JP2020165691A - Radio wave transmission cover - Google Patents

Abstract

To provide a radio wave transmission cover capable of both suppressing of a lack of heat generation performance and securing of required radio wave transmission performance.SOLUTION: A radio wave transmission cover includes a cover base material made of a resin material and arranged on a path of radio waves transmitted and received by a radio wave radar, and a conductive thin film 8 arranged on a surface of the cover base material and configured to generate heat by energization. The conductive thin film 8 includes a hole region 10 formed by an annular hole 12, and a resonance region 11 that is insulated by being surrounded by the hole region 10. A plurality of the hole regions 10 and resonance regions 11 are formed so as to be spaced apart from each other and regularly aligned with each other in the conductive thin film 8. A size of the resonance region 11 is a magnitude that outputs a radio wave having a wavelength equivalent to that of the radio wave when the radio wave is incident on the resonance region 11. Further, an interval between the regularly arranged hole regions 10 and resonance regions 11 is set to be an interval satisfying the heat generation performance required for the conductive thin film 8.SELECTED DRAWING: Figure 2

Description

The present invention relates to a radio wave transmitting cover.

Vehicles such as automobiles are equipped with devices that transmit and receive radio waves, such as radio wave radar. This radio wave radar transmits radio waves such as millimeter waves toward the outside of the vehicle, while receiving the above-mentioned radio waves (reflected waves) reflected by hitting an object outside the vehicle, and detects an object outside the vehicle through transmission and reception of such radio waves. is there. Further, on the front side (outside of the vehicle) of the radio wave radar in the transmission direction of radio waves, a radio wave transmission cover is provided so that the radio wave radar cannot be seen directly from the outside of the vehicle. This radio wave transmission cover is located on the path of radio waves transmitted and received by the radio wave radar.

A thinly elongated conductor is arranged on the radio wave transmitting cover as shown in Patent Document 1, and the conductor is heated by energizing the conductor to melt ice and snow adhering to the radio wave transmitting cover. Will be done. Incidentally, in Patent Document 1, the conductors are arranged so as to reciprocate and extend, and a predetermined distance is provided between the portions parallel to each other by reciprocating and extending the conductors. Then, if the ice and snow adhering to the radio wave transmitting cover are melted as described above, it is possible to suppress deterioration of the detection performance of the radio wave radar due to the attenuation of the radio wave due to the adhesion of the ice and snow.

Japanese Patent Application Laid-Open No. 4-150302

By the way, in the radio wave transmission cover, since the radio wave is blocked by the conductor that is energized, the parallel portion is provided by providing a predetermined distance between the parallel portions of the conductor that are elongated so as to reciprocate. Radio waves can be transmitted through the gaps between the parts. However, it is unclear to what extent the conductors arranged as described above affect the radio wave transmission performance of the radio wave transmission cover. Therefore, there is a possibility that the radio wave transmission performance required for the radio wave transmission cover cannot be obtained.

Further, for the purpose of improving the radio wave transmission performance of the radio wave transmission cover, it is conceivable to increase the gap between the parallel portions of the conductor that extends narrowly so as to reciprocate. However, in this case, it is undeniable that the amount of the conductor is reduced, and the heat generation performance of the conductor for melting the ice and snow adhering to the radio wave transmitting cover may be insufficient.

An object of the present invention is to provide a radio wave transmission cover capable of achieving both suppression of insufficient heat generation performance and securing of required radio wave transmission performance.

Hereinafter, means for solving the above problems and their actions and effects will be described.
The radio wave transmission cover that solves the above problems includes a resin cover base material provided on the path of radio waves transmitted and received by the device, and a conductive thin film provided on the surface of the cover base material and generating heat by energization. Be prepared. Further, the conductive thin film includes a hole region formed by annular holes and a resonance region that is insulated by being surrounded by the hole region, and the hole region and the resonance region are conductive. A plurality of thin films are formed at intervals from each other so as to be regularly arranged. The size of the resonance region is such that when the radio wave is incident on the resonance region, a radio wave having a wavelength equivalent to that radio wave is output. Further, the intervals between the regularly arranged hole regions and the resonance regions are set to satisfy the heat generation performance required for the conductive thin film. The interval is preferably a distance at which a so-called grating lobe does not occur.

According to the above configuration, a conductive thin film is provided on the surface of the cover base material of the radio wave transmission cover, and a portion of the conductive thin film other than the hole region and the resonance region is a portion that generates heat by energization. Then, the heat generated in that portion satisfies the heat generation performance required for the conductive thin film. Further, when a radio wave is incident on the resonance region of the conductive thin film, a radio wave having a wavelength equivalent to that radio wave is output from the resonance region, and thereby the same state as the state in which the radio wave is transmitted through the resonance region. Therefore, the required radio wave transmission performance can be ensured. As described above, it is possible to both suppress the insufficient heat generation performance of the radio wave transmission cover and secure the required radio wave transmission performance.

In the radio wave transmission cover, the resonance region is formed in a square shape having a side length a, and is arranged so as to have a distance p between the centers of the adjacent resonance regions. Further, the hole region is formed with a width w around the resonance region. Then, the size of the resonance region is set so that when a radio wave is incident on the resonance region, a radio wave having a wavelength equivalent to that of the radio wave is output, and the regularly arranged hall region and the above To set the distance between the resonance regions to satisfy the heat generation performance required for the conductive thin film, the following equation "(a + 2w) <p <(λ /) is applied to the wavelength λ of the radio wave incident on the resonance region. 2) It is realized by defining the length a, the distance p, and the width w so as to satisfy <(λ + a + 2w) ”.

According to the above configuration, since the resonance region and the hole region have a square shape, it is easy to arrange them regularly with respect to the conductive thin film. Further, by determining the length a, the distance p, and the width w so as to satisfy the above equation, it is necessary to suppress the insufficient heat generation performance of the radio wave transmission cover and to suppress the generation of the grating lobe. It is possible to secure the radio wave transmission performance to be performed.

In the radio wave transmission cover, the hole region is arranged so as to have a distance 2d from the hall region adjacent to the hall region, and the length a, the distance p, the width w, and the distance 2d are: It is conceivable that the following equations "p = a + 2w + 2d" and the equation "2d = a + 2w" are satisfied.

If the distance 2d is set to "2d <a + 2w", the resistance value of the conductive thin film becomes high and it becomes difficult for current to flow, which may not satisfy the power generation performance required for the conductive thin film. Further, if the distance 2d is set to "2d> a + 2w", the resistance value of the conductive thin film becomes low, so that the conductive thin film does not generate sufficient heat depending on the value of the current flowing through the conductive thin film, and is conductive. It may not meet the power generation performance required for thin films. According to the above configuration, since the distance 2d is defined to satisfy the formulas “p = a + 2w + 2d” and the formula “2d = a + 2w”, the power generation performance required for the conductive thin film cannot be satisfied as described above. Can be suppressed. As a result, the heat generation performance of the conductive thin film when the conductive thin film is energized can be set to the performance required for the conductive thin film.

The cover base material is provided on the path of radio waves transmitted and received by a radio wave radar mounted on the vehicle, and the conductive thin film is provided on the outer surface of the vehicle on the cover base material. It is conceivable that it is formed so as to be transparent.

According to this configuration, the ice and snow adhering to the radio wave transmitting cover can be effectively melted by the heat generated by the conductive thin film provided on the outer surface of the vehicle in the cover base material. Further, since the conductive thin film is formed to be transparent, when the cover base material is decorated so as to be visible from the outside of the vehicle, the decoration can be suppressed from being hidden by the conductive thin film. Become.

A cross-sectional view showing a radio wave radar and a radio wave transmission cover mounted on a vehicle. A front view showing a state in which the conductive thin film is viewed from the left side of FIG.

Hereinafter, an embodiment of the radio wave transmission cover will be described with reference to FIGS. 1 and 2.
FIG. 1 schematically shows a radio wave radar 1 and a radio wave transmission cover 2 mounted on a vehicle. The radio wave radar 1 transmits radio waves such as millimeter waves toward the outside of the vehicle (left side in FIG. 1), while receiving the above-mentioned radio waves (reflected waves) reflected by hitting an object outside the vehicle, and transmitting and receiving such radio waves transmits an object outside the vehicle. Detect. The radio wave transmission cover 2 is located on the front side (outside of the vehicle) of the radio wave radar 1 in the transmission direction of radio waves so that the radio wave radar 1 cannot be seen directly from the outside of the vehicle. The radio wave transmission cover 2 is located on the path of radio waves transmitted and received by the radio wave radar 1.

The cover base material 3 of the radio wave transmission cover 2 includes a base layer 4 formed of ASA (Acrylate Sthrene Acrylonitrile) resin. A protrusion 5 is formed on the surface of the base layer 4 opposite to the radio wave radar 1 (the surface on the left side in FIG. 1), and a metal having radio wave transmission is formed on the tip surface of the protrusion 5 in the protruding direction. A design layer 6 made of the material is formed. The portion of the base layer 4 on the protrusion 5 side is decorated with the design layer 6. Further, the cover base material 3 also includes a transparent layer 7 that covers a portion of the base layer 4 on the protruding portion 5 side. The transparent layer 7 is formed of polycarbonate, which is a transparent resin.

A conductive thin film 8 that generates heat when energized is provided on the outer surface of the cover base material 3 (the left surface of FIG. 1). The conductive thin film 8 is formed to be transparent by a conductor such as silver (Ag). Further, the outer surface of the vehicle in the conductive thin film 8 is covered with a protective layer 9 formed of polycarbonate. The cover base material 3 formed as described above is also located on the path of radio waves transmitted and received by the radio wave radar 1.

Next, the conductive thin film 8 will be described in detail.
FIG. 2 shows a state in which the conductive thin film 8 is viewed from the left side of FIG. As can be seen from FIG. 2, the conductive thin film 8 includes a hole region 10 formed by the annular holes 12 and a resonance region 11 that is insulated by being surrounded by the hole regions 10. A plurality of the hole regions 10 and the resonance regions 11 are formed at intervals from each other so as to be regularly arranged with respect to the conductive thin film 8. This interval is defined as an interval at which a so-called grating lobe does not occur. The resonance region 11 is formed in a square shape having a side length a, and is arranged so as to have a distance p between the centers of the adjacent resonance regions 11 and each other. Further, the hole region 10 is formed with a width w around the resonance region 11, and has a square shape like the resonance region 11.

The size of the resonance region 11 is such that when a radio wave transmitted from the radio wave radar 1 is incident on the resonance region 11, a radio wave having a wavelength equivalent to that radio wave is output. Further, the distance between the regularly arranged hole regions 10 and the resonance regions 11 is the heat generation performance required for the conductive thin film 8, in other words, the heat generation performance of the conductor capable of melting the ice and snow adhering to the radio wave transmitting cover. It is said that the interval is satisfied. Specifically, the length a so as to satisfy the following equation “(a + 2w) <p <(λ / 2) <(λ + a + 2w)… (A)” with respect to the wavelength λ of the radio wave incident on the resonance region 11. , The distance p, and the width w are defined.

By determining the length a in this way, the size of the resonance region 11 can be set to a size that outputs a radio wave having a wavelength equivalent to that of the radio wave when the radio wave is incident on the resonance region 11. It will be realized. Further, by determining the distance p and the width w as described above, the intervals between the regularly arranged hole regions 10 and the resonance regions 11 satisfy the heat generation performance required for the conductive thin film 8. Is realized.

The hole area 10 is arranged so as to have a distance of 2d from the hole area 10 adjacent to the hole area 10. Then, the length a, the distance p, the width w, and the distance 2d satisfy the following equations “p = a + 2w + 2d… (B)” and the equations “2d = a + 2w… (C)”. Is also defined.

Next, the operation of the radio wave transmission cover 2 will be described.
A conductive thin film 8 is provided on the outer surface of the cover base material 3 of the radio wave transmission cover 2, and a portion of the conductive thin film 8 other than the hole region 10 and the resonance region 11 becomes a portion that generates heat by energization. .. Then, the heat generated in that portion satisfies the heat generation performance required for the conductive thin film 8. Further, when a radio wave is incident on the resonance region 11 of the conductive thin film 8, a radio wave having a wavelength equivalent to the radio wave is output from the resonance region 11, whereby the radio wave is transmitted through the resonance region 11. Since it is in the same state as the state, the required radio wave transmission performance can be secured.

According to the present embodiment described in detail above, the following effects can be obtained.
(1) It is possible to both suppress the insufficient heat generation performance of the radio wave transmission cover 2 and secure the required radio wave transmission performance.

(2) Since the resonance region 11 and the hole region 10 have a square shape, it is easy to arrange them regularly with respect to the conductive thin film 8. Further, by determining the length a, the distance p, and the width w so as to satisfy the above formula (A), it is possible to suppress the insufficient heat generation performance of the radio wave transmission cover 2 and suppress the generation of grating lobes. Therefore, the required radio wave transmission performance can be ensured.

(3) If the distance 2d is set to "2d <a + 2w", the resistance value of the conductive thin film 8 becomes high and it becomes difficult for current to flow, which may not satisfy the power generation performance required for the conductive thin film 8. There is. On the other hand, if the distance 2d is set to "2d> a + 2w", the resistance value of the conductive thin film 8 becomes low, so that the conductive thin film 8 does not generate sufficient heat depending on the value of the current flowing through the conductive thin film 8. , There is a possibility that the power generation performance required for the conductive thin film 8 is not satisfied. However, since the distance 2d is set to satisfy the formulas (B) and (C), it is possible to prevent the conductive thin film 8 from being unable to satisfy the power generation performance required as described above. As a result, the heat generation performance of the conductive thin film 8 when the conductive thin film 8 is energized can be set to the performance required for the conductive thin film 8.

(4) Since the conductive thin film 8 is provided on the outer surface of the vehicle in the cover base material 3, the heat generated by the conductive thin film 8 can effectively melt the ice and snow adhering to the radio wave transmitting cover 2. .. Further, since the conductive thin film 8 is formed so as to be transparent, it is possible to prevent the decoration applied to the cover base material 3 from being hidden by the conductive thin film 8 so that it can be seen from the outside of the vehicle.

The above embodiment can be changed as follows, for example.
-The distance 2d does not necessarily have to be defined so as to satisfy the equation (C). For example, the distance 2d can be set to a value close to "a + 2w".

-Although the radio wave radar 1 has been exemplified as a device for transmitting and receiving radio waves, other devices may be adopted.
The conductive thin film 8 does not necessarily have to be provided on the outer surface of the vehicle on the cover base material 3, and may be provided on the inner surface of the vehicle (right surface in FIG. 1) of the cover base material 3.

The shape of the resonance region 11 and the hall region 10 may be a shape other than a square shape such as a circular shape.
-The radio wave transmitted and received by the radio wave radar 1 may be a radio wave other than millimeter waves.

-The conductive thin film 8 does not necessarily have to be formed of silver, and can be formed of another material such as indium tin oxide (ITO).
-The cover base material 3 may be formed of a resin other than the ASA resin, such as AES resin.

-The transparent layer 7 and the protective layer 9 may be formed of a transparent resin other than polycarbonate, such as acrylic resin.

1 ... Radio radar, 2 ... Radio transmission cover, 3 ... Cover base material, 4 ... Base layer, 5 ... Protrusion, 6 ... Design layer, 7 ... Transparent layer, 8 ... Conductive thin film, 9 ... Protective layer, 10 ... Hall region, 11 ... resonance region, 12 ... hole.

Claims (4)

It is provided with a resin cover base material provided on the path of radio waves transmitted and received by the device, and a conductive thin film provided on the surface of the cover base material and generating heat by energization.
The conductive thin film includes a hole region formed by annular holes and a resonance region that is insulated by being surrounded by the hole region, and the hole region and the resonance region are the conductive thin film. Multiple pieces are formed with a space between them so that they are lined up regularly.
The size of the resonance region is such that when the radio wave is incident on the resonance region, a radio wave having a wavelength equivalent to that radio wave is output.
A radio wave transmission cover characterized in that the regularly arranged intervals between the hole regions and the resonance regions are intervals that satisfy the heat generation performance required for the conductive thin film. The resonance region is formed in a square shape having a side length a, and is arranged so as to have a distance p between the centers of the adjacent resonance regions.
The hole region is formed with a width w around the resonance region.
The size of the resonance region shall be such that when the radio wave is incident on the resonance region, a radio wave having a wavelength equivalent to that of the radio wave is output, and the regularly arranged hall region and the resonance To set the distance between the regions to satisfy the heat generation performance required for the conductive thin film, the following equation “(a + 2w) <p <(λ) is used with respect to the wavelength λ of the radio wave incident on the resonance region. / 2) The radio wave transmission cover according to claim 1, which is realized by defining the length a, the distance p, and the width w so as to satisfy "(λ + a + 2w)". The hole area is arranged so as to have a distance of 2d from the hole area adjacent to the hole area.
The radio wave transmission according to claim 2, wherein the length a, the distance p, the width w, and the distance 2d are defined to satisfy the following formulas "p = a + 2w + 2d" and the formula "2d = a + 2w". cover. The cover base material is provided on the path of radio waves transmitted and received by the radio wave radar mounted on the vehicle.
The radio wave transmission cover according to any one of claims 1 to 3, wherein the conductive thin film is provided on the outer surface of the vehicle in the cover base material and is formed so as to be transparent.