JP2008270478A - On-vehicle airflow display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the expandability, visibility, and durability of an on-vehicle airflow display device while rationally reducing (downsizing) a display region of the on-vehicle airflow display device. <P>SOLUTION: Four light emitting segments 100A-D used in an airflow display portion have a contour in the shape of a vane of a rotary fan (luminescent display pattern). They are congruent, and are arranged rotationally symmetrical through 90° about one point P<SB>0</SB>of rotation symmetry. An n-side lead electrode 111A is connected to a negative electrode of a DC power supply via one switch (transistor). This switch is prepared one for each of the four light emitting segments, and the light emitting segments are separately controlled for turning on/off by their corresponding switches. The light emitting segment 100A includes total six p-side lead electrodes 112, and the potentials of the six electrodes can be separately controlled by six switches. The rotating speed of the fan and colors to be emitted are controlled by these switches. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an air volume display device that displays an output air volume of an in-vehicle air conditioner by lighting a light emitting segment.

As an air volume display device that displays the output air volume of an in-vehicle air conditioner by lighting display of a light emitting segment, for example, a device described in Patent Document 1 below is known. FIG. 7 is a front view of the display panel 20 of the conventional vehicle air conditioner. In this conventional apparatus, the output air volume of the air conditioner is displayed by the number of lighting of each bar graph-like display means 21a constituting the blower mode display means 21 arranged at the center.
JP-A-10-119564

However, in the above-described conventional apparatus, the output air volume of the air conditioner can be displayed in four stages, but cannot be displayed in five stages or more than six stages. For this reason, when further increasing the number of stages of air volume control, it is necessary to increase the number of stages of the display unit (display means 21a) of the display device. In this case, as the number of output air volume control steps increases, the display area is required to be wider on the right side, which causes problems in terms of expandability and miniaturization as a display device. Also, if the fan mark (blower display means 22) is omitted from this conventional device, it will be difficult to understand the meaning (display purpose) of the display means 21a. However, this is a factor that requires a wide display area in the conventional apparatus.
Further, since the bar graph-like display means 21a is a method of sequentially lighting from the left side, the light emission load tends to be concentrated on the leftmost display means 21a, so that the life of each light source (illumination means) is increased. Are likely to vary. In addition, due to variations in the light emission load, only the portion directly above the leftmost display means 21a of the resin covering the display portion is likely to be deteriorated in translucency (easily discolored) as compared with other portions. There is a problem to say.

  The present invention has been made to solve the above-mentioned problems, and the object thereof is to rationally reduce (miniaturize) the display area of the in-vehicle air volume display device, and at the same time, this in-vehicle air volume display device. Is to improve extensibility, visibility and durability.

In order to solve the above problems, the following means are effective.
That is, the first means of the present invention is an air volume display device that displays the output air volume of an in-vehicle air conditioner by lighting display of n light emitting segments (n ≧ 3) arranged in a rotationally symmetrical manner. Rotation display means for rotating a light-emitting display pattern constituted by turning on or off each of the light-emitting segments around the symmetry point of the rotational symmetry, and the rotation speed as a monotonically increasing function of the output air volume Rotating speed variable means, LEDs that are controlled to blink by the rotating display means on each of the light emitting segments, a wiring board having a metal wiring to which these LEDs are connected, and light diffusion for sealing the LEDs A sealing resin mixed with an agent, a black or dark light-shielding frame surrounding the sealing resin from the side, and a light reflecting member disposed on the bottom of the LED and the sealing resin. A.

However, the above-mentioned output air volume may be controlled (increase / decrease) stepwise by the above air conditioner, or may be continuously controlled steplessly. Further, when the rotational speed is monotonously increased with respect to the output air volume, the rotational speed may be continuously monotonously increased with respect to the output air volume, or may be monotonously increased stepwise. In addition, the shape of the three or more light-emitting segments does not necessarily have to be exactly congruent as long as it represents the rotation of the light-emitting display pattern, and their arrangement is not necessarily accurate. It does not have to be rotationally symmetric on a plane.
In addition, the number of the light emitting segments arranged in a substantially rotationally symmetric shape may be an arbitrary number of 3 or more, more preferably 4 or more and 10 or less. If this number is 2 or less, the rotational motion cannot be expressed. Further, when this number is increased, the rotation of the fan can be made smoother. However, if this number is excessively increased, the required manufacturing cost and processing accuracy become too high, which is not desirable.

Moreover, as a material of said light-shielding frame, the material with sufficiently low translucency is desirable, and it is desirable that the color is especially black or a color close to black as much as possible.
The light reflecting member may be anything as long as it easily reflects light. For example, the light reflecting member may be composed of a white paint, a silver paint, or a fluorescent paint printed on the bottom surface. Moreover, you may comprise with a white reflective resist film, the metal thin film apply | coated or vapor-deposited, etc.
In addition, as the light diffusing agent, known ones used for liquid crystal display devices such as general televisions, personal computers, car navigation systems, and mobile phones can be used. Moreover, you may use a light-diffusion film etc. instead of a light-diffusion agent.

The second means of the present invention is to form the light-shielding frame body from the resin applied to the upper surface of the wiring board and cured in a partition shape in the first means.
However, as such a resin, for example, a silicon resin or a silicon resin can be applied. The means for applying the resin to the upper surface of the wiring board may be arbitrary. For example, a printing machine that performs screen printing may be used, or a dispenser may be used.

According to a third means of the present invention, there is provided a black or dark light-shielding plate material whose back surface is bonded to the upper surface of the wiring board in the first means, and an opening formed in the light-shielding plate material. Each LED is connected to the upper surface of the wiring board exposed from the hole, and the light-shielding frame is configured from the side wall portion of the opening hole.
However, as the light-shielding plate material, in addition to the resin material, for example, ceramics, glass, or a metal plate having an insulating film can be used.

According to a fourth means of the present invention, in any one of the first to third means, the planar shape of the sealing resin is a fan blade of the above-described light-shielding frame. The sealing resin is surrounded so as to have a shape to be represented.
However, as a shape schematically representing the fan blades, for example, a rhombus, a semi-circle, or a circle may be used.

According to a fifth means of the present invention, in any one of the first to fourth means, the fifth light emitting device is disposed on the entire surface above the n light emitting segments, and masks the contour shape of the light emitting display pattern. A mask sheet material to be formed.
However, this mask sheet material may be obtained by printing or applying a light-shielding paint or resin on a light-transmitting plate material such as a resin film.

The sixth means of the present invention is to form the back surface of the mask sheet material with a reflecting surface made of a reflecting member, a reflecting agent, or a paint having a reflecting action in the fifth means.
However, as the reflecting member, a sputtered or vapor-deposited metal layer or the like may be used.

According to a seventh means of the present invention, in any one of the first to sixth means, the air conditioner has at least two operation modes of cooling, heating, dehumidification, and air blowing. A plurality of types of LEDs having different emission colors are provided in each light emitting segment, and the in-vehicle air volume display device is provided with a light emission color changing means for changing the light emission color of the light emitting segment in accordance with the operation mode. .
However, a mixed color obtained by combining a plurality of emission colors may be adopted as the emission color.

According to an eighth means of the present invention, in any one of the first to seventh means, a flat and translucent colored resin disposed on the entire upper surface of the n light emitting segments, a colored resin It is provided with the translucent member which consists of a film or smoked glass.
However, a light diffusing agent may be mixed or a light diffusing film may be attached to these flat light-transmitting members that cover the display unit of the in-vehicle air volume display device of the present invention.
By the above means of the present invention, the above-mentioned problem can be effectively or rationally solved.

The effects obtained by the above-described means of the present invention are as follows.
That is, according to the first means of the present invention, it is possible to make the fan blades appear to rotate by the rotation of the light emission display pattern by the rotation display means. Further, since the rotation speed becomes a monotonically increasing function of the output air volume of the air conditioner by the rotation speed variable means, the output air volume of the air conditioner is read from the rotation speed of the displayed fan (light emission display pattern). be able to.
Further, the number of stages of the air volume display can be freely set by the rotation speed variable means, and therefore can be arbitrarily set and changed without modifying the display unit.
Further, since the air volume display can be constituted by only the light emitting segments arranged in a rotationally symmetrical manner, only a display area narrower than the conventional display area is required.
Therefore, according to the first means of the present invention, the air volume display device capable of dealing with an arbitrary air volume control stage number can be configured smaller than the conventional one.

  In addition, since each of the light emitting segments blinks periodically, the light emitting load is not concentrated only on a specific light emitting segment, and these light emitting loads are distributed evenly. Therefore, according to the first means of the present invention, there is no variation in the lifetime of each LED and the local deterioration of the resin that covers the display unit, thereby greatly improving the durability as a display device. .

In addition, the LED has a significantly shorter turn-on rise time and turn-off fall time than fluorescent display tubes, liquid crystals, and the like. It does not appear blurry, and the visibility related to the rotation display of the fan is very high.
Further, the light-shielding frame of black or dark color effectively prevents light output from one light-emitting segment from leaking into other adjacent light-emitting segments, and individual light-emitting segments that are emitting light. The outline of the camera will not appear blurred. For this reason, the contrast of each light emitting segment can be maintained sufficiently high.
In addition, the light output intensity from each light emitting segment is made substantially uniform on one light emitting segment by the action of the light diffusing agent, and is effectively reinforced overall by the action of the light reflecting member. Is done. For this reason, the output light from each light emitting segment has sufficiently high luminance without unevenness.
Therefore, according to the first means of the present invention, it is possible to realize air volume display with very high visibility.

  Further, for example, a resin such as silicon or epoxy can be applied easily and with high accuracy using a dispenser or the like. Therefore, according to the second means of the present invention, the above light-shielding frame can be easily and highly accurately applied. Thereby, the shape of each light emitting segment can be formed at low cost and suitably.

  Moreover, according to the 3rd means of this invention, said light-shielding frame can be formed correctly and easily from the side wall part of said opening hole. In addition, if the entire upper surface of the wiring board is uniformly colored in advance with, for example, white paint, the light reflecting member can be configured simply by overlaying and joining the light shielding plate material on the surface. it can.

  Further, according to the fourth means of the present invention, the light-shielding mask sheet material for forming the contour shape of the light-emitting display of the light-emitting segment by masking is not necessarily disposed above the light-emitting segment. The desired shape of the light-emitting segment (the shape of the fan blades) can be formed by the light-shielding frame. However, the fourth means of the present invention does not prevent the introduction of such a mask sheet material (the fifth means of the present invention).

  In addition, since the mask pattern of the mask sheet material can be easily formed with high accuracy by printing or the like, according to the fifth means of the present invention, the outline of the light emitting segment can be easily and accurately formed into a desired shape. Can be formed.

  Further, according to the sixth means of the present invention, the light hitting the reflective surface on the back surface of the masking portion of the mask sheet material is not absorbed by the mask sheet material, and the light is applied to the sealing resin. Therefore, the light extraction efficiency is improved.

Further, according to the seventh means of the present invention, since the operation mode of the currently operating air conditioner can be visually recognized by the color display by the emission color of the light emitting segment, the discrimination performance with respect to the operation mode is improved. Thus, the convenience in operating the air conditioner is improved.
For example, by setting the light emission color of each light-emitting segment constituting the fan to a cold color during cooling and a warm color during heating, the operation status can be effectively appealed to the driver's feeling. That is, according to the seventh means of the present invention, the operation mode of the air conditioner can be sensibly recognized by the driver or the like, so that the driver or passenger can easily determine the operating state of the air conditioner. Since it can be recognized, the convenience of the air conditioning operation is improved.

  Further, according to the eighth means of the present invention, since the incident light from the outside hardly hits the light diffusing agent mixed in the sealing resin, the light emitting display pattern becomes difficult to see due to the irregular reflection of the incident light from the outside. This eliminates the problem and improves the visibility of the desired light-emitting display pattern.

  In addition, it is more desirable that the bottom surface and the side surface of the sealing resin are formed of a reflective surface such as a metal layer or a paint or a reflective material such as a reflective agent. Thereby, the light extraction efficiency of each light emitting segment can be further improved.

Hereinafter, the present invention will be described based on specific examples.
However, the embodiments of the present invention are not limited to the following examples.

  The front view of the display panel 200 of the vehicle-mounted air conditioner of Example 1 is shown in FIG. The rightmost triple 7 segment (88.8) of the display panel 200 is a display area indicating the air conditioning set temperature of the driver's seat, and the leftmost triple 7 segment (88.8) is the rear seat. It is a display area which shows air-conditioning preset temperature. The central two-segment 7 segment (88) is a display area indicating the outside air temperature. An air volume display unit 100 is provided on the left side of the outside air temperature display area.

FIG. 2 is a front view (enlarged view) of the air volume display unit 100 of the display panel 200 described above. The air volume display unit 100 is composed of four light emitting segments 100A, 100B, 100C, and 100D, and the contour shape of each light emitting segment is congruent with each other in a shape reminiscent of the shape of a rotating fan blade. Is formed. Further, their arrangement is arranged in a rotationally symmetric shape of 90 ° around one rotational symmetry point P ₀ .

FIG. 3A shows a plan view of a light emitting segment 100A which is one of the above four light emitting segments. This plan view (FIG. 3-A) shows a state before each LED (120r, 120g, 120b) is sealed with a sealing resin. On the upper surface of the wiring substrate 110 made of glass epoxy material, a planar n-side lead electrode 111A having a large area made of a plated metal layer having a multilayer structure in which a gold (Au) layer is laminated on a copper (Cu) layer; An island-shaped p-side lead electrode 112 having a smaller area is patterned. The bonding wire 132 connects the n-electrode of the LED and the n-side lead electrode 111A, and the bonding wire 133 connects the p-electrode of the LED and the p-side lead electrode 112.
These lead electrodes (111A, 112) act both as a light reflecting member and a metal plate for heat dissipation. In particular, since the lead electrode 111A effectively performs both light reflection and heat dissipation, it is desirable that the lead electrode 111A be formed as wide as possible. On the wiring board 110 having these lead electrodes, a light-shielding frame 140 made of a black silicon resin having a band width of about 0.8 mm and a height of about 2.4 mm is formed in an annular shape. . The planar shape of the light shielding frame 140 schematically represents the contour shape of one fan blade.

FIG. 3B shows the positional relationship between the LEDs of the light emitting segment 100A. The light emitting segment 100A includes three red light emitting LEDs 120r, three green light emitting LEDs 120g, and three blue light emitting LEDs 120b. These nine primary color light emitting LEDs are arranged in a grid pattern. It is arranged. Among them, the red light emitting LEDs 120r are arranged on a diagonal line, and the upper left LED 120r and the central LED 120r are connected in series by the bonding wire 134 in the same direction. Hereinafter, this series connection is referred to as a series connection 125r.
Further, two green light emitting LEDs 120g arranged in the same direction as the above diagonal line form a series connection of two series in the same direction (hereinafter referred to as LED 125g) via a bonding wire 134. The two blue light emitting LEDs 120b arranged in the same direction as the diagonal line form a series connection of two series in the same direction (hereinafter referred to as LED 125b) via the bonding wire 134. In addition, the remaining single LEDs (LED 120r, LED 120g, and LED 120b) that do not constitute these series connections are respectively arranged at three corners (three corners) of a grid-like arrangement.

FIG. 4 is a cross-sectional view of the light emitting segment 100A taken along the line AA ′. This sectional view shows a state before the assembly, and after the assembly, the mask sheet material 170 and the colored resin 180 which is a translucent member are sequentially bonded onto the light emitting segment 100A. .
The colored resin 180 is made of a colored acrylic plate. The mask sheet material 170 is obtained by printing a black silicon resin 172 on a light-transmitting film 171 having a thickness of 0.2 mm. The silicon resin 172 of the mask sheet material 170 is arranged so as to cover the light-shielding frame 140, and the contour shape of the light emitting segment 100A in FIG. 2 is formed by masking with the mask sheet material 170. . That is, the shape of the window frame 172a constituted by the inner edge of the silicon resin 172 is the contour shape of the light emitting segment 100A shown in FIG. The metal coating 173 made of aluminum (Al) deposited on the back surface of the translucent film 171 is for reflecting the light emitted from the LED downward. The metal coating 173 can be alternatively formed by, for example, applying a reflective paint, but in order to greatly clarify the luminance difference of the light emitting segment 100A between when the LED is turned on and when the LED is turned off. For this, it is desirable not to use a fluorescent agent.

The light-shielding frame 140 is formed on the wiring substrate 110 using a dispenser and then cured to form the light-shielding frame 140 on the side wall surface of the light-shielding frame 140 on the side in contact with the sealing resin 160. Is coated with a reflective material 141. The sealing resin 160 that seals the LED 120r while filling the frame of the light-shielding frame 140 is made of translucent silicon. The sealing resin 160 includes, for example, silica (SiO ₂ ) or oxidized Light diffuser particles made of titanium (TiO _x ) or the like are mixed therein. The colored resin 180 is colored in order to effectively prevent or alleviate the incidence of light from the outside on the particles of the light diffuser.

  The back surface of the red LED 120r is temporarily fixed to the upper surface of the lead electrode 111A with a silver paste 131. The n electrode of the LED 120r is electrically connected to the lead electrode 111A by a bonding wire 132. The p electrode is electrically connected to the lead electrode 112 by a bonding wire 133. Further, the lead electrode 112 is connected to a wiring pattern 154 </ b> A laminated on the back surface of the wiring substrate 110 through a filling metal 114 filled in a through hole 110 c formed in the wiring substrate 110. The wiring pattern 154A is formed from a plated metal layer having a multilayer structure in which a gold (Au) layer is stacked on a copper (Cu) layer. The exposed surface and a part of the back surface 110b of the wiring substrate 110 are formed on each part. An insulating film 116 made of silicon is formed. The insulating film 116 is for preventing a short circuit related to the wiring pattern 154A. However, since there is a region in direct contact with the sealing resin 160 on the upper surface 110a of the wiring substrate 110, the insulating film 116 is directed upward. It is more desirable to make it white considering the light reflection effect.

  Each of the wiring patterns 151A, 152A, 153A, 155A, and 156A in FIG. 3A is also a connection point where a line from each lead electrode 112 is drawn on the back surface 110b through the through hole 110c. The wiring pattern 154A or the wiring pattern 150A is pulled out from the upper surface 110a of the wiring board 110 onto the back surface 110b in a wiring form substantially similar to the wiring pattern 154A or the wiring pattern 150A.

The structure related to the light emitting segment 100A is the same as that of the light emitting segments 100B to 100D in FIG.
In FIG. 3A, the resin film 113 in FIG. 4 is omitted for the sake of understanding. However, the resin film 113 in FIG. Screen-printed in the peripheral area outside the frame. Such a black resin film 113 is formed over the entire region outside the frame of the light-shielding frame 140 because the incident light from the outside causes the upper surface 110a of the wiring board 110 or each lead electrode (111A, 112) in the region outside the frame. ) To reach the upper surface and be reflected again to the outside, which can also increase the contrast of the light emitting segment 100A.

FIG. 5 shows a circuit diagram of the in-vehicle air volume display device 300 according to the first embodiment having the air volume display unit 100 described above. The control circuit 320 includes a light emitting color selection means 321 for determining the luminance and light emission color of each light emitting segment 100a-d, 2 a fan (light-emitting display pattern) represented by them, symmetric point P ₀ in Fig. 3-A Rotation display means 322 for rotating around and rotation speed variable means 323 for calculating the rotation speed. The input information input to the control circuit 320 includes two types of information, that is, operation mode information M and output air volume information Q obtained from an on-vehicle air conditioner. The operation mode information M indicates one of four operation modes of cooling, heating, dehumidification, and air blowing, and is input to the emission color selection unit 321. The output air volume information Q is input to the rotation speed variable means 323.

The light emitting circuit of FIG. 5 is configured using each LED of FIG. 3-B included in the air volume display unit 100, and each LED of FIG. 3-B provided in each of the light emitting segments 100A to D of FIG. Are arranged over a total of four rows. That is, for example, each light emitting diode in the first row from the top corresponds to each LED in FIG. 3-B provided in the light emitting segment 100A. However, the above-described series connection 125r configured by series connection of two series LED 120r is collectively illustrated by a symbol of one light emitting diode. The same applies to the serial connections 125g and 125b.
Then, as described below with reference to FIG. 5, according to the control method of the in-vehicle air volume display device 300, the light emission display (emission color, emission luminance, and The rotational speed of the fan can be freely controlled.

The electrode pad 150A in FIG. 5 means the wiring pattern 150A in FIG. However, the electrode pad 150A may be formed wider by further expanding the wiring pattern 150A on the back surface 110b of the wiring substrate 110 shown in FIG. The electrode pad 151 connected to the wiring pattern 151A in FIG. 3A is connected to the emitter terminal of the NPN transistor 301, and the collector terminal of the transistor 301 is connected to the positive electrode of the DC power supply 330 via the resistor R1. It is connected. The electrode pad 150 </ b> A is connected to the collector terminal of the NPN transistor 311, and the emitter terminal of the transistor 311 is connected to the grounded negative electrode of the DC power supply 330.
The voltage of the base terminal of the transistor 301 is voltage controlled (ON / OFF control) by the light emission color selection means 321 included in the control circuit 320, and the voltage of the base terminal of the transistor 311 is controlled by the rotation display means 322 included in the control circuit 320. Voltage control (ON / OFF control) is performed. Further, the rotation speed ω of the light emission display pattern displayed by the rotation display unit 322 is calculated by the rotation speed variable unit 323 included in the control circuit 320 so as to monotonously increase with respect to the air volume represented by the output air volume information Q. The

Therefore, the ON / OFF state of the light emitting diodes (125r, 125g, 125b, 120r, 120g, 120b) in the first row corresponding to the light emitting segment 100A can be controlled by the base voltage of the transistor 311. The ON / OFF state of the light emitting diodes in the column can be controlled by the base voltage of the transistor 301. Therefore, for example, the series connection 125r of FIG. 3-B included in the light emitting segment 100A can be turned on only when the base voltages of both the transistor 301 and the transistor 311 are controlled to be in the ON state. Further, for example, the single LED 120r at the lower right in FIG. 3B included in the light emitting segment 100A can be turned on only when the base voltages of both the transistor 304 and the transistor 311 are controlled to be in the ON state. Therefore, for example, when the base voltage of the transistor 311 is in an ON state, the red LED 120r can emit any number of 0 to 3 LEDs by controlling the base voltages of the transistor 301 and the transistor 304.
The same applies to the light emitting diodes (LEDs 120r, 120g, 120b, serial connection 125r, 125g, 125b) in the other rows and columns, respectively, depending on the base voltages of the transistors 301 to 306 and the transistors 311 to 314, respectively. The ON / OFF state (lighting / extinguishing state) can be arbitrarily controlled.

At this time, the light emission state of each light emitting segment unit can be changed in ²⁶ ways by each of the ON / OFF operations of the six transistors 301 to 306. Therefore, if the brightness level is taken into account, the light extinction state is excluded. 63 different emission colors can be realized. Then, for example, by cyclically changing the base voltages of the transistors 311 to 314 based on the control operation of the rotation display unit 322, the row to be turned on is selected cyclically and sequentially, and the rotation speed variable unit 323 is used. If the change period is set to about 0.1 to 10 Hz, the fan figure (the air volume shown in FIGS. 1 and 2) depends on an arbitrary display color set (selection controlled) according to the actual operation mode in which the air conditioner operates. The light emission display by the display unit 100 can be rotated at a desired rotation speed (ω = 0.1 to 10 rotations / second).

Therefore, according to the above configuration, the display area of the in-vehicle air volume display device is rationally reduced (miniaturized), and at the same time, the expandability, visibility, and durability of the in-vehicle air volume display device are improved. Can be made.
The light emission color selection means 321, the rotation display means 322, and the rotation speed variable means 323 can also be configured by software (base voltage control program) for operating a computer.

  FIG. 6 shows a cross-sectional view of the light emitting segment 101 of the second embodiment. That is, FIG. 6 is a cross-sectional view of the light emitting segment 101 of Example 2 in which the light emitting segment 100A of Example 1 is slightly modified. Among the reference numerals in FIG. 6, the same reference numerals as those in FIG. 4 indicate the same parts as those in FIG. For example, the metal layer 111 in FIG. 6 is formed in the same manner as the lead electrode 111A in FIG. 4, and the sealing resin 160 made of translucent silicon filled thereon seals the LED 120. Yes.

In particular, in the light emitting segment 101 of the second embodiment, the filling region of the sealing resin 160 is formed from the internal space of the through hole 162 formed in the flat resin base material 145. That is, the wing-shaped region that emits light of the light emitting segments 100 </ b> A to 100 </ b> D in FIG. 2 becomes the through-hole 162, and the region other than the region is configured by the thick portion of the base material 145. A reflective agent 141 is applied to the inner wall surface 162 a of the through hole 162. This base material 145 is bonded to the upper surface 110 a of the wiring board 110. As a result, the bottom surface of the filling region is constituted by the upper surface 110 a of the wiring substrate 110. Further, the base material 145 constituting the side wall portion of the through-hole 162 constitutes a light-shielding frame body that encloses the sealing resin 160 from the side. And the black silicon resin 172 printed on the translucent film 171 which is the mask sheet material 170 is arrange | positioned at the upper part of the thick part of the base material 145. FIG. With this configuration, the contour shape of the light emitting segment 100 </ b> A in FIG. 2 is determined by the thick portion of the substrate 145 and the black silicon resin 172.
In this way, the light-shielding frame that surrounds the sealing resin 160 from the side can also be realized by a drilling process on the base material 145.

In addition to the mask sheet material 170, the light emitting segment 101 of Example 2 is further provided with a colored resin 180, which is a translucent member, in the same manner as the light emitting segment 100A (FIG. 4) of Example 1 above. You may arrange | position on the mask sheet material 170. FIG.
In addition, the LED 120 in FIG. 6 is obtained by crystal-growing a semiconductor layer 122 including a light emitting layer on a thick sapphire substrate 121. If such a thick sapphire substrate 121 is used, the LED 120 in the lateral direction is used. Therefore, the light emitting segment 101 can emit light evenly by mixing an appropriate amount of the light diffusing agent with respect to the sealing resin 160, an optimal distribution, or the like.

[Other variations]
The embodiment of the present invention is not limited to the above-described embodiment, and other modifications as exemplified below may be made. Even with such modifications and applications, the effects of the present invention can be obtained based on the functions of the present invention.
(Modification 1)
For example, in Example 1 described above, three types of LEDs (LED 120r, LED 120g, and LED 120b) that emit light with the three primary colors of light are used. For example, a Group III nitride compound described in Japanese Patent No. 376754 You may make it the structure which uses LED which changes luminescent color according to the change of an applied voltage like a semiconductor light-emitting device. In this case, the light emission colors of the individual light-emitting segments 100A to 100D can be simultaneously controlled by voltage control related to the air volume display unit 100 (light-emitting segments 100A to 100D) configured using only one same type of LED. Can be variably controlled. Therefore, according to such an applied voltage switching method, the number of voltage stages equal to the number of types of color display (operation mode) to be switched is provided, and the light emitting segments 100A to 100D are simply controlled by switching the applied voltages. The luminescent color can be arbitrarily controlled. Also in these cases, the rotation speed of the fan can be variably controlled using the same means as the rotation display means 322 and the rotation speed variable means 323 in FIG.

(Modification 2)
Further, although the output air volume information Q is not input to the emission color selection unit 321 in FIG. 5, the output air volume information Q may be used for the emission color selection process in the emission color selection unit 321. . For example, when the output air volume is large, the rotation speed of the fan (light emitting display pattern) can be increased and the luminance of the light emitting segment to be lighted can be increased at the same time. It is possible to effectively appeal the operating state of the air conditioner being used to the sense of the user.

The front view of the display panel 200 of the vehicle-mounted air conditioner of Example 1. FIG. The front view of the air volume display part 100 of the display panel 200. FIG. The top view of 100 A of light emission segments which comprise the air volume display part 100. FIG. The top view which shows the positional relationship of each LED of the light emission segment 100A. FIG. 3 is a cross-sectional view of a light emitting segment 100A constituting the air volume display unit 100. The circuit diagram of the vehicle-mounted air volume display apparatus 300 which has the air volume display part 100. FIG. Sectional drawing of the light emitting segment 101 of Example 2. FIG. The front view of the display panel 20 of the conventional vehicle air conditioner.

Explanation of symbols

100: Air volume display unit 100A: Light emitting segment 111: Light reflecting member (n-side lead electrode)
112: Light reflecting member (p-side lead electrode)
120r: LED emitting red light
120g: Green LED
120b: LED emitting blue light
140: light-shielding frame 160: sealing resin 180: colored resin 200: display panel 300: in-vehicle air volume display device 320: control circuit 321: luminescent color selection means 322: rotation display means 323: rotation speed variable means

Claims (8)

In the air volume display device that displays the output air volume of an in-vehicle air conditioner by lighting display of n (n ≧ 3) light emitting segments arranged in a rotationally symmetrical manner,
Rotation display means for rotating a light-emitting display pattern constituted by turning on or off each of the n light-emitting segments around the symmetry point of the rotational symmetry, and a rotation speed whose rotation speed is a monotonically increasing function of the output air volume Variable means,
Each said light emitting segment is
LED blinking controlled by the rotation display means;
A wiring board having metal wiring to which the LED is connected;
A sealing resin mixed with a light diffusing agent to seal the LED;
A black or dark shade frame surrounding the sealing resin from the side;
An in-vehicle air volume display device comprising: the LED and a light reflecting member disposed on a bottom portion of the sealing resin.   The in-vehicle air volume display device according to claim 1, wherein the light-shielding frame is formed of a resin that is applied to an upper surface of the wiring board and cured in a partition shape. Having a black or dark shading plate bonded to the upper surface of the wiring board on the back surface;
The LED is connected to the upper surface of the wiring board exposed from an opening hole formed in the light-shielding plate.
The in-vehicle air volume display device according to claim 1, wherein the light-shielding frame is configured by a side wall portion of the opening hole.   The said light-shielding frame is surrounding the said sealing resin so that the planar shape of the said sealing resin may become the shape which represents typically the blade | wing of a fan. The vehicle-mounted air volume display device according to any one of the above.   5. The mask sheet material according to claim 1, further comprising a mask sheet material that is disposed on the entire upper surface of the n light emitting segments and forms a contour shape of the light emitting display pattern by masking. The on-vehicle air volume display device described.   6. The in-vehicle air volume display device according to claim 5, wherein a back surface of a portion of the mask sheet material to be masked is formed by a reflecting surface made of a reflecting member, a reflecting agent, or a paint having a reflecting action.   The air conditioner has at least two or more types of operation modes of cooling, heating, dehumidification, and air blowing, each light-emitting segment has a plurality of types of LEDs having different light emission colors, and the in-vehicle air volume display The in-vehicle air volume display device according to any one of claims 1 to 6, wherein the device includes a light emission color changing unit that changes a light emission color of the light emission segment according to the operation mode.   8. A translucent member made of a flat, translucent colored resin, a colored film, or smoked glass disposed on the entire upper surface of the n light emitting segments. The in-vehicle air volume display device according to any one of the above.

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