KR20210019854A - Zinc sulfide sintering and infrared transmission lens having the same - Google Patents

Abstract

According to an embodiment of the present invention, an infrared transmitting lens comprises one surface and the other surface. The surface roughness (Ra) of at least one of one surface and the other surface is 30 nm to 100 nm. The infrared transmitting lens contains sintered zinc sulfide. The sintered zinc sulfide includes a plurality of zinc sulfide crystals. The ratio of the interface between the zinc sulfide crystals is 1%/mm^2 to 5%/mm^2.

Description

Zinc sulfide sintered body and infrared transmission lens including the same {ZINC SULFIDE SINTERING AND INFRARED TRANSMISSION LENS HAVING THE SAME}

The embodiment relates to a zinc sulfide sintered body and an infrared transmitting lens including the same.

The infrared sensing device is a device that detects infrared rays emitted from an object. Among them, the thermal image sensing device is a device that detects infrared rays emitted from the object and then images them into visible light that the user can recognize through the display device.

Such infrared sensing devices are applied to thermal imaging camera systems such as night vision goggles, night vision for vehicles, and security/surveillance cameras in the military or private fields along with lenses that transmit infrared rays.

In particular, with the commercialization of external infrared cameras that have been reduced in size to a level that can be installed and used on smartphones, infrared camera modules will be reduced in size so that they can be embedded in various types of mobile electronic devices. The resolution is also expected to increase.

Such an infrared transmitting lens is manufactured using a material that transmits infrared rays. For example, the infrared-transmitting lens may produce an infrared-transmitting lens by crystal-growing germanium, silicon, zinc sulfide, etc., which can transmit infrared rays, in an ingot shape, and then processing it into a lens shape.

As an example, the infrared transmission lens may be formed by crystallizing zinc sulfide in the form of an ingot and then further processing it to manufacture an infrared transmission lens.

But. When additional processes such as molding after ingot growth are performed, scattering increases due to the crystal characteristics and internal characteristics of the zinc sulfide sintered body, a separate surface treatment process is required, and the time of the zinc sulfide sintered body manufacturing process may be increased. .

Accordingly, there is a need for a zinc sulfide sintered body having an improved infrared transmittance and an infrared transmitting lens including the same without requiring a separate surface treatment process.

The embodiment is to provide a zinc sulfide sintered body having improved infrared transmittance and an infrared transmission lens including the same.

The infrared transmitting lens according to the embodiment includes one surface and the other surface, the surface roughness (Ra) of at least one surface of the one surface and the other surface is 30 nm to 100 nm, and the infrared transmitting lens includes a zinc sulfide sintered body, , The zinc sulfide sintered body includes a plurality of zinc sulfide crystals, and the ratio of the interface of the zinc sulfide crystals is 1%/mm2 to 5%/mm2.

The infrared transmission lens according to the embodiment may include a zinc sulfide sintered body.

In addition, the infrared transmission lens may have a surface roughness of about 30 μm or more, and may have an infrared transmittance of about 68% or more, preferably 68% to 75%, without a separate surface processing.

That is, the infrared transmission lens according to the embodiment may minimize scattering of infrared rays passing through the infrared transmission lens by controlling the ratio of the crystal interface and the size of the pores of the zinc sulfide sintered body constituting the infrared transmission lens.

Accordingly, the infrared transmissive lens according to the embodiment has a surface roughness of about 30 μm or more, but by controlling the crystal characteristics and pores of the infrared transmissive lens to minimize scattering of infrared rays, it has a high infrared transmittance, that is, an infrared transmittance of 68% or more. I can.

In addition, in order to reduce the surface roughness of the infrared transmission lens, since a separate surface processing treatment is not required, the process efficiency of the infrared transmission lens can be improved.

Accordingly, the infrared transmitting lens according to the embodiment may be easily manufactured and may have an improved infrared transmittance.

1 is a view showing a perspective view of an infrared transmission lens according to an embodiment.
2 is a view showing a side view of an infrared transmitting lens according to an embodiment.
FIG. 3 is an enlarged view of area B of FIG. 2.
FIG. 4 is an enlarged view of area C of FIG. 2.
5 is a flowchart illustrating a manufacturing process of an infrared transmitting lens according to an embodiment.
6 and 7 are diagrams for explaining a process of manufacturing an infrared transmitting lens according to an embodiment.
8 is a diagram showing a structure of a thermal imaging camera module to which an infrared transmitting lens according to an embodiment is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the technical idea of the present invention is not limited to some embodiments to be described, but may be implemented in various different forms, and within the scope of the technical idea of the present invention, one or more of the constituent elements may be selectively selected between the embodiments. It can be combined with and substituted for use.

In addition, terms (including technical and scientific terms) used in the embodiments of the present invention are generally understood by those of ordinary skill in the art, unless explicitly defined and described. It can be interpreted as a meaning, and terms generally used, such as terms defined in a dictionary, may be interpreted in consideration of the meaning in the context of the related technology.

In addition, terms used in the embodiments of the present invention are for describing the embodiments and are not intended to limit the present invention. In the present specification, the singular form may also include the plural form unless specifically stated in the phrase, and when described as “at least one (or more than one) of A and (and) B and C”, it may be combined with A, B, and C. It may contain one or more of all possible combinations.

In addition, terms such as first, second, A, B, (a), and (b) may be used in describing the constituent elements of the embodiment of the present invention. These terms are only for distinguishing the component from other components, and are not limited to the nature, order, or order of the component by the term.

And, when a component is described as being'connected','coupled' or'connected' to another component, the component is not only directly connected, coupled or connected to the other component, but also the component and The case of being'connected','coupled', or'connected' due to another element between the other elements may also be included.

In addition, when it is described as being formed or disposed on the “top (top) or bottom (bottom)” of each component, the top (top) or bottom (bottom) is one as well as when the two components are in direct contact with each other. It also includes a case in which the above other component is formed or disposed between the two components.

In addition, when expressed as "upper (upper) or lower (lower)", the meaning of not only an upward direction but also a downward direction based on one component may be included.

Hereinafter, a zinc sulfide sintered body and an infrared transmitting lens according to an embodiment will be described with reference to the drawings.

1 is a diagram showing a perspective view of an infrared transmitting lens. The infrared transmission lens 1000 may be formed of a sintered body formed by sintering powder constituting the infrared transmission lens. In detail, the infrared transmission lens 1000 may be formed of a zinc sulfide sintered body formed by sintering zinc sulfide powder. That is, the infrared transmission lens 1000 may be a zinc sulfide sintered body.

2 is a view showing a side view of an infrared transmitting lens according to an embodiment.

The infrared transmission lens 1000 may have a certain surface roughness. In detail, the infrared transmitting lens 1000 may have a surface roughness of a predetermined size defined as a surface roughness Ra.

For example, one surface 1S of the infrared transmitting lens 1000 and the other surface 2S opposite to the one surface 1S may have a surface roughness Ra of about 30 nm or more. In detail, one surface 1S of the infrared transmitting lens 1000 and the other surface 2S opposite to the one surface 1S may have a surface roughness Ra of 30 nm to 100 nm. In more detail, one surface 1S of the infrared transmitting lens 1000 and the other surface 2S opposite to the one surface 1S may have a surface roughness Ra of 30 nm to 50 nm.

One surface 1S and the other surface 2S of the infrared transmitting lens 1000 may have surface roughness having the same or similar size to each other. Accordingly, scattering of infrared rays passing through one surface and the other surface of the infrared transmitting lens can be minimized. That is, by making the size of the surface roughness of one surface (1S) and the other surface (2S) of the infrared transmitting lens uniform, the amount of infrared rays scattered from one surface (1S) and the other surface (2S) of the infrared transmitting lens is reduced Transmittance can be improved.

However, embodiments are not limited thereto, and one surface 1S and the other surface 2S of the infrared transmitting lens 1000 may have surface roughness of different sizes. That is, the surface roughness of one surface 1S of the infrared transmitting lens 1000 is greater than the surface roughness of the other surface 2S, or the surface roughness of the other surface 2S of the infrared transmitting lens 1000 is one surface 1S. May be greater than the surface roughness of

On the other hand, the infrared-transmitting lens, in order to offset the decrease in transmittance due to scattering of infrared rays according to the surface roughness of the infrared-transmitting lens, the crystal characteristics of the infrared-transmitting lens, that is, the crystal characteristics of the zinc sulfide sintered body constituting the infrared-transmitting lens. Can be controlled.

FIG. 3 is an enlarged view of area A of FIG. 2 and is a view for explaining crystal characteristics of a zinc sulfide sintered body constituting the infrared transmitting lens.

Referring to FIG. 3, the infrared transmission lens may include a plurality of zinc sulfide crystals (C). In detail, the infrared transmitting lens may include a plurality of crystals formed by agglomeration of a plurality of zinc sulfide powders.

Accordingly, the infrared transmission lens, that is, the zinc sulfide sintered body may have grain boundaries (GB) formed by the zinc sulfide crystals.

Crystal interfaces formed by the zinc sulfide crystals may be related to transmittance of infrared rays passing through the infrared transmission lens. In detail, the infrared rays passing through the infrared transmitting lens may be scattered at the interface of the zinc sulfide crystals, and thus, the transmittance of infrared rays passing through the infrared transmitting lens may be reduced by scattering.

That is, as the number of zinc sulfide crystals increases, the number of interfaces of the zinc sulfide crystals increases, so that scattering of infrared rays passing through the infrared transmission lens increases, so that infrared transmittance decreases, and as the number of zinc sulfide crystals decreases, the zinc sulfide crystals Since the number of boundary surfaces is reduced, scattering of infrared rays passing through the infrared transmitting lens may be reduced, and thus infrared transmittance may be increased.

That is, the number of zinc sulfide crystals may be related to the ratio of the zinc sulfide crystal interface.

Accordingly, the infrared transmissive lens according to the embodiment controls the ratio of the interface between the zinc sulfide crystals constituting the infrared transmissive lens, so that the infrared transmittance of the infrared transmissive lens, that is, at a wavelength of 10 μm to 13 μm, is controlled. Can increase.

In detail, the zinc sulfide crystal interface of the zinc sulfide sintered body constituting the infrared transmission lens may be 5% or less per unit area (mm 2 ). That is, the zinc sulfide crystal interface ratio of the zinc sulfide sintered body may be 5%/mm 2 or less. In detail, the ratio of the zinc sulfide crystal interface of the zinc sulfide sintered body may be 1%/mm2 to 5%/mm2.

When the interface ratio of the zinc sulfide sintered body is less than 1%/mm 2, the zinc sulfide sintered body constituting the infrared transmission lens is amorphized and absorbs infrared rays passing through the infrared transmission lens, so that infrared transmittance can be reduced. have.

In addition, when the interface ratio of the zinc sulfide sintered body exceeds 5%/mm 2, infrared rays passing through the infrared transmission lens are scattered at the crystal boundary surface of the zinc sulfide sintered body constituting the infrared transmission lens, thereby reducing infrared transmittance. .

Meanwhile, referring to FIG. 4, the infrared transmission lens may include a plurality of pores. FIG. 4 is an enlarged view of region B of FIG. 3, and is a diagram illustrating a zinc sulfide crystal constituting the infrared transmitting lens.

In detail, referring to FIGS. 3 and 4, the infrared transmissive lens includes a first pore P1 between the powder P forming the zinc sulfide crystals and a second pore P2 between the crystals. can do. The second pores P2 may correspond to the zinc sulfide crystal interface described above.

The first pores P1 and the second pores P2 may have sizes corresponding to each other. Alternatively, the first pores P1 and the second pores P2 may have different sizes. That is, the size of the first pore P1 may be larger than the size of the second pore P2 or the size of the second pore P2 may be larger than the size of the first pore P1.

In addition, the first pore P1 and the second pore P2 may be formed in a shape corresponding to each other. Alternatively, the first pore P1 and the second pore P2 may have different shapes.

The infrared transmission lens may control the pore size of the zinc sulfide sintered body in order to improve the infrared transmittance of about 10 μm to about 13 μm wavelength passing through the infrared transmission lens.

That is, the plurality of pores formed in the zinc sulfide sintered body may be related to the transmittance of infrared rays having a wavelength of about 10 μm to about 13 μm passing through the infrared transmission lens. In detail, as the pore size of the zinc sulfide sintered body increases, scattering of infrared rays passing through the infrared transmission lens increases, and thus transmittance of infrared rays passing through the infrared transmission lens may decrease. That is, the pore size of the zinc sulfide sintered body may be in inverse proportion to the transmittance of infrared rays passing through the infrared transmission lens.

In detail, in the zinc sulfide sintered body according to the embodiment, the sizes of the first pores P1 and the second pores P2 may be 1 μm or less. In more detail. In the zinc sulfide sintered body according to the embodiment, the first pores P1 and the second pores P2 may have a size of 0.01 μm to 1 μm.

The sizes of the first pores P1 and the second pores P2 may be defined as the length of the pores.

When the size of the first pore (P1) and the second pore (P2) exceeds about 1 μm, the scattering of infrared rays according to the difference in the refractive index between the pore and the zinc sulfide crystal or the pore and the zinc sulfide powder increases and transmits infrared rays. The infrared transmittance of the lens can be reduced to about 50% or less.

In addition, when the sizes of the first pores P1 and the second pores P2 are less than 0.1 μm, the zinc sulfide sintered body has an amorphous characteristic, so that infrared rays passing through the infrared transmission lens are rather transmitted through the zinc sulfide sintered body. Is absorbed from, the infrared transmittance can be reduced.

By controlling the sizes of the first and second pores, the sintered density of the zinc sulfide sintered body may be increased. In detail, the sintered density of the zinc sulfide sintered body may be about 99% or more.

The infrared transmission lens according to the embodiment may include a zinc sulfide sintered body.

In addition, the surface roughness of the infrared transmitting lens is about 30 μm or more, and may have an infrared transmittance of about 68% or more, preferably about 68% to 75%, without a separate surface processing.

That is, the infrared transmission lens according to the embodiment may minimize scattering of infrared rays passing through the infrared transmission lens by controlling the ratio of the crystal interface and the size of the pores of the zinc sulfide sintered body constituting the infrared transmission lens.

Accordingly, the infrared transmissive lens according to the embodiment has a surface roughness of about 30 μm or more, but by controlling the crystal characteristics and pores of the infrared transmissive lens to minimize scattering of infrared rays, it has a high infrared transmittance, that is, an infrared transmittance of 68% or more. I can.

In addition, in order to reduce the surface roughness of the infrared transmission lens, since a separate surface processing treatment is not required, the process efficiency of the infrared transmission lens can be improved.

Accordingly, the infrared transmitting lens according to the embodiment may be easily manufactured and may have an improved infrared transmittance.

Below. A method of manufacturing an infrared transmitting lens according to an embodiment will be described with reference to FIGS. 5 to 7.

Referring to Figure 5, the infrared transmission lens manufacturing method according to the embodiment, the step of preparing a zinc sulfide powder (ST10), sintering the zinc sulfide powder to prepare a zinc sulfide sintered body (ST20), and the zinc sulfide sintered body It may include a step of separating (ST30).

First, in the step of preparing zinc sulfide powder (ST10), a raw material for manufacturing an infrared transmitting lens is prepared.

The zinc sulfide powder may be prepared by hydrothermal synthesis.

In detail, first, after preparing the raw materials of the zinc sulfide powder, the raw materials may be mixed. _{The powder for the infrared transmission lens may include zinc sulfate (ZnSO 4} 7H ₂ O) as a zinc precursor (Zn precursor) to form a zinc sulfide powder, and sulfide as a sulfur precursor (S precursor) It may contain sodium hydroxide (Na ₂ S·9H _{2 O).}

The zinc precursor and the sulfur precursor may be mixed with each other by a wet mixing process using a solvent or a dry mixing process without using a solvent.

The zinc precursor and the sulfur precursor may be mixed by a method such as a ball mill or an attrition bill, and then caught using a sieve to recover the mixed powder.

At this time, the zinc precursor and the sulfur precursor may be mixed at a constant ratio. For example, the zinc sulfate hydroxide and sodium sulfide hydroxide may have a molar ratio of 1:1 to 1:3. In addition, the mole ratio (S/Zn) of sulfur contained in the sulfur precursor to zinc contained in the zinc precursor may have a range of 0.5 to 1.8.

Subsequently, a hydrothermal synthesis step may be performed. In the hydrothermal synthesis step, a mixed powder of sulfur and zinc prepared above is added to a reactor and then heated to a constant temperature to form zinc sulfide powder.

The hydrothermal synthesis step may be performed by heating the mixed powder at a temperature of 100°C to 220°C for 5 to 20 hours.

In the hydrothermal synthesis step, when the hydrothermal synthesis temperature is less than 100°C or the hydrothermal synthesis time is less than 5 hours, a sufficient reaction cannot occur due to the short reaction time, thereby preparing zinc sulfide powder having a uniform average particle size. Difficulties can follow. In addition, when the hydrothermal synthesis temperature exceeds 220℃ or the hydrothermal synthesis time exceeds 22 hours, sodium sulfide hydroxide (Na ₂ S 9H ₂ O) must be added in large amounts to activate the hydrothermal synthesis reaction. There is a problem of rising costs.

In addition, it is more preferable to stir at a speed of 100 rpm to 500 rpm using a stirrer during hydrothermal synthesis. If the stirring speed is less than 100 rpm, there is a fear that uniform mixing may not be achieved. Conversely, when the stirring speed exceeds 500 rpm, it may act as a factor that increases only the manufacturing cost without any further effect, and thus process efficiency may decrease.

Subsequently, the filtering step and the drying step may be performed. In the filtering step and the drying step, the reactant synthesized in the previous step may be filtered and dried to obtain zinc sulfide powder.

In the filtering step, the zinc sulfide powder synthesized in the synthesis step is filtered under reduced pressure, and then the zinc sulfide powder is repeatedly washed with deionized water to remove impurities.

Subsequently, in the drying step, the zinc sulfide powder subjected to the filtering step may be dried to prepare a final zinc sulfide powder.

In this case, the drying step may include a first drying step and a second drying step. In addition, a grinding step of grinding the zinc sulfide powder may be further included between the first drying step and the second drying step.

The primary drying may be performed for 8 hours at a temperature of 90°C, and the secondary drying may be performed for 8 hours at a temperature of 150°C. In addition, in the pulverizing step, the zinc sulfide powder may be pulverized to improve particle size and particle size uniformity.

The particle size of the zinc sulfide powder prepared by the above process may be 0.1 μm to 5 μm. When the particle size of the zinc sulfide powder is less than 0.1 μm, a phase transition occurs due to a decrease in sintering temperature in a subsequent sintering process, and thus transmittance of an infrared transmission lens manufactured by the zinc sulfide sintered body may be lowered.

In addition, when the particle size of the zinc sulfide powder exceeds 5 μm, the sintering characteristics may be deteriorated in the subsequent sintering process, and thus the transmittance of the infrared transmitting lens may be deteriorated.

In addition, the zinc sulfide powder produced by the above process may have a cubic shape, a spherical shape, and a hexagonal shape, but embodiments are not limited thereto.

Subsequently, in the step of sintering the zinc sulfide powder to produce a zinc sulfide sintered body (ST20), a zinc sulfide sintered body may be formed by using the zinc sulfide powder prepared by the hydrothermal synthesis method described above.

In detail, the zinc sulfide powder can be manufactured by forming a zinc sulfide sintered body using a hot press sintering apparatus, thereby manufacturing an infrared transmitting lens.

In detail, referring to FIGS. 6 and 7, a hot press sintering apparatus including a mold member 100 and a press unit 200 may be prepared.

The mold member 100 includes a mold space in which raw materials are filled. The mold space portion may have a circular, rectangular or polygonal shape. The mold member 100 may include a material such as SUS, graphite, silicon carbide, tungsten carbide, boron nitride, aluminum nitride, silicon nitride, etc. that can withstand high temperature and high pressure.

A raw material 500 including zinc sulfide powder prepared above may be filled in the mold space portion of the mold member 100.

Release sheets 400 may be positioned on the upper and lower surfaces of the mold space. The release sheet 400 allows the mold and the zinc sulfide sintered body to be easily released from each other when the zinc sulfide sintered body is manufactured by the hot pressing sintering device. The release sheet 400 may include a material that can withstand high temperatures and high pressures, and may include, for example, a material such as boron nitride and aluminum ytride.

The press parts 210 and 220 may be located on the upper and lower surfaces of the mold member 100. That is, the press units 210 and 220 may include a first press unit 210 and a second press unit 220 positioned on the upper and lower surfaces of the mold member 10. The first press unit 210 and the second press unit 220 may include materials such as SUS, graphite, silicon carbide, tungsten carbide, boron nitride, aluminum nitride, and silicon nitride that can withstand high temperatures.

Meanwhile, the first press unit 210 and the second press unit 220 may each include a convex shape and a concave shape for a lens shape. For example, the upper press portion may have a convex shape, and the lower press portion may have a concave shape.

Accordingly, the zinc sulfide sintered body finally manufactured can be implemented in a lens shape.

That is, the zinc sulfide sintered body manufactured by the hot press sintering apparatus can be used as an infrared transmitting lens without any additional processing.

The zinc sulfide powder filled in the mold space in the mold member 100 may be bonded to each other by a hot pressing process. That is, the zinc sulfide sintered body may be manufactured by simultaneously applying heat and pressure to sinter the zinc sulfide powder filled in the mold cavity. That is, by pressing the mold member 100 through the first press unit 210 and the second press unit at the previous temperature, the zinc sulfide powder filled in the mold member 100 may be sintered into a lens shape.

In detail, the mold member may be hot pressed by applying pressure to the upper and lower surfaces of the mold member by a press unit. For example, the mold member may be hot-pressed for about 10 minutes to about 20 minutes at a temperature of 900°C to 1000°C at a temperature of about 30 to 40 minutes at a pressure of 50 MPa to 100 MPa. At this time, heat and pressure may be performed in a vacuum atmosphere. Thereafter, the zinc sulfide sintered body may be manufactured through a cooling process for about 50 minutes to about 60 minutes.

On the other hand, when the sintering process is performed at a temperature of 900°C or less, the zinc sulfide powder is not sintered, so that the transmittance of the infrared transmitting lens manufactured thereby may decrease, and the sintering process is performed at a temperature exceeding 1000°C, A phase transition of the zinc sulfide powder may occur, so that the transmittance of the infrared transmitting lens may decrease.

Subsequently, in the step of separating the zinc sulfide sintered body (ST30), the sintered body may be separated from the mold member 100.

The particle diameter of the separated sintered body may be 6 mm to 15 mm, and the thickness may be 2 mm to 5 mm.

A sintered body having a particle diameter of less than 6 mm may be difficult to implement, and when the particle diameter exceeds 15 mm, sintering uniformity may be deteriorated, and transmission characteristics of the infrared transmitting lens may be deteriorated.

In addition, when the thickness of the sintered body exceeds 5 mm, the sintering uniformity may be deteriorated and the transmission characteristics of the infrared transmitting lens may be deteriorated.

Meanwhile, as described above, release sheets including a material such as boron nitride and aluminum itride are positioned on the upper and lower surfaces of the mold member, and accordingly, the mold member and the press part can be easily released. .

Meanwhile, an additional functional layer may be disposed on the surface of the zinc sulfide sintered body finally manufactured. For example, the surface of the zinc sulfide sintered body may be coated with an antireflection layer or a DLC (Diamond Like Carbon) layer to improve the strength of the infrared transmitting lens.

As described above, the infrared transmission lens formed by the zinc sulfide sintered body described above has a high surface roughness, but by controlling the internal crystal characteristics of the zinc sulfide sintered body, the infrared transmittance of the infrared transmission lens can be increased to 68% or more. have.

Therefore, since a process of forming a separate ingot and processing it into a lens shape and an additional process for reducing surface roughness are not required, an infrared transmitting lens can be easily manufactured.

In addition, the infrared transmission lens according to the embodiment may minimize scattering of infrared rays passing through the infrared transmission lens by controlling the ratio of the crystal interface and the size of the pores of the zinc sulfide sintered body constituting the infrared transmission lens.

Accordingly, the infrared transmissive lens according to the embodiment has a surface roughness of about 30 μm or more, but by controlling the crystal characteristics and pores of the infrared transmissive lens to minimize scattering of infrared rays, it has a high infrared transmittance, that is, an infrared transmittance of 68% or more. I can.

Hereinafter, the present invention will be described in more detail through measurement of surface roughness and infrared transmittance according to Examples and Comparative Examples. These examples are merely presented as examples to describe the present invention in more detail. Therefore, the present invention is not limited to these examples.

Example

After the zinc sulfide powder was filled into the mold member, heat and pressure were simultaneously applied through press portions disposed on the upper and lower portions of the mold member to prepare a zinc sulfide sintered body.

Subsequently, the zinc sulfide sintered body was removed from the mold member to prepare an infrared transmitting lens containing zinc sulfide.

Subsequently, the infrared transmittance of the infrared transmission lens at a wavelength of 10 μm was measured according to the surface roughness and the size of the surface roughness.

Meanwhile, the surface roughness according to the examples was measured by measuring the average value of the surface roughness in one area of the sintered body specimen of each example.

Comparative example

After the zinc sulfide powder was filled into the mold member, pressure was applied to the mold member to prepare a zinc sulphide molded body.

Subsequently, heat and pressure were simultaneously applied to the molded body through press portions disposed on the upper and lower portions of the mold member to prepare a zinc sulfide sintered body.

Subsequently, the zinc sulfide sintered body was removed from the mold member to prepare an infrared transmitting lens containing zinc sulfide.

Subsequently, the infrared transmittance of the infrared transmission lens at a wavelength of 10 μm was measured according to the surface roughness and the size of the surface roughness.

Meanwhile, the surface roughness according to the comparative examples was measured by measuring the average value of the surface roughness in one area of the sintered body specimen of each comparative example.

Surface roughness (nm) Transmittance (%) Example 1 30 68 Example 2 33 70 Example 3 36 73 Example 4 40 72 Example 5 50 65 Example 6 70 40 Comparative Example 1 10 73 Comparative Example 2 20 70

Referring to Table 1, it can be seen that the infrared transmission lens according to the embodiment has an infrared transmittance of about 68% or more.

In detail, it can be seen that the infrared transmittance of the sintered body according to the embodiment is about 68% or more in the range of 30 mm to 40 mm.

However, when the surface roughness of the sintered body exceeds 40 mm, it can be seen that the infrared transmittance gradually decreases as the surface roughness increases. That is, when the surface roughness of the sintered body exceeds 40 mm, when the infrared transmitting lens is applied to the thermal imaging camera, the characteristics may be deteriorated due to the decrease in transmittance.

That is, it can be seen that the sintered body according to the embodiment has an infrared transmittance of about 68% or more when the surface roughness is 30 mm to 40 mm.

That is, it can be seen that the infrared transmissive lens according to the embodiment has a higher surface roughness than the infrared transmissive lens according to the comparative example, but has almost the same infrared transmittance.

That is, although the infrared transmission lens according to the embodiment has a high surface roughness of the infrared transmission lens, it can be seen that the infrared transmittance can be increased by controlling the crystal boundary and pore size of the internal crystals to prevent infrared scattering.

8 is a diagram showing the structure of a thermal imaging camera module according to an embodiment to which an infrared transmitting lens is applied.

8, the thermal imaging camera module 2000 includes a holder 1100, a lens barrel 1200, a lens unit 1000, a filter unit 1400, a driving substrate 1500, a sensor unit 1600, and data. The processing element 1700 may be included, and at least one of them may be omitted or a vertical arrangement relationship may be changed.

The holder 1100 may be coupled to the lens barrel 1200 to support the lens barrel 1200 and may be coupled to the substrate 250 to which the sensor unit 1600 is attached. In addition, the holder 1100 may have a space under the lens barrel 1200 in which the flow plate unit 1400 can be attached. The holder 1100 may include a spiral structure. In addition, the lens barrel 1200 may also have a spiral structure corresponding to the holder 1100, and accordingly, the lens barrel 1200 and the holder 1100 may be rotationally coupled to each other. However, this is exemplary, and the holder 1100 and the lens barrel 1200 are bonded through an adhesive (eg, an adhesive resin such as epoxy), or the holder 1100 and the lens barrel 1200 are integrally formed. It could be.

The lens barrel 1200 is coupled to the holder 1100 and may have a space capable of accommodating the lens unit 1000 therein. The lens barrel 1200 may be rotationally coupled to the lens unit 1000, but this is exemplary and may be coupled in other ways such as a method using an adhesive.

The lens unit 1000 may be an infrared lens that passes infrared rays radiated from the subject. That is, in order to transmit infrared rays emitted from the subject, the lens unit 1000 may use the infrared transmission lens described above.

In addition, the lens unit 1000 may further include an infrared transmission window (not shown) to protect the lens in front. The infrared transmission window may be made of a material such as CaF2, BaF2, or polyethylene.

The sensor unit 1600 may be mounted on the driving substrate 1500 and performs a function of converting an infrared signal (infrared radiation energy) passing through the lens unit 1000 and the moving plate unit 1400 into an image signal. I can. That is, the sensor unit 1600 may include an element that senses infrared radiation energy. That is, the sensor unit 1600 may detect energy corresponding to the infrared radiation energy using the device. Preferably, the sensor unit 1600 may serve to convert the result of infrared radiation energy incident through the lens unit 1000 into an electrical signal.

Preferably, the sensor unit 1600 senses the temperature of the subject from infrared rays transmitted through the lens unit 1000 and outputs a corresponding physical characteristic change (analog signal). Such a sensor unit 1600 may be a microbolometer described in FIGS. 1 to 10.

The driving substrate 1500 may be disposed under the holder 1100 and may include wiring for transmitting electric signals between the respective components. In addition, a connector (not shown) for electrically connecting to an external power source of the camera device or other device (eg, an application processor) may be connected to the driving board 1500.

The driving substrate 1500 is composed of a Rigid Flexible Printed Circuit Board (RFPCB) and may be bent as required by a space in which the thermal imaging camera module 2000 is mounted, but the embodiment is not limited thereto.

In addition, a pattern portion may be disposed between the driving substrate 1500 and the sensor unit 1600.

A filter 1400 may be disposed between the sensor unit 1600 and the lens unit 1000. The filter 240 may provide an infrared signal passing through the lens unit 1000 to the sensor unit 1600.

Features, structures, effects, and the like described in the above-described embodiments are included in at least one embodiment of the present invention, and are not necessarily limited to only one embodiment. Furthermore, the features, structures, effects, and the like illustrated in each embodiment may be combined or modified for other embodiments by a person having ordinary knowledge in the field to which the embodiments belong. Accordingly, contents related to such combinations and modifications should be interpreted as being included in the scope of the present invention.

In addition, although the embodiments have been described above, these are only examples and do not limit the present invention, and those of ordinary skill in the field to which the present invention pertains are illustrated above within the scope not departing from the essential characteristics of the present embodiment. It will be seen that various modifications and applications that are not available are possible. For example, each component specifically shown in the embodiments can be modified and implemented. And differences related to these modifications and applications should be construed as being included in the scope of the present invention defined in the appended claims.

Claims (6)

As an infrared transmission lens including one side and the other side,
The surface roughness (Ra) of at least one of the one side and the other side is 30 nm to 100 nm,
The infrared transmission lens includes a zinc sulfide sintered body,
The zinc sulfide sintered body includes a plurality of zinc sulfide crystals,
The ratio of the interface of the zinc sulfide crystals is 1% / mm 2 to 5% / mm 2 infrared transmission lens. The method of claim 1,
An infrared transmission lens having a surface roughness (Ra) of at least one of the one surface and the other surface of 30 nm to 40 nm. Following paragraph 1,
The zinc sulfide crystals are formed by agglomeration of a plurality of zinc sulfide powders,
The zinc sulfide sintered body includes a first pore between the zinc sulfide powder and a second pore between the zinc sulfide crystals. The method of claim 3,
The first pore and the second pore size is 0.01㎛ to 1㎛ infrared transmission lens. The method of claim 1,
The zinc sulfide sintered body is an infrared transmission lens having a sintered density of 99% or more. Lens holder;
A lens unit coupled to one side of the lens holder; And
Including a sensor unit coupled to the other side of the lens holder,
The lens unit includes a zinc sulfide sintered body,
The lens unit includes one surface and the other surface,
The surface roughness (Ra) of at least one of the one side and the other side is 30 nm to 100 nm,
The lens unit includes a zinc sulfide sintered body,
The zinc sulfide sintered body includes a plurality of zinc sulfide crystals,
The ratio of the interface of the zinc sulfide crystals is 1%/mm2 to 5%/mm2,
The zinc sulfide crystals are formed by agglomeration of a plurality of zinc sulfide powders,
The zinc sulfide sintered body includes first pores between the zinc sulfide powders and second pores between the zinc sulfide crystals,
The first pore and the second pore have a size of 0.01 μm to 1 μm,
The zinc sulfide sintered body has a sintered density of 99% or more,
The lens unit thermal imaging camera module that transmits more than 68% of infrared rays having a wavelength of 10 μm to 13 μm.

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