This Application is a National Phase Application under 35 U.S.C. 371 claiming the benefit of PCT/JP03/08447 filed on Jul. 2, 2003, which has the priority based on Application No. Japan 2002-192881 filed on Jul. 2, 2002.
The present invention relates to a compact self-ballasted electrodeless discharge lamp and an electrodeless-discharge-lamp lighting device.
In recent years, from the viewpoints of global environment protection and economical efficiency, compact self-ballasted fluorescent lamps with electrodes, which are about five times higher in efficiency in comparison with incandescent lamps and also have an operating life time about six times longer than that of incandescent lamps, have been widely used in houses, hotels and the like in place of incandescent lamps. Moreover, recently, in addition to conventionally-used compact self-ballasted fluorescent lamps with electrodes, electrodeless compact self-ballasted fluorescent lamps have been utilized. Since the electrodeless fluorescent lamp, which has no electrodes, has an operating life time that is about two times longer than that of a fluorescent lamp with electrodes, it is expected to spread more and more in the future.
Conventionally, incandescent lamps having various shapes have been devised and put into practical use, and those having a pyriform shape have been most widely used. This shape is defined as A-type in JIS C7710-1988, and is also defined in the same manner internationally in IEC 60887-1988, and in accordance with this standard, similar standards have been set in the United States, Europe, etc. Most of lighting devices for lighting incandescent lamps have been prepared on the premise to be used for these A-type incandescent lamps. For this reason, with respect to the compact self-ballasted fluorescent lamps also, in particular, there have been demands for practically providing the shape and the size similar to those of A-type incandescent lamps.
The size of the generally-used A-type incandescent lamp is set to 60 mm in diameter and 110 mm in height from the top of the bulb to the tip of the base, for example, in the case of the incandescent lamp of 100 W in input power, and in order to replace incandescent lamps, it is important to determine the size of the compact self-ballasted fluorescent lamp so as not to excessively exceed the above-mentioned size.
Different from the incandescent lamp, the fluorescent lamp converts ultraviolet emitted by mercury that has been excited by electric discharge into visible light through a phosphor layer applied onto an external-tube bulb (bulb); thus, the fluorescent lamp functions as a light source. Among the ultraviolet emitted by mercury, in particular, that having luminescent line emission with a wavelength of 253.7 nm has the highest conversion efficiency to visible light in the phosphor layer. In other words, the efficiency of a fluorescent lamp is determined by the radiation efficiency of ultraviolet luminescent line of 253.7 nm. This efficiency in the fluorescent lamp is determined by the number density in mercury atoms inside the lamp, that is, the vapor pressure, and the highest efficiency is achieved in the case of about 6 m Torr (about 798 mPa). This state corresponds to the saturated vapor pressure at about 40° C. of the mercury droplet. For this reason, in an attempt to design a fluorescent lamp having high efficiency, it is desirable to set the temperature of at least a portion of the external-tube bulb to have the lowest temperature (hereinafter, referred to as the coldest point) to the vicinity of 40° C. Thus, excessive mercury vapor is allowed to form droplets at the coldest point.
Here, in general, in the case of a compact self-ballasted fluorescent lamp to be used for substituting an incandescent lamp, the size of the lamp is smaller for the power to be supplied to the lamp in comparison with a tublar fluorescent lamp. For this reason, upon operating, the temperature of the bulb becomes higher, and it is difficult in principle to set the temperature of the bulb to the vicinity of 40° C. In other words, in comparison with the straight tube fluorescent lamp and the like, the compact self-ballasted fluorescent lamp has a greater power per unit surface area, with the result that heat radiation from the lamp surface is not carried out sufficiently to cause a high temperature in the bulb.
With respect to the countermeasures to these problems, for example, Japanese Patent Application Laid-Open No. 11-31476 has proposed a method in which amalgam is used. In this method, by allowing amalgam to adsorb excessive mercury vapor that exceeds the optimal value due to a temperature rise upon operation, the mercury vapor pressure at the time of operation is controlled to the vicinity of the optimal value, and Bi—In based and Bi—Pb—Sn based amalgams, which have a mercury-vapor-pressure-controlling function, are utilized in this method.
Further, Japanese Patent Application Laid-Open No. 2001-325920 has proposed another countermeasure in which, a bump portion is formed at a portion to have the lowest temperature in a bulb toward the outside of the bulb so that heat radiation is locally increased so as to set the temperature of the corresponding portion to the vicinity of 40° C.
In the method using the amalgam, however, in the case when a lamp is turned on from a turn-off state in which the lamp temperature is low, since it takes some time until the amalgam has had a temperature rise to again release the adsorbed mercury, the resulting problem is that it takes not less than several minutes of rising-time to obtain sufficient brightness from the lamp after the turning-on.
Moreover, in the case of a method in which, in order to shorten the rising-time of brightness, without using amalgam, the bump portion is formed on the outer wall of the bulb with mercury droplets being enclosed in the bulb, although the effect for controlling the temperature of the coldest point to the vicinity of 40° C. is obtained, the glass strength of the bump portion tends to weaken to be easily broken. Furthermore, since the incandescent lamp has no bump portion of this type, it is not desirable from the aesthetic viewpoint, when this fluorescent lamp is used in place of an incandescent lamp.
The present invention has been devised to solve the above-mentioned problems, and its main objective is to provide a compact self-ballasted electrodeless discharge lamp which controls the temperature of the coldest point within a desired range by using a technique that is different from the conventional techniques, and an electrodeless-discharge-lamp lighting device.
According to one aspect of the present invention, a first compact self-ballasted electrodeless discharge lamp includes a bulb filled with discharge gas containing mercury and a rare gas; an excitation coil installed near the bulb; a ballast circuit which supplies high frequency power to the excitation coil; and a base that is electrically connected to the ballast circuit, and in this structure, the bulb, the excitation coil, the ballast circuit and the base are formed into an integral part; the bulb has a virtually spherical shape or a virtually ellipsoidal shape; a recessed portion to which the excitation coil is inserted is formed on the ballast circuit side of the bulb; the recessed portion has an opening section on the ballast circuit side, and has a tube shape with a virtually round shape in its cross section, with a portion positioned on the side opposite to the opening section of the recessed portion being provided with a function for suppressing the convection of the discharge gas; the largest diameter of the bulb is set in a range from not less than 60 mm to not more than 90 mm; the bulb wall loading of the bulb during a stable lighting operation is set in a range from not less than 0.07 W/cm2 to not more than 0.11 W/cm2; the ratio (h/D) of the height (h) of the bulb based upon the end face of the opening section in the recessed portion to the largest diameter (D) of the bulb is set in a range from not less than 1.0 to not more than 1.3; and, supposing that a distance between a top face of the recessed portion positioned on the side opposite to the opening section of the recessed portion and a top portion of the bulb facing the top face of the recessed portion is Δh, and that a diameter of a portion positioned on the side opposite to the opening section of the recessed portion is Dc, the following relationship is satisfied: Δh≦1.15×Dc+1.25 mm.
In one embodiment of the present invention, the above-mentioned diameter Dc and the above-mentioned distance Δh satisfy the following relationship: Δh≧1.16×Dc−7.4 mm.
The largest diameter of the bulb is preferably set in a range from not less than 65 mm to not more than 80 mm. Moreover, preferably, the bump portion is not formed on the top portion that forms the coldest point of the bulb or in the vicinity thereof.
In another embodiment, the excitation coil is constituted by a core and a coil wound around the core, and the center portion of the portion around which the coil is wound in the longitudinal direction of the core is positioned within a range that is apart from the plane on which the largest diameter of the bulb is located by a distance from not less than 8 mm to not more than 20 mm toward the ballast circuit side.
According to another aspect of the present invention, a second compact self-ballasted electrodeless discharge lamp includes a bulb filled with discharge gas containing mercury and a rare gas; an excitation coil installed near the bulb; a ballast circuit which supplies high frequency power to the excitation coil; and a base that is electrically connected to the ballast circuit, and in this structure, the bulb, the excitation coil, the ballast circuit and the base are formed into an integral part; the bulb has a virtually spherical shape or a virtually ellipsoidal shape; a recessed portion to which the excitation coil is inserted is formed on the ballast circuit side of the bulb; the recessed portion has an opening section on the ballast circuit side, and has a tube shape with a virtually round shape in its cross section, with a portion positioned on the side opposite to the opening section of the recessed portion being provided with a function for suppressing the convection of the discharge gas; the largest diameter of the bulb is set in a range from not less than 55 mm to not more than 75 mm; the bulb wall loading of the bulb during a stable lighting operation is set in a range from not less than 0.05 W/cm2 to less than 0.07 W/cm2; the ratio (h/D) of the height (h) of the bulb based upon the end face of the opening section in the recessed portion to the largest diameter (D) of the bulb is set in a range from not less than 1.0 to not more than 1.3; and, supposing that a distance between a top face of the recessed portion positioned on the side opposite to the opening section of the recessed portion and a top portion of the bulb facing the top face of the recessed portion is Δh, and that a diameter of a portion positioned on the side opposite to the opening section of the recessed portion is Dc, the following relationship is satisfied: Δh≦1.92×Dc−22.4 mm.
In one embodiment of the present invention, the above-mentioned diameter Dc and the above-mentioned distance Δh satisfy the following relationship: Δh≧1.16×Dc−17.4 mm.
The largest diameter of the bulb is preferably set in a range from not less than 60 mm to not more than 70 mm.
In another embodiment, the excitation coil is constituted by a core and a coil wound around the core, and the center portion of the portion around which the coil is wound in the longitudinal direction of the core is virtually positioned on a plane within which the largest diameter of the bulb is located.
In still another embodiment, the above-mentioned mercury is enclosed in the bulb not in the form of amalgam but in the form of mercury element.
In still another embodiment, the filling pressure of the rare gas is set in a range from not less than 60 Pa to not more than 300 Pa.
In the other embodiment, a phosphor layer is formed on an inner surface of the bulb.
A first electrodeless-discharge-lamp lighting device in accordance with the present invention includes a bulb that is filled with discharge gas containing mercury and a rare gas, and has a recessed portion; an excitation coil inserted in the recessed portion; and a ballast circuit which supplies high frequency power to the excitation coil, and in this structure, the bulb has a virtually spherical shape or a virtually ellipsoidal shape; the recessed portion has an opening section on the ballast circuit side, and has a tube shape with a virtually round shape in its cross section; the largest diameter of the bulb is set in a range from not less than 60 mm to not more than 90 mm; the bulb wall loading of the bulb during a stable lighting operation is set in a range from not less than 0.07 W/cm2 to not more than 0.11 W/cm2; the ratio (h/D) of the height (h) of the bulb based upon the end face of the opening section in the recessed portion to the largest diameter (D) of the bulb is set in a range from not less than 1.0 to not more than 1.3; and, supposing that a distance between a top face of the recessed portion positioned on the side opposite to the opening section of the recessed portion and a top portion of the bulb facing the top face of the recessed portion is Δh, and that a diameter of a portion positioned on the side opposite to the opening section of the recessed portion is Dc, the following relationship is satisfied: Δh≦1.15×Dc+1.25 mm.
According to the other aspect of the present invention, a second electrodeless-discharge-lamp lighting device includes a bulb that is filled with discharge gas containing mercury and a rare gas, and has a recessed portion; an excitation coil inserted in the recessed portion; and a ballast circuit which supplies high frequency power to the excitation coil, and in this structure, the bulb has a virtually spherical shape or a virtually ellipsoidal shape; the recessed portion has an opening section on the ballast circuit side, and has a virtually cylinder shape with a virtually round tube shape in its cross section; the largest diameter of the bulb is set in a range from not less than 55 mm to not more than 75 mm; the bulb wall loading of the bulb during a stable lighting operation is set in a range from not less than 0.05 W/cm2 to less than 0.07 W/cm2; the ratio (h/D) of the height (h) of the bulb based upon the end face of the opening section in the recessed portion to the largest diameter (D) of the bulb is set in a range from not less than 1.0 to not more than 1.3; and, supposing that a distance between a top face of the recessed portion positioned on the side opposite to the opening section of the recessed portion and a top portion of the bulb facing the top face of the recessed portion is Δh, and that a diameter of a portion positioned on the side opposite to the opening section of the recessed portion is Dc, the following relationship is satisfied: Δh≦1.92×Dc−22.4 mm.
In one embodiment, the diameter Dc of a portion positioned on the side opposite to the opening section of the recessed portion is greater than the diameter of a portion corresponding to virtually the center portion of the recessed portion in the longitudinal direction of the excitation coil.
The inventors of the present invention have repeated many experiments, and found an optimal range of dimensions of constituent elements inside a lamp, which can control the temperature of the coldest point to a desirable range, without using amalgam, without giving any adverse effects to the appearance of the lamp.
Referring to
An excitation coil (wire) 105, made of a copper stranded wire (litz wire) insulation-coated, is wound around a magnetic core (core) 106 made from Mn—Zn-based soft magnetic ferrite in the form of a solenoid inside the recessed portion 102. The two end lines 107 of the excitation coil 105 are connected to a high-frequency power-supply circuit (ballast circuit) 203 placed inside a housing 201 that is constituted by a resin member with an electric insulating property.
Commercial power-supply electric power, supplied through the base 202 that allows a direct power supply from a usual socket for the incandescent lamp, is converted to a high-frequency current having a frequency of about 400 kHz through the high-frequency power-supply circuit 203, and supplied to the excitation coil 105. By supplying this high-frequency current to the excitation coil 105, an induced electric field (not shown) is generated inside the bulb 101. Electrons in discharge gas are accelerated in this induced electric field and allowed to collide with atoms in a rare gas and mercury so that excitation and ionization are repeated to generate continuous discharging; thus, plasma is generated as shown in
Here, the frequency of the high-frequency power to be supplied to the excitation coil 105 by the high-frequency power-supply circuit 203 is set to about 400 kHz, which is a low frequency in comparison with 13.56 MHz or several MHz in the ISM band that is practically used in general. The reason for this is because, when operated in a comparatively high frequency range such as 13.56 MHz or several MHz, a large-size noise filter for suppressing line noise generated from the high-frequency power-supply circuit 203 is required to make the volume of the high-frequency power-supply circuit 203 larger. Moreover, in the case when noise, radiated or transmitted from a lamp, forms high-frequency noise, since high-frequency noise is strictly regulated by the act, an expensive shield needs to be used to adjust the noise to the regulation, resulting in a major problem with a cost reduction. In contrast, when operated in a low frequency range from 40 kHz to 1 MHz, inexpensive general products, which are used as electronic parts for general electronic apparatuses, can be used as parts to form the high-frequency power-supply circuit 203, and small-size parts can also be used; thus, great advantages, such as cost reduction and miniaturization, can be achieved. However, not limited to about 400 kHz, the present arrangement can be applied to another frequency area within the range from 40 kHz to 1 MHz and also to a comparatively high frequency area such as 13.56 MHz or several MHz.
In
Next, the following description will discuss how the coldest point temperature gives effects to the lamp efficiency in the electrodeless fluorescent lamp having of such an arrangement.
As clearly shown by
Upon taking the above-mentioned mechanism into consideration, it is important to clarify how heat is transferred inside the bulb 101, and conventionally, it has been considered that most of the heat transfer inside the bulb 101 is exerted through heat conduction, since the pressure inside the bulb 101 used in the present experiments is 80 Pa that is a small level. In other words, different from the high intensity discharge lamp typically represented by a high-pressure mercury lamp for use in the liquid crystal projector, low-pressure discharge plasma, such as that generated inside a fluorescent lamp, has a very low discharge-gas pressure, that is, a several hundredths of 1 atm; therefore, convection inside the bulb of a fluorescent lamp, which serves as a heat-scattering mechanism, has been conventionally ignored. Under these circumstances, the inventors of the present invention have directed their attention to the convection that has not been considered to contribute to heat transfer.
With respect to the convection inside the bulb 101 of the fluorescent lamp, first, discharge gas inside the bulb 101 is heated at its plasma portion, and is allowed to rise toward the housing 201 side. At an area of the bulb wall of the bulb 101 that contacts outside air, since the discharge gas is cooled due to heat transfer to the outside air, the discharge gas drops from the housing 201 side toward the top of the bulb 101. As a result, it is considered that, during a stable lighting operation, convections, indicated by arrows in
Here,
Here, the inventors of the present invention had an idea that it would become possible to control the temperature of the coldest point by preventing the convection from the plasma portion forming the highest temperature portion in the bulb 101 toward the coldest point by using any method.
By using a thermal hydraulic simulation technique so as to confirm the above-mentioned idea, the movements of discharge gas inside the bulb 101 during the stable lighting operation were calculated. As a result, as schematically indicated in the vicinity of the top of the recessed portion 102 of
With this idea, a number of prototype electrodeless fluorescent lamps having different lengths in the recessed portion 102, with the size of the bulb 101 being constant, were prepared, and experiments were repeatedly carried out to examine the correlation between the coldest point temperature and the gap Δh between the top of the recessed portion 102 and the top portion of the bulb 101.
The following description discusses the reason why two kinds of diameters in the recessed portion 102, that is, 21 mm and 25.4 mm, are used in the present experiments. The recessed portion 102 houses an excitation coil 105 and a magnetic core 106 inside thereof, and an exhaust pipe 104 is further placed inside thereof; and in the electrodeless fluorescent lamp of this type as shown in
When, based upon
Δh≦1.15×Dc+1.25 mm.
Here, since the temperature of the bulb 101 as a whole is generally determined by an input electric power per unit area of the bulb 101, that is, a bulb wall loading, the bulb wall loading becomes greater in an attempt to design an electrodeless fluorescent lamp so as to substitute the incandescent lamp, generally resulting in the above-mentioned problems. Here, since the above-mentioned relationship is prepared between Dc and Δh, it is not necessary to prepare a bump portion for use in cooling on the coldest point, that is, on the top portion of the bulb 101, or in the vicinity thereof; therefore, it is possible to avoid problems, such as a reduction in strength and degradation from the aesthetic viewpoint, caused by the installation of the bump portion.
As explained above, in an attempt to suppress the temperature of the coldest point, it is possible to obtain greater effects by making Δh smaller with an increased value of Dc. In the case when Δh is made further smaller with Dc being made further greater, in order to obtain greater effects, a new problem is raised in that an outline shadow of the recessed portion 102 is formed on the top portion of the bulb 101 and in the vicinity of the coldest point. This adverse effect is caused by the fact that, when viewed from the vicinity of the coldest point, the rate of ultraviolet discharged from the plasma portion being blocked by the top portion of the recessed portion 102 becomes greater as Δh becomes smaller, or as Dc becomes greater.
In order to also examine the relationship between Δh and Dc that can minimize this adverse effect, the inventors of the present invention prepared many electrodeless fluorescent lamps having different values in Δh and Dc, and measured the luminance of each of these lamps at the brightest portion of the side face of the bulb 101 as well as at the portion having the shadow in the vicinity of the coldest portion; thus, experiments were carried out so as to examine the relationship between the intensity of the shadow and Δh as well as Dc. Supposing that the luminance on the side face of the bulb 101 is Ss and that the luminance on the top portion of the bulb 101 to have the shadow is St, the contrast in brightness is defined by the following expression, and
C=(Ss−St)/(Ss+St)
In
Here, subjective evaluation tests were carried out to find out what degree of contrast would cause discomfort to the user, and the results showed that the value of contrast in a degree of 0.7 caused discomfort to two examinees out of eight.
The solid line of
Δh≧1.16×Dc−17.4 mm.
Based upon the above-mentioned relationships, the designing process is carried out so that Δh and Dc can satisfy the relationship within the area enclosed by the dotted line and the solid line of
Here, the importance of suppressing the influence of the outline shadow of the recessed portion 102 is also dependent on the state of use of the electrodeless fluorescent lamp at the time of the actual operation. For example, in the case when the lamp is used inside a device provided with a diffusion plate at the opening section, or in the case when the lamp is placed at a position below the human line of sight, the influence of the outline shadow is not so important. For this reason, the conditions for minimizing the influence of the outline shadow of the recessed portion 102 are not necessarily essential.
Here, in the case of conventionally known electrodeless fluorescent lamps such as those disclosed in U.S. Pat. No. 5,291,091 shown in FIG. 12 and U.S. Pat. No. 5,825,130 shown in FIG. 13, the shapes of these fail to satisfy the above-mentioned two expressions.
Next, the inventors of the present invention directed their attention to the generation position of plasma so as to improve the light-emitting efficiency. In other words, when the center portion for the plasma generation is too close to the housing 201, ambipolar diffusion becomes stronger on the bulb wall of the bulb 101 to cause an increase in electric power to be consumed so as to maintain plasma, resulting in a reduction in the efficiency. In contrast, when the center portion for the plasma generation is too close to the coldest point, the effect for suppressing the convection of the recessed portion 102 is cancelled to cause an increase in the coldest point temperature, resulting in a reduction in the efficiency. The center portion for the plasma generation is considered to virtually correspond to the center portion in the longitudinal direction of a portion of the magnetic core 106 on which the excitation coil 105 is wound around; thus, it is estimated that, when this portion is made coincident with the portion forming the maximum diameter of the bulb 101, the loss due to bipolar diffusion on the bulb wall is minimized.
In this case, in
The above-mentioned simulation relates to the gas flow, and in a separate manner from this, in order to find out a plasma generation position having the best light-emitting efficiency in accordance with the above-mentioned assumption, experiments were carried out, with the winding position of the excitation coil 105 to the magnetic core 106 being changed in various manners. As a result, the relationship shown in
The electrodeless fluorescent lamp that has been explained above is a so-called high-watt type lamp corresponding to an incandescent lamp of 100 W; however, with respect to an electrodeless fluorescent lamp that is a so-called low-watt type lamp corresponding to an incandescent lamp of 60 W, since the lamp of this type has a size and a bulb wall loading that are different from those of the high-watt type lamp, the relationship between Dc and Δh was examined in a separate manner. The following description will discuss the electrodeless fluorescent lamp of the low-watt type.
The electrodeless fluorescent lamp of the low-watt type has virtually the same shape as that of the high-watt type, as shown in
In the same manner as the lamp of the high-watt type, experiments were also carried out on those of the low-watt type so as to examine the cold point temperature and the influence of the outline shadow of the recessed portion 102 at the top portion of the bulb 101, as well as the relationship between Δh and Dc. The resulting desirable range of Δh and Dc corresponds to an area sandwiched by two straight lines in
Δh≦1.92×Dc−22.4 mm,
and
Δh≧1.16×Dc−17.4 mm.
Moreover, experiments were carried out, with the winding position of the excitation coil 105 onto the magnetic core 106 being changed in various manners; thus, the relationship shown in
ΔC=0 mm.
The following description will discuss structures of an electrodeless fluorescent lamp corresponding to an incandescent lamp of 100 W in power consumption and an electrodeless fluorescent lamp corresponding to an incandescent lamp of 60 W in power consumption in detail. However, the present invention is not limited to these structures.
<Electrodeless Fluorescent Lamp Corresponding to an Incandescent Lamp for Use in 100 W>
In
In this example, the largest diameter (D) of the bulb 101 is 70 mm, the height (h) of the bulb 101 measured from the opening end 103 of the recessed portion 102 is 80 mm, the diameter Dc of the recessed portion 102 is 23 mm, and Δh is 15 mm; thus, this structure is located in the area between the two straight lines, shown in
Δh≦1.15×Dc+1.25 mm,
and
Δh 1.16×Dc−17.4 mm.
Consequently, it becomes possible to suppress the coldest point temperature to not more than 46° C., while reducing the influence of the outline shadow of the recessed portion 102 to a minimum. Here, since the recessed portion 102 has a virtually cylinder shape, virtually the same diameter is obtained at any portion in the recessed direction, and the diameter of the portion positioned on the side opposite to the opening section of the recessed portion 102 is also 23 mm. Moreover, the distance AC from the center portion in the longitudinal direction of the winding face of the excitation coil 105 of the magnetic core 106 to the largest diameter portion of the bulb 101 is set in a range from −14 mm ±2 mm, more preferably, from −14 mm ±1 mm; thus, it becomes possible to increase the light-emitting efficiency, with the coldest point temperature and the resistance of plasma being controlled in a well-balanced manner.
In this example, while the shape and size that are similar to the incandescent lamp corresponding to 100 W are maintained, the diameter Dc of the recessed portion 102 and the distance Δh between a top face of the recessed portion 102 and a top portion of the bulb 101 opposing thereto are allowed to have a fixed relationship; thus, the coldest point temperature of the electrodeless fluorescent lamp can be controlled so that it becomes possible to improve the light-emitting efficiency without using amalgam. Moreover, since the center portion in the longitudinal direction of the winding face of the excitation coil 105 is placed within a constant distance range from the largest diameter portion of the bulb 101, it becomes possible to improve the light-emitting efficiency. In other words, in the compact self-ballasted electrodeless discharge lamp to be used for substituting an incandescent lamp, in accordance with the embodiment of the present invention, by providing a fixed relationship between the diameter of the recessed portion and the distance between the top of the recessed portion and the top portion of the bulb, it becomes possible to control the temperature of the coldest point, while maintaining the appearance and the size that are similar to the incandescent lamp. With this arrangement, it is possible to eliminate the necessity of using amalgam and to provide a compact self-ballasted electrodeless discharge lamp that can improve both the rising-time up to sufficient brightness and the lamp efficiency.
<Electrodeless Fluorescent Lamp Corresponding to an Incandescent Lamp for Use in 60 W>
In the present embodiment, the diameter Dc of the recessed portion 102 is 21 mm, and Δh is 12 mm; thus, this structure is located in the area between the two straight lines, shown in
Δh≦1.92×Dc−22.4 mm,
and
Δh≧1.16×Dc−17.4 mm.
Consequently, it becomes possible to suppress the coldest point temperature to not more than 45° C., while reducing the influence of the outline shadow of the recessed portion 102 to a minimum. Moreover, the distance ΔC from the center portion in the longitudinal direction of the winding face of the excitation coil 105 of the magnetic core 106 to the largest diameter portion of the bulb 101 is set in a range from 0 mm±2 mm, more preferably, from 0 mm±1 mm. In other words, since the bulb wall loading is smaller in comparison with the lamp for use in 100 W, it becomes possible to desirably control the coldest point temperature at a position of ΔC=0 mm where the resistance of plasma is minimized, and consequently to increase the light-emitting efficiency.
In the present embodiment, while the shape and size that are similar to the incandescent bulb corresponding to 60 W are maintained, the diameter Dc of the recessed portion 102 and the distance Δh between a top face of the recessed portion 102 and a top portion of the bulb 101 opposing thereto are allowed to have a fixed relationship; thus, the coldest point temperature of the electrodeless fluorescent lamp can be controlled so that it becomes possible to improve the light-emitting efficiency without using amalgam. Moreover, since the center portion in the longitudinal direction of the winding face of the excitation coil 105 is made virtually coincident with the largest diameter portion of the bulb 101, it becomes possible to improve the light-emitting efficiency. In other words, in the compact self-ballasted electrodeless discharge lamp to be used for substituting an incandescent bulb of 60 W in accordance with the embodiment of the present invention, by providing a fixed relationship between the diameter of the recessed portion and the distance between the top of the recessed portion and the top portion of the bulb, it becomes possible to control the temperature of the coldest point, while maintaining the appearance and the size that are similar to the incandescent bulb. With this arrangement, it is possible to eliminate the necessity of using amalgam and to provide a compact self-ballasted electrodeless discharge lamp that can improve both the rising-time up to sufficient brightness and the lamp efficiency.
<Modified Mode>
The aforementioned embodiments have discussed a case in which the inner face of the bulb 101 is coated with a phosphor film (not shown); however, in the case of an electrodeless lamp also in which, without using the phosphor film, ultraviolet from mercury is directly utilized by forming the bulb 101 by the use of a material that transmits ultraviolet, for example, fused quartz having appropriate purity and magnesium fluoride, it becomes possible to optimize the strength of ultraviolet by controlling the coldest point temperature.
The aforementioned embodiments have discussed a case in which the lamp main body and the high-frequency power-supply circuit 203 are formed into an integral part; however, those embodiments may also be applied to a structure in which the high-frequency power-supply circuit 203 is installed as a separate part from the lamp main body.
Moreover, a visible-light reflection film or phosphor film, made of alumina or the like, or both of these films, may be formed on the top portion of the recessed portion 102 so as to reduce the influence from the outline shadow of the recessed portion 102 to the top portion of the bulb 101.
In
Furthermore, the aforementioned embodiments have discussed a structure in which the excitation coil 105 is inserted into the recessed portion 102; however, even in a structure in which the excitation coil 105 is wound around the outside of the bulb 101, with a higher driving frequency, for example, 13.56 MHz, being used, the influence of the recessed portion 102 to the coldest point temperature is the same, and the same effects can be achieved. Here, in a structure in which the excitation coil 105 is inserted to the recessed portion 102 also, when a high driving frequency, for example, 13.56 MHz, is used, the magnetic core 106 is not necessarily required. Moreover, in order to suppress the high-frequency magnetic field generated in the excitation coil 105 from causing an eddy current loss inside the radiating member 109 made of metal, a round plate, which is made of a magnetic material having low electric conductivity, preferably, Mn—Zn-based or Ni—Zn based soft magnetic ferrite, may be placed between the radiating member 109 and the uppermost portion of the bulb 101 shown in the figure.
As described above, in accordance with the present invention, it is possible to provide a compact self-ballasted electrodeless discharge lamp in which the temperature of a coldest point is maintained within an appropriate range by using a technique that is different from conventional techniques, and an electrodeless-discharge-lamp lighting device for use in such a lamp.
The present invention is effectively used for improving the light-emitting efficiency of an electrodeless-discharge-lamp lighting device, and in particular, is suitably applied to a compact self-ballistic electrodeless discharge lamp.
Number | Date | Country | Kind |
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2002-192881 | Jul 2002 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP03/08447 | 7/2/2003 | WO | 00 | 10/11/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/006289 | 1/15/2004 | WO | A |
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