RU34612U1 - Window glass for buildings and structures - Google Patents

Description

Window glass for buildings and structures

The utility model relates to construction and can be used in the construction, reconstruction and / or operation of various buildings and structures.

One of the problems solved in the construction of buildings for various purposes is the maximum possible use of natural lighting, which is achieved by increasing the area of glazing. However, if you use ordinary glass for windows, then two problems arise: in the summer the rooms overheat, and in winter there are large heat losses through the glass, which requires additional heating costs. Therefore, in modern buildings, multilayer window glasses are used, which usually consist of three layers - two layers of ordinary glass or transparent plastic (dielectric) and a thin metal layer (conductive layer) placed between them. A conductive layer is usually applied to one of the surfaces of one of the dielectric layers. Such glasses protect against excessive overheating of the room and prevent the release of heat through them.

However, these glasses significantly weaken the transmitted radio emission, which prevents the stable operation of radios and transmitters, with antennas located outside the windows, indoors. The installation of transceiver antennas on the roofs or walls of structures spoils their appearance and requires cabling from antennas to subscribers, which significantly increases the cost of their installation and operation.

In order to resolve this contradiction, it is necessary that the well-known and widely used laminated glasses, along with their properties of creating comfortable conditions in rooms with minimal energy consumption, have radio transparency.

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metal elements are arranged in the form of one or two pairs of wire gratings.

A disadvantage of the known device is the certain complexity of its manufacture. It also does not provide for preventing the heating of the object located behind it by light radiation and has a low thermal resistance, which leads to heat loss if used in buildings and structures. In addition, the wire structures included in the radiolucent wall are sensitive to the polarization of the radio emission, therefore, their orientation should be adjusted to the polarization of the radio waves, the transmission of which must be ensured.

Known laminated glass, which can be used for various vehicles (see RU 2025297 121). Known glass contains the outer and inner sheets of glass, interconnected by an adhesive layer. A conductor for receiving radio waves is located around the glass perimeter, is installed inside the insulating layer and has an output in the form of two electrodes isolated from each other. A radio receiver is connected to the electrodes, as to an antenna. The insulating layer forms a seal between the sheets to limit the cavity between them under the bonding layer in the manufacture of glass.

The disadvantage of this glass is the complexity of its manufacture and, since it does not contain a conductive layer covering a significant part of its surface, it does not provide protection against overheating of the internal volume of the vehicle and is ineffective from the point of view of heat leaving the surrounding space in cold weather.

Closest to the claimed in its technical essence is laminated glass containing dielectric and conductive layers and providing comfortable conditions in the protected volume with minimal energy consumption for its heating or cooling (see JP 06040752/3 /).

A disadvantage of the known device is its low radio transparency, due to the fact that the conductive strips form a one-dimensional lattice filling almost the entire area of the glass (the width of the strips in which the conductive coating is removed is no more than 1/20 of the period).

In addition to low transparency, this device is time-consuming and expensive to manufacture. Firstly, the structure described above is created on the entire surface of the glass, which would require very significant costs if such glasses were used in construction, given the large glazing area of buildings. Secondly, the width of the dividing strips between the electrically conductive strips is chosen unreasonably small (less than 1/20 of the period), which further complicates the production. For example, with a radio wave length of 3 cm, the width of a separate strip is 0.05 mm. The creation of such a fine structure on a window pane of considerable area would be extremely expensive and would require the use of bulky specialized equipment.

The window glass design claimed as a utility model is aimed at reducing the costs of placing transceiver antennas in rooms insulated from the environment by heat-shielding glasses, as well as at reducing radio wave losses in such glasses.

This result is achieved in that the window glass for buildings and structures contains one or more dielectric layers and an electrically conductive layer, characterized in that its surface is provided with radio-transparent sections in which periodic parallel strips of the same width are made, where the electrically conductive layer is either removed or converted to non-conductive layer, with a period shorter than the wavelength of radio emission, while the total area of such bands occupies 10-50% of the area of the radio-transparent section, and the longitudinal s of each of the stripes is not parallel to the plane in which lies the electric field vector of the received and / or transmitted by radio.

The indicated result is also achieved by the fact that different radiolucent sections created within the same window can have different widths of non-conducting bands, the fill factor of the area of the section with these bands and the orientation of the bands.

This result is also achieved by the fact that the strips in which the electrically conductive layer is either removed or converted into a non-conductive layer are placed within the radio-transparent section in the form of intersecting periodic gratings.

The indicated result is also achieved by the fact that the strips in which the electrically conductive layer is either removed or converted into a non-conductive layer are made intermittent and placed within the radio-transparent section in the form of intersecting periodic gratings, forming in aggregate a multiply connected topological structure that separates the electrically conductive layer isolated from each other other sections with a size smaller than the wavelength of radio emission.

The indicated result is also achieved by the fact that a periodic lattice of strips in which the electrically conductive layer is removed or converted into a non-conductive one is made with a period selected from the condition: where I is the lattice period, m;

A, - wavelength of radio emission, m;

B is the minimum permissible transmittance of radio emission through a window glass with a grating deposited on it, selected within 0, 8 at: d / l 0,, 5, 5 1/10 and the angle between the direction of the grating bands and the plane in which the vector lies the electric field of the radiation passing through the grating, 90 ° ± 20 °, where d is the bandwidth, m;

5 - thickness of the conductive layer, m

The implementation of radiolucent sections only on part of the surface of the glass can significantly reduce costs and simplify the manufacture of glass. Radio transparency portions are created only in those areas through which radio emission will pass either from a transmitting antenna installed in the room or arriving at a receiving antenna. The radio transparency of a particular region is achieved by removing the electrically conductive layer in strips (or converting it into a non-conductive layer) so that a periodic lattice is formed of alternating parallel strips - electrically conductive and non-conductive. At the same time, it is advisable for glass to maintain its overall heat and light protection functions.

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so that the area of the remote conductive layer within the boundaries of the radiolucent area occupies from 10% to 50% of the area of this area.

If the bandwidth is less than 10% of the area of the radiolucent, the radiolucency may be insufficient for many practical applications, but if you remove more than 50%, this almost does not affect the increase of radiolucency, but significantly reduces the heat and light-shielding properties of glass in the created radiolucent areas.

The radio transparency of the area in which the lattice is made of alternating conductive and non-conductive strips is achieved only if the longitudinal axis of these strips are not parallel to the plane in which the electric field vector of the received or transmitted radio emission lies and reaches a maximum with mutual orthogonality of these directions.

Accordingly, to ensure stable communication, it is necessary either to properly install the receiving and transmitting equipment, or, if the equipment is already installed, it is necessary to take into account the direction of the plane of polarization of the radio emission in the aperture of the antenna and, when forming a radio-transparent section in the glass, properly orient the direction of the bands created in the electrically conductive layer bars.

Therefore, in particular cases of implementation, it seems advisable to create radiolucent sections by forming in them not one but two or more lattices so that the longitudinal axis of the bands constituting the lattice intersect at an angle. Then the requirement of non-parallelism of the longitudinal axes of the stripes of the grating of the plane in which the vector of the electric field of the radio emission lies will be satisfied automatically for at least one of the formed gratings, regardless of the polarization of the radio emission.

A special case of several gratings created within a single radiolucent section is a structure of several systems of discontinuous bands forming a multiply connected topological structure, i.e.

a closed structure of non-conducting sections, between which there are "conductivity islands with a size smaller than the wavelength of radio emission. The isolation of these “islands from each other weakens the electric current induced in them, which generates electromagnetic radiation that impedes the passage of radio waves. An example of the implementation of a closed site structure is a “cellular non-conductive structure created in an electrically conductive layer, see Fig. 3. This structure is indifferent to the polarization of radio waves, in addition, it looks aesthetically pleasing, which is also essential when used in construction.

In order to ensure the most optimal transmission of radio emission through the radio transparency portions with the minimum expenses for their formation and with the maximum preservation of the heat and light-shielding properties of the glass, it is necessary to create gratings with the following conditions:

where I is the lattice period, m;

X, is the wavelength of the radio emission, m;

B is the minimum allowable transmittance of radio emission through a window pane with a grating deposited on it, selected within 0, 8, with: d / l 0.1-5-0.5, 5 1/10 and the angle between the direction of the grating bands and the plane in which the vector of the electric field of the radiation passing through the grating lies, 90 ° ± 20 °,

where d is the bandwidth, m;

5 - thickness of the conductive layer, m

As follows from the above conditions, if you set the required coefficient of transmission of radio emission B through the glass (or rather, the required portion of the glass) and the known wavelength I of the used radio emission, then you can choose

.

the optimal parameters of the lattice being created are the strip width of the removed (or converted into a non-conducting) electrically conductive layer d and the lattice period I. In this case, the choice of optimal parameters can be carried out within the stipulated applicability conditions given above.

It should be noted that it is possible to create adjacent to each other radio-transparent sections with different periods of non-conductive bands formed in them. Due to this, it is possible, in particular, to provide apodization of the aperture of the radio antenna by arranging along its section sections with a certain selected period of the bands providing the required distribution of B over the section.

The essence of the claimed design window glass is illustrated by examples of its implementation and drawings. Figure 1 shows the window glass in plan and its cross section (two options) with a schematically and enlarged shown radiotransparent portion; figure 2 shows schematically a particular case of implementation of the design in accordance with paragraph 3 of the formula of the utility model; Fig. 3 shows schematically a particular case of the implementation of the structure in accordance with paragraph 4 of the formula of the utility model.

Window glass contains, for example, two dielectric layers 1, which are made of available transparent materials - glass, plexiglass, polymers, etc. An electrically conductive layer 2 is placed between them, which can be made of aluminum, gold, silver, tin, tin oxide, and the like. (see figa). In special cases, one dielectric layer with an electrically conductive layer deposited on it can also be used. But this implementation option is less preferable, because when washing windows, a thin conductive layer may be damaged.

The implementation case is very practical when there is an air gap between two glasses (or layers of another optically transparent dielectric material) and a conductive layer is deposited on the surface of one of the glasses facing the air gap, as shown in FIG. 16. In this case, the removal (or conversion to non-conductive) of the electrically conductive layer due to its heating by optical radiation

is the simplest, since the evaporation products of the layer have free access to the air gap.

A radio transparency section 3 is created in the glass (the boundaries are indicated by a dotted line) by removing the electrically conductive layer (or converting it to non-conductive) by parallel strips 4 so that a lattice is formed of alternating conductive strips, the longitudinal axes of which 5 should not be parallel to the electric field vector received or transmitted radio emissions. Moreover, this lattice can be formed in several ways.

For example, in the process of manufacturing glass when applying an electrically conductive layer by magnetron sputtering, you can use a mask or a template, as is widely used in photolithography processes used in the manufacture of printed circuit boards and microprocessors. In another case, a radiolucent portion may be formed in a window pane already installed in a building or structure. For this, the laser scribing technology described in / 3 / can be used, with which you can remove the electrically conductive layer in the required areas.

To convert the conductive layer into a non-conductive one, it is also possible to apply heating of the layer by optical radiation within predetermined bands. In this case, choosing the heating mode, it is possible to achieve oxidation of the conductor forming the layer. Since there are conductors that practically lose their electrical conductivity during oxidation, this procedure can ensure the formation of non-conductive strips without resorting to evaporation of the electrically conductive layer.

The most optimal parameters of the lattice created in the formed radiolucent areas can be selected from the conditions specified in paragraph 5 of the utility model formula.

For example, if to solve a specific practical problem, it is necessary to ensure the radio transparency of glass B 0.75, and the working wavelength of the radiation source is 10.7 mm (which corresponds to the frequency of 28 GHz used in local information distribution systems, the so-called LMDS systems), then we we get the estimated period of the lattice

Since there are restrictions that d / l 0, 5 and 6 1/10, it can be determined that in the manufacture of glass, the strip widths where the electrically conductive layer is removed can be from 0.22 to 1.1 mm, and the thickness of the electrically conductive layer should not exceed 0.22 mm.

Using the mathematical dependencies given in the formula of the utility model, one can also solve the inverse problem - by setting the parameters of the lattice formed in the radio transparency section, determine its radio transparency coefficient (or absorption value).

For example, it is required to determine the additional (in excess of the dielectric losses in the glass completely devoid of conductive coating) losses introduced by the grating with a period to wavelength ratio of 1 / A, 0.25 with a grating optical transparency coefficient d / l of 0.15.

From the above formula and the conditions of its applicability, it follows that the selected value of d / l falls into the allowable range, and the transmittance of radio waves B in this case exceeds B 1-1,2- (1 / X) 1-1,2-0,25 0 , 7, which corresponds to the additional losses introduced by such a grating, “1.5 dB.

Considering that typical insertion loss values for uncoated window glasses are on average 2 dB, the total radio emission power loss in this case will be less than -3.5 dB.

The proposed window glass is used as follows. When erecting a building for those premises where it is planned to install radio equipment with a known working length of radiation, glass with a prepared radiolucent area in the form of one non-conductive lattice formed in electro is produced in advance in the factory (about 1:., 2MM

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conductive layer or two intersecting gratings with the required parameters.

If the building has already been erected, is in operation, and there is a need to install radio antennas in some of the rooms, then radio-transparent sections are formed in place in the glass already installed in the window. In addition, it is possible to replace previously installed glass without radiolucent sections with glass with a radiolucent section (s) made on the basis of specific requirements (wavelength and polarization of the working radiation, installation location, minimum permissible radio transparency coefficient, etc.).

The operation of the device is not described, because It is used in statics. The basic principles of the occurrence of radio transparency in the presence of alternating conducting and non-conducting bands forming a grating on the radiation path are known from the prior art (see / 1 /, / 2 /, / 3 / or V.P. Shestopalov, A.A. Kirilenko, S . A. Masalov, Yu. K. Sirenko. Resonant scattering of waves, vol. 1. Diffraction gratings., Kiev, Naukova Dumka, 1986/4 /).

Claims (5)

1. Window glass for buildings and structures containing one or more dielectric layers and an electrically conductive layer, characterized in that its surface is provided with radio-transparent sections in which periodic parallel stripes of the same width are made, where the electrically conductive layer is either removed or converted into a non-conductive layer with a period shorter than the wavelength of radio emission, while the total area of such bands occupies 10-50% of the area of the radiolucent portion, and the longitudinal axis of each of the bands is not parallel to the plane spine, which is the electric field vector of the received and / or transmitted by radio. 2. Window glass according to claim 1, characterized in that the various radiolucent sections created within the same window can have different widths of non-conductive strips, the fill factor of the area of the plot with these strips and the orientation of the strips. 3. Window glass according to claim 1, characterized in that the strip in which the electrically conductive layer is either removed or converted into a non-conductive layer is placed within the radio-transparent section in the form of intersecting periodic gratings. 4. Window glass according to claim 1, characterized in that the strips in which the electrically conductive layer is either removed or converted into a non-conductive layer are intermittent and placed within the radiolucent region in the form of intersecting periodic gratings, which together form a multiply connected topological structure that separates an electrically conductive layer on sections isolated from each other with a size smaller than the wavelength of radio emission. 5. Window glass according to claim 1, characterized in that the periodic lattice of strips in which the electrically conductive layer is removed or converted to non-conductive is made with a period selected from the condition:

where I is the lattice period, m; λ is the wavelength of radio emission, m; B - the minimum allowable transmittance of radio emission through a window pane with a grating deposited on it, selected in the range of 0.3-0.8 for: d / I = 0.15-0.5, δ≤I / 10 and the angle between the direction of the bands lattice and the plane in which lies the vector of the electric field passing through the radiation lattice, 90 ° ± 20 °, where d is the bandwidth, m; δ is the thickness of the conductive layer, m