Process for sealing of a joint

Abstract

A process for installation of surface elements (1), the surface elements (1) comprising a core, a decorative upper surface (3) and edges (2) provided with joining means for mechanically locking the surface elements (1) together. Predetermined portions of the edges (2) are provided with a glue which is present on the edges (2) of the surface elements (1) in a passive dry form and which may be activated by applying a liquid. The surface elements (1) are joined to each other by use of the joining means wherein a unit of a plurality of surface elements (1) is formed.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to sealing of a joint comprising mechanical locking.

2. Description of the Prior Art

Prefabricated surface elements which at their edges are provided with groove and tenon are well known nowadays. As these are very easy to install it is possible for the normal handy man to achieve this. Such elements can be constituted of massive wood, fibre board or particle board. These are often provided with a surface layer, such as lacquer or some sort of laminate. The boards are most often installed by gluing them together via their groove and tenon. It is desired to join the separate elements so closely that the joint becomes practically invisible, which increases the moisture resistance radically. The usable life of the installed elements are thereby also increased. It is essential that glue is used excessively in order to achieve a tight joint. Any gaps will lead to moisture penetrating the joint with subsequent swelling of the core material closest to the joint. The glue also has to be used to an amount that it is spilled out through the joint on the decorative side of the surface elements. The superflous glue will of course have to be wiped off before beginning to set, which is rather time consuming.

One way of solving the problem is available on the market for some time now through different types of so-called click or snap-lock floor boards where no glue is to be used. The installation of such floor boards has become much swifter as no glue is required. The problems with these type of surface elements are that relativelly small spills of fluids like water may cause great damage on the installed surface elements as well as subwalls and especially subfloors as the fluid will run through the joints rather rapidly due to the capillary effect. It is, of course, possible to use glue on these snap-lock type of elements as well although the problem with the time consuming cleaning during installation would remain.

BRIEF SUMMARY OF THE INVENTION

It has, through the present invention, been made possible to solve the above mentioned problems so that self sealing surface elements can be achieved. Accordingly the invention relates to a process for installation of surface elements. The surface elements comprising a core, a decorative upper surface and edges are provided with joining means for mechanically locking the surface elements together. The invention is characterised in that predetermined portions of the edges are provided with a glue which is present on the edges of the surface elements in a passive dry form and which may be activated by applying a liquid. The surface elements are thereby joined to each other by use of the joining means wherein a unit of a plurality of surface elements is formed. The glue is suitably a polyvinyl alcohol [PVA] glue. The glue is suitably applied on the edges as an emulsion which then is allowed to dry before the joining of the surface elements.

The liquid used for reactivating the glue is suitably water. The water is advantageously mixed with alcohol since this reduces the surface tension of the liquid as well as increasing the evaporation rate. A thin coat of the liquid is suitably applied on the installed surface elements wherein small amounts of the liquid will pentetrate into the joints thereby moisturising and activating the glue. The glue will thereby expand and merge over the edges of the joint and will act as sealant against further penetration of liquid. It is not necessary to actively activate the glue by applying the liquid over the installed surface elements as small amounts of liquid accidently spilt on the installed surface elements will pentetrate into the joints thereby moisturising and activating the glue so that the glue expands and merges over the edges of the joint thereby acting as a sealant against further penetration of liquid.

According to one embodiment of the invention the joining means comprises lower joining lips at two adjacent edges while the two remaining edges are provided with upper joining lips. The lower joining lips are provided with intrinsically vertical lower lip surfaces arranged parallel to the closest edge. The lower lip surfaces are adapted to interact with mainly vertical upper lip surfaces arranged on the upper joining lips so that two joined adjacent surface elements are locked together in a horizontal direction. The joining lips are furthermore are provided with at least one heel adapted to snap join with recesses which, by being provided with intrinsically horizontal locking surfaces, limits vertical movement between two joined adjacent surface elements. The surface elements are hereby assembled by being pressed downwards once the edges are vertically aligned.

According to another embodiment of the invention the surface elements comprises a combination of at least two different types of surface elements, which types comprise female surface elements and male surface elements, whereby:

a) The female surface element is provided with a female joining member on at least half of the number of its edges and a male joining member on less than half of the number of its edges.

b) The male surface element is provided with a male joining member on at least two thirds of the number of its edges and a female joining member on less than one third of the number of its edges.

c) An optional joining profile possibly constitutes a junction between two adjacent male joining members of two adjacent surface elements.

The female joining member comprises an upwards protruding lip, being parallel to the edge, with a guiding surface. The guiding surface faces the edge. The female joining member also comprises a locking groove, being parallel to the edge. The locking groove has a locking surface facing downwards, which locking surface terminates in a locking edge. An angle αI between the guiding surface and vertical plane is in the range 0-30° while an angle βII between the locking surface and a horizontal plane also is in the range 0-30° as seen in a perpendicular cross-section.

The male joining member comprises a groove, being parallel to the edge, on the lower side with a guiding face. The guiding face faces away from the edge. The male joining member is also provided with a locking heel, being parallel to the edge The locking heel has a locking face facing upwards. An angle βI between the guiding face and a vertical plane is in the range 0-30° while an angle βII between the locking face and a horizontal plane is also in the range 0-30° as seen in a perpendicular cross-section.

The possible joining profile comprises two upwards protruding rims, being parallel to each other and distanced from each other by a centre section. The two upwards protruding rims are provided with guiding areas, the guiding areas facing inwards. The joining profile is furthermore provided with two locking cheeks placed on an extension. The locking cheeks has locking areas facing downwards, which locking areas terminates in a locking edge. An angle ΨI between the guiding area and a vertical plane is in the range 0-30° while an angle ΨII between the locking area and a horizontal plane is in the range 0-30° as seen in a perpendicular cross-section. The angles αI and βI are mainly the same, the angles αII and βII are mainly the same and the angles ΨI and ΨII are mainly the same.

According to yet another embodiment of the invention the surface elements are joined by means of joining members. The edges are separated into a first and a second edge, which first and second edges are arranged on opposite sides, and a third and a fourth edge being adjacent to the first and the second edge and which third and fourth edges are arranged on sides opposite to one another. The surface elements are provided with male joining members on the first edge while the second edge of the surface elements are provided with a female joining member. The male joining member is provided with a tongue and a lower side groove, while the female joining member is provided with a groove and a cheek, the cheek being provided with a lip. The surface elements are joined together via the male and female joining members by tilting the surface element to be joined with an already installed surface element or a row of already installed floor elements, with the male joining member of the surface element angled downwards. The first edge is positioned mainly parallel to the second edge of the already installed surface element or row of surface elements. The tongue of the tilted surface element is then inserted into the groove of the female joining member of the already installed surface element or row of floor elements, whereby the tilted surface element is turned downwards, with its lower edge as a pivot axis, so that the lip eventually snaps into the lower side groove where the decorative upper layer of the surface elements are mainly parallel. The third and fourth edges of the surface elements are joined by means of joining members selected from the group consisting of:

a) The third edge of the surface elements are provided with a male vertical assembly joining member while the fourth edge is provided with a female vertical assembly joining member. The fourth edge is arranged on a side opposite to the third edge.

b) The third edge of the surface elements are alternatively provided with a male vertical assembly joining member while the fourth edge also is provided with a male vertical assembly joining member. The fourth edge is arranged on a side opposite to the third edge. The adjacent male vertical assembly joining members are joined by means of a separate vertical assembly joining profile.

Two adjacent edges of a surface element are at the same time, and in the same turning motion, joined with a surface element adjacent to the first edge and a surface element adjacent to the third or fourth edge.

These embodiments of the invention include:

The joint between two joined floor elements suitably also comprises cavities. According to one embodiment of the invention a snapping hook is constituted by a separate spring part which is placed in the cavity. Alternatively an undercut is constituted by a separate spring part which is placed in a cavity. The spring part is suitably constituted by an extruded thermoplastic profile, a profile of thermosetting resin or an extruded metal profile.

BRIEF DESCRIPTION OF THE DRAWINGS

Particular embodiments of the invention is described further in connection to enclosed drawings whereby;

FIG. 1 shows a part of a surface element 1 according to a first embodiment of the invention.

FIGS. 2 a-b show a part of a surface element 1 according to a second embodiment of the invention.

FIGS. 3 a-f show a part of a surface element 1 according to a third embodiment of the invention.

FIG. 4 shows the third and fourth edges of a surface element 1 according to the embodiment according to FIG. 2a.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows parts of a surface element 1. The surface elements 1 are provided with edges 2, a horizontal lower side 5, and a horizontal upper decorative surface 3. The surface elements 1 are at two adjacent edges 2 provided with lower joining lips 10 (only one shown) while the two remaining edges 2 are provided with upper joining lips 20 (only one shown). The lower joining lips 10 are provided with mainly vertical lower lip surfaces 11 arranged parallel to the closest edge 2. The lower lip surfaces 11 are intended to interact with mainly vertical upper lip surfaces 21 arranged on the upper joining lips 20 so that two joined adjacent surface elements 1 are locked together in a vertical direction. The joining lips 10 and 20, respectively, are furthermore provided with each one heel 31 with a matching recess 32. A vertical movement between two joined adjacent surface elements 1 is limited since the recess 32 and heel 31 respectively are provided with essentially horizontal locking surfaces. The joining surfaces are also provided with fitting surfaces 3^I in order to avoid unintended gaps in the joint. The geometry of the joining edges are only shown schematically and may, of course, be changed in many ways within the scope of the invention.

FIG. 2 a shows, in cross-section, a first and a second edge 2^I and 2^II respectively, during assembly. The figure shows parts of surface elements 1 with a mainly rectangular shape. The surface elements 1 are provided with edges 2, a lower side 5 and an upper decorative layer 3. The surface elements 1 are intended to be joined by means of joining members 200. The surface elements 1 are provided with male joining members 220 on a first edge 2^I while a second edge 2^II of the floor elements 1 are provided with a female joining member 210. The second edge 2u is arranged on a side opposite to the first edge 2^I. The male joining member 220 is provided with a tongue 110 and a lower side 5 groove 12. The female joining member 210 is provided with a groove 13 and a cheek 14, the cheek 14 being provided with a lip 15. The surface elements 1 are intended to mainly be joined together by tilting the surface elements 1 to be joined with an already installed surface elements 1 or a row of already installed surface elements 1, with the male joining member 220 of the surface elements 1 angled downwards and that the first edge 2^I is allowed to be mainly parallel to the second edge 2^II of the already installed surface element 1 or elements 1. The tongue 110 of the tilted surface element 1 is then inserted into the groove 13 of the female joining member 210 of the already installed surface element 1 or elements 1, whereby the tilted surface element 1 is turned downwards, with its lower edge 2 as a pivot axis, so that the lip 15 eventually falls into the lower side 5 groove 12 where the decorative upper layer 3 of the surface elements 1 are mainly parallel. The lip 15 and lower side 5 groove 12 are further provided with a cam 16 and a cam groove 17 which provides a snap action locking during the turning motion.

FIG. 2 b shows, in cross-section, a third and a fourth edge 2^III and 2^IV respectively, of a surface element 1 according to the invention. The surface elements 1 are provided with a male vertical assembly joining member 220^I on a third edge 2^III while a fourth edge 2^IV is provided with a female vertical assembly joining member 210^II. The fourth edge 2^IV is placed on a side opposite to the third edge 2^III. The male vertical assembly joining members 220^I are provided with mainly vertical lower cheek surfaces 21 arranged parallel to the closest edge 2. The lower cheek surfaces 21^I are intended to interact with mainly vertical upper cheek surfaces 22^II arranged on the female vertical assembly joining members 210^II so that two joined adjacent surface elements 1 are locked against each other in a horizontal direction. The male vertical assembly joining members 220^II are moreover provided with two snapping hooks 23^I while the female vertical assembly joining members 210^II are provided with matching under cuts 24^II, which by being provided with mainly horizontal locking surfaces limits the vertical movement between two joined adjacent surface elements 1.

The joint between a third and a fourth edge 2^III and 2^IV, respectively, of two joined surface elements 1 further comprises contact surfaces which are constituted by the mainly horizontal locking surfaces of the under cut 23^I and hook 24^II, the mainly vertical upper cheek surfaces 22^II lower cheek surfaces 21^I as well as upper mating surfaces 25. The joint between two joined surface elements 1 also comprises cavities 60.

As shown in FIG. 1, glue 4 may be included on at least one edge of surface element 1 and activated as heretofore described. Also, as shown in FIG. 4, which is an enlarged view of the third and an opposite fourth edges 4^III and 4^IV, respectively, of surface element 1, a cavity 460 houses a spring part 402 placed in the cavity 460. The spring 402 acts as a hook to engage undercut 424^II. As with the heretofore described embodiment of FIG. 2a, the surface elements 1 of FIG. 4 have the same horizontal upper decorative surface 3, a horizontal lower side 5, and male vertical joining member 420^I and female vertical joining member 410^I. When assembled, decorative surfaces 3, having upper mating surfaces 25, form a joint which is practically invisible.

FIGS. 3 a, 3b, 3c and 3d are shown in exploded view and in cross-section. In an embodiment of joining members 1210 (FIG. 3a) and 1220 (FIG. 3b) respectively for surface elements 111^I, 111^II according to the invention, before the assembly the surface elements 111^I, 111^II which are assembled vertically, have a rectangular shape, as seen from above. The surface elements 111^I, 111^II are provided with edges 112, 112^I which are provided with joining members 1210, 1220. The surface elements 111^I, 111^II are further provided with a lower sides 115, 115^I and decorative top surfaces 113, 113^I. The surface elements 111^I, 111^II comprise a combination of at least two types of surface elements, which types comprises female surface elements 1111^I and male surface elements 111^II.

The female surface element 111^I is provided with a female joining member 1210 on at least half of the number of its edges 112 and a male joining member 1220 on less than half of the number of its edges 112^I. The female joining member 1210 comprises an upwards protruding lip 1211, being parallel to the edge 112. The upwards protruding lip 1211 is provided with a guiding surface 1212, the guiding surface 1212 facing the edge 112, and a locking groove 1213, being parallel to the edge 112. The locking groove 1213 has a locking surface 1214 facing downwards, which locking surface 1214 terminates in a locking edge 1215. An angle αI (FIG. 3b) between the guiding surface 1212 and a vertical plane is 10°, while the angle αII (FIG. 3b) between the locking surface 1214 and a horizontal plane is 15° as seen in a perpendicular cross-section.

The male surface element 111^II is provided with a male joining member 1220 on at least two thirds of the number of its edges 1121 and a female joining member 1210 on less than one third of the number of its edges 112.

The male joining member 1220 comprises a groove 1221, with a guiding face 1222, being parallel to the edge 112^I, on the lower side 115. The guiding face 1222 is facing away from the edge 112^I. The male joining member 1220 is also provided with a locking heel 1223, being parallel to the edge 112^I. The locking heel 1223 has a locking face 1224 facing upwards. An angle βI (FIG. 3c) between the guiding face 1222 and vertical plane is 10°, while an angle βII between the locking face 1224 and a horizontal plane is 15° as seen in a perpendicular cross-section.

Accordingly, the angles αI and 131 are the same and the angles αII and βII are also the same.

An optional joining profile 50 (see FIGS. 3e and 3f) may possibly constitute a junction between two adjacent male joining members 11220 of two adjacent surface elements 1111^I and 1111^II.

The section placed between the edges 1112 and the grooves 1221 has a thickness which is less than the maximum surface element thickness by a recess 116 on the lower side 115 of the surface elements 1111. The thickness of the surface elements 111 is normally between 5 and 15 mm whereby a suitable depth of the recess 6 is 1-5 mm.

The width of the locking face 1224 is depending on aspects like the thickness of the surface element 111, the material used in the core, the dimensions of the part between the locking groove 1213 and the lower side 115 and the angles αI and βI chosen. The width of the locking face 1224 is typically less than 30% of the thickness of the surface element which normally is between 5 and 15 mm whereby the width is less than 4.5 mm for floors with 15 mm thickness and 2.1 mm for a common surface element with a thickness of 7 mm. It has, however shown to be fully sufficient with a width between 0.2 mm and 1 mm.

FIGS. 3 e and 3f show, in cross-section, an embodiment of a joining profile 50 to a surface element 1111^I and 1111^II according to the invention. The joining profile 50 is intended to be used as a junction between two male joining members 11220 and 11220^I. The joining profile 50 comprises two upwards protruding rims 511, being parallel to each other and distanced from each other by a centre section 506. The two upwards protruding rims 511 are provided with guiding areas 512. The guiding areas 512 are facing inwards. The joining profile 50 is furthermore provided with two locking cheeks 513 placed on an extension 507. The locking cheeks 513 has locking areas 514 facing downwards, which locking areas 514 terminates in a locking edge 515. An angle ΨI between the guiding area 512 and the vertical plane is 10° and the angle ΨII between the locking area 514 and a horizontal plane is 15° as seen in a perpendicular cross-section.

Accordingly, the angles αI, βI (FIGS. 3a-3d) ΨI and are the same and the angles αII, βII (FIGS. 3a-3d) ΨII are also the same. In other embodiments of the invention the joint between two joined floor elements suitable also comprise cavities. According to one embodiment of the invention, the snapping hook, is constituted by a separate spring part which is placed in the cavity. Alternatively an undercut is constituted by a separate spring part which is placed in a cavity. The spring part is suitably made of an extended thermoplastic profile, a profile of thermosetting resin or a metal profile.

The invention is not limited by the embodiments shown since these can varied in different ways within the scope of the invention.

Claims

1. A surface element designed to be assembled together with similar surface elements to form a plurality of joined surface elements: the surface element comprising a core, a decorative upper surface, an opposed lower surface and at least four edges disposed between the upper and lower surfaces;the four edges comprising a first edge and a second edge defining a first pair of opposite sides, and a third edge and a fourth edge defining a second pair of opposite sides;wherein the first edge of the surface element comprises a first male joining member and a second edge comprises a first female joining member;the first male joining member comprising a tongue and the first female joining member comprising a groove;the first male joining member and the first female joining member being configured such that two surface elements can be coupled and vertically as well as horizontally locked at respective edges by rotational movement;wherein the third edge and the fourth edge comprise a snapping hook and undercut, one of the snapping hook or undercut being formed by a separate spring part; andwherein the third and fourth edges are adapted to connect with adjacent edges via vertical motion resulting in vertical as well as horizontal locking.

2. The surface element of claim 1 wherein the spring part is formed of thermoplastic.

3. The surface element of claim 1 wherein the spring part part is formed of thermosetting resin.

4. The surface element of claim 1 wherein the spring part is formed of metal.

5. The surface element of claim 1 wherein the spring part is configured to engage the undercut.

6. An assembled unit of the plurality of surface elements according to claim 1.

7. The surface element of claim 1 wherein the decorative upper surface comprises a laminate.

8. The product of claim 1 wherein the decorative upper surface comprises a lacquer.

9. The surface element of claim 1 wherein the snapping hook is formed by the spring part.

10. The surface element of claim 1 wherein the undercut is formed by the spring part.

11. The surface element of claim 1 wherein the joining members of all edges are configured such that concurrently with joining of the first and second edges by rotational movement, joining also simultaneously occurs of the third and fourth edges.

12. A product comprising installed surface elements, the surface elements comprising: a core selected from at least one material from the group consisting of wood, particleboard and fiberboard;a decorative upper surface, an opposed lower surface and edges, the edges being disposed between the upper and lower surfaces, the edges provided with at least one of a first and a second joining member for mechanically joining the surface elements together, wherein: at least one of the first and the second joining members comprises a male joining member and at least one of the first and the second joining elements comprises a female joining member;the male joining member comprises a tongue and lower side groove;the female joining member comprises a groove and a cheek, the cheek being provided with a lip; andat least one of the edges comprising the female joining member further comprises a cavity, wherein the cavity comprises a separate spring part,wherein the surface elements are configured to connect to an adjacent edge via vertical motion, whereby adjacent surface elements are locked vertically and horizontally.

13. The product of claim 12, wherein the core is fiberboard.

14. The product of claim 12, wherein the core is wood.

15. The product of claim 12, wherein the core is particleboard.