This invention relates to a rear glass that is attached to a backdoor of a rear portion of a vehicle.
While a plurality of antennas for various media such as AM, FM, DTV and DAB are provided on the rear glass of automobiles, shared antennas having a common power supply unit have increasingly been used in recent years for the purpose of reducing the number of components such as connection terminals and cables. AM and FM, in particular, have increasingly been installed as a shared antenna (e.g., Patent Literature 1).
Patent Literature 1: JP 2011-135405A
Incidentally, there is a problem in that reception sensitivity deteriorates when an AM antenna is disposed in a position near a metallic region such as the body flange on the periphery of the rear glass or the defogger in the center of the rear glass. Thus, an AM/FM shared antenna such as the above is disposed a fixed distance away from metallic regions, mainly in consideration of the AM reception characteristics. However, when such AM constraints are taken into consideration, sufficient reception performance cannot be obtained with regard to FM of the AM/FM shared antenna. The invention has been made in order to solve this problem, and an object thereof is to provide a rear glass that can obtain favorable reception sensitivity with regard to both AM and FM in an AM/FM shared antenna.
A first invention is a rear glass for attachment to a lift-up backdoor that closes an opening in a rear portion of a vehicle, the rear glass including a glass plate, a defogger disposed in a vicinity of a center of the glass plate in an up-down direction, and a shared antenna installed on the glass plate upward or downward of the defogger, the shared antenna including a power supply unit, an AM antenna connected to the power supply unit, and an FM antenna connected to the power supply unit, and a relationship between an element length LAM of the AM antenna, a center wavelength λFM-C corresponding to a reception frequency band of the FM antenna and a wavelength shortening coefficient a of the glass plate satisfying 0.49×α×λFM-C≤LAM≤0.67×α×λFM-C.
In the above rear glass, the AM antenna can include a first AM antenna element extending in a horizontal direction from the power supply unit, a second AM antenna element extending in the up-down direction from an end portion of the first AM antenna element, and a third AM antenna element extending in the horizontal direction on the power supply unit side from a vicinity of an end portion of the second AM antenna element.
In the above rear glass, the AM antenna can include a fourth AM antenna element extending in the up-down direction on the first AM element side from an end portion of the third antenna AM element, and a fifth AM antenna element extending in the horizontal direction from an end portion of the fourth AM antenna element so as to couple with the second AM antenna element.
In the above rear glass, the defogger can include a pair of bus bars respectively extending in the up-down direction along right and left end portions of the glass plate, and a plurality of heating wires extending horizontally so as to join the pair of bus bars, the FM antenna can include a first FM antenna element extending in the up-down direction toward the defogger from the power supply unit, and a second FM antenna element coupled to an end portion of the first FM antenna element and extending in the horizontal direction, and the second FM antenna element can be capacitively coupled to the heating wire most closely approaching the FM antenna, among the heating wires of the defogger.
In the above rear glass, a distance between the second FM antenna element and the defogger can be set to less than or equal to a distance between the AM antenna and the defogger.
In the above rear glass, a distance in the up-down direction of a space between the defogger and an upper edge or a lower edge of an inner periphery of the backdoor to which the rear glass is attached can be set to less than or equal to 100 mm, the shared antenna can be disposed in the space, and the length of the AM antenna in the up-down direction can be set to less than or equal to 75 mm.
In the above rear glass, the shared antenna can be disposed upward of the defogger.
The above rear glass can further include a DAB antenna.
A second invention is a rear glass for attachment to a backdoor of a rear portion of a vehicle, the rear glass including a glass plate, a defogger disposed in a vicinity of a center of the glass plate in an up-down direction, and a shared antenna installed on the glass plate upward or downward of the defogger, the shared antenna including a power supply unit, an FM antenna connected to the power supply unit, an AM antenna, and a coil disposed between the power supply unit and the AM antenna.
With a rear glass according to this invention, favorable reception sensitivity can be obtained with regard to both AM and FM in an AM/FM shared antenna.
Hereinafter, an embodiment of a backdoor to which is attached a rear glass according to this invention will be described with reference to the drawings.
As shown in
As shown in
As shown in
The outer panels are constituted by two members, that is, an upper panel 21 and a lower panel 22. The upper panel 21 is a rectangular member that covers the upper edge part 13 of the inner panel 1. Also, the lower panel 22 is a member that covers the main body part 11 of the inner panel 1. Accordingly, the rear glass 3 is attached between the upper panel 21 and the lower panel 22.
Since the two reinforcing frames 4 have a symmetrical shape, only the reinforcing frame 4 on the left side will be described here. This reinforcing frame 4 is an L-shaped member having a first region 41 extending in the up-down direction and a second region 42 coupled to an upper end of this first region 41 and extending horizontally toward the right side, with these regions being integrally formed. This reinforcing frame 4 is disposed between the inner panel 1 and the outer panels 21 and 22. That is, the first region 41 of the reinforcing frame 4 is attached to an area corresponding to the side edge part 12 of the inner panel 1 and a vicinity of the upper end of the main body part 11 that is continuous therewith. On the other hand, the second region 42 is attached to an area corresponding to a vicinity of the center from the left end portion of the upper edge part 13 of the inner panel 1. Accordingly, a vicinity of the upper end of the main body part 11, both side edge parts 12, and the upper edge part 13 of the inner panel 1 are reinforced by the two reinforcing frames 4.
The inner panel 1, the upper panel 21, the lower panel 22, and the reinforcing frames 4 are formed from a resin material. For example, a carbon fiber reinforced resin (CFRP) can be employed. The lower panel 22, however, contributes little to the rigidity of the backdoor, and can thus be formed from a resin material such as polypropylene. Note that at least some of the parts constituting the backdoor, such as the inner panel 1, the outer panel 2 and the reinforcing frames 4, can also be formed from a metal.
Note that although the attachment angle θ (refer to
Next, the rear glass 3 will be described, with reference to
A known glass plate for automobiles can be utilized for the rear glass 3. For example, heat absorbing glass, common clear glass, common green glass or UV green glass may be utilized as the glass plate. Such a glass plate needs, however, to realize a visible light transmittance in line with safety standards of the country in which the automobile will be used. For example, solar absorbance, visible light transmittance and the like can be adjusted to meet safety standards. Hereinafter, an example of the composition of clear glass and an example of the composition of heat absorbing glass will be shown.
The composition of heat absorbing glass can, for example, be given as a composition, based on the composition of clear glass, including total iron oxide in terms of Fe2O3 (T—Fe2O3) at a ratio of 0.4 to 1.3 mass %, CeO2 at a ratio of 0 to 2 mass %, and TiO2 at a ratio of 0 to 0.5 mass %, and in which the skeletal component (mainly SiO2 or Al2O3) of the glass is reduced by an amount equivalent to the increase in T—Fe2O3, CeO2 and TiO2.
Note that the type of glass plate is not limited to clear glass or heat absorbing glass, and is selectable as appropriate according to the embodiment. For example, the glass plate may be a resin window made of acrylic resin, polycarbonate resin or the like.
Also, this rear glass 3 is formed in a curved shape as appropriate, so as to follow the shape of the inner panel 1. Such a rear glass 3, apart from being constituted by a single glass plate, may be a laminated glass in which an intermediate film such as a resin film is sandwiched by a plurality of plates of glass.
Next, the defogger 5 will be described. As shown in
Also, a distance G1 between an upper edge of the inner periphery of the backdoor to which the rear glass 3 is attached and an uppermost portion (heating wire 52 disposed most upward) of the defogger 5 can be set to 40 to 100 mm. Similarly, a distance G2 between a lower edge of the inner periphery of the backdoor and a lowermost portion (heating wire 52 disposed most downward) of the defogger 5 can also be set to 40 mm to 100 mm, for example. Also, the length of the defogger 5 in the up-down direction is not particularly limited, and can be set to 200 mm to 400 mm, for example. Alternatively, the length of the defogger 5 in the up-down direction can also be set to a length that is 65 to 85% of the length of the rear glass 3 in the up-down direction.
Next, the shared antenna 6 will be described. As shown in
On the other hand, the FM antenna 63 is provided with a rectangular frame-shaped FM main body element 630 that is coupled to the power supply unit 61 and extends in the horizontal direction toward the right side, a first FM antenna element 631 that extends downward from the power supply unit 61, and a second FM antenna element 632 that is coupled to a lower end portion of the first FM antenna element 631 and extends in the horizontal direction. The first FM antenna element 631 and the second FM antenna element 632 are formed in an inverted T-shape. A gap is formed between the second FM antenna element 632 and the heating wire 52 of the uppermost portion of the defogger 5, with a length L of this gap in the up-down direction preferably being 5 to 40 mm, and a length of the second antenna element 632 preferably being 100 to 300 mm. Also, the length L is more preferably 15 to 40 mm, and the second antenna element 632 is more preferably 200 to 500 mm. Furthermore, the length L is even more preferably 30 to 40 mm, and the second antenna element 632 is even more preferably 400 to 1000 mm. The second FM antenna element 632 and the defogger 5 are thereby constituted to be capacitively coupled. Since the possibility of noise being superimposed on AM broadcast waves due to the defogger 5 decreases as the length L increases, the length L is preferably longer. On the other hand, lengthening the second FM antenna element 632 facilitates capacitive coupling of the second FM antenna element 632 and the defogger 5. Also, due to the above configuration, the FM antenna 63 is positioned closer to the defogger 5 than is the AM antenna 62.
Also, the automobile is provided with a receiver for AM and FM (illustration omitted) and an amplifier (illustration omitted) connected thereto, and a cable (illustration omitted) connected to the amplifier is electrically connected to the power supply unit 61.
With the shared antenna 6 according to this embodiment, it was discovered that the influence of the AM antenna 62 on the reception performance of the FM antenna 63 can be reduced by adjusting the element length of the AM antenna 62 as follows. This point will be described with reference to
As shown in
Note that the wavelength shortening coefficient α of the glass plate 3 is also changed depending on factors such as the composition of the glass plate, and is approximately 0.5 to 0.7, for example. In the present application, 0.61 is used as a typical value in some calculations.
Although various patterns are conceivable for the AM antenna 62 other than
Note that the auxiliary element 620 is not necessarily required and need not be provided. Also, the length of each AM antenna element is not particularly limited, and can be changed as appropriate. The first to fourth patterns all use, as a basic pattern, a structure having the first AM antenna element 621 that extends horizontally from the power supply unit and the second and third AM antenna elements 622 and 623 (folded portion) that double back from the end portion thereof to the power supply unit side, but as long as this shape is provided, the element length LAM will be the total length of the first to third AM antenna elements 621 to 623, and the length of the auxiliary element 620 can be added if necessary.
Also, although the length (e.g., a2) of the AM antenna 62 in the up-down direction is not particularly limited, it is advantageous, in the case where the area between the defogger 5 and the upper end portion of the glass plate 3 is small, such as with the rear glass 3 that is provided on a lift-up backdoor, if this length is 50 mm or less, preferably 40 mm or less, and more preferably 30 mm or less, for example.
A defogger 5 and shared antenna 6 such as the above are constituted by assembling together wire rods, and these members can be formed by laminating a conductive material having conductivity on the surface of the rear glass 3 so as to have a predetermined pattern. Such a material need only have conductivity, and is selectable as appropriate according to the embodiment, with silver, gold, platinum and the like given as examples. Specifically, these members can be formed by, for example, printing and baking a conductive silver paste containing silver powder, glass frit and the like on the surface of the rear glass 3.
According to this embodiment, as described above, the following effects can be obtained.
(1) In the shared antenna 6, the element length LAM of the AM antenna 62 is configured to satisfy inequation (1), thus enabling a reduction in the reception performance of the FM antenna 63 to be suppressed. That is, even when the shared antenna 6 has the AM antenna 62 and the FM antenna 63, the AM antenna 62 can be prevented from affecting the reception performance of the FM antenna 63. Note that the FM antenna 63 generally exerts very little influence on the reception performance of the AM antenna 62. Accordingly, as long as inequation (1) is satisfied, the AM antenna 62 and the FM antenna 63 can be individually designed, and flexibility of design can be improved. As a result, the reception performance of both the AM antenna 62 and the FM antenna 63 in the shared antenna 6 can be improved.
(2) The area of the AM antenna 62 increases when the AM antenna 62 has a loop region such as with the second pattern, thus enabling the reception sensitivity of AM broadcast waves to be improved.
(3) The second FM element 632 of the FM antenna 63 is capacitively coupled to the defogger 5, thus enabling the reception sensitivity of FM broadcast waves to be improved.
Although an embodiment of this invention has been described above, the invention is not limited to the foregoing embodiment, and various changes can be made without departing from the gist of the invention. Note that the following variations can be combined as appropriate.
4-1. The patterns of the AM antenna 62 of the shared antenna 6 are examples, and the number, length, shape, direction and the like of the elements are not particularly limited, and can be configured in various forms. For example, the first pattern of the AM antenna 62 of the above embodiment is folded downward but may be folded upward, as shown in
4-2. The configuration of the FM antenna 63 is not particularly limited, and, for example, the FM main body element 630 can also be formed in another shape rather than a frame shape, such as at least a single line shape. Alternatively, the FM antenna 63 can also be constituted by only the first and second FM antenna elements 631 and 632, without providing the FM main body element 630. The shape of the first and second FM antenna elements 631 and 632 can be changed to be L-shaped or the like, for example, and other elements can also be provided. Alternatively, an FM sub-antenna in which an element extends from another power supply unit different from the power supply unit 61 can also be provided.
4-3. In the above embodiment, the element length LAM of the AM antenna 62 is adjusted so as to not affect the reception performance of the FM antenna 63, but a configuration such as shown in
4-4. In the above embodiment, the second FM antenna element 632 is disposed in a position nearer the defogger 5 than is the AM antenna 62, but the distance between the defogger 5 and the AM antenna 62 may be the same as the distance between the defogger 5 and the second FM antenna element 652. For example, the second FM antenna element 632 and the third AM antenna element 623 may be disposed the same distance from the defogger 5 by being aligned linearly. In this case, the third AM antenna element 623 need only be partially rather than entirely aligned linearly with the second FM antenna element 632.
4-5. Also, in the above embodiment, the shared antenna 6 is disposed more upward than is the defogger 5, but may be disposed downward of the defogger 5.
4-6. Antennas related to other media, such as a digital television antenna and a DAB antenna, for example, can also be provided.
4-7. The shape of the defogger 5 is also not particularly limited, and a configuration need only be adopted in which at least the bus bars 51a and 51b are respectively disposed on both sides and a plurality of horizontal heating wires 52 joining these bus bars 51a and 51b are provided. Also, the number and position of the vertical wires 53 are not particularly limited, and may be other than five and need not be disposed at equal intervals. A configuration can also be adopted in which the vertical py 53 are not provided.
4-8. The backdoor is not particularly limited in shape, and need only have a resin panel, and an opening part in which the rear glass 3 is fitted need only be formed in this resin panel. Accordingly, a configuration can also be adopted in which the backdoor has a single resin panel formed by integrating the upper panel and the lower panel, or, furthermore, has a plurality of panels, for example.
Also, the panels constituting the backdoor are preferably all formed from a resin material from the viewpoint of the reception sensitivity of the antennas, but a region of at least some panels may be formed from a metal. For example, the reinforcing frames can be formed from a metal and at least some of the other panels can also be formed from a metal.
4-9. The amplifier may be disposed on the glass plate 3, other than being provided in the vehicle interior. Also, the amplifier may be omitted, and the power supply unit and the receiver may be directly connected.
Hereinafter, working examples of this invention will be described. The invention is, however, not limited to the following working examples.
In the following investigations of reception performance, three dimensional electromagnetic simulation software (Time Domain 3D EM simulation software) was used. In this simulation, a glass plate was modeled, assuming a typical tempered glass having a thickness of 3.1 mm. Also, a model was configured in which the line width of the defogger and the antenna elements was given as 1 mm, and the shortening coefficient of the glass plate was given as 0.61. As the simulation procedure, simulation was executed, after having (1) modeled the vehicle, dielectric body, antennas and the like and set the materials, and (2) set an appropriate mesh for the vehicle, dielectric body, antennas and the like. Such setting and execution of the simulation was common to the investigations of all the working examples and comparative examples shown below.
A rear glass shown in
Simulation was performed with regard to the reception sensitivity in the FM frequency band (76 to 108 MHz) of the shared antenna in the case where the rear glass according to working examples 1 to 7, comparative examples 1 to 4 and the reference example was attached to the lift-up backdoor of a vehicle. That is, reception sensitivity was simulated for the case where radio waves (vertically polarized waves, horizontally polarized waves, diagonally polarized waves, etc.) were emitted toward the vehicle. Reception sensitivity was calculated using the simulation results for a dipole antenna modeled so as to have matching impedance for every frequency, by correcting these results. The conditions at the time of measurement were as follows.
Also, the wavelength shortening coefficient of the rear glass used here was set to 0.61 as described above, and inequation (1) was investigated using this value, as will be described later.
The results are as shown in
Here, the wavelength (λFM-C) at the center frequency (92 MHz) in the 76 to 108 MHz band is 3582 mm, and 974 mm 1332 mm from inequation (1). Thus, as shown in Table 1, the element length LAM of the AM antenna of working examples 1 to 7 satisfies inequation (1). On the other hand, the element length L of the AM antenna of comparative examples 1 to 4 does not satisfy inequation (1). Accordingly, it was found that an AM antenna having an element length that satisfies inequation (1) does not affect the reception performance of the FM antenna.
Note that, in this invention, it was investigated whether reception of AM broadcast waves was possible with only an FM antenna (reference numerals 63 (630, 631, 632) in
Simulation was performed with regard to the reception sensitivity in the AM frequency band (500 to 1500 kHz) of the shared antenna with a simulation method similar to that described above. The results are as shown in
2. Examinations Relating to Mode in which AM Antenna and Power Supply Part are Connected with Coil
Working example 8 having a shared antenna shown in
The reception performance of working example 8 and comparative example 5 was measured similarly to the above examinations. The results are as shown in
Next, working examples 9 to 12 in which the shape of the FM antenna was changed were prepared, and the reception performance was measured similarly to the above examinations.
The results are as shown in
3 Rear glass
5 Defogger
6 Shared antenna
61 Power supply unit
62 AM antenna
63 FM antenna
Number | Date | Country | Kind |
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2018-050275 | Mar 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/010546 | 3/14/2019 | WO | 00 |