KR20090070628A - Infrared wave cut filter and its manufacturing method - Google Patents

Abstract

An infrared ray shielding filter implementing a slimed optical system and manufacturing method thereof are provided to decrease the number of processes forming an infrared absorbing material by adding an infrared absorbing material in a lens resin material. One or more lens(31) is formed with a resin material, and transmits light from outside. An infrared ray shielding filter(10) is formed by plasma coating on one side of the lens. A photosensitive element is arranged on a rear side of the lens. The photosensitive element detects the light delivered through the lens and the filter.

Description

Infrared wave cut filter and its manufacturing method

The present invention relates to an infrared cut filter, and more particularly, to an infrared cut filter used by replacing an infrared absorber in part of an infrared cut filter formed of a multilayer film composed of 30 to 40 layers.

The conventional infrared cut filter is formed of a multilayer film, and is composed of about 30 or more and 40 layers, and consists of two stacks.

1-Stack; 650nm to 900nm block (15 or more layers)

2-Stack; 900nm ~ 1100nm area blocking (more than 15 layers)

A filter made of a multilayer film requires two stacks, one of which is to reduce the difficult process of making a multilayer film using infrared absorbers in half.

As the demand of the portable communication device market, which is in the spotlight, has increased recently, cameras are increasingly installed as a part of communication devices, and cameras have a function of reading information in the visible light region and converting them into images and images. These modules tend to be smaller in size to meet the purpose of portable devices. Due to the small size of the module, there is a need to secure a space in order to increase the degree of freedom of lens design in a limited area.

1 is a cross-sectional view of a camera lens module used in a conventional portable communication device. In the conventional camera lens module, a lens and a photosensitive sensor are arranged in the upper and lower housings 21 and 22. The photosensitive sensor 1 is mounted on an upper surface of the lower housing 22, and a plurality of lenses 11 are arranged on the photosensitive sensor 1. An infrared cut filter glass 10 is arranged between the lens 11 and the photosensitive sensor 1.

Our eyes can only see visible light between wavelengths 380 and 770 nm, a specific area of electromagnetic waves. This wavelength range spreads from the purple of the rainbow to the red and when combined adds white light. The human eye has three light receptor cells that are sensitive to blue, green, and red, respectively, to distinguish many colors.

On the other hand, the photosensitive sensor (CCD) of the camera can see the wavelength of a wider area than the human eye as light. Thus, the CCD or CMOS sensor still recognizes an infrared region of 700 nm or more that is invisible to humans. As a result, the image of the camera is displayed as it is. To prevent this, an infrared cut filter (ICF) is installed inside the camera.

2 is a view showing the function of such an infrared cut filter 10. Light entering the lens module of the camera has a wavelength band as shown in FIG. Here, the function of the infrared cut filter is to block the light in the area beyond the photosensitive sensor so as not to detect the light of more than 700 nm in the infrared region.

3 shows a wavelength band of light detected by the photosensitive sensor when the infrared cut filter is used. In Figure 3 it can be seen that the light of the infrared wavelength band of more than about 700nm is not detected.

Such an infrared cut filter 10 is formed separately from the lens, as shown in Figure 1, in particular is formed by coating a glass lens. Conventional infrared cut filter is formed on the glass plate by a vacuum deposition method, to increase the temperature inside the vacuum chamber to increase the adhesion of the film.

However, when the infrared cut filter is used separately from the lens in this manner, the size of the entire module cannot be reduced, and if the assembly is performed, the number of process parts is increased, thereby increasing the number of assembly processes of the product. In addition, a subsidiary material (adhesive agent) for attaching the filter glass 10 to the housing is required in the manufacturing process, and management and inspection are required accordingly, thereby increasing the frequency of actual defects and becoming an obstacle to process improvement.

In particular, when attaching the infrared cut filter to the lens module, the adhesive is often attached to the filter surface or the lens surface to cause a failure of the entire module is often a big problem. Due to such an assembly mistake, about 5% of the modules are typically discarded due to defects. Therefore, research into the lens module structure for reducing such manufacturing defects has been continued in the art.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to form a part of a stack of infrared cut filter as an infrared absorber to reduce a difficult process of forming a multilayer film and to manufacture a more efficient infrared cut filter.

In the infrared cut filter, the infrared absorbing material is put into the lens resin material to be used. In addition, by providing an infrared absorbing material to the resin material provides a slim optical system. In addition, the present invention can enable a multilayer film for making an infrared cut filter to 20 layers (or 15 layers or less) or less.

In another aspect, the present invention, the camera lens module, formed of a resin material, at least one lens for transmitting light from the outside; An infrared cut filter formed by plasma coating on one surface of the lens; And a photosensitive element arranged at a rear side of the lens and sensing the light entering through the lens and the filter.

Preferably, one surface of the lens on which the infrared cut filter is formed may be formed such that the normal of the interface at which the light is incident and the incident path of the light substantially match. More preferably, the lens on which the infrared cut filter is formed may be formed of light. It is characterized in that it is formed to protrude in the same direction as the entry direction.

In this case, the infrared cut filter may be formed on the front surface or the rear surface of the lens. Also preferably, the plasma coating of the infrared cut filter is performed by a plasma source and an electron beam evaporator.

The present invention also provides a camera lens module comprising: a first lens formed of a resin material and configured to refract and transmit light incident from the outside to be close to a normal line of an interface; A second lens having an infrared cut filter formed thereon and including one surface formed to substantially coincide with a normal line of an interface at which light enters and an incident path of light; It is arranged on the rear side of the second lens, and provides a lens module with an infrared cut filter comprising a; photosensitive element for sensing the light entering through the lens and filter.

Preferably, one surface of the second lens is formed to protrude in the same direction as the light entering direction, and one surface of the second lens may be a front surface or a rear surface. Also preferably, at least one surface of the first lens has a convex shape.

The present invention has the effect of reducing the difficult process of forming a multilayer film by forming a part of the stack of the infrared cut filter with the infrared absorber, it is possible to implement a slimmer optical system.

In the infrared cut filter, the infrared absorbing material is put into the lens resin material to be used. In addition, by providing an infrared absorbing material to the resin material provides a slim optical system. In addition, the present invention can enable a multilayer film for making an infrared cut filter to 20 layers (or 15 layers or less) or less.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 4 is a view showing an infrared cut filter integrated camera lens module according to the present invention.

The present invention is characterized in that an infrared cut filter is formed on any one lens of the lens group including at least one lens. The lens is a transparent synthetic resin material, and the curvature and the gap between the lenses vary depending on the design of the lens module.

Since the lens is made of plastic, there is a problem in that it is difficult to use a method used as it is when forming an infrared cut filter on a conventional glass material. In the conventional case, the glass lens (or glass plate) made of glass is heated to a high temperature of about 300 ° C., whereby sufficient energy forms a dense film without defects. This is called a vapor deposition process, and if the lens is made of plastic, the lens is bent or deformed, and thus there is a problem that it is difficult to apply such a conventional method.

Therefore, the present invention has applied a plasma coating method in which the film properties are continuously changed while the film is formed on the plastic lens. Plasma coating is achieved by introducing a film forming material such as an evaporator under a plasma atmosphere.

By plasma coating, an infrared cut filter (IR-cut) can be formed on the plastic lens surface, thereby removing the infrared cut filter glass that is conventionally used separately.

Since the infrared cut filter glass 10 can be removed, a great effect on the process is obtained. That is, in the process of attaching a conventional filter glass, a material such as an adhesive, which is used as an attachment means, flows into the lens housing or adheres to the lens surface to cause a defect of the lens module. Such a failure rate is about 5 ~ 10%, if a failure occurs, the lens module itself is disposed of at all. As a result, a huge cost is lost.

However, when the infrared cut filter is integrally formed on the lens surface as proposed in the present invention, the filter glass is not used separately, and thus an additional attachment process may be omitted in the lens module. Omission of such a process can eliminate the cause of defects caused by the adhesion, which leads to a breakthrough innovation of the process.

On the other hand, the infrared cut filter formed on the lens surface by the plasma coating is most preferably designed so that light is incident perpendicular to the interface in order to increase the conversion efficiency. Therefore, the present invention proposes a structure that can form an infrared cut filter on the surface of the lens so that the use of a separate infrared cut filter lens can be omitted, and also the efficiency of the infrared cut filter is most enhanced.

5 is a view showing a path of light incident on the lens of the lens module according to the present invention, Figure 6 is a view showing a light incidence path in the case of using a conventional infrared cut filter glass.

When the infrared cut filter glass is removed and the infrared cut filter film is formed on the lens surface, it is most preferable that the incident angle of the light passing through the filter film a is perpendicular to the interface.

The lens module according to the present invention includes a first lens 31 on the front surface and a second lens 32 arranged on the rear side of the first lens. The first lens 31 refracts the light incident from the outside to be close to the normal of the boundary surface and transmits the light to the rear side. Light transmitted to the rear side is incident on the second lens 32.

In this case, the light incident on the first lens 31 may include light L1 perpendicular to the boundary surface, and light L2 and L3 having an angle of incidence that is not vertical. The double vertical light L1 is incident on the second lens via the first lens while keeping the normal of the boundary surface as it is. When the light L2 and L3 that are not perpendicular are refracted while passing through the first lens and are incident on the second lens, the light L2 and L3 are incident in a vertical state to some extent.

However, L2 and L3 light is difficult to be refracted in a completely vertical state as it passes through the first lens. This is because the size of the lens module is small and there is a problem in that the number of lenses to be stacked is reduced as much as possible, so that it is difficult to make the incident light into a vertical incident state by overlapping several lenses.

Therefore, in the present invention, the lens surface on which the infrared cut filter is formed is formed such that the angle of incidence of the light is nearly 0 degrees, that is, the normal of the boundary surface where the light is incident and the incident path of the light substantially coincide. 5 shows a schematic shape of such a lens. Both surfaces of the first lens 31 are convex, thereby refracting light close to vertical, and an infrared cut filter is formed on the front surface a of the second lens 32, and the infrared cut filter surface a The filter surface is formed to have a predetermined curvature so that the incident light is incident almost vertically.

In particular, the filter surface a is formed to protrude in the same direction as the entrance direction of light. The filter surface a may be formed on the front surface a of the second lens, and may also be formed on the rear surface b. When formed on the rear surface, the light is incident on the second lens, and the effect of refraction can be obtained once again, which may be more efficient.

However, the infrared blocking filter forming surface (a or b) should be formed of a lens so as to project in the direction of the light travel. Therefore, the front side of the second lens may have a concave lens, and the rear side may have a convex lens shape.

In FIG. 5 and FIG. 6, the light L3 and L4 at the most lateral side will be described.

5, it can be seen that L3 has a path substantially coincident with the normal line d perpendicular to the filter forming surface (a) of the lens and its boundary surface (c). This is because the filter forming surface (a) of the lens is formed to have a predetermined curvature, thereby maximizing the infrared blocking efficiency through the filter.

However, it can be seen from FIG. 6 that L4 does not coincide with the normal c of the interface f and is incident with a considerable angle difference.

According to the present invention, since the infrared cut filter glass is removed by forming an infrared cut filter on at least one surface of the lens, the available space of the photosensitive sensor portion can be increased even when using a module housing having the same size as before. Therefore, it is possible to use a photosensitive sensor with much improved performance than before. In addition, when using the photosensitive sensor as in the past it is possible to reduce the height, volume of the lens module, which reduces the volume occupied by the camera lens module can increase the design freedom of the device using the camera lens module.

1 is a cross-sectional view of a conventional camera lens module.

FIG. 2 is a graph showing the function of the infrared cut filter and shows sensitivity characteristics for each wavelength band.

3 is a graph showing sensitivity characteristics for each wavelength band when an infrared cut filter is used.

4 is a cross-sectional view of an infrared cut filter integrated lens module according to the present invention.

Explanation of symbols on the main parts of the drawings

1: photosensitive sensor 10: infrared cut filter glass

31, 32, 33: lens 21, 22: housing

Claims (11)

In the camera lens module, At least one lens formed of a resin material and transmitting light from the outside; An infrared cut filter formed by plasma coating on one surface of the lens; And And a photosensitive element arranged at a rear side of the lens and configured to sense light entering through the lens and the filter. The lens module of claim 1, wherein one surface of the lens on which the infrared cut filter is formed is formed such that a normal line of an interface at which light is incident coincides with an incident path of light. The lens module of claim 2, wherein the lens on which the infrared cut filter is formed is formed to protrude in the same direction as the entrance direction of the light. The lens module of claim 3, wherein the infrared cut filter is formed on a front surface of the lens. The lens module of claim 3, wherein the infrared cut filter is formed on a rear surface of the lens. The lens module of claim 1, wherein the plasma coating of the infrared cut filter is performed by a plasma source and an electron beam evaporator. In the camera lens module, A first lens formed of a resin material and transmitting and refracting light incident from the outside to be close to a normal line of an interface; A second lens having an infrared cut filter formed thereon and including one surface formed to substantially coincide with a normal line of an interface at which light enters and an incident path of light; And a photosensitive element arranged at a rear side of the second lens and configured to sense light entering through the lens and the filter. The lens module of claim 7, wherein one surface of the second lens protrudes in the same direction as the entrance direction of light. The lens module of claim 8, wherein one surface of the second lens is a front surface. The lens module of claim 8, wherein one surface of the second lens is a rear surface. The lens module of claim 8, wherein at least one surface of the first lens has a convex shape.

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