RU2103054C1 - Method of active electroosmotic drying of walls of buildings and structures from ground waters - Google Patents

Abstract

FIELD: construction and reconstruction of buildings and structures; may be used in major and minor repairs. SUBSTANCE: method includes connection of electrodes to DC source and to wall of building or structure to set up electric field, and moisture flow is formed to dry the wall. At the first stage DC source sets up field intensity which exceeds the threshold value and depending on height of moisture rise in wall at which moisture in wall capillaries is displaced and excessive moisture is removed. Upon completion of the first stage, the voltage of DC source is reduced to value ensuring counteraction to the process of capillary rise of moisture in wall under pressure of grounds and filtration waters. All anode electrodes may be separated into sections. In this case, separate independent current lead is provided in each section. Voltage in sections may vary depending on moisture content in wall. Applying various voltage values to wall different sections may result in efficient drying over the entire perimeter of building. Separation of one section of anode electrodes into two groups with alternating supply of electric energy to each group, mutual interaction of neighboring anode electrodes is reduced and drying efficiency is raised while the power consumption is reduced. With use of internal nongrounded metal structures as electrodes, the time required for wall drying is decreased. When additional sections of anode electrodes are installed at grounded metal structures, water-logging of sections of wall near these section reduces. EFFECT: efficient wall drying, reduced time for drying, and higher operating reliability. 7 cl, 4 dwg

Description

 The invention relates to the construction, reconstruction of buildings and structures and can be used when conducting major and cosmetic repairs.

 To date, extensive experience has been gained in the application of electroosmotic methods for draining the walls of buildings and structures from groundwater, which are divided into "passive" methods that do not require an external direct current source, and "active" methods in which electric forces are created using an external DC source . Active methods are most prevalent. Under the action of an applied electric field, positive ions move from the electrodes-anodes located in the drained wall to the electrodes-cathodes placed in the ground, dragging water molecules along, as a result, the humidity of the wall decreases. After draining the wall, the electric field prevents the capillary rise of moisture and keeps the wall dry.

 A method of active electroosmotic drainage of walls from groundwater, developed in Austria and used in many countries, is carried out using flat mesh electrodes-anodes superimposed on a wall, which operate at low current densities and create small electric field strengths in the volume of the wall (source voltage DC current does not exceed 6 V). In this case, rod electrodes-cathodes are located outside the drained wall - in the ground [1].

 The disadvantage of this method is the long drainage period (2 to 3 g).

 Closest to the invention is a method of active electroosmotic drainage of walls of buildings and structures from groundwater, which consists in placing in the volume of the wall a system of rod electrodes-anodes, and in the soil of a system of electrode-cathodes connected respectively to the positive and negative poles of a direct current source, and transmitting current between these electrodes [2].

The disadvantages of the prototype, not allowing to achieve the goal, are:
insufficiently rational arrangement of the electrodes in the wall and soil, performed without taking into account such factors as the height of the capillary rise of moisture, the width of the wall, various moisture saturation of the wall sections, the peculiarities of using plate and rod anodes;
insufficiently efficient use of electric energy, associated with an unregulated mode of operation of a direct current source in the process of draining the wall, a long drainage time, leading to inhibition of repair and finishing work, due to low values of the electric field strength and (as a result) low values of the electroosmotic drainage rate. As a rule, the created electric field strength is only enough to prevent capillary rising of moisture, but not enough to remove excess moisture from the wall, and excess moisture in this case is removed by natural evaporation in 2 - 3 g.

 The objective of the invention is to increase the efficiency and reliability of the method of draining the walls of buildings and structures from groundwater, as well as the creation of electroosmotic waterproofing and reducing drainage time with the optimal use of electrical energy.

 The invention is expressed in the following set of essential features, sufficient to achieve the above result.

 According to the invention, a method of active electroosmotic drainage of walls of buildings and structures from groundwater, which consists in placing a system of anode electrodes in a volume or on a wall surface, and in a soil a system of electrode cathodes connected to the positive and negative poles of a direct current source, respectively, and passing current between these electrodes is characterized by the fact that the process of draining the wall is carried out in two stages, while at the first stage excess moisture is removed from the wall, for which the voltage of the source The direct current nickname and the location of the anode electrodes are chosen in such a way that an electric field is created in the cross section of the wall at the level of the lower boundary of the drainage zone, the voltage of which at all points of this section exceeds the threshold value at which the electroosmotic movement of moisture occurs, while the cathode electrodes are installed in the soil at a distance from the lower boundary of the drainage zone, exceeding half the height of the capillary rise of moisture, and on the second - the voltage of the DC source is reduced to eniya that protects walls from rising damp.

 This is the totality of essential features that provides a technical result in all cases to which the requested amount of legal protection applies.

где H - высота капиллярного поднятия влаги в стене, м;
h - высота установки электродов-анодов относительно нижней границы зоны осушения, м;
B - толщина стены, м;
L - расстояние между смежными электродами-анодами, м;
l - длина электродов-анодов, м;
при H ≥ B электроды-аноды выполняют в виде плоской сетки или полосы, которую накладывают на поверхность стены вдоль линии, параллельной нижней границе зоны осушения, причем высоту установки сетки или полосы выбирают из соотношения

ряд стержневых электродов-анодов разделяют последовательно по длине стены на секции, к каждой из которых осуществляют независимую подачу электрической энергии от источника постоянного тока;
сеточный или полосовой электрод-анод подключают к положительному полюсу источника постоянного тока несколькими токоподводами;
электроды-аноды в одной секции разделяют на две группы, каждая из которых объединяет все несмежные электроды в секции, при этом к каждой из групп осуществляют поочередную подачу постоянного тока;
при наличии в стене здания каких-либо заземленных металлических конструкций устанавливают дополнительные секции электродов-анодов таким образом, чтобы каждая заземленная конструкция находилась между секциями электродов-анодов, а при наличии в стене здания каких-либо незаземленных металлических конструкций и расположении их в зоне увлажнения, выше электродов-анодов, эти конструкции подключают к положительному полюсу источника постоянного тока, при расположении тех же конструкций под электродами-анодами, конструкции первоначально подключают к отрицательному полюсу источника постоянного тока, а затем к положительному полюсу.In addition, the present invention has optional features characterizing its particular cases, specific forms of its material embodiment or special conditions for its use, namely:
a system of electrodes-anodes, performed in the form of a series of rods or pipes, with a constant step between adjacent electrodes, parallel to the lower boundary of the drainage zone, and the location parameters of the electrodes-anodes are determined by the following relationships:

where H is the height of the capillary rise of moisture in the wall, m;
h is the installation height of the anode electrodes relative to the lower boundary of the drainage zone, m;
B - wall thickness, m;
L is the distance between adjacent anode electrodes, m;
l is the length of the anode electrodes, m;
at H ≥ B, the anode electrodes are made in the form of a flat grid or strip, which is laid on the wall surface along a line parallel to the lower boundary of the drainage zone, and the installation height of the grid or strip is selected from the ratio

a number of rod electrodes-anodes are divided sequentially along the length of the wall into sections, to each of which an independent supply of electrical energy from a direct current source is carried out;
a grid or strip electrode-anode is connected to the positive pole of the DC source by several current leads;
the anode electrodes in one section are divided into two groups, each of which combines all non-adjacent electrodes in the section, with alternating supply of direct current to each of the groups;
if there are any grounded metal structures in the building wall, additional sections of anode electrodes are installed so that each grounded structure is between the anode electrodes sections, and if there are any non-grounded metal structures in the building wall and their location in the humidification zone, above the anode electrodes, these structures are connected to the positive pole of the direct current source, when the same structures are located under the anode electrodes, the structures dklyuchayut to the negative pole of the DC source, and then to the positive pole.

 The proposed technical solution is new, since the combination of its essential features contained in the independent claim is not known from the current level of technology.

 The immediate technical result that can be obtained by implementing the proposed combination of features is that the efficiency and reliability of drainage are increased and its time is reduced.

 When considering analogues, no solutions were found that have signs that coincide with such distinctive features of the proposed solution as exceeding the threshold value of the electric field strength, rational arrangement of the electrodes in the wall and soil, changing the mode of the DC source during the drainage process, and taking into account the presence of metal structures in the wall.

 At the same time, such separately known signs from the prior art as installed and connected to a constant current source electrodes anodes and electrodes cathodes do not ensure the achievement of the above technical result, therefore, we can conclude that the proposed solution meets the criterion of "inventive step".

 In FIG. 1 presents a General diagram of the implementation of the proposed method; in FIG. 2 - section along the drained wall; in FIG. 3 and 4 - groups of non-adjacent electrodes.

 The method is implemented using a system of electrodes-anodes 1 installed in the volume or on the surface of the wall 2, and a system of electrodes-cathodes 3 installed below the electrodes 1 in the ground. The electrodes are connected to a direct current source 4 and create an electric field, the lines of force of which are indicated by pos. 5. The placement of the electrodes 1 and 3 depends on the height of the capillary rise of moisture 6 and the position of the lower boundary of the drainage zone 7.

 The method is implemented as follows.

 When electrodes 1 and 3 are connected to a direct current source 4, an electric field is created in the wall of the building at the level of the lower boundary of its drainage zone 7 and an even stream of moisture drains the wall.

 For this, the anode electrodes 1 and the cathode electrodes 3 must be arranged in accordance with the above conditions. Moreover, for rod and plate anodes and various ratios between the width of the wall and the height of the capillary rise of moisture, a close to uniform electric field is slightly dependent on the length of electrode 1 in the cross section of the wall at the level of the lower boundary of the drainage zone. In the case of H ≥ B, which can be flat in the form of a grid, or rod with an arbitrary length. In the case of H <B, to ensure the above indicated electric field, the electrode-anode must have a length of 1. The plane of the drainage zone, depending on the operating conditions of the building, can coincide with the level of the foundation, floor or ground.

 During the drying process, the moisture contained in the wall is redistributed in the space between the anode electrodes 1 and the cathode electrodes 3, and three zones are conditionally distinguished: the anode one is the driest, the middle one and the cathode one as the wettest. The cathode zone must be removed from the space of the drained wall, or moved below the boundary of the drainage zone, which is done by the appropriate choice of the installation location of the cathode electrodes.

 The threshold electric field strength is selected on the basis of laboratory experiments that are performed with materials of the drained wall.

 At the first stage of drainage, the constant current source 4 mode is set, at which the field strength exceeds a threshold value in the plane 7, at which moisture is shifted in the capillaries of the wall.

 At the end of the first stage of draining the wall, the voltage of the direct current source 4 is reduced to a value that ensures the electric field strength, which counteracts the process of capillary raising of moisture into the wall under the influence of ground and filtration water pressure.

 The anode electrodes can be divided into sections, with each section being independently supplied with voltage, and the voltage from section to section can vary depending on the humidity of the wall section. By connecting different voltages to different parts of the wall, it is possible to ensure effective drainage along the entire perimeter of the building, regardless of the humidity of the wall sections. Partitioning eliminates the nonequipotentiality of the anode electrodes for long drainage zones. When dividing one section of the anode electrodes into two groups, each of which is supplied with electrical energy in turn, the mutual influence of adjacent anode electrodes is reduced, the drainage efficiency is increased, and energy costs are reduced.

 Within the walls of buildings and structures can be located various structures: fittings, pipelines, etc. (grounded or ungrounded). Internal grounded metal structures are located between additional sections of the anode electrodes, thereby ensuring reliable drainage of these wall sections.

 In the case of non-grounded structures, metal structures are used as additional electrodes when connected to the poles of a direct current source, and non-grounded structures located above the anode electrodes are connected to the positive pole of the direct current source, when the same structures are located under the anode electrodes, the structures are initially connected to the negative pole of the DC source, and then to the positive pole.

 The possibility of industrial application of the invention as it is characterized in the independent claim is confirmed by the means and methods described in the application materials for its implementation.

Using the proposed method in comparison with all known means of a similar purpose provides the following advantages:
effective drainage of walls;
reduced drainage time;
high reliability.

Claims (6)

 1. The method of active electroosmotic drainage of walls of buildings and structures from groundwater, which consists in placing in the volume or on the wall surface a system of electrode anodes, and in the soil of a system of electrode cathodes connected respectively to the positive and negative poles of a direct current source, and transmitting current between these electrodes, characterized in that the process of draining the wall is carried out in two stages: at the first stage, excess moisture is removed from the wall, for this the voltage of the DC source and the electrodes of the anodes are chosen in such a way that an electric field is created in the cross section of the wall at the level of the lower boundary of the drainage zone, the intensity of which at all points of this section exceeds the threshold value at which the electroosmotic movement of moisture occurs, while the cathode electrodes are installed in the soil at a distance from the lower boundary of the drainage zone, exceeding half the height of the capillary rise of moisture, in the second stage, the voltage of the DC source is reduced to a value that provides protection a wall of rising damp. 2. The method according to claim 1, characterized in that the system of electrodes-anodes is made in the form of a series of rods or tubes with a constant step between adjacent electrodes parallel to the lower boundary of the drainage zone, and the location parameters of the electrodes-anodes are determined by the ratios
for H ≥ B

H ≥ h ≥ L / 2;
for H <B
L <3h / 2; H ≥ h ≥ 2 (B l),
where H is the height of the capillary rise of moisture in the wall, m;
h the installation height of the anode electrodes relative to the lower boundary of the drainage zone, m;
B wall thickness, m;
L is the distance between adjacent anode electrodes, m;
l the length of the anode electrodes, m 3. The method according to claim 1, characterized in that at H ≥ B, the anode electrodes are made in the form of a flat grid or strip, which is applied to the wall surface along a line parallel to the lower boundary of the drainage zone, and the height of the grid or strip is selected from the ratio

4. The method according to PP. 1 and 2, characterized in that the series of rod electrodes-anodes are divided sequentially along the length of the wall into sections, to each of which an independent supply of electric energy from a direct current source is carried out.  5. The method according to claim 3, characterized in that the grid or strip electrode-anode is connected to the positive pole of the DC source by several current leads.  6. The method according to claims 1, 2 and 4, characterized in that the anode electrodes in one section are divided into two groups, each of which combines all non-adjacent electrodes in the section, with alternating supply of direct current to each of the groups.  7. The method according to PP.1 to 6, characterized in that if there are any grounded metal structures in the building wall, additional sections of the anode electrodes are installed so that each grounded structure is between the sections of the anode electrodes, and if there is a building in the wall any non-grounded metal structures and their location in the humidification zone above the anode electrodes, these structures are connected to the positive pole of the DC source, when the same structures are located under the electrodes - the design anodes are initially connected to the negative pole of the DC source, and then to the positive pole.

Images