SE524875C2 - Frame element - Google Patents

Abstract

A doorframe element for a door, window or the like, including a profile element (1) and a heat insulating material (21), which expands when heated and which is arranged at the profile element, wherein at least one through opening (23) is arranged in a first wall section (10) of the profile element, adjacent to the expanding insulating material for allowing the insulating material to expand through the opening. In order to enhance the ability to prevent heat transfer through the doorframe element, the opening (23) and the insulating material (23) are arranged so that the insulating material, partially or fully, takes up a space which is formed between the first and a second wall section of the profile element when the insulating element expands.

Description

o .. to you us; o soon 10 15 20 25 30 524 875 2 According to the state of the art, frame pieces for fire doors are usually designed as elongated profile elements of bent sheet steel or extruded aluminum. Each frame piece mainly consists of such an elongate profile element as well as means for attaching the frame piece to the wall, a sealing strip for sealing between the frame piece and the door leaf and internal insulation to counteract heat transport by radiation and convection through the profile element.

The profile element has a number of wall portions which extend along the full length of the element. These wall portions form a cross-section of the profile element with a generally rectangular part which has an open side intended to face the short side of the wall in the door opening. At this side, there may also be means for attaching door or frame lining, which extends, one on each side of the wall, from profile elements a distance inwards over the wall. DE 20109826 describes how door linings according to the state of the art can be attached to a frame piece. On the side of the profile element of the frame piece which is turned away from the open side facing the wall, a number of wall portions further form a projection with a stop against which the door leaf is intended to abut when the door leaf is in closed position. Usually the door leaf does not abut directly against the stop, but a sealing strip is arranged between the stop and the door leaf.

In another previously known frame piece, the space in the profile element which corresponds to the generally rectangular part of the cross-section of the profile element is filled with heat-insulating stone wool. The stone wool insulation aims to prevent heat being transported by radiation and convection from one of the wall portions that form the rectangular part to another. Furthermore, three wall portions of the profile element form a groove between the rectangular part of the profile element and the abutment. The groove extends along the full - ~ of the profile element. . .- so: av ou over a o 10 15 20 25 n Q -. .n 524 875 3 ~ aaa- length. In the groove, a strip of a thermal insulation material which expands on heating is provided. This strip aims at normal use of the door to seal between the frame piece and the door leaf. In the event of a fire, the side of the door facing the hearth will be heavily heated. Since the parts of the door leaf and frame which are closest to the hearth are heated and expanded more than the parts of the door facing away from the hearth, deformations of the door leaf and frame then occur. The expanding insulation strip then aims to maintain a good seal between the door leaf and the frame despite the deformations that occur. As the strip expands more and more as the temperature gets higher, the insulation material will penetrate into the gaps between the door leaf and the frame that arise due to the deformations. In this case, a good seal is maintained between the door leaf and the frame piece at the same time as heat transport between the door leaf and the frame piece is counteracted.

A disadvantage of the known construction described above is that it is difficult to achieve a good internal rock wool insulation between the wall portions of the profile element which form the groove and the stop. The interior spaces and distances between these wall portions are relatively small. Therefore, it is complicated and expensive to apply rock wool or other thermal insulation in these spaces during the manufacture of the frame pieces. Even if rock wool or other conventional thermal insulation were to be applied in these spaces, good thermal insulation between the wall portions is not obtained. Since these wall portions are deformed on heating and since conventional insulation does not follow such deformations, gaps occur between wall portions and insulation, whereby the insulating effect with regard to radiation and convection is considerably impaired. The deformations can also cause the insulation material between two or more wall sections to be completely compressed. -. . .- a c o o avaotoo u at; n o o o: 40 nano Oc g ~ 10 15 20 fx) UI b) O. - - »a. 524 875 4 a n .. away, which has the consequence that the radiation and convection insulation between these wall sections completely disappears.

The small distances between the wall portions in this part of the profile element further means that heat transport by radiation and convection between the wall portions becomes particularly significant here.

In addition, these wall portions are located in the very part of the profile element which, in terms of heat transport, forms the boundary between the hot and cool side of the frame piece, when either side of the frame piece is heated. A good counteracting action against heat transport is therefore particularly important in this particular part of the profile element, in order to prevent heat from spreading from one of the fire doors to the other side as far as possible.

In addition to radiation and convection, heat can also be transported between the various wall parts of the profile element by heat conduction. BE 827106 describes a profile element in metal for a frame piece, which profile element also has a groove for a sealing strip and a stop for the door leaf. To counteract heat transport through the profile element, a number of circular openings are accommodated in the wall portion which forms the groove. the openings are arranged one after the other in the longitudinal direction of the profile element. As a result, the wall portion which delimits the groove is in fact perforated, whereby the wall portion will contain less heat-conducting material than if the wall portion were solid. Heat transport through the profile element is thus counteracted by reducing the heat-conducting properties of the profile element by removing heat-conducting material. However, a disadvantage of the profile element described in BE 827106 is that heat can still be transported through the openings themselves. Since the openings are in practice filled with air, heat transport is allowed within each opening by radiation and convection between different parts on the edge surface of each opening. Because it perforated 10 15 20. -. . In addition, the wall portion is located in the part of the profile element which, in terms of heat transport, forms the boundary between the hot and cool side of the frame piece, such heat transport by radiation and convection also adversely affects and significantly the ability of the frame piece to counteract heat transport. The object of the present invention is therefore a frame piece, in which heat transport through critical parts of the frame piece, both by heat conduction and also radiation and convection is easily and efficiently counteracted.

This object is achieved according to the invention with a frame piece according to the first paragraph, characterized in that at least one opening is arranged through a first wall portion of the profile element, in the vicinity of the expanding insulating material, to allow the insulating material to expand through the opening. so that heat transport through the frame piece is counteracted.

Since one or more openings are arranged in the first wall portion, heat conduction through the material in the first wall portion is effectively counteracted. This applies both before and after the expanding insulation material has begun to expand as a result of heating due to a fire or the like. In addition, since the openings are arranged in the vicinity of the expanding insulating material, this insulating material, as it expands when heated, will penetrate into and fill in the openings. When the insulation material has filled the openings, heat transport by radiation and convection through the openings is also effectively counteracted, ie. between different parts of the edge surface of each opening. The invention thus provides a simple and efficient device for counteracting heat transport through. »-. .- 10 15 20 25 ansa n n o ooøoauo - - ~ - n. 524 875 6 the frame piece in terms of both heat conduction and radiation and convection.

According to an advantageous embodiment of the frame piece, the profile element comprises a second wall portion which is arranged so as to form a space between the first and the second wall portion. The openings and the insulating material are then arranged so that the insulating material, when it expands, completely or partially, fills the space between the first and second wall portion.

In this way, it is effectively achieved that heat transport by radiation and convection between different wall portions of the profile element is counteracted. By choosing a suitable location of the openings and the insulating material in relation to the wall portions, it is possible to strongly counteract radiation and convection in heat-critical parts of the profile element. Examples of such critical parts are between two parallel adjacent wall portions and at right-angled or pointed corners between two wall portions.

The frame piece can furthermore be suitably designed so that the insulating material is arranged on the side of the first wall portion opposite the second wall portion. Hereby the advantage is achieved that the insulating material when heated both penetrates and fills the openings and also fills the space between the first and second wall portion, whereby radiation and convection are counteracted both within the openings and between the wall portions.

According to a preferred embodiment of the frame piece according to the invention, the profile element is designed so that two or more wall portions form a laterally open groove, which extends in the longitudinal direction of the profile element. The depth of the groove is defined by a wall portion which forms a stop for the door leaf, as this is in the closed position. The insulation material is arranged in the groove so oo out o o o o n nano oo Anon now 10 15 20 25. . ». .u 524 875 7 - un. that it protrudes past the appropriation. In this way, the insulating material will also function as a seal between the frame piece and the door leaf when the door is closed. One or more of the wall portions forming the groove is provided with one or more sets of openings. Within each set, the openings are arranged in a row along the length of the profile element.

This ensures that the insulating material, as it expands, completely and along the entire length of the profile element, can fill the spaces on both sides of the wall portion which has the set of openings. This without adversely affecting the strength of the profile element.

Sets of openings are suitably located on such wall portions which have adjacent other wall portions, for example the wall portions which form the groove, where the risk of heat transport by radiation and convection is great.

Description of preferred embodiments of the invention Below are described various embodiments of the invention with reference to the figures, in which: Fig. 1 shows a perspective view of a part of a profile element intended for use in a frame piece according to the invention.

Fig. 2 shows a section through a frame piece according to the invention before the insulating material has been heated and expanded.

Fig. 3 shows the section in Fig. 2 after the insulation material has begun to expand.

Fig. 4 shows a section through a frame piece according to an alternative embodiment, after the insulating material has been heated and expanded. 10 15 20 <~. . .n 524 8.75 a. Fig. 5 shows a section through a frame piece according to a further embodiment, after the insulating material has been heated and expanded.

Figure 1 shows in perspective a part of a profile element 1 which is intended to be included as a part in a frame piece according to the invention. The profile element consists of an elongate body which is formed of bent or roll-shaped steel plate. Alternatively, the profile element can be manufactured by extruding aluminum. The wall of the profile element consists of a number of elongate wall portions 5-15, which are parallel to the longitudinal axis of the profile element.

Figures 2-5 show different embodiments of the frame piece fastened in a door opening of a building wall 4 by means of fastening devices which are not shown. The frame piece comprises the profile element 1 shown in Figure 1. The section in Figures 2-5 is taken perpendicular to the longitudinal axis of the frame piece and the profile element and is seen from below the profile element shown in Figure 1. In the figures, a dashed line also indicates a door leaf 20 in the closed position.

Referring primarily to Fig. 2, the cross section of the profile element 1 has a generally rectangular part 2 and a projection 3 projecting from the rectangular part. The generally rectangular part 2 is formed by the wall portions 6, 7, 8, 13, 14. At one side of the rectangular part 2, the wall of the profile element is open. This side faces the short side of the wall 4, which short side faces the door opening. Extending through the open part 16 of the profile element wall, in a number of places along the length of the frame piece, are adjusting and fastening screws (not shown) which with one end abut against each other and penetrate into the short side of the wall 4. These screws are at its other end firmly connected to it to the wall. . - Q ~. o o nn onto o: nu 10 15 20 30 524 875 9. n -. .u opposite wall portion 8 of the generally rectangular part 8. The rectangular part 8 is further filled with rock wool 17 to prevent heat being transported by radiation and convection between this part 2 different wall portions.

Figure 2 also shows how two pieces of frame or door lining 31, 32 are attached to the frame piece. The two liners 31, 32 are designed as elongate profile elements of bent or rolled steel sheet. Alternatively, they can be made of extruded aluminum.

The cross section of the upper liner 31 shown in Figure 2 is formed by three wall portions 33, 34, 35 and has a general J-shape with a longer leg 33, a bottom 34 and a shorter leg 35.

The liner 31 is releasably attached to the frame piece by means of a number, preferably three, snap devices which are distributed along the length of the liner 31 and the frame piece. The frame piece therefore has a first lining groove 38 formed by the wall portions 5 and 6. In one of these wall portions, the wall portion 6 in the example shown, three openings 36 are arranged, one near each end of the frame piece and one in the middle.

The longer leg 33 of the liner 31 has three corresponding punched bulges 37. These openings 36 and bulges 37 constitute the snap devices for fastening the liner. When mounting the liner 31, the longer leg 33 is inserted into the groove 38, the elasticity of the material of the wall portions of the liner and the frame piece causing the bulges 37 to snap into the openings 36. The location of the openings 36 in the groove 38 and the bulges 37 on the leg 33 is so formed so that the short side 39 of the shorter leg 35 of the lining 31 ends up level with the surface of the building wall 4.

The lower liner 32 shown in Figure 2 is differently attached to the frame piece. The cross section of this liner also has a -. . But in this liner 32 the longer leg 40 is substantially longer relative to the shorter leg 42 than in the liner 31. The frame piece has a second lining groove 43 formed by the wall portions 14 and 15 of the liner. the profile element 1. This lining groove 43 is usually substantially deeper than the first lining groove 38 for the lining 31. When mounting the lining 32, it is first inserted into the groove so deep that the short side 44 of the shorter leg 42 of the lining 32 abuts against the wall 4. Then the lining is fixed longer leg 40 in the groove 43 by screwing a number of self-drilling screws 45 through the two wall portions 14, 15 of the profile element 1 forming the groove 43 and the longer leg 40 of the liner 32. For this purpose a number of openings (not shown) are arranged in the wall portion 12. of the profile element, through which openings screws and screwdrivers can be inserted for tightening the screws. Normally, three screws 45 are used, one near each end of the profile element and one in the middle.

There are several advantages to this new way of attaching door or frame lining to the frame pieces. On the one hand, the system allows easy attachment and removal of the liners 31, 32, which in turn means that the liners can be easily replaced if desired. On the one hand, it is possible that several different models of lining, in terms of color and shape, can be provided for one and the same type of door frame. However, the main advantage of the lining / frame combination described above lies in the fact that one and the same lining can be used for building walls with different thicknesses.

The system provides completely stepless adaptation to different wall thicknesses. Since the groove 43 is relatively deep, normally 30-50 mm, preferably about 40 mm, and the longer leg 40 of the liner 32 is relatively long, usually 35-400 mm, preferably about 75 mm, one and the same liner / frame combination is used for walls whose thickness. . . - ..-. n _ ...__ ___ .. _ .__ _. _ ._. 10 _ __ .. .__ _ ._ _ _. _ n .... .__ __... _ .. _ _ _ _... ._ .__ ___, _ ._. __ ". H _ __., 10 15 20 -.» »U. 524 875 ll differ by up to 35 mm. In addition, it is possible for one and the same type of door frame to provide lining 32 with different lengths of the longer leg 40. In this way, a modular system is obtained that is suitable for all wall thicknesses.

A further advantage of the flexible fastening of the lower liner 32 shown in Figure 2 is that during assembly it is possible to compensate for variations in the wall thickness along the length of the hug piece.

On the side opposite to the wall 4 of the generally rectangular part 2 of the profile element 1, the projection 3 is arranged. The projection 3 is formed by a number of wall portions 9-13, which form an open groove 18, a stop 11 and a support wall 12 for the stop. The groove 18 normally extends substantially along the entire length of the profile element. However, if necessary, it may be shorter than the profile element, for example to allow joining of several frame pieces to one frame. The groove is formed in the example shown by three wall portions 8, 9, 10, the cross section of the groove having a general U-shape. However, the cross section of the groove may also take several other shapes, with only two or more than three longitudinal wall portions forming the groove.

The groove 18 is further limited outwards, at its open part, by a wall portion 11 which forms the abutment of the door leaf 20, which is shown in dashed lines in Figures 2-5, when this is in the closed position.

In the groove 18 a strip 21 of expanding thermal insulation material is arranged, substantially along the entire length of the groove 18.

The insulation material is of such a nature that it expands sharply if heated. The material is further insulating against heat transport by radiation and convection, both before and after it has expanded. In addition, it has good gas and smoke sealing properties. . . . . .- 10 15 20 524 875 12 Examples of materials that can be used to form the strip are different mixtures of graphite, synthetic binders and sealants. Depending on the composition, such insulating materials begin to expand at about 170-190 ° C. With continued heating, the material expansion then continues to about 700-800 ° C. Typically, such a material has increased its volume by approx. 18 times if heated to 550 ° C under load and 37 times if heated to 450 ° C without load. Alternatively, a so-called fire strip marketed by BASF under the trade name "Palosol" can be used. This material increases its volume about 15 times when heated from 120 ° C to 600 ° C.

The strip 21 of the expanding insulating material is so arranged in the groove 18 that it fills the groove and projects beyond the stop 11, so that it will seal against the door leaf 20 when it is in the closed position. To further improve the sealing action against the door leaf 20, as shown in Figures 2-4, a conventional rubber sealing strip 22 can be vulcanized together with the expanding material, at the part of the expanding material projecting beyond the stop 11.

According to a first embodiment (see Figs. 2 and 3) of the invention, a set of openings 23 are arranged in the wall portion 10 which delimits the groove 18 at the side of the groove which faces the door opening, i.e. the wall portion 10 which, in the cross section of the profile element, extends from the bottom 9 of the groove to the wall portion 11 which constitutes the abutment. The set of openings 23 extends substantially along the full length of the profile element and consists of a plurality of slots arranged one after the other in the longitudinal direction of the profile element. The slots are elongate in the longitudinal direction of the profile element and are typically 10-40 mm, preferably 30 mm long and 3-5 mm, u Q. . .e 10 15 20 | . e - nu 524 875 13. ...- preferably 4.4 mm wide, the space between the slots in a set is typically 3-5 mm, preferably 4.4 mm.

In the event of a fire, for example on the side of the door facing downwards in Figures 2 and 3, the side of the door facing the hearth will be heated strongly. Typically, the temperature of this side of the door frame pieces after 60 minutes of fire can amount to about 850 ° C. The stone wool insulation 17 in the rectangular part 2 of the frame piece prevents heat from being transported by radiation and convection from the wall portions 13 facing 14 of the rectangular part which are and directly exposed by fire to the non-directly exposed, "cool" wall portions 6,7 of the rectangular part. 8. Furthermore, the slots 23 prevent heat transport by conduction from the wall portions 11-14 directly exposed by the fire of the entire profile element to the non-directly exposed wall portions 5-9 of the profile element. Nevertheless, heat will be transported to the wall portions 8,9,10 which form the track.

In this case, the temperature of the expanding insulation strip will also be raised.

When the temperature of the strip reaches around 170-190 ° C (if a graphite strip is used), the insulation material begins to expand (see Fig. 3). Since the slits 23 according to the invention are arranged close to the insulating material, this material will now penetrate into and completely fill the slits 23. Thereby also heat is prevented from being transported by radiation and convection between each edge 23 edge surfaces. The total heat transport through the wall portion 10 in which the slots are arranged is thus significantly reduced. This reduction in heat transport is particularly significant in this wall portion because the wall portion forms a heat transport boundary between the part of the frame piece which is directly exposed by the heat from the hearth and the unexposed part. - - ~. In addition, as the insulating material 21 expands, it will penetrate the slits 23 and completely fill the space between the wall portion 10 in which the slits are arranged and the wall portion 12 which forms a support wall for the abutment 11. This counteracts radiation and convection between these wall portions 10, 12 and between these two wall portions 10, 12 and the wall portion 11 which constitutes the stop. Since the distances between all these three wall portions 10.11, 12 are relatively small, whereby radiation and convection between them would otherwise be significant, such a counteracting effect is significant. These three wall portions 10,1l, 122 are also on the boundary between the exposed and non-exposed parts of the frame piece, which further increases the importance of the reduction of heat transport which is achieved.

Another significant effect is that the insulating material 21, as it gradually expands, follows the surrounding geometries. The insulating material thus fills all the spaces between the surrounding wall portions 10, 11, 12, even if these are deformed due to non-uniform heating.

In this way, voids are prevented between the wall portions, in which voids the effect against radiation and convection would otherwise be absent. Yet another positive effect of the invention is that the insulating material 21 consumes heat as it expands. During the expansion of the insulation material, therefore, heat is transferred from surrounding wall portions to the insulation material. This means a reduced temperature increase of these surrounding wall portions, which in turn counteracts heat transport through the profile element.

It should be noted that the insulating material 21 also expands in the outward direction from the groove 18 seen. In this case, the insulating material 21 will fill in any spaces and gaps ~ »-. .- 10 15 20. . -. .- 524 875 15 ...- between the door leaf 20 and the frame piece, which spaces and gaps may exist from the beginning or arise due to heat deformations. The expanding insulating material 21 thus also counteracts heat transport through both conduction and radiation and convection between the door leaf 20 and the frame piece. In addition, a good seal is ensured which prevents gases and smoke from escaping through the door.

According to a second embodiment (see Fig. 4), a set of 24 slots is arranged in the wall element 9 which forms the bottom of the groove.

Corresponding effects are achieved in terms of counteracting heat transport through the line as well as radiation and convection through the frame piece. The difference in this embodiment compared to the one described above is that heat conduction is counteracted in the wall portion which constitutes the bottom 9 of the groove. If the dimensional relationship between the volume of insulating material 21 contained in the groove 18 and the internal volume of the protrusion 3 is optimized with respect to the insulating ability the insulating material as it expands is made to fill the entire inner space of the projection 3. In this way a good counteracting against heat transport is obtained in a simple manner by radiation and convection between all the critically placed wall portions 9,10, 11, 12, 13, which form the projection 3. .

According to a third embodiment (see Fig. 1), slots 25 are arranged in the wall portion 8 which delimits the groove towards the generally rectangular part of the profile element. In this case, it is obtained in the first place that heat conduction as well as radiation and convection through the wall portion 8 itself and its openings are counteracted.

According to a fourth embodiment (see Fig. 5), openings 26 are arranged in the wall portion 11 which constitutes the stop and the expanding insulating material is arranged on the opposite side. 4 ~. .. 10 15 20 -. -. .- 524 875 16 - 4 ... side of this wall element 11 in relation to the door leaf 20. As the insulating material expands, it then partly penetrates the openings and fills any gaps between the door leaf and the frame piece, whereby both conduction and radiation and convection between these door leaf and frame piece are counteracted. At the same time, the insulating material also expands into the inner space of the projection 3, so that the advantages described in the second embodiment above are also obtained.

Experiments A fire test according to the Swedish and European test standard SSEN 1634-1 was performed on a fire door provided with frame pieces according to the invention and a reference door. In this case, a fire door was heated provided with a frame of three frame pieces (two side frame pieces and one upper frame piece) according to the invention and a threshold successively on one side. The frame pieces were designed in accordance with the third embodiment above. Ie. the strip 21 of expanding insulating material was arranged in a U-shaped groove 18 between the rectangular part 2 of the profile element and the stop 11 and a set of openings in the form of elongate slits were arranged in the wall portion 8 which formed the wall of the groove against the rectangular part 2 of the profile element.

The slits were 30 mm long, 4.4 mm wide and placed at 4.4 mm intervals along the entire length of each frame piece, 8 mm into the wall portion 8 from the bottom of the groove 9. For reference, the same test was performed with an identical fire door without such openings.

During the heating process, the temperature rise was measured at a plurality of measuring points, which were identically placed on the other, not directly heated, side of the two frames. The result for one of these measuring points is reported below (Atemp. = The temperature of the measuring point at the current time - the initial temperature of the measuring point):. . . - - 10 15 524 875. -. . .o 17 _ Tid Atemp. without Atemp. with Difference Difference [min] openings [° C] openings [° C] [° C] [%] 30 237 229 8 3.4 36 266 257 9 3.4 60 344 325 19 5.5 68 357 338 19 5, As can be seen from the table above, heat transport through the frame was counteracted to a significantly greater extent in the fire door which was provided with frame pieces according to the invention.

In accordance with the invention, it is of course possible to combine several of the embodiments described above and also to place openings with adjacent expanding insulation materials in other wall portions, where it is desirable to counteract heat transport by both conduction and radiation and convection.

The invention has been described above in connection with a fire door.

It is of course also possible to use the frame piece in other applications, such as for windows, shutters or gates, where it is desirable to counteract heat transport through the frame.

Claims (12)

10 15 20 25 30 524 875 ~~~ 18 E "Eu! .'2- .. .. .. _. .. ... z Krav A frame piece for a door, window or the like comprising a profile element (1) and a thermal insulation material (21) which expands on heating and which is arranged at the profile element, at least one opening (23) being arranged through a first wall portion (10) of the profile element , in the vicinity of the expanding insulating material, to allow, when heating the frame piece, to allow the insulating material to expand through the opening, characterized in that the profile element comprises a second wall portion (12) which is arranged so as to form a space between the first and second wall portions, and in that the opening (23) and the insulating material (21) are arranged so that the insulating material, when it expands, completely or partially, fills the space between the first and second wall portion to counteract heat transport through the frame piece. Frame piece according to claim 1, characterized in that the insulating material (21) is arranged on the side of the first wall portion (10) opposite to the second wall portion (12). 3. A frame piece according to any one of the preceding claims, characterized in that the profile element comprises a third wall portion (8) which together with the first wall portion (10) forms a groove (18) extending in the longitudinal direction of the profile element, in which groove the insulating material (21) is provided. Frame piece according to claim 3, characterized in that the first (10) and second (12) wall portions are connected by a fourth wall portion (11), which faces the door leaf (20) and forms a stop for the door leaf, when it is closed mode and -. . »A. 10 15 20 25 n ø c n ~ o - -. - »- a. . -. ~. -. ._ in oo '. -. ... - 19. . . . .. .. .. .. .. .. ... which constitutes an open lateral boundary of the groove (18), the insulating material projecting beyond the open boundary to, when the door leaf is in the closed position, form a seal between the frame piece and the door leaf . Frame piece according to one of the preceding claims, characterized in that one or more of the wall portions (5-15) of the profile element have one or more sets of openings (23, 24, 25, 26), the openings in each set being arranged, the one after the other, in the longitudinal direction of the profile element. Frame piece according to one of the preceding claims, characterized in that the first wall portion (10) has a set of openings (23), which openings are arranged, one after the other, in the longitudinal direction of the profile element. Frame piece according to one of Claims 3 to 6, characterized in that the third wall portion (8) has a set of openings (25), which openings are arranged, one after the other, in the longitudinal direction of the profile element. Frame piece according to one of Claims 3 to 7, characterized in that the first and third wall portions are joined by a fifth wall portion (9) which forms the bottom of the groove (18), this fifth wall portion (9) having a set of openings (24). which openings are arranged, one after the other, in the longitudinal direction of the profile element. Frame piece according to one of Claims 4 to 8, characterized in that a set of openings (26) is arranged in the fourth wall portion (11) and in that the insulating material is arranged on the side of the fourth wall portion (11) opposite the door leaf (20). 10 15 20 nn ~ - nu - un Q - -. . s. Frame piece according to one of Claims 3 to 9, characterized in that the insulating material (21) is designed as a strip which is arranged in the groove (18) and which extends substantially along the full length of the groove. 11. ll. Frame piece according to one of the preceding claims, characterized in that a first (31) and a second (32) frame liner are detachably attached to the frame piece, the first (31) frame liner having an elongate wall portion (33) projecting into a first lining groove. (38) of the frame piece and which in this lining groove (38) is detachably fastened by means of a number of snap devices (36, 37) which are arranged along the length of the frame lining (31) and the frame piece and in that the second frame lining (32) has an elongate wall portion ( 40) projecting into a second liner (43) of the frame piece and removably attached to said second liner (43), the depth of the second liner (45) and the dimensions of the elongate wall portion (40) of the second liner (32) are designed to allow attachment of the second liner (32) as its elongate wall portion (40) projects into the second liner groove (43) to varying degrees. Fire door characterized in that it comprises one or more frame pieces according to any one of the above claims.