DE29618902U1 - Plant for the purification of waste water without producing sewage sludge - Google Patents

Description

The present invention relates to a plant for cleaning waste water without producing sewage sludge.

Regarding the relevant state of the art, it can be stated that the environmentally friendly treatment and disposal of sewage sludge from wastewater treatment is increasingly associated with waste management problems. As is well known, sewage sludge, which usually becomes waste, is increasingly presenting financial, technological and waste management problems for municipal sewage treatment plant operators and the local authorities responsible for disposal. The possibility of landfilling requires, according to the current state of the art, very extensive and therefore complex dewatering, which makes the use of expensive chamber filter presses necessary, unless the required blade shear strengths can be ensured by mineral additives, which, however, disadvantageously increase the volume of mass to be deposited.

Irrespective of this, sewage sludge generally worsens the stability of landfills and increases the risk of surface subsidence.

Furthermore, it should be noted that future landfills will be even more difficult to implement than before due to the more stringent requirements of the regulations according to the TA-Municipal Waste with regard to dry matter content.

The thermal utilization of sewage sludge waste as an alternative to landfilling requires technically complex incineration plants, which are expensive to operate and cannot be built across the board. Furthermore, these incineration plants are often difficult to convince the public to use. Another disadvantage of these incineration plants is that the valuable properties of the waste are not utilized because the organic substances are burned.

Furthermore, there is a declining acceptance in agriculture of the issue of the proper use of sewage sludge, as the heavy metal content of sewage sludge is sometimes too high, making it increasingly rare to use it as a fertilizer. As a rule, only slightly contaminated, solid ingredients from domestic sewage, particularly in rural areas, are an excellent addition to soils used for agriculture and gardening due to their high content of organic substances and plant nutrients. However, this requires good drainage and composting.

This finding is the basis of the present invention. The aim of the present invention is to create a system for cleaning wastewater, while avoiding the above-mentioned disadvantages of the prior art, in which sewage sludge is not produced in the first place and which, due to its optimized process flow, only causes low operating costs.

A further advantage of the plant according to the invention is that its operating costs are minimal and it can be designed in small, medium and large dimensions, whereby the investment costs can be kept low even for small consumers. The plant according to the invention produces an optimal, humus-like material that is ideally suitable for adding to cultivated soils. The plant according to the invention is therefore both economically and ecologically advantageous, it saves landfill space and largely makes the construction of cost-intensive waste treatment plants of the state of the art superfluous.

The above-mentioned object is achieved according to the invention by creating a system which is characterized in that it consists of at least one shaft which contains a waste water inlet device, a rotting tank with a filter layer, and a discharge device for the purified water. Preferred embodiments of the subject matter of the invention are characterized in that the rotting tank has an organic filter layer which filters out solids present in the waste water and/or that the filter layer of the rotting tank consists of wood chips and/or wood chips and/or that the shaft is sunk into the ground and/or that the shaft has at least one cover plate which can be designed as a grating and/or that a submersible pump or a mechanical impact feeder is arranged in the shaft which transports the purified waste water to the discharge device and/or that

a float switch is arranged in the pump sump as a safety device and/or that an intermediate wall with overflow is arranged in the shaft and/or that the system according to the invention has at least two rotting containers and/or that a pivoting inlet device is arranged for feeding the waste water to be cleaned into different rotting containers.

A particularly preferred embodiment of the subject matter of the invention is further characterized in that the system described above contains, as an integrated further system component, a plant-based sewage treatment plant that is in itself part of the state of the art and consists of a plant-based vertical filter, a pipe distributor, a film seal to the ground, a removal drainage and a control and regulating shaft.

The system according to the invention is preferably used in domestic and municipal areas and also serves as an alternative to the conventional multi-chamber settling or septic tank. In the system according to the invention, solids are separated and the wastewater contents are composted in an optimal manner. The solid components of the wastewater are therefore collected in special containers and subjected to a rotting process with the help of microorganisms and sufficient oxygen.

This already involves a partial biological degradation of the organic pollution and a revitalization of the water flowing through.

As a result of the aerobic conditions in the rotting container and the subsequent composting, the formation of sewage sludge is prevented, which also prevents unpleasant odors. It is important to ensure that there is a permanent water drain and a continuous oxygen supply when operating the system according to the invention. The specific structure of the system according to the invention depends on the space available and the number of residents who are connected to the wastewater treatment system according to the invention. Depending on the connection value, concrete or plastic shafts can be built into the floor and closed with cover plates, whereby a grating in particular can be advantageously used to ensure the desired oxygen supply and to remove the rotting containers and the rotting material.

The solid components of the wastewater to be treated are retained in the preferably organic filter layer and subjected to a rotting process due to the prevailing aerobic conditions, while the water seeps through and reaches a collecting shaft. According to the biological principles outlined above, a combined plant sewage treatment plant can synergistically enhance the overall effect.

A time- and level-controlled submersible pump and/or a mechanical shock feeder can be used to transport the water from the collection area of the shaft to the plant-based sewage treatment plant via at least one pipeline.

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A float switch can be installed in the pump sump as a safety device, which triggers a visual or acoustic warning signal, or both, in the event of an unusual water level. To optimize the process, organic materials such as straw or wood chips can be added to the rotting material at predetermined intervals, depending on the amount of wastewater.

For example, after the first container is filled, it remains in the system until it is completely drained and composted, while a second and possibly further containers are fed via a pivoting inlet pipe. The subsequent removal and emptying takes place using mobile and stationary lifting devices. The use of the system according to the invention for cleaning wastewater optimally meets the essential criteria of modern waste management, namely:

Mechanical and partially biological pre-treatment for small and plant-based sewage treatment plants; Replacement of conventional multi-chamber and septic tanks as well as replacement of settling ponds; Maintaining the oxygen content through short retention times of the water in the collection shaft as well as the possibility of producing compost for use in horticulture and agriculture.

The essence of the present invention will now be further explained with reference to the two accompanying drawings, which show preferred embodiments by way of example.

Figure 1 shows the system according to the invention for use with regard to waste water for approximately 1-20 people.

Figure 2 shows a variant for the waste water of more than 20 people. The design according to Figure 1 is particularly suitable for use in limited space, for example for single-family homes or restaurants and is therefore designed as a single-shaft system. In Figure 1, reference number 1 is the concrete/plastic shaft, 2 is the base plate, 3 is the cover plate, 4 is the grating, 5 is the concrete cover, 6 is the inlet device, 7 is the rotting container, 8 is the solids, 9 is the filtrate, 10 is the collection area, 11 is the overflow, 12 is the partition wall, 13 is the pump shaft, 14 is the pump shaft, 15 is the pump chamber, 16 is the pump chamber, 17 is the pump chamber, 18 is the pump chamber, 19 is the pump chamber, 20 is the pump chamber, 21 is the pump chamber, 22 is the pump chamber, 23 is the pump chamber, 24 is the pump chamber, 25 is the pump chamber, 26 is the pump chamber, 27 is the pump chamber, 28 is the pump chamber, 29 is the pump chamber, 30 is the pump chamber, 31 is the pump chamber, 32 is the pump chamber, 33 is the pump chamber, 34 is the pump chamber, 35 is the pump chamber, 36 is the pump chamber, 37 is the pump chamber, 38 is the pump chamber, 39 is the pump chamber, 40 is the pump chamber, 41 is the pump chamber, 42 is the pump chamber, 43 is the pump chamber, 44 is the pump chamber, 45 is the pump chamber, 46 is the pump chamber, 47 is the pump chamber, 48 is the pump chamber, 49 is the pump chamber, 50 is the pump chamber, 51 is the pump chamber, 52 is the pump chamber, 53 is the pump chamber, 54 is the pump chamber, 55 is the pump chamber, 56 is the pump chamber, 5

14 the submersible pump and/or a mechanical impact feeder and with

15 the float switch.

In the embodiment according to Figure 2, several shafts are arranged.

In the distribution shaft, the incoming water is fed into one of the shafts using a valve. Here, the solid components of the wastewater are optimally drained through the organic filter layer, the ventilation and drainage floor, the ventilation and drainage walls and supplied with the oxygen necessary for composting or rotting. The cleaned wastewater is then fed into the deeper collection shaft.

In Figure 2, the reference number Γ designates the distribution shaft, 2' the slider, 3' the rotting shaft, 4' the ventilation and drainage wall, 5' the ventilation and drainage floor, 6' the ventilation room, 7' the ventilation chimney and 8' the collection shaft.

Claims (12)

Protection claims 1. Plant for the purification of waste water without the formation of sewage sludge, characterized in that it consists of at least one shaft (1) which contains a waste water inlet device (6), a rotting container (7) having a filter layer and a discharge device for the purified water. 2. Plant according to claim 1, characterized in that the rotting container (7) has an organic filter layer that filters out the solids present in the waste water. 3. Plant according to claim 2, characterized in that the organic filter layer consists of straw and/or wood chips and/or wood chips. 4. Installation according to claims 1-3, characterized in that the shaft (1) is sunk into the ground. 5. Installation according to claims 1-4, characterized in that the shaft (1) has a cover plate. 6. Installation according to claim 5, characterized in that the cover plate consists of concrete and/or a grating. 7. Plant according to claims 1-6, characterized in that a submersible pump (14) and/or a mechanical impact feeder is arranged in the shaft (1), whereby the purified water is transported to the discharge device. 8. System according to claims 1-7, characterized in that an intermediate wall (12) with overflow (11) is arranged in the shaft (1). 9. Plant according to claims 1-8, characterized in that at least two rotting containers are arranged in the shaft. 10. Plant according to claim 9, characterized in that it has a pivotable feed device for feeding the waste water to be cleaned into several rotting containers one after the other. 11. System according to claims 1 - 10, characterized in that a float switch (15) is arranged in the pump sump as a safety device, which triggers warning signals. 12. Plant according to claims 1-10,
characterized, that it is connected via a pipe to a state-of-the-art plant-based sewage treatment plant, which consists of a vertical plant filter, a pipe distributor, a film seal to the ground, an extraction drainage system and a control and regulating shaft.