Patent Publication Number: US-11649642-B2

Title: Mechanical locking system for floor panels

Description:
RELATED APPLICATIONS 
     The present application is a continuation of U.S. application Ser. No. 16/027,711, filed on Jul. 5, 2018, which is a continuation of U.S. application Ser. No. 15/614,962, filed on Jun. 6, 2017, now U.S. Pat. No. 10,066,400, which is a continuation of U.S. application Ser. No. 15/164,291, filed on May 25, 2016, now U.S. Pat. No. 9,758,972, which is a continuation of U.S. application Ser. No. 15/067,999, now U.S. Pat. No. 9,714,515, filed on Mar. 11, 2016, which is a continuation of U.S. application Ser. No. 13/596,988, filed on Aug. 28, 2012, now U.S. Pat. No. 9,314,936, and which claims the priority of Swedish Application No. 1150778-7, filed on Aug. 29, 2011 and Swedish Application No. 1150803-3, filed on Sep. 6, 2011. The entire contents of each of U.S. application Ser. No. 16/027,711, U.S. Ser. No. 15/614,962, U.S. Ser. No. 15/164,291, U.S. application Ser. No. 15/067,999, U.S. application Ser. No. 13/596,988, U.S. Pat. No. 9,314,936, and Swedish Application Nos. 1150778-7 and 1150803-3 are incorporated herein by reference. 
    
    
     TECHNICAL FIELD 
     The disclosure generally relates to the field of mechanical locking systems for floor panels and building panels. The disclosure shows floorboards, locking systems and production methods. 
     FIELD OF APPLICATION 
     Embodiments of the present disclosure are particularly suitable for use in floating floors, which are formed of floor panels which are joined mechanically with a locking system integrated with the floor panel, i.e. mounted at the factory, are made up of one or more upper layers of wood or wood veneer, decorative laminate, powder based surfaces or decorative plastic material, an intermediate core of wood-fibre-based material or plastic material and preferably a lower balancing layer on the rear side of the core. Floor panels with a surface layer of cork, linoleum, rubber or soft wear layers, for instance needle felt glued to a board, printed and preferably also varnished surface are included. Embodiments of the disclosure may also be used for joining building panels which preferably contain a board material for instance wall panels, ceilings, furniture components and similar. 
     The following description of known technique, problems of known systems and objects and features of embodiments of the disclosure will, as a non-restrictive example, be aimed above all at floor panels and especially thin floor panels such a luxury vinyl tiles, generally referred to as LVT, with long and shorts edges intended to be mechanically joined to each other on both long and short edges. 
     The long and short edges are mainly used to simplify the description of embodiments of the disclosure. The panels may be square. 
     BACKGROUND 
     As shown in  FIGS.  1   a  and  1   b    LVT flooring usually comprise a transparent wear layer  3  which may be coated by a PU lacquer  2 , preferably UV cured, a decorative plastic foil  4  and one or several core layers  5   a ,  5   b  which generally are of different density and hardness. Relevant parts of this known description are also a part of the disclosure. 
     Thin LVT floors with a thickness of 2-3 mm have traditionally been installed by gluing to the sub floor. Recently LVT floors have been introduced on the market that comprises a mechanical locking system, which allows a floating installation without glue. This facilitates installation and eliminates a lot of work to prepare the sub floor for gluing. 
     Such LVT floors have generally a thickness of 4-5 mm. This thickness is mainly required in order to form the locking system. The panel itself is strong and flexible and a thickness of about 3 mm would in many applications be sufficient but may not be suitable since it&#39;s difficult to form a locking system in such thin floors. 
     Floating LVT floors of this type have however several disadvantages. They are heavy. The density is for example about 1.6 kg/dm3 compared to about 0.8 kg/dm3 for laminate floors. The temperature sensitivity is more than three times higher than for laminate floors. An LVT floor may move about 2 mm/M when the temperature is changing 20 degrees Celsius. 
     Such problems related to thickness are also applicable in other high quality floor panels such as wood powder based floors with high density and quality. The additional cost of forming a locking system is considerable since the material content of the whole floor panel has to be increased with 25% or more. 
     DEFINITION OF SOME TERMS 
     In the following text, the visible surface of the installed floor panel is called “front side”, while the opposite side of the floor panel, facing the sub floor, is called “rear side”. The edge between the front and rear side is called “joint edge”. By “horizontal plane” is meant a plane, which extends parallel to the outer part of the surface layer. Immediately juxta-posed upper parts of two adjacent joint edges of two joined floor panels together define a “vertical plane” perpendicular to the horizontal plane. By “vertical locking” is meant locking parallel to the vertical plane. By “horizontal locking” is meant locking parallel to the horizontal plane. 
     By “up” is meant towards the front side, by “down” towards the rear side, by “inwardly” mainly horizontally towards an inner and centre part of the panel and by “outwardly” mainly horizontally away from the centre part of the panel. 
     By “locking systems” are meant co acting connecting elements, which connect the floor panels vertically and/or horizontally. By “strip plane” is meant a horizontal plane positioned at the lowest part of the upper strip body surface. By “groove plane” is meant a horizontal plane positioned at the upper and inner part of a locking groove. 
     RELATED ART AND PROBLEMS THEREOF 
       FIGS.  1   a  and  1   b    show a LVT floor panel with a locking system that is locked with angling. The horizontal locking is obtained by a locking strip  6  having a strip body  7  and a locking element  8  formed at one panel edge  1  that locks into a locking groove  14  formed in another adjacent panel edge  1 ′. 
     The strip body  7  has a strip surface  7   a . A strip plane SP is positioned at the lowest part of the strip surface  7   a . The locking groove  14  has a vertical extension that is needed to house the locking element  8 . A groove plane GP is positioned at the upper part of the locking groove  14 . The floor panel thickness must be adapted to this required vertical distance between the strip plane SP and the groove plane GP. The thickness of the floor panel may be decreased by 25% and more if it would be possible to use a locking system where the vertical distance between the strip plane SP and the groove plane GP may be reduced or even completely eliminated. 
     It would be a major advantage if thin panels may be locked with a locking system that do not require deep vertical locking grooves and locking elements that extend vertically from the main strip body. It would also be an advantage if the weight may be decreased and if problems related to temperature changes, especially in installations with floor heating, may be eliminated. 
     SUMMARY 
     An overall objective of embodiments of the present disclosure are to provide an improved and more cost efficient locking system that may be used in primarily thin floorings and floorings with soft flexible core layers. 
     A specific objective is to decrease weight of LVT floors and adapt the panel such that it is suitable to be installed in areas, which are subjected to considerable temperature changes. 
     Another specific objective is to provide cost efficient production methods to produce locking systems in especially thin floor panels. 
     The above objects of embodiments of the disclosure are achieved wholly or partly by locking systems and floor panels according to embodiments of the disclosure. 
     A first aspect of the disclosure is building panels provided with a locking system for vertical and horizontal locking of a first and a second edge of adjacent panels. Said locking system comprising a tongue and a tongue groove for vertical locking. A strip at the first edge is provided with a locking element, which cooperates for horizontal locking with a downwardly open locking groove formed in the second adjacent edge. The strip comprises a strip body with a cavity and the second edge comprises a local protrusion that extends downwards. The protrusion is located in the cavity when the panels are locked vertically and horizontally. 
     The locking element may be a part of the cavity and the strip body may comprise several cavities. 
     The second edge may comprise several local protrusions. 
     The locking element and/or the protrusions may discontinuous along the edge. 
     The strip body may comprise a horizontal strip plane that is positioned at the lowest part of the upper strip surface and a locking groove that comprise a horizontal groove plane that is positioned at the upper and inner part of the locking groove, such that the strip plane and the groove plane are closer to each other vertically than the vertical extension of the locking element. 
     The locking system may comprise a strip plane and groove plane that are located essentially on the same horizontal plane. 
     A second aspect of the disclosure is a method to produce a panel with a locking system. The method comprises the steps of:
         a) forming a part of the cavities with punching; and   b) forming a part of the protrusions by a screw cutter.       

     The locking system may be formed on long and/or short edges and may be locked with angling and/or horizontal snapping and/or vertical folding. 
     A third aspect of the disclosure is a building panel according to the first aspect produced by the method according to the second aspect. 
     A fourth aspect of the disclosure is building panels provided with a locking system for vertical and horizontal locking of a first and a second edge of adjacent panels. Said system is configured to lock the edges by a vertical displacement of the adjacent edges relative each other. The locking system comprises a separate tongue fixed into a fixation groove. Said tongue cooperates with a tongue groove for vertical locking. A strip at the first edge is provided with a locking element, which cooperates for horizontal locking with a downwardly open locking groove formed in the second adjacent edge. 
     The strip comprises a strip body with a cavity and the second edge comprises a local protrusion that extends downwards. The protrusion is located in the cavity when the panels are locked vertically and horizontally. A lower part of the tongue groove is in locked position located essentially on the same horizontal plane as an upper part of the strip surface. 
     The locking element may be a part of the cavity. 
     The strip body may comprise several cavities. 
     The second edge may comprise several local protrusions. 
     A fifth aspect of the disclosure is building panels provided with a locking system for vertical and horizontal locking of a first and a second edge of adjacent panels. Said system is configured to lock the edges by a vertical displacement of the adjacent edges relative each other. The locking system comprises a tongue, which cooperates with a tongue groove or an undercut for vertical locking. A strip at the first edge is provided with a locking element, which cooperates for horizontal locking with a downwardly open locking groove formed in the second adjacent edge. The strip comprises a strip body with a cavity. The second edge comprises a local protrusion that extends downwards. The protrusion is located in the cavity when the panels are locked vertically and horizontally. 
     The tongue may be located at a lower part of the protrusion. 
     A sixth aspect of the disclosure is a method to produce a panel comprising a locking system that locks vertically and/or horizontally. The method comprises the steps of:
         forming a part of the locking system with knives that comprise an essentially V or U shaped open cutting edge; and   displacing cut-off material such that it flows in the inner part of the open cutting edge during cutting.       

     A seventh aspect of the disclosure is a method to separate a sheet into a first and a second floor panel and to form two adjacent edges comprising a locking system that locks vertically and/or horizontally. The first edge comprises a lower part that protrudes horizontally beyond an upper part and the second edge comprises an upper part that protrudes horizontally beyond a lower part. The method comprises the step of:
         cutting the sheet and separating the panels by cutting knives that cuts horizontally and vertically; and   forming the lower part on the first panel and the upper part on the second panel by said cutting.       

     An eight aspect of the disclosure are floor panels, provided with a locking system for vertical and/or horizontal locking of a first and a second edge of adjacent panels, comprising a plastic wear layer and one or several plastic core layers with several essentially vertical flexing grooves that have a vertical extension of at least about one third of the core thickness. 
     The flexing grooves may be covered with an underlay. 
     The flexing grooves may be essentially parallel with the long edges and have a length that is smaller than the distance between the locking systems on the short edges. 
     A ninth aspect of the disclosure is resilient floor panels with long and short edges provided with a locking system for vertical and/or horizontal locking of a first and a second edge of adjacent panels. The panels comprise a resilient material that allows a bending with overlapping short edges. One of the long edges is provided with a plastic locking strip extending along the edge and protruding horizontally from the edge. The locking strip comprises at least one vertically extending protrusion configured to be inserted into a locking groove formed at the adjacent edge. 
     The locking strip may be a thermoplastic extruded section. 
     The floor panel may have a length that is at least 15 times larger than the width. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The disclosure will in the following be described in connection to exemplary embodiments and in greater detail with reference to the appended exemplary drawings, wherein: 
         FIGS.  1   a - b    illustrate floor panels and locking systems according to known technology. 
         FIGS.  2   a - c    illustrate two edge sections with a locking system according to an embodiment of the disclosure. 
         FIGS.  3   a - 3   c    illustrate locking with a locking system according to an embodiment of the disclosure. 
         FIGS.  4   a - d    illustrate production methods to form a locking system according to embodiments of the disclosure. 
         FIGS.  5   a - d    illustrate a locking system according an embodiment of the disclosure that may be locked with vertical folding. 
         FIGS.  6   a - d    illustrate a separate strip part connected to an edge according to an embodiment of the disclosure. 
         FIGS.  7   a - b    illustrate embodiments of the disclosure. 
         FIGS.  8   a - d    illustrate a fold down locking system with a separate tongue according to an embodiment of the disclosure. 
         FIGS.  9   a - d    illustrate an embodiment with a fold down locking system with a tongue made in one piece with the panel. 
         FIGS.  10   a - f    illustrate embodiments of the disclosure. 
         FIGS.  11   a - f    illustrate separation of panels according to embodiments of the disclosure. 
         FIGS.  12   a - b    illustrate an embodiment comprising cutting with a screw cutter. 
         FIGS.  13   a - d    illustrate an embodiment comprising forming of a locking system with several knives. 
         FIGS.  14   a - d    illustrate an embodiment comprising a LVT panel with reduced weight and improved temperature properties. 
         FIGS.  15   a - d    illustrate a locking system installed with a vertical motion. 
         FIGS.  16   a - d    illustrate a locking system installed with a vertical motion. 
         FIGS.  17   a - c    illustrate a locking system installed with a vertical motion. 
         FIGS.  18   a - d    illustrate a locking system installed with angling. 
         FIG.  19    illustrates grooves formed at the rear side. 
         FIGS.  20   a - b    illustrate grooves formed at the rear side. 
         FIGS.  21   a - d    illustrate installation of a roll-formed resilient floor. 
         FIGS.  22   a - d    illustrate a locking system comprising extruded profiles. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     To facilitate understanding, several locking systems in the figures are shown schematically. It should be emphasized that improved or different functions may be achieved using combinations of the embodiments. 
     All embodiments may be used separately or in combinations. Angles, dimensions, rounded parts, spaces between surfaces etc. are only examples and may be adjusted within the basic principles of the disclosure. 
       FIG.  2   a    shows from above an edge section of a first  1  and a second panel  1 ′ according to one embodiment of the disclosure. Several cavities  20  are formed in the strip body  7  from the strip surface  7   a  to the rear side of the panel  1 . The cavities extend horizontally to the locking element  8 . Cooperating vertically extending protrusions  21  are formed on the second panel  1 ′ between the locking groove  14  and the tongue  10 . The locking element  8 , in this embodiment, continues along the joint. The cooperation locking surfaces  42 ,  43  of the locking element and the locking groove are discontinuous. 
       FIG.  2   b    shows a cross section A-A that intersects a cavity  20  and a protrusion  21 . The strip plane SP and the groove plane GP are located essentially in the same horizontal plane. The protrusion  21  is formed such that it may be inserted in the cavity  20 . The extension of the protrusion in the length direction of the joint is smaller than the corresponding extension of the cavity. 
     It is preferred that the protrusion is 2-5 mm smaller such that a precise positioning during locking is not required when a first panel in a row is installed. 
     The locking element  8  is located completely below the strip surface  7   a  and the strip plane SP. This makes it possible to decrease the floor thickness since no locking groove  14  is needed that extends above the strip plane SP. 
       FIG.  2   c    shows a cross section B-B that intersects a part of the strip  6  where no cavity is formed. This unbroken strip body is connected to the locking element  8 . The adjacent second edge  1 ′ has no protrusion and no locking groove. The lower part of the edge  23  is essentially flat and extends essentially horizontally. 
       FIGS.  3   a  and  3   b    shows the cross sections B-B and A-A in locked position.  FIG.  3   c    shows locking by angling. The locking system may also be designed such that it may be locked by horizontal and/or vertical snapping where a strip bends backwards or a small tongue  10  is pressed into a tongue groove. 
       FIG.  4   a    shows a method to form the cavity  20  with punching. The panel is machined with the surface layer pointing downwards. A punching wheel  30  may be used to form cavities  20  in line with the machining of the locking system when the panel is displaced in relation to rotating cutting tools. The cavities may be formed as an intermediate step, when a part of the locking system is formed, or as a last step when the whole edge is formed—in line or as a separate operation. A rotating cutting tool  31  may be used, preferably after punching, to form small guiding surfaces on the locking element. 
       FIG.  4   b    shows a method to form local protrusions  21  with a screw cutter  32  that cuts perpendicularly along the joint. Moving saw blades may also be used. 
       FIGS.  4   c  and  4   d    shows adjacent edges in locked position.  FIG.  4   d    shows that embodiments of the disclosure may be combined with a preferably small locking element  8 ′ that preferably comprises upper guiding surfaces, and a small locking groove  14 ′. 
       FIG.  4   c    shows that the building panel may comprise a third core layer  5   c , preferably positioned vertically within the strip  7 , such that the strip  7  is reinforced. The third layer is in a preferred embodiment positioned at the cooperating surfaces of the locking element  8  and the locking groove  14 . Such a layer increases the locking strength and makes it easier to position the locking element  8  into the locking groove  14 . The core may comprise several such layers. 
       FIGS.  5   a - 5   c    shows that the horizontal locking according to an embodiment of the disclosure may be combined with a flexible and displaceable tongue  11  that is fixed into a horizontally extending fixation groove  12  and that snaps during vertical folding. The disclosure may be used in combination with all known so called fold down systems that are locked with vertical snapping during folding or a side push action after folding when the panels are lying flat on the sub floor. The separate tongue  11  may be fixed to the first  1  or second panel  1 ′ edge.  FIG.  5   d    shows a flexible bristle tongue that comprises flexible protrusions  13 . The tongue is displaced in the fixation groove  12  during folding. A separate tongue may also be fixed into a groove and may comprise an outer part that is flexible. 
       FIGS.  6   a - 6   d    shows that the principles of embodiments of the disclosure may be combined with a separate strip part  6  that is attached to the panel edge and that comprises cavities  20 ,  20 ′. The strip part  6  comprises fixing element  33  and strip legs  34  that may be inserted in grooves or pressed into the plastic core. The strip part  6  may be formed such that it may be connected to the panel edge with essentially a horizontal snapping. 
       FIGS.  7   a  and  7   b    show cavities that are formed such that the locking element  8  is discontinuous along the joint. 
     Embodiments of the disclosure make it possible to form a strong locking in in 3 mm floor panels or even thinner. The floor panel may be formed with an upper lip  24 , as shown in  FIG.  2   c   , of about 1 mm, a tongue  10  and a tongue groove  9  of about 1 mm and a strip body of about 1 mm. The locking element  8  and the locking groove  14  need no material and this means that considerable cost savings may be reached by decreasing the panel thickness. 
       FIGS.  8   a - 8   d    shows a fold down locking system suitable for very thin floor panels. A separate and preferably flexible and/or displaceable tongue  11  may be inserted into a fixation groove  12  that is formed such that its lower part is located essentially on the same horizontal plane HP as the upper part of the strip  6 . The strip  6  is an extension of the lower part of the fixation groove  12 . The lower part  9   a  of the tongue groove  9  is in locked position located essentially on the same horizontal plane HP as the upper part of the strip surface  7   a .  FIG.  8   b    shows the second panel  1 ′ turned upside down with the surface pointing downwards. The separate tongue  11  overlaps vertically an inner part of the cavity  20 . An advantage is that the locking system may be formed in a thinner panel since the protrusions  21  are located in the cavities  20  below the upper part of the strip surface  7   a.    
       FIGS.  9   a - 9   d    show a locking system that may be locked with a vertical motion and that comprises a tongue  10   a  on the lower part of the protrusion  21 . The tongue is in this embodiment formed in one piece with the panel.  FIG.  9   b    show that the locking element  8  comprises a flexing part  22  that bends essentially horizontally and outwardly. The tongue  10   a  locks against an undercut  15  formed on the lower part of the cavity  20 . It is an advantage if the protrusion  21  is smaller in the length direction of the joint than the corresponding opening of the cavity  20 . This facilitates flexing of the flexible part  22  that will be pushed outwardly during locking. The panel may comprise a reinforcement layer  5   c  of for example glass fibre or a strong plastic layer that may increase the strength and flexibility of the locking element. The reinforcement layer is preferably unbroken around the whole cavity  20 . One or several tongues may be formed on the protrusion at the outer  10   a  or inner part  10   c  or on one or both edges  10   b ,  10   d  along the joint. 
       FIGS.  10   a - 10   f    shows different embodiments of the locking system shown in  FIG.  9   .  FIG.  10   a    shows a tongue  10   c  formed at an inner part of the protrusion that may comprise a bending groove  16 .  FIGS.  10   b  and  10   c    show two tongues  10   a ,  10   c  with corresponding undercuts  15 ,  15   a .  FIGS.  10   d  and  10   e    show a tongue and groove connection  10 ,  9  formed at an upper edge above the strip and  FIG.  10   f    shows a hook connection that only locks horizontally. 
     All embodiments shown in this description may be partly or completely combined and may be used optionally on long and/or short edges. 
     LVT panels are produced in sheets that are cut vertically into several individual floor panels  1 , 1 . The forming of the locking system creates a waste W, as shown in  FIG.  11   a   .  FIGS.  11   b - 11   f    show that cutting the individual panels vertically and horizontally may reduce the waste W. A cutting groove  36  is preferably formed with knifes, carving tool or rotating cutting tools and various combinations of such tools. The panels are thereafter separated by a knife  35   a  that cuts essentially horizontally and a knife or carving tool  35   b  that cuts essentially vertically.  FIG.  11   e    shows that the first edge  1  is formed with a lower part  40  that protrudes horizontally beyond the upper part and the second edge  1 ′ is formed with an upper part  41  that protrudes horizontally beyond the lower part. A non-linear cut with knives or scraping tool may be formed and this may give considerable material savings.  FIG.  11   f    shows that the whole cut may be formed with one knife  35   c  that cuts vertically and horizontally. 
       FIGS.  12   a  and  12   b    show forming of the panel edges by a screw cutter  32  that cuts perpendicularly to the displacement direction of the panel  1 ′ and forms the protrusions  21 . 
     A locking system in a plastic based LVT flooring may be formed with traditional rotating cutting tools that cut as a saw blade but also partly or completely with cutting knives that may be fixed or rotating. Carving tools may also be used.  FIGS.  13   a - 13   d    show that all parts of a mechanical locking system may be formed by cutting knifes which have a straight cutting edge  35   a ,  35   b ,  35   c  or which have an irregular form  35   d ,  35   e ,  35   f  and  35   g . Cutting knives with a straight edge are preferably rotating knives. The irregular knives are preferably formed as open V or U-shaped section that allow the cut-off material to flow in the inner part of the cutting tool  37  such that it may be removed when the tool  35  or the panel  1  is displaced in relation to each other. 
     The knives may be stationary and the panel may be displaced in relation to the knives. It is also possible to displace the knives in relation to a fixed panel. 
     Increased temperature will facilitate all type of separation and forming of the edges with for example knives, carving, punching wheels, screw cutters etc. since plastic material is considerable softer when the temperature is increased. The panel may be heated completely or only locally with for example infrared lamps, hot air etc. that heat an edge part. 
     Bevels or rounded edges are easily formed at increased temperature and with rollers or pressing wheels that compress and form the edges. Such forming devices may be embossed and the edges may be formed with the same structure as the panel surface. A decorative paint may be applied during forming. 
     Parts of the locking system may also be formed with heat and rollers that press and form the edge. 
     LVT floors are very moisture stable but they expand or shrink when the temperature is changing. Some LVT floors may shrink and expand about 2 mm when the temperature is changing from 10 to 40 degrees Celsius. This may cause problems when LVT floors are installed floating especially in a room with floor heating. 
     The major reason for the temperature sensitivity is the type of plastic (PVC) that is used in the surface and core layers. Adding special fillers into the core layers may decrease the temperature sensitivity. 
     The expansion and shrinking may be compensated by the flexibility of the panel. This flexibility must be such that the locking system is able to keep the floor together in low temperature and such that the panels will not warp or bend upwards when they expand in high temperature. 
       FIGS.  14   a ,  14   b  and  14   d    show that the flexibility may be increased considerably if several flexing grooves  19  are formed at the rear side of the core  5   b . Such grooves may preferably be formed with knives along and/or across the board. The cut-off material may be recycled completely and used to produce a new core. The grooves may also be formed when the panel is pressed. Such a production method is suitable when the sheets are pressed in a discontinuous press. Knives may preferably be used when the sheets are produced in continuous presses. The material is very easy to remove when the material is hot. 
       FIGS.  14   b,d    show that the flexing grooves may be covered with an underlay  18  that may be foam or any other plastic material similar to the material used in the core. It is preferred that the flexing grooves  19  have a vertical extension of at least about one third of the core thickness. 
     The grooves  19  may be used to decrease the weight of the panel. 
       FIG.  14   c    show that including layers that are more stable, for example one or several layers of glass fibre or a sub core  17  that preferably comprises wood fibres, may increase the temperature stability. The sub core  17  may be a high quality HDF board or wood powder based board with high moisture resistance. 
       FIG.  15   a - d    show a locking system that is locked with vertical snapping. The protrusion  21  comprises a tongue  10   a  that cooperates with an undercut  15   a  formed at the rear side of the locking element. The tongue  10  may be formed at an inner part of the protrusion  21 . The protrusion  21  and the locking element are bent and displaced horizontally during the vertical motion, as shown in  FIGS.  15   b  and  15   c   .  FIG.  15   d    shows a cross section where no protrusion and cavity are formed. Such cross section has only a horizontal locking. This embodiment is characterized in that the locking system comprises a first set of sections along the joint that locks only horizontally and a second set of sections that locks horizontally and vertically. The locking system is also characterized in that the protrusion  21  and the locking element  8  are displaced horizontally during the vertical motion. 
       FIGS.  16   a - 16   d    shows a locking system similar to the system shown in  FIGS.  15   a - d   . The tongue  10   a  is however formed at an outer part of the protrusion  21 . The locking element  8  may also be discontinuous as shown in  FIGS.  16   c - d   . Such geometry facilitates the forming of the cavities  20  that may be formed with rotation tools. This embodiment is characterized in that the locking system comprises a first set of sections along the joint (A-A) that locks only vertically and a second set of sections (B-B) that only locks horizontally. 
       FIGS.  17   a - c    shows the locking of the locking system according to  FIGS.  16   a - d   . A first set of sections A and the second set of sections B are displaced vertically wherein the protrusion  21  is displaced horizontally and inwardly during locking. 
       FIGS.  18   a - c    shows a locking system where the cavities  21  and protrusions  20  are mainly used to guide the floor panels during the angling action. The horizontal locking is accomplished with cooperating locking surfaces  42 , 43  on the locking element  8  and the locking groove  14  that are located above and below the strip plane SP. A strong locking may be obtained in plastic material with vertically extending locking surfaces that are only about 0.2-0.5 mm, especially if the locking angle  44  on a part of the locking surfaces is high, for example about 90 degrees as shown in  FIG.  18   b   . The locking is only possible if a protrusion is positioned above a cavity. The locking may be accomplished in several steps. In case the protrusion  21  is not above the cavity  20  as shown in  FIG.  18   c   , the panels will stay in an angled position. A displacement along the joint may thereafter take place and the protrusion  21  will automatically fall into the cavity  20  as shown in  FIG.  18   c   .  FIG.  18   d    shows that the tongue  10  may be formed on the edge comprising a cavity  20 . This embodiment may be used to save material. 
       FIG.  19    shows that flexing grooves  19  may be formed at the rear side with a length that is smaller than the length of the rear side. Such forming may be made with rotating jumping tools or with knives. The advantage is that the flexing grooves  19  are not formed in the edge sections where the locking system is formed. The flexing grooves  19  may be essentially parallel with the long edges and may have a length that is smaller than the distance between the locking systems on the short edges. 
       FIG.  20   a - b    show that position marks  45  may be formed by mechanical forming or with color spots on the tongue  10  such that they are visible from the front side. They may be used to position the protrusions  21  above the cavities  20 .  FIG.  20   b    shows that the flexing grooves  19  may be discontinues and arranged in various patterns. 
       FIG.  21   a - d    show that resilient floors may be delivered in rolls with overlapping short edges where each roll corresponds to one row. The rolls have preferably a width of 0.1-0.5 m and may comprise floor material that in installed position has a length of several meters. A preferred embodiment is a roll comprising a resilient flooring material, preferably PVC material, which in an unrolled and installed position has a length that is larger than 15 times the width. An even more preferred embodiment is a roll with an installed length that is larger than about 50 times the width. Such a roll may be about 0.2 m wide and about 10 m long and may comprise 2 m2 of flooring material. An extruded locking strip  46  comprising a first  47  and second  48  upwardly extending protrusions may be attached in a holding groove  49  in one edge of the roll. The first upwardly extending protrusion  47  is attached in a holding groove  49  of a first edge  1  and the second upwardly extending protrusion  48  is rolled and pressed during installation into a locking groove  14  formed in the adjacent edge  1 ′ of a second roll. Such a combined pressing and rolling action facilitates the insertion of the protrusion  48  into the locking groove  14  since the protrusion is gradually inserted into the locking groove when the floor is unrolled. 
       FIGS.  22   a - 22   d    shows that all the above described embodiments may be used to form locking strips  46   a ,  46   b  that may be attached on adjacent panel edges or roll edges as separate strips in order to provide a vertical and/or horizontal locking.  FIGS.  22   b  and  22   c    shows that punching of an extruded plastic section may form locking strips comprising cavities  20  and protrusions  21 .  FIG.  22   d    shows the locking strips in a locked position. The locking system is locked by vertical displacement where the protrusions  21  are inserted into the cavities  20  with a rolling motion. The first upwardly extending protrusion  47  may be combined or replaced by glue or thermal bonding. The locking strips may comprise several upwardly extending protrusions  48 ′,  48  as shown in  FIG.  22     d.    
     The methods above may also be used to lock linoleum floors and other resilient floors.