WO2019186351A1 - Heating film with positive temperature coefficient resistance and method for producing same - Google Patents

Abstract

The invention relates to a polymer heating film (1) with positive temperature coefficient (PTC) resistance, comprising an electrically conductive polymer layer with PTC resistance, characterised by the fact that the electrically conductive polymer layer with PTC resistance is an electrically conductive polymer layer with PTC resistance (2) comprising a thermoplastic polymer matrix in which conductive charges are distributed, the polymer heating film with PTC resistance (1) also comprising a first surface electrode (3) covering one of the faces of the electrically conductive polymer layer with PTC resistance (2) and a second surface electrode (4) covering the other, opposing, face of the electrically conductive polymer layer with PTC resistance (2). The invention also concerns a method for producing such a polymer heating film with PTC resistance (1).

Description

POLYMER HEATING FILM HAVING POSITIVE TEMPERATURE COEFFICIENT RESISTANCE AND METHOD OF MANUFACTURING THE SAME

The present invention relates to the field of heating films, and relates in particular to a positive temperature coefficient resistance heating film polymer, especially for the automotive field, and its manufacturing process.

In the case of motor vehicles with a thermal engine (diesel or gasoline), the heat engine provides the heating function in the passenger compartment of the vehicle for the comfort of the user, the amount of energy available to heat the passenger compartment being the order of 6 to 8 kW.

However, in the case of motor vehicles with electric motor, the energy available for the heating of the passenger compartment is only of the order of 1 to 2 kW. It is therefore necessary to provide thermal comfort by distributing heating elements in the passenger compartment of the motor vehicle with an electric motor, the heating elements being able, for example, to be arranged in the dashboard, the ceiling lamp and / or the interior doors.

In the field of heating surfaces, there are known flexible heating films consisting of wire-based resistive tracks made of metal alloy, etched resistive tracks or polymer tracks. These tracks are sandwiched between two electrical insulation films where the resistive wire travels a path on a frame. The resistive tracks or the electrical resistance of these tracks do not vary or very slightly as a function of temperature. In the case of the resistive wire, it is possible to have a variation of the electrical resistance with the temperature when the resistive wire is a polymer, but the heating is not continuous. In addition, these types of heating film operate in all or nothing and must be controlled by a thermostat-type device.

The disadvantages of these existing heating films are: the control of the heating film with a thermostat, the need to define the heating film upstream according to the need for heating, the oversizing of the heating film to predict the extreme conditions, the destruction of the heating film when it is trapped in a thick layer of thermal insulation, and a heating that follows the conductive tracks and not a continuous and homogeneous heating.

To distribute the heating in the passenger compartment of a motor vehicle, the existing solutions are heating wires or heating films with constant power. However, today there is no self-regulating flexible heating film or self limiting electric power, the self limitation meaning that the power dissipated is likely to vary positively or negatively depending on the need.

European Patent Application EP2127473A2 discloses a heating film comprising a positive temperature coefficient resistance sheet, CTP, in contact with wire electrodes. However, this PTC heating film does not make it possible to obtain a volume resistivity of the heating film so as to dissipate a homogeneous electrical power by the volume and does not allow localized self-regulation of the heating film.

The present invention aims to overcome the drawbacks of the prior art by proposing a positive temperature coefficient resistance heating film CTP, comprising a layer of electroconductive polymer with CTP resistance covered by two surface electrodes, which allows to obtain a homogeneous heating of the heating film by the volume and a localized regulation of the heating film as a function of the temperature.

The subject of the present invention is therefore a polymer film with a positive temperature coefficient resistance, CTP, comprising an electroconductive polymer layer with a CTP resistance, characterized in that the electroconductive polymer layer with CTP resistor is a layer of electroconductive polymer with resistance. CTP comprising a thermoplastic polymer matrix in which conductive fillers are distributed, the CTP polymer resistance heating film further comprising a first surface electrode covering all of one of the faces of the electroconductive polymer CTP layer and a second surface electrode covering all of the opposite side of the faces of the electroconductive polymer layer CTP resistance.

The conductive fillers distributed in the polymer layer allow the conduction of electricity.

The first and second surface electrodes may each cover all of one of the two faces of the polymer layer.

Thus, the electroconductive polymer layer of the heating film is thermally sensitive and has a variable electrical resistance as a function of temperature to make it a temperature sensor and a heating element having a locally variable power density depending on the temperature of the carrier or the atmosphere.

The "smart" heating film is suitable for automotive applications, the intelligence of the heating film coming from its ability to achieve localized heating to meet a thermal need.

The application of the heating film in the automotive field allows a distribution of thermal comfort in the passenger compartment of the motor vehicle in a simple, economical and efficient manner.

The resistivity of the heating film is volume, and the self-regulation of the heating film is localized, that is to say that the PTC-effect polymer layer has the possibility of locating the heating function on a surface.

The polymer heating film is self-regulating, dissipating electric power by volume and having the ability to modulate the power as a function of the temperature of the surface or the perceived radiation and this thanks to the polymeric plastic material.

The invention makes it possible to obtain a simple heating film whose structure based on electrically conductive polymer is sufficiently simple to allow the realization of it in large numbers and at low cost.

The equivalent electrical diagram of the polymer heating film is similar to an infinity of variable electrical resistances as a function of the temperature between the first and second electrodes.

When the heating film is placed on a support for heating the support, the film will heat up by applying a power density depending on the support.

The heating film can read the surface temperature of the support and adapt only the power to be dissipated to maintain the entire surface of the support at the same temperature. The power density on the surface is thus modulated according to the local thermal need. The power density will be greater on the cold areas of the surface of the support, and the power density will be lower on the surface portion of the warmer support.

The advantages of the PTC effect polymer heating film according to the invention are: a power density adapted to the support, a continuous heating on the surface of the support, a saving in energy consumption by the self-adaptation of the heating compared to the need thermal, lack of a control circuit with complex thermostat, a lack of monitoring circuit by self limitation of electric power, a lack of double, triple or quadruple heating circuit to increase or decrease the power density as a function of the zone to be heated, a mechanical flexibility, a solution that can for example be inserted in the dashboard structures of motor vehicles or in mirrors for frost protection functions, and a solution that can be sandwiched in composite structures.

Under 12V direct current, and by Joule effect, the thermosensitive conductive polymer layer having a variable electrical resistance will dissipate calories. The polymer of the PTC effect polymer layer is a specific polymer for safety extra low voltage (12V) applications or for low voltage (230V) applications.

The polymer of the thermoplastic polymer matrix is a thermoplastic polymer doped with fine electrically conductive particles. The polymer may be high density polyethylene, mixtures of high and low density polymers (polyethylene, high density polyethylene, low density polyethylene), polymer blends (polyethylene + polypropylene type), polyethylene associated with oligomers (type ethylene-vinyl acetate (EVA), ethylene-butyl acetate (EBA), ethylene-ethyl acrylate (EEA)), fluoropolymers (polyvinylidene fluoride (PVDF), ethylene tetrafluoroethylene (ETFE), perfluoroalkoxy (PFA)), thermoplastic elastomers, polyesters.

The particles can be carbon black, carbon nanoparticles.

According to a particular characteristic of the invention, the conductive fillers are at least one of carbon black particles, carbon nanotubes and metal particles.

Thus, the conductive fillers allow the conduction of electricity in the volume of the polymer layer to heat the latter.

According to one particular characteristic of the invention, the PTC-resistant electroconductive polymer layer further comprises, distributed in the thermoplastic polymer matrix, at least one of thermal stabilizing additives, antioxidant additives, electrical conduction and thermal conduction enhancement additives.

The main additives are antioxidant additives whose role is to protect the polymer against oxidation.

The thermal stabilizing additives are substantially identical to the antioxidant additives.

The antioxidant additives are at least one of polyphenolics and organic phosphites.

The electrical and thermal conduction enhancement additives are, for example, zinc oxides.

According to one particular characteristic of the invention, the PTC-resistant electroconductive polymer layer has a thickness of between 10 μm and 1.5 mm, preferably between 100 μm and 300 μm.

Thus, the very thin heating film can easily be inserted into different elements of the passenger compartment of a motor vehicle such as the dashboard, the ceiling lamp or the interior of the doors.

According to a particular characteristic of the invention, each of the first electrode and the second electrode is made of copper, of copper alloy, of aluminum, of aluminum alloy, of silver, of silver alloy, of nickel, of nickel alloy or electroconductive carbon fiber.

The conductive electrodes may have a thickness of a few hundred Ångström to a few tens of microns. Preferably, the conductive electrodes may have a thickness between 1 and 100 microns, or even between 1 and 10 microns.

According to a particular characteristic of the invention, the PTC resistance polymer heating film further comprises at least one electrical insulation layer disposed on at least one of the first electrode and the second electrode.

Thus, the at least one layer of electrical insulation can electrically isolate the heating film.

Preferably, a first electrical insulation layer is disposed on the first electrode and a second electrical insulation layer is disposed on the second electrode.

According to a particular characteristic of the invention, the electroconductive polymer layer CTP resistance is perforated so as to have an electrically resistive geometry.

According to a particular characteristic of the invention, the PTC resistance polymer heating film is flexible.

Thus, the heating film is similar to a textile and is very flexible.

The present invention furthermore relates to a process for manufacturing a PTC resistance polymer heating film as described above, characterized in that said process comprises the steps of hot mixing the thermoplastic polymer matrix in phase. melting, the conductive fillers and, if appropriate, the additives so as to form the PTC-resistant electroconductive polymer layer, disposing the first surface electrode on all of one of the faces of the PTC-resistance electroconductive polymer layer; and arranging the second surface electrode over the entire opposite side of the faces of the PTC resistor electroconductive polymer layer.

Thus, the hot implementation makes it possible to have a perfect cohesion between the polymer matrix and the two metal electrodes, that is to say a good ohmic and thermal contact between the polymer and the electrodes.

According to a particular characteristic of the invention, the electroconductive polymer layer CTP resistance is shaped by extrusion, extrusion calendering, compression or thermoforming.

Each of the aforementioned methods provides a controlled thickness of the polymer layer of the heating film.

According to a particular feature of the invention, said method further comprises the step of inserting metal elements at least partially into the electroconductive polymer layer CTP resistance during its shaping, said metal elements allowing the arrangement of the first and second electrodes on the PTC resistor electroconductive polymer layer.

• dépôts métalliques : dépôts PVD (dépôt physique en phase vapeur) ou CVD (dépôt chimique en phase vapeur) de différent métaux ; et/ou
• impression d’encre conductrice électrique chargée de particules ou de nanoparticules conductrices organiques ou métalliques.

Different printing or depositing techniques can be used to make the electrodes:

• metal deposits: PVD (Physical Vapor Deposition) or CVD (Chemical Vapor Deposition) deposits of different metals; and or
• printing electrically conductive ink charged with organic or metal conductive particles or nanoparticles.

The metal elements are preferably copper, aluminum, silver, nickel or metal alloy.

To better illustrate the object of the present invention will be described below, by way of illustration and not limited to two preferred embodiments, with reference to the accompanying drawings.

On these drawings:

is a perspective view of a PTC resistance polymer heating film according to a first embodiment of the invention; and

is a perspective view of a PTC resistance polymer heating film according to a second embodiment of the invention.

With reference to FIG. 1, it can be seen that there is shown a PTC resistance polymer film 1 according to a first embodiment of the invention.

The PTC resistance polymer film 1 comprises an electroconductive polymer layer CTP 2, a first surface electrode 3 covering one of the faces of the PTC 2 electroconductive polymer layer and a second surface electrode 4 covering the other opposed faces of the electroconductive polymer layer CTP 2 resistance.

The CTP 2 electroconductive polymer layer comprises a thermoplastic polymer matrix in which conductive fillers are distributed in order to allow conduction of electricity.

The electroconductive polymer layer 2 of the heating film 1 is thus heat-sensitive and has a variable electrical resistance as a function of temperature.

The resistivity of the CTP-resistance polymer layer 2 of the heating film 1 is volumetric, and the self-regulation of the heating film 1 is localized, that is to say that the polymer layer 2 has the possibility of locating the function. heating on a surface.

The polymer heating film 1 is self-regulating, dissipating electric power by volume and having the ability to modulate the power as a function of the temperature of the surface or the perceived radiation and this thanks to the polymeric plastic material.

When the heating film 1 is placed on a support for heating this support, the heating film 1 will heat up by applying a power density as a function of the temperature of the support.

The heating film 1 can read the surface temperature of the support and adapt only the power to be dissipated to maintain the entire surface of the support at the same temperature. The power density on the surface is thus modulated according to the local thermal need.

The heating film 1 may for example be inserted into the dashboard structures of motor vehicles or mirrors for anti-freeze functions.

Under 12V direct current, and by Joule effect, the polymer layer 2 having a variable electrical resistance will dissipate calories.

The polymer of the polymer layer 2 is a thermoplastic polymer doped with electrically conductive particles.

The conductive fillers distributed in the PTC 2 resistance polymer layer are at least one of carbon black particles, carbon nanotubes, and metal particles.

The CTP 2 electroconductive polymer layer may also comprise, distributed in the thermoplastic polymer matrix, at least one of thermal stabilizing additives, antioxidant additives, electrical conduction enhancement additives and enhancement additives. thermal conduction.

The main additives are antioxidant additives whose role is to protect the polymer against oxidation.

The thermal stabilizing additives are substantially identical to the antioxidant additives.

The antioxidant additives are at least one of polyphenolics and organic phosphites.

The electrical and thermal conduction enhancement additives are, for example, zinc oxides.

The electroconductive polymer layer CTP 2 has a thickness of between 10 microns and 1.5 mm, preferably between 100 microns and 300 microns. The very thin heating film 1 can thus easily be inserted into different elements of the passenger compartment of a motor vehicle such as the dashboard, the ceiling lamp or the interior of the doors.

Each of the first electrode 3 and the second electrode 4 is made of copper, copper alloy, aluminum, aluminum alloy or electroconductive carbon fibers.

It should be noted that the CTP 2 electroconductive polymer layer could also be perforated so as to have an electrically resistive geometry, without departing from the scope of the present invention.

The polymer resistance film CTP 1 is flexible and is similar to a textile.

The present invention also relates to a method of manufacturing the CTP 1 polymer resistance heating film, said method comprising the steps of: hot mixing the thermoplastic polymer matrix in the melting phase, the conductive fillers and, if appropriate, the additives of in order to form the CTP 2 electroconductive polymer layer, to arrange the first surface electrode 3 on one side of the CTP 2 electroconductive polymer layer, and to arrange the second surface electrode 4 on the opposite side faces of the electroconductive polymer layer with CTP resistance 2.

The PTC 2 electroconductive polymer layer is shaped by extrusion, calender extrusion, compression or thermoforming, thereby obtaining a controlled thickness of the polymer layer 2 of the heating film 1.

The manufacturing method could also include a step of inserting metal elements at least partially in the electroconductive polymer layer CTP resistance 2 during its shaping, said metal elements allowing the arrangement of the first and second electrodes 3, 4 on the electroconductive polymer layer with CTP resistance 2.

Referring to Figure 2, it can be seen that there is shown a PTC resistance polymer film 5 according to a second embodiment of the invention.

The elements common to the first embodiment of the invention in FIG. 1 and this second embodiment of the invention bear the same reference numeral, and will not be described in greater detail here when they are of identical structures. .

The PTC resistance polymer film 5 according to the second embodiment is identical to the PTC resistance polymer film 1 according to the first embodiment, except that the heating film 5 further comprises a first layer of electrical insulation 6 disposed on the first surface electrode 3 and a second electrical insulation layer 7 disposed on the second surface electrode 4, the first and second electrical insulation layers 6 and 7 for electrically isolating the heating film 5 vis- to the outside.

Claims (11)

CTP (1; 5) positive-temperature coefficient polymer heating film comprising an electroconductive polymer layer having a CTP resistance, characterized in that the CTP-resistant electroconductive polymer layer is a PTC-resistant electroconductive polymer layer ( 2) comprising a thermoplastic polymer matrix in which conductive fillers are distributed, the PTC resistance polymer heating film (1; 5) further comprising a first surface electrode (3) covering all of one of the faces of the layer of a PTC resistor electroconductive polymer (2) and a second surface electrode (4) covering the whole of the other opposite side of the PTC resistor electroconductive polymer layer (2). - PTC resistance polymer film (1; 5) according to claim 1, characterized in that the conductive fillers are at least one of carbon black particles, carbon nanotubes and metal particles. PTC-resistance polymer heating film (1; 5) according to claim 1 or 2, characterized in that the PTC-resistance electroconductive polymer layer (2) further comprises, distributed in the thermoplastic polymer matrix, at least one element among thermal stabilizing additives, antioxidant additives, electrical conduction enhancement additives and thermal conduction enhancement additives. - PTC resistance polymer film (1; 5) according to one of claims 1 to 3, characterized in that the electroconductive polymer layer CTP resistance (2) has a thickness of between 10 microns and 1.5 mm preferably between 100 μm and 300 μm. - PTC resistance polymer film (1; 5) according to one of claims 1 to 4, characterized in that each of the first electrode (3) and the second electrode (4) is copper, alloy of copper, aluminum, aluminum alloy, silver, silver alloy, nickel, nickel alloy or electroconductive carbon fiber. - PTC resistance polymer heating film (5) according to one of claims 1 to 5, characterized in that it further comprises at least one electrical insulation layer (6, 7) disposed on at least one of the first electrode (3) and the second electrode (4). - PTC resistance polymer film (1; 5) according to one of claims 1 to 6, characterized in that the PTC resistance electroconductive polymer layer (2) is perforated so as to have an electrically resistive geometry. - PTC resistance polymer heating film (1; 5) according to one of claims 1 to 7, characterized in that the PTC resistor heating film (1; 5) is flexible. - A method of manufacturing a polymer film CTP resistance resistor (1; 5) according to one of claims 1 to 8, characterized in that said method comprises the steps of hot mixing the thermoplastic polymer matrix in phase melting, the conductive fillers and, where appropriate, the additives so as to form the PTC-resistance electroconductive polymer layer (2), disposing the first surface electrode (3) on all of one of the faces of the layer of electroconductive polymer with CTP resistor (2), and arranging the second surface electrode (3) over the entire opposite side of the faces of the PTC resistor electroconductive polymer layer (2). - Method according to claim 9, characterized in that the CTP-resistant electroconductive polymer layer (2) is shaped by extrusion, calender extrusion, compression or thermoforming. - Method according to claim 9 or 10, characterized in that said method further comprises the step of inserting metal elements at least partially in the electroconductive polymer layer CTP resistance (2) during its shaping, said metal members for disposing the first (3) and second (4) electrodes on the PTC resistor electroconductive polymer layer (2).

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