KR20110062816A - Prism array for polarization beam splitting and the polarization converting module - Google Patents

Abstract

PURPOSE: A polarization separation prism array and a polarization converting system comprising the same are provided to have good polarization efficiency, by preventing the loss of light intensity. CONSTITUTION: A polarization separation prism array comprises a number of prisms(51) with slops(52). The prism array comprises an incident plane(53) and an output plane(54). Polarization coating films(55,56) and anti-reflection coating films(57,58) are formed on the slope. The anti-reflection coating films are sloped toward the output plane. The polarization coating films are located between the anti-reflection coating films.

Description

Prismatic array for polarization beam splitting and the polarization converting module

The present invention relates to a polarization separation prism array and a polarization conversion system having the same, and more particularly, is provided to polarize most of the light emitted from the light source so that almost no loss of light is generated and the polarization efficiency is excellent. A polarization separation prism array having a structure and a polarization conversion system having the same.

In general, a polarization converting system (PCS) is a non-polarized light emitted from an arc light source such as a metal halide lamp or a xenon lamp or a conventional LED light source attached to a parabolic reflector. In order to convert the light into polarized light in one direction, it is generally used in projection imaging apparatuses including liquid crystal display (LCD) projectors or liquid crystal on silicon (LCOS) projectors.

The polarization conversion system and the conventional polarization separation prism array provided therein will be described with reference to the drawings. As shown in FIG. 1, the polarization conversion system 10 is usually provided with a field lens 12 so as to focus unpolarized light emitted from a light source 11 such as an LED. The polarized light separating prism array 13 is formed to pass the focused light to polarize the light.

Here, the polarization separation prism array 13 allows a pair of rectangular prisms 14 to be coupled to each other with the inclined surface 15 and at the same time forms a polarizing coating film at the position of the inclined surface 15 to form one prism assembly. The prism assembly is formed such that a plurality of the prism assemblies are stacked so as to be stacked in the longitudinal direction, thereby allowing the P-polarized light and the S-polarized light to pass orthogonally intersect among the non-polarized light emitted from the light source 11.

In addition, the polarization separation prism array 13 changes the traveling direction of the polarized light (S polarized light) reflected among P polarized light or S polarized light, and at the same time, converts the phase to have the same wavelength characteristic for the polarized light (P polarized light) passing through the prism assembly. The plate-shaped lambda / 2 plate 16 may be further included.

However, the conventional polarization conversion system 10 is not provided so that the light emitted from each light source 11 is directly incident, but is provided to be incident after the light is focused through the field lens 12, In the process, a part of the light may not be transmitted to the polarization separation prism array 13 and may not only be lost, but also the polarization efficiency may be lowered. There is a problem that (11) should be provided, and therefore, there is a risk of loss of energy.

In addition, in the conventional polarization splitting prism array 13, when P-polarized light and S-polarized light pass by the prism assembly, in contrast to P-polarized light that passes directly through the prism assembly in the case of S-polarized light, other adjacent prism assemblies Since the light is passed through the λ / 2 plate 16 after being reflected, it is a structural hassle for the field lens 12 to be provided so as to focus on one of the two prism assemblies.

In addition, as the field lens 12 is provided between the light source 11 and the polarization separation prism array 13, the manufacturing trouble of precisely matching the position of the polarization separation prism array 13 and the field lens 12 is required. Not only does it have a lot of troubles, but there is a limitation in making a thin thickness due to the characteristics of the structure, which makes it difficult to apply to miniaturized products.

The present invention is to solve the problems as described above, the present invention is provided to polarize most of the light emitted from the light source so that almost no loss of the amount of light is generated, the polarization efficiency is excellent, and also the compact size The present invention provides a polarization separation prism array having a new structure and a polarization conversion system having the same, which can be easily applied to miniaturized products and provide convenience in manufacturing.

According to the present invention, a plurality of prisms 51 having inclined surfaces 52 are provided, the prisms 51 being coupled to each other to form a bar or plate shape; A prism array 50 in which an incident surface 53 on which light emitted from the light source 31 is incident is formed on one surface thereof, and an emission surface 54 on which light is emitted on the other surface thereof;

On the plurality of inclined surfaces 52 to which the prisms 51 are coupled to each other, polarization coating films 55 and 56 that transmit or reflect light incident through the incident surface 53 by polarization separation, and the polarization coating films 55 and Reflection coating films 57 and 58 are formed to reflect the polarized light reflected by 56 to the exit surface 54;

The reflective coating layers 57 and 58 may be inclined toward the exit surface 54, but may be spaced apart from each other to define a range of the incident surface 53. A coating film 58;

The polarizing coating layers 55 and 56 are positioned between the reflective coating layers 57 and 58 so as to correspond to the incident surface 53, and are parallel to the first reflective coating layer 57 and the second reflective coating layer 58, respectively. A polarization splitting prism array is provided, comprising a first polarization coating film 55 and a second polarization coating film 56 that are inclined so as to be inclined.

According to another feature of the present invention, the polarization separation prism array 50 has the light source 31 proximate to the incident surface 53 side, the polarization separation prism array 50 and the light source 31 are each A polarization conversion system is provided, characterized in that the center is located in a straight line and at the same time the light by the light source 31 emits light directly to the incident surface 53.

As described above, according to the present invention, the light source 31 and the polarization separation prism array 50 are disposed in a straight line, and the light emitted from the light source 31 passes directly through the polarization separation prism array 50. Since it is provided so as to, there is no need to provide a separate field lens 12 for focusing the light emitted from the light source 31 as in the prior art to simplify the overall configuration can reduce the manufacturing hassle and cost In addition, the polarization conversion system 30 of the present invention by such a configuration can be formed relatively thin thickness has an advantage that can be easily applied to a thin film or miniaturized products.

In addition, the light source 31 and the polarization separation prism array 50 is disposed close to each center is arranged in a straight line so that the light by the light source 31 can be directly incident on the polarization separation prism array 50. As it is possible to enter the polarization separation prism array 50 with little loss of light emitted by the light source 31 being generated, not only the loss of light amount is generated but also the same number of light sources. There is an advantage that can increase the polarization efficiency in the condition provided with (31).

In addition, the polarization separation prism array 50 of the present invention is provided so that the light is polarized by the polarization coating film (55, 56) located in the center to be reflected by the reflection coating film (57, 58) on both sides, the light source 31 Since the exit surface 54 can be formed with a relatively large area compared to the diameter of the c), fewer light sources 31 are required for the same polarization efficiency, thereby reducing the number of light sources 31 and simultaneously. There is an advantage that can reduce the power loss.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 2 schematically shows a configuration according to an embodiment of the present invention. As shown in FIG. 2, the polarization conversion system 30 of the present invention includes a polarization splitting prism array 50 having a plurality of prisms 51 coupled to each other and having a bar shape having a predetermined thickness. On one side of the polarization separation prism array 50, a light source 31 provided in a form coupled to a PCB substrate is disposed close to each other.

In this configuration, the polarization separation prism array 50 is a prism 51 having the inclined surface 52 are coupled to each other to form a bar shape, the prism 51 is mutually coupled to the light source 31 on one surface An incidence surface 53 through which light emitted from the light is incident is formed, and an emission surface 54 through which polarized light is emitted on the other surface is formed, and the prism 51 is formed in a substantially right triangle, an isosceles triangle, or parallelogram shape. It is provided with at least one inclined surface 52 is formed, the inclined surface 52 or each surface is coupled to each other.

Here, when the inclined surfaces 52 of the respective prisms 51 are coupled to each other, polarization coating films 55 and 56 or reflection coating films 57 and 58 are formed on the inclined surfaces 52 to separate incident light and polarize the light. In this case, the light is separated into P-polarized light and S-polarized light orthogonal to the P-polarized light by the polarized coating films 55 and 56, and the P-polarized light is polarized coating films 55 and 56. ) Is directly passed through the exit surface 54, the S-polarized light is reflected by the polarizing coating film (55, 56) to the reflective coating film (57, 58) and then exit to the exit surface (54) .

In this configuration, the reflective coating films 57 and 58 are composed of a first reflective coating film 57 and a second reflective coating film 58 whose reflection surfaces are inclined toward the exit surface 54. The reflective coating film 57 and the second reflective coating film 58 are provided at a distance from each other so that the range of the incident surface 53 is limited by the distance.

In addition, the polarization coating films 55 and 56 are positioned between the reflection coating films 57 and 58 so as to correspond to the incident surface 53 of the polarization split prism array 50. The polarization coating films 55 and 56 are formed of the first coating. A first polarizing coating film 55 and a second polarizing coating film 56 provided to be parallel to the first reflective coating film 57 and the second reflective coating film 58, respectively.

Here, the reflective coatings (57, 58) is a mirror coating having a normal mirror function or similar to the polarizing coating film (55, 56) is a polarizing coating that can pass a specific polarization and reflect other polarization at the same time The reflective coatings 57 and 58 may be provided as polarization coatings because the polarized light reflected by the polarization coatings 55 and 56 may be reflected again by polarization coating.

On the other hand, in the polarization conversion system 30 including the polarization separation prism array 50 as described above, the light source 31 is disposed close to the incident surface 53 side, the light source 31 and the polarization separation prism The array 50 is provided such that each central portion is located in a straight line, and the light emitted by the light source 31 is directly emitted to the incident surface 53. In this structure, polarization separation from the light source 31 is performed. There is no need for a separate field lens 12 as in the prior art between the prism arrays 50.

Here, the incident surface 53 of the polarization separation prism array 50 is formed to substantially match the diameter of the light source 31, the exit surface 54 is 2 compared to the diameter of the light source 31 Although it is preferable to form about twice as large, it is not limited to this specification.

As described above, the light emitted from the light source 31 is mostly incident on the incident surface 53 to minimize the loss of the amount of light, and the polarization separation prism array 50 after the polarization is separated at the center thereof. The light source 31 and the polarization separation prism array 50 correspond to one-to-one as well as the structure provided to be reflected to both sides, thereby reducing the number of the light sources 31 compared to the system having the same polarization efficiency. At the same time, power consumption can be reduced.

Reference numerals not described above indicate a conventional phase delay plate 32. The phase delay plate 32 is provided on the exit surface 54 to enable conversion of P polarization or S polarization. The position of the phase delay plate 32 may be appropriately selected depending on the polarization to be converted.

In addition, such a phase delay plate 32 can convert P-polarized light (or S-polarized light) into S-polarized light (or P-polarized light) when it is provided with λ / 2 plates 16 as described in the prior art. When the phase delay plate 32 is provided with λ / 4 plate or 3λ / 4 plate, not only can the P polarized light (or S polarized light) be converted into left circularly or right circularly polarized light, but also λ / 4 plate as necessary. By using only the optical axis of the λ / 4 plate can be provided to have a phase difference (about 45 degrees) with respect to P polarized light (or S polarized light), and can be converted into a desired left circularly polarized light or right circularly polarized light, which is similar to the conventional one, and also described. Other unsigned symbols S and P represent S polarization and P polarization, respectively.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a configuration diagram showing an example of a conventional polarization conversion system

2 is a block diagram showing an embodiment of the present invention

Claims (2)

A plurality of prisms 51 having inclined surfaces 52 are provided, the prisms 51 being coupled to each other to form a bar or plate shape; A prism array 50 in which an incident surface 53 on which light emitted from the light source 31 is incident is formed on one surface thereof, and an emission surface 54 on which light is emitted on the other surface thereof; On the plurality of inclined surfaces 52 to which the prisms 51 are coupled to each other, polarization coating films 55 and 56 that transmit or reflect light incident through the incident surface 53 by polarization separation, and the polarization coating films 55 and Reflection coating films 57 and 58 are formed to reflect the polarized light reflected by 56 to the exit surface 54; The reflective coating layers 57 and 58 are formed to be inclined toward the exit surface 54, and the first reflective coating layer 57 and the second reflective coating layer are formed to be spaced apart from each other to limit the range of the incident surface 53. Consisting of 58; The polarizing coating layers 55 and 56 are positioned between the reflective coating layers 57 and 58 so as to correspond to the incident surface 53, and are parallel to the first reflective coating layer 57 and the second reflective coating layer 58, respectively. Polarizing separation prism array, characterized in that consisting of the first polarizing coating film 55 and the second polarizing coating film 56 inclined to. The light source 31 is disposed close to the incident surface 53 side of the polarization split prism array 50 of claim 1, and the central portions of the polarization split prism array 50 and the light source 31 are located in a straight line. And light emitted by the light source 31 to emit light directly to the incident surface 53.

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