RU2819015C2 - Wall element - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: wall element (1) of soundproof wall, comprising frame (2) and at least outer side (4), wherein frame (2) has bearing surface (7) in direction of at least outer side (4), wherein on support surface (7) there is at least solar module (3) connected to frame (2), wherein solar module (3) is inclined relative to vertical (8) in direction of upper side (9) of wall element (1), wherein frame (2) has, on at least one outer side (4), at least sound-absorbing surface (10) directly accessible for sound, wherein sound-absorbing surface (10) is inclined at least partially relative to vertical (8) and/or relative to longitudinal direction of wall element (1), wherein the area of sound-absorbing surface (10) is at least equal to the area of the visible surface of wall element (1).

EFFECT: broader functional capabilities.

10 cl, 5 dwg

Description

The invention relates to a noise barrier wall element, wherein the wall element includes a frame and at least an outer side, wherein the frame has a supporting part relative to at least the outer side, and on the supporting side there is at least a solar module connected to frame, wherein the solar module is inclined relative to the vertical in the direction of the upper side of the wall element, wherein the frame, on at least one outer side, has at least a sound-absorbing surface directly reached by incoming sound.

The combination of noise protection parts with photovoltaic modules and the resulting overall benefits have been known in principle for a long time. The main problem with such a combination is, as a rule, the sound reflectivity of the surface of photovoltaic modules and the associated diametrically opposite direction of the necessary properties of the noise-protective part.

A way to circumvent this problem is disclosed, for example, in DE 923 18 768 U1. There, the photovoltaic laminate is located parallel to the extension plane of the noise protection part on its rear side. The front side of the noise protection part is thus not used to generate energy. Despite this, with a vertical position of the noise protection part, due to its also vertical position in this case, it is impossible to ensure optimal efficiency of the photovoltaic module.

In another case, namely not in relation to a wall element, but in relation to an existing soundproof wall, a solution to this problem is known from DE 20 2011 004 U1. It shows a soundproofing system in which several solar modules are placed on a soundproofing wall in an inclined position. The solar modules are connected in this case, regardless of the initially provided soundproofing segments, to the supporting structure, due to which the solar modules and soundproofing segments can be replaced independently of each other. However, the downside to this is that the overall installation costs of a sound wall are significantly higher than a conventional sound wall (without solar modules).

To eliminate this drawback, a combined wall element combining both functions, namely sound absorption and photovoltaic, is already known from KR 2018 0022124 A1. The costs of constructing a corresponding noise barrier wall are therefore unlikely to be higher than for a conventional sound barrier wall and additionally mainly include only the production of electrical connection points. However, the disadvantage of such a wall element is the complex structure and thus the correspondingly large number of necessary components, as well as the resulting high production costs.

DE 196 02 779 A1 discloses a wall element of the above type, which at least partially eliminates or mitigates the aforementioned disadvantages. The wall elements are formed by ready-made parts, with solar photovoltaic modules mounted on shoulders made of one part. The surface of finished parts, reached directly by horizontal sound, i.e. not blocked by the solar module, is small compared to the total visible area.

DE 297 06 785 U1 discloses a sound protection wall in which horizontal sound protection elements are secured between two vertically mounted load-bearing members. Soundproof walls are formed by rectangular non-isosceles prism-shaped bodies, stacked self-supporting in guides on load-bearing elements. The shortest side of the prism hip of each prism-shaped frame is formed by solar photovoltaic panels arranged in an anti-top direction, and the longest side of the prism hip is configured as a noise-absorbing arrangement and arranged in a downward-facing direction.

EP 1 788 155 A2 shows a noise protection wall made of lightweight structures with vertical supports fixed in the foundation and wedge-shaped noise-absorbing elements made of sound-absorbing sound-absorbing material with a weather protection ceiling. In this case, the sound-absorbing material consists of natural and renewable raw materials in the form of hay, straw or plant fibers.

The solutions known from KR 2018 0022124 A1 and DE 196 02 779 A1 are aimed at solving the above-mentioned main problem by using a wall element with a deterioration in the sound-absorbing properties of solar modules of individual wall elements due to the need to redirect sound in the corresponding chambers behind the solar modules to absorb it. Such redirection in practice is not effective enough to meet the increasingly restrictive sound absorption requirements of soundproofing walls.

The objective of the invention is to eliminate this drawback or at least reduce its impact.

The invention provides a wall element of the type indicated at the beginning, wherein the sound-absorbing surface is at least partially inclined relative to the vertical and/or relative to the longitudinal direction of the wall element, and the area of the sound-absorbing surface is at least equal to the area of the visible surface of the wall element. In this case, the sound-absorbing surface is that part of the surface of the wall element on its outer side outside the surface of at least one solar module, which is directly accessible to incoming sound, i.e. without the need to first reflect or redirect the sound. Therefore, the parts of the surface of the wall element that are protected from incoming sound by the solar module do not belong to the sound-absorbing surface. The visible surface of the wall element corresponds to the area of the contour of the wall element in a side view of the outer side. More precisely, we are talking about the visible surface of the outer side, i.e. in the viewing direction perpendicular to the vertical and perpendicular to the longitudinal extent of the wall element, at least on the outer side. Therefore, due to the at least partial inclination of the sound-absorbing surface, its area is larger than its own visible surface area. The relative difference of both areas depends on the angle of inclination. At a tilt angle of 45°, the ratio of visible surface area to surface area is approximately 1:1.4 (1 to the square root of 2). It follows from this that when approximately 71% of the visible surface is formed by a sound-absorbing surface inclined at 45° and when the remaining 29% of the visible surface is occupied by solar modules, the area of the sound-absorbing surface is at least equal to the area of the visible surface of the wall element. The outer side may be the side facing the sound. In this case, the vertical is the axis passing between the lower side and the upper side of the wall element. The designation “vertical” does not limit the use of the wall element, which is also used for inclined soundproof walls without violating the scope of paragraph 1 of the claims. In the case of a noise-protection wall installed, as a rule, obliquely, from the described wall elements, the vertical corresponds to the absolute vertical of the noise-protection wall. The vertical, for example, is perpendicular to the longitudinal direction of the wall element. The visible surface, according to the above definition, corresponds in this case to the area of the projection of the wall element onto the plane formed by the vertical and longitudinal direction.

The incoming sound (sound emission), although it reaches the sound-absorbing surface directly, but not necessarily horizontally (perpendicular to the vertical). Since most of the sound emission is expected to come from a relatively small area of the spatial angle, it is preferable that the area of the section of sound-absorbing surface directly accessible to incoming sound from the sound emission area should be (in general) at least equal to the area of the visible surface of the wall element, with the area sound emission would include the angular zone between the perpendicular to the vertical and the inclination set at 70° of this perpendicular towards the underside of the wall element. Optionally, the specified condition for the area of sections of the sound-absorbing surface can already be, in the case of the sound emission zone, an angle from the perpendicular to the vertical (hereinafter this perpendicular is briefly designated 0°) to 60° of this perpendicular in the direction of the lower side of the wall element, or an angle from 0° to 50°, or an angle from 0° to 40°, or an angle from 0° to 30°, or an angle from 0° to 20°, or an angle from 0° to 10°.

The area of the sound-absorbing surface may be approximately 1.2 or more of the visible surface area of the wall element. The increased sound-absorbing surface further improves the sound-absorbing qualities of the wall element and provides, for a given absorbent material, for example, a frame, a better degree of sound absorption (i.e., absorption of a greater volume of sound or sound energy). Optionally, the area of the sound-absorbing surface sections can be (in total) at least 1.2 times the area of the visible surface of the wall element directly reachable by sound coming from the sound emission zone.

The frame may also have an upper support surface and a lower support surface for stacking several wall elements in a stacking direction, the support surface being at least partially substantially perpendicular to the vertical, whereby, depending on the number of rows of wall elements, a noise barrier wall of varying degrees can be formed height.

According to another embodiment, the sound-absorbing surface may be perpendicular to the solar module, at least mostly covered by the solar module. Provided that the light hits the solar module perpendicularly (corresponding to optimal efficiency), the sound-absorbing surface is located at least mostly in the shadow of the solar module. This arrangement of the solar module and sound-absorbing surface ensures high utilization of incident solar energy. It does not matter whether the sound-absorbing surface passes through the solar module of the same wall element or along the vertical of a higher, adjacent or adjacent wall element.

Optionally, the sound-absorbing surface may be located in the sound-absorbing wall, including the wall element, completely in the shadow line between the upper edge of the lower solar module and the lower edge of the upper solar module. This allows the shadow of the profile of the sound-absorbing surface to avoid reducing the efficiency of the solar module.

In this regard, according to a special embodiment, the frame has, on at least one outer side outside the solar module, at least an elevation to increase the sound-absorbing surface, the outer edge of the elevation touching the shadow line or located inside the shadow line. Due to this elevation, the space within the shadow line can be optimally used to increase the sound-absorbing surface without reducing the efficiency of the solar module possibly located underneath (the same or an adjacent wall element).

Alternatively or additionally, the distance between vertically adjacent solar modules of a noise barrier wall with a wall element is selected such that the shadow line between these solar modules is located substantially perpendicular to the front side of at least the solar module. With this arrangement, the top solar module does not cast a shadow on the bottom solar module, provided that the light hits the solar module perpendicularly (optimal efficiency). In this way, optimal use of the available photovoltaic surface can be ensured.

Also in a side view of the outer side, the gap between vertically adjacent solar modules may be greater than or equal to the gap between the top edge and the bottom edge of the solar module. In other words, with this configuration, solar modules occupy 50% or less of the visible surface. This helps to avoid very flat (less than 30°) angles of inclination of the sound-absorbing surface and therefore very sharp ones (less than 60° including the angle), which can limit the material used for the frame without endangering its structural integrity.

The frame may consist, for example, mainly of sound-absorbing material. The sound-absorbing material is suitable for creating the supporting structure of the solar module. Sound-absorbing material means a material with a sound absorption degree of at least 4 dB. Sound-absorbing material is, for example, wood fiber concrete. Within the scope of the present disclosure, the frame may also consist of another sound-absorbing material, for example, porous concrete.

The invention will now be described in more detail on the basis of particularly preferred embodiments, to which it is not limited, however, and with reference to the drawings, which show:

fig. 1 is a pictorial representation of a first embodiment of the present wall element;

fig. 2 is a vertical sectional diagram of a first embodiment of the present wall element;

fig. 3 diagram of a vertical section of a noise-protective wall with wall elements located on both sides;

fig. 4 is a visual representation of a wall module with wall elements located on both sides;

fig. 5 is a visual representation of a noise barrier wall with wall elements located on both sides.

In fig. 1 and fig. 2 shows a wall element 1 of a noise barrier wall. The wall element 1 has a fiber concrete frame 2 and a solar module 3. The wall element 1 has an outer side 4 (front side). The frame 2 has on the outer side 4 two elevations 5, 6 or projections. The first elevation 5 forms, towards the outer side 4, a supporting surface 7, on which the solar module 3 is located, connected to the frame 2. The solar module 3 is inclined relative to the vertical 8 in the direction of the upper side 9 of the wall element 1.

In addition, the frame 2 has on the outer side 4 a sound-absorbing surface 10, directly reached by the sound coming from the sound emission zone in accordance with the angular limit 34 from the perpendicular (i.e. parallel to the perpendicular 32) or to an inclination 33 of 45° below the perpendicular 32 to vertical 8. The second elevation 6 is located outside the solar module 3, more precisely to the side or next to the solar module 3, and is designed to increase the sound-absorbing surface 10, and the outer edge 11 of the elevation 6 is in contact with the shadow line 12 under the solar module 3, due to which elevation 6 is located inside the shadow line. The sound-absorbing surface 10 in the direction perpendicular to the solar module 3 is completely covered by the solar module 3.

The sound-absorbing surface 10, due to the geometry of the second elevation 6 (with a triangular profile), is divided mainly into three sections 13, 14 and 15, inclined or perpendicular to the vertical 8 of the wall element 1. The area of the sound-absorbing surface 10 is greater than the area of the visible surface of the wall element 1, for example , approximately 1.2 times.

The frame 2 has an upper support surface 16 and a lower support surface 17 for stacking several wall elements 1 in the stacking direction (cf. Fig. 3). The supporting surfaces 16, 17 are located mostly perpendicular to the vertical 8.

In the described possible embodiments, the sound-absorbing surface 10 has, in addition to three inclined or horizontal sections 13, 14 and 15, also a fourth section 18, located parallel to the vertical, between two elevations 5, 6, which should prevent an acute angle between both elevations 5, which may be problematic in manufacturing, 6. The pointed end part (outer edge) of the first elevation 5 is made in the same way.

In fig. 3 shows a noise protection wall 19, in which on both sides 20, 21 several wall elements 22 are arranged vertically one above the other. The individual wall elements 22 consist of two modules 23, 24, each individual module 23, 24 corresponding to a wall element 1 according to the embodiment of FIG. 1 and 2 and both modules 23, 24 have a common solid frame 25, due to which the two modules 23, 24 form a wall element 22 (respectively with two solar modules). The noise barrier wall 19 has a load-bearing core 26, for example, made of reinforced concrete or a lightweight frame structure between steel posts (the gap between, for example, 165, 200 or 500 cm), as well as a basement area 27 made of concrete.

The distance between the solar modules 3 adjacent in the vertical direction of the noise barrier wall 19 is selected so that the shadow line 12 between these solar modules 3 is generally perpendicular to the outside of the parallel solar modules 3 in this example. In a side view of the outside 4 (not shown, but visible in the profile shown), the gap between vertically adjacent solar modules 3 (eg 14 cm) is greater than or equal to the gap between the top edge 28 and bottom edge 29 of the solar module 3 (eg 11 cm). The sound-absorbing surfaces 10 of the wall element 22 are located entirely within the shadow line 12 between the upper edge 28 of the lower solar module 3 and the lower edge 29 of the upper solar module 3.

The wall elements 22 (with a module height of, for example, 25 cm and a corresponding element height, for example, 50 cm) are stacked, whereby the supporting surfaces 16, 17 of adjacent wall elements 22 touch each other. The width of the solar modules 3 is, for example, 16.5 cm. The individual wall elements 22 are connected to the supporting frame 26, for example glued or screwed.

In fig. 4 shows a diagram of a section of the noise-protective wall 19 in accordance with the wall module. The wall module includes a frame section 26. On both sides 20, 21 of each frame section there is a wall element 22 with a solid frame 25. Each edging element has two modules 23, 24, each equipped with a solar module 3. The shown wall module has dimensions along vertical 8 (height) is approximately 50 cm. Each module 23, 24 or each row of modules is approximately 25 cm in height. The height of the solar modules 3 is approximately 16.5 cm. Alternatively, it is proposed that a wall module of this height have three rows of modules , and the width of the solar modules was approximately 12.5 cm. But there is the possibility of a wall module with only one row of modules, for example 25 cm high.

In fig. 5 shows a visual view of a noise-protective wall 19 with wall elements on two sides, similar to FIG. 3.

The noise-protective wall 19 in the longitudinal direction has sections limited, respectively, by support posts 30 fixed in the ground. The longitudinally adjacent sections 31 of the noise barrier wall in FIG. 5 are shaded to show the continuation of the noise wall with row repetitions or a sequence of several sections of the noise wall.

Claims (10)

1. Wall element (1) of a noise-protective wall, containing a frame (2) and at least an outer side (4), wherein the frame (2) has a supporting surface (7) in the direction of at least the outer side, and on the supporting surface (7 ) there is at least a solar module (3) connected to the frame (2), and the solar module (3) is inclined relative to the vertical (8) in the direction of the upper side (9) of the wall element (1), and the frame (2) has on at least one outer side (4) at least a sound-absorbing surface (10) directly accessible to sound, characterized in that the sound-absorbing surface (10) is inclined at least partially relative to the vertical (8) and/or relative to the longitudinal direction of the wall element (1), and the area of the sound-absorbing surface (10) is at least equal to the area of the visible surface of the wall element (1). 2. Wall element (1) according to claim 1, characterized in that the area of sections of the sound-absorbing surface (10) directly accessible to sound coming from the sound emission zone is at least equal to the area of the visible surface of the wall element (1), wherein the sound zone emission includes the angular limit between the perpendicular and an angle of 70° from this perpendicular towards the underside of the wall element. 3. Wall element (1) of a wall according to claim 1 or 2, characterized in that the area of the sound-absorbing surface (10) corresponds to approximately 1.2 or more of the visible surface area of the wall element. 4. Wall element (1) according to any one of paragraphs. 1-3, characterized in that the frame (2) has an upper support surface (16) and a lower support surface (17) for stacking several wall elements (1) in the stacking direction, wherein the support surface (16, 17) is located at least partially, substantially perpendicular to the vertical (8). 5. Wall element (1) according to any one of paragraphs. 1-4, characterized in that the sound-absorbing surface (10) in the direction perpendicular to the solar module (3) is covered at least mostly by the solar module (3). 6. Wall element (1) according to any one of paragraphs. 1-5, characterized in that the sound-absorbing surface (10) in the noise-protective wall including the wall element (1) is located entirely within the shadow line (12) between the upper edge (28) of the lower solar module and the lower edge (29) of the upper solar module . 7. Wall element (1) according to claim 6, characterized in that the frame (2) has at least an elevation (6) on the outer side (4) outside the solar module (3) to increase the sound-absorbing surface (10), wherein the outer edge (11) of the elevation touches the shadow line (12) or is located inside the shadow line (12). 8. Wall element (1) according to claim 6 or 7, characterized in that the gap between the solar modules (3) adjacent in the vertical direction (8) of the noise-protective wall with the wall element (1) is selected so that the shadow line (12) was located between these solar modules (3), essentially perpendicular to the front side of at least the solar module (3). 9. Wall element (1) according to any one of paragraphs. 1-8, characterized in that in the side view of the outer side (4) the gap between the solar modules (3) adjacent in the vertical direction (8) is greater than or equal to the gap between the upper edge (28) and the lower edge (29) of the solar module (3 ). 10. Wall element (1) according to any one of paragraphs. 1-9, characterized in that the frame (2) consists essentially of sound-absorbing material, preferably wood-fiber concrete.