KR100800196B1 - Projection system - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a projection system, and more particularly, to a projection system that enables a lamp assembly provided in a projection television to be stably fixed, supported and efficiently cooled.

Projection system according to the present invention for achieving the object as described above, the light is generated; A bracket to which the front surface of the lamp is coupled; A lamp case accommodating the lamp therein and having the bracket coupled to an opened side; And a supporter for firmly fixing the lamp to the bracket.

By the above configuration, the interior of the lamp assembly and the optical engine is cooled quickly and efficiently, the lamp is stably fixed and supported, and manufacturing costs are reduced.

Projection, Fixed, Cooled

Description

Projection system. {Projection system}

1 is a cross-sectional view schematically showing a projection system according to the present invention.

2 is an external perspective view of an optical engine according to the present invention;

3 is a partially exploded perspective view of the optical engine;

Figure 4 is an exploded perspective view showing the optical engine coupled to the base according to the invention.

5 is an exploded perspective view of the optical engine.

6 is a perspective view of a lamp assembly of the optical engine according to the invention.

7 is a perspective view of a lamp case of the optical engine according to the present invention.

8 is a perspective view of a supporter of the optical engine according to the present invention;

9 is a perspective view of a grill member of the optical engine according to the present invention.

10 is a perspective view showing a coupling structure of the lamp assembly of the optical engine according to the present invention.

FIG. 11 is a cross-sectional view taken along line II ′ of FIG. 6, illustrating a flow of air in the lamp assembly of the optical engine according to the present disclosure; FIG.

<Explanation of symbols for the main parts of the drawings>

1: projection system 10: optical engine unit

12: DMD fan 141: lamp cooling fan

20: optical engine 21: lamp assembly

22: color wheel assembly 23: light tunnel housing

24: light tunnel assembly 25: condensing lens

26: DMD Assembly 27: Actuator

28: reflector case 29: folding mirror

30: total reflection prism 31: projection lens assembly

51 supporter 52 grill member

TECHNICAL FIELD The present invention relates to a projection system, and more particularly, to a projection system that enables a lamp assembly provided in a projection television to be stably fixed, supported and efficiently cooled.

Recently, large-screen high-definition display devices have emerged as a major topic, and such large-screen high-definition display devices include CRT (Cathode Ray Tube) televisions, Liquid Crystal Display (LCD) televisions, Projection televisions, and Plasma Display Panel (PDP) televisions. It's coming out.

Among them, the demand for the projection television and the development of technology are actively made as one of the display apparatuses that satisfy the requirements of large screen high definition. The projection television includes a liquid crystal on silicon (LCOS) method using an LCD and a digital light porsessing (DLP) method using a digital micromirror device (DMD).

Recently, low-cost projection TVs using LCDs or DMDs have been in the spotlight. In particular, as the consumer's desire for high quality along with a large screen increases, the demand is increasing year by year, and the trend is particularly popular in the digital television market currently being trial broadcast.

In addition, as the use of computers and presentations using computers have been increasing in recent years, the use of projectors using LCDs or DMDs has also increased.

In general, a projection television adopts a method in which light generated by an optical engine mounted inside a cabinet is reflected and an image is projected on a screen.

In detail, an optical engine using a DMD includes a lamp that emits white light, a color wheel device that separates light emitted from the lamp into red, green, and blue light, an illumination system that collects light passing through the color wheel device; And a DMD for receiving a light passing through the illumination system to create a desired screen, and a projection lens to enlarge and project the image generated from the DMD onto the screen.

The illumination system, the DMD, and the projection lens of the general projection system may be collectively referred to as an optical engine, and the optical engine is a part where high heat is generated by illumination light generated from a lamp. Therefore, in order to allow such high heat to be cooled, it is important to ensure that the lamp is stably supported while having an appropriate cooling system. If the high heat is not cooled, a problem may occur that a plurality of films provided in the illumination system and a DMD provided in the synthesis system are oxidized, and furthermore, a problem that the projection system does not operate normally may occur.

In such conventional projection systems, the lamp assembly and the interior of the optical engine are generally cooled by the air entering the air inlet of the fully opened lamp assembly. However, due to the decrease in DMD panel size (0.5 inch-> 0.45 inch) and consequent increase in lamp brightness (120 watts-> 132 watts) the temperature rise inside the optical engine makes it difficult to increase cooling efficiency with existing cooling systems. I lost. That is, there is a problem in that efficient cooling is not achieved because the air passage is not completely secured by the air inlet of the lamp assembly which is completely opened.

In addition, conventionally, the left supporter and the right supporter are separately formed to support and fix the lamps in order to fix and support the positions of the lamps mounted on the lamp assembly. Therefore, since the plurality of supporters are separately manufactured and assembled, there is a problem in that work efficiency is lowered and manufacturing costs are increased. In addition, each conventional supporter has a shape that is not suitable for guiding the flow of air flowing into the lamp, and because the surface area is small, there is a problem that the lamp is not cooled efficiently.

The present invention has been proposed to solve the above problems, the grill member is provided on one side of the lamp assembly of the optical engine to guide the air flow path, thereby cooling the interior of the lamp assembly and the optical engine quickly and efficiently It is an object of the present invention to propose a projection system for stable operation.

In addition, an integrated supporter is provided in the lamp mounting portion of the lamp assembly of the optical engine, and an object of the present invention is to propose a projection system in which the lamp is stably fixed and supported, manufacturing and assembly is easy, and manufacturing cost is reduced.

In addition, the lamp mounting portion of the lamp assembly of the optical engine is provided with a grill member to guide the air introduced into the grill member, it is an object to propose a projection system that can maximize the heat dissipation effect.

It is also an object of the present invention to propose a projection system in which the operation of the device can be stably performed even when the optical engine is used for a long time.

Projection system according to the present invention for achieving the object as described above, the light is generated; A bracket to which the front surface of the lamp is coupled; A lamp case accommodating the lamp therein and having the bracket coupled to an opened side; And a supporter which is in surface contact with the bracket in a state where the lamp is fixed so that the lamp is firmly fixed to the bracket.

According to another aspect, a projection system according to the present invention comprises: a lamp in which light is generated; A lamp case accommodated inside the lamp case to fix and support a position of the lamp; And a grill member coupled to one side of the lamp case and guiding outside air into the lamp case, wherein the grill member is arranged at a predetermined interval with a plurality of inclination plates inclined at a predetermined angle. It is characterized in that the outside air to be sucked is guided to the front of the lamp.

According to yet another aspect, a projection system according to the present invention comprises: a lamp comprising a lamp burner and a reflector for concentrating light emitted from the lamp burner in one place; A lamp case in which the lamp is accommodated; A bracket in which the front part of the reflector is in close contact with one surface; And a supporter for pressing the front portion of the reflector from the rear to fix the bracket more firmly and to guide the air sucked into the reflector.

By the above configuration, the interior of the lamp assembly and the optical engine is cooled quickly and efficiently, the lamp is stably fixed and supported, and manufacturing costs are reduced.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily added by adding, changing, or deleting other elements. I can suggest.

1 is a cross-sectional view schematically showing a projection system according to the spirit of the present invention.

Referring to FIG. 1, a projection system 1 according to the present invention includes a cabinet 2 forming an appearance, a screen 4 mounted on the front surface of the cabinet 2, and an optical seat mounted on a lower end of the cabinet 2. An engine unit 10 and a rearview mirror 3 mounted to the inner circumferential surface of the cabinet 2 to reflect the image emitted from the optical engine unit 10 onto the screen 4 are included.

In detail, the image screen formed and projected by the optical engine unit 10 is reflected by the rearview mirror 3. The reflected image is extended and projected onto the screen 4 so that the image screen is recognized by the user.

Hereinafter, the structure and function of each part of the optical engine unit 10 will be described in more detail with reference to the accompanying drawings.

2 is an external perspective view of an optical engine according to the inventive concept, and FIG. 3 is a partially exploded perspective view of the optical engine.

2 and 3, the optical engine unit 10 according to the present invention includes a base 11, an optical engine 20 mounted on the base 11, and an outer portion of the optical engine 20. Various parts to be mounted are included.

In detail, a power supply unit 15 for supplying an appropriate amount of power to various electrical components constituting the optical engine unit 10 may be provided to various components mounted on the outside of the optical engine 20, and the power supply unit 15. A power supply supporter 16 for supporting the lamp, a lamp cooling fan assembly 14 for cooling a lamp (to be described later) constituting the optical engine 20, and a ballast 13 mounted to one side of the base 11. ), A projection lens cap 17 surrounding the projection lens (to be described later) constituting the optical engine 20, and a DMD fan 12 for cooling the DMD (to be described later) constituting the optical engine 20. ) Is included.

In more detail, the power supply unit 15 is a switching mode power supply (SMPS), and is a modular power supply unit that converts electricity supplied from the outside to match the electric device. In addition, the power supply unit 15 controls the intermittent control at a high frequency of a commercial frequency or higher and mitigates the impact by using semiconductor switching characteristics.

In addition, the ballast 13 functions to apply a high voltage when the lamp constituting the optical engine 20 is turned on and to appropriately adjust the current so that an overcurrent does not flow after the lamp is turned on.

In addition, the lamp cooling fan assembly 14 includes a lamp cooling fan 141 for cooling the heat generated from the lamp.

As shown in FIG. 3, in the case of the optical engine unit 10 according to the present invention, each part except for the optical engine 20 may be independently separated from the base 11. Thus, the optical engine 20 is mounted to the base 11, and then each of the components mentioned above are coupled to the base 11.

4 is an exploded perspective view illustrating a state in which an optical engine according to the spirit of the present invention is coupled to a base, and FIG. 5 is an exploded perspective view of the optical engine.

Referring to FIG. 4, the optical engine 20 for making an image screen in the optical engine unit 10 according to the present invention may be integrally separated from the base 11.

In detail, the optical engine 20 assembly is completely separated by removing only eight fastening members that allow the optical engine 20 assembly to be fixed to the base 11. Therefore, there is an advantage that the service is easily made and the disassembly and assembly process is very simple.

In addition, in order for the optical engine 20 assembly to be secured to the base 11, it is not necessary to first have the components of the optical engine 20 assembled to the base 11. That is, the optical engine 20 is assembled separately, and then integrally mounted on the base 11.

Referring to FIG. 5, the optical engine 20 according to the present invention includes a lamp assembly 21 in which white light is generated by a high voltage supplied by the ballast 13, and unpolarized light emitted from the lamp assembly 21. A color wheel assembly 22 for separating the red, green, and blue, a light tunnel assembly 24 for uniformly making red, green, and blue separated light while passing through the color wheel assembly 22; A light tunnel housing 23 in which the color wheel assembly 22 and the light tunnel assembly 24 are accommodated therein, and a condensing lens 25 in which uniform light is collected while passing through the light tunnel assembly 24. A folding mirror 29 for reflecting light passing through the condensing lens 25, a total reflection prism 30 for reflecting light reflected by the folding mirror 29 again, and total reflection By prism (30) DMD assembly 26 for reflecting light gathers to form image information, an actuator 27 for doubling the number of pixels of light reflected from the DMD assembly 26, and the actuator 27 A projection lens 31 for enlarging the light passing through is included. Here, the lamp assembly 21 is called a lamp system. The assembly of the color wheel assembly 22, the light tunnel assembly 24, and the condensing lens 25 is called an illumination system. The aggregate of the folding mirror 29 and the total reflection prism 30 is called a reflectometer, and the aggregate of the reflectometer and the DMD assembly 26 is called a synthetic system.

In more detail, the lamp assembly 21 includes a lamp 212 emitting white light, a lamp case 211 and a bracket 210 protecting the lamp 212. In addition, the reflector of the lamp 212 serves to change the light emitted from the burner of the lamp is reflected to focus at a certain distance, that is, the focal length. The lamp assembly 21 will be described in detail later in the drawings.

On the other hand, the color wheel assembly (22) is divided into red (Green), green (Green), blue (Blue) is divided into a color wheel (also called 221: RGB color filter) that rotates at high speed, and the color A motor 223 driving the wheel 221 and a heat dissipation fin 222 for cooling the motor 223.

In detail, light emitted from the lamp 212 by the reflector of the lamp 212 is focused on the surface of the color wheel 221. In addition, the light collected by the color wheel 221 passes through the color wheel 221 and has any color of red, blue, and green. Here, the color wheel 221 has a disk shape having a predetermined diameter, the disk is divided into red, green, blue. Accordingly, the unpolarized light reflected by the reflector has one of red, blue, and green colors due to the color of the color wheel 221 positioned at the time of condensing.

In addition, the color wheel assembly 22 and the light tunnel assembly 24 are housed inside the light tunnel housing 23. In addition, a color wheel cooling fan 43 is coupled to the rear of the light tunnel housing 23 in order to cool the color wheel 221 rotating at a high speed.

In addition, the light tunnel assembly 24 is also called a rod lens, and serves to uniformly make colored light passing through the color wheel 221.

In detail, the light tunnel assembly 24 is formed by joining four small, long rectangular bar mirrors facing each other. The light passing through the color wheel assembly 22 is diffusely reflected while passing through the light tunnel, and the brightness distribution is uniform.

In addition, the condensing lens 25 performs a function of collecting red, green, and blue light uniformed while passing through the light tunnel assembly 24 to the DMD elements constituting the DMD assembly 26. do.

The total reflection prism 30 may also be referred to as a total internal reflection (TIR) prism, and a prism having a large refractive index and a prism having a relatively small refractive index are bonded to each other. And, due to the difference in refractive index is totally reflected or transmitted according to the incident angle of the light irradiated from the condensing lens 25.

In detail, each object has its own refractive index, and the difference in refractive index determines the critical angle at which light is totally reflected or transmitted.

Therefore, light incident at an angle greater than or equal to a critical angle is totally reflected by the total reflection prism 30, and light incident at an angle smaller than or equal to a critical angle passes through the total reflection prism 30.

In addition, the DMD assembly (Digital Micro-mirror Device Assembly) 26 is composed of a DMD panel and a driver board that accommodates the DMD panel. In detail, the driver board is a device for controlling the driving of the ballast and the color wheel or controlling the image.

On the other hand, the DMD panel is designed such that the same amount of fine mirrors as the resolution of the display is arranged so as to have a one-to-one correspondence with the screen.

In detail, the DMD panel determines whether the red, green, and blue light transmitted through the total reflection prism 30 is emitted toward the screen or discarded out of the screen. The DMD panel is mounted in a complementary metal oxide semiconductor (CMOS) memory and driven by a signal transmitted from the CMOS memory.

In more detail, the micromirror constituting the DMD panel is manufactured in the form of a fine diamond-shaped pixel having a width and width of 16 μm, and tilted by ± 10 degrees according to a signal transmitted from the CMOS, thereby reducing the total reflection prism 30. Passing light is either reflected off the screen or thrown out of the screen.

In addition, the actuator 27 is disposed between the DMD panel and the projection lens 31, and a mirror is mounted at the center portion. In detail, the actuator 27 functions to double the number of pixels of the image signal by refracting and dividing the image signal emitted from the DMD panel by half a frame. Due to the refraction characteristics of the mirror, the resolution of the screen is increased. The actuator includes a transmission type and a reflection type.

In addition, the projection lens assembly 31 functions to enlarge the image passing through the actuator 27 toward the rearview mirror 3. Details of the projection lens assembly 31 will be described in detail with reference to the accompanying drawings.

In the optical engine 20 having the above-described configuration, the actuator 27, the total reflection prism 30, and the folding mirror 29 are inserted from different surfaces of the reflector case 28 so that one reflectometer may be used. Configure. The color wheel assembly 22 and the light tunnel assembly 24 are accommodated in the light tunnel housing 23 to form another assembly. In addition, the lamp assembly 21 forms a separate assembly together with the lamp 212 mounted inside the lamp case 211, and the light tunnel housing 23 is in close contact with the front of the lamp assembly 21. do.

As described above, since a plurality of parts form a single assembly, there is an advantage that parts replacement and service are easily performed.

In the following, each configuration applied to the projection system according to the present invention, in particular the cooling system of the optical engine 20, will be briefly described.

First, the optical engine 20 guides the flow of air by the three fans 12, 141, 43 and the fans 12, 141, 43 to force the air to flow. A plurality of guide structures are formed for the purpose of describing the cooling system of the optical engine 20 based on the flow order of air.

First, cold air introduced into the projection system 1 from the outside is introduced into the optical engine 20, in particular, the DMD fan 12 on the side of the synthesis system, whereby heat generated from the synthesis system can be cooled. .

In addition, a lamp cooling fan 141 is formed in front of the lamp assembly 21 to cool the lamp 212. The lamp cooling fan 141 is discharged to the front of the projection system 1 after the air near the power supply 15 is introduced into the lamp assembly 21 to be discharged to the outside of the projection system.

Meanwhile, in order to cool the color wheel 221 rotating at a high speed, a color wheel cooling fan 43 is formed at the rear of the light tunnel housing 23. The color wheel cooling fan 43 flows into the light tunnel housing 23 after the air near the power supply unit 15 enters the light tunnel housing 23, and then cools the light tunnel housing 23, and then discharges it toward the front of the projection system 1. Be sure to

As can be seen from the above structure, the DMD fan 12, the lamp cooling fan 141 and the color wheel cooling fan 43 is seated in an adjacent position where the heat source is placed to provide a suction force, so that cold air is used to After passing through the structure to absorb the heat and sucked into the fan 12, 141, 43 is discharged.

Hereinafter, the configuration of the lamp assembly of the projection system according to the present invention will be described in detail.

6 is a perspective view of a lamp assembly of the optical engine according to the invention.

Referring to FIG. 6, the lamp assembly 21 of the optical engine 20 according to the present invention includes a lamp 212 in which white light is generated, and the lamp 212 is accommodated therein so that the lamp 212 may be protected from an external impact. A lamp case 211 that protects the lamp case 211, a supporter 51 that is coupled to the lamp 212 to support the lamp 212 to be fixed to the lamp case 211, and guides an air flow path, and the lamp case ( The grill member 52 coupled to one side of the 211 to guide the flow path of air introduced into the lamp case 211 is included.

In detail, the lamp 212 is a lamp burner 213, the white light is generated by the high voltage supplied by the ballast, and the light emitted from the lamp burner 213 is reflected so as to change the focus at a certain distance, that is, the focal length It is composed of a reflector 214. The reflector 214 is recessed into the lamp assembly 21 to facilitate light collection, and a lamp bulb 215 is formed in the recessed portion of the reflector 214. In addition, as air flows through the lamp bulb 215, heat generated from the lamp 212 is cooled.

On the other hand, the front rim of the reflector 214 is formed with one or more depressions 216, 217 formed to be lower than a certain degree. The first recess 216 is formed to abut on an opening (see 219 in FIG. 7) formed at one side of the lamp case 211 so that air flows into the lamp case 211 and is introduced into the opening. Air flows smoothly into the lamp bulb 215. In addition, the second recess 217 is formed on the opposite side of the first recess 216 to provide a passage through which the air introduced into the first recess 216 is discharged. After cooling the lamp 212, the air discharged to the first recess 216 may be discharged to the outside through the lamp cooling fan duct (see 42 of FIG. 5) and the lamp cooling fan (see 141 of FIG. 5). Discharged.

Since the structure and operation of the lamp 212 is the same as a conventional projection system, a detailed description thereof will be omitted.

7 is a perspective view of a lamp case of the optical engine according to the present invention.

Referring to FIG. 7, the lamp case 211 for accommodating the lamp 212 and protecting the lamp 212 from an external shock is hollow so that the lamp 212 may be inserted and accommodated therein. It is made of a box shape. In addition, a coupling protrusion 218 is formed at one side of the lamp case 211 so that the bracket (see 210 of FIG. 5) is coupled thereto. In addition, an opening portion 219 through which air is introduced into the lamp case 211 is formed at one side of an outer surface of the lamp case 211, and a grill member for smoothly distributing air in the opening 219 ( 52) is combined.

By the above configuration, the lamp 212 is stably fixed to the lamp case 211 and supported, and the air for cooling the heat generated from the lamp 212 can be smoothly flowed to achieve rapid and efficient cooling. It has an effect.

8 is a perspective view of a supporter of the optical engine according to the present invention.

Referring to FIG. 8, in the supporter 51 of the optical engine according to the present invention, a lamp insertion hole 514 into which the lamp 212 may be inserted is formed on a flat plate having a predetermined shape.

In detail, both ends of the supporter 51 may be in close contact with the bracket 210 to support the lamp 212, and a guide part 512 connecting between both ends of the close part 511. ) And a coupling hole 513 for inserting and receiving a coupling protrusion (not shown) of the bracket 210 to allow the supporter 51 to be coupled to the bracket 210.

More specifically, the close contact portion 511 is formed in a substantially flat surface to be in close contact with one surface of the bracket 210. In addition, between the contact portions 511 formed at both ends of the supporter 51, the lamp 212 is stably supported and serves as a guide to smoothly distribute air in the lamp case 212. Guide portion 512 is formed. The guide part 512 is bent or bent a plurality of times at a predetermined curvature so as to correspond to the depressions 216 and 217 of the lamp case 212, and is closely coupled to the depressions 216 and 217. In addition, the guide part 512 is formed to protrude to a certain extent than the close contact part 511, and is formed to be close to the grill member 52 in a state in which it is coupled with the lamp case 212, thereby the grill member 52. Guides the air introduced into the lamp 212 to be completely supplied into the lamp 212.

Unlike the supporter of the conventional projection system, which is separately formed and coupled to the left supporter and the right supporter, the supporter 51 of the present invention is formed integrally, thereby reducing manufacturing costs and simplifying the manufacturing process. In addition, the entire surface of the supporter 51 is tightly coupled to the lamp 212 and the bracket 210 to support the lamp 212, there is an advantage that the entire lamp is supported evenly. In addition, the area in contact with the air is enlarged by the guide part 512 that is bent, thereby providing efficient cooling.

9 is a perspective view of a grill member of the optical engine according to the present invention.

Referring to FIG. 9, in the grill member 52 coupled to the opening 219 of the lamp case 211, a plurality of inclined plates 521 which are inclined at a predetermined angle are arranged at predetermined intervals, and the optical engine 20 The outside air smoothly flows into the lamp case 211 and serves as a guide to guide the front of the lamp 212. In addition, the grill member 52 further includes a coupling hole 522 to be fixed to the lamp case 211 is supported.

Unlike the conventional projection system in which only an opening is formed on the side of the lamp case, in the present invention, the grill member 52 having the inclined plate 521 for guiding the flow path of the air is coupled to the opening, whereby air introduced from outside Is guided to flow in a constant direction, there is an advantage that faster and more efficient cooling is performed.

10 is a perspective view showing a coupling structure of the lamp assembly of the optical engine according to the present invention.

10, the lamp assembly of the optical engine according to the present invention is combined in the following order.

First, the lamp 212 and the supporter 51 are combined. In detail, the coupling hole 514 of the supporter 51 is fitted from the rear of the lamp 212 to the front, that is, the radius of the reflector 214 of the lamp is smaller to larger. In addition, the guide part 512 of the supporter 51 and the recessed parts 216 and 217 of the lamp 212 are formed in close contact with each other.

Next, the lamp 212 and the supporter 51 coupled to each other as described above is coupled to the bracket 210. In detail, the coupling hole 513 formed in the supporter 51 may be coupled to a coupling protrusion (not shown) formed in the bracket 210. Alternatively, a coupling hole (not shown) may be formed in the bracket 210, and the coupling hole 513 of the supporter and the coupling hole (not shown) of the bracket may be coupled by a separate fastening member. By the above structure, the supporter 51 may press the reflector 214 of the lamp 212, such that the lamp 212 may be tightly coupled to the bracket 210.

Finally, the lamp 212, the supporter 51 and the bracket 210 coupled to each other as described above is inserted into the lamp case 211 is coupled. In detail, the lamp 212 is completely received into the lamp case 211, and the coupling hole (not shown) of the bracket 51 is fitted to the coupling protrusion 218 formed at each corner of the lamp case, The coupling of the lamp assembly 21 is completed.

By the configuration as described above, there is an advantage that the stable structure of the lamp assembly 21 is provided.

FIG. 11 is a cross-sectional view taken along line II ′ of FIG. 6, and is a perspective view illustrating air flow of the lamp assembly of the optical engine according to the present disclosure.

First, the driving force of the air flow for cooling the lamp 212 in which high heat is generated is provided by a lamp cooling fan (see 141 of FIG. 5) formed at one side of the lamp assembly 21. In other words, the lamp cooling fan 141 provides a suction force to suck air, so that the air at the rear of the lamp assembly 21 is discharged forward through the interior of the lamp assembly 21, thereby, The inside of the assembly 21 is cooled efficiently.

Referring to FIG. 11, air at the rear of the lamp assembly 21 is introduced into the lamp assembly 21 by suction force provided by the lamp cooling fan 141. In detail, the air is introduced into the lamp assembly 21 through the vent 521 formed in the grill member 52. At this time, the grill member 52 serves to increase the cooling efficiency inside the lamp by allowing the air to flow in a constant direction.

As described above, the air introduced into the lamp assembly 21 flows along the guide part 512 formed near the grill member 52 and flows into the lamp bulb 215 with almost no loss of air flow rate. do. In addition, the air introduced into the lamp bulb 215 absorbs heat emitted from the lamp 212 while flowing inside the lamp bulb 215, and then the lamp assembly 21 through the guide part 512 of the other side. Discharged outside).

Preferably, the grill member 52 and the guide portion 512 are configured to maximize the flow rate of the air flowing in the lamp bulb 214, after the inlet air cools the entire front surface of the lamp bulb 214 Can be discharged.

As described above, as the flow path of the air is guided by the grill member 52 and the guide part 512, most of the air is introduced into the lamp bulb 215 without loss of air flow rate, thereby providing rapid and efficient cooling. There is an advantage that is made.

On the other hand, in a plurality of components provided to the optical engine 20, high heat is generated by the light generated by the lamp 212, such high heat is to be quickly discharged to the outside for the normal operation of the device There is a need. If the high heat generated during the operation of the device is not discharged to the outside, there is a problem that the matching of the image may be distorted due to the expansion of the parts, and the problem of oxidizing the DMD panel and various films may occur.

To this end, in the present invention, cooling is performed by the air sucked into the fan. Hereinafter, the cooling system of the projection system that solves this problem will be described in detail.

The cooling system of the present invention is divided into three parts, a first cooling system mainly for cooling the synthesis system, a second cooling system for cooling the lamp 212 in which high heat is directly generated, and a color wheel 221 rotating at high speed. A third cooling system for cooling) is included.

First, the first cooling system is a cooling system operated by the DMD fan 12, in which cool air outside the projection system 1 flows into the DMD fan 12 on the side of the synthesis system, thereby generating from the synthesis system. The hot air being cooled can be cooled.

In other words, the cooling system by the DMD fan 12 is configured to allow the sound pressure provided from the DMD fan 12 to be transmitted to the synthesis system. In addition, the sound pressure generated in the DMD fan 12 may be transmitted to the synthesis system and may be transmitted to other components near the DMD fan 12 to be cooled.

On the other hand, the second cooling system according to the present invention is a system operated by the lamp cooling fan 141 placed in front of the lamp assembly 21, the lamp cooling fan 141 is located near the power supply 15 After the air flows into the lamp 212 side and absorbs the high heat of the lamp 212, the lamp cooling fan duct 42 and the lamp cooling fan 141 formed on the front surface of the lamp assembly 21 may be used. Allow to be discharged to the outside. As a result, the lamp 212 in which high heat is generated can be cooled quickly and efficiently.

Meanwhile, the third cooling system according to the present invention is a system operated by the color wheel cooling fan 43 formed at the rear of the light tunnel housing 23 so that the color wheel 221 rotating at high speed is cooled. to be. The color wheel cooling fan 43 flows into the light tunnel housing 23 after the air near the power supply unit 15 enters the light tunnel housing 23, and then cools the light tunnel housing 23, and then discharges it toward the front of the projection system 1. Be sure to

As can be seen from the above structure, the first, second and third cooling systems are seated adjacent to where the heat source is placed to provide suction, so that cold air is absorbed by the fan as it passes through the heat source and is then drawn into the fan and discharged. It consists of a structure to make it possible. Since the air sucked by such a suction type cooling system can stably flow in the form of laminar flow when flowing into a high temperature part, for example, a color wheel, it is possible to obtain the advantage that the high temperature part increases the cooling efficiency. . In addition, since foreign matters are not lifted by the air flowing into the high-temperature parts, it is possible to obtain an advantage of preventing contamination by foreign matters.

By the cooling system according to the present invention it is possible to obtain an advantage that the cooling efficiency is improved while reducing the contamination of the projection system, in particular the optical engine.

According to the present invention, the grill member and the guide part are provided at one side of the lamp assembly of the optical engine to guide the air flow path, so that the interior of the lamp assembly and the optical engine can be cooled quickly and efficiently and stably operated. .

In addition, since the integrated supporter is provided in the lamp mounting portion of the lamp assembly of the optical engine, the lamp is stably fixed and supported, manufacturing and assembly are easy, and manufacturing cost is reduced.

In addition, the lamp mounting portion of the lamp assembly of the optical engine is provided with a grill member that can guide the air introduced into the grill member, there is an effect that the heat dissipation effect is maximized.

In addition, even if the optical engine is used for a long time there is an advantage that the operation of the device is performed stably.

Claims (11)

A lamp in which light is generated; A bracket to which the front surface of the lamp is coupled; A lamp case accommodating the lamp therein and having the bracket coupled to an opened side; And And a supporter which is in surface contact with the bracket in a state in which the lamp is fixed so that the lamp is firmly fixed to the bracket. The method of claim 1, The supporter is inserted into the front from the rear of the lamp, the projection system, characterized in that coupled to the bracket. The method of claim 1, The supporter includes a lamp insertion hole through which the lamp penetrates; The close contact with the surface in contact with the bracket, And a guide part connected between both ends of the close contact part and formed by bending or bending a plurality of times at a predetermined curvature. The method of claim 1, The lamp includes a lamp burner for emitting white light, and a reflector for condensing the light emitted from the lamp burner to a point, And the bracket presses the front part of the reflector so as to be in close contact with the lamp case. The method of claim 1, The grill system is provided on one side of the lamp case, the grill member for guiding the outside air into the lamp case further comprises a projection system. A lamp in which light is generated; A lamp case accommodated inside the lamp case to fix and support a position of the lamp; And Is coupled to one side of the lamp case, the grill member for guiding the outside air into the lamp case; Includes, The grill member is a projection system characterized in that a plurality of inclined plates which are inclined at a predetermined angle are arranged at a predetermined interval, so that the outside air to be sucked is guided to the front of the lamp. delete The method of claim 6, A bracket coupled to the lamp case while the lamp is in close contact; And a supporter for stably fixing the lamp to the bracket and for guiding external air sucked through the grill member into the lamp. A lamp including a lamp burner and a reflector for concentrating light emitted from the lamp burner in one place; A lamp case in which the lamp is accommodated; A bracket in which the front part of the reflector is in close contact with one surface; And a supporter that presses the front part of the reflector from the rear to fix the bracket more firmly and guides the sucked air into the reflector. The method of claim 9, The grill member is provided on the side of the lamp case to guide the intake of external air further includes, And the supporter extends toward the grill member to guide air passing through the grill member into the reflector. The method of claim 9, The front rim of the reflector is provided with a depression curved at a predetermined curvature, so that the outside air is easily sucked out and discharged into the reflector, The supporter is a projection system characterized in that the guide portion is formed along the outer peripheral surface of the depression.

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