JP2014056083A - Display switching device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display switching device having suppressed brightness unevenness.SOLUTION: A display switching device 1 comprises: a shielding part 14 which is formed on a substrate 13 and intercepts first light 110 and second light 120 and has an opening 140; a first transmission part 15 which is formed in the opening 140 of the shielding part 14, and intercepts the second light 120 and transmits the first light 110; a second transmission part which is formed in the opening 140 apart from the first transmission part 15, and intercepts the first light 110 and transmits the second light 120; and a brightness adjustment part 17 as a third transmission part transmitting the first light 110 and the second light 120, which is provided between the first transmission part 15 and the second transmission part 16 and has third transmittance based on first transmittance of the first transmission part 15 and second transmittance of the second transmission part 16.

Description

  The present invention relates to a display switching device.

  As a conventional technique, a first printed portion that is applied to the sheet and transmits only the wavelength of the first light source, a second printed portion that is applied to the sheet and transmits only the wavelength of the second light source, and a sheet is applied to the sheet. A third printed portion that does not transmit the wavelength of the first light source and the wavelength of the second light source, and a dimming surface portion that suppresses the amount of light passing through the overlapping portion of the first display and the second display, There is known a variable display structure provided with (for example, see Patent Document 1).

  The variable display structure can switch between the first display and the second display by switching the light source.

JP 2005-241759 A

  However, in the conventional variable display structure, the light transmittance of the first printed portion and the second printed portion, the portion where the first printed portion and the light control surface portion overlap, and the second print portion and the light control surface portion overlap. Since they are different, the overlapping portion becomes darker than the non-overlapping portion, and there is a problem that luminance unevenness occurs.

  Accordingly, an object of the present invention is to provide a display switching device that suppresses uneven brightness.

  One embodiment of the present invention includes a first light source that emits first light, a second light source unit that emits second light having a wavelength different from that of the first light, the first light and the second light A base that transmits light, formed on the base, shields the first light and the second light, has an opening, and is formed at the opening of the shield, and blocks the second light and the first. A first transmission part that transmits the first light, a second transmission part that is formed in the opening so as to be separated from the first transmission part, blocks the first light, and transmits the second light; Provided between the transmissive portion and the second transmissive portion, and having a third transmittance based on the first transmittance of the first transmissive portion and the second transmittance of the second transmissive portion. And a third transmission unit that transmits the first light and the second light.

  According to the present invention, luminance unevenness can be suppressed.

1A is a schematic diagram of the display switching device according to the first embodiment, and FIG. 1B is a cross-sectional view taken along line I (b) -I (b) in FIG. It is sectional drawing seen from the arrow direction. FIG. 2A is a schematic diagram of the display switching device according to the second embodiment, and FIG. 2B is a cross-sectional view taken along line II (b) -II (b) in FIG. It is sectional drawing seen from the arrow direction. FIG. 3A is a schematic diagram in the vicinity of the luminance adjustment unit of the display switching device according to the second embodiment, and FIG. 3B is a schematic diagram of a modification of the luminance adjustment unit. 4A is a schematic diagram of the display switching device according to the third embodiment, and FIG. 4B is a cross-sectional view taken along line IV (b) -IV (b) in FIG. 4A. It is sectional drawing seen from the arrow direction.

(Summary of embodiment)
The display switching device according to the embodiment includes a first light source that emits first light, a second light source unit that emits second light having a wavelength different from that of the first light, first light, and A base body that transmits the second light, and formed on the base body, shields the first light and the second light, has a shield part having an opening, and is formed in the opening of the shield part, and shields the second light. And a first transmission part that transmits the first light, and a second transmission part that is formed in the opening so as to be separated from the first transmission part, and that blocks the first light and transmits the second light, A third transmittance that is provided between the first transmission portion and the second transmission portion, and is based on the first transmittance of the first transmission portion and the second transmittance of the second transmission portion. And a third transmission part that transmits the first light and the second light.

  In this display switching device, since the third transmittance of the third transmissive portion is based on the first transmittance of the first transmissive portion and the second transmittance of the second transmissive portion, The difference in transmittance between the light transmitted through the first transmission unit, the light transmitted through the second transmission unit, and the light transmitted through the third transmission unit, compared to the case where the third transmission unit is not formed. Is reduced, and uneven brightness is suppressed.

[First Embodiment]
1A is a schematic diagram of the display switching device according to the first embodiment, and FIG. 1B is a cross-sectional view taken along line I (b) -I (b) in FIG. It is sectional drawing seen from the arrow direction. In each figure according to the embodiment, the ratio of the drawn image to the image may be different from the actual ratio.

  The display switching device 1 includes a first display 3 indicated by a first oblique line that rises right and a second display indicated by a second oblique line that rises left. 4 is switched. The display switching device 1 is configured so that the first display 3 and the second display 4 cannot be seen by the smoke gray printing unit 22 formed on the surface when there is no light from the light source. The common area 5 where the first oblique line and the second oblique line intersect is included in the first display 3 and the second display 4. That is, the first display 3 appears when the first transmissive part 15 and the common region 5 are illuminated by the first light source 11, and the second display 4 is displayed by the second transmissive part 16. And the common area 5 appear when illuminated by the second light source 12.

  The display switching device 1 includes a first light source 11 that emits first light 110, a second light source 12 that emits second light 120 having a wavelength different from that of the first light 110, and a first light 110. And a base 13 that transmits the second light 120, and a shielding part 14 that is formed on the base 13 and shields the first light 110 and the second light 120 and has an opening 140. ing.

  Further, the display switching device 1 is formed in the opening 140 of the shielding unit 14, and is separated from the first transmission unit 15 and the first transmission unit 15 that blocks the second light 120 and transmits the first light 110. And a second transmissive portion 16 that is formed in the opening 140 and blocks the first light 110 and transmits the second light 120.

  Furthermore, the display switching device 1 is provided between the first transmission unit 15 and the second transmission unit 16, and the first transmittance of the first transmission unit 15 and the second transmission unit 16 of the second transmission unit 16. It has a third transmittance based on the transmittance, and is schematically configured to include a luminance adjustment unit 17 as a third transmission unit that transmits the first light 110 and the second light 120.

  In the display switching device 1, as shown in FIG. 1A, the first display 3 is formed by the first light 110 that passes through the first transmission unit 15 and the luminance adjustment unit 17, and the second transmission is performed. The second display 4 is formed by the second light 120 that passes through the unit 16 and the luminance adjustment unit 17.

(Configuration of the first light source 11 and the second light source 12)
The first light source 11 and the second light source 12 are, for example, light emitting diodes (LEDs) disposed on a substrate 10 that is a printed wiring board. As an example, the first light source 11 is configured to emit blue light having a center wavelength of 450 nm. For example, the second light source 12 is configured to emit red light having a central wavelength of 650 nm different from the central wavelength of the first light source 11. This center wavelength is, for example, the wavelength at the center of the spectrum. In the present embodiment, since the light emitting diode is used as the light source, the intensity is greatest at the center wavelength. Note that the wavelengths of the first light 110 and the second light 120 are not limited to the above, and can be arbitrarily selected.

(Configuration of Base 13)
The base 13 is formed into a plate shape using, for example, highly transmissive optical glass, polycarbonate, acrylic, or the like. As shown in FIG. 1A, a smoke gray printing portion 22 is formed on the surface 130 side of the base 13. Further, the shielding part 14, the first transmission part 15, the second transmission part 16, and the luminance adjustment part 17 are formed on the back surface 131 side of the base 13.

  The smoke gray printing unit 22 formed on the surface 130 of the base 13 is a smoke gray filter that reduces the amount of light regardless of the wavelength of light. Provided on the surface 130 of the base 13 so that the first display 3 and the second display 4 cannot be seen by external light when the first light source 11 and the second light source 12 are turned off. ing.

(Configuration of shielding unit 14)
The shielding part 14 is formed using methods, such as vapor deposition and printing, for example. In this Embodiment, the shielding part 14 is formed in the back surface 131 side of the base | substrate 13 by silk screen printing.

  The shielding unit 14 is configured not to transmit the light of the first light source 11 and the second light source 12, that is, to shield them. The shielding portion 14 has an opening 140 having a shape based on the first display 3 and the second display 4. That is, the opening 140 has a shape in which opposite arrows are connected as shown in FIG.

(Configuration of the first transmission part 15 and the second transmission part 16)
The first transmission part 15 and the second transmission part 16 are formed using a method such as vapor deposition and printing, for example. In the present embodiment, the first transmission portion 15 and the second transmission portion 16 are formed on the back surface 131 side of the base 13 by silk screen printing.

  The first transmission unit 15 is configured to transmit the first light 110 of the first light source 11 and shield the second light 120 of the second light source 12. That is, the first transmission unit 15 is configured to transmit only light in the vicinity of the center wavelength of the first light source 11.

  Further, the second transmission unit 16 is configured to transmit the second light 120 of the second light source 12 and shield the first light 110 of the first light source 11. That is, the second transmission unit 16 is configured to transmit only light in the vicinity of the center wavelength of the second light source 12.

  Here, the light in the vicinity of the center wavelength is, for example, the center wavelength than the light in the region where the spectrum of the first light 110 of the first light source 11 and the spectrum of the second light 120 of the second light source 12 intersect. It shows more light. That is, in the case of a transmissive part that transmits the light in the intersecting area, for example, even if the first light source 11 is turned on and the second light source 12 is turned off, the second transmissive part 16 to the first light source 11 The first light 110 is transmitted, and not only the first display 3 but also the second display 4 is illuminated and seen. Therefore, the first transmission unit 15 and the second transmission unit 16 are in a region where the spectrum of the first light 110 of the first light source 11 and the spectrum of the second light 120 of the second light source 12 intersect. It is configured not to transmit light.

  A part of the first transmission part 15 and the second transmission part 16 is also formed on the shielding part 14 as shown in FIG. This is to prevent the occurrence of a gap with the shielding part 14 due to printing misalignment.

  As shown in FIG. 1A, the first transmission portion 15 is mainly formed in a portion excluding the common region 5 of the first display 3. Further, as shown in FIG. 1A, the second transmission portion 16 is mainly formed in a portion excluding the common region 5 of the second display 4.

  As shown in FIGS. 1A and 1B, the common region 5 corresponds to an end portion of a straight line portion of the arrow graphic of the first display 3 and the second display 4, and the first light source 11. This is a region through which both the first light 110 and the second light 120 of the second light source 12 are transmitted.

(Configuration of the brightness adjustment unit 17)
The brightness adjustment unit 17 is formed between the first transmission unit 15 and the second transmission unit 16 as shown in FIG. The brightness adjusting unit 17 is formed using a method such as vapor deposition and printing, for example. In the present embodiment, the brightness adjusting unit 17 is formed on the back surface 131 side of the base 13 by silk screen printing. In addition, the luminance adjusting unit 17 is formed with white ink as an example. The luminance adjustment unit 17 adjusts the luminance of light emitted through the common region 5, and the luminance difference between the first transmission unit 15 and the luminance adjustment unit 17 and between the second transmission unit 16 and the luminance adjustment unit 17. The brightness unevenness in the first display 3 and the second display 4 is suppressed.

  Here, the common region 5 between the first transmissive part 15 and the second transmissive part 16 only needs to transmit the first light 110 and the second light 120, so that the brightness adjusting part 17 is formed. Even if not, the first display 3 and the second display 4 can be switched. However, as an example, the first transmittance of the first light 110 of the first transmission portion 15 is 85%, the second transmittance of the second light 120 of the second transmission portion 16 is 85%, and the smoke When the transmittance of the gray printing unit 22 is 20%, 20% of light is transmitted through the common region 5, so that the light passing through the first transmission unit 15 and the second transmission unit 16 and the common region 5 With respect to the light passing therethrough, the luminance difference (difference in transmittance) is 3% (= (0.20−0.85 × 0.20) × 100), and the luminance difference between the tip portion of the arrow and the common region 5 portion. Becomes noticeable and looks bad.

  Therefore, in the present embodiment, the luminance adjustment unit 17 is formed between the first transmission unit 15 and the second transmission unit 16 to suppress the luminance difference. The third transmittance of the luminance adjustment unit 17 is determined based on the first transmittance of the first transmission unit 15 and the second transmittance of the second transmission unit 16. In the above example, since the first transmittance and the second transmittance are 85%, the third transmittance is preferably 85%. If the third transmittance is 85%, the transmittance of the light transmitted through the first transmission unit 15, the second transmission unit 16, and the luminance adjustment unit 17 becomes equal, so that no luminance difference occurs.

  The display switching of the display switching device 1 according to the first embodiment will be described below. Below, the case where the 1st display 3 of the left side shown to Fig.1 (a) is illuminated first is demonstrated.

(About switching display)
The display switching device 1 turns on the first light source 11 and turns off the second light source 12. This control may be performed by the display switching device 1 having a control unit, and may be performed by the control unit, or may be executed by control by an external device.

  The first light 110 emitted from the first light source 11 does not pass through the second transmission unit 16 but passes through the first transmission unit 15 and the luminance adjustment unit 17.

  The first light 110 transmitted through the first transmission unit 15 and the first light 110 transmitted through the luminance adjustment unit 17 are emitted through the base 13 and the smoke gray printing unit 22. Accordingly, the first display 3 is illuminated by the first light 110 transmitted through the first transmission unit 15 and the first light 110 transmitted through the luminance adjustment unit 17 and can be viewed by the user. Become.

  Subsequently, the case where the second display 4 on the right side illustrated in FIG. 1A is illuminated will be described below.

  The display switching device 1 turns off the first light source 11 and turns on the second light source 12.

  The second light 120 emitted from the second light source 12 does not pass through the first transmission unit 15 but passes through the second transmission unit 16 and the luminance adjustment unit 17.

  The second light 120 transmitted through the second transmission unit 16 and the second light 120 transmitted through the luminance adjustment unit 17 are emitted through the base 13 and the smoke gray printing unit 22. Therefore, the second display 4 is illuminated by the second light 120 transmitted through the second transmission unit 16 and the second light 120 transmitted through the luminance adjustment unit 17, and can be viewed by the user. Become.

(Effects of the first embodiment)
The display switching device 1 according to the present embodiment can suppress luminance unevenness. Specifically, in the display switching device 1, the third transmittance of the luminance adjustment unit 17 is changed to the first transmittance of the first transmission unit 15 and the second transmittance of the second transmission unit 16. Since it is based, compared with the case where the brightness adjusting unit 17 is not formed, light transmitted through the first transmission unit, light transmitted through the second transmission unit, light transmitted through the third transmission unit, The difference in transmittance is reduced, and uneven brightness is suppressed.

  Further, in this display switching device 1, since the brightness adjusting unit 17 is formed on the back surface 131 side of the base 13, which is the same as the first transmissive portion 15 and the second transmissive portion 16, the display switching device 1 is formed on the surface 130 side of the base 13. Compared with the case where it is done, the precision which forms the brightness | luminance adjustment part 17 is high.

[Second Embodiment]
(Configuration of the display switching device 1)
FIG. 2A is a schematic diagram of the display switching device according to the second embodiment, and FIG. 2B is a cross-sectional view taken along line II (b) -II (b) in FIG. It is sectional drawing seen from the arrow direction.

  The second embodiment is different from the first embodiment in that the luminance adjusting unit 17 has a pattern. In each of the following embodiments, portions having the same functions and configurations as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, and description thereof is omitted.

  As shown in FIG. 2B, the luminance adjustment unit 17 of the display switching device 1 according to the present embodiment is between the first transmission unit 15 and the second transmission unit 16 and the first transmission unit. The first pattern part 18 formed at a distance from the part 15 and the second transmission part 16, and at least a part of the first pattern part 18 and the first transmission part 15 is the first pattern part 18. It is formed on one of the pattern portion 18 and the first transmission portion 15, and at least a part between the first pattern portion 18 and the second transmission portion 16 is the first pattern portion 18 and the first transmission portion 15. A second pattern portion 19 formed on any one of the two transmission portions 16 and formed in accordance with a predetermined pattern.

  In the display switching device 1, as shown in FIG. 2A, the first display 3 is formed by the first light 110 transmitted through the first transmission unit 15 and the luminance adjustment unit 17, and the second transmission is performed. The second display 4 is formed by the second light 120 that passes through the unit 16 and the luminance adjustment unit 17.

(Configuration of the brightness adjustment unit 17)
FIG. 3A is a schematic diagram in the vicinity of the luminance adjustment unit of the display switching device according to the second embodiment, and FIG. 3B is a schematic diagram of a modification of the luminance adjustment unit.

  As shown in FIGS. 2B and 3A, the brightness adjusting unit 17 is schematically configured to include a first pattern unit 18 and a second pattern unit 19. The brightness adjusting unit 17 is formed using a method such as vapor deposition and printing, for example. In the present embodiment, the brightness adjusting unit 17 is formed on the back surface 131 side of the base 13 by silk screen printing, for example. In addition, the luminance adjusting unit 17 is formed with white ink as an example. The luminance adjusting unit 17 adjusts the luminance of the light emitted through the common region 5 by forming a pattern in consideration of the deviation at the time of formation in the common region 5, and adjusts the luminance with the first transmitting unit 15. The luminance difference between the first display 3 and the second display 4 is suppressed by suppressing the luminance difference between the unit 17 and the second transmission unit 16 and the luminance adjustment unit 17.

  The first pattern portion 18 is formed between the first transmission portion 15 and the second transmission portion 16 and at a distance from the first transmission portion 15 and the second transmission portion 16. That is, the first pattern portion 18 is formed so as not to overlap the first transmission portion 15 and the second transmission portion 16 even if a shift (printing shift) occurs during the formation.

  The interval L between the first transmission portion 15 and the first pattern portion 18 shown in FIG. 3A is, for example, as described above, even if a print misalignment occurs, the first pattern portion 18 The interval is set so as not to overlap with the transmitting portion 15 or the second transmitting portion 16. In the present embodiment, the interval L is, for example, 0.3 mm. As an example, the interval L between the second transmissive portion 16 and the first pattern portion 18 is set to be the same value as the interval L between the first transmissive portion 15 and the first pattern portion 18. .

Therefore, as an example, the width h ₁ of the first pattern portion 18 is set by subtracting a value twice the interval L from the distance between the first transmission portion 15 and the second transmission portion 16. Is done. As an example, the diameter of the dot 19a shown in FIGS. 2B and 3A is 0.1 mm.

The width h2 of the _second pattern portion 19 is set in consideration of printing misalignment. Width _{h 2} of the present embodiment, as an example, is 0.6 mm.

  That is, the brightness adjusting unit 17 is formed with a pattern that fills the space between the first transmissive part 15 and the second transmissive part 16 while suppressing the overlap between the first transmissive part 15 and the second transmissive part 16. The The pattern of the brightness adjusting unit 17 illustrated in FIG. 3A is a circular pattern (dot pattern), but is not limited to this and may be an arbitrary pattern. Note that the pattern of the brightness adjusting unit 17 is preferably a pattern in which the area of the portion overlapping the first transmission unit 15 and the second transmission unit 16 is small when printing misalignment occurs. Further, the second pattern portion 19 is formed so that the portion where the dot 19a is not formed does not continue in a straight line. This is because when the line is long, the portion becomes uneven in luminance.

  Here, as shown in the first embodiment, the first display 3 and the second display 4 can be switched without forming the luminance adjustment unit 17. However, as an example, the transmittance of the first light 110 of the first transmission unit 15 is 85%, the transmittance of the second light 120 of the second transmission unit 16 is 85%, and the transmission of the smoke gray printing unit 22 is performed. When the rate is 20%, the luminance difference becomes 3%, and the luminance difference becomes conspicuous at the tip portion of the arrow and the common region 5, and the appearance is deteriorated.

  Further, in order to suppress the above luminance difference, for example, a film (transmittance 85%) is formed so as to be within the common region 5 and not to overlap the first transmission part 15 and the second transmission part 16. In this case, since a margin for printing misalignment is required, a gap is generated between the first transmissive part 15 and the second transmissive part 16, and a luminance of 3% is provided near the gap in the same manner as described above. There is a difference.

  For example, when a film covering the common region 5 (transmittance of 85%) is formed so as to overlap the first transmission unit 15 and the second transmission unit 16, the first transmission unit 15 and the second transmission unit 16 are formed. The transmittance of the portion overlapping with is 14.45% (= (0.85 × 0.85 × 0.20) × 100), resulting in a luminance difference of 2.55%.

  In the present embodiment, this luminance difference can be suppressed by adjusting the pattern of the luminance adjusting unit 17. Specifically, since the transmittance of the first pattern portion 18 is the same as the transmittance of the first transmission portion 15 and the second transmission portion 16, the transmittance of the second pattern portion 19 is the first transmittance. What is necessary is just to become the same as the transmittance | permeability of the permeation | transmission part 15 and the 2nd permeation | transmission part 16. FIG.

Specifically, in the case of the first display 3, the transmittance of the second pattern portion 19 is mainly the transmittance of the portion where the first transmission portion 15 and the dot 19a overlap with each other, and the first transmission portion 15. Further, it is determined by the transmittance of the portion where the first pattern portion 18 is not formed and the portion where the dot 19a is not formed, that is, the portion where the substrate 13 is exposed. Therefore, if the combined transmittance of the overlapping portion and the portion where the dot 19a is not formed is the same as the transmittance of the first transmission portion 15 and the first pattern portion 18, the luminance adjustment of the first transmission portion 15 and the first transmission portion 15 is performed. The luminance difference at the boundary with the unit 17 is suppressed. Accordingly, when the area ratio of the portion where the dots 19a overlap in the second pattern portion 19 is a and the area ratio of the portion where the dots 19a are not formed is (1-a), the following equation is established. In the following expression, the transmittance of the first transmission part 15 and the first pattern part 18 is 17%.
0.2a + 0.1445 (1-a) = 0.17 (1)
Solving equation (1) yields a = 0.4594, and the second pattern portion 19 forms a pattern in which the overlapping portion is approximately 46% and the portion where the dot 19a is not formed is approximately 54%. Disappears. As shown in FIG. 2 (a), even if the second pattern portion 19 is shifted to the left and right of the paper surface of FIG. 2 (a) due to printing misalignment, the area ratio is almost unchanged, so the luminance difference is almost zero. Become.

(Modification of the second pattern portion 19)
As a modification, as shown in FIG. 3B, the second pattern portion 19 may be formed by arranging, for example, discrete linear patterns 19b. Similar to the dot pattern, the pattern 19b is also formed on the first pattern portion 18, the first transmission portion 15, and the second transmission portion 16 in consideration of printing misalignment.

  The pattern for forming the second pattern portion 19 is not limited to the above example, and at least a part of the first pattern between the first pattern portion 18 and the first transmission portion 15 is the first pattern. Between the first pattern portion 18 and the second transmission portion 16, and at least a part of the first pattern portion 18 and the second transmission portion 15 is formed between the first pattern portion 18 and the second transmission portion 16. Any pattern that can be formed on any one of the transmissive portions 16 may be used. Furthermore, it is preferable that the pattern for forming the second pattern portion 19 is formed so that the portions where the second pattern portion 19 is not formed are not arranged in a straight line.

  Hereinafter, display switching of the display switching device 1 according to the second embodiment will be described. Below, the case where the 1st display 3 of the left side of Fig.2 (a) is illuminated first is demonstrated.

(About switching display)
The display switching device 1 turns on the first light source 11 and turns off the second light source 12. This control may be performed by the display switching device 1 having a control unit, and may be performed by the control unit, or may be executed by control by an external device.

  The first light 110 emitted from the first light source 11 does not pass through the second transmission unit 16 but passes through the first transmission unit 15 and the luminance adjustment unit 17.

  The first light 110 transmitted through the first transmission unit 15 and the first light 110 transmitted through the luminance adjustment unit 17 are emitted through the base 13 and the smoke gray printing unit 22. Accordingly, the first display 3 is illuminated by the first light 110 transmitted through the first transmission unit 15 and the first light 110 transmitted through the luminance adjustment unit 17 and can be viewed by the user. Become.

  Subsequently, a case where the second display 4 on the right side illustrated in FIG. 2A is illuminated will be described below.

  The display switching device 1 turns off the first light source 11 and turns on the second light source 12.

  The second light 120 emitted from the second light source 12 does not pass through the first transmission unit 15 but passes through the second transmission unit 16 and the luminance adjustment unit 17.

  The second light 120 transmitted through the second transmission unit 16 and the second light 120 transmitted through the luminance adjustment unit 17 are emitted through the base 13 and the smoke gray printing unit 22. Therefore, the second display 4 is illuminated by the second light 120 transmitted through the second transmission unit 16 and the second light 120 transmitted through the luminance adjustment unit 17, and can be viewed by the user. Become.

(Effect of the second embodiment)
Since the display switching device 1 according to the present embodiment includes the luminance adjustment unit 17 having a pattern in consideration of a shift that occurs during formation between the first transmission unit 15 and the second transmission unit 16, Brightness unevenness can be suppressed. Specifically, the display switching device 1 overlaps the first transmission unit 15 and the second transmission unit 16 in the common region 5 between the first transmission unit 15 and the second transmission unit 16 but is discrete. The second pattern portion 19 is formed by the target dot 19a. Since the second pattern portion 19 can control the transmittance of this region by the dot 19a, it is possible to suppress luminance unevenness.

[Third Embodiment]
The third embodiment is different from the above-described embodiment in that an adjustment unit 17 a that further adjusts the transmittance is formed on the luminance adjustment unit 17.

  4A is a schematic diagram of the display switching device according to the third embodiment, and FIG. 4B is a cross-sectional view taken along line IV (b) -IV (b) in FIG. 4A. It is sectional drawing seen from the arrow direction.

  The display switching device 1 according to the present embodiment includes a first light source 11 that emits first light 110, and a second light source 12 that emits second light 120 having a wavelength different from that of the first light 110. A base 13 that transmits the first light 110 and the second light 120; a shielding portion 14 that is formed on the base 13 and shields the first light 110 and the second light 120 and has an opening 140; Is generally configured.

  Further, the display switching device 1 is formed in the opening 140 of the shielding unit 14, and is separated from the first transmission unit 15 and the first transmission unit 15 that blocks the second light 120 and transmits the first light 110. And a second transmissive portion 16 that is formed in the opening 140 and blocks the first light 110 and transmits the second light 120.

  Further, the display switching device 1 is provided between the first transmission unit 15 and the second transmission unit 16, has a third transmittance, and transmits the first light 110 and the second light 120. A luminance adjustment unit 17 serving as a third transmission unit is schematically provided.

  Furthermore, the display switching device 1 is provided on the brightness adjusting unit 17 and has a fourth transmittance based on the first to third transmittances, and includes the first light 110 and the second light. An adjustment portion 17a as a fourth transmission portion that transmits 120 is schematically configured.

  In the display switching device 1, as shown in FIG. 4A, the first display 3 is formed by the first light 110 that passes through the first transmission unit 15, the luminance adjustment unit 17, and the adjustment unit 17 a, The second display 4 is formed by the second light 120 that passes through the second transmission unit 16, the brightness adjustment unit 17, and the adjustment unit 17a.

(Configuration of the first light source 11 and the second light source 12)
The first light source 11 and the second light source 12 are, for example, light emitting diodes (LEDs) disposed on a substrate 10 that is a printed wiring board. As an example, the first light source 11 is configured to emit blue light having a center wavelength of 450 nm. For example, the second light source 12 is configured to emit red light having a central wavelength of 650 nm different from the central wavelength of the first light source 11. This center wavelength is, for example, the wavelength at the center of the spectrum. In the present embodiment, since the light emitting diode is used as the light source, the intensity is greatest at the center wavelength. Note that the wavelengths of the first light 110 and the second light 120 are not limited to the above, and can be arbitrarily selected.

(Configuration of Base 13)
The base 13 is formed into a plate shape using, for example, highly transmissive optical glass, polycarbonate, acrylic, or the like. As shown in FIG. 4A, a smoke gray printing portion 22 is formed on the surface 130 side of the base 13. Further, the shielding part 14, the first transmission part 15, the second transmission part 16, and the luminance adjustment part 17 are formed on the back surface 131 side of the base 13.

  The smoke gray printing unit 22 formed on the surface 130 of the base 13 is a smoke gray filter that reduces the amount of light regardless of the wavelength of light. Provided on the surface 130 of the base 13 so that the first display 3 and the second display 4 cannot be seen by external light when the first light source 11 and the second light source 12 are turned off. ing.

(Configuration of shielding unit 14)
The shielding part 14 is formed using methods, such as vapor deposition and printing, for example. In this Embodiment, the shielding part 14 is formed in the back surface 131 side of the base | substrate 13 by silk screen printing.

  The shielding unit 14 is configured not to transmit the light of the first light source 11 and the second light source 12, that is, to shield them. The shielding portion 14 has an opening 140 having a shape based on the first display 3 and the second display 4. That is, as shown in FIG. 4A, the opening 140 has a shape in which opposite arrows are connected.

(Configuration of the first transmission part 15 and the second transmission part 16)
The first transmission part 15 and the second transmission part 16 are formed using a method such as vapor deposition and printing, for example. In the present embodiment, the first transmission portion 15 and the second transmission portion 16 are formed on the back surface 131 side of the base 13 by silk screen printing.

  The first transmission unit 15 is configured to transmit the first light 110 of the first light source 11 and shield the second light 120 of the second light source 12. That is, the first transmission unit 15 is configured to transmit only light in the vicinity of the center wavelength of the first light source 11.

  Further, the second transmission unit 16 is configured to transmit the second light 120 of the second light source 12 and shield the first light 110 of the first light source 11. That is, the second transmission unit 16 is configured to transmit only light in the vicinity of the center wavelength of the second light source 12.

  Here, the light in the vicinity of the center wavelength is, for example, the center wavelength than the light in the region where the spectrum of the first light 110 of the first light source 11 and the spectrum of the second light 120 of the second light source 12 intersect. It shows more light. That is, in the case of a transmissive part that transmits the light in the intersecting area, for example, even if the first light source 11 is turned on and the second light source 12 is turned off, the second transmissive part 16 to the first light source 11 The first light 110 is transmitted, and not only the first display 3 but also the second display 4 is illuminated and seen. Therefore, the first transmission unit 15 and the second transmission unit 16 are in a region where the spectrum of the first light 110 of the first light source 11 and the spectrum of the second light 120 of the second light source 12 intersect. It is configured not to transmit light.

  A part of the first transmission part 15 and the second transmission part 16 is also formed on the shielding part 14 as shown in FIG. This is to prevent the occurrence of a gap with the shielding part 14 due to printing misalignment.

  As shown in FIG. 4A, the first transmission portion 15 is mainly formed in a portion excluding the common region 5 of the first display 3. Further, as shown in FIG. 4A, the second transmission portion 16 is mainly formed in a portion excluding the common region 5 of the second display 4.

  As shown in FIGS. 4A and 4B, the common region 5 corresponds to an end portion of a straight line portion of the arrow graphic of the first display 3 and the second display 4, and the first light source 11. This is a region through which both the first light 110 and the second light 120 of the second light source 12 are transmitted.

(Configuration of the brightness adjustment unit 17)
The brightness adjustment unit 17 is formed between the first transmission unit 15 and the second transmission unit 16 as shown in FIG. The brightness adjusting unit 17 is formed using a method such as vapor deposition and printing, for example. In the present embodiment, the brightness adjusting unit 17 is formed on the back surface 131 side of the base 13 by silk screen printing. In addition, the luminance adjusting unit 17 is formed with white ink as an example. The brightness adjusting unit 17 adjusts the brightness of the light emitted through the common area 5.

  The brightness adjustment unit 17 is also formed on the first transmission unit 15 and the second transmission unit 16 as shown in FIG. This is to suppress the occurrence of gaps due to printing misalignment. Accordingly, the overlapping portion is set in consideration of printing misalignment.

(Configuration of adjustment unit 17a)
The adjustment unit 17 a is formed on the luminance adjustment unit 17. The adjustment part 17a is formed using methods, such as vapor deposition and printing, for example. In the present embodiment, the adjustment unit 17a is formed on the luminance adjustment unit 17 by silk screen printing. Moreover, the adjustment part 17a is formed with white ink as an example.

  The adjustment unit 17 a suppresses the luminance difference between the first transmission unit 15 and the luminance adjustment unit 17, and the second transmission unit 16 and the luminance adjustment unit 17, thereby reducing the first display 3 and the second display 4. It suppresses uneven brightness.

  Here, the common region 5 between the first transmissive part 15 and the second transmissive part 16 only needs to transmit the first light 110 and the second light 120, so that the brightness adjusting part 17 is formed. Even if not, the first display 3 and the second display 4 can be switched. However, as shown in the first embodiment, in this case, the luminance difference between the light passing through the first transmission part 15 and the second transmission part 16 and the light passing through the common area 5 is 3%. Thus, the luminance difference becomes conspicuous between the tip portion of the arrow and the common region 5 and the appearance is deteriorated.

  Therefore, in the present embodiment, the luminance adjustment unit 17 and the adjustment unit 17a are formed between the first transmission unit 15 and the second transmission unit 16 to suppress the luminance difference. Specifically, as an example, when the third transmittance of the luminance adjusting unit 17 is 92% and the fourth transmittance of the adjusting unit 17a is 92%, the light transmitted through both is 16.9%, which is almost equal to the transmittance of the light transmitted through the first transmission part 15 and the second transmission part 16, so that there is almost no difference in luminance.

  Also, from the left side of FIG. 4B, the first region including only the first transmission unit 15, the second region where the first transmission unit 15 and the luminance adjustment unit 17 overlap, and the third region including only the luminance adjustment unit 17. A region, a fourth region where the luminance adjustment unit 17 and the adjustment unit 17a overlap, a fifth region including only the luminance adjustment unit 17, a sixth region where the second transmission unit 16 and the luminance adjustment unit 17 overlap, and a second region Assuming that the seventh region includes only the transmissive portion 16, the transmittance can be obtained as follows using the above-described transmittance as an example. The transmittance of the first region is 17%. The transmittance of the second region is 15.6%. The transmittance of the third region is 18.4%. The transmittance of the fourth region is 16.9%. The transmittance of the fifth region is 18.4%. The transmittance of the sixth region is 15.6%. The transmittance of the seventh region is 17%.

  Therefore, when the first display 3 is displayed, the transmittance from the left side of FIG. 4B is 17%, 15.6%, 18.4%, 16.9%, and 18.4%. The luminance difference is within a range of ± 1.4%. Similarly, when the second display 4 is displayed, the transmittance from the left side of FIG. 4B is 18.4%, 16.9%, 18.4%, 15.6%, and 17%. Thus, the luminance difference is within a range of ± 1.4%. This is because the brightness difference is smaller than when the brightness adjusting unit 17 and the adjusting unit 17a are not formed between the first transmitting unit 15 and the second transmitting unit 16. Further, since the transmittance increases or decreases, gradation is produced, and the luminance difference is difficult to understand.

  In the above calculation, the transmittances of the brightness adjusting unit 17 and the adjusting unit 17a are set to the same value, but the present invention is not limited to this, and the range of the brightness difference can be further narrowed by using different values. is there.

  Further, the display switching device 1 can eliminate the third area and the fifth area because the adjusting unit 17a is formed to have the same size as the luminance adjusting unit 17.

  The display switching of the display switching device 1 according to the first embodiment will be described below. First, the case where the left first display 3 shown in FIG. 4A is illuminated will be described below.

(About switching display)
The display switching device 1 turns on the first light source 11 and turns off the second light source 12. This control may be performed by the display switching device 1 having a control unit, and may be performed by the control unit, or may be executed by control by an external device.

  The first light 110 emitted from the first light source 11 does not pass through the second transmissive portion 16, and the first region of only the first transmissive portion 15 from the left side of FIG. The second region where the transmission unit 15 and the luminance adjustment unit 17 overlap, the third region where only the luminance adjustment unit 17 overlaps, the fourth region where the luminance adjustment unit 17 and the adjustment unit 17a overlap, and the fifth region where only the luminance adjustment unit 17 overlaps. Is transparent.

  The first light 110 transmitted through this region is emitted through the base 13 and the smoke gray printing unit 22. Accordingly, the first display 3 is illuminated by the first light 110 transmitted through the first region to the fifth region, and can be viewed by the user.

  Subsequently, a case where the second display 4 on the right side illustrated in FIG. 4A is illuminated will be described below.

  The display switching device 1 turns off the first light source 11 and turns on the second light source 12.

  The second light 120 emitted from the second light source 12 does not pass through the first transmission unit 15, and is a third region including only the luminance adjustment unit 17 from the left side of FIG. 4A, the luminance adjustment unit 17. And the fourth region where the adjustment unit 17a overlaps, the fifth region where only the luminance adjustment unit 17 overlaps, the sixth region where the second transmission unit 15 and the luminance adjustment unit 17 overlap, and the second region where only the second transmission unit 16 overlaps. 7 is transmitted.

  The second light 120 transmitted through this region is emitted through the base 13 and the smoke gray printing unit 22. Therefore, the second display 4 is illuminated by the second light 120 that has passed through the third region to the seventh region, and can be viewed by the user.

(Effect of the third embodiment)
The display switching device 1 according to the present embodiment can suppress luminance unevenness. Specifically, the display switching device 1 uses the luminance adjustment unit 17 and the adjustment unit 17 a to change the transmittance of light transmitted between the first transmission unit 15 and the second transmission unit 16 to the first transmission unit 15. Therefore, the light transmitted through the first transmission portion and the second transmission portion can be compared with the case where the luminance adjustment portion 17 is not formed. The difference in transmittance between the transmitted light and the light transmitted through the third transmission part is reduced, and luminance unevenness is suppressed.

  Further, the display switching device 1 can easily finely adjust the transmittance by forming the adjusting unit 17a.

  As a modification, the adjustment unit 17a may be a pattern.

  Moreover, although the display switching device 1 according to the above-described embodiment is the display switching with two colors, the display switching apparatus 1 is not limited to this, and the display switching with an arbitrary number of colors is possible.

  As mentioned above, although some embodiment and modification of this invention were demonstrated, these embodiment and modification are only examples, and do not limit the invention based on a claim. These novel embodiments and modifications can be implemented in various other forms, and various omissions, replacements, changes, and the like can be made without departing from the scope of the present invention. In addition, not all combinations of features described in these embodiments and modifications are necessarily essential to the means for solving the problems of the invention. Furthermore, these embodiments and modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Display switching device 3 ... 1st display 4 ... 2nd display 5 ... Common area | region 10 ... Board | substrate 11 ... 1st light source 12 ... 2nd light source 13 ... Base | substrate 14 ... Shielding part 15 ... 1st transmission part 16 ... 2nd transmission part 17 ... Brightness adjustment part 17a ... Adjustment part 18 ... 1st pattern part 19 ... 2nd pattern part 19a ... Dot 19b ... Pattern 22 ... Smoke gray printing part 110 ... 1st light 120 ... Second light 130 ... front surface 131 ... back surface 140 ... opening

Claims (5)

A first light source that emits first light;
A second light source unit that emits second light having a wavelength different from that of the first light;
A base that transmits the first light and the second light;
A shielding part that is formed on the substrate, shields the first light and the second light, and has an opening;
A first transmissive part formed in the opening of the shielding part, which shields the second light and transmits the first light;
A second transmissive portion that is formed in the opening to be separated from the first transmissive portion, blocks the first light, and transmits the second light;
The first transmission unit is provided between the first transmission unit and the second transmission unit, and is based on a first transmission rate of the first transmission unit and a second transmission rate of the second transmission unit. A third transmission part having a transmittance of 3, and transmitting the first light and the second light;
A display switching device. The third transmission part is
A first pattern part formed at a distance from the first transmission part and the second transmission part;
A part of the first pattern portion and the first transmission portion is formed on at least one of the first pattern portion and the first transmission portion, and the first pattern A portion is formed on at least one of the first pattern portion and the second transmission portion between the first transmission portion and the second transmission portion, and is formed according to a predetermined pattern A second pattern portion;
The display switching device according to claim 1.   The display switching device according to claim 1, wherein the predetermined pattern of the second pattern portion is a dot pattern.   And a fourth transmittance based on the first transmittance to the third transmittance, the first light and the second light being provided on the third transmission portion. The display switching device according to claim 1, further comprising a fourth transmission portion that transmits light. A first light source that emits first light;
A second light source unit that emits second light having a wavelength different from that of the first light;
A base that transmits the first light and the second light;
A shielding part that is formed on the substrate, shields the first light and the second light, and has an opening;
A first transmissive part formed in the opening of the shielding part, which shields the second light and transmits the first light;
A second transmissive portion that is formed in the opening to be separated from the first transmissive portion, blocks the first light, and transmits the second light;
A third transmission part provided between the first transmission part and the second transmission part, having a third transmittance, and transmitting the first light and the second light;
Provided on the third transmission portion, having a fourth transmittance based on the first transmittance to the third transmittance, and transmitting the first light and the second light; A fourth transmission part;
A display switching device.

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