RU129976U1 - VACUUM GLASS PACKAGE - Google Patents

Abstract

A vacuum double-glazed unit, comprising at least two glass plates connected by a sealing seam, placed relative to each other with a gap formed by separation elements, characterized in that the separation elements are located over the area of the glass unit with an increase in the step between them as they approach the perimeter of the glass unit.

Description

The utility model relates to the field of construction and can be used in the design and manufacture of double-glazed windows to provide windows for industrial buildings, residential buildings, etc.

The most promising double-glazed windows providing the highest resistance to heat transfer are vacuum double-glazed windows.

Vacuum double-glazed windows are two glass plates located at a distance from each other, hermetically connected around the perimeter by means of a sealing seam to form a closed volume from which the atmosphere is pumped out to the required vacuum. The gap between the glass plates is fixed by a system of dividing elements, ensuring the mechanical strength of the glass.

In this regard, in the manufacture of double-glazed windows, there are a number of structural and technological problems associated with sealing, the location of the separation elements, a decrease in heat transfer resistance through the separation elements, and a decrease in transparency due to the separation elements.

Minimizing the number of separation elements will increase the transparency of the glass, increase the heat transfer resistance through the separation elements, simplify the technology of manufacturing the glass.

Known double-glazed window containing two glass plates, the distance between which is fixed by a separating element located along the perimeter of the double-glazed window at the sealing joint [RF patent No. 2211296, ЕВВ 3/66, ЕВВ 5/10, Е04С 2/54, 2001]

In this design, the absence of dividing elements over the area of the double-glazed window leads to a decrease in mechanical strength, resistance to external factors, such as, for example, wind pressure.

Known vacuum double-glazed window, consisting of at least two sheets of window glass, connected along the perimeter by a sealing seam to form a closed volume, in which the dividing elements are uniformly placed, fixing the distance between the sheets of window glass [RF patent No. 2165510, ЕВВ 3/66, 2001]

The disadvantage of this design is a significant number of separating elements evenly spaced over the entire area of the glass packet, which leads to a decrease in heat transfer resistance, lower strength, and more complicated assembly technology.

Closest to the proposed technical solution is a vacuum double-glazed window, comprising at least two glass plates connected by a sealing seam, placed relative to each other with a gap formed by dividing elements [RF patent No. 51788, 25-01, 25-02, 2003 . - prototype].

The disadvantage of this design is the presence of a large number of separation elements evenly distributed over the entire area of the double-glazed window, which leads to a decrease in heat transfer resistance to 0.45 m ² · K / W, lower strength, more complicated assembly technology.

The objective of the utility model is to create a design of a vacuum double-glazed window, which allows to increase the transparency of the double-glazed window, to increase the heat transfer resistance of the double-glazed window, to simplify the technology of its manufacture.

The specified technical effect is achieved by the fact that in the known vacuum glass unit, which includes at least two glass plates connected by means of a sealing seam, arranged relative to each other with a gap formed by the separation elements, the separation elements are located over the area of the glass unit with increasing step between them as approach to the perimeter of the glass.

Increasing the step as you approach the perimeter of the glass unit is possible due to the fact that the perimeter is formed by a sealing seam, which in itself is a rigid dividing element that fixes the distance between the glass plates. In this regard, in the area of the sealing seam, the dividing elements can be positioned in large increments. As you approach the center of the double-glazed window, the density of the spacer elements must be increased, since the effect on the design stiffness of the sealing joint decreases.

Due to the reduction of the dividing elements, heat loss is reduced, the transparency of the glass packet is increased, the manufacturing technology is simplified.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, made it possible to establish that the applicant did not find an analogue characterized by features identical to all existing features of the claimed utility model, and the determination from the list of identified prototype analogues revealed a combination of significant to the applicant's perceived technical result of the distinguishing features in the claimed object, set forth in the utility model formula. Therefore, the claimed utility model meets the requirement of "novelty" under current law.

The proposed design of the glass is illustrated by drawings.

In figure 1, figure 2 presents one of the variants of the claimed vacuum glass.

The double-glazed window (Fig. 1, Fig. 2) contains two glass plates 1 and 2, which are sealed around the perimeter by a sealing seam 3, consisting of a vacuum-tight material, for example, fusible glass or glass cement. The gap between the glass plates is formed by a system of dividing elements 4 located in increments, which is determined by the size of the glass unit, the thickness of the glass plates, the size of the separation elements, and the degree of evacuation of the glass unit. With the small size of the double-glazed unit, the stiffness of the sealing joint extends to the entire area of the double-glazed unit, so the increase in the step between the dividing elements starts from the center of the double-glazed unit. With large glass units, the effect of the sealing joint is limited to a certain peripheral zone in which the step between the spacer elements can be increased. In the inner zone, where there is no influence of the sealing joint, the step between the dividing elements should be equal (the same).

Examples of specific performance.

Example 1

Two glass plates with a size of 600 × 600 mm and a thickness of 4 mm are connected around the perimeter by a seam of sealing from fusible glass. The gap between the glass plates of 0.75 mm is formed by dividing elements from dielectric spacers. The spacing of the separation elements in the center of the glass unit is 20 mm and when approaching the perimeter of the glass unit increases to 100 mm. The tight volume between the glass plates is pumped out to a vacuum at a pressure of 1 · 10 ^-5 mm Hg. The heat transfer resistance of such a double-glazed unit is 0.56 m ² · K / W.

Example 2

Two glass plates with a size of 1200 × 1200 mm and a thickness of 4 mm are connected around the perimeter by a seam of sealing from fusible glass. The gap between the glass plates of 0.75 mm is formed by dividing elements from dielectric spacers. The spacing of the separation elements in the center of the glass unit is 20 mm and when approaching the perimeter of the glass unit increases to 150 mm. The tight volume between the glass plates is pumped out to a vacuum at a pressure of 1 × 10 ^-5 mm Hg. The heat transfer resistance of such a glass unit is 0.63 m ² · K / W.

Thus, the proposed technical solution allows to increase the heat transfer resistance, the transparency of the glass, simplifies the assembly technology.

Claims (1)

A vacuum double-glazed unit, comprising at least two glass plates connected by a sealing seam, placed relative to each other with a gap formed by separation elements, characterized in that the separation elements are located over the area of the glass unit with an increase in the step between them as they approach the perimeter of the glass unit.

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