Sheet metal plate with raised areas for creating industrial flooring with improved adhesive properties

Abstract

The invention relates to a sheet metal plate (10) for creating flooring (30), in particular for industrial vehicles, having on its upper surface (11) a plurality or raised patterns, each raised pattern comprising one or more protruding portions (20), the raised patterns being arranged periodically, discreetly and in orderly fashion, the height h of the raised patterns being between 0.3 and 3 mm, characterized in that the plate has, on its lower surface (12), which is intended to be bonded to a support member, a rough surface the roughness Rmax of which is between 10 m and 250 m. The invention also relates to the method of producing said plate and the use of said sheet metal plate for creating flooring for industrial vehicles, preferably flooring for refrigerated vehicles.

Claims

1. A sheet metal plate for making flooring, said sheet metal plate having on an upper face thereof a plurality of raised patterns, each raised pattern comprising one or more protruding portion(s), said raised patterns being arranged periodically, discreetly and in orderly fashion, the height h of said raised patterns being comprised between 0.3 and 3 mm, wherein said sheet metal plate has on a lower face thereof, intended to be bonded to a support, a rough surface whose roughness R.sub.max is comprised between 10 m and 250 m.

2. The sheet metal plate according to claim 1, wherein the roughness R.sub.max of said rough surface is comprised between 50 m and 150 m.

3. The sheet metal plate according to claim 1, wherein the roughness of the lower face is obtained by electrochemical milling, mechanical milling, brushing, or by deformation.

4. The sheet metal plate according to claim 1, wherein the roughness of the lower face is obtained by a texture repeated periodically and in orderly fashion.

5. The sheet metal plate according to claim 1, wherein the sheet metal plate is made of an aluminum alloy belonging to the group including the aluminum alloys of the 1xxx, 3xxx, 5xxx, 6xxx series according to the designation of the Aluminum Association as well as the alloys of the 7xxx series, comprising less than 0.4% Cu.

6. The sheet metal plate according to claim 1 for making flooring of industrial vehicles.

7. The sheet metal plate according to claim 2, wherein the roughness R.sub.max of said rough surface is comprised between 100 m and 140 m.

8. The sheet metal plate according to claim 3, wherein the roughness of the lower face is obtained by sandblasting, shot-peening, rolling, embossing, and/or crimping.

9. The sheet metal plate according to claim 3, wherein the roughness of the lower face is obtained by rolling.

10. The sheet metal plate according to claim 4, wherein the roughness of the lower face is made by rolling.

11. The sheet metal plate according to claim 6 for making flooring of refrigerated vehicles.

12. A method of manufacturing a sheet metal plate according to claim 1, comprising: (i) rolling using a rolling engraved roll including engraved cavities allowing obtaining the raised patterns of the upper face of the sheet metal plate; (ii) electrochemical milling, mechanical milling, brushing, or deformation, allowing obtaining the roughness of the lower face of the sheet metal plate.

13. The method according to claim 12, wherein (i) and (ii) are carried out simultaneously on a rolling mill including two engraved rolls: a first engraved roll to obtain the raised patterns of the upper face and a second engraved roll to obtain the texture of the lower face of the sheet metal plate.

14. The method according to claim 13, wherein the two engraved rolls are work rolls used during a last pass of a hot tandem rolling mill.

15. The method according to claim 12, wherein (ii) is carried out by sandblasting, shot-peening, rolling, embossing, and/or creeping.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic sectional representation of a sheet metal plate with raised areas according to the prior art.

(2) FIG. 2 is a schematic sectional representation of a sheet metal plate according to the invention.

(3) FIG. 3 is a schematic sectional representation of a sheet metal plate according to the invention according to an advantageous embodiment.

(4) FIG. 4 schematically illustrates bonding of a sheet metal plate according to the invention on a wooden flooring.

(5) FIG. 5 shows the patterns of Examples B (FIG. 5a) and C (FIG. 5b).

(6) FIG. 6 is a schematic representation of the lap shear test.

(7) FIG. 7 is a schematic representation of a rolling mill used in the method according to the invention.

(8) FIG. 8 shows the patterns of Examples E (FIG. 8a), F (FIG. 8b), and G (FIG. 8c).

DETAILED DESCRIPTION OF THE INVENTION

(9) The sheet metal plate according to the invention is a sheet metal plate intended to be bonded to a support to form the flooring of a vehicle. According to the common definition, a sheet metal plate is a rolled product with a generally rectangular cross-section whose average thickness does not exceed 1/10th of the width. The flooring is the portion of a construction work or a vehicle which forms a horizontal platform, the upper face of which forms the ground. The roughness parameter R.sub.max is defined as the largest difference between the highest peak and the lowest trough over the analyzed length or the analyzed surface. Typically, the analyzed length has a direction perpendicular to the rolling direction of the sheet metal plate and has a value depending on the value R.sub.max, as described hereinafter:

(10) TABLE-US-00001 0.025 m < R.sub.max 0.1 m typical analyzed length: 0.08 mm 0.1 m < R.sub.max 0.5 m typical analyzed length: 0.25 mm 0.5 m < R.sub.max 10 m typical analyzed length: 0.80 mm 10 m < R.sub.max 50 m typical analyzed length: 2.50 mm 50 m < R.sub.max 250 m typical analyzed length: 8.00 mm

(11) It might be more appropriate for some facets featuring discrete patterns to characterize by a surface large enough to include several patterns.

(12) In particular, the parameter R.sub.max is mentioned in BS 1134 2010 A2 wherein the definitions hereinabove may be supplemented where necessary.

(13) The sheet metal plate according to the invention has on its upper face, intended to form the upper face of the flooring, raised patterns which comprise one or more protruding portion(s) and which, like the elementary mesh of a crystal lattice, are repeated periodically and in orderly fashion. Hence, a raised pattern is a piece of sheet metal which is repeated indefinitely by translation in two directions of the plane of the sheet metal plate. This piece of sheet metal may comprise only one protruding portion but it may also comprise several protruding portions which may have different shapes or orientations. It does not seem advantageous to have protruding portions with different heights but this is not excluded a priori. The height h of these raised patterns is comprised between 0.3 mm and 3 mm. The height of the raised pattern is the difference, h, between the maximum thickness measured up to the top of the pattern and the thickness t of the relief-free adjoining area. Advantageously, in particular as regards sheet metal plates with raised areas made of an aluminum alloy, it is comprised between 0.3 and 1.5 mm, preferably between 0.4 and 0.8 mm.

(14) Said patterns are also repeated discreetly, because such a configuration is favorable to the non-skid property of the flooring. Indeed, the reliefs behave like indenters which act on the surface of the sole or the tread of the wheel: under the effect of the weight of the pedestrian or the trolley, the latter deforms and sinks around the relief over a given height whose order of magnitude is one, two or three tenths of a millimeter. A discontinuous relief promotes, in the sole or the tread, the formation of a bead all around its top wall, which promotes hooking of the sole, the tread or the tire of the wheel on the floor. On the other hand, patterns that are discreetly repeated facilitate cleaning, the flow of fluids and the discharge thereof being easier. Hence, the sheet metal plate according to the invention should not have any continuous relief.

(15) The raised patterns of the upper face are obtained by rolling using a rolling engraved roll characterized in that it includes engraved cavities allowing obtaining the raised patterns of the sheet metal plate.

(16) According to the invention, the lower face of the sheet metal plate, intended to be bonded to a flooring, has a rough surface whose roughness R.sub.max is comprised between 10 m and 250 m and preferably between 50 m and 150 m, preferably between 100 m and 140 m.

(17) The present inventor has noticed that thanks to the roughness of the lower face of the sheet metal plate, the adhesion between the flooring, typically made of wood, and the sheet metal plate is satisfactory in the absence of surface treatment and of primer deposition. In particular, the roughness according to the invention may be obtained by electrochemical milling, mechanical milling, brushing, or by deformation, typically sandblasting, shot-peening, rolling, embossing, creeping. Preferably, the roughness is obtained by rolling.

(18) In an advantageous embodiment of the invention, the roughness of the lower face of the sheet metal plate is obtained by a texture, preferably made by rolling. In this embodiment, the sheet metal plate according to the invention has on its lower face a texture which comprises one or more protruding portion(s) and which are repeated periodically and in orderly fashion. It does not seem advantageous to have protruding portions with different heights but this is not excluded a priori. In this embodiment, the roughness R.sub.max of the lower face of the sheet metal plate corresponds to the maximum height of these protruding portions of the lower face. Preferably, in this preferred embodiment, at least 30% and preferably at least 50% of the lower face of the sheet metal plate is covered by the texture and/or the dimension of the texture is comprised between 1 and 6 mm and/or the replication pitch of the texture is comprised between 1 and 6 mm.

(19) Advantageously, the sheet metal plate according to the invention is an aluminum alloy sheet metal plate. Advantageously, the sheet metal plate is made of an aluminum alloy belonging to the group including the aluminum alloys of the 1xxx, 3xxx, 5xxx, 6xxx series according to the designation of the Aluminum Association as well as the alloys of the 7xxx series, comprising less than 0.4% Cu. Preferably, the alloy is selected from the list consisting of AA1050A, AA3003, AA3103, AA5026, AA5052, AA5083, AA5086, AA5754, AA6061, AA6082 and AA7020.

(20) FIG. 2 schematically represents a sheet metal plate 10 according to the invention having on its upper face 11 a raised pattern comprising a protruding portion 20, with a height h and on its lower face 12, a rough surface.

(21) FIG. 3 schematically represents a sheet metal plate 10 according to the invention in a preferred embodiment having on its upper face 11 a raised pattern comprising a protruding portion 20, with a height h and on its lower face 12, a rough surface consisting of a texture including protruding portions repeated periodically and in orderly fashion.

(22) FIG. 4 schematically represents a flooring 30 comprising a sheet metal plate 10 according to the invention bonded to a board 32 using an adhesive 31.

(23) The method for manufacturing the sheet metal plates according to the invention comprises (i) A rolling step using a rolling engraved roll including engraved cavities allowing obtaining the raised patterns of the upper face of the sheet metal plate. (ii) A step of electrochemical milling, mechanical milling, brushing, or deformation, typically sandblasting, shot-peening, rolling, embossing, creeping, allowing obtaining the roughness of the lower face of the sheet metal plate.

(24) Advantageously, the two steps are carried out simultaneously on a rolling mill including two engraved rolls: a first engraved roll to obtain the raised patterns of the upper face and a second engraved roll to obtain the texture of the lower face. In an advantageous embodiment, the two engraved rolls are the work rolls used during the last pass of a hot tandem rolling mill. A tandem rolling mill is a rolling mill comprising several successive stands, wherein the product is engaged in several stands at the same time.

(25) FIG. 7 schematically represents the last stand 40 of a hot tandem rolling mill in this embodiment. The used working rolls 41, 42 are engraved rolls. A first engraved roll 41 includes cavities 411 allowing obtaining the raised patterns of the upper face. A second engraved cylinder 42 includes cavities 421 allowing obtaining the texture of the lower face of the sheet metal plate.

(26) The use of the sheet metal plates according to the invention to make flooring of industrial vehicles, preferably flooring of refrigerated vehicles is particularly advantageous.

Example

(27) In this example, the adhesion performance of a 2.5 mm thick sheet metal plate made of the AA5086 alloy, having on the upper face a relief with a rice grain pattern as defined in the standard NF EN 1386 and on the lower face a variable roughness, has been compared. In a reference example A, the lower face was unrolled and the roughness R.sub.max was smaller than 3 m. In examples according to the invention B, C, E, F and G the lower face was textured with patterns having reliefs with different heights as described in Table 1. The textured patterns have been obtained by rolling with an engraved roll. The same roll has been used for the samples B and C with a different clamping force so as to make the depth of the indentation vary. These textures are shown in FIG. 5. The pitch of the patterns being about 4 mm in the X and Y direction. The patterns were circles with a diameter of about 2.5 mm. The patterns of Examples E, F and G are shown in FIGS. 8a, 8b and 8c, respectively. All samples have been degreased and then a lubricant (Lubrilam) has been deposited on the surface at 0.3 g/m 2 so as to simulate an unrolled sample under reproducible conditions. A fourth sample D has been prepared according to the prior art by depositing an adhesion primer varnish over the lower face.

(28) The configuration of the test is shown in FIG. 6. Samples measuring 10025 mm of a sheet metal plate 10 and plywood boards 32 have been bonded using an epoxy 31 (Korapr 666) type glue over a joint length of 16.5 mm and undergone a lap shear test. The obtained results are shown in Table 1. When the break-up occurs within the wood or within the glue, the break-up is said to be cohesive. When the break-up occurs at the interface between the sheet metal plate and the glue, the break-up is said to be adhesive. In the absence of a textured pattern, the break-up is essentially adhesive and a strong dispersal of the shear force is observed. On the contrary, in the presence of the textured pattern, the break-up is cohesive and the obtained force is similar to that obtained according to the prior art in the presence of an adhesion primer.

(29) TABLE-US-00002 TABLE 1 Sheet metal Adhesion R.sub.max Shear force plate primer (m) Break-up (MPa) A No <3 Adhesive 9.6 +/ 4.1 B No 137 Cohesive 12.2 +/ 0.5 C No 87 Cohesive 10.7 +/ 0.6 D Yes <3 Cohesive 11.6 +/ 0.7 E No 110 Cohesive 11.2 +/ 1.2 F No 108 Cohesive 10.8 +/ 2.2 G No 98 Cohesive 9.2 +/ 2.8