The invention relates to a sensor device comprising for instance, a temperature probe.
Sensor device with surface-mountable temperature sensors are knows, for example, from the publications U.S. Pat. No. 6,588,931 B2 and U.S. Pat. No. 6,431,750 B1.
The problem of the invention is to specify a sensor device that comprises a space-saving probe head.
This problem is solved by a sensor device according to Claim 1. Advantages configurations of the invention follow from the additional claims.
The invention specifies a sensor device with a flexible first film, the first surface of which comprises structured conductive traces (electrical lead wires). The conductive traces are electrically connected to a probe that is arranged lying on the first surface of the first film and is mounted there. Lying as used here means that one of the largest surfaces of the probe flatly contacts the first film. The probe preferably has surface-mountable external contacts, each of which is permanently connected, preferably soldered, to a conductive trace or a connection surface contacting this conductive trace and arranged on the surface of the first film.
A flexible second film that surrounds the probe conformally from above and tightly seals it to the first surface of the first film is arranged on the upper side of the first film. Thus the sensor is encapsulated in the empty space formed between the first film and the second film and is protected from environmental influences such as moisture and contamination. The invention has the advantage that is possible to forgo an additional housing of the probe head formed in this manner.
The probe can consist, for instance, of a PTC or NTC ceramic (PTC=positive temperature coefficient; NTC=negative temperature coefficient). The probe preferably constitutes a flat surface-mountable component with a low height and SMD contacts (SMD=surface mounted device). The probe can also be a wired component or a component with a crimpable contact. The height of the probe is preferably less than 1 mm and can, for instance, be 100 μm. The SMD contacts of the probe are preferably arranged on its underside turned toward the first film.
The conductive traces are formed in a structured metal layer. A metal such as copper with good thermal conductivity is particularly suitable for this.
The first and/or second film can be, e.g., polyimide films, polyester imide films (PEI) films or other flexible dielectric films. It is advantageous to select the first and second film from the same material.
The first as well as the second film preferably comprise several sublayers, which together form a flexible layer composite. At least one of the sublayers is dielectric. The connection of the first and second film is advantageously an adhesive layer, which can be contained in the composite of the second layer as the lowest sublayer, for instance. One of the preferably outer, sublayers of the first or second film can be electrically conductive and have a shielding effect against electromagnetic fields. The electromagnetic shielding of the probe and the conductive traces leading to it is of particular advantage in high-frequency applications of the sensor device, since the metallic components of the sensor device act as an antenna and, when integrated into an HF device, can capture undesired HF interface.
In one variant, the first film comprises a dielectric sublayer which is tightly connected to the structured metal layer by means of an adhesive layer, wherein the composite of the metal layer, the adhesive layer and the dielectric sublayer is flexible.
The adhesive layer, preferably viscous at room temperature, is applied between the dielectric sublayer and the surface of the first film and then cured at a high temperature, for instance, 200° C., remaining flexible even after curing.
The thickness of the first and second film, respectively, can be, for example, 25-50 μm.
In one variant, the sensor device can constitute a compact, flexible sensor component. It is also possible to integrate the sensor in an additional device such as an air conditioner.
The invention will be described in detail below on the basis of embodiments and the associated figures. The figures show various embodiments of the invention on the basis of schematic representations not drawn to scale. Identical or identically functioning parts are labeled with the same reference numbers. Schematically and in parts,
First film 1 comprises a dielectric layer, for instance, sublayer 11 in
Second film 4 comprises a dielectric layer such as a sublayer 41 in
In
In the variant shown in
The plan view onto the sensor device shown in
Although it was only possible to describe the invention on the basis of a few embodiments, it is not limited thereto. The elements of different embodiments can be arbitrarily combined with one another. Basically, any suitable materials or material composites as well as arbitrary layer thickness of individual sublayers of the overall structure can be used.
Number | Date | Country | Kind |
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1020040477256 | Sep 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE05/01726 | 9/28/2005 | WO | 6/29/2007 |