WO1998011319A1

WO1998011319A1 - Thermoinsulating composite section

Info

Publication number: WO1998011319A1
Application number: PCT/IT1997/000223
Authority: WO
Inventors: Giacomo Ezio Mazzer; Valerio Pessina
Original assignee: Mazzer Materie Plastiche Di Mazzer Giacomo Ezio & C. S.N.C.
Priority date: 1996-09-13
Filing date: 1997-09-12
Publication date: 1998-03-19
Also published as: AU4396697A; IT240881Y1; ITMI960609U1; ITMI960609V0

Abstract

The composite metal section (1) is of the type including two metal sections (2) and (3) connected to each other by means of crosspieces (7) made of a plastic insulating material which together with the metal sections (2, 3) form a chamber (5) intended to be filled with a foamed plastic material and it comprises a shaped elongated portion (11) made of a thermoexpansible material placed in the chamber (5) defined by the two metal sections (2, 3) and the two crosspieces (7) of plastic insulating material and extending lenghtwise the chamber (5), said shaped elongated portion (11) made of thermoexpansible material being compelled to expand by the action of heat received during the treatment of the composite metal section (1) in a furnace.

Description

Thermoinsulatinq composite section

Technical Field

The present invention generally relates to metal sections of the type used for manufacturing windows, doors and the like and, more particularly, to metal sections of this kind featuring great heat insulating characteristics.

Background Art

It is known that special composite sections generally are used for manufacturing windows, doors and the like made of metal material, particularly aluminium. These special composite sections comprise a metal external section which forms the outwardly facing portion of the window, door or the like, and a metal internal section which forms the inwardly facing portion of the window, door or the like.

These pair of metal sections are mechanically connected to each other by means of a plastic section which features little thermal conductivity so as to interrupt the flow of heat that otherwise would occur if conventionl metal materials are used.

Several methods already exist for interrupting the thermal bridge between two metal sections.

A first method consists in using an insert made of a plastic insulating material that is fastened between the two metal sections by means of suitable adhesives.

A second method consists in using a rubber hose segment in which vacuum is made and which is placed in a chamber formed at the juntion of the two metal sections.

A third method consists in using two crosspieces made of plastic insulating material which transversely connect the two metal sections and interrupt the thermal bridge. The internal sides of the metal sections and of the crosspieces of plastic insulating material define a chamber which extends lengthwise of the composite metal section and has a cross-section substantially rectangular in shape. The chamber can be filled with plastic heat-insulating material, particularly a foamed material, so as to enhance the insulating power of the composite metal section.

A fourth method also uses similar crosspieces made of plastic insulating material which are inserted in suitable seats provided in opposite positions on the two metal sections. In this case also, the crosspieces of plastic insulating material form a chamber and are provided with upper and lower foot shaped portions which form connecting means intended to cooperate with the above mentioned seats provided on the metal sections. According to this method, the crosspieces of plastic insulating material provide for a mechanical connection between the two metal sections. In order to further increase the insulating power of this connection, the chamber enclosed between the pair of crosspieces of plastic insulating material and the pair of metal sections is generally filled with a foamed material that fully fills the chamber and, in the case of a foamed material having adhesive characteristics, contributes to connect together the two metal sections.

According to a fifth method, a hollow section made of a heat-insulating material and closed at one end is placed in the chamber defined by the two crosspieces of plastic insulating material and the two metal sections and is resting with its external sides on the internal sides, of the metal sections and the insulating crosspieces, and in the hollow portion of which vacuum is made so as to avoid heat transmission by convection. One of the metal sections is provided with an another chamber which is placed at the location of the seats intended to receive the foot shaped portions of crosspieces of plastic insulating material and contributes to thermal insulation. All these methods are used for interrupting the thermal bridge between the two metal sections so as to prevent condensation of air moisture and thermal losses and contribute to the mechanical fastening of the metal sections. Generally, the thermoinsulating composite metal sections which are used for manufacturing doors, windows and the like, also require anodizing or painting operation and a following drying in a furnace. These operations cause disadvantages, particularly if a foamed insulating material has to be injected in the chamber defined by the crosspieces of plastic insulating material and the two metal sections, so that the insulating material is injected in the chamber after the heat treatment of the metal sections in the furnace. As a result, the above mentioned methods have disadvantages both from the point of the expansion of the insulating material used and of the mechanical fastening of the two metal sections.

Disclosure of Invention

The present invention is directed at obviating the above disadvantages by providing an improved thermoinsulating composite metal section which permits convection of heat to be eliminated and greatly reduces the power of the metal section to transmit heat.

More particularly, the composite metal section according to the present invention is of the type including two metal sections connected to each other by means of crosspieces made of a plastic insulating material which together with the metal sections form a chamber intended to be filled with a foamed plastic material and is characterized in that it comprises a shaped elongated portion made of a thermo expansible material placed in the chamber defined by the two metal sections and the two crosspieces of plastic insulating material and extending lenghtwise the chamber, said shaped elongated portion made of thermoexpansible material being compelled to expand by the action of heat received during the treatment of the composite metal section in a furnace.

According to a feature of the present invention, the shaped elongated portion made of a thermoexpansible material is provided with connecting means intended to cooperate with mating connecting means provided on at least one of the crosspieces of plastic insulating material.

According to another feature of the present invention, the shaped elongated portion made of thermoexpansible material is integral with the crosspieces of plastic insulating material . According to still another feature of the present invention, at the location of the crosspieces of plastic insulating material that connect the two metal sections, one of the metal sections is provided with a chamber also intended to receive the elongated and variously shaped portion of thermoexpansible material.

According to a further feature the crosspieces of plastic insulating material are provided with foot shaped portions which include little grooves adapted to receive a thread of a glueing material intended to attach the foot shaped portions to the corresponding seats.

The invention will be now described more in detail in connection with the accompanying drawings, wherein:

Figure 1A is a cross sectional view of the connection portion between an external metal section and an internal metal section which together form the thermoinsulating composite metal section according to the present invention; Figure IB is a cross sectional view of the external metal section according to a different type;

Figure 2 is a cross sectional view of the detail of the connection portion between the two metal sections wherein grooves are provided in the foot shaped portions of the crosspieces for connecting them to the metal sections with a thread of glue;

Figure 3 is a view similar to Figure 2 showing the elongated portion made of thermoexpansible material having a circular cross-section in shape; Figure 4 is a view similar to Figure 2 showing the elongated portion made of thermoexpansible material having and angled cross-section in shape;

Figure 5 is a cross sectional view of the detail of Figure 2 wherein the elongated portion of thermoexpansible material is shaped so as to provide connecting means for the connection to one of the crosspieces of plastic insulating material prior to the expansion phase;

Figure 6 is a view similar to Figure 5 wherein the elongated portion of thermoexpansible material is shown after the expansion phase. As can be seen in Figure 1A, the composite metal section according to the present invention, generally indicated with 1, is particularly intended to be used for manufacturing doors, windows and the like made of a metal material. It is formed of an external metal section 2 and an internal metal section 3. The external metal section 2 is provided with a portion 4 which forms a chamber 5. On the upper wall of the chamber 5 and on the lower wall of the external metal section 2 joint grooves, herein shown with a dovetail shape 6, are formed, and each of which is intended to receive a crosspiece of plastic insulating material 7 with upper and lower foot shaped portions 8 which have a shape that mates the grooves 6. The crosspieces are inserted in said grooves in order to produce the mechanical connection between the metal sections 2 and 3. Thus, since the crosspieces are made of an insulating material, the heat flow between the metal sections 2 and 3 is interrupted. As can be seen, a chamber 9 is formed between the pair of crosspieces of plastic insulating material and the pair of metal sections 2 and 3.

In Figure 2 a method for fastening the foot shaped portions 8 of the crosspieces 7 into the grooves 6 of the two metal sections is shown. For this purpose, the foot shaped portions 8 of the crosspieces of plastic insulating material are provided with channels 10 each of which is intended to receive a thread of glueing material which is activated by heat and softens and strongly glues the crosspieces 7 of plastic insulating material to their grooves 6 when the composite metal section undergoes the common treatment in a furnace, thus forming a strong mechanical connection. Furthermore, the foot shaped portions 8 of the crosspieces 7 may have any suitable shape and composition for the purpose of correctly fastening the crosspieces 7 to the relevant seats in the metal sections 2 and 3.

According to the invention, in order to enhance the thermoinsulating power of the composite metal section 1, a string 11 made of thermoexpansible material is provided. This string of thermoexpansible material is inserted in the chamber 9 defined by the two crosspieces 7 of plastic insulating material and the two metal sections 2, 3. The string 11 can have a circular cross section as shown in Figure 3, or an angled cross section as shown in Figure 4, and is inserted in the chamber 9 so as to extend along all the length of said chamber. Preferably, as shown in Figure 5, the string of thermoexpansible material 11 is provided with a connecting projection 12, having herein a dovetail shape, and one of the crosspieces 7 made of plastic insulating material is provided with mating retaining means 14 so as to permit it to be put on the market already equipped with the string 11 of thermoexpansible material and thus to have the string 11 already arranged in the chamber 9 when the two crosspieces 7 are assembled. The shape of the strings of thermoexpansible material are given solely for explanatory purposes, since they may also have any other shape because the shape is sized according to the space to be filled and knowing the expanding capabilities along the three directions in the space of the material forming the thermoexpansible string.

Figure 5 shows the string 11 of thermoexpansible material in a non expanded condition. When the composite metal section 1 undergoes a heating treatment in a furnace, the string 11 of thermoexpansible material expands in the chamber 9 and fills it all as shown in Figure 6. This enhances the insulating power of the composite metal section 1 because the convection of heat is eliminated.

Preferably, the two metal sections 2, 3 are provided with recesses 13 in opposite positions so as to let the expanded plastic material to penetrate the recesses, thus giving more strength to the connection between the metal sections. The recesses can be more than one and have several shapes and extend along all the internal surface of the metal sections 2, 3 for the purpose of fastening the expanded material.

According to another feature of the invention, also the power of heat transmission of the internal metal section 3, for example, is greatly reduced. For this purpose, as already explained, this metal section is provided with a chamber 5 intended to receive a string of thermoexpansible material which is inserted therein so as to expand during the heating treatment of the composite metal section and fill all the chamber. If the metal section 2 is designed with a suitable chamber, as shown in Figure IB, a string 11 of thermoexpansible material can be provided therein. In principle, all the empty chambers of the metal sections can be filled in order to enhance the heat insulation effect. Therefore, it can be seen that the thermoinsulating composite metal section 1 used for manufacturing windows, doors and the like has the following advantages: a) the expansible insulating material is inserted in the chamber defined by the crosspieces of plastic insulating material and the metal sections prior to the heating treatment of the composite metal section and, therefore, afterwards it is not necessary to inject in the chamber the expansible insulating material because the heat of the furnace causes the expansion of the expansible material; this permits a final product both painted and entirely heat insulated in only one working step to be obtained; b) it is possible to extremely reduce the power of heat transmission of the metal section by also inserting a string of thermoexpansible material in the chamber formed in the metal section which expands under the heating treatment; c) the insertion of the string of thermoexpandable material in chamber can be avoided by providing fastening means for said string both on the crosspieces of plastic insulating material and on a wing of the chamber provided on the metal section.

Claims

1. Composite metal section of the type including two metal sections connected to each other by means of crosspieces made of a plastic insulating material which together with the metal sections form a chamber intended to be filled with a foamed plastic material, characterized in that it comprises a shaped elongated portion made of a thermoexpansible material placed in the chamber defined by the two metal sections and the two crosspieces of plastic insulating material and extending lenghtwise the chamber, said shaped elongated portion made of thermoexpansible material being compelled to expand by the action of heat received during the treatment of the composite metal section in a furnace.

2. Composite metal section according to claim 1, characterized in that the shaped elongated portion made of a thermoexpansible material is provided with connecting means intended to cooperate with mating connecting means provided on at least one of the crosspieces of plastic insulating material .

3. Composite metal section according to claim 1, characterized in that the shaped elongated portion made of thermoexpansible material is integral with the crosspieces of plastic insulating material.

4. Composite metal section according to claim 1, characterized in that at the location of the crosspieces of plastic insulating material that connect the two metal sections, one of the metal sections is provided with a chamber also intended to receive the elongated and variously shaped portion of thermoexpansible material.

5. Composite metal section according to claim 1 to 4, characterized in that at the location of the crosspieces of plastic insulating material that connect the two metal sections, the other metal section also is provided with a chamber also intended to receive the elongated and variously shaped portion of thermoexpansible material.

6. Composite metal section according to claims 1 to 4, characterized in that the shaped elongated portion of thermoexpansible material is placed in the other chambers provided in the metal sections.

7. Composite metal section according to one of the precedings claims, characterized in that the crosspieces of plastic insulating material are provided with foot shaped portions having small grooves adapted to receive a thread of glueing material intended to secure the foot shaped portions to the corresponding seats.

8. Composite metal section according to claim 7, characterized in that the foot shaped portion of the crosspieces of plastic insulating material have a shape and composition suitable to be correctly fastened to the corresponding seats of the metal sections when they are combined in all the manners and ways with shaped portions of thermoexpansible material having any shape and restrain.