JP5822320B2 - projector - Google Patents

Description

  The present invention relates to a projector, and more particularly to a projector provided with a fan for cooling a power supply unit.

  As disclosed in Japanese Patent Application Laid-Open No. 2011-76071, there is a projector provided with a fan for cooling the inside.

  As a projector provided with a fan, an exhaust fan for cooling the power supply unit is arranged on the side surface on the side where the power supply unit is arranged, and a cooling intake hole is provided on the side surface facing the exhaust fan. is there.

  As a structure to provide the cooling intake holes other than the side facing the exhaust fan, a structure in which the cooling intake holes are provided in the bottom surface, or a structure in which the cooling intake holes are provided in the side surface orthogonal to the side surface in which the exhaust fan is provided. Is mentioned.

JP 2011-76071 A

  The structure in which the exhaust fan is arranged on one side and the cooling intake hole is provided on the opposite surface has the following problems.

  The first problem is that the power supply unit and the cooling intake hole are spaced apart. For this reason, the power supply unit is cooled by air whose temperature is higher than the outside air temperature in the device. Therefore, it is necessary to increase the rotation speed of the exhaust fan, increase the air volume, and cool the noise. Is to grow.

  The second problem is that the power consumption is increased by increasing the rotational speed of the exhaust fan.

  The third problem is that when the projector is installed so that the side with the cooling air intake hole is close to the wall, etc., the cooling air intake hole is blocked, resulting in insufficient cooling, and the projector is safe. Does not work.

  In the structure in which the cooling air intake holes are provided on the bottom surface of the projector, if a soft cloth or the like is laid on the projector installation surface, the cooling air intake holes on the bottom surface will be blocked and the projector will not operate safely. It was.

  In the case of a structure in which a cooling intake hole is provided on the side surface orthogonal to the side surface on which the exhaust fan is provided, the cooling efficiency is improved because the intake hole is provided on the surface orthogonal to the flow of air by the exhaust fan. It became worse and it was necessary to increase the rotation speed of the exhaust fan and increase the air volume to cool it. As a result, there is a problem that noise and power consumption increase. Also, when installing the projector, if the projector is installed so that the side where the cooling air intake holes are provided is close to the wall, etc., the cooling air intake holes are blocked and the projector does not operate safely. .

  As described above, depending on the location of the side surface where the cooling intake holes are provided and the way of installation, there are problems in cooling, which may cause problems in noise and power consumption.

  Besides cooling, various problems arise due to the arrangement of the components. For example, the image light projected from the lens unit including the projection lens is naturally projected so as not to cause interference due to the power supply unit or an internal component for cooling the power supply unit. For this reason, when it is set as the structure where the highest part of a power supply unit or other internal components is arrange | positioned higher than the highest part of a lens part, let projection angle be an angle from which a projection light is not shielded by a power supply unit or other internal components. It is necessary to increase the dimensions of the projector installation surface and the projection screen highest part. As a result, there is a problem that the degree of freedom of the installation height of the projector is lowered.

  The present invention realizes a projector having a structure capable of efficiently performing cooling and having a high degree of freedom in the installation height of the projector.

The projector according to the present invention includes a convex portion that protrudes toward the outside of the housing formed in the lower case forming the housing,
A power supply unit housed in the convex part;
An exhaust fan formed on the first side surface of the convex portion;
And an air hole for cooling the power supply unit formed on the second side surface of the convex portion facing the first side surface.

  The present invention having the above configuration realizes a projector that can efficiently perform cooling and has a structure with a high degree of freedom in the installation height of the projector.

It is the perspective view which looked at one Embodiment of the projector by this invention from the bottom face. It is a perspective view which shows the positional relationship of an optical engine unit and a power supply unit. It is a perspective view which shows the positional relationship of the power supply unit and exhaust fan inside a projector. It is a side view which shows a projector and a projection screen position. It is a side view which shows a projector and a projection screen position.

  Next, embodiments of the present invention will be described with reference to the drawings. 1 is a perspective view of an embodiment of a projector according to the present invention as seen from the bottom, FIG. 2 is a perspective view showing a positional relationship between an optical engine unit and a power supply unit, and FIG. 3 is a positional relationship between a power supply and an exhaust fan inside the projector. It is a perspective view shown.

  Embodiments of the present invention will be described with reference to FIGS.

  As shown in FIG. 1, the housing of the projector 1 is configured by combining a lower case 21 and an upper case 22. A part of the lower case 21 is provided with a convex portion 6 that protrudes toward the outside of the housing. An air hole 9 for power supply cooling is formed in the convex vertical surface 10 which is one side surface of the convex part 6.

  As shown in FIG. 2, an optical engine unit 2, a light source unit 3, a projection optical unit 4, and a power supply unit 5 are mounted on the lower case 21. Here, the projection optical unit includes a lens unit 4a and a mirror unit 4b. Further, the optical engine unit 2, the light source unit 3, and the projection optical unit 4 are in a so-called L-shaped arrangement. The power supply unit 5 is arranged in an empty part of the L-shaped arrangement. The light generated by the light source unit 3 is converted into image light by the optical engine unit 2 and projected through the lens unit 4a and the mirror unit 4b in order.

  The power supply unit 5 is mounted in a form accommodated in the above-described convex portion 6, and is arranged so that the exhaust surface 8 of the power supply cooling exhaust fan 7 is in contact with the side surfaces of the convex portion 6 and the lower case 21. A power cooling air hole 9 is formed on the side surface of the convex portion 6 (the convex vertical surface 10 shown in FIG. 1) facing the exhaust surface 8.

  The cooling mechanism in the projector of the present embodiment configured as described above will be described with reference to FIG. 3 showing the positional relationship between the power supply unit and the exhaust fan.

  Air that cools the power supply unit 5 accommodated in the convex portion 6 enters the casing through the power cooling air hole 9 formed in the convex vertical surface 10 of the convex portion 6, and is supplied by the power cooling exhaust fan 8. It is discharged from the exhaust surface 8 to the outside of the housing.

  By providing the convex portion 6 on the lower case 21 and arranging the power supply unit 5, the power supply cooling air hole 9 can be provided in the vicinity of the power supply unit 5. Thereby, the temperature of the outside air introduced from the outside of the casing does not rise in the casing, and the power supply unit 5 can be cooled by lower cooling air. For this reason, the rotation speed of the exhaust fan 7 for cooling the power supply can be reduced as compared with the prior art, and noise and power consumption can be reduced.

  In addition, by providing the convex portion 6 in the lower case 21, the power cooling air hole 9 can be provided in the convex vertical surface 10 facing the side surface on which the power cooling exhaust fan 7 is provided. As a result, the opening area of the power cooling air hole 9 becomes larger than the flow direction of the wind by the power cooling exhaust fan 7, so that the cooling efficiency is improved. This also makes it possible to reduce the rotational speed of the power supply cooling exhaust fan 7, thereby reducing noise and reducing power consumption.

  Further, by providing the power cooling air hole 9 on the convex vertical surface 10 of the convex part 6 on the inner side of the projector outer shape, the power cooling air hole 9 is not blocked by the installation conditions of the projector. Stable cooling is always performed.

  4 and 5 are side views showing the projector and the projection screen position.

  In this embodiment, since the power supply unit 5 is accommodated in the convex part 6, it will be arrange | positioned in the position lower than the position where the projection optical part 4 is arrange | positioned. As a result, as shown in FIG. 4, the highest part of the power supply unit 5 or other internal components can be positioned lower than the highest part of the projection optical part 4. As a result, in the projector according to this embodiment in which the projection light is reflected by a mirror or the like inside the projector, the projection angle 11 from the installation surface 12 and the projection screen maximum portion 13 are determined by the height of the projection optical unit 4 itself. Will be.

  Incidentally, as shown in FIG. 5, when the power supply unit 5 or other internal components are higher than the projection optical unit 4, the projection angle 11 from the installation surface 12 is avoided in order to prevent the projected image light from interfering. The projection screen highest portion 13 is determined by the height of the highest portion of the power supply unit 5 or other internal components. As a result, the projection angle 11 and the projection screen highest portion 13 must be large. The position of the projection screen can only be set above a certain height from the projector installation position. Therefore, if the projection angle 11 and the projection screen highest portion 13 are large, the position of the projection screen is limited. In other words, the projection angle 11 and the projection screen highest part 13 determine the degree of freedom of the installation height of the projector. As described above, in the projector according to the present embodiment, the projection angle 11 from the installation surface 12 and the projection screen maximum portion 13 are determined by the height of the projection optical unit 4 itself. The degree becomes higher.

DESCRIPTION OF SYMBOLS 1 Projector 2 Optical engine unit 3 Light source part 4 Projection optical part 5 Power supply unit 6 Convex part 7 Exhaust fan for power cooling 8 Exhaust surface 9 Air hole for power cooling 10 Convex part vertical surface 21 Lower case 22 Upper case

Claims (2)

A convex portion protruding toward the outside of the housing formed in the lower case forming the housing;
A power supply unit housed in the convex part;
An exhaust fan formed on the first side surface of the convex portion;
An air hole for cooling the power supply unit formed on the second side surface of the convex portion facing the first side surface. The projector according to claim 1.
A projector, wherein a highest part of a projection optical unit that projects image light is higher than a highest part of the power supply unit.

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