JP2004327207A - Optical device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a constitution of an optical device in which the optical device composed of a concave reflecting mirror and a discharge lamp is miniaturized and the occurrence of crack at a negative electrode side sealing part is prevented. <P>SOLUTION: This device is composed of an ultra-high pressure discharge lamp 1 and the concave reflecting mirror 20 surrounding this discharge lamp 1, and as for the discharge lamp 1, a pair of the sealing parts 11 are connected to both edges of a light emitting part 10 composed of quartz glass, and 0.15 mg/mm<SP>3</SP>or more of mercury is enclosed in this light emitting part 10 and a pair of electrodes 3, 4 are arranged with a distance of 2.0 mm or less. Then, as for the ultra-high pressure discharge lamp 1, the length of the positive electrode side sealing part 11a is 20 mm or less, and it is connected and sustained in a state that this positive electrode side sealing part 11a is inserted into the top part 21 of the concave reflecting mirror via an inorganic adhesive 13 containing sodium component and/or lithium component, and this inorganic adhesive 13 is electrically insulated from the positive electrode of the discharge lamp 1. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ultra-high pressure discharge lamp having a mercury vapor pressure of 150 atm or more when turned on, and in particular, for projection of a projector device such as a liquid crystal display device or a DLP (digital light processor) using a DMD (digital mirror device). It relates to an ultra-high pressure discharge lamp used as a light source.
[0002]
[Prior art]
The projection type projector device is required to illuminate an image uniformly on a rectangular screen with sufficient color rendering properties. For this reason, a metal halide lamp in which mercury or a metal halide is sealed has been used as a light source. Further, further miniaturization and point light sources have been promoted, and those having an extremely small distance between electrodes have been put to practical use.
[0003]
Under such circumstances, a lamp having an extremely high mercury vapor pressure, for example, 200 bar (about 197 atm) or more has been proposed in place of the metal halide lamp. This lamp suppresses the spread of the arc and increases the light output further by increasing the mercury vapor pressure. For example, JP-A-2-148561 (U.S. Pat. 181) and JP-A-6-52830 (U.S. Pat. No. 5,497,049).
[0004]
On the other hand, since the projector device employs a DLP (Digital Light Processor) system using a DMD (Micro Mirror Device), there is no need to use a liquid crystal panel, and as a result, attention has been paid to further miniaturization. is there. In other words, a discharge lamp serving as a projection light source of a projector device requires a high light output and an illuminance maintenance ratio, but with the downsizing of the projector device, a downsized reflector and a discharge lamp are also required. .
[0005]
FIG. 6 shows an optical device incorporated in the projector device, which is composed of a concave reflecting mirror and a discharge lamp. (A) shows a normal optical device, and (b) shows an optical device which has been made smaller in size in response to a demand for miniaturization.
In (a), the discharge lamp 1 has a light emitting portion 10 and sealing portions 11a and 11b connected to both ends thereof. A base 12 is attached to the tip of the anode-side sealing portion 11a, and the base 12 is attached to a support member 14 via an adhesive 13. The supporting member 14 is connected to the concave reflecting mirror 2 via a connecting member 15. The connecting member 14 is, for example, a metal plate having ventilation holes, and has a structure capable of cooling the sealing portion 11a.
In (b), while the length of the sealing portion 11a is shortened, the base 12 is attached to the support member 14 via the adhesive 13, and the support member 14 is concavely reflected through the adhesive (not shown) or the like. It is directly attached to the mirror 2. Therefore, as compared with the structure of (a), the difference is that the sealing portion 11a is shorter and the connecting member 15 is not used. The description is based on the assumption that the performance and specifications of the discharge lamp such as the rated power are the same.
[0006]
Here, the discharge lamp and the concave reflecting mirror must be positioned with high accuracy, and must be firmly fixed so that the positional relationship is not destroyed by some vibration. This is because if the arc starting point of the discharge lamp is not located at the focal point of the concave reflecting mirror, the light extraction efficiency is significantly reduced. Accordingly, in both figures (a) and (b), the adhesive plays an extremely important role in fixing the positional relationship between the two. With this background, many optical devices currently on the market only consider the point of securely fixing the discharge lamp and the concave reflecting mirror. Therefore, a large amount of adhesive is injected into the gap formed between the discharge lamp and the reflector or the support member.
[0007]
As described above, in order to reduce the size of the entire optical device, a mounting structure (specifically, the anode-side sealing portion 11a, the base 12, the adhesive 13, the support member 14, and the like) formed on the outer side of the top of the concave reflecting mirror is required. Attention must be paid to miniaturization of such structures. This is because the size and shape of the interior of the concave reflecting mirror are restricted to some extent from the viewpoint of light extraction.
In other words, the demand for downsizing the projector device has led to a demand for downsizing of the optical device, and as a structure therefor, the structure outside the top of the concave reflecting mirror has been downsized.
[0008]
However, in the optical device described above, there was a problem in that the discharge lamp was damaged due to foil floating or cracking in the cathode side sealing portion 11b of the discharge lamp. In particular, comparing the optical devices shown in FIGS. 6A and 6B, it was found that the optical device having the structure shown in FIG. 6B caused more damage.
[0009]
[Problems to be solved by the invention]
The problem to be solved by the present invention is to provide an optical device including a concave reflecting mirror and a discharge lamp, which can be reduced in size and can prevent the occurrence of cracks in the cathode-side sealing portion.
[0010]
[Means for Solving the Problems]
In order to solve the above problems, an optical device according to a first aspect of the present invention includes an ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the discharge lamp. Is connected to the light-emitting part at 0.15 mg / mm ³ The above mercury is sealed, and a pair of electrodes is arranged at 2.0 mm or less. In the ultrahigh-pressure discharge lamp, the length of the anode-side sealing portion is 0.115 times (mm) or less of the rated lighting power (W), and the anode-side sealing portion is inserted into the top of the concave reflecting mirror. In this state, it is held in contact with an inorganic adhesive containing a sodium component and / or a lithium component, and the inorganic adhesive is electrically insulated from the anode of the discharge lamp. It is characterized by.
[0011]
Further, the optical device according to the second invention is an optical device comprising the above-mentioned ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the discharge lamp, wherein the ultra-high pressure discharge lamp has an anode-side sealing portion at the top of the concave reflecting mirror. In the state of being inserted in, the contact member is held in contact with an inorganic adhesive containing a sodium component and / or a lithium component, and the inorganic adhesive has a conductive member electrically connected to an anode. The lamp is in contact at a position where the temperature is 450 ° C. or less when the lamp is turned on.
[0012]
Further, the optical device according to the third invention is an optical device comprising the above-mentioned ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the discharge lamp, wherein the ultra-high pressure discharge lamp has an anode side sealing portion formed of the concave reflecting mirror. In the state of being inserted into the top portion, the electrode is held in contact with an inorganic adhesive containing a sodium component, and a conductive member electrically connected to the anode includes a light emitting part and an anode. It is characterized by being separated from the boundary position of the side sealing portion toward the anode side sealing portion by 1/20 (mm) or more of the lamp lighting power (W).
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a schematic configuration diagram for explaining an optical device according to the first invention.
The optical device includes a short arc type ultra-high pressure discharge lamp 1 (hereinafter, also simply referred to as a “discharge lamp”) and a concave reflecting mirror 2 surrounding the discharge lamp 1. The optical axis L of the concave reflecting mirror 2 and the discharge lamp 1 are arranged so that their arc directions substantially coincide with each other, and the arc luminescent spot of the discharge lamp 1 coincides with the first focal point of the concave reflecting mirror 2.
[0014]
The discharge vessel of the discharge lamp 1 includes a substantially spherical light emitting portion 10 and rod-shaped sealing portions 11a and 11b connected to both ends of the light emitting portion 10. In the light emitting portion 10, an anode 3 and a cathode are provided. 4 are opposed to each other. The anode-side sealing portion 11a of the discharge lamp 1 is inserted into the opening of the top 21 of the concave reflecting mirror 2, and the anode-side sealing portion 11a is attached to the support member 14 via the adhesive 13. A power supply lead 16 protrudes from the tip of the sealing portion 11a, and is electrically connected to a power supply device (not shown) via a power supply line or the like. The support member 14 is made of a ceramic material or the like. For example, the support member 14 may have a shape in which the cylindrical portion integrally extends from the top of the concave reflecting mirror.
[0015]
The reflecting mirror 2 is a generally bowl-shaped elliptical converging mirror as a whole, and includes a top 21 and a front opening 22. The front opening 22 is necessary for emitting light, and the top 21 is also provided with an opening for mounting a discharge lamp. A dielectric multilayer film of, for example, titanium oxide (TiO2) and silica (SiO2) is formed on the inner surface of the reflecting mirror 2 and has a function of reflecting a desired wavelength, and the focal position of the reflecting mirror 2 is a discharge position. It is located at the arc bright spot of the lamp 1. As a material of the reflecting mirror, for example, borosilicate glass is employed, but the reflecting mirror may be formed of a metal member such as aluminum or a ceramic mix. A light-transmitting front glass 23 made of, for example, borosilicate glass is attached to the front opening 23 of the reflecting mirror 2. By providing the front glass 23, the inside of the reflecting mirror 2 can be made a closed structure. Therefore, in the event that the discharge lamp 1 is damaged, it is possible to prevent the fragments from being scattered. The front glass 23 is not indispensable, and a structure without the front glass can be adopted when the necessity of cooling the discharge lamp is high. Further, a structure in which the front glass 23 is provided but the inside is not completely closed, but a cooling opening is partially provided may be employed.
[0016]
The joining of the discharge lamp 1 and the reflector 2 is performed outside the top 21 of the reflector 2 and around the sealing portion 11a of the discharge lamp 1. Specifically, the adhesive 13 is injected into a gap between the sealing portion 11a and the support member 14. The adhesive 13 is injected in such a large amount that it completely fills the gap between the two, and therefore may exist near the boundary between the light emitting unit 10 and the sealing unit 11a.
The anode-side sealing portion 11a located on the top opening side of the concave reflecting mirror 2 is shortened in order to cope with miniaturization of the optical device. Specifically, it is 0.115 times or less (mm) of the lamp lighting power (W), and is 23 mm or less when the rated power is 200 W, and 20.7 mm or less when the rated power is 180 W. This is because the length of the sealing portion depends on the temperature in principle, and the temperature depends on the rated operating power of the lamp.
[0017]
The adhesive is an inorganic adhesive containing at least a sodium component or a lithium component. For example, Sumiceram (trade name) and siloxane (trade name) are employed. As for the components, Sumiceram is introduced as an example. ₂ ), Alumina (Al ₂ O ₃ ), Water (H ₂ O) as a main component and sodium oxide (Na ₂ O ₃ ) And lithium oxide (Li ₂ O) is contained in a trace amount.
[0018]
The optical device of the first invention is characterized in that the inorganic adhesive is electrically insulated from the anode of the discharge lamp, and the two are not electrically connected. More specifically, the outer peripheral surface of the anode-side sealing portion 11a is filled with the inorganic adhesive 13 in contact therewith, but the adhesive 13 does not directly contact the external lead 16, There is no contact with the lead 16 via a conductive member or the like.
[0019]
FIG. 2 is an enlarged view for explaining the anode-side sealing portion and the adhesive of the discharge lamp.
The shaft 31 of the anode 3 is joined to a metal foil 32, and the external lead 16 is joined to the other end of the metal foil 32. The metal foil 32 is completely buried in the anode-side sealing portion 11a. With this structure, the discharge space of the light emitting unit 10 can be hermetically sealed, and an electric power supply structure inside and outside the light emitting unit 10 is formed. Molybdenum is used for the metal foil 32.
The adhesive 13 is in contact with the outer surface of the sealing portion 11a. In the figure, for convenience of explanation, the adhesive is shown only on the upper part of the sealing part, but it is present so as to surround the entire outer peripheral surface of the sealing part 11a as shown in FIG.
[0020]
Here, in the optical device shown in FIG. 6, the present inventors have conducted intensive studies on the cause of the occurrence of foil floating and cracks in the cathode-side sealing portion, and as a result, they found the following. .
That is, the sodium component or the lithium component contained in the adhesive 13 is attracted by the cathode of the light emitting unit 10 and moves in the direction shown in FIG. That is, since the sodium component and the lithium component are positively charged, they are attracted to the negative charge of the cathode.
It is considered that the movement of the sodium component and the lithium component may not only occur when moving to the cathode via the light emitting space, but also when moving to the cathode side sealing portion through the inside of the quartz glass constituting the light emitting portion. .
Some of the sodium component and the lithium component have reached the metal foil of the cathode side sealing portion, thereby breaking the junction between them. As a result, the hermetic sealing between the metal foil and the quartz glass is weakened, causing a so-called foil floating phenomenon, and it can be inferred that the progress of the foil floating leads to cracks and lamp damage.
[0021]
This phenomenon occurs in a very short discharge lamp in which the distance between the electrodes is 2.0 mm or less, the emission space is very small, and the length of the anode-side sealing portion is 20 mm or less (when the lighting power is about 180 W). It can be said that this is a technical problem that occurs only when an adhesive is used to combine the anode-side sealing portion of the lamp with the reflector.
In other words, the phenomenon that the sodium component and the lithium component are attracted to the cathode occurs because the distance between the electrodes is short, and the adhesive is applied in a large amount and exists close to the light-emitting part because the anode-side sealing portion is short. Because it becomes.
Here, the length of the anode-side sealing portion means A in the figure, and refers to a portion from the boundary 1 between the light emitting portion 10 and the sealing portion 11 to the outer end of the sealing portion.
[0022]
The present inventors have further studied diligently and found that the movement of the sodium component and the lithium component naturally stops when the adhesive is electrically insulated.
In other words, even if the sodium component or lithium component contained in the adhesive is pulled by the cathode and moves to the cathode-side sealing portion, the adhesive from which the sodium component or lithium component has escaped becomes neutral due to a decrease in positive charge. This is because the state becomes a negative charge, and as a result, the power for moving toward the cathode is lost.
Therefore, as long as the adhesive applied to the sealing portion is electrically insulated, even if some movement of the sodium component or lithium component occurs in the early stage of lamp operation, the movement naturally stops thereafter. As a result, they have found that as a result, there is no practical problem such as foil floating or crack generation.
[0023]
The structure for electrically insulating the adhesive from the anode is not limited to the structure shown in FIG. 2, in which the adhesive is not placed in contact with the position of the adhesive. A sex base can be provided. In addition, not only the base but also an insulating member can be employed as a partition.
[0024]
Next, the optical device of the second invention will be described.
FIG. 3 shows an optical device including a discharge lamp and a concave reflecting mirror, and FIG. 4 shows a structure in which an anode side sealing portion and an adhesive are enlarged. The difference from the structure shown in FIGS. 1 and 2 is that a metal base 12 (conductive member) is attached to the outer end of the sealing portion, and the adhesive 13 contacts the outer peripheral surface of the base 12. are doing. That is, the adhesive 13 is electrically connected to the anode 3 via the metal base 12.
[0025]
The present inventors have found that even if the adhesive is electrically connected to the anode as described above, if the contact position with the adhesive is 450 ° C. or less when the lamp is turned on, the foil floats and cracks can be removed satisfactorily. I found that it could be prevented. Specifically, when a metal base is attached to the outer end of the sealing portion, the position at which the base comes into contact with the adhesive may be 450 ° C. or less.
The reason is that the sodium component and the lithium component contained in the adhesive 13 diffuse (penetrate) into the quartz glass, which is the anode-side sealing portion, as in the structure of FIG. However, unlike the structure of FIG. 2, the adhesive is supplemented with a positive charge, so that the adhesive itself does not change from a neutral state to a negative charge. Therefore, the sodium component and the lithium component may be continuously diffused into the discharge lamp.
[0026]
The second invention solves such a problem. The diffusion of the sodium component and the lithium component into the quartz glass is affected not only by the attractive force based on the electric polarity but also by the temperature at the contact position between the two. I found that. That is, it has been found that the sodium component and the lithium component hardly diffuse into quartz glass under the condition of 450 ° C. or less, preferably 300 ° C. or less, more preferably 200 ° C. or less.
Of course, even under the condition of 450 ° C. or less, the diffusion does not completely stop, some components may diffuse into the quartz glass, and other external factors such as moisture, static electricity, presence of dust, and the like. Diffusion into quartz glass can occur. However, the temperature is dominant, and as is clear from experiments described below, other external influences are not at a level that leads to foil floating or crack generation.
[0027]
Specifically, the position 12a shown in FIG. 4 has the highest temperature among the contact positions of the base 12 and the adhesive 13, and the temperature of the adhesive at this position 12a becomes a problem. In general, the higher the temperature, the closer to the discharge space. However, for example, when heating or cooling is performed locally, or when the surroundings are locally affected, the position close to the discharge space may not always be a problem. Therefore, it is desirable that the temperature be 450 ° C. or less at all positions where the base 12 comes into contact with the adhesive 13.
It does not matter that the adhesive is applied to the discharge space side from the position 12a as shown in FIG. This is because, in this portion, even if sodium component and lithium component enter the quartz glass, they do not continue.
[0028]
In the structure in which the contact position between the base 12 and the adhesive 13 is set to 450 ° C. or less, it is desirable to provide a cooling structure such as a fan outside and forcibly cool the structure. In this case, a cooling fan can be provided on the side of the support member 14, and when the concave reflecting mirror 2 is not provided with the front glass 23 or when a cooling opening is provided in a part thereof, the cooling air flows from the front opening 22. It is also possible to spray. Further, a structure in which cooling fins are attached to the base 12 is also desirable.
[0029]
Further, in the structure without the conductive member as shown in FIG. 2, even when the adhesive directly contacts the external leads, the temperature of the adhesive is set to 450 ° C. or less, so that the sodium component and the lithium The components can be prevented from diffusing into quartz glass. In this case, the external lead corresponds to a conductive member electrically connected to the anode.
[0030]
Next, an optical device according to a third invention will be described.
The present invention can be described using the structure shown in FIGS.
In the structure shown in FIGS. 3 and 4, the metal base 12 as the conductive member is separated from the boundary position 17 between the light emitting part and the sealing part by a distance (mm) 1/20 times the lamp lighting power (W). It features a structure that comes into contact with the adhesive at the position. That is, the present inventors have found that adopting this structure can solve the problems of foil floating and cracking without defining the contact position by temperature as in the second invention. The second invention specifies the contact position by the temperature of the adhesive, while the third invention specifies a specific distance.
[0031]
The reason is that the temperature of the adhesive is dominantly affected by the heat generated from the discharge lamp, so that the position can be generally specified by the rated lighting power and the distance of the discharge lamp. Specifically, it is necessary to separate from the position 17 to the outer end of the sealing portion by a distance (mm) 1/20 times the rated power. The present inventors have determined that the mercury amount is 0.15 mg / mm. ³ As described above, the distance between the electrodes is 2.0 mm or less, the anode-side sealing portion is 20 mm or less (when the lighting power is about 180 W), and the discharge lamp and the concave reflecting mirror are attached using an inorganic adhesive containing a sodium component or a lithium component. In the structure, when the rated power is 100 (W), the distance is about 5 (mm), when the rated power is 150 (W), the distance is about 7.5 (mm), and when the rated power is 180 (W), the distance is about 9 (mm). mm), a distance of about 10 (mm) for a rated power of 200 (W), a distance of about 12.5 (mm) for a rated power of 250 (W), and a distance of about 15 (mm) for a rated power of 300 (W). mm), it has been confirmed that the problems of foil floating and cracks can be solved. This distance means the distance between the boundary position 17 between the light emitting portion and the anode-side sealing portion and the position closest to the light emitting portion where the conductive member 12 contacts the adhesive 13.
[0032]
That is, if the position of the adhesive is defined based on the distance determined by the relationship with the rated lighting power of the discharge lamp, the temperature of the adhesive is substantially lower than 450 ° C., and the contents described in the second invention are described. In the same manner as described above, the ability to diffuse sodium and lithium components can be reduced.
The above distance is defined for the case where a forced cooling mechanism is not provided, and when a forced cooling mechanism is provided, the contact position between the adhesive and the conductive member is set to a value smaller than the above distance. Can be.
[0033]
Numerical examples in the mounting structure of the concave reflector and the discharge lamp will be introduced in common with the first invention, the second invention, and the third invention.
The length of the anode-side sealing portion 11a needs to be 0.115 times (mm) or less of the lamp rated lighting power (W) as described above. Specifically, when the rated power is 150 (W), Is equal to or less than 17.25 (mm), 20.7 (mm) or less for rated power of 180 (W), 23 (mm) or less for rated power of 200 (W), and rated power of 300 (W). It is necessary to be 5 (mm) or less. Considering only miniaturization of the optical device, it is preferable to make it as small as possible. However, if the lighting point force of the lamp becomes large, it may not be possible to simply shorten it because of the influence of temperature. Specifically, in the case of a rated power of 200 (W), the range is, for example, 10 mm to 20 mm, and for example, 15 mm, 18 mm, and 20 mm are employed.
The outer diameter of the sealing portion is selected from the range of φ5 mm to 8 mm, and is, for example, φ5.8 mm. If only the miniaturization of the optical device is considered, it is desirable that the sealing portion is as small as possible in both length and outer diameter.However, the sealing portion has a certain size due to the support of the electrodes, the hermetic sealing of the light emitting portion, and other restrictions on manufacturing operations. Is required, and the lower limit is set as described above.
The opening diameter of the top 21 of the concave reflecting mirror 20 is selected from a range of φ30 mm to 100 mm, and is, for example, φ50 mm.
The inner diameter of the support member 14 is selected from a range of φ8 mm to 18 mm, and is, for example, φ12 mm.
[0034]
The conductive member 12 is a metal base made of, for example, brass, nickel, or the like, and is attached to the outer end of the sealing portion for the purpose of electrical connection with a connector.
As described above, the adhesive 13 is made of sumiceram or siloxane, and the applied amount is about 1 cc.
[0035]
Further, although the content is common to the first to third inventions, a trigger wire 30 is provided in the discharge lamp as shown in FIGS. One end of the trigger wire 30 is connected to the cathode-side external lead, and the other end is wound around the boundary between the light emitting unit 10 and the anode-side sealing unit 11a. The trigger wire 30 applies a negative charge to the base of the anode at the time of starting the lighting of the discharge lamp, thereby generating a dielectric barrier discharge between the trigger wire and the anode at the time of starting the discharge. There is an operational effect that facilitates starting.
[0036]
The optical device according to the first to third aspects of the present invention is configured such that when one end is connected to the cathode-side external lead and the other end is provided with a trigger wire wound around a boundary position between the light emitting unit 10 and the anode-side sealing unit 11a. Especially effective. This is because the structure in which a negative charge is applied to the base of the anode promotes the electrical attraction of the sodium component and the lithium component contained in the adhesive.
[0037]
The optical device according to the present invention is summarized below.
An optical device according to a first aspect of the present invention has a structure in which an anode-side sealing portion of a discharge lamp and a concave reflecting mirror are attached by an inorganic adhesive containing a sodium component and / or a lithium component, and the inorganic adhesive is discharged. Electrical insulation from the anode of the lamp. In this case, even if the sodium component and / or the lithium component of the inorganic adhesive diffuses into the quartz glass of the discharge lamp, the inorganic adhesive changes from a neutral state to a negative charge state. It is the content that the diffusion of nature stops naturally.
[0038]
The optical device according to the second invention also has a structure in which the anode-side sealing portion of the discharge lamp and the concave reflecting mirror are attached by an inorganic adhesive containing a sodium component and / or a lithium component. Even when the agent is electrically connected to the anode of the discharge lamp, the contact position on the adhesive is set to 450 ° C. or less. In this case, since this temperature is a temperature at which the adhesive is not activated, even if the supply of the positive charge is continued, the diffusion of the sodium component and / or the lithium component into the quartz glass is reduced to a level having no practical effect. It is content that can be prevented.
[0039]
The optical device according to the third aspect of the present invention has the same structure as described above, and even when the inorganic adhesive is electrically connected to the anode of the discharge lamp, the contact position on the adhesive is the rated power of the discharge lamp. Is separated from the light-emitting unit by a distance that is 1/20 times the distance. In this case, similarly to the second invention, since the temperature is such that the adhesive is not activated, even if the supply of the positive charge is continued, the diffusion of the sodium component and / or the lithium component into the quartz glass is practically possible. The content is that it can be prevented to a level that has no effect.
[0040]
FIG. 5 is a schematic overall view of an example of a discharge lamp used in the optical device of the present invention.
The discharge lamp 1 has a substantially spherical light emitting portion 10 formed by a discharge vessel made of quartz glass. In the light emitting portion 10, an anode 3 and a cathode 4 are arranged so as to face each other. Further, sealing portions 11a and 11b are formed so as to extend from both ends of the light emitting portion 10, and a conductive metal foil 32 usually made of molybdenum is buried in these sealing portions 11 in an airtight manner by, for example, a shrink seal. ing. One end of the metal foil 32 is joined to the anode 3 or the cathode 4, and the other end of the metal foil 32 is joined to the external lead 16.
Note that the anode 3 and the cathode 4 may be expressed as electrodes including the rod-shaped portion bonded to the metal foil, but in the present invention, unless otherwise specified, the anode rod-shaped portion 31 and the cathode rod-shaped portion 41 are used. I will call it.
[0041]
The light emitting unit 10 is filled with mercury, a rare gas, and a halogen gas.
Mercury is used to obtain a required visible light wavelength, for example, radiation light having a wavelength of 360 to 780 nm, and is 0.15 mg / mm. ³ It is enclosed above. The amount of sealing varies depending on the temperature conditions, but becomes extremely high at 150 atm or more during lighting. In addition, by filling in more mercury, a discharge lamp having a high mercury vapor pressure of 200 atm or more and 300 atm or more at the time of lighting can be produced. As the mercury vapor pressure becomes higher, a light source suitable for a projector device is formed. Can be realized.
As the rare gas, for example, argon gas is filled in at about 13 kPa, and the lighting startability is improved.
Halogen is enclosed in the form of a compound of iodine, bromine, chlorine and the like with mercury and other metals. The amount of halogen enclosed is, for example, 10 ^-6 -10 ^-2 μmol / mm ³ The function is to extend the life of the lamp using a halogen cycle.However, the discharge lamp of the present invention, which is extremely small and has a high internal pressure, encapsulates such a halogen. This is considered to have the effect of preventing the discharge vessel from being damaged or devitrified.
[0042]
As an example of the numerical value of such a discharge lamp, for example, the outer diameter of the light emitting portion is selected from a range of φ6.0 to 15.0 mm, for example, 9.5 mm, and the distance between the electrodes is 0.5 to 2.0 mm. For example, 1.5 mm selected from the range, the inner volume of the arc tube is 40 to 300 mm ³ 75mm selected from the range ³ It is. The lighting condition is, for example, a tube wall load of 1.5 W / mm. ² , Rated voltage 80V and rated power 150W.
Further, the discharge lamp is built in a projector device or the like that is downsized, and requires a high light amount while the overall structure is extremely downsized. Therefore, the thermal conditions in the light emitting section become extremely severe, and the tube wall load value is 0.8 to 2.0 W / mm. ² , Specifically 1.5 W / mm ² That is.
Then, it is mounted on a presentation device such as the projector device or the overhead projector, and can provide emitted light having good color rendering properties.
[0043]
As shown in FIG. 5, when the diameter of the light emitting portion is large, it is preferable that the diameter of the shaft portion of the electrode be reduced at the joint with the metal foil. This is because if the electrode diameter is large, the bonding area with the metal foil also increases, and undesired voids may be generated in the bonding of the two, which may promote the entry of sodium and lithium components.
The outer diameter of the anode shaft 31 shown in the figure is smaller than that of the anode 3, and the outer diameter of the anode shaft 31 is also reduced in two stages. The outer diameter of the anode 3 is, for example, 1.8 mm, and the outer diameter of the anode shaft 31 is, for example, 1.4 mm and 0.5 mm. The heat capacity can be increased by increasing the volume of the anode 3. In particular, in the discharge lamp of this embodiment, since the anode 3 is present in the sealing portion 11 to the inside, the heat generated by the light emitting portion 10 can be radiated well.
The optical device of the present invention considers the influence of the adhesive directly applied to the sealing portion in a discharge lamp in which the temperature of the light emitting section 10 is extremely high and the thermal conditions are severe.
[0044]
The discharge lamp used for the optical device of the present invention is a direct current lighting type discharge lamp, and the anode side sealing portion is located at the top opening of the concave reflecting mirror. In the structure in which the cathode side sealing portion is arranged at the top opening of the reflecting mirror, even if the adhesive comes into contact with the metal base, a negative charge is applied to the adhesive from the base and supplied. That is, since the sodium component and the lithium component contained in the adhesive are originally electrically connected to the cathode, the phenomenon of diffusing into the quartz glass does not occur. Therefore, an optical device having a structure in which the cathode side sealing portion is inserted and attached to the top opening of the reflecting mirror does not originally have the technical problem to be solved by the present invention.
[0045]
However, even in the case of a discharge lamp of DC lighting, a case where the electrode polarity is temporarily reversed for some reason to be lit, or an AC lamp, a rectangular wave lamp, or a discharge lamp which is lit by other waveforms for the same reason, the same applies. In the case of temporary DC lighting, the configuration of the optical device of the present invention is applied if the electrode arranged on the top of the concave reflecting mirror becomes an anode during the temporary DC lighting. be able to.
[0046]
For example, a discharge lamp that performs AC lighting during steady lighting may perform DC lighting when lighting is started. In particular, 0.15 mg / mm of mercury ³ In the sealed discharge lamp described above, DC lighting is often performed when the lighting is restarted immediately after the lamp is turned off. Because the mercury vapor pressure in the light emitting unit is high and cannot be turned on by normal startup, this is to use the above-described electrical induction by the trigger wire.
In this case, it is effective to arrange the electrode to be an anode on the top of the concave reflecting mirror and to arrange the electrode to be the cathode on the front opening side of the concave reflecting mirror, only at the start of lighting.
[0047]
The optical device of the present invention is based on the precondition that an inorganic adhesive containing a sodium component and a lithium component is used. In this case, not only the case where either the sodium component or the lithium component is contained, but also the case where both are contained. In addition, not only the case where the sodium component and the lithium component are essential components, but also the case where they are contained in trace amounts as impurities. In particular, the present invention is effective when the concentration of sodium or lithium contained in the adhesive is higher than the concentration of sodium or lithium contained as impurities in quartz glass constituting the sealing portion. This is because it is easy to penetrate by diffusion.
[0048]
Although it is ideal to use a material that does not contain a sodium component or a lithium component as an adhesive and adopt a structure in which the adhesive does not come into contact with the sealing portion, as described above, the discharge lamp and the concave reflecting mirror are Since the adhesive must be positioned with high accuracy and must be firmly fixed so that the positional relationship does not collapse, currently known adhesives are not enough. The reality is that you have to make contact.
[0049]
Next, an experiment on the optical device of the present invention will be described.
The discharge lamp has a maximum outer diameter of the light-emitting portion of 10 mm, a distance between the electrodes of 1.2 mm, and a discharge tube inner volume of 66 mm. ³ , Anode side sealing part length 20 mm, mercury filling amount 0.25 mg / mm ³ , Halogen and enclosing quantity 4 × 10 ^-4 μmol / mm ³ , Tube wall load 1.5W / mm ³ , A rated voltage of 82 V and a rated power of 200 W.
In the experiment, three types of optical devices (experimental device {circle around (1)}, experimental device {circle around (2)}, and experimental device {circle around (3)}) were prepared, and each experiment was performed several times. The experimental device (1) and the experimental device (2) are optical devices having the structure shown in FIGS. 3 and 4, and the experimental device (3) is an optical device having the structure shown in FIGS.
Specifically, the experimental device (1) uses a conductive member that is electrically connected to the anode, and is in contact with the adhesive at a distance of 4 mm from the light emitting unit. The experimental device (2) uses a conductive member electrically connected to the anode, and is in contact with the adhesive at a distance of 10 mm from the light emitting portion. The distance in this case is a distance from a boundary position between the light emitting portion and the anode-side sealing portion. "Sumiceram" was used for the adhesive, and the conductive member was formed by winding a metal coil. In the experimental device (3), the adhesive and the anode were insulated without using a conductive member.
[0050]
Comparing the experimental device (1) and the experimental device (2) based on the results of several experiments, the experimental device (1) generated red luminescence, which is sodium luminescence, within a few minutes after the lamp was turned on. 2 ▼ hardly generated red light emission.
Further, when lighting was continued, the experimental device (1) was turned off due to the occurrence of cracks in about 40 minutes, while the experimental device (2) was kept turned on.
In addition, when the same experiment was performed by appropriately changing the distance in the range of 5 mm to 8 mm, although the time and the degree of occurrence were slightly different, the result was close to that of the experimental device (1), that is, sodium Red light emission, foil floating at the cathode side sealing portion, and cracks were generated.
From this experimental result, it can be seen that, at a distance of 10 mm from the light emitting portion, red light emission caused by sodium can be dramatically reduced, and the occurrence of foil floating and cracks can be significantly reduced.
As a comparative example, when a discharge lamp to which no adhesive was applied was similarly caused to emit light, red light emission, foil floating, and cracks did not occur. As a result, it was found that sodium contained in the adhesive was diffused in the red light emission, and that the floating of the foil and cracks were also affected by sodium.
[0051]
In the experimental device (3), although red light emission by sodium was observed in the first few minutes, it gradually decreased, and the red light emission disappeared by lighting for about 20 minutes. Also, no foil floating or cracking occurred. That is, it was proved that the insulation from the anode can stop the diffusion of the sodium component naturally.
[0052]
As described above, the first optical device of the present invention has a structure in which the anode-side sealing portion of the discharge lamp and the concave reflecting mirror are attached by an inorganic adhesive containing a sodium component and / or a lithium component, The inorganic adhesive is electrically insulated from the anode of the discharge lamp. With this configuration, even if the sodium component and / or lithium component of the inorganic adhesive diffuses into the quartz glass of the discharge lamp, the inorganic adhesive changes from a neutral state to a negative charge state. Diffusion can be stopped naturally.
[0053]
Further, the second optical device of the present invention has a structure in which the anode-side sealing portion of the discharge lamp and the concave reflecting mirror are similarly attached by an inorganic adhesive containing a sodium component and / or a lithium component. Even if the system adhesive is electrically connected to the anode of the discharge lamp, the contact position on the adhesive is set to 450 ° C. or less. With this configuration, the temperature can be set so that the adhesive is not activated, and even if the supply of the positive charge is continued, the diffusion of the sodium component and / or the lithium component into the quartz glass is reduced to a level that has no practical effect. Can be prevented.
[0054]
Further, the third optical device of the present invention has the same structure as that of the second invention, and even if the inorganic adhesive is electrically connected to the anode of the discharge lamp, the contact position on the adhesive is Is separated from the light emitting part by a distance 1/20 times the rated power of the discharge lamp. With this structure, as in the second invention, the temperature becomes a temperature at which the adhesive is not activated. Therefore, even if the supply of the positive charge is continued, the sodium component and / or the lithium component can be diffused into the quartz glass. It can be prevented to a level where there is no influence.
[Brief description of the drawings]
FIG. 1 is an overall view of an optical device according to the present invention.
FIG. 2 is a partially enlarged view of the optical device according to the present invention.
FIG. 3 is an overall view of an optical device according to the present invention.
FIG. 4 is a partially enlarged view of the optical device according to the present invention.
FIG. 5 shows a discharge lamp used in the optical device according to the present invention.
FIG. 6 shows a discharge lamp used in a conventional optical device.
[Explanation of symbols]
1 Discharge lamp
10 Light emitting unit
11 Sealing part
12 conductive members
13 adhesive
14 Supporting members
20 Concave reflector
21 Top of concave reflector
22 Front opening of concave reflector
23 Front glass
30 Trigger wire

Claims (8)

A pair of sealing portions were connected to both ends of a light emitting portion made of quartz glass, and 0.15 mg / mm ³ or more of mercury was sealed in the light emitting portion, and a pair of electrodes were arranged at a distance of 2.0 mm or less. In an optical device comprising an ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the ultra-high pressure discharge lamp,
The ultrahigh-pressure discharge lamp, wherein the length of the anode-side sealing portion is 0.115 times (mm) or less of the rated lighting power (W),
The anode-side sealing portion is held in contact with an inorganic adhesive containing a sodium component and / or a lithium component in a state of being inserted into the neck portion of the concave reflecting mirror. An optical device, wherein the agent is electrically insulated from the anode. A pair of sealing portions were formed at both ends of a light emitting portion made of quartz glass, and 0.15 mg / mm ³ or more of mercury was sealed in the light emitting portion, and a pair of electrodes were arranged at a distance of 2.0 mm or less. In an optical device comprising an ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the ultra-high pressure discharge lamp,
The ultrahigh-pressure discharge lamp, wherein the length of the anode-side sealing portion is 0.115 times (mm) or less of the rated lighting power (W),
Further, in this ultrahigh-pressure discharge lamp, the anode-side sealing portion is held in contact with an inorganic adhesive containing a sodium component and / or a lithium component with the anode-side sealing portion inserted into the neck of the concave reflecting mirror. An optical device, wherein a conductive member electrically connected to an anode is in contact with the inorganic adhesive at a temperature of 450 ° C. or less when the lamp is turned on. A pair of sealing portions were formed at both ends of a light emitting portion made of quartz glass, and 0.15 mg / mm ³ or more of mercury was sealed in the light emitting portion, and a pair of electrodes were arranged at a distance of 2.0 mm or less. In an optical device comprising an ultra-high pressure discharge lamp and a concave reflecting mirror surrounding the ultra-high pressure discharge lamp,
The ultrahigh-pressure discharge lamp, wherein the length of the anode-side sealing portion is 0.115 times (mm) or less of the rated lighting power (W),
Further, in this ultrahigh-pressure discharge lamp, the anode-side sealing portion is held in contact with an inorganic adhesive containing a sodium component and / or a lithium component with the anode-side sealing portion inserted into the neck of the concave reflecting mirror. ,And,
In the inorganic adhesive, a conductive member electrically connected to the anode includes 1/1 / RW of the rated lighting power (W) from the boundary position between the light emitting portion and the anode side sealing portion toward the anode side sealing portion. An optical device which is separated by 20 (mm) or more. 4. The optical device according to claim 2, wherein the conductive member is a metal base that covers an outer end of the anode-side sealing portion. 5. The optical device according to claim 1, wherein the anode-side sealing portion is held by a holding member with the inorganic adhesive interposed therebetween, and the holding member joins a neck of the concave reflecting mirror. apparatus. The ultra-high pressure discharge lamp is characterized in that one end is connected to an external lead extending from the cathode side sealing portion, and the other end has a trigger wire wound around a boundary position between the anode side sealing portion and the light emitting portion. The optical device according to claim 1. The optical device according to claim 1, wherein the ultra-high pressure discharge lamp is a DC lighting type lamp. The optical device according to claim 1, wherein the ultra-high pressure discharge lamp is a lamp that performs DC lighting at least at an initial stage of lighting and then performs AC lighting thereafter.

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