RU196079U1 - Insulating panel - Google Patents

Abstract

The utility model relates to the field of construction, namely, the design of the insulating panel is used to protect buildings and structures, as well as individual rooms from temperature and sound effects. The insulating panel consists of alternating straight elements and wave-shaped elements interconnected in the interface areas, with the formation of air channels bounded by direct elements and wave-like elements. Moreover, the interface areas in which a direct element and two adjacent wave-like elements are connected , are located in such a way that the projections of these interface areas do not intersect on the plane of this direct element. The technical result achieved by solving the problem is to increase the thermal properties of the insulating panel without compromising the overall dimensions and strength parameters of the insulating panel.

Description

Technical field

The utility model relates to the field of construction, namely, the design of the insulating panel is used to protect buildings and structures, as well as individual rooms from temperature and sound effects.

State of the art

The prior art various designs of insulating panels. The closest in design to the claimed utility model is a technical solution known from German patent No. DE 628814, published on 04.16.1936. To provide a better understanding of FIG. 1, FIG. 3, FIG. 3.1, FIG. 5 shows the construction of an insulating panel according to patent No. DE 628814.

The insulating panel consists of alternating straight elements 101 (1011, 1012, 1013) and wave-like elements 102 (1021, 1022), interconnected in the mating areas S, M, B, C. In the mating areas M and B, a straight element 1012 is connected and two adjacent wavy elements 1021 and 1022. In this case, the mating regions M and B are arranged so that the projections of these mating regions intersect on the plane of the straight element 1012 (shown in Fig. 5). The formed air channels are bounded by straight elements 101 and wave-like elements 102.

приведенным сопротивлением теплопередаче наружного ограждения. Для улучшения теплотехнических свойств (увеличения приведенного сопротивления теплопередаче) необходимо уменьшить тепловые потери через теплопроводные включения. Для этого необходимо увеличить пути движения теплового потока по теплопроводному включению (которым является DEFG на Фиг. 2) по сравнению с известным уровнем техники Фиг. 1, где пути движения теплового потока по теплопроводному включению является SMBC.Modern exterior walls and other fences have a complex structure in which the heat-conducting characteristics depend not only on the characteristics of the materials and thickness of the layers making up the fence, but also on the presence of internal structural connections, which are heat-conducting inclusions. In which the heat flux moves through the entire structure, making the most of the material with the highest coefficient of thermal conductivity. As a result, the enclosing structure has an inhomogeneous temperature field, which is characterized by

reduced resistance to heat transfer of the outer fence. To improve the thermal properties (increase the reduced resistance to heat transfer), it is necessary to reduce heat loss through heat-conducting inclusions. For this, it is necessary to increase the heat flux movement paths through the heat-conducting inclusion (which is the DEFG in FIG. 2) compared with the prior art of FIG. 1, where the heat flux path through the heat transfer inclusion is SMBC.

Disclosure

The technical result in the inventive insulating panel, consisting of alternating straight elements and wave-like elements interconnected in the mating areas, with the formation of air channels, each of which is limited to one straight and one wave-like element ACHIEVED THEM, which contains n + 1 direct elements and n wave-like elements, where n is any integer greater than or equal to 2, and straight elements and wave-like elements are made of wood veneer, all the conjugation areas in which the direct element and two the adjacent undulating member are arranged so that the coupling projection data areas do not intersect the plane of the straight element.

Possible clarifying features of the claimed utility model are indicated below.

In the insulating panel, straight elements have the same thickness. In an insulating panel, not all straight elements have the same thickness. In the insulating panel, straight elements have the same distance between themselves. In an insulating panel, not all straight elements have the same distance between themselves. In the insulating panel, the wave-like elements have the same thickness. In the insulating panel, not all wave-like elements have the same thickness. In the insulating panel, wave-like elements have the same waveform geometry. In an insulating panel, not all wave-like elements have the same waveform. In an insulating panel, waves in one wave-like element have the same bending geometry. In an insulating panel, not all waves in one wave-like element have the same bending geometry. In the insulating panel, alternating straight elements and wave-like elements are connected by means of an adhesive composition. In the insulating panel, alternating straight elements and wave-like elements are connected by means of fasteners. In the insulating panel on one of the inner surfaces of the air channels, reflective heat-insulating material is placed. In an insulating panel on more than one inner surface of the air channels, reflective heat-insulating material is placed. In the insulating panel on the outer surface of the panel is placed reflective heat-insulating material. In the insulating panel of one of the inner surfaces of the air channels placed film material. In the insulating panel on more than one inner surface of the air channels, film material is disposed. In the insulating panel, thermal insulation material is placed in the air channels. In the insulating panel, heat-insulating material is partially placed in the air channels.

The technical result achieved by solving the problem is to increase the thermal properties of the insulating panel without compromising the overall dimensions and strength parameters of the insulating panel.

The improvement of the thermotechnical properties of the structure due to the increase in the path of heat flow through the enclosing structure is also reflected in other building structures, for example, in a steel thin-walled thermo-profile (Figure 7.24 in SP 260.1325800.2016) or concrete stone (Figure 8 in GOST 6133-52) .

In the context of the present description, the words “straight” and “undulating” are given to provide an understanding of the presence of two types of elements. Moreover, the so-called “direct” element is essentially direct in comparison with the so-called “wavy element”. As will be clear to the specialist, in view of the properties of various materials and in view of the production technology, the “direct element” may not be absolutely straight and may have a certain undulation, however, the “wave element” will have a substantially greater undulation noticeable to the naked eye, for example, as shown in the attached figures.

Brief Description of the Drawings

In FIG. 1 is a design of an insulating panel according to patent No. DE 628814 (prior art).

In FIG. 2 design of the inventive insulating panel with the shown difference from the known design.

In FIG. 3 - a characteristic element of an insulating panel according to patent No. DE 628814 (prior art).

In FIG. 3.1 characteristic element of the insulating panel according to patent No. DE 628814 (prior art), without heat-conducting inclusions.

In FIG. 4 characteristic element of the inventive insulating panel.

In FIG. 4.1 - a characteristic element of the inventive insulating panel, without heat-conducting inclusions.

In FIG. 3 interface areas M and B of the insulating panel according to patent No. DE 628814 (prior art).

In FIG. 6 - field pairing E and F of the inventive insulating panel with the shown difference from the known design.

Description

In FIG. 2 shows a non-limiting embodiment of the inventive insulating panel. The inventive insulating panel contains 3 straight elements 201 (2011, 2012, 2013) and 2 wave-like elements 202 (2021, 2022), interconnected in the mating areas D, E, F, G. In the mating areas E and F, a straight element is connected 2012 and two adjacent wave-like elements 2021 and 2022. The formed air channels are bounded by straight elements 201 and wave-like elements 202.

The number of alternating straight elements 201 and wave-like elements 202 is not particularly limited. It should only be noted that the insulating panel contains n + 1 straight elements 201 and n wave-like elements 202, where n is any integer greater than or equal to 2. That is, the lower bound of the range of the number of elements for straight elements 201 is 3, and for wave-shaped elements 202 equal to 2.

The salient features of the claimed utility model from the prior art is that the mating regions E and F are arranged so that the projections of these mating regions do not intersect on the plane of the straight element 2012 (shown in Fig. 6). The consequence of this is that the heat path DEFG (shown in FIG. 2) will be larger than in the known construction shown in FIG. 1, where is the SMBC heat path. As a result, the reduced heat transfer resistance R _r ⁰ will be different for the known insulating panel (Fig. 1) and the inventive insulating panel (Fig. 2).

Based on GOST R 54851-2011 ("National Standard of the Russian Federation. Buildings that are heterogeneous building. Calculation of reduced heat transfer resistance"), the reduced heat transfer resistance is determined by the formula:

where And this is the area of the structure in the considered fragment, m ² ;

R ₀ is the heat transfer resistance of the homogeneous part of the structure, m ² * C / W;

L is the length of all joints in the fragment under consideration, m;

N is the number of point heat engineering heterogeneities in the considered fragment, pcs;

To this is the additional specific heat loss through a point heat engineering heterogeneity, W / C;

ψ is the additional specific linear heat loss through the joint, W / (m * C), determined by the formula:

where ΔQ ^L is the additional heat loss through the joint per one running meter of the joint, W / m. Determined by the formula:

where Q _j is the heat loss through the homogeneous filling section, which entered the computational domain when calculating the joint temperature field, W / m. Determined by the formula:

Where I _j is the length of the calculation region when calculating a two-dimensional temperature field in the direction perpendicular to the cross section, equal to 1 m;

A _j is the area of homogeneous fillings included in the calculation area when calculating the temperature field, m2;

+ t is the calculated air temperature from the side of the internal surface of the structure, ° С;

-t is the calculated air temperature from the outside of the structure, ° C;

Q ^L is the heat loss through the joint per one meter of the joint, resulting from the calculation of the temperature field, W / m. Determined by the formula:

where A _L , T, I _{L is} similar to Q _j

R is the thermal resistance of a homogeneous layer, m ² * C / W.

where δ is the layer thickness, m;

λ is the calculated coefficient of thermal conductivity of the material of the layer, W / m * C.

Compare R ^r _{0 of} two different insulating structures. The first design is the prior art (Fig. 1). The second design is the claimed utility model (Fig. 2). Both structures consist of the same material, with the same thickness of the corresponding elements. In FIG. 1 highlight the characteristic element of FIG. 3 (highlighted in bold in FIG. 1), of which the entire structure of the insulating panel consists. In FIG. 2 highlight the characteristic element of FIG. 4 (highlighted in bold in FIG. 2), of which the entire structure of the insulating panel consists.

We substitute all elements (4.3) - (4.5) into formula (4.2), and also take into account that in FIG. 3 and FIG. 4 there are no point technical inhomogeneities (therefore, ∑N * K = 0), then formula (4.2) takes the form:

Based on the illustrative examples of insulating panel designs shown in FIG. 3 and FIG. 4, the homogeneous part (without heat-conducting inclusions) has the same appearance and dimensions (that is, U, L, H ₁ , H ₂ are equal in the illustrations shown in Fig. 3.1 and Fig. 4.1), we make an assumption and all the same parts of the formula (between Fig. 3 and Fig. 4) denote as Δ:

It can be seen that in the formula R ^r ₀ in FIG. 3 and FIG. 4, only the value of R differs, therefore:

Since the known insulating panel of FIG. 3 and the claimed insulating panel of FIG. 4 as a considered, non-limiting example, are made of the same material (λ ₁ = λ ₂ ), and δ _{DEFG is} greater than δ _SMBC (heat path DEFG and SMBC, respectively), therefore, R of the inventive insulating panel in FIG. 4 is larger than R of the known insulating panel of FIG. 3. And since R ^r ₀ increases with increasing R, we conclude that R ^r _{0 of the} inventive insulating panel of FIG. 2 is greater than R ^r _{0 of the} known insulating panel of FIG. 1. Based on the foregoing, we conclude that the thermotechnical properties of the claimed insulating panel of FIG. 2 is better than the known insulating panel of FIG. 1.

A different combination: shape, size, quantity, distance between the elements is aimed primarily at an additional increase in the thermal properties of the claimed insulating panel.

In addition, reflective heat-insulating material can be placed on one of the inner surfaces of the air channels. Reflective heat-insulating material may be placed on several internal surfaces of the air channels. On the outer surface of the insulating panel, reflective heat-insulating material may be placed. As such a material, for example, foil can be used. In the note of table 7 in SP 23-101-2004 (“Code of design and construction rules. Designing the thermal protection of buildings.”), It is written that if there is a heat-reflecting aluminum foil on one or both surfaces of the air layer, the thermal resistance should be doubled . That is, the use of a reflective surface is directly related to an increase in the reduced resistance to heat transfer, therefore, it affects the improvement of thermal properties.

Similarly, film material can be placed on one or more internal surfaces of the air channels. As such a material, for example, polyethylene can be used. The film material is necessary to reduce vapor permeation and air permeation of the insulating panel, since the penetration of cold air or overmoistening of building envelopes causes an increase in heat loss. Therefore, its presence improves the thermotechnical properties of the insulating panel. In clause 8.1. SP 50.13330.2012 “Code of practice. Thermal protection of buildings. " it is written: "Protection against overmoistening of enclosing structures should be ensured by designing enclosing structures with resistance to vapor permeation ...".

Insulating material, such as basalt wool, can be placed in the air ducts.

This panel can perform both enclosing and decorative functions. To achieve various purposes, the inventive insulating panel may have a different shape, size, location, number of elements. Heat-reflecting or film materials can be placed on the inner surfaces of the air channels, and heat-insulating material can be placed in the air channels themselves. The presented improvements are aimed at improving the thermal properties of the insulating panel.

The manufacture of an insulating panel can be carried out, for example, similarly to the method known from the closest analogue. Namely, by connecting structural elements (direct elements and wave-like elements) by means of an adhesive composition. Alternatively or additionally, the connection of all or some of the structural elements can be carried out by means of fasteners. For example, staples, rivets, etc. without any restrictions.

The installation of reflective heat-insulating material and / or film material can also be carried out by means of an adhesive composition or fasteners.

Technological operations associated with the manufacture of an insulating panel are obvious to a person skilled in the art and can be performed manually, or at least partially using various technical means currently known.

The presented illustrative embodiments, examples and description serve only to provide an understanding of the claimed technical solution and are not limiting. Other possible embodiments will be apparent to those skilled in the art from the description provided. The scope of this utility model is limited only by the attached utility model formula.

Claims (20)

1. An insulating panel consisting of alternating straight elements and wave-shaped elements interconnected in the interface areas, with the formation of air channels, each of which is limited to one direct and one wave-like element, characterized in that it contains n + 1 straight elements and n wave-like elements, where n is any integer greater than or equal to 2, and the straight elements and wave-like elements are made of wood veneer, all the mating areas in which the straight element and two adjacent wave-like elements are connected lementa arranged such that the projections of these areas do not overlap at interface plane of the straight element. 2. The insulating panel according to claim 1, characterized in that the straight elements have the same thickness. 3. The insulating panel according to claim 1, characterized in that not all straight elements have the same thickness. 4. The insulating panel according to claim 1, characterized in that the straight elements have the same distance between each other. 5. The insulating panel according to claim 1, characterized in that not all straight elements have the same distance between each other. 6. The insulating panel according to claim 1, characterized in that the wave-like elements have the same thickness. 7. The insulating panel according to claim 1, characterized in that not all wave-like elements have the same thickness. 8. An insulating panel according to claim 1, characterized in that the wave-like elements have the same waveform. 9. An insulating panel according to claim 1, characterized in that not all wave-like elements have the same waveform. 10. An insulating panel according to claim 1, characterized in that the waves in one wave-like element have the same bending geometry. 11. An insulating panel according to claim 1, characterized in that not all waves in one wave-like element have the same bending geometry. 12. An insulating panel according to claim 1, characterized in that the alternating straight elements and wave-like elements are connected by means of an adhesive composition. 13. The insulating panel according to claim 1, characterized in that the alternating straight elements and wave-shaped elements are connected by means of fastening elements. 14. An insulating panel according to claim 1, characterized in that a reflective heat-insulating material is placed on one of the inner surfaces of the air channels. 15. An insulating panel according to claim 1, characterized in that reflective heat-insulating material is placed on more than one inner surface of the air channels. 16. The insulating panel according to claim 1, characterized in that a reflective heat-insulating material is placed on the outer surface of the panel. 17. The insulating panel according to claim 1, characterized in that film material is placed on one of the inner surfaces of the air channels. 18. An insulating panel according to claim 1, characterized in that film material is placed on more than one inner surface of the air channels. 19. An insulating panel according to claim 1, characterized in that heat-insulating material is placed in the air channels. 20. The insulating panel according to claim 1, characterized in that the heat-insulating material is partially placed in the air channels.

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