JP2006091388A - Phase plate for projector, and liquid crystal projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a phase plate for a projector which can prevent a liquid crystal display element and its related components from being deteriorated due to the adverse effect of heat from a light source and has excellent durability of members. <P>SOLUTION: In the phase plate 39 for the projector which is adjacently arranged on the incident side of the liquid crystal display element and constituted of the sticking of a plurality of optically anisotropic crystal plates 391, 392 having respectively different thickness so that an incident beam is spectrally divided into a normal beam and an abnormal beam and in which a phase difference is formed between both the beams to change the optical characteristics of the incident beam, the thickness T1 of the stuck phase plate 39 is set to 0.7 to 4mm. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a phase plate formed by laminating a plurality of optically anisotropic crystal plates having different thicknesses, and in particular, a projector that is used in a liquid crystal projector and is disposed close to the front and rear of a liquid crystal display element. And a liquid crystal projector using the same.

  Conventionally, there are two types of phase plates applied to the polarizing optical system of a liquid crystal projector. For example, as disclosed in Patent Document 1, a transparent substrate in which a resin phase difference film is attached to an adhesive material is used. The reason for using the retardation film by sticking it to the transparent substrate without using the retardation film in this way is that the retardation film has high heat shrinkage, and the retardation film absorbs light from the light source and generates heat. Therefore, the transparent substrate functions as a heat radiating substrate to prevent the retardation film from being deformed. As the transparent substrate, glass, quartz, sapphire, or the like is used. The thermal conductivity (w / m · k) of these transparent substrates is as high as 41.9 for sapphire, followed by 5.4 to 9.3 for quartz and 0.55 to 0.75 for glass (blue plate glass). Sapphire is the best. However, in terms of cost, glass is the cheapest, followed by quartz and sapphire. In addition, sapphire has a drawback that it has poor workability due to its high hardness and low transmittance due to its high refractive index. For this reason, the present situation is that quartz is used as the most practical transparent substrate for a retardation film that balances cost and thermal conductivity.

  The other is, as disclosed in Patent Document 2, using two substrates made of an optically anisotropic medium such as a quartz substrate, and using the difference in velocity between these ordinary rays and extraordinary rays, Those that create a phase difference between the rays are used. Then, when configured as a quarter wavelength plate (having a phase difference of π / 2), linearly polarized light is converted into circularly polarized light or circularly polarized light is converted into linearly polarized light as described above. This type of phase plate is extremely superior in terms of durability and heat resistance of the member compared to the former type of phase plate, and is currently being used as a phase plate for liquid crystal projectors. .

  Hereinafter, the phase plate on which the quartz substrate is bonded will be described. In general, as a phase plate, a thickness dimension required to correspond to a wavelength region (for example, around 600 nm) of a light beam used in an optical apparatus is theoretically about 15 to 20 μm in the case of a quarter wavelength plate. However, it is difficult to obtain a quartz substrate having this thickness dimension in crystal processing. Therefore, a laminate of two quartz substrates processed with a thickness difference of the above dimensions is generally used. That is, a phase difference performance equivalent to that of the quartz substrate having the above thickness dimension (about 15 to 20 μm) is obtained by using the thickness difference between the two quartz substrates. As a configuration example of the phase plate, a quartz wavelength plate having an optical axis angle of 0 ° with respect to a reference surface (one side of a rectangular quartz substrate) and a quartz wavelength plate having an optical axis angle of 90 ° are combined with a UV adhesive ( There is a structure in which they are bonded together by an ultraviolet curable adhesive).

JP 2003-228058 A JP 2003-222724 A

  However, even if a phase plate made of an optically anisotropic crystal plate is used as described above, the thermal adverse effect of the light source cannot be completely eliminated. In particular, as a light source used in a liquid crystal projector, a powerful lamp such as an ultra-high pressure mercury lamp or a metal halide lamp is used. Therefore, the temperature of the phase plate sometimes exceeds 80 ° C. By receiving, a member related to the liquid crystal display element may be deteriorated, or if the influence is strong, the liquid crystal display element itself may be deteriorated. In particular, a polarizing film that is attached to the incident surface of a liquid crystal display element and polarizes a light component in the liquid crystal axis direction of the liquid crystal display element is often made of a resin film and is extremely affected by thermal effects. There was a problem that it was easy. When this polarizing film deteriorates, the color of the image projected on the liquid crystal projector may become strange, or the image itself may be abnormal. Further, when the liquid crystal projector is miniaturized, since various optical systems are arranged closer to each other, there is a problem that it is easily affected by radiant heat from the outside of the optical path.

  The present invention has been made in view of the above points, and provides a projector phase plate that prevents deterioration of a liquid crystal display element and related parts due to adverse effects of heat from a light source and has excellent durability of members. Thus, an object of the present invention is to provide a liquid crystal projector that can extend the life of the product.

  Therefore, the projector phase plate according to claim 1 of the present invention is disposed close to the incident side of the liquid crystal display element, and a plurality of optically anisotropic crystal plates having different thicknesses are bonded together, and the incident light beam is converted into an ordinary light beam. In the projector phase plate that changes the optical characteristics of the incident light by giving a phase difference between the two light beams, the thickness of the bonded phase plate is 0.7 mm or more and 4 mm or less. It is characterized by that.

  According to a second aspect of the present invention, a plurality of optically anisotropic crystal plates having different thicknesses are bonded to each other on the incident side of the liquid crystal display element, and the incident light is changed into an ordinary ray and an extraordinary ray. In the projector phase plate that changes the optical characteristics of the incident light by spectroscopically dividing and giving a phase difference between the two light beams, a heat dissipation substrate is bonded to one of the principal surfaces of the phase plate to form a phase plate body. It is characterized by comprising.

  According to a third aspect of the present invention, the thickness of the bonded phase plate is 0.7 mm or more and 4 mm or less.

  In addition, as shown in claim 4, the phase plate and the heat dissipation substrate are made of a quartz substrate, and the phase plate is bonded in a state where the optical axes are arranged in a direction perpendicular to each other, A crystal substrate used as a heat dissipation substrate is bonded to one of the main surfaces of the phase plate in a state where the optical axis is arranged in a direction rotated by 45 ° from any one of these optical axis directions. .

  According to a fifth aspect of the present invention, the thickness of the bonded phase plate is 0.1 mm or more and 0.5 mm or less.

  According to a sixth aspect of the present invention, a phase plate body is formed by attaching a heat dissipation substrate having a thickness larger than that of the phase plate to both principal surfaces of the phase plate.

  According to a seventh aspect of the present invention, the projector phase plate according to the first to sixth aspects, a light source, a liquid crystal display element that modulates the light intensity of the transmitted light in accordance with image information, and the modulation thereof. And a projector for projecting optical information, wherein the projector phase plate is disposed close to the incident side of the liquid crystal display element.

  According to the first aspect of the present invention, the durability of the phase plate is improved by being disposed close to the incident side of the liquid crystal display element and setting the thickness of the bonded phase plate to 0.7 mm or more. In addition, since heat dissipation is further enhanced, heat is not trapped in the liquid crystal display element, and further thermal deterioration of the liquid crystal display element and its related parts is suppressed. In particular, the heat radiation component (infrared light) is removed before reaching the polarizing film of the liquid crystal display element, and the polarizing film and the liquid crystal display element are not overheated and deteriorated. For this reason, the optical characteristics (color and image quality) of the liquid crystal display element are not deteriorated. In addition, the increase in thickness of the phase plate increases the strength and rigidity of the phase plate, which prevents the phase plate from being warped or distorted by external factors such as optical coating materials, adhesives, or heat. The parallelism and flatness of both principal surfaces of the phase plate can be improved. That is, the phase plate does not change the incident angle of the light beam incident on the main surface due to warping or distortion, so that a desired phase characteristic can be obtained and a phase plate that does not adversely affect the optical characteristic can be obtained. Further, by setting the thickness of the bonded phase plate to 4 mm or less, processing difficulty and cost increase due to increase of the thickness of the phase plate can be suppressed, and space saving can be achieved.

  According to the second aspect of the present invention, the phase plate is disposed close to the incident side of the liquid crystal display element, and the heat dissipation substrate is bonded to one of the main surfaces of the phase plate, so that the durability of the phase plate is improved. Since heat dissipation is further enhanced, heat is not trapped in the liquid crystal display element, and further thermal deterioration of the liquid crystal display element and its related parts is suppressed. In particular, the thermal radiation component (infrared rays) is removed before reaching the polarizing film of the liquid crystal display element, and the polarizing film and the liquid crystal display element are not overheated and deteriorated. For this reason, the optical characteristics (color and image quality) of the liquid crystal display element are not deteriorated. In addition, since the thickness of the phase plate can be suppressed by bonding the heat dissipation substrate to the phase plate, the retardation value relative to the incident angle (refraction of ordinary and extraordinary rays of the quarter-wave plate) The dependence of the difference in refractive index, that is, the product of the birefringence difference and the thickness of the quarter-wave plate can be reduced.

  According to claim 3, in addition to the above-described effects, the thickness of the bonded phase plate or the bonded phase plate body is set to 0.7 mm or more. Durability and heat dissipation are further enhanced. By setting the thickness of the bonded phase plate to 4 mm or less, processing difficulty and cost increase due to increase in thickness of each member, or cost due to increase in the number of steps of each member. The increase can be suppressed. Moreover, space saving is achieved by suppressing the thickness of the phase plate.

  FIG. 8 is a comparative graph showing the usage time of the liquid crystal projector and the surface temperature for each thickness of the phase plate. As a phase plate, when a quartz substrate with a length of 20 mm and a width of 22 mm is bonded with an acrylic UV adhesive, and a phase plate with a different thickness is incorporated into a reflective liquid crystal projector, The surface temperature is measured for each usage time. In addition, the heat resistance temperature of the polarizing film that is disposed close to these phase plates and used for the liquid crystal display element is about 80 ° C. to about 100 ° C. for a normal product, and about 100 ° C. for a heat resistance specification product. As these graphs show, in order not to give a thermal adverse effect to the polarizing film, the thickness of the phase plate needs to be 0.7 mm or more, more preferably 1 mm or more. Recognize. In addition, since there is no significant change in heat dissipation when the thickness of the phase plate is 4 mm and when the thickness of the phase plate is 6 mm, the thickness of the phase plate is reduced to 4 mm or less. An increase in cost due to the increase can be suppressed. In the case of a phase plate body in which two or more quartz substrates are bonded together, if the total thickness of the bonded substrates is the same, the heat insulation effect is high, and the value is slightly lower than the above temperature.

  According to the fourth aspect of the present invention, in addition to the above-described effects, the most practical quartz substrate that balances cost and thermal conductivity, has good workability, and has no decrease in transmittance is used as a heat dissipation substrate. Can do. Further, even if the same crystal as the phase plate is used for the heat dissipation substrate, the two crystal substrates are bonded together with the optical axes arranged in directions orthogonal to each other, and 45 ° from either of these optical axis directions. Since the optical axis is arranged in the rotated direction, the function as a heat dissipation substrate can be obtained without adversely affecting the phase difference characteristics. In addition, since the phase plate and the heat dissipation substrate are made of the same material, the optical characteristics are almost the same and the transmittance characteristics are excellent.

  Further, according to claim 5, in addition to the above-described effects, the thickness of the bonded phase plate is 0.1 mm or more and 0.5 mm or less. As a result, the contrast performance when used in a liquid crystal projector can be drastically improved. Note that if the thickness of the phase plate is less than 0.1 mm, processing becomes difficult and is not preferable for practical use. However, if the thickness of the phase plate is 0.1 mm or more, processing cost does not increase. Further, if the thickness of the phase plate is greater than 0.5 mm, the dependency of the retardation value becomes a problem, and the contrast performance when used in a liquid crystal projector is lowered, which tends to lead to a reduction in image quality.

  According to the sixth aspect of the invention, in addition to the above-described effects, the heat dissipation substrate having a thickness larger than that of the phase plate is attached to the main surfaces at both ends so as to sandwich the phase plate. Suppresses warping and distortion of the phase plate due to external factors such as adhesives or heat, and also warps and strains due to internal factors of the anisotropic crystal plate itself caused by variations in polishing accuracy. It can be modified to improve the parallelism and flatness of the principal surfaces at both ends of the phase plate. That is, the phase plate does not change the incident angle of the light beam incident on the main surface due to warping or distortion, so that a desired phase difference characteristic can be obtained and a phase plate that does not adversely affect the optical characteristics can be obtained. In addition, since the heat dissipation board with a large thickness is attached so as to sandwich the main surfaces at both ends of the phase plate, not only the strength and rigidity of the phase plate are reinforced, but also the main surface of the phase plate is damaged by external factors. No cracking or chipping occurs on the phase plate.

  According to claim 7 of the present invention, since the projector phase plate as described above is arranged close to the incident side of the liquid crystal display element, the liquid crystal display element by the light emitted from the light source and its Thermal radiation components (infrared rays) that lead to deterioration of related parts are removed before reaching the polarizing film of the liquid crystal display element, and the polarizing film and the liquid crystal display element do not deteriorate due to overheating. Therefore, the product life can be extended and the product life of the liquid crystal projector can be extended without degrading the optical characteristics (color and image quality) of the liquid crystal display element. Even if the various optical systems are arranged closer to each other, the adverse effect of the radiant heat from the outside of the optical path on the liquid crystal display element can be suppressed, so that the space can be saved and the liquid crystal projector can be downsized.

  Hereinafter, a first embodiment of the present invention will be described with reference to the drawings by taking a ¼ wavelength plate (quartz phase plate) as an example. FIG. 1 is an exploded perspective view of the phase plate according to the first embodiment, and FIG. 2 is a perspective view of the assembled state of FIG.

  As shown in these drawings, the quarter-wave plate (phase plate) 39 is composed of two quartz substrates (optical anisotropic crystal plates) 391 and 392. This will be specifically described below. Here, in FIG. 1 and FIG. 2, the near side is referred to as the incident surface, the quartz substrate on the near side is referred to as the first quartz substrate 391, and the far side (right side in FIG. 2) is defined as the exit surface. Is referred to as a second quartz substrate 392.

  Each of the quartz substrates 391 and 392 is configured in the same rectangular shape in plan view. The first quartz substrate 391 has an optical axis angle of 0 ° and a thickness dimension of, for example, 0.7 mm with respect to a reference plane (one side of the rectangular quartz substrate), and the second quartz substrate 392 has the optical axis angle described above. Is 90 ° and the thickness dimension is set to 0.715 mm. That is, the same function (equivalent polarization performance) as that of a phase plate made of a single crystal substrate having a thickness of 15 μm is obtained in a pseudo manner by utilizing a thickness difference of 15 μm. The thickness difference is not limited to 15 μm, and the thickness difference is appropriately set according to the incident light to be polarized. The first quartz substrate 391 and the second quartz substrate 392 are bonded together by the UV adhesive S1 in a state where the optical axis angles thereof are orthogonal to each other, and the total thickness T1 of the phase plate is about 1.5 mm. The optical axis of the first crystal substrate 391 is indicated by a solid line, and the optical axis of the second crystal substrate 392 is indicated by a broken line. Although not shown, dielectric thin films such as SiO 2 and TiO 2 are formed in multiple layers on the incident surface of the first crystal substrate 391 and the exit surface of the second crystal substrate 392 by a technique such as vacuum deposition. Thus, an antireflection film is formed.

  The feature of this embodiment is that the thickness T1 of the bonded quarter wavelength plate (phase plate) is 0.7 mm or more. For this reason, the durability of the quarter wave plate (phase plate) is improved and the heat dissipation is further enhanced, so that heat is not trapped in the liquid crystal display element, and further thermal deterioration of the liquid crystal display element and its related parts is achieved. Suppress. Further, since the thickness and the rigidity of the phase plate are increased by increasing the thickness of the quarter wavelength plate (phase plate), the quarter wavelength plate is caused by an external factor such as an optical coating material, an adhesive, or the influence of heat. It is suppressed that the (phase plate) is warped or distorted.

  In the first embodiment, the quartz substrate is used in which the optical axis angle of each quartz substrate is 0 ° and 90 °, and the angle between the optical axes is 90 °. The angle may be other than 0 ° and 90 °, and the angle formed by the optical axes may be set to less than 90 °.

  Next, a second embodiment of the present invention will be described with reference to the drawings. FIG. 3 is an exploded perspective view of the phase plate according to the second embodiment, and FIG. 4 is a perspective view of the assembled state of FIG.

  As shown in these figures, a quarter-wave plate (phase plate) 39 includes a quarter-wave plate (phase plate) composed of two quartz substrates (optically anisotropic crystal plates) 393 and 394, and The heat dissipation substrate 395 is made of crystal. This will be specifically described below. Here, in FIG. 3 and FIG. 4, the near side is referred to as an incident surface, the near side quartz substrate is referred to as a first quartz substrate 393, and the far side (right side in FIG. 4) is referred to as an exit surface, and the near side quartz substrate. Is referred to as a second quartz substrate 394.

  Each of the quartz substrates 393 and 394 and the heat dissipation substrate 395 are configured in the same rectangular shape in plan view. The first crystal substrate 393 has an optical axis angle of 0 ° with respect to a reference plane (one side of the rectangular crystal substrate) and a thickness dimension of 0.2 mm, for example, and the second crystal substrate 394 has the optical axis angle described above. Is 90 °, the thickness dimension is 0.215 mm, and the heat dissipation substrate 395 made of quartz is set to the optical axis angle 45 ° and the thickness dimension is 1 mm. The thickness difference between the first quartz substrate and the second quartz substrate is not limited to 15 μm, and this thickness difference is appropriately set according to the incident light to be polarized. The first crystal substrate 393 and the second crystal substrate 394 are orthogonal to each other in optical axis angle, and the heat dissipation substrate 395 is a 45 ° direction obtained by dividing the optical axis direction of each crystal substrate into two equal parts from the incident surface. The first crystal substrate 393, the second crystal substrate 394, and the heat dissipation substrate 395 are bonded together in this order by the UV adhesive S1, and the total thickness T21 of the phase plate is about 1.5 mm. The optical axes of the first crystal substrate 393 and the second crystal substrate 394 are indicated by solid lines, and the optical axis of the heat dissipation substrate 395 made of crystal is indicated by dotted lines. In a state where the optical axis is arranged in a direction rotated by 45 ° from the optical axis direction of any one of the quartz crystal substrates arranged orthogonal to each other, that is, the optical axis of the first quartz substrate. Since the optical axis of the heat dissipation substrate made of crystal is arranged at 45 ° with respect to the angle of 0 ° and the optical axis angle of 90 ° of the second crystal substrate, the phase difference constituted by the first crystal substrate and the second crystal substrate Does not adversely affect properties. The optical axis of the heat dissipation substrate may be arranged at 135 °, 225 °, or 315 °. Although not shown in the figure, dielectric thin films such as SiO 2 and TiO 2 are formed in multiple layers on the incident surface of the first quartz substrate 393 and the emission surface of the heat dissipation substrate 395 by a technique such as vacuum deposition. An antireflection film is formed.

  The feature of this embodiment is that the thickness T2 of the bonded quarter-wave plate (phase plate) is about 0.5 mm, and a heat dissipation substrate made of crystal is further bonded. The thickness T21 of the four-wave plate (phase plate) 39 is about 1.5 mm. That is, by making the thickness T2 of the quarter-wave plate (phase plate) 0.1 mm or more and 0.5 mm or less, it is easy to process, and the retardation value dependency on the incident angle is particularly reduced. The contrast performance when used in a liquid crystal projector can be dramatically improved. In addition, a heat dissipation substrate made of crystal is bonded to one end main surface of the thinned quarter-wave plate (phase plate) so that the thickness T21 of the quarter-wave plate (phase plate) 39 is 0.7 mm or more. Therefore, the durability of the quarter-wave plate (phase plate) is improved and the heat dissipation is further enhanced, so that heat is not trapped in the liquid crystal display element, and the thermal resistance of the liquid crystal display element and related parts is further increased. Suppress deterioration. Furthermore, by bonding the heat dissipation substrate, two adhesive layers are interposed, and this adhesive layer has a heat insulating effect, so that it is possible to suppress heat radiation that enters the inside of the optical system.

  Next, a third embodiment of the present invention will be described with reference to the drawings. FIG. 5 is an exploded perspective view of the phase plate according to the third embodiment, and FIG. 6 is a perspective view of the assembled state of FIG.

  As shown in these figures, a quarter-wave plate (phase plate) 39 includes a quarter-wave plate (phase plate) composed of two quartz substrates (optically anisotropic crystal plates) 393 and 394, and Two heat-radiating substrates 395 and 396 made of quartz having a thickness larger than that of the quarter-wave plate (phase plate) are attached to both principal surfaces of the quarter-wave plate (phase plate). . This will be specifically described below. Here, in FIG. 5 and FIG. 6, the near side is referred to as an incident surface, the near side quartz substrate is referred to as a first quartz substrate 393, and the far side (right side in FIG. 6) is defined as an exit surface. Is referred to as a second quartz substrate 394.

  The quartz substrates 393 and 394 and the heat dissipation substrates 395 and 396 are configured in the same rectangular shape in plan view. The first crystal substrate 393 has an optical axis angle of 0 ° with respect to a reference plane (one side of the rectangular crystal substrate) and a thickness dimension of 0.2 mm, for example, and the second crystal substrate 394 has the optical axis angle described above. Is 90 ° and the thickness dimension is set to 0.215 mm. The thickness difference between the first quartz substrate and the second quartz substrate is not limited to 15 μm, and this thickness difference is appropriately set according to the incident light to be polarized. The heat dissipating substrates 395 and 396 made of quartz are set to have a thickness dimension of 1 mm at the optical axis angle of 45 °. The first crystal substrate 393 and the second crystal substrate 394 are perpendicular to each other in optical axis angle, and the heat dissipation substrates 395 and 396 are 45 ° (or 135 °) obtained by dividing the optical axis direction of each crystal substrate into two equal parts. The direction is set. The heat radiation substrate 396, the first crystal substrate 393, the second crystal substrate 394, and the heat radiation substrate 395 are bonded together in this order from the incident surface, and the total thickness T31 of the phase plate is about 2.5 mm. The optical axes of the first crystal substrate 393 and the second crystal substrate 394 are indicated by solid lines, and the optical axes of the heat dissipation substrates 395 and 396 made of crystal are indicated by dotted lines. In a state where the optical axes are arranged in a direction rotated by 45 ° with respect to the optical axis direction of each quartz crystal substrate arranged orthogonal to each other, that is, the first quartz substrate. Since the optical axes of the two heat dissipating substrates made of crystal are arranged at 45 ° with respect to the optical axis angle of 0 ° and the optical axis angle of the second crystal substrate of 90 °, the first crystal substrate and the second crystal substrate There is no adverse effect on the phase difference characteristics. The optical axis of the heat dissipation substrate may be arranged at 135 °, 225 °, or 315 °. Although not shown in the figure, a dielectric thin film such as SiO 2 or TiO 2 is formed in multiple layers on the incident surface of the heat dissipation substrate 396 and the exit surface of the heat dissipation substrate 395 by a method such as a vacuum deposition method, thereby reflecting A prevention film is formed.

  The feature of this embodiment is that the thickness T3 of the bonded quarter-wave plate (phase plate) is about 0.5 mm, and the heat dissipation substrate made of quartz having a larger thickness is the quarter-wavelength. A thickness of the quarter-wave plate (phase plate) 39, which is affixed to both principal surfaces of the both ends of the plate (phase plate), is set to about 2.5 mm. That is, by setting the thickness T3 of the quarter-wave plate (phase plate) to 0.1 mm or more and 0.5 mm or less, processing can be easily performed, and the retardation value dependency on the incident angle is particularly reduced. The contrast performance when used in a liquid crystal projector can be dramatically improved. In addition, a heat dissipation substrate made of crystal is bonded to both end principal surfaces of the thinned quarter-wave plate (phase plate) so that the thickness T31 of the quarter-wave plate (phase plate) 39 is 0.7 mm or more. Therefore, the durability of the quarter-wave plate (phase plate) is improved and the heat dissipation is further enhanced, so that heat is not trapped in the liquid crystal display element, and further heat of the liquid crystal display element and related parts is obtained. Suppresses deterioration. Further, a quarter-wave plate (phase plate) is formed by pasting a heat dissipation substrate made of quartz with a larger thickness on both principal surfaces of the thinned quarter-wave plate (phase plate). Therefore, the quarter-wave plate (phase plate) is increased in strength and rigidity, and is made thinner by external factors such as optical coating materials, adhesives, and heat. Is suppressed from being warped or distorted, and the parallelism and flatness of the principal surfaces at both ends of the quarter-wave plate (phase plate) can be improved. In addition, the thinned quarter-wave plate (phase plate) is not damaged or chipped due to external factors. Furthermore, by bonding the heat dissipation substrate, three adhesive layers are interposed, and since this adhesive layer has a heat insulating effect, it is possible to suppress heat radiation that enters the inside of the optical system.

In the second and third embodiments described above, the crystal substrates having the optical axis angles of 0 ° and 90 ° are used and the angle between the optical axes is 90 °. The optical axis angle may be other than 0 ° and 90 °. In addition, although the quartz substrate is taken as an example of the heat dissipation substrate, the substrate is not limited to this, and the quartz substrate (optically anisotropic crystal plate) approximates the optical refractive index characteristic and the thermal expansion coefficient, for example, It can also be composed of quartz glass material, sapphire glass, white plate glass, or the like. Furthermore, in the third embodiment, the heat radiating substrates are made of the same material and the same thickness, but may be made of different materials and different thicknesses.

  Next, a reflection type liquid crystal projector incorporating a quarter wavelength plate (phase plate) or a quarter wavelength plate (phase plate) as disclosed in the first to third embodiments will be described with reference to the drawings. . FIG. 7 is a configuration diagram of a reflective liquid crystal projector according to this embodiment. The reflective liquid crystal projector of this embodiment includes a light source 1 such as a lamp that emits white light, a liquid crystal display element, other optical systems, and a screen. Projecting means for projecting onto the screen.

  The light source 1 includes, for example, an ultrahigh pressure mercury lamp, a metal halide lamp, and the like, and the liquid crystal display element includes three reflective liquid crystal display elements 2R respectively corresponding to the three primary colors of red (R), green (G), and blue (B). , 2G, 2B.

  The optical system is configured in the following order along the optical path from the light source. That is, the white light of the light source is divided into a plurality of light fluxes by the lens arrays 31 and 32, and the white light is changed by the PBS plate 33 for polarization, and the light from the light source is changed by the condenser lens 34. Collect and irradiate uniformly toward the optical path.

  The white light includes two dichroic mirrors 35 and 36 and a total reflection mirror 37, polarization beam splitters 38R, 38G, and 38B, and a quarter wavelength plate (or 1 / The light is guided to the area of the next liquid crystal display element along the optical path obtained by the four-wavelength plates 39R, 39G, and 39B. At this time, since the dichroic mirror 35 has a red transmission green-blue reflection type characteristic and the dichroic mirror 36 has a blue transmission green reflection type characteristic, the white light is R (red) · G. While being separated into the three primary colors (green) and B (blue), they are led to the liquid crystal display elements 2R, 2G, and 2B corresponding to the three primary colors. At this time, the light of each of the three primary colors is aligned with the S polarization component by a polarizing plate (not shown), and unnecessary P polarization components are removed, and only the S polarization component of each of these three primary colors is converted into each polarization beam. The light enters the splitters 38R, 38G, and 38B. Each incident S-polarized component is reflected by the polarization beam splitter, passes through the quarter-wave plates (or quarter-wave plates) 39R, 39G, and 39B and is converted into circularly-polarized component light, The light enters the liquid crystal display elements 2R, 2G, and 2B.

  Each of the liquid crystal display elements 2R, 2G, and 2B includes a polarizing film 4R, 4G, and 4B at an incident portion, respectively, and polarizes a light component in the liquid crystal axis direction of the liquid crystal display element, and has a specific polarization axis direction. It is configured to transmit and block light components. These polarizing films are made of a resin film. The quarter wave plates (or quarter wave plate bodies) 39R, 39G, and 39B are arranged in close contact with the incident side of the polarizing film of each liquid crystal display element. These liquid crystal display elements modulate the light transmitted through the liquid crystal display element by changing the shading by controlling the amount of light for each pixel according to image information.

  The rotationally polarized light components thus modulated are reflected from the liquid crystal display elements 2R, 2G, and 2B, and pass through the quarter-wave plates (or quarter-wave plates) 39R, 39G, and 39B again. At the same time, it is converted into a P-polarized light component and is incident on each of the polarization beam splitters 38R, 38G, and 38B. Each incident P-polarized component passes through the polarization beam splitter and enters the dichroic prism 5. The dichroic prism 5 combines R (red), G (green), and B (blue) light, and the projection lens 6 projects an image on the screen 7. Further, the reflection type liquid crystal projector of the present embodiment is provided with a cooling fan (not shown), and can radiate heat absorbed by the liquid crystal display element and the polarizing film by being irradiated from the light source 1 and can be cooled. It is configured as follows.

  As described above, the ¼ wavelength plate (phase plate) or the ¼ wavelength plate (phase plate) configured as in the first to third embodiments is provided on the incident side of each liquid crystal display element. Since they are arranged close to each other, thermal radiation components (infrared light) that lead to deterioration of the liquid crystal display element or polarizing film due to the light emitted from the light source are removed before reaching the polarizing film of the liquid crystal display element. The liquid crystal display element does not deteriorate due to overheating. Therefore, the product life can be extended and the product life of the liquid crystal projector can be extended without degrading the optical characteristics (color and image quality) of the liquid crystal display element. Even if the various optical systems are arranged closer to each other, the adverse effect of the radiant heat from the outside of the optical path on the liquid crystal display element can be suppressed, so that the space can be saved and the liquid crystal projector can be downsized.

-Other embodiments-
In the above-described embodiment, the case where a quarter-wave plate made of a quartz substrate is used as the phase plate has been described. However, the present invention is not limited to this, and other optical anisotropic materials or other optical materials can be used. A phase plate having characteristics can also be implemented. In addition, the phase plate is not limited to a rectangular shape, and may be other polygonal shapes or circular shapes. In the above-described embodiment, the reflective liquid crystal projector is taken as an example, but it can also be used for other liquid crystal projectors such as a transmissive liquid crystal projector.

The disassembled perspective view of the phase plate which concerns on 1st Embodiment. The perspective view of the state which assembled FIG. The disassembled perspective view of the phase plate which concerns on 2nd Embodiment. The perspective view of the state which assembled FIG. The disassembled perspective view of the phase plate which concerns on 3rd Embodiment. The perspective view of the state which assembled FIG. 1 is a configuration diagram of a reflective liquid crystal projector according to the present embodiment. Comparison graph showing the operating time of the liquid crystal projector and the surface temperature for each thickness of the phase plate.

Explanation of symbols

1 Light source 2R, 2G, 2B Liquid crystal display element 31, 32 Lens array 33 Polarizing PBS plate 34 Condenser lens 35, 36 Dichroic mirror 37 Total reflection mirror 38R, 38G, 38B Polarizing beam splitter 39, 39R, 39G, 39B Wavelength Plate (wavelength plate)
4R, 4G, 4B Polarizing film 5 Dichroic prism 6 Projection lens 7 Screen

Claims (7)

Adjacent to the incident side of the liquid crystal display element, a plurality of optically anisotropic crystal plates with different thicknesses are bonded together, and the incident light is split into ordinary and extraordinary rays, with a phase difference between these two rays. In the projector phase plate that changes the optical characteristics of the incident light by providing the thickness, the thickness of the bonded phase plate is 0.7 mm or more and 4 mm or less. Adjacent to the incident side of the liquid crystal display element, a plurality of optically anisotropic crystal plates with different thicknesses are bonded together, and the incident light is split into ordinary and extraordinary rays, with a phase difference between these two rays. In the projector phase plate that changes the optical characteristics of the incident light beam by applying a heat radiation substrate to the main surface of one end of the phase plate to form a phase plate body Phase plate. The projector phase plate according to claim 2, wherein the thickness of the bonded phase plate body is 0.7 mm or more and 4 mm or less. The phase plate and the heat radiating substrate are made of a quartz substrate, and the phase plate is bonded together in a state where the optical axes are arranged in a direction orthogonal to each other. 4. A crystal substrate used as a heat dissipation substrate is bonded to any one of the main surfaces of the phase plate in a state where an optical axis is arranged in a rotated direction. The phase plate for projectors as described. The projector phase plate according to any one of claims 2 to 4, wherein a thickness of the bonded phase plate is 0.1 mm or more and 0.5 mm or less. 6. The phase plate for a projector according to claim 5, wherein a heat radiating substrate having a thickness larger than that of the phase plate is attached to both principal surfaces of the phase plate to constitute a phase plate body. A projector phase plate according to any one of claims 1 to 6, a light source, a liquid crystal display element that modulates the intensity of transmitted light according to image information, and the modulated optical information is projected. A liquid crystal projector comprising a projecting unit, wherein the projector phase plate is disposed close to an incident side of the liquid crystal display element.

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