SE529198C2 - Glazed door, has glazing unit in tight contact with profiled section of insulation layer extending around opening in door - Google Patents

Abstract

The insulation layer around the opening in which the glazing unit is mounted comprises a profiled section for locating the unit in such a way that a tight seal is formed between this section and the unit abutting against it.

Description

fw 15 20 .25 529 198 2 The present invention relates to a glazed door and a method of glazing the door.

The door consists of a laminate comprising a first outer layer, a second outer layer and an insulating layer therebetween. The door also includes. a »glass unit framed in a hole through the door that is almost continuous. The invention is characterized in that the insulating layer around the through-hole comprises an enamelled portion arranged to receive the glass unit in such a way that the insulating layer and the glass unit lie against each other and form a sealing joint.

An advantage of the invention is that the insulating layer seals directly against the glass unit and forms a waterproof and windproof unit without the use of sealant and without the use of a specially formed frame between the two outer layers.

The hole in the insulating layer advantageously comprises a first through-opening smaller than a second through-opening, the difference in size bidding the profiled portion. The insulating layer consists of a resilient and self-supporting material, which gives the advantage that the insulating material is easily processed, whereby the proliferation becomes easy to adapt f 'for different types of glass units. In the prior art glazing, the-circumferential wooden frame must be adapted for each profile and, in addition to the above-mentioned disadvantages, it is difficult to manufacture such a wooden frame for certain geometries of the glass unit, e.g. for geometries that are oval, round, etc.

During glazing, a through hole is made in the door in such a way that the first outer layer obtains a first opening smaller than a second opening in the second outer layer. The first opening in the first outer layer is adapted for the first opening in the insulating layer and the second opening in the second outer layer is adapted for the second opening in the insulating layer. In the manufacture of the door, the first openings can be made in a common process step and the second openings in another common process step. The first openings can for example be milled from the first outer layer 10 G 20, and from a part of the insulating layer. The other openings can be milled from the second outer layer in a similar manner. from a remaining part of the insulating layer.

According to one embodiment of the invention, the first outer layer covers the entire insulating layer and the second outer layer covers only a part of the insulating layer. The first outer layer thus covers everything without the first opening in the insulating layer and the second outer layer covers everything without the outside. second opening in the insulation layer. Because the second opening is larger than the first opening, the second outer layer does not cover the profiled part.

The glass unit advantageously consists of at least two glass sheets, each of which has a two-dimensional extent delimited by a circumferential edge.

Each glass sheet has a certain thickness in a third dimension and thus comprises two flat sides facing each other. ~ The glass sheets are 'assembled along the edges with. a circumferential and sealing strip. The strip acts as a spacer element and provides a space between the glass sheets, which space can be filled with a gas at a pressure above, below or at atmospheric pressure. The gas may consist of air or other gas suitable for insulation, e.g. argongas. Such glass units are already known and may consist of fl more than two glass sheets. The glass unit can also consist of a single glass plate without a strip.

To simplify the understanding of the description, the design of the door is given as follows: The door has a main distribution in a vertical direction and a horizontal direction, which are perpendicular to each other. The door also has a thickness in a third direction perpendicular to the other two directions, the three directions forming an orthogonal three-dimensional system. The choice of the terms vertical and horizontal year made based on how the door can be described when it is mounted in a doorway, e.g. in a housing, and is not to be construed as limited to such a position but is intended solely to describe the door, whether or not the door is positioned with the vertical portion aligned with the gravitational field or at an angle to the gravitational field. 10 115 20 25 30 i 529 198 4% With the above-mentioned fi nition, the glass unit has a spread in a vertical and horizontal direction when it is -mounted in the door, or kept parallel to the door, and a thickness that coincides with the direction of the door thickness, dv-s. _in the third direction. The glass sheets together with the strips also provide edge sides of the glass unit, which extend in a direction coinciding with the thickness of the glass unit and one or both of the vertical and horizontal directions. When the glass unit is square, two of the edge sides have an extent that coincides with the thickness of the glass unit and the vertical direction, and the other two edge sides have an extent that coincides with the thickness of the glass unit and the horizontal direction. For other geometries, e.g. triangular, pentagonal, hexagonal, etc., has at least one edge side to an extent which coincides with the thickness of the glass unit »and one; diagonal direction at an angle to both the horizontal direction and the vertical direction.

The glass unit and thus the hole in the door can be of any geometric shape in the extent of the door, e.g. rectangular, triangular, oval, round, polygonal, etc .. hence the possible directions indicated by the edge sides above.

According to one embodiment of the invention, the insulating layer is formed "with a profiled portion which gives the insulating layer a portion with a shaped cross-section (hereinafter referred to as the L-shaped portion) around the hole. , with an extension in the vertical direction and the horizontal direction adjacent to the first opening in the first layer. The insulating layer has a predetermined thickness which consists of the space between the two outer layers and is larger than the first thickness. The insulating layer is formed with a second section extending in the third direction and the vertical direction as well as in the third direction and the horizontal direction. The second section has an extension in the third direction which is the difference between the "advanced" thickness and the * first thickness. The first section is a part of the L-shaped portion and the second section is the second part which is _w 15. ao 25 529 198 5 perpendicular to the 'first part.' The first thickness and the extent of the first section in the vertical and horizontal directions can be varied depending on the design of the glass unit. The glass unit is arranged in the profiled portion in such a way that one flat side of the glass unit is pressed against the first section of the insulating layer and forms a sealing joint.

The above advantages are thus "obvious" since a windproof and waterproof unit is formed by the contact surface between the glass unit and the insulating material ".

The following process steps are examples of how the glazing can be carried out: -The door is formed by manufacturing a rectangular first and second outer layer and an insulating layer based on advanced material. The different layers have the same size and are joined together to form a laminate with the same shape as the different 'layers'. The hole is then taken up by a suitable process, Lex. by milling. The first opening; is taken up in a first size together with the formation of the first section of the insulating layer with a corresponding size in the vertical and horizontal direction as the 'first' opening by removing further selected parts of the insulating layer.

The second opening is taken up in the second layer and the insulating material with a second size larger than the first size, the part of the insulating layer constituting the second section being formed by removing selected parts of the insulating layer. The L-shaped portion of the insulating layer is hereby formed. In an embodiment of the invention, moreover, the glass unit and the hole in the door can be adapted in such a way that a negative clearance is obtained between the glass unit and the second section. The glass unit is then pressed into the opening, whereby the insulating material yields to such. such that the second section seals against the edge sides of the glass unit, the glazing method providing the unit with a sense of wind and waterproof ability. The embodiment is not limited to a negative play, but the profiled portion can be designed in such a way that the glass unit fits exactly, i.e. with a zero game.

Since the insulating layer is made of an airy material and the glass unit of a hard material, it can be difficult to; obtain exact fit, but. the design of the profiled section always provides a better fit for the glass unit than a corresponding trawl strip would do. Although the second section does not exactly correspond to the edge sides of the glass unit, a sealing joint is obtained between the two units which reinforces the sealing joint between the first section and the flat surface of the glass unit.

According to another embodiment of the invention, the L-shaped portion of the insulating layer is formed by two insulating layers with different sized holes. The apertures may be concentric, but may also be offset from each other.

During manufacture, the two insulating layers form a laminated insulating layer that can be manufactured separately, after which lamination with the two outer layers takes place.

Alternatively, all four layers can be laminated at the same time.

According to one embodiment of the invention, no L-shaped portion is present in the insulating layer, but an L-shaped portion is formed in the door by having a smaller hole in the insulating layer than the second outer layer, the thickness of the second outer layer being the first section. the L-shaped portion and where the thickness of the second outer layer constitutes the second section of the L-shaped portion. The glass unit is here included in the outer layer opening in such a way that the flat side of the glass unit abuts against the insulating layer in such a way that the insulating layer seals against the glass unit.

In all of the embodiments described above, the first outer layer preferably has a hole received which corresponds to the hole in the insulating material and the first layer can thus be considered to form part of the first section of the L-shaped portion. An advantage of this is that the first external. the layer reinforces the glazing structure in that the first outer layer abuts the insulating layer and absorbs forces directed towards the insulating layer in the third direction, i.e. in the thickness of the door, via the first section. This is particularly advantageous from a burglary point of view because the glass unit, from the outside of a housing, cannot be pushed through the hole in the door if the first outer layer is placed against the housing because the insulating layer and the first outer layer act as a stop.

However, the invention is not limited to having the first outermost layer towards the housing as above, but the first outer layer can advantageously be wetted from the outside. the house. An advantage of the latter embodiment is that the seal between the profiled portion of the insulation layer and the glass unit faces out from the housing. This means that water and wind are prevented from penetrating into and through the door already at. the outermost layer. In the case where the outer layer faces the opposite housing, the insulating layer and the second outer layer form a sealing joint which prevents water and wind from penetrating between these two layers. The insulating layer and the glass unit form via the profiled part a sealing joint as above which prevents water and wind from penetrating into and through the door. The sealing joint may consist of the glass unit and the first section, or the glass unit and the first section together with the second section.

Regardless of which side: of the door facing out of the house, a waterproof and windproof door is obtained with the advantages stated above.

By windproof 'is meant that moving air on one side of the door can not' pass 'the door in such a way that air on the other side of the door is affected to' move, but that air may possibly diffuse through the door depending on the choice of material of the different layers.

The glass unit can advantageously be secured in the hole by a number of strips which are fastened in the second outer layer in such a way that the strip abuts against the glass unit which is thereby retained in the hole between the strip and the first section. Since the insulating material seals against the glass unit, no sealant needs to be used to seal the strips. Additional strips can be applied to the first outer layer to increase the aesthetic impression, but these strips have no functional significance with regard to water * and wind tightness because the insulation layer seals against the glass unit according to the invention. Porous insulation can be used in the door. -trä fi ber-board; cellular plastics such as polystyrene, polyurethane; Phenol, PVC, Acrylic, cellular plastic, etc. as well; mineral wool, glass wool or rock wool; foam glass; cork straw; adhesive chipboard; etc. The thickness of the insulation layers should be between 30 "- 80 mm, but may vary depending on the environment of use of the door and the material included in the door. The insulation layer also advantageously has an extent I corresponding to the extent of the first outer layer and the second outer layer: or individually comprise any of or combinations notwithstanding: wood, aluminum, plywood, MDF (Medium oensity Fiberboard), HDF (Eng. High Density Fiberboard), elas fi ber, Pvo, aluminum sheet, sheet steel.The outer layers may also include fl era layers of different materials, eg with plywood and aluminum and / or sheet metal etc.

Defuter layers are dimensioned based on the choice of material in the door and can be at least 0.7 mm in the case of a steel door and can advantageously be 3-12 mm or more in the case of a plywood door.

DESCRIPTION OF FIGURES The invention will be described below in connection with a number of figures where: Fig. 1 schematically shows a glazed door according to the invention; Fig. 2 schematically shows a cross section of the door frame 1 along the line A-A according to a first embodiment of the invention, and there; Fig. 3 schematically shows a cross section of the door frame 1 along the line A-A according to a second embodiment of the invention, 10 15 20 25 i 5 2 9 1 9 8 9 BRIEF WRITING OF EXAMPLE EXAMPLE. V Fig. 1 schematically shows a glazed door 1 according to the invention. The door 1 consists of a laminate comprising a first outer layer 2, a second outer layer 3 and an insulating layer 4 therebetween. The door 1 further comprises a glass unit 5 framed in a hole 6 in the door 1 which is substantially continuous in the door 1. The door 1 i has a main extension in a vertical direction, the Y-joint in the figure, and a horizontal direction, the X-joint in the clock, which are perpendicular to each other. The door 1 also has a thickness in a third direction, the Z-joint, perpendicular to the two other directions, the three directions forming an orthogonal three-dimensional system.

Fig. 2 'schematically shows a cross-section of the door 1 in Figure 1 along line A-A' according to a first embodiment of the invention. The glass unit 5 comprises two glass sheets 7, each of which has a two-dimensional extent delimited by a circumferential edge 8. Each glass sheet has? has a certain thickness in the Z-direction and thus comprises two flat sides 9 ,. »10- facing each other.- The glass sheets 7 years assembled along. the edges 8 with a circumferential and corroding strip 11. The strip 11 acts as a spacer element and forms a gap between the glass sheets 7 and circumferential edge sides 12, 13.

The glass unit 5 is mounted in the door and thus has a spread in an X-joint and a Y-joint and a thickness in a Z-joint. The glass unit 5 is square and the glass sheets 7 together with the strips 11 form two pairs of parallel edge sides 12, 13 of the glass unit. A pair of the edge sides '12 have an extension in the Z-direction and the X-joint, the other pair of edge sides 13' having an extension in the Z-direction and.

Y-led. In other geometries of the glass unit 5, e.g. triangular, pentagonal, hexagonal, etc., at least one of the edge sides has a different width than those indicated above and which may coincide with the thickness of the glass unit and a diagonal direction at an angle to both the X-joint and the Y-joint. a profiled portion 14 arranged to receive the glass unit 5 in such a way that the insulating layer 4 'and the flat side 9 of the glass unit 5 abut against each other and form a connecting joint.

The hole 6 in the insulating layer 4 advantageously comprises a first through-opening 15 smaller than a second through-opening 16, the difference in size biding the profiled portion 14. Figure 2 'shows that a through-hole 6 is taken up in the door 1 in such a way that it the first outer layer 2 obtains a first opening 17 smaller than a second opening 18 in the second outer layer 3.

The first opening 17 in the first outer layer 3 is adapted for the first opening 15 in the insulating layer and the second opening 18 in the second outer layer 4 is adapted for the second opening 16 in the insulating layer 4. In the manufacture of the door 1, the first the openings 15, 17 are made in a common process step. and the other openings 16, 18 in another common process step. The first openings 15, 17 can e.g. milled from the first outer layer 2 and from a part of the insulating layer. 4. The second openings 16, 18 can be milled in the same way from the second outer layer 3 and from a remaining part of the insulating layer 4. Figure 2 shows that the first outer layer 2 covers the entire insulating layer 4 and; that the second outer layer 3 covers only a part of the insulating layer 4.

The opening is not limited to this, but both the first opening 17 in the outer layer 2 and the second opening 18 - in the second layer 3 can be made larger or smaller than the corresponding openings 15, 16 in the insulating material 4. Figure 2 shows that the insulating layer 4 is formed with a profiled portion 14 which gives the insulating layer 4 a portion with an L-shaped cross-section (hereinafter referred to as the L-shaped portion) around the hole 6. The L-shaped portion 14 thus provides an insulating layer 4 with a first thickness 19 in a first section 20 with a distribution in the XY plane adjacent to the first opening 15 in the first layer 2 and adjacent to the first opening 17 in the insulating layer 4. the insulating layer 4 has a predetermined thickness 21 which is constituted by the space between the two outer layers 2, 3 and is larger 'end ïw 215 20 25 30 529 198 11 first thickness 19. The insulating layer -4 is formed with a second section 22 with a spread which. essentially corresponds to glass unit edge sides 12, 13, i.e. a distribution in Z-joints and X-joints as well as in Z-joints and Y-joints. The second section 22 has an extension in the Z-direction which constitutes the difference between the predetermined thickness 21 and the first thickness 19 .: The first section 20 constitutes the part of the L-shaped portion which has an extension in the door, 1. 'direction of extension. and the second section 22 constitutes the second part of the, 1-shaped portion 14 which is perpendicular to the first section 20, i.e. with 'an extent in the Z-direction. The first thickness 19 and the extent of the first section 20 in X-direction and Y-direction, respectively, can be varied depending on the design of the glass unit 5. Fig. 2 shows that the glass unit 5 is arranged in the profiled portion 14 in such a way that one flat side 9 of the glass unit 5 is pressed against the first section ~ 20 of the insulating layer 4.

Figure 2 shows that one glass plate 7 of the glass unit 5, i.e. its flat side 9, abuts the first section 20 in such a way that the insulating layer 4 seals against the glass unit 5 in a waterproof and windproof manner. Figure 2 also shows that the glass unit 5 and the hole 6 in the door 1 have been adapted in such a way that a negative play has been obtained between the glass unit 5 and the second section 22.

The glass unit 5 »has been pressed into the second opening 16 in the insulating layer, the insulating material 4 yielding in a resilient manner in such a way that the second section 22 seals against the edge sides 12, 13 of the glass unit, whereby the glazing method becomes further wind and waterproof. Fig. 2 shows that the outer layers 2, 3 comprise an aluminum layer 25 and that the door comprises strips 26, 27 arranged at the glass unit. The strips 26, 27 are arranged against the respective outer layers 2, 3 and the respective flat sides 9, 10 of the glass unit. The strip 27 which abuts against the second outer layer 3 and the second flat side is arranged to secure the glass unit in the hole 6. The door 1 is conveniently placed with the second outer layer 3 directed away from a housing since the first outer layer 2 and the release profile -14 together secure the glass unit from moving in a Z-direction towards the housing. Fig. 3 schematically shows a cross section of the door 1 in figure with the line A-A according to a second embodiment of the invention. Figure 3 shows that the insulating layer 4 comprises a first insulating layer 23 comprising the first opening 15 with a first size and a second insulating layer 24 comprising the second opening 16 with a second size larger than the first size. Figure 3 shows that the first insulating layer 23 lies directly. against the second insulating layer 24 and forms the profiled portion 14, i.e. the L-shaped portion 14, in the insulating layer 4 by having the various large openings 15, 16 placed in relation to each other in a suitable manner. The openings 15, 16 can advantageously be concentric, but can also be displaced relative to each other.

In Figure 3, as in Figure 2, it is shown that the L-shaped portion 14 seals against the glass unit 5 by one glass sheet 7 of the glass unit 5, i.e. its flat side 9, abuts the first section 20 in such a way that the insulating shield 4 seals against the glass unit 5 in a waterproof and windproof manner. Figure 3 also shows that the glass unit 5 ~ and the hole 6 in the door 1 'have been adapted in such a way that a negative clearance has been obtained between the glass unit 5 and the second section 22. The glass unit 5 has been pressed into the second opening 161 in the insulating layer 4, the insulating material 4 yielded to a resilient one. in such a way that the second section 22 seals against the edge sides12 of the glass unit12. 13 whereby the glazing method becomes further wind and waterproof.

Figure 3 thus shows all the features shown in Figure 2, with the difference that insulating layer 14 comprises two layers 23, 24.

Claims (10)

10 15 20 25 r 529 198 13 PATENT REQUIREMENTS A glazed door (1) comprising an insulating layer (4) and a glass unit (5) included in a through hole (6) present in the door (1), characterized in that the insulating layer (4) surrounds the through hole (6). ) comprises a profiled portion (14) arranged to frame the glass unit (5) in such a way that the profiled portion (14) and the glass unit (5) abut each other and form a sealing joint. The door (1) according to claim 1, characterized in that the hole (6) in the insulating layer (4) comprises a first through opening (15) smaller than a second through opening (16), the difference in size bidding the profiled portion ( 14). The door (1) according to claim 2, characterized in that the insulating layer (4) comprises a first insulating layer (23) comprising the first opening (15) and a second insulating layer (24) comprises the second opening (16), wherein the first the insulating layer (23) abuts the second insulating layer (24). t The door (1) according to any one of the preceding claims, characterized in that the profiled portion (1) 4 comprises a substantially Lå-shaped portion comprising the first opening (15) and the second opening (16), the glass unit (5) is framed in the L-shaped portion. The door (1) according to any one of the preceding claims, characterized in that the door (1) consists of a laminate comprising a first outer layer (2), a second outer layer (3) and the insulating layer (4) therebetween. in The door (1) according to claim 1, characterized in that the first outer layer (2) comprises a first through-opening (17) which is smaller than an opening (8) which can be seen in the second outer layer (3). 10 15 529 198 14 The door (1) according to any one of claims 5 or 6, characterized in that the first outer layer (2) covers the entire insulation layer (4) and that the second outer layer (3) covers only a part of the insulation layer (4). The door (1) according to any one of the preceding claims, characterized in that the insulating layer (4) comprises a resilient and self-supporting material. A method of glazing a door (1) comprising an insulating layer (4) and a glass unit (5) is included in a hole (6) which is substantially continuous in the door (1). characterized in that the insulating layer (4) around the through hole (6) comprises a profiled portion (14) in which the glass unit (5) is fitted in such a way that the profiled portion (14) and the glass unit (5) abut each other and form a sealing joint A method of glazing a door-open claim 9, characterized in that the insulating layer (4) is made to comprise a * first through-opening (15) smaller than a second through-opening (16), the difference in size bidding the profiled portion (14 ).