EP0754837A2 - Device for irradiation of wells to prevent biological stains - Google Patents

Abstract

A ground water well filter assembly incorporates a radioactive source. The novelty is that the radioactive source (1) is located within a pipe system consisting of an outer protective sheath (2) surrounding a watertight probe pipe (3) around a perforated source (1) tube (4). The upper part of the probe (5) pipe system is closed at the head of the well by a safety valve (7) and an upper section (5) with an aerosol filter (6).

Description

The invention relates to a well irradiation system for preventing biological blockage and is applicable in particular for the protection of production wells, lowering wells, infiltration wells and heat pump wells in water management, industry and agriculture.

The biological sedimentation is the result of the activity of microorganisms, in particular bacteria influencing iron and manganese compounds. Under certain conditions, these bacteria can absorb the divalent iron and manganese present in the groundwater and excrete them in the form of insoluble iron and manganese compounds. This mineralization occurs primarily in the filter tube slots, in the gap volume the gravel fill as well as on the inlet strainer of the feed pumps and in the feed lines. The result is an ever increasing decline in output.
This significantly reduces the reliability of the water intake. Repetitive regeneration and replacement investments require high economic expenditure.

It is known to counteract the biological loosening with mechanical-hydraulic, chemical or electrical processes.
A disadvantage of these solutions is the high expenditure on work and equipment and the discontinuous mode of operation.

Furthermore, from DD 48 766 a method for preventing blockages in wells is known, which is characterized in that the well filter is subjected to a constant or periodically successive influence of ionizing radiation, whereby the effect of the microbiological hindrance of the life processes of small organisms occurs and that irradiated clogging sludge undergoes colloidal chemical changes corresponding to degradation. To implement this method, a radioactive radiation source is encapsulated watertight in a protective tube made of plastic or metal, which is installed over the entire length of the filter inside the well filter.

A disadvantage of this known technical solution is that the radiation sources are installed in the well filter and measures to ensure the required safety do not meet today's national and international requirements.

The invention is therefore based on the object of providing a well irradiation system for preventing biological blockage, which reliably and effectively prevents well blockage over a long period of time, ensures a high safety standard and can be manufactured, installed and maintained easily and economically.

This object is achieved by the features in the characterizing part of claim 1 in conjunction with the features in the preamble. Appropriate embodiments of the invention are contained in the subclaims.

A particular advantage of the invention is that with a one-time investment, permanent protection of approximately 10 years is achieved, the well constantly having a stable delivery capacity by the radiation sources in a pipe system consisting of a protective tube, a probe tube therein and a source tube located therein be arranged, and the pipe system on the well head is completed with a probe upper part having at least one safety valve and a filter.
After about 10 years, it is necessary to reload new radiation sources into the source tube in order to maintain the protective effect. The existing radiation sources can continue to be used. In total, the radiation sources are expected to have a useful life of around 20 years in the well before they are disposed of. It is advisable that wells that are subject to biological clogging are irradiated when they begin to be used in order to prevent a drop in performance from the outset. In use cases with the already existing hardening, if the deposits are not yet firmly encrusted, a complicated dehydration and mineralization process not only stops the hardening process, but also increases the performance again.

The invention will be explained in more detail below using exemplary embodiments.

Fig. 1

eine Prinzipdarstellung des Rohrsystems mit den Strahlenquellen;

Fig. 2

eine Schnittdarstellung durch das Sondenoberteil;

Fig. 3

eine Prizipdarstellung für die Beschickung und die Entnahme der Strahlenquellen.

Show it:

Fig. 1

a schematic diagram of the pipe system with the radiation sources;

Fig. 2

a sectional view through the probe top;

Fig. 3

a diagram for the loading and unloading of the radiation sources.

As can be seen from Fig. 1, the well irradiation system consists of three vertically arranged tubular columns, which form the tube system.
The outer pipe, the protective pipe 2, is placed at a defined distance from the well pipe in the gravel fill of the well. The even distance to the well pipe is ensured by means of spacers. The protective tube 2 is perpendicular to a support on the bottom of the well. The number of pipe systems for a well depends on the hydrological conditions.
The pipe system is installed parallel to the well pipe in the filter gravel and consists of protective pipe 2, probe pipe 3, source pipe 4 and the radiation sources arranged therein 1. The radiation field is generated by radiation sources 1 with the isotope Co-60 in a double-encapsulated, hermetically sealed form. The triple-layered protective barrier of the pipe system and source capsule as well as a control system prevent radioactive contamination with certainty. The use of the Co-60 isotope principally excludes activation of the water and the building materials due to its gamma quantum energy. Within the limits of the design guideline values it is guaranteed that changes in the water and the dissolved constituents remain within the range of a negligible side effect.
The shielding effect of the earth area and a sufficiently high operating water level ensure that radiation cannot escape into the well's access area.
The vertically nested probe and source tubes are positioned at a defined distance from each other by special centering elements.
The protective tube 2 fills with ground water through inserted filter parts up to the level of the aquifer.
The probe tube 3 arranged in the protective tube 2 is designed as a waterproof tube, since it absorbs the storage liquid in addition to the complete source tube 4. The storage liquid does not come into contact with the well water. In the present exemplary embodiment, the storage liquid is bidistilled water and encloses the radiation sources 1. The storage liquid extends to the upper part of the probe 5. The structural design of the source tube 4 and the probe tube 3 ensures circulation of the storage liquid. This circulation cools the radiation sources 1 on the one hand and on the other there is the possibility of checking the tightness of the radiation sources 1.
The source tube 4 contains and guides the radiation sources 1. The number of radiation sources 1 is determined in accordance with the well geometry and the hydrological conditions. The position of the radiation sources 1 is determined by the lower edge of the source tube 4 and the length of the spacer tubes 12. Through slits in the bottom area and through bores in the upper tube area and in the top area of the source tube 4, this is permeable for escaping gas bubbles and for the circulation of the storage liquid.

The upper part 5 of the probe is arranged above the pipe system. The upper part of the probe 5 is accessible in the fountain room. It closes off the pipe system at the top and accommodates the necessary components to ensure function and system safety.

In the basic embodiment shown in FIG. 2, the probe tube 3 and the upper probe part 5 form a pressure-tight system. In this system, an operating pressure builds up in the storage liquid caused by radiolysis. This pressure is displayed on the manometer 10 and limited by the safety valve 7. The tightness of the system can be assessed by checking the manometer pressure. An integrated aerosol filter 6 retains the moisture content of the radiolysis gas. The connecting flange 8a which closes the protective tube 2 and the hood 8 with integrated means 9 for aeration and ventilation form a protection against mechanical stress. The hood 8 is fastened with a screw connection on the connecting flange 8a.

In addition to mechanical security, sealing the hood can protect it against unauthorized access. Through the means 9 for ventilation, the air inside the hood is flushed out before a check or before opening for other reasons in order to remove any oxyhydrogen gas that may be present.

The well irradiation system must be prepared accordingly for loading and unloading the radiation sources 1. The hood 8 and the inner part of the upper part 5 of the probe are disassembled or, for the first loading, the assembly is carried out only up to the state described. The storage liquid is pumped out while the radiation sources are being removed. The bed liquid is filled up before loading.

For the actual loading or unloading process, as shown schematically in FIG. 3, a connection between the source tube 4 and the manipulation container 11 aligned in the system axis is established with the connecting tube 13 using a special loading and unloading technique. The radiation sources 1 and the spacer tubes 12 are removed using special gripping devices. The radiation sources 1 and distance tubes 12 are pulled out of the source tube 4. The radiation sources 1 remain in the manipulation container 11, the spacer tubes 12 are removed through the manipulation container 11.
During the loading process, the radiation sources 1 and spacer tubes 12 are introduced into the well irradiation system in the required length, number and sequence. After removing the manipulation container 11 and the loading and unloading technology, the storage liquid brought to the required level and the probe top 5 completed according to the design provided.

In the upper part 5 of the sensor, sensors (not shown) are arranged in FIG. The parameters to be recorded or monitored can be pressure, radioactive radiation and possibly temperature. The data recorded by the sensors are transmitted by wire or wirelessly to the process data processing system via remote data transmission.

The invention is not restricted to the exemplary embodiments described here. Rather, it is possible to implement further design variants by combining the features mentioned, without leaving the scope of the invention.

Claims (10)

Well irradiation system to prevent biological blockage with radiation sources arranged parallel to the well filter tube,
characterized,
that the radiation sources (1) are arranged in a pipe system consisting of a protective tube (2), a probe tube (3) therein and a source tube (4) therein and the tube system on the well head with at least one safety valve (7) and a filter (6 ) having the upper part of the probe (5) is completed. Well irradiation system according to claim 1,
characterized,
that the probe top (5) is closed with a hood (8) which has means (9) for ventilation and a manometer (10) is arranged on the probe top (5). Well irradiation system according to claim 1,
characterized,
that the filters (6) are aerosol filters. Well irradiation system according to claim 1,
characterized,
that spacers are arranged between the well pipe and the protective tube (2) and the protective tube (2) in the aquifer area has filter parts for groundwater entry. Well irradiation system according to claim 1,
characterized,
that the probe tube (3) is watertight and filled with a storage liquid which encloses the radiation sources (1) in the source tube (4) and the storage liquid is bidistilled water. Well irradiation system according to claim 1 or 5,
characterized,
that the source tube (4) has slots in the lower region and bores in the upper region and spacer tubes (12) are arranged in the source tube (4) between the radiation sources (1) and the source tube (4) is centered in the probe tube (3) with centering elements. Well irradiation system according to claim 1,
characterized,
that sensors for detecting a wide variety of parameters are arranged in the upper part of the probe (5) and are connected to process data processing. Well irradiation system according to claim 7,
characterized,
that the parameters are pressure and / or temperature and / or radioactive radiation. Well irradiation system according to claim 1,
characterized,
that the loading and unloading of the radiation sources (1) takes place with the probe upper part (5) removed via a manipulation container (11) which is coupled to the source tube (4) via a connecting tube (13). Well irradiation system according to claim 9,
characterized,
that the radiation sources (1) and the distance tubes (12) are removed with special gripping devices and the radiation sources (1) remain in the manipulation container (11) and the distance tubes (12) are removed through the manipulation container (11).

Images