JP4412010B2 - Projection display - Google Patents

Description

  The present invention relates to a projection display device.

There is a projection display device (projector) that forms an image by projecting a light beam on a screen. Such a projection-type display device emits a light source, an optical system that separates a light beam emitted from the light source into a plurality of light beams having different wavelengths, and combines each separated light beam into one light beam for image formation. Image forming means, an optical system, and a housing for housing the image forming means.
The optical system includes an optical member that is arranged so as to intersect with the optical path of the optical system, has a length along the intersecting direction, and has different optical characteristics along the length direction. Configured. For example, a dichroic mirror with a wedge is used as such an optical member, and the dichroic mirror with a wedge is formed so that the wavelength characteristics (reflection characteristics and transmission characteristics) change along the length direction.
A dichroic mirror separates a light beam into light beams having different wavelengths.If the light beam incident on the dichroic mirror is not a light beam parallel to the optical path of the optical system, the light beam is positioned along the surface of the dichroic mirror. Therefore, the angle formed with the optical path is different. A dichroic mirror with a wedge is used in order to obtain an appropriate wavelength characteristic regardless of the change in the angle between the light beam and the optical path.
By the way, the dielectric multilayer film in the dichroic mirror has a wavelength characteristic, that is, a variation in 50% wavelength tolerance of reflectance or transmittance, or the light source has a variation in light flux amount and wavelength characteristic. As a result, the brightness of the color image formed on the screen, in other words, brightness, color purity, and white balance are also affected and vary.
In order to avoid such an influence, the wavelength characteristic of the dichroic mirror with a wedge may be adjusted so as to shift to the long wavelength side or the short wavelength side. Specifically, it is necessary to move the dichroic mirror along the length direction while maintaining the angle θ formed by the dichroic mirror and the optical path.
When such a dichroic mirror is adjusted in position relative to the optical path and attached to the housing, for example, using a dedicated jig or equipment, the position along the optical path direction of the dichroic mirror is maintained and orthogonal to the optical path. In this state, the dichroic mirror is fixed to the housing (see, for example, Patent Document 1).
JP 2002-23262 A

However, the prior art requires a jig and equipment for positioning the dichroic mirror, which is costly. In addition, the projection display device is attached to or detached from a dedicated jig or equipment. This is disadvantageous in improving the efficiency of the adjustment work.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a projection display that is advantageous in reducing the cost and improving the efficiency of position adjustment work of optical members having different optical characteristics along the length direction. To provide an apparatus.

In order to achieve the above object, a projection display apparatus according to the present invention includes a light source, an optical system that separates a light beam emitted from the light source into a plurality of light beams having different wavelengths, and the separated light beams for image formation. A projection-type display device comprising: an image forming unit that synthesizes and emits the light beam; and a housing that houses the optical system and the image forming unit. The optical system is disposed on an optical path formed by the optical system. And an optical member having a length along the intersecting direction and having different optical characteristics along the length direction, and the housing is formed in an open shape upward. There are two groove portions into which both ends in the length direction of the optical member are inserted, and each groove portion is parallel to the crossing direction and a positioning surface facing each other with a gap larger than the length of the optical member. In the direction to An abutting surface capable of contacting the surface of the optical member extending in a direction parallel to the length direction of the optical member, and a surface of the optical member elastically contacting the optical member inserted into the groove. A spring member that is urged in a direction to be applied to the abutting surface, and is further inserted into one of the groove portions in a state where both ends in the length direction of the optical member are inserted into the two groove portions. An insertion member that abuts one end surface in the length direction of the optical member and abuts the other end surface in the length direction of the optical member to the positioning surface of the other groove portion, and the insertion member is inserted into the groove portion Fixing means for fixing the insertion member in a state is provided.
Further, in the projection type display device of the present invention, the housing includes a base that divides a bottom portion and left and right side portions of the optical path, and a cover that is attached to the base and divides an upper portion of the optical path, and the groove portion includes An opening is formed in the base, and an opening for inserting the insertion member into the groove is formed in the cover.

According to the projection type display device of the present invention, when adjusting the optical member, the state in which the surface of the optical member is applied to the application surface of the groove portion of the housing is held by the spring member, so that the optical system is maintained. The angle of the optical member with respect to the optical path of the optical member is maintained, and by inserting the insertion member into one of the two grooves, the optical member is moved in a direction intersecting the optical path so that the end surface in the length direction of the optical member is the groove of the housing. It can be moved to a position in contact with the positioning surface.
Therefore, when adjusting the position of the optical member in the length direction, there is no need for a dedicated jig or equipment, which is advantageous in reducing the manufacturing cost, and the projection display device is attached to the dedicated jig or equipment. This is advantageous in improving the efficiency of the adjustment work because it does not take time and effort to remove and remove.
Furthermore, according to the projection type display device of the present invention, when adjusting the optical member, the luminance of the color image formed on the screen in a state where the housing is covered with the cover and is not affected by the outside. Further, since color purity and white balance can be adjusted, more reliable adjustment can be performed. Further, when adjustment is required for service such as repair, adjustment work can be easily performed from the outside of the housing.

  The purpose of reducing the cost and improving the efficiency of the position adjustment operation in the longitudinal direction of the optical member is applied by the spring member to the housing side abutting surface provided on the housing. Realized by attaching.

Embodiments of a projection display device according to the present invention will be described below in detail with reference to the drawings.
First, an outline of the optical system of the projection display device will be described.
FIG. 1 is a configuration diagram of an optical system of a projection display apparatus according to Embodiment 1 of the present invention.

The optical system 10 of the projection display apparatus 100 includes a light source 12, an illumination optical system 14, a color separation optical system 16, a relay optical system 18, three liquid crystal panels 20, a cross dichroic prism 22, and a projection lens 24.
White light emitted from the light source 12 is guided to the color separation optical system 16 and the relay optical system 18 by the illumination optical system 14, and red (R), green (G), and blue by the color separation optical system 16 and the relay optical system 18. (B) are separated into three color light fluxes, and the three color light fluxes correspond to the three liquid crystal panels 20 (3) for displaying the corresponding three color image information of red (R), green (G), and blue (B), respectively. 20R, 20G, and 20B), and then combined into one light beam by the cross dichroic prism 22 and projected as a color image on the screen via the projection lens 24. In this embodiment, the three liquid crystal panels 20 and the cross dichroic prism 22 constitute the image forming means as claimed.

More specifically, the illumination optical system 14 includes a concave lens 1402, a UV cut filter 1404, first and second fly-eye lenses 1406 and 1408, a PS conversion element 1410, and a condenser lens 1412, which are arranged in this order. The light beam from 12 passes through these and enters the color separation optical system 16. For convenience of explanation, the optical path of the optical system 10 from the light source 12 to the color separation optical system 16 is referred to as a first optical path 10A. The condenser lens 1412 is disposed in a direction intersecting the first optical path 10A, and is disposed at 90 degrees in this embodiment.
The color separation optical system 16 includes a blue dichroic mirror 1602 that reflects a blue light beam and transmits green and red light beams, and a red dichroic mirror 1604 that reflects a green light beam and transmits a red light beam. is doing. These two dichroic mirrors 1602 and 1604 are disposed in a direction intersecting the first optical path 10A, and are disposed at 45 degrees in this embodiment.
Of the light beams emitted from the illumination optical system 14, when the blue light beam is reflected by the dichroic mirror 1602, it passes through the liquid crystal panel 20 </ b> B via the UV absorption filter 1606, the total reflection mirror 1608, and the condenser lens 1610, and the cross dichroic prism 22. To. For convenience of explanation, the optical path of the optical system 10 from the dichroic mirror 1602 to the total reflection mirror 1608 is referred to as a second optical path 10B, and the optical path of the optical system 10 from the total reflection mirror 1608 to the cross dichroic prism 22 is referred to as a third optical path 10C. In the present embodiment, the first optical path 10A and the second optical path 10B are orthogonal, and the second optical path 10B and the third optical path 10C are also orthogonal.

Of the light beams transmitted through the blue dichroic mirror 1602, when the green light beam is reflected by the red dichroic mirror 1604, it passes through the liquid crystal panel 20 G via the condenser lens 1610 and reaches the cross dichroic prism 22. For convenience of explanation, the optical path of the optical system 10 from the dichroic mirror 1602 to the dichroic mirror 1604 is referred to as a fourth optical path 10D, and the optical path of the optical system 10 from the dichroic mirror 1604 to the cross dichroic prism 22 is referred to as a fifth optical path 10E. In the present embodiment, the first optical path 10A and the fourth optical path 10D are located on the same axis, and the fourth optical path 10D and the fifth optical path 10E are orthogonal to each other.
Of the light beams that have passed through the blue dichroic mirror 1602, when the red light beam passes through the red dichroic mirror 1604, the first relay lens 1802, the total reflection mirror 1804, and the second relay lens 1806 that constitute the relay optical system 18. The total reflection mirror 1808 passes through the liquid crystal panel 20R via the condenser lens 1610 and reaches the cross dichroic prism 22. For convenience of explanation, the optical path of the optical system 10 from the dichroic mirror 1604 to the total reflection mirror 1804 is referred to as a sixth optical path 10F, and the optical path of the optical system 10 from the total reflection mirror 1804 to the total reflection mirror 1808 is referred to as a seventh optical path 10G. The optical path of the optical system 10 from the total reflection mirror 1808 to the cross dichroic prism 22 is referred to as an eighth optical path 10H. In the present embodiment, the sixth optical path 10F and the seventh optical path 10G are orthogonal, and the seventh optical path 10G and the eighth optical path 10H are also orthogonal.
The second relay lens 1806 is disposed in a direction intersecting the seventh optical path 10G, and is disposed at 90 degrees in this embodiment.
Each of the three liquid crystal panels 20B, 20G, and 20R is provided with an incident side polarizing plate 2002 on the light beam incident side and an output side polarizing plate 2004 on the light beam output side.

In the cross dichroic prism 22, a dielectric multilayer film 22B that reflects a blue light beam and a dielectric multilayer film 22R that reflects a red light beam are formed in an approximately X shape along the interface of four right-angle prisms. Yes. The cross dichroic prism 22 has three incident surfaces that face each of the emission sides of the liquid crystal panels 20B, 20G, and 20R and that are orthogonal to the optical axis, and one emission surface that faces the projection lens 24 and is orthogonal to the optical axis. 2202.
The blue light beam incident on the cross dichroic prism 22 from the liquid crystal panel 20B corresponding to the blue light beam is reflected by the dielectric multilayer film 22B, emitted from the emission surface 2202, and reaches the projection lens 24.
The red light beam incident on the cross dichroic prism 22 from the liquid crystal panel 20R corresponding to the red light beam is reflected by the dielectric multilayer film 22R, emitted from the emission surface 2202, and reaches the projection lens 24.
The green light beam incident on the cross dichroic prism 22 from the liquid crystal panel 20G corresponding to the green light beam passes through the dielectric multilayer film 22B and the dielectric multilayer film 22R, is emitted from the emission surface 2202, and reaches the projection lens 24. For convenience of explanation, the optical path of the optical system 10 that is emitted from the cross dichroic prism 22 and reaches the projection lens 24 is referred to as a ninth optical path 10I. In the present embodiment, the third optical path 10C and the ninth optical path 10I are orthogonal to each other, the fifth optical path 10E and the ninth optical path 10I are positioned on the same axis, and the eighth optical path 10H and the ninth optical path 10I are orthogonal to each other.
Accordingly, a light beam obtained by combining three light beams of blue, red, and green is incident on the projection lens 24 from the exit surface 2202 of the cross dichroic prism 22, and the light beam guided by the projection lens 24 is imaged on the screen. As a result, a color image is formed.

Also, the two dichroic mirrors 1602 and 1604 (corresponding to the optical members in the claims) are so-called wedged dichroic mirrors in which the wavelength characteristics (reflection characteristics and transmission characteristics) of the dielectric multilayer film change along a predetermined direction. It is configured. In this embodiment, as shown in FIG. 2, the two dichroic mirrors 1602 and 1604 have a rectangular shape, and the wavelength characteristics (optical characteristics) of the dielectric multilayer film are in the long side direction (length direction) of the rectangle. It is comprised so that it may change along.
More specifically, since the illumination optical system 14 includes the first and second fly-eye lenses 1406 and 1408, the light beams incident on the dichroic mirrors 1602 and 1604 from the illumination optical system 14 are respectively in the first optical path 10A, It is not a light beam parallel to the fourth optical path 10D. Therefore, the angle formed by the light beam and the first optical path 10A differs depending on the position along the surfaces of the dichroic mirrors 1602 and 1604.
Dichroic mirrors with wedges are used as the dichroic mirrors 1602 and 1604 in order to obtain appropriate wavelength characteristics regardless of changes in the angle between the light beam and the first optical path 10A and the fourth optical path 10D.
By the way, the dielectric multilayer films in these dichroic mirrors 1602 and 1604 have wavelength characteristics, that is, variations in reflectance or transmittance of 50% wavelength tolerance, or the light source 12 has variations in light flux amount and wavelength characteristics. The brightness of the color image formed on the screen by the projection lens 24, in other words, the brightness, the color purity, and the white balance. Will also be affected and vary.

In order to avoid such influence, the wavelength characteristics of the two dichroic mirrors 1602 and 1604 may be adjusted so as to shift to the long wavelength side or the short wavelength side. Specifically, the two dichroic mirrors 1602 and 1604 are moved along the long side direction while maintaining an angle θ (45 degrees) formed by the two dichroic mirrors 1602 and 1604 and the first optical path 10A and the fourth optical path 10D. It can be moved. By moving the two dichroic mirrors 1602 and 1604 in this way, the wavelength characteristics of the two dichroic mirrors 1602 and 1604 are shifted to the long wavelength side or the short wavelength side.
In addition, when the optical system in the projection type display device includes a fly-eye lens, it is possible to obtain appropriate reflection characteristics or transmission characteristics by using a dichroic mirror with a wedge, and wavelength characteristics by moving the dichroic mirror with a wedge. It is publicly known to adjust (for example, JP-A-2001-174908).

Further, in order to eliminate the color shift of the color image projected on the screen, it is necessary to adjust the position shift of the red, green, and blue light beams with respect to the ninth optical path 10I.
Therefore, the condenser lens 1412 is configured to be movable along a plane orthogonal to the first optical path 10A while maintaining the position in the first optical path 10A direction, and the second relay lens 1806 is configured in the seventh optical path 10G direction. While maintaining the position, it is configured to be movable along a plane orthogonal to the seventh optical path 10G.
In the present embodiment, the two lenses of the condenser lens 1412 and the second relay lens 1806 are configured to be able to translate in the X and Y directions orthogonal to each other on the surfaces orthogonal to the first optical path 10A and the seventh optical path 17G. ing.
More specifically, the condenser lens 1412 condenses a light beam of white light including light of three colors of red, green, and blue, and is disposed on a plane orthogonal to the first optical path 10A. The condenser lens 1412 Is moved in two directions orthogonal to each other on the surface orthogonal to the first optical path 10A, thereby adjusting the positions of the red, green, and blue light beams.
The second relay lens 1806 matches the optical path length of the red light beam with the optical path lengths of the blue and green light beams, and is disposed on a plane orthogonal to the seventh optical path 10G. The position of the red light beam is adjusted by moving in two directions orthogonal to each other on a plane orthogonal to the seven optical paths 10G.
As described above, since the position adjustment of the red light beam is performed by the movement of the second relay lens 1806, the position adjustment of the green and blue light beams is performed by the movement of the condenser lens 1412.

Next, assembly of the projection display device 100 will be described.
2 is a perspective view showing the inside of the main part of the projection display apparatus 100, FIGS. 3 and 4 are perspective views showing a state in which the base 30 of the projection display apparatus 100 is covered with a cover 40, and FIG. 5 is a condenser lens. 6 is a perspective view of the second relay lens 1806, FIG. 7 is a perspective view of the support portion of the condenser lens 1412, FIG. 8 is a perspective view of the support portion of the second relay lens 1806, and FIGS. 11 is a perspective view showing a supporting portion of the dichroic mirror 1604, FIG. 12 is a plan view showing the supporting portion of the dichroic mirror 1604, FIG. 13 is an enlarged view of the supporting portion of the dichroic mirror 1604, and FIG. 14 is a supporting portion of the dichroic mirror 1604. FIG. 15 is a perspective view of the insertion member, and FIG. 16 is an explanatory view of the adjustment operation of the dichroic mirror 1604.

As shown in FIGS. 2 and 3, the projection display device 100 includes a base 30 and a cover 40 that house members other than the light source 12, the concave lens 1402, and the projection lens 24 in the optical system 10. The cover 40 constitutes the claimed housing.
The light source 12 and the projection lens 24 are attached to the base 30.
The base 30 is attached to the housing, and has a bottom wall 3002 and a side wall 3004 erected from the edge of the bottom wall 3002, and an accommodation space whose upper side is opened by the bottom wall 3002 and the side wall 3004 is formed. Has been. That is, the base 30 partitions the bottom of the optical path of the optical system 10 and the left and right sides.
The cover 40 is formed in the same shape as the bottom wall 3002 in plan view, and the housing 40 is closed by attaching the cover 40 to the upper part of the side wall 3004, and the upper part of the optical path of the optical system 10 is covered by the cover 40. Will be partitioned.
The said accommodation space of the base 30, U V cut filter 1404, first and second fly-eye lens 1406, 1408, PS conversion element 1410, a condenser lens 1412, the dichroic mirror 1602, 1604, UV-absorbing filter 1606, the total reflection mirror 1608, condenser lens 1610, three liquid crystal panels 20, first relay lens 1802, total reflection mirror 1804, second relay lens 1806, total reflection mirror 1808, condenser lens 1610 and cross dichroic prism 22 are first to ninth optical paths 10A. Is accommodated in a state of being arranged along -10I.
Of all these optical components, the optical components except for the four optical components of the condenser lens 1412, the second relay lens 1806, and the dichroic mirrors 1602 and 1604 are fixed to the base 30 so as not to move.
In the figure, reference numeral 2006 denotes a flexible substrate that supplies a drive signal for displaying image information on each of the three liquid crystal panels 20.

Next, the condenser lens 1412, the second relay lens 1806, and the dichroic mirrors 1602 and 1604 will be described.
As shown in FIG. 5, the condenser lens 1412 includes a lens 1412A and a lens frame 1412B formed in a rectangular frame shape that holds the lens 1412A.
A bulging portion 1412H bulging in the long side direction is formed in the upper half of the two short side portions of the lens frame 1412B.
A single plane that is orthogonal to the optical axis of the lens 1412A on the surface facing the one side in the thickness direction of the lens 1412A (the surface on the same side as the exit surface of the lens 1412A in this embodiment) at the lower portion of the bulging portion 1412H Two abutting surfaces 1412C located above extend along the short side direction.
Each abutment surface 1412C is formed with a concave groove 1412D along the extending direction thereof, and the concave groove 1412D is formed to extend in a U shape in which a pair of grooves are connected at the lower end.
Further, knobs 1412E are formed at both ends in the long side direction at the upper part of the bulging part 1412H, and formed so that the two knobs 1412E can be sandwiched between fingers while the condenser lens 1412 is incorporated in the base 30. Has been.

As shown in FIG. 7, a groove 3006 into which the two bulging portions 1412H of the lens frame 1412B of the condenser lens 1412 are inserted is formed in the two opposite side walls 3004 of the base 30 in the first optical path 10A portion. .
Each groove 3006 extends downward from the upper end of the side wall 3004 and is open at the upper end.
The width of each groove 3006 along the direction of the first optical path 10A is formed to be larger than the thickness of the lens frame 1412B, and one of the two side surfaces constituting each groove 3006 is orthogonal to the first optical path 10A. Each of the contact surfaces 3008 is formed on a single plane extending in the direction in which the contact surfaces are formed.
A leaf spring 3010 is provided on the other of the two side surfaces constituting each groove portion 3006. When the bulging portion 1412H is inserted between the leaf spring 3010 and the abutting surface 3008 while the abutting surface 1412C of the lens frame 1412B faces the abutting surface 3008, the abutting of the lens frame 1412B is performed by the leaf spring 3010. The surface 1412C is applied to the contact surface 3008, and the condenser lens 1412 is positioned with respect to the first optical path 10A.
Therefore, when the bulging portion 1412H is inserted into the groove portion 3006 while the abutting surface 1412C of the lens frame 1412B faces the abutting surface 3008, the condenser lens 1412 is held via the groove portion 3006 and the leaf spring 3010 in a positioned state. Then, when the lens frame 1412B is moved while holding the knobs 1412E of the lens frame 1412B with fingers, the abutting surfaces 1412C and 3008 are applied, so that the condenser lens 1412 is orthogonal to the optical axis of the first optical path 10A. The condenser lens 1412 is moved to a desired position by being moved in a direction orthogonal to the first optical path 10A while maintaining the extended state on the surface to be moved.
It should be noted that a notch portion 1412I for securing a space between the wall portion of the groove portion 3006 in which the abutting surface 3008 is formed at the bulging portion 1412H located at the upper portion of the abutting surface 1412C of the condenser lens 1412. It is provided so that application of the adhesive described later can be performed smoothly.

As shown in FIG. 7, a groove 3006 into which the two bulging portions 1412H of the lens frame 1412B of the condenser lens 1412 are inserted is formed in the two opposite side walls 3004 of the base 30 in the first optical path 10A portion. .
Each groove 3006 extends downward from the upper end of the side wall 3004 and is open at the upper end.
The width of each groove 3006 along the direction of the first optical path 10A is formed to be larger than the thickness of the lens frame 1412B, and one of the two side surfaces constituting each groove 3006 is orthogonal to the first optical path 10A. Each of the contact surfaces 3008 is formed on a single plane extending in the direction in which the contact surfaces are formed.
A leaf spring 3010 is provided on the other of the two side surfaces constituting each groove portion 3006. When the bulging portion 1412H is inserted between the leaf spring 3010 and the abutting surface 3008 while the abutting surface 1412C of the lens frame 1412B faces the abutting surface 3008, the abutting of the lens frame 1412B is performed by the leaf spring 3010. The surface 1412C is applied to the contact surface 3008, and the condenser lens 1412 is positioned with respect to the first optical path 10A.
Therefore, when the bulging portion 1412H is inserted into the groove portion 3006 while the abutting surface 1412C of the lens frame 1412B faces the abutting surface 3008, the condenser lens 1412 is held via the groove portion 3006 and the leaf spring 3010 in a positioned state. Then, when the lens frame 1412B is moved while holding the knobs 1412E of the lens frame 1412B with fingers, the abutting surfaces 1412C and 3008 are applied, so that the condenser lens 1412 is orthogonal to the optical axis of the first optical path 10A. The condenser lens 1412 is moved to a desired position by being moved in a direction orthogonal to the first optical path 10A while maintaining the extended state on the surface to be moved.
As shown in FIG. 3, in the state where the upper part of the base 30 is closed by the cover 40, each groove 3006 is opened upward, and each knob 1412E of the lens frame 1412B is exposed to the outside of the cover 40 and can be operated. It is like that.
It should be noted that a notch portion 1412I for securing a space between the wall portion of the groove portion 3006 in which the abutting surface 3008 is formed at the bulging portion 1412H located at the upper portion of the abutting surface 1412C of the condenser lens 1412. It is provided so that application of the adhesive described later can be performed smoothly.

As shown in FIG. 6, the second relay lens 1806 includes a lens 1806A and a lens frame 1806B formed in a rectangular rectangular frame shape that holds the lens 1806A.
A bulging portion 1806H that bulges in the long side direction is formed in the upper half of the two short side portions of the lens frame 1806B.
A single plane perpendicular to the optical axis of the lens 1806A is provided on a surface facing the one side in the thickness direction of the lens 1806A (surface in the present embodiment on the same side as the exit surface of the lens 1806A) at the lower portion of the bulge 1806H Two abutting surfaces 1806C located on the upper side extend along the short side direction.
Each abutment surface 1806C is formed with a concave groove 1806D along the extending direction thereof, and the concave groove 1806D extends so as to have a U shape with its lower end connected when viewed from the optical axis direction of the lens 1806A. Is formed.
Further, knobs 1806E are formed to protrude upward at both ends in the long side direction at the upper part of the bulging part 1806H, and the two knob parts 1806E are sandwiched between the fingers while the second relay lens 1806 is incorporated in the base 30. It is formed to be able to.

As shown in FIG. 8, a groove 3006 into which the two bulging portions 1806H of the lens frame 1806B of the second relay lens 1806 are inserted is formed on the two side walls 3004 facing the base 30 in the seventh optical path 10G. ing.
Each groove 3006 extends downward from the upper end of the side wall 3004 and is open at the upper end.
The width of each groove 3006 along the direction of the seventh optical path 10G is formed with a dimension larger than the thickness of the lens frame 1806B, and one of the two side surfaces constituting each groove 3006 is orthogonal to the seventh optical path 10G. Each of the contact surfaces 3008 is formed on a single plane extending in the direction in which the contact surfaces are formed.
A leaf spring 3010 is provided on the other of the two side surfaces constituting each groove portion 3006. When the bulging portion 1806H is inserted between the leaf spring 3010 and the abutting surface 3008 with the abutting surface 1806C of the lens frame 1806B facing the abutting surface 3008, the abutting of the lens frame 1806B by the leaf spring 3010 is performed. The surface 1806C is applied to the contact surface 3008, and the second relay lens 1806 is positioned with respect to the seventh optical path 10G.
Therefore, when the bulging portion 1806H is inserted into the groove portion 3006 while the abutting surface 1806C of the lens frame 1806B faces the abutting surface 3008, the second relay lens 1806 is positioned via the groove portion 3006 and the leaf spring 3010. When the lens frame 1806B is moved while holding the knobs 1806E of the lens frame 1806B with fingers, the contact surfaces 1806C and 3008 are applied, so that the second relay lens 1806 is connected to the seventh optical path 10G. The second relay lens 1806 is moved to a desired position by being moved in a direction orthogonal to the seventh optical path 10G while maintaining a state extending on a plane orthogonal to the optical axis.
As shown in FIG. 3, with the upper portion of the base 30 closed by the cover 40, each knob 1806E of the lens frame 1806B protrudes above the cover 40 through the opening 4050 (see FIG. 4) of the cover 40. It can be operated.
In addition, in the bulging part 1806H location located in the upper part of the contact surface 1806C of the 2nd relay lens 1806, the missing part for ensuring a space between the wall part of the groove part 3006 in which the contact surface 3008 was formed. 1806I is provided so that application of an adhesive described later can be performed smoothly.

As shown in FIG. 2, the blue dichroic mirror 1602 and the red dichroic mirror 1604 are formed in a rectangular plate shape.
First, the assembly of the red dichroic mirror 1604 will be described. As shown in FIGS. 12 to 14, the two opposite each other at the base 30 where the fourth optical path 10D, the fifth optical path 10E, and the sixth optical path 10F intersect. A groove portion 3012 into which two short side portions of the dichroic mirror 1604 are inserted is provided at the location of the two side walls 3004.
As shown in FIGS. 12 and 13, the groove 3012 is formed to extend vertically with a width larger than the thickness of the dichroic mirror 1604, and the upper end is open.
Each groove 3012 has a positioning surface 3014 facing each other with a larger distance than the length of the dichroic mirror 1604 (optical member), and a length direction of the dichroic mirror 1604 extending in a direction parallel to the intersecting direction. An abutting surface 3016 that can be in contact with the surface of the dichroic mirror 1604 extending in a parallel direction, and a surface of the dichroic mirror 1604 that abuts against the dichroic mirror 1604 inserted in the groove 3012 and abuts against the abutting surface 3016. A leaf spring 3018 (spring member) that biases in the direction is provided.
More specifically, the groove 3012 includes a positioning surface 3014 that can be in contact with the end surface 1604A in the long side direction of the dichroic mirror 1604, and one surface in the thickness direction of the dichroic mirror 1604, in this embodiment, the dichroic mirror 1604. And an abutting surface 3016 capable of abutting against the incident surface 1604B.
The abutting surfaces 3016 of the groove portions 3012 facing each other are formed as surfaces positioned on a single plane extending in a direction that forms an angle θ (45 degrees) with the fourth optical path 10D.
A plate spring 3018 is provided at the position of the groove 3012 facing the abutting surface 3016 to abut the dichroic mirror 1604 on the abutting surface 3016.

Therefore, when the incident surface 1604B of the dichroic mirror 1604 faces the abutting surface 3016 and the dichroic mirror 1604 is inserted between the leaf spring 3018 and the abutting surface 3016, the incident surface 1604B of the dichroic mirror 1604 is abutted by the leaf spring 3018. The light is applied to the attachment surface 3016, and the incident surface 1604B is held in an angle θ with respect to the fourth optical path 10D.
The positioning surfaces 3014 of the grooves 3012 facing each other are provided such that the dimension between them is larger than the dimension in the long side direction of the dichroic mirror 1604.
Therefore, the dichroic mirror 1604 has two grooves 3012 on one end surface 1604A in the long side direction of the dichroic mirror 1604 in a state where the incident surface 1604B is held at an angle θ with respect to the fourth optical path 10D as described above. , The wavelength characteristic of the dichroic mirror 1604 is shifted to one of the long wavelength side and the short wavelength side, and the long side direction of the dichroic mirror 1604 When the other end surface 1604A is brought into contact with the positioning surface 3014 of the other groove 3012 of the two grooves 3012, the wavelength characteristic of the dichroic mirror 1604 is in the second state shifted to the other of the long wavelength side or the short wavelength side. Is formed.

In the present embodiment, such positioning of the dichroic mirror 1604 is performed using the insertion member 50 and the fixing means.
That is, both ends in the length direction of the dichroic mirror 1604 are inserted into one of the groove portions 3012 in a state where both ends in the length direction of the dichroic mirror 1604 are inserted into contact with one end surface 1604A in the length direction of the dichroic mirror 1604, and An insertion member 50 that abuts the other end surface 1604A in the length direction against the positioning surface 3014 of the other groove 3012 and a fixing means that fixes the insertion member 50 in a state where the insertion member 50 is inserted into the groove 3012 are provided. It has been.
More specifically, a guide surface 3020 is formed at the bottom of each groove 3012. The guide surface 3020 is formed at the lower part of each groove 3012 so as to reach the lower side as it approaches the fourth optical path 10D to the sixth optical path 10F. Yes.
As shown in FIG. 15, the insertion member 50 has a shaft portion 5002 having a substantially rectangular cross section and extending linearly, and an attachment piece 5006 having a screw insertion hole 5004 is formed at the upper end of the shaft portion 5002 so as to protrude. An engaging surface 5008 that can be engaged with the guide surface 3020 of the groove 3012 is formed at the tip of the shaft portion 5002.
The shaft portion 5002 has a width that is substantially the same as the width of the groove portion 3012, and is formed in a size that can be inserted into the groove portion 3012 without rattling.
As shown in FIG. 9, an opening 4002 into which the insertion member 50 can be inserted is formed through the cover 40 corresponding to the groove 3012, and a screw hole 4004 is provided in the cover 40 in the vicinity of the opening 4002. .
The insertion member 50 inserts the shaft portion 5002 into the one groove portion 3012 through the opening 4002, engages the engagement surface 5008 with the guide surface 3020 of the groove portion 3012, and pushes the insertion member 50 in this state. The insertion member 50 is guided and moved by the engagement surfaces 5008 and 3020 in a direction approaching the fourth to sixth optical paths 10D, 10E, and 10F. Accordingly, one end surface 1604A in the long side direction of the dichroic mirror 1604 comes into contact with the side surface of the shaft portion 5002 of the insertion member 50, the dichroic mirror 1604 is moved in the direction of the other groove 3012, and the other side of the dichroic mirror 1604 in the long side direction. End surface 1604A contacts the positioning surface 3014 of the other groove portion 3012 to be in the first state. Similarly, when the shaft portion 5002 is inserted into the other groove portion 3012 through the opening 4002, the engagement surface 5008 is engaged with the guide surface 3020 of the groove portion 3012, and the insertion member 50 is pushed in this state, The insertion member 50 is guided and moved by the engagement surfaces 5008 and 3020 in a direction approaching the fourth to sixth optical paths 10D, 10E, and 10F. As a result, one end surface 1604A in the long side direction of the dichroic mirror 1604 is brought into contact with the side surface of the shaft portion 5002 of the insertion member 50, the dichroic mirror 1604 is moved in the direction of the one groove 3012, and one side of the dichroic mirror 1604 in the long side direction. End surface 1604A comes into contact with the positioning surface 3014 of one groove 3012 to enter the second state.
Then, with the dichroic mirror 1604 positioned in the first state or the second state, the insertion member 50 is attached to the cover 40 by screwing the screw N1 into the screw hole 4002 via the screw insertion hole 5004 of the mounting piece 5006. It is configured so that it can be attached. In the present embodiment, the screw insertion hole 5004, the screw hole 4002, and the screw N1 constitute the fixing means for the insertion member 50.

  The blue dichroic mirror 1602 is also configured to be movable in the long side direction as described above. By inserting the insertion member 50 into one of the two groove portions 3012, the dichroic mirror 1602 and the first optical path are arranged. The first state in which the wavelength characteristic of the dichroic mirror 1602 is shifted to one of the long wavelength side and the short wavelength side while maintaining the angle θ (45 degrees) formed by 10A, and the wavelength characteristic of the dichroic mirror 1602 is the long wavelength It is comprised so that it may become the 2nd state shifted to the other of the side or the short wavelength side.

Next, alignment adjustment of three light beams of red, green, and blue will be described.
First, the light source 12 and the projection lens 24 are incorporated into the base 30, and the concave lens 1402, the UV cut filter 1404, the first and second fly-eye lenses 1406 and 1408, and the PS conversion element 1410 are arranged along the first to ninth optical paths 10A to 10I. , Condenser lens 1412, dichroic mirrors 1602, 1604, UV absorption filter 1606, total reflection mirror 1608, condenser lens 1610, three liquid crystal panels 20, first relay lens 1802, total reflection mirror 1804, second relay lens 1806, total reflection The condenser lens 1610 and the cross dichroic prism 22 are incorporated by the mirror 1808 and the cover 40 is attached.
Next, of the three liquid crystal panels 20, the two liquid crystal panels 20B and 20G corresponding to the blue and green light fluxes are set to the transmissive state, and the liquid crystal panel 20R corresponding to the red light flux is set to the non-transmissive state. A cyan reference image (for example, a rectangle having the same shape and the same size as the outline of the screen) is projected, and the convex portion 1412E of the condenser lens 1412 is sandwiched between fingers so that the cyan rectangular image coincides with a predetermined position on the screen. The lens 1412 is moved.
Of the three liquid crystal panels 20, the liquid crystal panel 20G corresponding to the green light flux is set in the non-transmissive state, and the two liquid crystal panels 20B and 20R corresponding to the blue and red light fluxes are set in the transmissive state. A magenta reference image having the same shape and size as the reference image is projected, and the second relay lens 1806 is sandwiched between the convex portions 1806E of the second relay lens 1806 so that the magenta reference image matches the reference position on the screen. Move.
As a result, the positions of the three light beams of red, green and blue are adjusted so as to coincide with the ninth optical path 10I, in other words, the optical axis of the optical system 10.
In this state, the abutting surface 1412C of the condenser lens 1412 and the abutting surface 3008 of the groove 3006 are bonded and fixed with, for example, a liquid instantaneous adhesive. Specifically, when an instantaneous adhesive is applied between the abutting surfaces 1412C and 3008, the instantaneous adhesive spreads evenly in the gaps between the abutting surfaces 1412C and 3008 by capillary action. At this time, since the surplus adhesive flows into the concave groove 1412D, it is possible to suppress leakage to the outside of the abutting surfaces 1412C and 3008.
Further, the second relay lens 1806 is also bonded and fixed with an instantaneous adhesive as described above. Specifically, an instantaneous adhesive is applied between the contact surface 1806C of the second relay lens 1806 and the contact surface 3008 of the groove 3006. In this case as well, the instantaneous adhesive spreads evenly across the gaps between the abutting surfaces 1806C and 3008 due to capillary action. Moreover, since the excess adhesive flows into the concave groove 1806D in the same manner as described above, it is possible to suppress leakage to the outside of the abutting surfaces 1806C and 3008.

Next, luminance adjustment will be described.
First, the dichroic mirror 1602 is placed in the first state, for example, by inserting the insertion member 50 into one groove 3012.
Next, white light is projected from the projection lens 24 by setting the three liquid crystal panels 20B, 20G, and 20R to the transmissive state, and the brightness of the projected white light is measured. If the measurement result does not meet the standard, the dichroic mirror 1602 is moved to the second state by removing the insertion member 50 from one groove 3012 and inserting the insertion member 50 into the other groove 3012. The brightness of white light is measured, and if the measurement result satisfies the standard, the insertion member 50 is fixed to the base 30 with the screw N1.
If the luminance does not satisfy the reference even after adjusting the dichroic mirror 1602, the dichroic mirror 1604 is adjusted in the same procedure, and the insertion member 50 is similarly fixed to the base 30 with the screw N1.

According to the first embodiment, when the alignment adjustment of the three light beams of red, green, and blue is performed, the state in which the contact surface 1412C of the condenser lens 1412 is applied to the contact surface 3008 of the groove 3006 is a leaf spring. 3018 is held, and the condenser lens 1412 is held in a state extending on the surface orthogonal to the optical axis of the first optical path 10A. Therefore, by sandwiching the convex portion 1412E with a finger, the condenser lens 1412 is orthogonal to the first optical path 10A. The condenser lens 1412 can be moved in the direction and moved to a desired position.
A state in which the contact surface 1806C of the second relay lens 1806 is applied to the contact surface 3008 of the groove portion 3006 is held by the leaf spring 3018, and the second relay lens 1806 is a surface orthogonal to the optical axis of the seventh optical path 10G. Since the state of extending upward is maintained, the second relay lens 1806 can be moved in a direction orthogonal to the seventh optical path 10G and moved to a desired position by sandwiching the convex portion 1806E with a finger.
Therefore, the alignment adjustment of the three light fluxes of red, green, and blue can be performed without requiring a dedicated jig or equipment, which is advantageous in reducing the cost. Since it does not take time to attach to and remove from tools and equipment, it is advantageous for improving the efficiency of adjustment work.
In addition, since the condenser lens 1412 and the second relay lens 1806 can be moved in a state where the members constituting the optical system 10 are accommodated in the base 30 and the cover 40 is attached, it is not necessary to remove the cover 40 for adjustment. Therefore, it is more advantageous for improving the efficiency of adjustment work.

Further, when the abutting surfaces of the condenser lens 1412 and the second relay lens 1806 and the abutting surface 3008 of the groove 3020 are bonded and fixed with, for example, a liquid instantaneous adhesive, the adhesive remaining from the gap between the abutting surfaces is Since it flows into the concave grooves 1412D and 1806D of the condenser lens 1412 and the second relay lens 1806, it is possible to suppress leakage to the outside of each abutting surface. For this reason, it is advantageous in preventing a phenomenon in which excess adhesive leaks to the outside of each contact surface and whitens the condenser lens 1412 and the second relay lens 1806.
Further, since the adhesive remaining from the gaps between the contact surfaces flows into the concave grooves 1412D and 1806D of the condenser lens 1412 and the second relay lens 1806, it is not necessary to strictly control the amount of adhesive to be applied. This is advantageous for improving the efficiency of the bonding operation.

Further, the state in which the abutting surface 1412C of the condenser lens 1412 is abutted against the abutting surface 3008 of the groove 3006 is held by the leaf spring 3018, and the abutting surface 1806C of the second relay lens 1806 is retained in the groove 3006. Since the state applied to the abutting surface 3008 is held by the leaf spring 3018, the following effects are obtained.
1) The positions of the condenser lens 1412 and the second relay lens 1806 do not fluctuate during the curing of the adhesive, which is advantageous for reliably holding the adjustment position. In addition, even if some vibration occurs during the curing of the adhesive, the adjustment position does not shift, so that it can be transported to the next process in the middle of the assembly, and the manufacturing tact can be shortened.
2) Since the contact surfaces are in reliable contact with each other, the amount of adhesive applied can be minimized, and the remaining adhesive can be prevented from adhering to the condenser lens 1412 and the second relay lens 1806 and becoming dirty. This is advantageous.
3) Since the abutting surfaces are securely contacted with each other by the adhesive, it is advantageous in securing the adhesive strength.

Further, when performing the brightness adjustment, the dichroic mirrors 1602 and 1604 can be moved to the first and second states by inserting the insertion member 50 into one of the two groove portions 3012. Brightness can be adjusted without the need for equipment, which is advantageous for reducing manufacturing costs, and adjustment work is not required for attaching and detaching the projection display device to or from a dedicated jig or equipment. This is advantageous in improving efficiency.
Further, the state in which the abutting surface 1412C of the condenser lens 1412 is abutted against the abutting surface 3008 of the groove portion 3006 is held by the leaf spring 3018, and the condenser lens 1412 is on a surface orthogonal to the optical axis of the first optical path 10A. Since the extended state is maintained, the dichroic mirrors 1602 and 1604 can be moved to the first and second states without changing the angles of the first optical path 10A and the fourth optical path 10D with respect to the optical axis. Therefore, the brightness can be adjusted, which is advantageous for improving the efficiency of the adjustment work.
In addition, the dichroic mirrors 1602 and 1604 can be moved to the first and second states while the members constituting the optical system 10 are accommodated in the base 30 and the cover 40 is attached. There is no need for removal, which is advantageous in improving the efficiency of adjustment work.
Further, since the insertion member 50 can be inserted into the groove portion 3012 from the direction in which the cover 40 is attached to the base 30, it is further advantageous in improving the efficiency of the adjustment work.

  Therefore, according to the present embodiment, it is advantageous to reduce the cost and to make the position adjustment work of an optical member such as a dichroic mirror having different optical characteristics along the length direction more efficient.

In the present embodiment, the condenser lens 1412 and the second relay lens 1806 inserted into the groove portion 3006 and the abutting surfaces 1412C and 1806C of the second relay lens 1806 are biased in the direction to abut against the abutting surface 3008. 2 The leaf spring 3010 that presses the relay lens 1806 is used, but the biasing may be performed by applying a pulling force to the condenser lens 1412 and the second relay lens 1806 as such a spring member. Of course, the good thing is.
In this embodiment, the leaf spring 3018 that presses the dichroic mirrors 1602 and 1604 is used as a spring member that biases the incident surface 1604B of the dichroic mirrors 1602 and 1604 inserted into the groove 3012 to the abutting surface 3016. It goes without saying that the biasing may be performed by applying a pulling force to the portions of the dichroic mirrors 1602 and 1604 as such a spring member.
Two insertion members 50 may be provided corresponding to the two groove portions 3012. However, a single insertion member 50 is provided as in the present embodiment, and the single insertion member 50 is connected to the two groove portions 3012. If it is inserted in one or the other, only one insertion member 50 is required, which is advantageous in reducing the number of parts.
In the embodiments, the dichroic mirror has been described as an example of the optical member having different optical characteristics along the length direction. However, the optical member is not limited to the dichroic mirror, and the present invention is not limited to the optical characteristics along the length direction. The present invention is also applied to other optical members having different values.

It is a block diagram of the optical system of the projection type display apparatus in Example 1 of this invention. 2 is a perspective view showing the inside of a main part of the projection display device 100. FIG. 4 is a perspective view showing a state in which a base 30 of the projection display device 100 is covered with a cover 40. FIG. 3 is a perspective view showing a state in which a base 30 of the projection display apparatus 100 is covered with a cover 40. FIG. 6 is a perspective view of a condenser lens 1412. FIG. FIG. 10 is a perspective view of a second relay lens 1806. 6 is a perspective view showing a support portion of a condenser lens 1412. FIG. FIG. 10 is a perspective view showing a support portion of a second relay lens 1806. FIG. 6 is a perspective view showing a supporting portion of a dichroic mirror 1604. FIG. 6 is a perspective view showing a supporting portion of a dichroic mirror 1604. FIG. 6 is a perspective view showing a supporting portion of a dichroic mirror 1604. FIG. 6 is a plan view showing a support portion of a dichroic mirror 1604. FIG. 6 is an enlarged view of a support portion of a dichroic mirror 1604. It is a front view of the support part of the dichroic mirror 1604. FIG. It is a perspective view of an insertion member. It is an explanatory diagram of the adjustment operation of the dichroic mirror 1604.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Projection type display apparatus, 10 ... Optical system, 12 ... Light source, 14 ... Illumination optical system, 16 ... Color separation optical system, 18 ... Relay optical system, 20 (20R, 20G, 20B) ... ... Liquid crystal panel, 30 ... Base, 40 ... Cover, 50 ... Insertion member, 1602, 1604 ... Cross dichroic mirror, 1604A ... End face, 1604B ... Incident face, 3012 ... Groove, 3014 ... For positioning Surface, 3016... Application surface, 3018.

Claims (9)

A light source;
An optical system for separating a light beam emitted from the light source into a plurality of light beams having different wavelengths;
Image forming means for combining the separated luminous fluxes into one luminous flux for image formation and emitting the same;
A housing for housing the optical system and the image forming means;
A projection display device comprising:
The optical system has an optical member that is arranged so as to intersect with an optical path constituted by the optical system, has a length along the intersecting direction, and has different optical characteristics along the length direction. ,
The housing has two grooves that are formed in an open shape upward and into which both ends in the length direction of the optical member are inserted,
Each of the groove portions has a positioning surface facing each other with a gap larger than the length of the optical member, and extends in a direction parallel to the intersecting direction and extends in a direction parallel to the length direction of the optical member. An abutting surface capable of coming into contact with the surface of the optical member, and a spring member for elastically contacting the optical member inserted in the groove and biasing the surface of the optical member to the abutting surface Is provided,
Furthermore, the length of the optical member is in contact with one end surface in the length direction of the optical member inserted into one of the groove portions with both ends in the length direction of the optical member being inserted into the two groove portions. An insertion member that makes the other end surface of the direction contact the positioning surface of the other groove portion, and a fixing means that fixes the insertion member in a state where the insertion member is inserted into the groove portion.
A projection type display device characterized by that.   The housing includes a base that divides a bottom portion and right and left side portions of the optical path, and a cover that is attached to the base and divides an upper portion of the optical path, and the groove is formed in the base, The projection display device according to claim 1, wherein an opening for inserting an insertion member into the groove is formed.   The groove portion is provided with a guide surface, the insertion member is provided with an engagement surface engageable with the guide surface, and the insertion member is inserted into the groove portion via the guide surface and the engagement surface. The projection display device according to claim 1, wherein the projection display device is configured to move toward the optical path.   The fixing means is a screw insertion hole formed at the upper end of the insertion member, a screw hole formed in the housing, and is screwed into the screw hole from the screw insertion hole to fasten and fix the upper end of the insertion member to the housing. The projection display device according to claim 1, comprising a screw.   The fixing means is a screw insertion hole formed at the upper end of the insertion member, a screw hole formed in the housing, and is screwed into the screw hole from the screw insertion hole to fasten and fix the upper end of the insertion member to the housing. The insertion member is formed as a single unit so that it can be inserted into either of the two groove portions, and two screw holes are provided corresponding to the two groove portions. The projection display device according to claim 1.   The housing includes a base that divides a bottom portion and left and right side portions of the optical path, and a cover that is attached to the base and divides an upper portion of the optical path, and the groove portion is formed in the base, 6. The projection display device according to claim 4, wherein an opening for inserting an insertion member into the groove is formed, and the screw hole is formed in the cover.   The projection display device according to claim 1, wherein the spring member is configured by a leaf spring disposed inside the groove.   The optical system includes a separation optical system that separates a light beam emitted from the light source into a plurality of light beams having different wavelengths by a dielectric multilayer film, and the optical member has a wavelength characteristic of the dielectric multilayer film in the length direction. The projection display device according to claim 1, wherein the projection type display device is a dichroic mirror with a wedge configured to change along the projection. The projection display device according to claim 6, wherein the optical member is disposed so as to intersect with the optical path at an angle of 45 degrees, and the groove portions face each other.

Images