WO2009098361A1

WO2009098361A1 - Mineral wool element, manufacturing method thereof and method for insulating curved surfaces

Info

Publication number: WO2009098361A1
Application number: PCT/FI2009/050098
Authority: WO
Inventors: Esa SEPPÄNEN; Lasse Satka; Risto Hevosmaa
Original assignee: Paroc Oy Ab
Priority date: 2008-02-08
Filing date: 2009-02-06
Publication date: 2009-08-13
Also published as: RU2010136406A; UA99336C2; LT2252456T; EP2252456B1; FI20085116L; EP2252456A1; FI20085116A0; PL2252456T3; RU2450932C1

Abstract

The invention relates to a mineral wool element (7), its fabrication method, and a method for insulating curvilinear surfaces, as well as a wind-load resistant structure comprising a curvilinear building surface, an insulation layer (2) of mineral wool installed thereon, and a sheet metal skin (1) protecting the outside of this insulation layer. The mineral wool element (7) according to the invention includes an insulating mineral wool layer (2) with two opposite main surfaces, one of which is clad with a pliable sheet metal (1) and the other is made up by bare mineral wool, the sheet-metal clad mineral wool layer being pliable jointly with the sheet metal. Such an element (7) can be fabricated either in such a way that one of the two main surfaces of the mineral wool layer (2) is clad with pliable sheet metal (1) and the other is left uncovered, or in such a way that a conventionally fabricated mineral wool element (7) with sheet metal cladding (1', 1"), in which at least both opposite main surfaces of the mineral wool layer (2) have been clad with a pliable sheet metal (1', 1"), is split in two relative to the element's (7) thickness. The element (7) according to the invention enables curvilinear surfaces to be insulated as follows: on a curvilinear surface are installed one or more mineral wool elements of the invention by bending this particular mineral wool element substantially to the conformity with the curvilinear surface geometry in such a way that, of two opposite main surfaces of the mineral wool element, the one made up by bare mineral wool (2) becomes placed against said curvilinear surface to be insulated.

Description

MINERAL WOOL ELEMENT, MANUFACTURING METHOD THEREOF AND METHOD FOR INSULATING CURVED SURFACES

Object of the invention

One object of the invention is a mineral wool element, comprising an insulating mineral wool layer with two opposite main surfaces.

A second object of the invention is a method for the fabrication of a mineral wool element according to the invention.

Still another object of the invention is a method for insulating curvilinear surfaces with mineral wool and providing the same with a cladding sheet metal protecting the outside of mineral wool placed on a curvilinear surface.

A further object of the invention is a wind-load resistant structure, comprising a curvilinear building surface, an insulation layer of mineral wool installed thereon, and a sheet metal skin protecting the outside of this insulation layer.

Prior art

In prior art, the insulation of curvilinear surfaces, such as for example the outer walls of cylindrical storage tanks, with mineral wool has been highly laborious and tedious because of a plurality of different operations. For example, the insulation work of major industrial containers (diameter >8 m) has involved a lot of manual installation labor, such as the installation of support structures, a wool lining, and covering sheet metals from a scaffolding erected around the tank. The installation of support structures has involved making a reinforcement system around an upright storage tank, as well as welding insulation attachment studs and brackets to the reinforcement. This has been followed by securing the insulation in the form of mats or slabs onto the outer surface of the tank by means of the studs. All junctions have been caulked with loose mineral wool. Finally, section sheet metals have been secured for cladding the wool lining.

The above-described approach has been a common way of insulating upright storage tanks and it is described in standard SFS 3978 of the Finnish Standards Association. This common way has been highly laborious and tedious. The Applicant has now invented a new approach with fewer operations, whereby the insulation work for curvilinear surfaces can be remarkably simplified and accelerated, resulting in reduced costs.

Disclosure of the invention

In view of eliminating the prior art problems, a mineral wool element of the invention is characterized in that one of the two opposite main surfaces of the mineral wool layer is clad with a pliable sheet metal and the other made up by bare mineral wool, the sheet-metal clad mineral wool layer being pliable jointly with the sheet metal.

On the other hand, a method of the invention for the fabrication of a mineral wool element is characterized in that

(a) one of the two main surfaces of a mineral wool layer is clad with a pliable sheet metal and the other is left unclad, the mineral wool layer of a thus obtained mineral wool element being pliable jointly with the sheet metal, or

(b) a conventionally fabricated, sheet-metal clad mineral wool element, in which at least both opposite main surfaces of the mineral wool layer have been clad with a pliable sheet metal, is split in two relative to the element's thickness, resulting in two mineral wool elements, each having one of its two opposite main surfaces substantially made up by bare mineral wool and the other by sheet metal, each sheet-metal clad mineral wool layer being pliable jointly with the sheet metal.

On the other hand, a method of the invention for insulating curvilinear surfaces is characterized in that on a curvilinear surface are installed one or more mineral wool elements as set forth in any of claims 1-4, or mineral wool elements fabricated according to the method of claim 5, by bending the mineral wool element in question substantially to the conformity with the curvilinear surface geometry in such a way that, of two opposite main surfaces of the mineral wool element, the one made up by bare mineral wool becomes placed against said curvilinear surface to be insulated.

As already presented above, the invention further relates to a wind-load resistant structure, comprising a curvilinear building surface, an insulation layer of mineral wool installed thereon, and a sheet metal skin protecting the outside of this insulation layer. In this structure according to the invention, for which protection has been claimed in the independent claim 11, the curvilinear surface has installed thereon one or more mineral wool elements as set forth in any of claims 1-4, or mineral wool elements fabricated according to the method of claim 5, which have been brought by bending substantially to the conformity with the curvilinear surface geometry, and that, of two opposite main surfaces of the mineral wool element, the one made up by bare mineral wool is placed against said curvilinear surface to be insulated, whereby the sheet metal skin and the mineral wool layer in attachment therewith function jointly as a composite structure, by virtue of which the membrane forces developed on the sheet metal skin of a mineral wool element as a result of wind pressure and suction are passed into the mineral wool layer having a sufficient compression strength, wherefrom the compression forces are passed further to a tank wall with uniform compression. In one preferred embodiment for a mineral wool element of the invention, the mineral wool layer is adhesive-bonded to the sheet metal cladding. The mineral wool layer can be in the form of a mineral wool mat, a mineral wool slab, or a structure consisting of laminar sheets. In a mineral wool mat or slab, the fibers are generally settled in a substantially longitudinal direction of the slab or mat (orientation 0°). In slabs made up by lamellar sheets of mineral wool (lamellar slab), the mineral fibers are generally at right angles (orientation 90°) relative to the lamellar slab's major surfaces. Such lamellar slabs have the maximum compression strength at right angles relative to the lamellar slabs' major surfaces, whereas the thermal conductivity thereof is higher, which means that the insulation capacity is respectively lower. On the other hand, the mineral wool slab or mat, in which the orientation of fibers is substantially 0°, has a lower thermal conductivity and thereby a better insulation capacity. In this case, the product again has a lesser compression strength. Alternatives for these two options come in the form of such lamellar products (slabs or mats), in which the orientation of fibers lies between 0° and 90°, whereby a desired compromise solution can be reached with a compression strength sufficient for the purpose and a thermal conductivity respectively sufficient for the purpose.

In addition to inventing a new approach with fewer operations, by which the installation work for curvilinear surfaces can be remarkably simplified and accelerated, thereby reducing costs, the Applicants have discovered that their invention is much more wind-load resistant than the prior art solutions. This effect is achieved when the sheet metal skin and the mineral wool layer attached thereto e.g. by adhesive bonding (or by any other way known to a skilled artisan) function as a composite structure. By virtue of its composite structure, the membrane forces developed on the sheet metal skin of a mineral wool element as a result of wind pressure and suction are passed into the mineral wool layer having a sufficient compression strength, wherefrom the compression forces are passed further to a tank wall with uniform compression. As a result, the loads applied to the tank are distributed more evenly than in the traditional prior art method.

What is the sufficient compression strength in each case depends on the size of an object to be insulated, i.e. on the size of a tank's diameter, for example. If the question is e.g. about a fairly large-size tank (4 m or more in diameter), a sufficient compression strength is attained by using mineral wool elements of the invention, in which the slab-shaped insulation layer is substantially constituted by lamellar sheets of mineral wool with the fibers at an orientation of 90° relative to the mineral wool element's main surfaces. If the object to be insulated is a smaller tank, it is possible to attain a sufficient compression strength by using a "regular" mineral wool slab (fiber orientation 0°) as a mineral wool layer in an element of the invention. In some other insulation projects, a sufficient compression strength can also be reached by means of a lamellar slab (or mat), in which the fiber orientation relative to the mineral wool element's main surfaces is between 0° and 90°.

In one preferred embodiment for a structure of the invention, the curvilinear building surface is a cylindrical storage tank's outer wall, whereby the structure's mineral wool layer has been selected to have a sufficient compression strength depending on a size of the tank's diameter, e.g. if the tank to be insulated has a diameter of 4 m or more, the mineral wool layer must have its fibers at an orientation of 90° relative to the mineral wool layer's main surfaces.

In another preferred embodiment for a structure of the invention, the diameter of a storage tank to be insulated is 4 m or more, the orientation of fibers is 90° relative to the mineral wool layer's main surfaces, the mineral wool elements have vertical tongue-and-groove joints which are further secured by screws. Preferably, the mineral wool element has at least two of its opposite ends provided with tongues and grooves. In another preferred embodiment of the mineral element, the sheet metal consists of a sheet metal which is rustproof or coated with an anti-corrosive covering.

In this application, the term "sheet metal" is used in reference to a thin plate composed of metal, wherein the metal can be any metal, such as e.g. steel or a metal alloy. Thus, the "rustproof sheet metal" may refer e.g. to zinc coated steel. In addition, the sheet metal can be coated with some anti- corrosive covering, such as plastic.

In one preferred embodiment for a method of the invention intended for insulating curvilinear surfaces, the curvilinear surface to be insulated is a substantially cylindrical storage tank's jacket surface with a radius of not less than 4 m. In another preferred embodiment of this method, the mineral wool elements are secured to each other with tongues and grooves, present at least in a vertical direction thereof, and to the surface to be insulated with fastening elements. It is further preferred that the fastening elements be secured through the elements at least across the tongue-and-groove joints, such that the fastening element extends through both pairs of tongues and grooves in a tongue-and-groove joint. It is also preferred that the installation placement of mineral wool elements be performed by means of hoists. The hoisting can be conducted by using either lifting devices provided with suction pads or mechanical grippers capable of grabbing insulation elements and lifting the same.

The invention enables reaching a clearly increased rate of installation speed and, moreover, the novel installation procedure does not require specialists' work input to the same extent as the traditional solution as there are distinctly fewer operations involved. By using the insulation method and insulation element of the invention, it is possible to attain an installation rate of 200-300 m²/day. The insulation method and insulation element of the invention are particularly useful for insulating the outer walls of cylindrical storage tanks. In case the insulation elements are installed in vertical orientation, and are for example 1200 mm in width, said elements are particularly useful for insulating the outer walls of such cylindrical storage tanks which measure more than 8 m in diameter. There is no actual upper limit for the diameter of a tank, but a typical diameter for large-size tanks is 52 m.

Drawings

The invention will now be described more closely by way of example with reference to the accompanying drawings, in which:

Fig. Ia shows a mineral wool element of the prior art in a perpendicular width-wide cross-section, which element can be used for fabricating an insulation element of the invention,

Fig. Ib shows an insulation element of the invention in one preferred embodiment, which is obtained by splitting the element of fig. Ia relative to its thickness,

Fig. 2a shows a mineral wool element of the invention in its application as insulation for the outer walls of an upright storage tank in a cross-section from above the storage tank,

Fig. 2b is an enlarged view of a detail in fig. 2a,

Fig. 3 shows the embodiment of fig. 2a in a perpendicular side view, Fig. 4 shows the stresses applied to a skin 1 and an insulation core 2 of insulation elements 7 installed vertically on a storage tank's cylindrical outer wall, and

Fig. 5 shows the effect of a wind suction force F on the outer surface of insulation elements.

Example

Fig. Ia illustrates a prior art insulation element, consisting of a core 2 in the shape of a mineral wool slab between two sheet metal skins 2. The mineral wool core 2 can be for example a rockwool slab whose fibers, in longitudinal directions thereof, extend in a direction substantially perpendicular to the main surfaces of sheet metals 1' and 1". This prior art element has its two longer edges provided with double tongues and grooves. Along one longer flank extend tongues 3' and 3" and along the other longer flank respectively two grooves 4' and 4". The prior art insulation element can be fabricated, according to the prior art, by gluing the sheet metals 1' and 1" to two main surfaces of the mineral wool slab core 2.

The Applicants have now invented that a mineral wool element 7, which essentially consists of a mineral wool slab 2 having just one of its two opposite main surfaces lined with a sheet metal 1, the other main surface being thus made up by bare mineral wool, is exactly appropriate in terms of its pliability for insulating curvilinear, such as e.g. convex or concave, surfaces. Such mineral wool elements according to the invention can be fabricated for example by sawing a prior art mineral wool element shown in fig. Ia for two halves relative to the direction of its thickness. Hence, there is obtained an insulation element 7 shown in fig. Ib, which is good for insulating curvilinear surfaces and which consists of a rockwool slab 2 with one of its main surfaces having a sheet metal cladding 1 adhesive-bonded thereto. This insulation element 7 has one of its longer flanks provided with one tongue 3 worked on the sheet metal 1 and its opposite longer flank provided with one groove 4 worked on the sheet metal 1.

This type of two-layer element 7 of the invention need not necessarily be fabricated by sawing a sandwich element of the prior art in two, but it can also be manufactured in such a way that to a mineral wool slab or mat 2, on one of its main surfaces, is adhesive-bonded a sheet metal 1, which has a pre-existing tongue 3 and a pre-existing groove 4 extending along its two opposite flanks.

The sheet metal 1 is conveniently plastic-coated for higher resistance to ambient weather conditions and for protecting the sheet metal from rusting.

The two-layer rockwool element 7 lends itself particularly well to vertical installation on an outer surface 5 of upright storage tanks 8, meaning that the tongue 3 and the groove 4 position themselves respectively in a vertical position relative to the groove 4 and the tongue 3 of another rockwool element 7 to be placed alongside. The rockwool element 7 does not have tongues and grooves on its two shorter flanks.

Fig. 2a shows in a plan view and in cross-section a cylindrical storage tank 8 insulated with insulation elements 7. If the insulation element 7 is for example 1200 mm in width, it will be particularly useful for vertical installation around such a storage tank 8 which has a radius r of more than 4 m. There is no absolute upper limit for the radius r, but the largest cylindrical storage tanks 8 have had the radius r of 26 m.

In fig. 2b, which is an enlarged detail from fig. Ia, there is shown one option of ensuring the reliability of tongue-and-groove joints established by the tongue and groove 3 and 4. This option is based on using screws 6 for screwing the connections of tongues and grooves to the engagement with the storage tank's 8 outer wall 5, such that each screw 6 extends through both grooves and tongues 4 and 3 of a tongue-and-groove joint.

The reason why the vertical joints established by the tongues and grooves 3 and 4 must be further secured by means of the screws 6 is the Applicants' discovery that provided this way around the storage tank 8 is a shell which is capable of withstanding the membrane forces produced by wind suction loads. However, this ability to withstand or absorb membrane forces requires that the mineral wool layer be provided with a sufficient amount of compression strength. In this example, the sufficient compression strength is obtained by using an insulation layer 2 made up by lamellar sheets of mineral wool, in which the fibers, as regards the longitudinal directions thereof, are substantially perpendicular to an external sheet metal skin 1. The more densely there are screws 6 received vertically in the connections, as well as also in the horizontal edges (which have no tongue-and-groove joints) of the insulation elements 7, the more reliably the insulation elements making up an outer skin for the storage tank 8 remain stationary and withstand the wind load. As a result of the rockwool sheets' high compression strength, the insulation layer 2 has a capability of absorbing those compression forces which develop in response to a reaction force (i.e. counter-force) of the wind pressure and the membrane forces. Thus, the membrane forces resulting from the wind suction are passed by way of a sheet metal skin into a mineral wool layer, which, by virtue of its compression strength, transmits such forces to the storage tank's wall. This principle is depicted in figs. 4 and 5.

Fig. 4 illustrates the stresses applied to a skin 1 and a core 2 of the insulation elements 7 installed vertically of the storage tank 8. When the wind pressure is q_w, the wind suction in the wind direction is qι and k = n -0,5...-0,7 and the wind suction perpendicularly to the wind direction is qι and k = n -1,7...-2,3. A force F, resulting from wind suction and acting on the sheet metal skin 1 of each insulation element 7, is calculable by means of a formula (1)

in which d is a storage tank's diameter.

A maximum pressure p_maχ acting on the core 2 of each insulation element 7 can be calculated by means of a formula (2)

in which coefficients ki and k₂ result from a non-linearity of the cylindrical surface and a magnitude of the coefficients is determined from trade literature. The wind suction force F has its effect depicted in fig. 5.

Depicted in fig. 3 is the principle that it is advisable to secure the screws in a sufficient density for providing a durable external shell made up by insulation elements 7. The insulation elements 7 are installed on an outer wall 5 of the storage tank 8 by bending this particular mineral wool element 7 substantially to the conformity with the curvilinear outer wall's 5 geometry in such a way that, of two opposite main surfaces of the two-layer sheet metal- mineral wool element 7, the one made up by bare mineral wool becomes placed against said curvilinear outer wall 5. As pointed out even above, the element 7 according to this example is particularly useful as insulation for the external jacket surface of such a cylindrical storage tank which has a radius of not less than 4 m. The installation placement of mineral wool elements 7 is performed by means of hoists. The hoists are provided with lifting elements which may comprise suction pads or mechanical grippers.

Claims

1. A mineral wool element (7), comprising an insulating mineral wool layer (2) with two opposite main surfaces, characterized in that one of the two opposite main surfaces of the mineral wool layer (2) is clad with a pliable sheet metal (1) and the other made up by bare mineral wool, the sheet- metal clad mineral wool layer being pliable jointly with the sheet metal.

2. A mineral wool element as set forth in claim 1, characterized in that the mineral wool layer (2) comprises a mineral wool slab, adhesive-bonded to the sheet metal (1), or a slab assembly consisting of lamellar sheets.

3. A mineral wool element as set forth in claim 1 or 2, characterized in that the mineral wool element (7) has at least two of its opposite ends provided with tongues and grooves (3, 4).

4. A mineral wool element (7) as set forth in any of claims 1-3, characterized in that the sheet metal (1) consists of a sheet metal which is rustproof or coated with an anti-corrosive covering.

5. A method for the fabrication of a mineral wool element (7) as set forth in any of claims 1-4, characterized in that

(a) one of the two main surfaces of a mineral wool layer (2) is clad with a pliable sheet metal (1) and the other is left unclad, the mineral wool layer of a thus obtained mineral wool element being pliable jointly with the sheet metal, or

(b) a conventionally fabricated, sheet-metal clad mineral wool element, in which at least both opposite main surfaces of the mineral wool layer (2) have been clad with a pliable sheet metal (1', 1"), is split in two relative to the element's thickness, resulting in two mineral wool elements (7), each having one of its two opposite main surfaces substantially made up by bare mineral wool (2) and the other by sheet metal (1), each sheet-metal clad mineral wool layer being pliable jointly with the sheet metal.

6. A method for insulating curvilinear surfaces with mineral wool (2) and providing the same with a cladding sheet metal (1) protecting the outside of mineral wool installed on a curvilinear surface, characterized in that on a curvilinear surface are installed one or more mineral wool elements (7) as set forth in any of claims 1-4, or mineral wool elements (7) fabricated according to the method of claim 5, by bending the mineral wool element in question substantially to the conformity with the curvilinear surface geometry in such a way that, of two opposite main surfaces of the mineral wool element, the one made up by bare mineral wool (2) becomes placed against said curvilinear surface to be insulated.

7. A method as set forth in claim 6, wherein the curvilinear surface to be insulated is a substantially cylindrical storage tank's jacket surface with a radius of not less than 4 m.

8. A method as set forth in claim 6 or I₁ characterized in that the mineral wool elements (7) are secured to each other with tongues and grooves (3, 4), present at least in a vertical direction thereof, and to the surface to be insulated with fastening elements (6).

9. A method as set forth in claim 8, characterized in that the fastening elements (6) are secured through the elements (7) at least across the tongue-and-groove joints (3, 4), such that the fastening element extends through both pairs of tongues and grooves in a tongue-and-groove joint.

10. A method as set forth in any of claims 6-9, characterized in that the installation placement of the mineral wool elements (7) is performed by means of hoists.

11. A wind-load resistant structure, comprising a curvilinear building surface, an insulation layer (2) of mineral wool installed thereon, and a sheet metal skin (1) protecting the outside of this insulation layer, wherein the curvilinear surface has installed thereon one or more mineral wool elements (7) as set forth in any of claims 1-4, or mineral wool elements (7) fabricated according to the method of claim 5, which has been brought by bending substantially to the conformity with a curvilinear surface geometry, and that, of two opposite main surfaces of the mineral wool element, the one made up by bare mineral wool (2) is placed against said curvilinear surface to be insulated, whereby the sheet metal skin (1) and the mineral wool layer (2) in attachment therewith function jointly as a composite structure, by virtue of which the membrane forces developed on the sheet metal skin (1) of a mineral wool element as a result of wind pressure and suction are passed into the mineral wool layer (2) having a sufficient compression strength, wherefrom the compression forces are passed further to a tank wall with uniform compression.

12. A structure as set forth in claim 11, wherein the curvilinear building surface is a cylindrical storage tank's outer wall and wherein the structure's mineral wool layer (2) has been selected to have a sufficient compression strength depending on a size of the storage tank's diameter, e.g. if the tank to be insulated has a diameter of 4 m or more, the mineral wool layer (2) must have its fibers at an orientation of 90° relative to the mineral wool layer's main surfaces.

13. A structure as set forth in claim 12, wherein the diameter of a storage tank to be insulated is 4 m or more, the orientation of fibers is 90° relative to the mineral wool layer's main surfaces, the mineral wool elements have vertical tongue-and-groove joints (3, 4) which are further secured by screws (6).