RU10413U1 - WINDOW BLOCK - Google Patents

Abstract

1. A window unit containing a binding, a light-transmitting glazing material and a translucent heat-reflecting coating located along the opening height, characterized in that the translucent heat-reflecting coating has a thickness δ uneven in the glazing height and blackness ε, respectively determined by the formulas where x is the distance from the lower border of the light transmission from the condition 0 <x <h; h is the height of the area with a heat-reflecting coating; δ is the deposition thickness at a distance x; δ is the deposition thickness at the lower point of the glazing, x = 0; ε is the local the degree of blackness of the translucent heat-reflecting coating at a distance x; ε is the local value of the degree of blackness of the translucent coating at the lower point of the glazing, x = 0; A, B, m, n are constant coefficients determined from the condition of preservation of the standardized lighting parameters of the room upon reaching the greatest effect increase thermal protection (m ≥ 0, n ≥ 0) .2. The block according to claim 1, characterized in that the translucent heat-reflecting coating is formed by sputtering and has a density that decreases with distance from the lower edge of the glazing. The block according to claim 1, characterized in that the translucent heat-reflecting coating is made in the form of a predominantly shrink film and is fixed on the binding from the outside and / or inside by spot fasteners or using a spacer frame or double-sided adhesive tape or glue. The block according to claim 1 or 3, characterized in that the translucent heat-reflecting coating is multilayer.

Description

The utility model relates to designs of windows with single binders with single and double-chamber double-glazed windows, separate and paired binders, installed in the window openings of buildings.

The closest known block is a window block containing a binding, translucent glazing material and a translucent heat-reflecting coating located along the height of the opening (RU patent No. 2091557, class E 06 B 9/00, 1997).

A disadvantage of the known window unit is that the thermal barrier coating has low light transmission. When applying a heat-resistant coating with a low degree of blackness

(f 0.2) on glass or film, their light transmission is significantly (from 20 to 80%) and the level of illumination on the working surface of the room decreases. This design is the closest to the invention in technical essence and the achieved result.

The technical result of use is to increase the thermal resistance of window blocks with

single bindings with one- and two-chamber with hexapacks,

separate, paired bindings without loss of illumination on a working surface remote from the light beam.

IPC 6: E On at 9/00 Window unit

 practically

This is achieved by the fact that in the window block containing

binding, translucent glazing material and a translucent heat-reflecting coating located along the opening height — the translucent heat-reflecting coating has a 5x thickness uneven in the glazing height and blackness

ECG determined, respectively, by the formulas: 5x 5o + A ()

EX So + B (),

h (i, 2) where: X is the distance from the lower boundary of the light transmission from the condition

0 X h (i, 2) r

HI, NC - the height of the plot with a heat-reflecting coating,

5x - spraying thickness at a distance X,

5 ° - spraying thickness at the lower point of the glazing,

EX - local value of the degree of black translucent

heat-reflecting coating at a distance of X, BO - the local value of the degree of black translucent

coatings at the lower point of the glazing, A, B, t, n - constant coefficients, determined from the condition of preservation of the normalized lighting parameters of the room when the greatest effect of increasing thermal protection (t O,) is achieved. In this case, a translucent heat-reflecting coating can be formed by spraying and has a decreasing

X

removal from the lower edge of the glazing density. Translucent

heat-reflecting coating It can be made in the form of mainly heat-shrinkable film and fixed on the binding from the outside and / or inside by spot fasteners or using a spacer frame or double-sided adhesive tape or glue. In addition, the translucent heat-reflecting coating can be multilayer.

The utility model is illustrated by drawings, where:

- figure 1 shows a window unit with a single wooden binding and a single-chamber double-glazed window with an uneven heat-reflecting coating,

- figure 2 shows a window unit with a single wooden binding and a two-chamber double-glazed window with an uneven heat-reflecting coating,

-Fig. 3 shows a window unit with separate wooden binding and translucent material fixed to an external binding with an uneven heat-reflecting coating,

- figure 4 shows a window unit with separate wooden

binding and single-chamber double-glazed window with uneven heat-reflecting coating on the inner binding,

- figure 5 shows a window unit with a paired wooden binding and fixed to an external binding translucent material with an uneven heat-reflecting coating,

- figure 6 shows a window unit with a paired wooden binding and fixed to the inner binding

I

- Fig.7 shows a window unit with a paired wooden

binding and single-chamber double-glazed window in the inner binding with an uneven heat-reflecting coating.

The construction of a window with single binders with one- (1) and two-chamber (2) double-glazed windows, separate, paired binders with an uneven selective heat-reflective coating (3) applied to the lower part of the glazing (4) has high heat-and-technical properties while observing standardized lighting parameters. The height, light transmission coefficient and degree of blackness of the spraying is determined from the condition of preservation of the lighting properties at the design points of the room and the maximum allowable increase in thermal resistance of the structure. As is known, the distribution of the brightness of the cloudy sky obeys the Moon-Spencer law (Architecture of civil and industrial buildings, Vol. 2 Design Basics, edited by V. Predtechensky, M., 1976) and a decrease in the light transmission of the lower part of the glazing to a much lesser extent to reduce lighting properties in the design points of the room remote from the light beam. Due to a gradual decrease in the density of deposition (as you move away from the lower edge of the glazing), the light transmission increases, practically without affecting the optical perception of the outer space and without reducing the level of illumination at the calculated point

premises. At the same time, the lower part of the glazing has the most

low temperature and the most dangerous in terms of condensation and ice formation. The application of an uneven heat-reflecting coating on the lower part of the glazing will make it possible to increase and equalize the temperature of the inner surface of the glazing. This technical result is “-. i, .- ,; “F - iVGLL - V --.- V- -; t 5 is achieved due to the fact that one or two layers of heat-reflecting coating of uneven thickness is applied to one of the glazing layers, depending on the design of the binding (see Fig. 1-7). The greatest thickness is in the lower part of the glazing. The spraying height is determined from the condition of preservation of the standardized lighting parameters at a point remote from the light apertures. The greatest thickness of the spraying is in the lower part of the glazing. In the cases depicted in Fig. 3,5, b, a translucent material with a heat-reflecting coating applied is fixed on the binding from the outside (Fig. 3,5) or the inside (Fig. 6) of the side by point fasteners using a spacer frame or with a double-sided adhesive tape ( maybe just glue). It is advisable to use shrink film. The use of windows in single, twin and separate bindings with non-uniform heat-reflecting coatings applied significantly increases the thermal resistance of the structure, practically without reducing its lighting characteristics. An example of the use of formulas for calculating the thickness of a translucent heat-reflecting coating and its degree of blackness Let us consider the simplest option: on glass, the degree of blackness of which is 94, at a height of 5ho (where ho is the height of the translucent material), a reflective coating uniformly decreasing by linear law is applied (n 1, m 1). The thickness of the single-layer heat-reflecting coating at the lower point of the glazing x - O - 6o 0.0001m, the degree of blackness at the bottom glazing H1ya X - O - EO O, I. Then: A X5oEO X 5, - 0.0001 (-) + 0 , 0001, m, EX 0.1 + 0.84 (-).

Claims (4)

1. The window unit containing a cover, a translucent glazing material and a translucent heat-reflecting coating located along the height of the opening, characterized in that the translucent heat-reflecting coating has an uneven thickness of the glazing thickness δ _x and the degree of blackness ε _x determined respectively by the formulas

where x is the distance from the lower boundary of the light transmission from the condition 0 <x <h;
h is the height of the area with a heat-reflecting coating;
δ _x - spraying thickness at a distance x;
δ _o - spraying thickness at the lower point of the glazing, x = 0;
ε _x is the local value of the degree of blackness of the translucent heat-reflecting coating at a distance x;
ε _o is the local value of the degree of blackness of the translucent coating at the lower point of the glazing, x = 0;
A, B, m, n - constant coefficients, determined from the condition of preservation of the normalized lighting parameters of the room upon reaching the greatest effect of increasing thermal protection (m ≥ 0, n ≥ 0).  2. The block according to claim 1, characterized in that the translucent heat-reflecting coating is formed by spraying and has a density that decreases with distance from the lower edge of the glazing.  3. The block according to claim 1, characterized in that the translucent heat-reflecting coating is made in the form of a predominantly shrink film and is fixed on the binding from the outside and / or inside by spot fasteners or using a spacer frame or double-sided adhesive tape or glue. 4. The block according to claim 1 or 3, characterized in that the translucent heat-reflecting coating is multilayer.