NO20130645A1 - Heat film with three-phase power supply - Google Patents

Abstract

The invention comprises a heating film (1) having an electrical connection with three-phase power supply. The foil (1) is characterized in that at least part of the circuit feeds (P1-P3 P'2, P'3) extend parallel to at least one of the sides of the heating foil (1), in which equipment (7-9, 11-19) is adapted to avoid overlapping of at least one circuit supply via a coupling extending from another circuit (P2, P3, P'2, P'3) each supplying its respective resistive element, (2a-2c, 3a-3c, 4a -4c, 5a-5c). The invention can be used in the field of heating.

Description

The invention applies, on a general basis, to a heating foil with a three-phase power supply.

More specifically, the invention is a heating foil with a three-phase power supply, where the supply is largely in two dimensions and where the thickness of the foil is not affected.

Such a foil is thin and can cover a given surface. It can be incorporated into various elements, for example walls, ceilings or floors in premises. It can also be used in various means of transport, including trains, boats, planes and cars, for example electric or hybrid cars.

Typically, such a heating foil will have a conducting metal conductor laid flat between two foils of synthetic or composite material, where each end is tied together by a cable lug with an electrical current supply. The supply to the foil is usually supplied in one phase.

When using three-phase, it is necessary to use a heating foil for one current phase, i.e. three foils, which is unfortunate in terms of cost and space requirements. The different power supplies will overlap and thus increase the thickness of the heating foil.

The aim of the invention is for the supply to the heating foil to be transported via an electrical connection with a three-phase power supply so that the aforementioned does not take up too much space, as is the case if the foil becomes thicker.

The invention has a soft heating foil with at least one electrical insulation and at least one block that has at least one resistive element. It also has an electrical connection with a three-phase supply that has at least one power supply circuit for each phase. At least one electrical connection which supplies a resistive element and which runs from each power supply circuit, characterized in that at least one part of the power supply circuit extends parallel along at least one of the sides of the heating foil. This is arranged so that overlapping of at least one power supply circuit is avoided by means of a connection that goes from another circuit and which supplies one respective resistive element.

In addition, the invention has:

- equipment that prevents overlapping of at least one power supply circuit provided by a connection from a secondary circuit via a current inverter in the given power supply circuit. This given circuit is fed through by this link which reduces or cancels the thickness locally of said circuit.

- the foil has at least three heating blocks, each of which has a resistive element.

- the power supply to each block is made by a respective phase.

- the connection has three power supply circuits, each with its own phase. The innermost circuit in the heating foil in the connection, hereafter called circuit, supplies the resistive element in the first block in its respective phase. This first circuit is pierced by a current inverter at the resistive element current supply level on block number two. This is to ensure the connection passage to a second circuit (the innermost of the electrical connections, after the first circuit) and supplies the resistive element in block number two in its respective phase. The third connection in the outermost electrical connection in the heating foil supplies the resistive element in the third block in its respective phase. The first and second circuits each have a current inverter at the current supply to the resistive element in the third block to ensure the passage of the link that goes from the third circuit towards the associated resistive element.

- the three phases supply each of the blocks.

- each block has three resistive elements and the electrical connection has four power supply circuits. That is, a power supply circuit which is not part of the power supply in its first respective phase and which supplies a first resistive element in the first block, then a first resistive element in the subsequent blocks via an additional power supply circuit inside the foil and which goes into the blocks. The first power supply circuit which is innermost in the foil supplies a secondary resistive element in the first block, and a secondary power supply circuit which supplies, in its respective phase, the third resistive element in the first block. The first power supply circuit is provided with a switch at the level of the supply of the third resistive element of the first block, to enable the passage via the first circuit of the link that goes from the secondary power supply circuit. This secondary circuit extends into the supply of a secondary resistive element, the supply of which to the secondary resistive element passes through a switch in the first circuit. A third power supply circuit which in its respective phase supplies the third resistive element of block two wherein the first and second power supply circuits are each provided with respective switches at the level of the supply to the third resistive element of block two, to enable the passage of the link which passes from the third power supply circuit through these. The third circuit extends into the connection to supply the second resistive element in the third block, the connection of which to the second resistive element is through a switch from the first and second circuits. A fourth power supply circuit supplies the third resistive element in the third block in its respective phase. The first, second and third circuits in the connection are each provided with their respective switches at the level of the supply to the third resistive element in block three, to enable the passage of the link passing from the fourth power supply circuit through them.

- the electrical power supply, in three phase is either balanced or unbalanced.

- the electrical power supply is made according to a star or a delta connection-

- the foil's insulation is made of polyester.

- at least one resistive element is in aluminum or other conductive alloys.

- the foil is covered with an adhesive layer, so that it can be glued to all types of surfaces.

The invention will now be described in more detail, without thereby being limiting with respect to the attached illustrations. - illustration 1, is a schematic representation of a three-phase branch with balanced star connection, and which has one block per phase. - illustration 2, is a schematic representation of a three-phase branch with balanced star connection, and which has a block for the three phases. - illustration 3, is a greatly enlarged schematic representation of another type of similar invention, with power supply of three-phase heating foil.

Illustrations 1 and 2 show a heating foil 1, composed of at least one electrical insulation, of at least one resistive element, respectively, 2a, 2b, 2c and 3a, 4a, 5a, 3b, 4b, 5b, 3c, 4c and 5c and an electrical connection 6, supplied by a three-phase having at least one power supply circuit to each phase.

Until now, the electrical power supply to the heating foil 1 has been in single-phase current, that is to say that two power supply lines were sufficient. In a three-phase supply, shown in illustration 1, there are three power supply circuits Pl, P2 and P3. In illustration 2, there are five power supply circuits Pl, P2 and P'2, P3 and P'3.

Illustrations 1 and 2 show the heating foil made of three blocks, respectively Bl, B2, B3 and Cl, C2 and C3. Illustration 1 shows an embodiment of a branched three-phase in balanced star form with a block having a three-phase supply.

In order to get a better overview of the current supply circuits of the electrical connection 6, the circuits and connections to the respective resistive elements are drawn in bold. This as long as these circuits are not broken.

The circuits P1, P2 P3, P'2 and P13 show the respective connections to a resistive element 2a, 2b, 2c or 3a to 3c, 4a to 4c and 5a to 5c which lie perpendicularly along the electrical connection 6 and flow through these more or less deep, according as the conductive circuit in the connection is more or less at a distance in relation to the heating foil 1, that is to say more or less inside or outside in relation to the foil.

The resistive element is preferably designed with at least one soft electrical resistance in a conductive material covered by a plastic film.

The conductive material is aluminum and the covering plastic material is a polyester foil.

Illustrations 1 and 2 are now described separately.

In illustration 1, the electrical connection 6 is equipped with three circuits Pl, P2 and P3 which provide electrical current supply to the electrical phase, respectively phases 1,2 and 3, but these are not limiting. The three circuits P1, P2 and P3 extend in parallel along the electrical connection 6 on one side of the heating foil. Circuit Pl will preferably be the innermost, and circuit P3 the outermost in this connection 6 in relation to the foil 1.

As the heating foil 1, in illustration 1, consists of three blocks, Bl, B2 and B3, each of which consists of one resistive element, 2a, 2b and 2c, with one phase per block, block Bl will be connected to circuit Pl, block B2 connected to circuit P2, and block B3 will be connected to circuit P3.

The aim of the invention is to make the electrical connection 6 as thin as possible by preferably having it in two dimensions.

The power supply circuits P1, P2 and P3 extend in parallel next to each other along at least one of the sides of the heating foil, as has already been mentioned, and the equipment 7, 8 and 9 are used to avoid overlapping of at least one of the power supply circuits. Pl, then Pl and P2 with a link that goes from another circuit, (illustration 1) where circuit P2 goes to circuit Pl, and further circuit P3 will go to circuits P2 and Pl. This second circuit P2 or P3 supplies each resistive element, 2b or 2c, respectively.

The power supply to the heating foil 1 is three-phase and does not exceed the thickness of the heating foil 1. This is made possible by the arrangement of the power supply circuits Pl, P2 and P3, which are not above each other but next to each other. The use of equipment which enables the passage from a given power supply circuit to a resistive element via one or more circuits which are closer to the resistive element than said power supply circuit also helps to make this possible. In this way, overlapping of one or more power supply circuits which are placed on the road towards the resistive element is avoided, because the connections extend parallel to the aforementioned power supply circuits.

The equipment which prevents an overlapping of the connections and the power supply circuits is in the form of a current inverter 7, 8 and 9 in at least one power supply circuit. In illustration 1, circuit P1 is in block B2, further circuits P1 and P2 are in block B3. These current converters are in the form of through-holes 7, 8 and 9 which reduce or cancel the thickness locally of the aforementioned electrical connection, but this is not mandatory. It is not necessary that the piercing goes right through the electrical connection to the heating foil 1, only that it locally reduces the thickness of said connection to ensure the passage of the connection or connections.

An example of such a connection with different circuits Pl, P2 and P3 will now be described in more detail with reference to illustration 1.

In illustration 1, circuit P1 is stopped after the power supply from the resistive element 2b from block B2. There is an advantageous current inverter 7, in circuit P1 which enables the passage from the power supply circuit to the resistive element 2b from block B2 which goes from circuit P2.

Circuit P2 is broken after the supply from the resistive element 2b from the second block B2. As regards the supply to the resistive element 2c from block B3, two through-holes 8 and 9 respectively are preferably carried out in the circuits P1 and P2. This enables the passage between the connection from the circuit P3 to the resistive element 2c from block B3, the circuits Pl and P2 are thus interrupted by little or no thickness in the passage of said connection which goes from circuit P3 through circuits Pl and P2.

Illustration 2 is detailed below. Illustration 2 deals with a three-phase power supply in each of the blocks Cl, C2 or C3.

What has previously been said regarding the execution of illustration 1 applies

also for illustration 2. This means that at least part of the power supply circuits P2, P3, P'2 and P'3 extend in parallel along at least one of the sides of the heating foil 1. The equipment 11 to 19 is intended to be used to avoid overlapping of at least one of the power supply circuits via a link that goes from another circuit P2, P3 or P'2 and each of which supplies its

respective resistive element.

Broadly speaking, the connection in illustration 2 will be equipped with five circuits Pl, P2 and P'2, P3 and P'3 to enable a three-phase power supply of the three resistive elements, 3a, 4a and 5a in block Cl, the three resistive elements 3b, 4b and 5b in block C2, and the three resistive elements 3c, 4c and 5c in block C3.

Circuit Pl is a power supply circuit because it does not lie along the electrical connection 6, and stops after the connection to the power supply of its restive element 3a, connected to the first block Cl.

The electrical connection 6 has four circuits P2 and P'2 and P3 and P'3 which extend parallel along the electrical connection 6 on one side of the heating foil, preferably along this. From the innermost circuit P2, to the heating foil 1, and to the outermost circuit P'3, their alternation in the circuits in the electrical connection 6 of illustration 2, are P2, P3 and P'3. Circuits P2 and P'2 refer to phase 2, and circuits P3 and P'3 refer to phase 3.

The circuits P2 and P'2, respectively P3 and P'3 in the second and third phases are double, while the first phase has a single circuit P1.

In the case of block B1, it is circuit P1 in the first phase which supplies the first resistive element 3a in block C1. Circuit Pl goes no further than its connection to the resistive element 3a.

Because the power supply in phase 1 must also be possible for block C2 and C3 after block Cl, an additional power supply circuit 10 is envisaged, which extends inside the heating foil 1. It goes partly around block Cl, then partly around block C2, except around the side that has the electrical connection 6. This additional power supply circuit 10, inside the foil, connects the extremity of the resistive element 3a in block C2, which is supplied by circuit Pl in the extremity of the resistive element 3b in block C2. They supply in phase 1, and then the extremity of the resistive element 3b in block C2 in the extremity of the resistive element 3c in block C3 which is also supplied in phase 1. In this way, a resistive element 3a, 3b and 3c which respectively belong block Cl, C2 and C3 will be supplied in phase 1.

With regard to the other two resistive elements, 4a and 5a in block Cl, they are supplied in phase 2 via circuit P2 and in phase 3 by circuit P3. The power supply in circuit P2 is then interrupted, while circuit P3 which supplies in phase 3 is extended without a current inverter to supply block C2.

In order for the connection in circuit P3 to be maintained to its resistive element 5a to which it belongs, the part of circuit P2 which is not flowed through by phase 2 will be equipped with a current inverter 11, preferably a piercing which is partly from circuit P3 and which makes it impossible to supply current through this .

For the second block C2 of the heating foil 1, this also has three resistive elements, 3b, 4b and 5b. The first resistive element 3b is electrically supplied in phase 1 by the additional power supply circuit 10 which is inside the foil and which extends between block Cl and C2.

The second resistive element 4b is electrically supplied in phase 3 of circuit P3 by the electrical connection 6, a connection from this P3 circuit to the resistive element 4b and passes through the interrupted P2 circuit, and which has been pierced by a current inverter 12.

The current passage in circuit P3 is then interrupted in the electrical connection 6, this circuit is equipped with a current inverter in the electrical connection 6. This circuit is equipped with a current inverter 13 in the electrical connection part 6, adjacent to block C2 to ensure the power supply of the resistive element 5b in block C2 from phase 2. This via a current connection that goes from circuit two P'2 and which supplies in phase 2. Circuit P2 is also equipped with a current inverter 14 to ensure passage to the connection that goes from circuit P' 2. The third circuit P'2 in the electrical connection 6 thus supplies the third resistive element 5b.

The third block C3 in the heating foil 1 also has three resistive elements, 3c, 4c and 5c. The first resistive element 3c receives its power supply in phase 1 of the additional power supply circuit 10, inside the heating foil 1. It extends between block Cl, and then between blocks C2 and C3.

The second resistive element 4c receives its current supply in phase 2 from circuit P'2 in the electrical connection 6. The connection in circuit P'2 to the second resistive element 4c goes through circuits P2 and P3, interrupted as previously mentioned and which is locally equipped with a current inverter each 16 and 15 to enable the passage in the aforementioned link from circuit P'2 towards block C3.

Circuit P'2 is then interrupted in the electrical connection 6 in that it is equipped with a current inverter 18, in the electrical connection part 6, adjacent to block C3. This is so that the current supply to block C3 in phase 3 by means of the fourth circuit P'3 is supplied in phase 3. The fourth circuit P'3 in phase 3 supplies the third resistive element 5c by its connection which passes circuit P'2, as well as the circuits P2 and P3 which are also equipped with current inverters, respectively 19 and 17.

Illustration 3 shows a three-phase power supply of a heating foil 1. In this illustration, the main electrical connection to the heating foil 1 is on the upper right part of the panel field. The various electrical connections Pel, Pc2 and Pc3 in the invention which have this main connection, and which are attributed to each of their resistive elements lie parallel to each other and supply their respective circuits, Pl, P2 and P3.

In order to avoid overlapping of the respective circuits, P1, P2 and P3, equipment is envisaged which includes respective connections in each circuit P1, P2 and P3 as well as a specific device for the said circuits to avoid this overlapping.

In illustration 3, it is seen that the circles P1, P2 and P3 are drawn with an excessive distance and that the ratio between their lengths is also greatly enlarged.

In the embodiment of the invention in illustration 3, certain changes can be made to avoid overlapping of the circuits P1, P2 and P3. These changes may imply a different arrangement in phase one, or in the relationship between the phases. The first part of circuit P3 extends over a longer part of the heating foil 1 than the first part of circuit P2. The first part of circuit P2 also extends over a longer part of the heating foil 1 than the first part of circuit Pl.

At the end of the first part of a circuit P1, P2 or P3, this first part will be connected to a part two of the respective circuit. Pl, P2 or P3 extend in the opposite direction of the first part to rest on the part of the heating foil 1 that has the main electrical connection of the heating foil 1. The connection between each first and second part that is connected is made with a respective connection, 21, 22 and 23.

Sequentially, going from the end of the heating foil which has the main electrical connection and where the various parts of circuits Pl, P2 and P3 extend in parallel and descend towards the middle part of the heating foil 1, the disposition of the circuits Pl, P2 and P3 has on illustration 3, the first part of circuit P3, the first part of circuit P2 and the first part of circuit Pl. Then this first part of circuit Pl will be followed by the secondary part of the same mentioned circuit Pl, and then by the secondary part of circuit P2 and the secondary part of circuit P3. This is to avoid overlapping of one or more circuits Pl, P2 and P3.

Due to the different lengths of the first part of the circuits P1, P2 and P3, there will be no overlap with the aforementioned circuits P1, P2 and P3. It is also achieved by the way part two of circuit P1, P2 and P3 are placed in relation to each other. The secondary part of circuit Pl is placed right after the first part of circuit Pl and connected to it at connection 21. Because the first part of circuit Pl is the shortest of the first parts of circuit Pl, P2 and P3, there is no overlap of circuit P2 or P3 from the secondary part of circuit Pl.

The same applies to the secondary part of circuit P2, which does not overlap circuit P3 because it is led towards the main connection to heating foil 1.

Like the first parts, the secondary parts (which have different lengths) will extend in the same direction as the heating foil's 1 main connection. The secondary part of circuit P1 extends more along the right side of the heating foil than the secondary part of circuit P2, which in turn extends more towards the right side of the heating foil than circuit P3.

These secondary parts are respectively connected to the tertiary parts corresponding to circuits P1, P2 or P3, with each having its respective connection 31, 32 and 33.

The same applies to the subsequent parts of circuits Pl, P2 and P3. The overlapping of at least one circuit P1, P2 or P3 by at least one other circuit P1, P2 or P3 is thus avoided for all parts of said circuits P1, P2 and P3.

In illustration 3, only the first three parts of circuit P1, P2 and P3 are represented in their entirety. The fourth parts are only partially represented. The remaining parts of circuit P1, P2 and P3 are not represented.

The advantages of this invention are, in addition to guaranteeing a three-phase power supply in a heating foil with an electrical connection that does not exceed the thickness of the foil, that you save wires compared to three single-phase foils. Furthermore, it will also be space-saving with one internal center point, as well as the option of having either a three-phase in one block or three phases per block.

The invention is not limited to the descriptions or illustrations shown here, and are only intended as examples.

Claims (12)

1. Foil (1) which is soft and heat-generating, made of at least one current insulation, of at least one block (Bl to B3, Cl to C3) and which has at least one resistive element (2a to 2c, 3a to 3c, 4a to 4c , and 5a to 5c). It also has an electrical connection (6) provided with a three-phase which has at least one circuit supply (Pl to P3 and P'2 and Pl3) for each phase. At least one current link supplying a resistive element (2a to 2c, 3a to 3c, 4a to 4c and 5a to 5c) running from each circuit supply (Pl to P3 and P'l to P'3), characterized in that at least part of the circuit feeds (Pl to P3 and P'2 and P'3) extend in parallel along at least one of the sides of the heating foil (1). Equipment (7 to 9 and 11 to 19) is arranged so as to avoid overlapping of at least one circuit supply via a connection that goes from another circuit (P2, P3, P'2 or P'3) which supplies each of its respective resistive elements , (2a to 2c, 3a to 3c, 4a to 4c and 5a to 5c). 2. Soft heating foil (1) according to previous patent claims, characterized in that the equipment (7 to 9 and 11 to 19) which avoids overlapping of at least one circuit supply is triggered by a connection that goes from a secondary circuit and which consists of at least one switch in a given circuit supply. This given circuit supply which in turn is passed through the coupling, the switch (7 to 9 and 11 to 19) is reduced or canceled, if nothing else then locally the said circuit thickness. 3. Soft heating foil (1) according to any one of the preceding patent claims, characterized in that it has at least three blocks (Bl to B3 and Cl to C3) which are heat-generating, and each of which has a resistive element (2a to 2c, 3a to 3c, 4a to 4c and 5a to 5c). 4. Soft heating foil (1) according to the preceding patent claim, characterized in that the supply to each block (Bl to B3 and Cl to C3) is led through each respective phase. 5. Soft heating foil (1) according to the preceding patent claim, characterized in that the connection (6) has three supply courses (Pl to P3) which each belong to its respective phase. The innermost circuit (Pl) to the heating foil connection (6), hereafter called the first circuit, supplies the resistive element (2a) in the first block (Bl) in its respective phase. This innermost circuit (Pl) is equipped with a switch (7) at the level of the supply to the resistive element (2b) in the second block (B2) to enable the connection to circuit two (P2), which is the innermost in the connection ( 6). After this first circuit (Pl) and by supplying the resistive element (2b) in block two (B2) in its respective phase, the third circuit (P3) in the connection (6) which is the outermost in the heating foil (1), supply the resistive element (2c) in the third block (B3). In their respective phases, the first and the secondary circuits (Pl and P2) will each be equipped with their respective switches (8 and 9) at the level of the supply of the resistive element (2c) in the third block (B3) against the corresponding resistive element (2c). 6. Soft heating foil (1) according to the patent claim, characterized in that the three phases supply each block (Cl to C3). 7. Soft heating foil (1) according to the preceding patent claim, characterized in that each block (Cl to C3) has three resistive elements (3a to 3c, 4a to 4c and 5a to 5c) and the electrical connection (6) has four circuits (P2) , P3, P'2 and P'3, a circuit supply (Pl) which is not connected to the connection (6) and which supplies in its respective phase a first resistive element (3a) in the first block (Cl), then a first resistive element (4a and 5a) in block (C2 and C3) and which is followed by a reserve circuit supply (10) which is located inside the foil and which passes inside the blocks (Cl, C2 and C3). The first circuit (P2 ) to the electrical connection (6), and which is the innermost part of the foil (1) supplies a secondary resistive element (3b) in the first block (Cl), and a secondary circuit (P3) in the connection (6), which again in its respective phase, the third resistive element (3c) in the first block (Cl) supplies The first circuit (P2) in the connection (6) is equipped with a switch (11) at the level of f the orsewing at the third resistive element (3c) in the first block (Cl) to enable the passage through the first circuit (P2) in the link that goes from the secondary circuit (P3) in the connection (6). This secondary circuit (P3) extends into the connection (6) to supply a secondary resistive element (4b) in block two (C2). This connection to the secondary resistive element (4b) (12). The first and the second circuits (P2 and P3) in the connection (6) are each equipped with their respective switches (13 and 14) at the level of the supply of the third resistive element (4c) in block two (C2) for the passage of the connection which goes from the third circuit (P'2) in the connection (6) through them. This third circuit (P'2) extends into the connection (6) to supply a secondary resistive element (5b) in block three (C3). This third block (C3) is connected to the secondary resistive element (5b) passing through a switch (16, 15), the first circuit (P2), and the secondary circuit (P3). A fourth circuit (P'3) in the connection supplies the third resistive element (5c) in block three (C3) in its respective phase. The first (P2), second (P3) and third (P'2) circuits in the connection (6) are each equipped with their respective switches (17, 18 and 19) at the level of the supply to the third resistive element (5c) in block three (C3), to enable the passage from the coupling that goes from the fourth circuit (P13) in the connection (6) through them. 8. Soft heating foil (1), according to any of the preceding patent claims, characterized in that the three-phase power supply is balanced or unbalanced. 9. Soft heating foil (1), according to any of the preceding patent claims, characterized in that the power supply takes place by either a star or delta connection. 10. Soft heating foil (1), according to any of the preceding patent claims, characterized in that the insulation material of the foil is polyester. 11. Soft heating foil (1), according to any of the preceding patent claims, characterized in that at least one of the resistive elements (2a to 2c, 3a to 3c, 4a to 4c and 5a to 5c) is made of aluminum or of a every other conductive alloy. 12. Soft heating foil (1), according to any of the preceding patent claims, characterized in that the foil is coated with an adhesive layer, so that it can be glued to all types of surfaces.