the bottom 8 of the chamber 7, the settled particles of contaminants form a bottom sediment. In this regard, to ensure the operability of the garbage collector, it is necessary to periodically clean it from accumulated contaminants.

Cleaning of chamber 7 is performed with cover 16 removed. The supply of waste water is shut off, then, after releasing latches 17, cover 16 is removed from the body of tank 1 (the inlet pipe remains connected to the cover and does not interfere with the removal of chamber 7) and chamber 7 is removed, simply holding it by flanges 15. Then the sediment is removed from chamber 7. After all the contaminants have been removed, chamber 7 is again installed in tank 1 (the chamber rests with its flanges on the elements of the tank body) and cover 16 is closed, fixing its position with latches 17, the inlet pipe is then inserted into the cavity of the inner chamber. The garbage collector is again ready for operation.

Thus, the proposed design of the garbage collector ensures simplicity and technological efficiency of the process of cleaning the device from accumulated contaminants (i.e. simplification of the garbage collector maintenance) during its operation, which allows avoiding possible mechanical damage to the device and thereby increasing the reliability and efficiency of its operation.

In addition, it should be noted that the implementation of the inlet pipe connection through the cover directly into the inner chamber allows for only one connection of the inlet pipe requiring sealing (the “cover - inlet pipe” connection), which reduces the risk of leaks and increases the reliability of the device.

It is also worth noting that the vertical supply of wastewater into the internal chamber allows, during operation of the garbage collector, to almost completely eliminate the stagnation of waste in the supply pipe and inlet pipe, which increases the throughput capacity of the device and the efficiency of its operation.

Claims (10)

1. A waste collector for cleaning wastewater from contaminants that precipitate, characterized in that it contains a tank, the body of which is formed by a bottom and side walls connected to it, an internal chamber with the possibility of its removal is installed inside the tank, the internal chamber contains a bottom and side walls connected to it and is made open at the top, wherein the upper part of the internal chamber is provided with support elements on the outside, which rest on the corresponding support elements with which the upper part of the tank is provided, through holes are made in the upper half of the side wall of the internal chamber, a lid is installed on top of the tank body with the possibility of fixing it outside the side walls of the tank, wherein the lid is made removable and closes the tank with the internal chamber installed in it, an inlet pipe is installed in the lid, namely in that part of it that is located above the internal chamber, wherein the outlet part of the inlet pipe is located in the cavity of the internal chamber, an outlet pipe is installed in the side wall of the tank body. 2. A garbage collector according to item 1, characterized in that the possibility of securing the lid on the outside of the side walls of the tank is ensured by means of latches. 3. A garbage collector according to item 1, characterized in that the inlet pipe is vertically oriented. 4. A garbage collector according to item 1, characterized in that the inlet pipe is installed with a seal at the place where it connects to the cover, and the outlet pipe is also installed with a seal at the place where it connects to the side wall of the tank. 5. A garbage collector according to item 1, characterized in that the outlet pipe is installed in such a way that its inlet part is located below the end of the outlet part of the inlet pipe. 6. A garbage collector according to item 1, characterized in that the bottom of the inner chamber is rectangular in shape, and the side walls connected to it are vertically oriented. 7. A garbage collector according to paragraph 1, characterized in that the internal chamber is installed inside the tank in such a way that its bottom and side walls do not come into contact with the bottom and side walls of the tank. 8. A garbage collector according to item 1, characterized in that the support elements with which the upper part of the tank is provided are made in the form of horizontally oriented plate elements, between which an internal chamber is located, the plate elements adjoin the side walls of the tank, the support elements with which the upper part of the internal chamber is provided are made in the form of flanges located outside the internal chamber along the upper edges of its side walls, wherein the internal chamber rests with flanges on the free edges of the plate elements. 9. A garbage collector according to item 1, characterized in that the internal chamber is installed inside the tank in such a way that its side walls are oriented parallel to the side walls of the tank body, and through holes are made in the side wall of the internal chamber that is farthest from the inlet part of the outlet pipe. 10. A garbage collector according to item 9, characterized in that the openings in the side wall of the inner chamber are made in a section limited by the upper edge of said side wall and its lower boundary, located at a distance from the bottom of the inner chamber equal to 2/3 of the height of said side wall.