DE102008011304B4 - Temperature measurement unit - Google Patents

Abstract

Temperature measuring unit (11) for determining a sunlight-compensated temperature in the interior (25) of a motor vehicle, comprising a temperature sensor (17), a light sensor (19) and a plurality of metallic conductor tracks (13a, 13b, 13c) for electrically contacting the temperature sensor (17) and the light sensor (19), wherein the temperature sensor (17), the light sensor (19) and parts of the conductor tracks (13a, 13b, 13c) are enclosed by a common housing (23) which is at least in a region between a light entry surface (27 ) of the housing and the light sensor (19) is transparent, wherein the temperature measuring unit (11) is formed within the housing (23) to suppress the light sensor (19) impinging light reflections (37), characterized in that at least one of the conductor tracks ( 13a, 13c) has an end face (15a, 15c) which is arranged adjacent to the light entry surface (27) of the housing (23), this end face (15a, 15 c) is adapted to absorb into the housing (23) entering light (35).

Description

The invention relates to a temperature measuring unit for determining a sunlight-compensated temperature in the interior of a motor vehicle. Such a temperature unit is needed to control or regulate an air conditioning system of the vehicle depending on the temperature. For this purpose, the temperature measuring unit is arranged in the vehicle interior, for example in the area of an instrument panel. In addition to the determination of a temperature measured value, the intensity and the angle of incidence of the sunlight entering the vehicle interior are to be taken into account in order to be able to compensate for a falsification of the temperature measured value as a result of the sunlight. Namely, a direct exposure to sunlight causes heating of the surface of the temperature measuring unit and its environment, so that the determined temperature reading does not represent the temperature of the air in the interior of the vehicle, but is higher than the actual air temperature.

For this purpose, the temperature measuring unit has a temperature sensor, for example an NTC resistance element. Furthermore, the temperature measuring unit has a light sensor, for example a photodiode. In addition, the temperature measuring unit has a plurality of metallic conductor tracks for electrically contacting the temperature sensor and the light sensor, so that the respective signals of the temperature sensor and the light sensor can be supplied to an associated evaluation device. The temperature sensor, the light sensor and parts of the conductor tracks are usually enclosed by a common housing to form a preassemblable unit, wherein the necessary electrical connections can be formed via the protruding from the housing parts of the conductor tracks. The housing has a light entry surface, which forms the interface with the interior of the vehicle. At least between this light entry surface of the housing and the light sensor, the housing is translucent to allow the desired detection of sunlight. The housing may have a separate light entrance window for this purpose. Typically, however, the housing is molded integrally from a transparent plastic, i. H. the temperature sensor, the light sensor and the projecting into the housing parts of the conductor tracks are embedded in the housing and are in surface contact with the housing.

Such a temperature measuring unit is from the DE 103 12 077 B3 the contents of which are incorporated in the disclosure of the present application.

A difficulty in connection with the detection and consideration of the sunlight incidence is that the same cosine dependence should be represented by means of the light sensor, which is based on the parasitic heating of the temperature sensor as a result of exposure to sunlight. In other words, the signal of the light sensor should have the same dependency on the light incidence angle as that portion of the signal of the temperature sensor, which is due to the additional heating of the temperature measuring unit due to the exposure to sunlight. For this it is from the DE 103 12 077 B3 It is known to provide the front-side outer surface of the housing adjacent to the vehicle interior with a certain curvature, wherein an inner region should have a comparatively large radius of curvature and an outer region a comparatively small radius of curvature. While such an embodiment of the housing already gives good results, it has been shown that the desired agreement between the dependence of the signal of the light sensor on the angle of light incidence and the thermal angle dependence is not yet achieved in all relevant cases.

Other temperature measuring units are from the documents DE 100 49 979 A1 . DE 20 2004 002427 U1 and EP 1 457 365 A2 known.

It is an object of the invention to provide a temperature measuring unit, which allows a more accurate determination of the temperature in the interior of a motor vehicle and in particular allows an improved consideration of the angular characteristics of the sunlight.

This object is achieved in each case by a temperature measuring unit having the features of the independent claims, wherein the temperature measuring unit within the housing is designed to suppress the light sensor impinging light reflections.

In the temperature measuring unit according to the invention, such reflections of the incident light which occur within the housing and which would lead to an indirect exposure to light of the light entrance surface of the light sensor, are specifically avoided. Such light reflections are possible for example due to the metallic design of the tracks and due to the light-reflecting properties of the side surfaces of the commonly used temperature sensor. The suppression of such light reflections is effected in particular by absorption or by deflecting light which passes through the light entry surface of the housing into the interior of the housing and in this case not directly Light sensor acted upon, or by a suitable choice of the arrangement of the various components of the temperature measuring unit within the housing relative to the light entry surface of the housing.

The invention is based on the knowledge that light reflections can occur on components of the temperature measuring unit which are arranged within the housing, which light reflections can reach the light sensor and thus distort its signal. In particular, sunlight, which passes through the light entry surface of the housing into the housing interior and is reflected there by components of the temperature measuring unit, reach the light entry surface of the light sensor by total reflection on the inside of the housing outer surfaces. Such effects can be observed, for example, when the sunlight entering the housing interior is reflected at parts of the conductor tracks or a carrier device carrying the conductor tracks, or at the temperature sensor. According to the invention, a suppression of these light reflections. This can happen, in particular, in that the sunlight reaching into the interior of the housing is partially or completely absorbed, insofar as the light sensor is not directly applied to it. The sunlight reaching into the interior of the housing can also be deflected in a targeted manner in order to prevent indirect exposure of the light sensor. For example, the sunlight is deflected so that it leaves the housing again or that it is absorbed at another location within the housing. Thus, different individual measures are possible within the scope of the invention, which are each already effective on their own, depending on the specific geometric conditions of the temperature measuring unit, or which are particularly effective in combination with one another.

Thus, it is avoided that the light sensor receives in addition to the direct exposure to sunlight, which passes through the light entrance surface of the housing directly to the light sensor and causes the generation of a useful signal, Störlichtanteile resulting from the reflection of sunlight inside the housing. This avoids that the useful signal dese light sensor is falsified by said Störlichtanteile. Namely, such light reflections or stray light components can have a dependence on the light incidence angle, which deviates considerably from the cosine dependence of the useful signal. The temperature measuring unit according to the invention thus enables a particularly accurate and reproducible sunlight compensation of the temperature measured value.

If reference is made in the context of the invention to "light", this is to be understood as meaning visible and / or infrared light, corresponding to the typical spectral sensitivity of the commonly used light sensors.

According to an advantageous embodiment, the end of at least one of the conductor tracks projecting into the housing has an end face which is designed to absorb light entering the housing. In order to avoid unwanted light reflections on this end face, this end face is at least partially light-absorbing with respect to the light entering the housing. This prevents that the reaching over the light entry surface of the housing into the housing interior light is reflected at the relevant conductor end face and thus passes indirectly to the light sensor. In addition, other areas of the relevant conductor track or additional conductor end faces may be formed correspondingly light-absorbing.

In particular, the relevant conductor end face may be provided with a light-absorbing layer, for example with a light-absorbing paint or a light-absorbing resin.

According to a further advantageous embodiment, at least one of the plurality of conductor tracks, which project into the housing of the temperature measuring unit, has an end side which is arranged adjacent to the light entry surface of the housing. The surface normal of this end face or a portion of this end face extends obliquely to the surface normal of the light entry surface of the housing. In this context, the respective surface normal should be based on the center of the light entry surface of the housing or of the respective front side section, if the light entry surface or the front side section is not planed but is, for example, arched.

Due to the oblique course of said surface normal relative to one another, it is achieved that the conductor end face or the respective end face section reflects the light entering the housing in an oblique direction such that exposure of the light sensor to the reflected light is avoided. Preferably, a reflection is provided to the side, directed away from the light sensor. In particular, the relevant end face or the end face section can be oriented obliquely in such a way that the light which strikes the end face or the face side section through the light entry surface of the housing is guided out of the housing again while avoiding total reflection. Alternatively it can be provided that the light, which passes through the light entry surface of the housing on the respective end face or the end face portion, in a region of the temperature measuring unit is deflected, in which the light is ultimately absorbed, especially after multiple reflection.

In order to achieve such an effect of a deflection, it is preferred if the respective end face or the end side section extends obliquely with respect to the light entry surface of the housing, d. H. is inclined. Alternatively or additionally, the respective front side or the end side section may extend obliquely with respect to the light entry surface of the light sensor.

According to a further advantageous embodiment, the temperature sensor of the temperature measuring unit is adapted to absorb at least a portion of the light which passes through the light entrance surface of the housing to the temperature sensor, or to reflect with respect to a surface normal through the center of the light entrance surface of the housing in an oblique direction , By these measures it is prevented that the sunlight, which does not reach directly to the light sensor but the temperature sensor is applied, is guided in an indirect way to the light sensor and there causes unwanted noise signal components.

For example, it can be provided that the temperature sensor is at least partially provided with a light-absorbing layer, in particular on one of the light entry surface of the housing facing end side. For this purpose, for example, a light-absorbing paint or a light-absorbing resin may be provided.

In order to guide away the light acting on the temperature sensor from the light sensor, it is preferred if an end face of the temperature sensor, which is arranged adjacent to the light entry surface of the housing and facing it substantially, has a surface normal, which extends obliquely to the surface normal of the light entry surface of the housing , Also in this context, the respective surface normal should be based on the center of the light entry surface of the housing or the front side of the temperature sensor, if the light entrance surface or the end face is not planed but curved, for example.

In order to deflect the light acting on the temperature sensor away from the light sensor, it is advantageous if the temperature sensor is arranged obliquely with respect to the light entry surface of the housing and / or with respect to the light entry surface of the light sensor, d. H. is aligned inclined.

According to a further advantageous embodiment, it is provided that the light sensor is seated on an associated contact surface of one of the plurality of conductor tracks, the end of at least one other of the plurality of conductor tracks projecting into the housing being offset back relative to this support surface for the light sensor, ie from the light entry surface of the light guide Housing is further spaced than said support surface. As a result, light reflections are not directly absorbed or obliquely deflected at the relevant strip conductor and in particular at its end face. However, such a retreating of the relevant track can already cause the light reflected on the track to no longer reach the light sensor or only to a negligibly small extent, for example because the light reflections are then outside the angular range which is decisive for a total reflection. Thus, a falsification of the signal of the light sensor is also avoided by this simple measure.

According to a particularly simple further development, the relevant (recessed) conductor track projects into the housing less deeply in the direction of the light entry surface of the housing than the conductor track on which the light sensor is arranged. In other words, this conductor track is deliberately designed to be shorter than the conductor track carrying the light sensor.

In principle, it is possible that the said interconnects are cantilevered, d. H. the interconnects are not necessarily mechanically connected to each other by a common carrier device. In particular, the conductor tracks may be formed by a leadframe arrangement (so-called leadframe construction), in which the conductor tracks are typically formed flat and extend substantially within a common plane of extent.

Alternatively, however, it is possible that a common carrier device is provided for the conductor tracks, for example a rigid or flexible board or printed circuit board. The interconnects are formed in this case, in particular as metallizations.

In the case of such a construction with a carrier device, it may be designed to be light-absorbing, at least in regions, on an end face which faces the light entry surface of the housing, in particular by providing the end face in question with a light-absorbing layer. As a result, as explained above for the end faces of the interconnects, it is prevented that light reflections caused on the fore-side of the carrier device reach the light sensor and cause unwanted interference signal components there.

Alternatively or additionally, an end face of said support means associated with the light entry surface of the housing and this is substantially facing, or a portion of such an end face have a surface normal, which extends obliquely to the surface normal of the light entry surface of the housing (possibly in turn based on the respective center of the end face portion and the light entry surface). In this way, it can be achieved that light reflections occurring at the relevant end face are deflected to the side and thus no longer reach the light sensor. In particular, the respective front side or the end side section is aligned obliquely with respect to the light entry surface of the housing and / or with respect to the light entry surface of the light sensor.

The invention will now be described by way of example only with reference to the drawings.

1 shows a known temperature measuring unit in a schematic cross-sectional view.

2 to 9 show various embodiments of a temperature measuring unit in a respective schematic cross-sectional view.

1 shows a known temperature measuring unit 11 , This has three tracks 13a . 13b . 13c , A temperature sensor 17 For example, an NTC resistor element is on the tracks 13a and 13b arranged for electrical contacting of the temperature sensor 17 serve. At one end 15b the middle conductor track 13b is a light sensor 19 arranged, which is formed for example by a photodiode and a light entrance surface 21 has. The temperature sensor 17 , the light sensor 19 and parts of the tracks 13a . 13b . 13c are in a housing 23 cast from translucent synthetic resin. The one vehicle interior 25 facing frontal outer surface of the housing 23 forms a light entrance surface 27 ,

The temperature measuring unit 11 is on a front panel 29 attached to an air conditioner controller, not shown here, the front panel 29 the housing 23 the temperature measuring unit 11 encloses circumferentially. The three tracks 13a . 13b . 13c are with one opposite the front panel 29 reset motherboard 31 coupled and thereby with an evaluation 33 electrically connected. This evaluation device 33 may be connected to an electronic control unit, not shown here, of said air conditioning control unit or be part of this control unit.

In the 1 shown temperature measuring unit 11 serves to provide a sunlight-compensated temperature reading for the vehicle interior 25 to investigate. For this purpose, by means of the temperature sensor 17 a temperature reading is determined, which is substantially the air temperature in the vehicle interior 25 corresponds because the temperature sensor 17 over the housing 23 thermally conductive with the vehicle interior 25 is coupled. The signal of the temperature sensor 17 is from the evaluation device 33 over the tracks 13a and 13b detected.

However, if the front panel 29 and in particular the housing 23 the temperature measuring unit 11 Direct sunlight is applied to the vehicle interior 25 incident, this causes a surface warming of the front panel 29 and the housing 23 , This determines the temperature sensor 17 ultimately a higher temperature than the actual air temperature in the vehicle interior 25 equivalent. In order to be able to compensate the temperature measured value accordingly, by means of the light sensor 19 therefore the sunlight incidence is detected. Depending on the angle of incidence of the sunlight relative to a surface normal N of the light entry surface 27 and depending on the intensity of the incident sunlight, the light sensor generates 19 a signal substantially showing a cosine dependence on the angle of incidence. This signal is from the evaluation device 33 over the two tracks 13b and 13c read out, with the light sensor 19 via a bonding wire (in 1 for better clarity not shown) with the trace 13c connected is. Based on this additional signal compensates the evaluation 33 by means of the temperature sensor 17 determined temperature reading.

A problem with this signal detection and evaluation, however, is that the inside of the housing 23 existing interfaces inevitably cause light reflections, resulting in an indirect exposure of the light sensor 19 and thus to a distortion of the signal of the light sensor 19 being able to lead. In particular, undesired deviations from the aforementioned cosine dependence of the signal of the light sensor can thereby result 19 result so that the explained compensation of the sunlight can not be performed with the desired accuracy. Exemplary is in 1 an incident light beam 35 shown inside the case 23 initially on the front side 15c the conductor track 13c is reflected. The reflected light beam 37 passes through total reflection on the inside of the light entry surface 27 of the housing 23 finally to the light entry surface 21 of the light sensor 19 and causes there a corresponding signal increase.

To avoid such signal distortions such light reflections are within the housing 23 avoided, which without additional countermeasures ultimately the light sensor 19 would reach. This will be explained below with reference to 2 to 9 explained for various embodiments. Similar elements as in 1 are shown accordingly and / or identified by the same reference numerals.

2 shows an embodiment in which the end face 15a the conductor track 13a and the front side 15c the conductor track 13c each completely with a light-absorbing layer 41 are provided. This layer 41 may be formed by any material that is suitable or customary in the context of the manufacture of semiconductor devices, as long as this material has light-absorbing properties (for example so-called glob top).

Because those end faces 15a . 15c the tracks 13a . 13c with the light absorbing layer 41 are covered, which is the light entry surface 27 of the housing 23 are facing, are related to 1 explained light reflections and the related distortions of the signals of the light sensor 19 avoided.

To the 2 It should also be noted that the light-absorbing layer 41 also the bonding wire 43 which is usually provided to the relevant track 13c with the light sensor 19 electrically conductive to connect. Furthermore, it may be sufficient if only one end face 15a or 15c with the light absorbing layer 41 is provided, and / or if the end faces 15a . 15c only partially with the light-absorbing layer 41 are provided. Also, those areas can be the front side 15b the middle conductor track 13b which the light sensor 19 laterally surrounded, also with such a light-absorbing layer 41 be provided.

3 shows a similar embodiment as in 2 , Here is the front of the usually rectangular temperature sensor 17 that the light entry surface 27 of the housing 23 associated with a light absorbing layer 41 provided (eg opaque synthetic resin, black color). This avoids that through the light entry surface 27 in the case 23 incident sunlight on the relevant side surface of the temperature sensor 27 is reflected and ultimately to the light entry surface 21 of the light sensor 19 arrives. Of course, this embodiment with the embodiment according to 2 be combined.

4 shows an embodiment in which the end face 15a the conductor track 13a , which of the light entry surface 27 of the housing 23 assigned and substantially facing, has an inclined course. The surface normal N 'of this end face 15a thus runs obliquely - ie at an angle between 0 ° and 90 ° - to the surface normal N of the light entrance surface 27 of the housing 23 , As in the embodiment shown here, the light entry surface 27 is designed essentially plan, this means that the relevant end face 15a obliquely to the light entry surface 27 runs. This will be the vehicle interior 25 over the light entry surface 27 in the case 23 incident sunlight at the relevant end face 15a reflected to the side, so that the reflected light is no longer to the light sensor 19 arrives.

Out 4 also shows that one of the light entry surface 27 of the housing 23 facing conductor front side and only partially sections may have the described oblique course. This is in 4 for the conductor track 13c shown. Their front page 15c has two inclined surface sections 45 , The respective surface normal N 'of these inclined surface sections 45 runs obliquely to the surface normal N of the light entry surface 27 of the housing 23 ,

A similar advantageous effect can also be achieved if that end face 47 of the temperature sensor 17 that the light entry surface 27 of the housing 23 assigned and substantially facing, with respect to the light entry surface 27 of the housing 23 slants. This is in 5 shown. In other words, in this embodiment, the temperature sensor 17 arranged tilted. The surface normal N 'of the relevant end face 27 thus runs obliquely to the surface normal N of the light entry surface 27 of the housing 23 (relative to the center of the light entry surface 27 ). If that through the light entry surface 27 in the case 23 incident sunlight on the respective front side 47 of the temperature sensor 17 falls, the light is deflected to the side. This largely avoids that of the temperature sensor 17 reflected light on the light sensor 19 meets and there causes an unwanted signal corruption.

6 shows an embodiment of a temperature measuring unit 11 , in the light reflections on the front sides 15a and 15c the two outer tracks 13a and 13c Although not specifically absorbed and not deflected to the side. However, the front side forms 15b the middle conductor track 13b here a support surface 49 for the light sensor 19 , and with respect to this bearing surface 49 are the ones with the bonding wire 43 provided front side 15c and the other front side 15a the tracks 13c and 13a opposite the light entry surface 27 of the housing 23 moved back. Alone by this simple measure can already be achieved that the angular characteristic of the light reflections, at the end faces 15a and 15c through the through the light entry surface 27 in the case 23 reaching sunlight, is no longer sufficient to total reflection on the inside of the light entry surface 27 of the housing 23 a significant parasitic light incident on the light sensor 19 to effect. Thus, this embodiment can be particularly easy to realize manufacturing technology, since the two outer conductor tracks 13a and 13c only shorter than the form the light sensor 19 carrying middle conductor track 13b , With regard to the usual structure (cf. 1 ), it is only necessary, the bonding wire 43 to do a little longer.

7 illustrates that various of the above measures to suppress housing-internal light reflections that the light sensor 19 could be combined with each other. In the example shown here are the end faces 15a and 15c the two outer tracks 13a and 13c with a light absorbing layer 41 provided, and the temperature sensor 17 is with respect to the light entrance surface 27 of the housing 23 or with respect to the light entry surface 21 of the light sensor 19 arranged in an oblique orientation.

In the embodiments explained above, the conductor tracks have 13a . 13b and 13c a conductor strip structure and are cantilevered, ie the tracks 13a . 13b and 13c the temperature measuring unit 11 are alone through the case 23 fixed together. Alternatively, the tracks 13a . 13b and 13c be formed on a common support means, such as a rigid or flexible circuit board, which also includes the temperature sensor 17 and the light sensor 19 wearing.

This is in 8th shown. The tracks 13a . 13b and 13c are formed here by metallizations on a common carrier board 51 are formed. Part of the carrier board 51 is from the case 23 surrounded by a positive fit. Also in such an embodiment of the temperature measuring unit 11 can the explained problem of housing internal light reflections occur, which ultimately the light sensor 19 apply and cause signal distortions there. Such unwanted light reflections can in particular by that end face 53 the carrier board 51 caused the light entry surface 27 of the translucent housing 23 is facing. According to the invention, such light reflections are the light sensor 19 suppressed. At the in 8th embodiment shown this happens in that the relevant end face 53 with a light absorbing layer 41 is provided.

9 shows a similar embodiment as 8th , The front side 53 the carrier board 51 that the light entry surface 27 of the housing 23 assigned and substantially facing, here has two inclined surface sections 55 , whose respective surface normal N 'obliquely with respect to the surface normal N of the light entry surface 27 of the housing 23 (relative to the center of the light entry surface 27 in the case of a curved light entry surface 27 ) runs. As a result, sunlight, through the light entrance surface 27 of the housing 23 on the relevant front page 53 the carrier board 51 passes, deflected in the lateral direction, so that this light is not the light sensor 19 reached.

If, in connection with the invention, an oblique alignment of end faces of printed conductors (cf. 4 ), from front sides of the temperature sensor (see. 5 and 7 ) or from end faces of a support device (vg. 9 ), It is particularly advantageous if this oblique orientation is chosen such that sunlight, which falls through the light entry surface of the housing frontally into the housing, is directed away from the light sensor.

LIST OF REFERENCE NUMBERS

11

Temperature measurement unit

13a, 13b, 13c

conductor path

15a, 15b, 15c

front

17

temperature sensor

19

light sensor

21

Light entry surface

23

casing

25

Vehicle interior

27

Light entry surface

29

front panel

31

motherboard

33

evaluation

35

incident light beam

37

reflected light beam

41

light absorbing layer

43

bonding wire

45

Sloping segment

47

front

49

bearing surface

51

carrier board

53

front

55

Sloping segment

N

surface normal

N '

surface normal

Claims (14)

Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), characterized in that at least one of the tracks ( 13a . 13c ) an end face ( 15a . 15c ) adjacent to the light entry surface (FIG. 27 ) of the housing ( 23 ), this end face ( 15a . 15c ) is designed to fit into the housing ( 23 ) entering light ( 35 ) absorb. Temperature measuring unit according to claim 1, characterized in that the end face ( 15a . 15c ) at least in regions with a light-absorbing layer ( 41 ) is provided. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), characterized in that at least one of the tracks ( 13a . 13c ) an end face ( 15a . 15c ) adjacent to the light entry surface (FIG. 27 ) of the housing ( 23 ), wherein the surface normal (N ') of this end face ( 15a ) or a section ( 45 ) of this end face ( 15c ) obliquely to the surface normal (N) of the light entry surface ( 27 ) of the housing ( 23 ) runs. Temperature measuring unit according to claim 3, characterized in that the end face ( 15a ) or the front side section ( 45 ) with respect to the light entry surface ( 27 ) of the housing ( 23 ) and / or with respect to the light entry surface ( 21 ) of the light sensor ( 19 ) runs obliquely. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), characterized in that the temperature sensor ( 17 ) is formed at least partially light-absorbing. Temperature measuring unit according to claim 5, characterized in that at least one end face of the temperature sensor ( 17 ) adjacent to the light entrance surface ( 27 ) of the housing ( 23 ) is arranged with a light-absorbing layer ( 41 ) is provided. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), characterized in that the temperature sensor ( 17 ) an end face ( 47 ) adjacent to the light entry surface (FIG. 27 ) of the housing ( 23 ), wherein the surface normal (N ') of this end face ( 47 ) obliquely to the surface normal (N) of the light entry surface ( 27 ) of the housing ( 23 ) runs. Temperature measuring unit according to claim 7, characterized in that the temperature sensor ( 17 ) with respect to the light entry surface ( 27 ) of the housing ( 23 ) and / or with respect to the light entry surface ( 21 ) of the light sensor ( 19 ) is oriented obliquely. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) to is formed, the light sensor ( 19 ) acting light reflections ( 37 ), characterized in that the light sensor ( 19 ) on a support surface ( 49 ) one of the plurality of tracks ( 13b ), which is in the housing ( 23 ) projecting end of at least one other of the plurality of tracks ( 13a . 13c ) from the light entry surface ( 27 ) of the housing ( 23 ) with respect to the bearing surface ( 49 ) for the light sensor ( 19 ) is set back. Temperature measuring unit according to claim 9, that the at least one other of the plurality of tracks ( 13a . 13c ) less deep in the direction of the light entry surface ( 27 ) of the housing ( 23 ) in the housing ( 23 ) protrudes as the conductor track ( 13b ) at which the light sensor ( 19 ) is arranged. Temperature measuring unit according to one of the preceding claims, characterized in that the conductor tracks ( 13a . 13b . 13c ) are cantilevered. Temperature measuring unit according to claim 11, characterized in that the conductor tracks ( 13a . 13b . 13c ) are formed by a lead frame assembly. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), the printed conductors ( 13a . 13b . 13c ) at a common carrier device ( 51 ), characterized in that the support means ( 51 ) at least on one end face ( 53 ), the light entry surface ( 27 ) of the housing ( 23 ), is designed to absorb light. Temperature measuring unit ( 11 ) for determining a sunlight-compensated temperature in the interior ( 25 ) of a motor vehicle, with a temperature sensor ( 17 ), a light sensor ( 19 ) and several metallic interconnects ( 13a . 13b . 13c ) for the electrical contacting of the temperature sensor ( 17 ) and the light sensor ( 19 ), whereby the temperature sensor ( 17 ), the light sensor ( 19 ) and parts of the tracks ( 13a . 13b . 13c ) of a common housing ( 23 ) are enclosed, at least in a region between a light entry surface ( 27 ) of the housing and the light sensor ( 19 ) is translucent, the temperature measuring unit ( 11 ) within the housing ( 23 ) is adapted to the light sensor ( 19 ) acting light reflections ( 37 ), the printed conductors ( 13a . 13b . 13c ) at a common carrier device ( 51 ) are formed, characterized in that at least one end face ( 53 ) of the carrier device ( 51 ) adjacent to the light entrance surface ( 27 ) of the housing ( 23 ), or a section ( 55 ) of this end face ( 53 ) with respect to the light entry surface ( 27 ) of the housing ( 23 ) and / or with respect to the light entry surface ( 21 ) of the light sensor ( 19 ) runs obliquely.

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