JP2010232024A - Luminous tube for fluorescent lamp, and method of manufacturing the same and fluorescent lamp with built-in stabilizer using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an luminous tube for a fluorescent lamp having a coldest point at the end, improved productivity, and a spiral portion, and to provide a method of manufacturing the same and the fluorescent lamp with a built-in stabilizer using the same. <P>SOLUTION: The luminous tube for the fluorescent lamp includes a glass bulb 6 having the spiral portion 2 and a straight portion 3 at least at one end, a pair of filaments 5a, 5b arranged in the glass bulb 6, and a mercury amalgam 4 for releasing mercury vapor into the glass bulb 6, at least the filament 5a out of the pair of filaments being arranged in the straight portion 3 at a position where a height from the end of the straight porion 3 is 20 mm or greater. The method of manufacturing the same and the fluorescent lamp with the built-in stabilizer using the same are provided. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a fluorescent lamp arc tube, a method for manufacturing the same, and a ballast built-in fluorescent lamp using the same.

An arc tube for a fluorescent lamp is configured such that a filament is attached to both ends of a glass bulb having an inner surface coated with a fluorescent layer, and a discharge gas containing mercury vapor is enclosed inside the glass bulb.
Fluorescent lamps are used as a light source for various types of lighting fixtures because they can achieve equivalent or higher illuminance with less power consumption than incandescent lamps.
However, fluorescent lamps have the disadvantage that the rise in brightness immediately after lighting is slower than incandescent bulbs. This is because the temperature of the arc tube is low immediately after lighting and the mercury vapor pressure in the arc tube is low.

In order to accelerate the rise of brightness immediately after lighting, a method using a mercury amalgam that releases mercury vapor at a relatively low temperature is known.
However, when mercury amalgam is used, there is a problem that the illuminance during stable lighting is lowered. This is because the mercury vapor pressure in the arc tube becomes higher than the optimum range when the temperature of the arc tube is increased by discharge.

This problem is particularly remarkable in a fluorescent lamp arc tube having a spiral portion, which is often used for a fluorescent lamp with a built-in ballast.
An arc tube for a fluorescent lamp having a spiral portion has a smaller heat radiation area per length of the arc tube than a straight tube type or an annular type arc tube, and the generated heat is likely to be trapped inside. As a result, the difference between the temperature immediately after lighting and the temperature during stable lighting becomes larger than that of a straight tube type or an annular arc tube, and it is more difficult to keep the mercury vapor pressure in the optimum range.

  In order to avoid a decrease in illuminance during stable lighting, it is effective to lower the temperature at the lowest temperature in the arc tube, that is, the so-called coldest point. By lowering the coldest spot temperature, excess mercury vapor released into the arc tube is condensed at the coldest spot, and the mercury vapor pressure is maintained within an appropriate range.

  Theoretically, the coldest spot may exist in any part of the arc tube. However, heat is generated in the filament and the discharge path formed between the filaments during light emission. For this reason, it is easier to lower the cold spot temperature if the cold spot is provided at a position away from the filament or the discharge path.

Patent Document 1 discloses a configuration in which a protruding portion communicating with an arc tube is provided at an end portion of the arc tube having a spiral portion.
In this configuration, the protrusion functions as the coldest point.

Patent Document 2 discloses a configuration in which one end portion of the arc tube has the coldest spot in an annular fluorescent lamp.
In this configuration, of the pair of filaments disposed at both ends of the arc tube, the filament disposed at one end is longer than the filament disposed at the other end. For this reason, one end part is less affected by heat generated in the filament and the discharge path than the other end part, and functions as the coldest point.

JP 2005-347236 A JP 2002-329481 A

However, the configuration disclosed in Patent Document 1 has a problem that it is difficult to mold the arc tube because the structure of the protruding portion is complicated.
Furthermore, in the assembly process of the fluorescent lamp with a built-in ballast, the protruding portion is easily damaged, and there is a problem in terms of productivity.

On the other hand, the configuration disclosed in Patent Document 2 is intended for an annular arc tube.
When a filament is inserted into a glass bulb having a spiral portion, the direction and angle of the glass bulb and the filament must be precisely adjusted, and production is difficult.
In addition, if the insertion direction or angle is wrong, the fluorescent layer attached to the glass bulb may come into contact with the filament, and the fluorescent layer may be damaged or the filament may be damaged.

  The present invention has been made in view of the above problems, and has an arc tube for a fluorescent lamp having a spiral portion, having a coldest point at the end and excellent in productivity, a method for manufacturing the same, and a method for manufacturing the same. It is an object of the present invention to provide a fluorescent lamp with a built-in ballast.

  An arc tube for a fluorescent lamp according to the present invention includes a glass bulb having a spiral portion and a linear portion at least at one end, a pair of filaments disposed in the glass bulb, and the glass bulb. An arc tube for a fluorescent lamp comprising a mercury amalgam that emits mercury vapor, wherein at least one of the pair of filaments is the straight portion and has a height from an end of the straight portion of 20 mm or more. It is arranged at a position.

  The fluorescent lamp arc tube manufacturing method according to the present invention is characterized in that after the filament is inserted from the end of the straight portion in a direction substantially parallel to the straight portion, the end of the straight portion is sealed. .

  A fluorescent lamp with a built-in ballast according to the present invention includes an arc tube for a fluorescent lamp according to the present invention, an electronic ballast that is electrically connected between a power source and a filament, and applies a voltage to the filament, and the electronic stability And a cover containing the vessel.

ADVANTAGE OF THE INVENTION According to this invention, although using the mercury amalgam which is excellent in productivity and discharge | releases mercury vapor | steam at comparatively low temperature, the arc tube for fluorescent lamps which can prevent the fall of the illumination intensity at the time of stable lighting can be provided.
According to the present invention, the fluorescent lamp arc tube according to the present invention can be obtained with high productivity.

It is a front view of the arc tube for fluorescent lamps according to Embodiment 1 of the present invention. FIG. 2 is a top view of the fluorescent lamp arc tube shown in FIG. 1. It is an internal block diagram of the arc tube for fluorescent lamps shown in FIG.1 and FIG.2. It is a front view of the arc tube for fluorescent lamps according to another embodiment of the present invention. FIG. 5 is a top view of the fluorescent lamp arc tube shown in FIG. 4. It is a front view of the arc tube for fluorescent lamps according to the second other embodiment of the present invention. It is a right view of the arc tube for fluorescent lamps shown in FIG. It is a front view of the arc tube for fluorescent lamps according to a third other embodiment of the present invention. It is a schematic diagram which shows the manufacturing method of the arc tube for fluorescent lamps concerning Embodiment 2 of this invention. (A) is a state before inserting the filament, (b) is a process of inserting the filament, (c) is a state where the insertion of the filament is completed, and (d) is a state of the straight portion of the glass bulb. The end is sealed. It is an internal block diagram of the fluorescent lamp with a built-in ballast concerning Embodiment 3 of the present invention. It is an internal block diagram of the fluorescent lamp with a built-in ballast which concerns on Embodiment 4 of this invention. It is the figure which notched and showed a part of fluorescent lamp with a built-in ballast shown in FIG.

  Hereinafter, a fluorescent tube for a fluorescent lamp according to an embodiment of the present invention, a manufacturing method thereof, and a fluorescent lamp with a ballast using the same will be described with reference to the drawings.

(Embodiment 1)
First, a fluorescent lamp arc tube 1 according to Embodiment 1 of the present invention will be described with reference to FIGS.
FIG. 1 is a front view of a fluorescent lamp arc tube 1 according to Embodiment 1 of the present invention. FIG. 2 is a top view of the fluorescent lamp arc tube 1. FIG. 3 is an internal configuration diagram of the fluorescent lamp arc tube 1.

  As shown in FIG. 3, the fluorescent lamp arc tube 1 is configured by enclosing filaments 5 a and 5 b and a mercury amalgam 4 in a glass bulb 6.

  As shown in FIGS. 1 and 2, the glass bulb 6 is formed by bending a single cylindrical glass tube. One end portion of the glass tube is a straight portion 3 having a length L, and the remaining portion is wound so as to form a spiral with the straight portion 3 as a central axis and toward the end portion of the straight portion 3. It is formed. The straight line portion 3 is disposed along the spiral rotation axis of the spiral portion 2 and substantially orthogonal to the spiral rotation surface of the spiral portion 2.

A fluorescent layer is deposited on the inner surface of the glass bulb 6.
Further, a discharge gas containing a rare gas and mercury vapor is sealed inside the glass bulb 6.

As shown in FIG. 3, the filament 5 a is disposed at the end of the straight portion 3 of the glass bulb 6. The filament 5 b is disposed at the end of the spiral portion 2 of the glass bulb 6.
The filaments 5a and 5b are made of tungsten.
The mercury amalgam 4 is disposed at the end of the straight portion 3.

The filament 5a is supported at both ends by a support member 7a made of two metal wires. The filament 5b is similarly supported by the support member 7b.
The support members 7a and 7b have a role of supporting the filaments 5a and 5b and defining their arrangement positions and heights from the ends, and a role of electrically connecting the filaments 5a and 5b and the power source.

The support member 7 a passes through the glass stem 8 and is fixed to the stem 8. The length of the stem 8 is 25 mm.
The stem 8 insulates the supporting member 7a made of two metal wires to prevent a short circuit. Further, the support member 7a is reinforced to prevent the filament 5a from coming into contact with the fluorescent layer.
Note that the stem 8 does not block all the space from the filament 5a to the end of the straight portion 3. Mercury vapor can freely move between the mercury amalgam 4 and other parts in the glass bulb 6.

The front end of the support member 7 a is located at a height of 30 mm from the end of the linear portion 3. The height Ha of the filament 5a supported by the support member 7a from the end of the linear portion 3 is 30 mm.
The front end of the support member 7 b is located at a height of 15 mm from the end of the spiral portion 2. The height of the filament 5b supported by the support member 7b from the end of the spiral portion 2 is 15 mm.

  The filaments 5a and 5b are coated with an emitter that emits electrons when heated.

  When a voltage is applied from the power source to the filaments 5a and 5b through the support members 7a and 7b, the filaments 5a and 5b generate heat. As a result, electrons are emitted from the emitters applied to the filaments 5a and 5b, and a discharge path is formed between the filaments 5a and 5b.

Electrons collide with mercury atoms contained in the discharge gas while moving along the discharge path. Mercury atoms collided with electrons emit ultraviolet rays.
Ultraviolet light hits the fluorescent layer deposited on the inner surface of the glass bulb 6 and generates visible light in the fluorescent layer. As a result, the fluorescent lamp arc tube 1 functions as a lighting device.

When a discharge occurs in the fluorescent lamp arc tube 1, heat is generated.
However, since the end portion of the straight line portion 3 is located outside the discharge path and is separated from the filament 5a by 30 mm, it is not easily affected by heat generated in the filament 5a and the discharge path. As a result, the end of the straight line portion 3 functions as the coldest point.

  Excess mercury vapor present in the fluorescent lamp arc tube 1 is condensed at the coldest spot or absorbed by the mercury amalgam 4 arranged at the coldest spot. As a result, the mercury vapor pressure in the fluorescent lamp arc tube 1 at the time of stable lighting is kept in the optimum range, and a decrease in illuminance can be prevented.

  Since the fluorescent lamp arc tube 1 has the spiral portion 2, a longer arc tube can be accommodated in a limited volume, and high illuminance can be obtained even in a small size.

  Since the filament 5a is disposed in the linear portion 3, the support member 7a is bent before the filament 5a is inserted into the glass bulb 6, and the orientation and angle of the support member 7a or the glass bulb 6 are precisely set when inserting the filament 5a. There is no need to make adjustments. Further, there is little risk of damaging the fluorescent layer deposited on the inner surface of the glass bulb 6 during insertion. For this reason, the arc tube 1 for fluorescent lamps is excellent in productivity.

  The fluorescent lamp arc tube according to the present invention has been described with reference to the first embodiment, but the scope of the present invention is not limited to the first embodiment.

  The glass bulb 6 is formed by bending a single cylindrical glass tube. However, the glass bulb 6 may be formed by joining a spiral glass tube and a linear glass tube.

  The glass bulb 6 has the straight part 3 at one end and the spiral part 2 at the other end, but may have a straight part at the other end. However, the configuration having the spiral portion 2 at the other end is more preferable because a longer arc tube can be accommodated in a limited volume and the illuminance can be increased.

As the ratio of the length of the spiral portion 2 to the entire length of the glass bulb 6 increases, the arc tube can be lengthened within a limited volume, and the illuminance becomes higher.
The proportion is preferably 50% or more, more preferably 70% or more, and particularly preferably 80% or more.

  The straight line portion 3 of the glass bulb 6 is arranged along the spiral rotation axis of the spiral portion 2 and substantially orthogonal to the spiral rotation surface of the spiral portion 2, but is not limited thereto.

For example, as shown in FIGS. 4 and 5, when the straight line portion 3 is arranged so as to be substantially orthogonal to the rotation surface of the spiral of the spiral portion 2, one point on the circumference of the circle drawn by the spiral of the spiral portion 2 And the straight line part 3 may be arrange | positioned so that it may pass along the point which bisects the line | wire which connects the center of this circle | round | yen.
Alternatively, when the straight portion 3 is arranged so as to be substantially orthogonal to the spiral surface of the spiral of the spiral portion 2, the straight portion 3 may be arranged so as to pass outside the circle drawn by the spiral of the spiral portion 2. Good.

Furthermore, the straight line portion 3 may be disposed substantially parallel to the spiral rotation surface of the spiral portion 2.
At this time, for example, as shown in FIGS. 6 and 7, the straight portion 3 may be arranged in parallel with a line orthogonal to the rotational axis of the spiral of the spiral portion 2.
Alternatively, as shown in FIG. 8, the end portion of the straight line portion 3 may be disposed so as to be close to the end portion of the spiral portion 2.
However, the linear part 3 of the glass bulb 6 is arranged along the rotational axis of the spiral of the spiral part 2 and so as to be substantially orthogonal to the rotational surface of the spiral of the spiral part 2. It can be made smaller and more preferable.

The mercury amalgam 4 is disposed at the end of the straight line portion 3 that is the coldest point, but is not limited thereto.
You may arrange | position to the edge part of the spiral part 2, and you may throw in into the inside of the fluorescent tube 1 for fluorescent lamps, without limiting a position.
In addition, if necessary, pure mercury or auxiliary amalgam for optimizing the mercury vapor pressure immediately after lighting or at the time of stable lighting can be arranged or introduced in the fluorescent lamp arc tube 1.

  Tungsten is used as the material of the filaments 5a and 5b, but is not particularly limited as long as it has desired heat resistance and electrical conductivity.

Although the height Ha of the filament 5a is 30 mm, the height Ha of the filament 5a may be 20 mm or more.
The height Ha of the filament 5a is preferably 30 mm or more, particularly preferably more than 50 mm.
If the height Ha of the filament 5a is less than 20 mm, the heat generated from the filament 5a cannot be sufficiently prevented from being transmitted to the end of the straight portion 3, and the coldest spot is hardly formed at the end of the straight portion 3. In this case, it is difficult to prevent a decrease in illuminance during stable lighting.

  The higher the height Ha of the filament 5a, the lower the temperature of the end portion of the straight portion 3 that is the coldest point. For this reason, the height Ha of the filament 5a is preferably 70% or less of the length of the straight portion L, and more preferably 50% or less.

  The filament 5b is arranged at the end of the spiral portion 2, but the arrangement position is not limited.

Although the height of the filament 5b from the end of the spiral portion 2 is 15 mm, it is not limited to this.
The height of the filament 5b is usually 5 to 30 mm, preferably 8 to 25 mm, and more preferably 10 to 20 mm. If it exceeds 30 mm, the fluorescent layer may be damaged during insertion, or the filament 5b or the support member 7b may be damaged.

  After the stem 8 is inserted, the end of the straight portion 3 is sealed by heating the end of the straight portion 3 and applying a force from the outside. However, after the stem 8 is inserted, the end is sealed with sealing glass. May be.

  Glass is used as the material of the stem 8, but it is not particularly limited as long as it has insulating properties and heat resistance. Further, the shape of the stem is not limited to the flare type stem like the stem 8. For example, a flat disk-shaped stem can be used.

Although the length of the stem 8 is 25 mm, the length is not limited as long as it is less than the height Ha of the filament 5a.
However, since the filament 5a becomes unstable as the support member 7a becomes longer, the stem 8 preferably has a length of 1/2 or more with respect to the height Ha of the filament 5a.
It is more preferably 2/3 or more with respect to the height Ha of the filament 5a, and particularly preferably 3/4 or more.

(Embodiment 2)
Next, a method for manufacturing a fluorescent lamp arc tube according to Embodiment 2 of the present invention will be described with reference to FIG.
As described above, the glass bulb 6 has the spiral portion 2 and has the straight portion 3 having a length L at one end (in FIG. 9, the spiral portion 2 is omitted for easy understanding). is doing). A fluorescent layer is deposited on the inner surface of the glass bulb 6.

  An emitter is applied to the filament 5a, and both ends thereof are supported by the support member 7a. Although not shown in FIG. 9 for easy understanding, the support member 7a is fixed to a stem 8 (not shown). A mercury amalgam 4 (not shown) is arranged on the stem 8.

  As a stage before inserting the filament 5a, first, as shown in FIG. 9A, the longitudinal axis of the support member 7a (indicated by a one-dot chain line in FIG. 9) and the longitudinal direction of the linear portion 3 The axes are arranged so as to be aligned on substantially the same straight line.

  Next, as shown in FIG. 9B, the filament 5 a is inserted in a direction substantially parallel to the linear portion 3 toward the opening at the end of the linear portion 3. The axis of the longitudinal direction of the support member 7a and the axis of the longitudinal direction of the linear portion 3 are always between at least after the filament 5a is inserted into the opening at the end of the linear portion 3 and reaches a predetermined position. Insert it so that it is almost collinear.

As shown in FIG. 9C, when the filament 5a reaches a predetermined position, the insertion is stopped. The relative position of the filament 5a and the glass bulb 6 is fixed. At this time, the stem 8 (not shown) is fitted inside the opening at the end of the straight portion 3.
Subsequently, an external force is applied while heating the end portion of the straight portion 3 to seal the end portion of the straight portion 3 and fix the support member 7a. A sealing portion 12 is formed at the end of the straight portion 3.
Since the filament 5a is fixed to the support member 7a, when the support member 7a is fixed, the height Ha of the filament 5a is determined as shown in FIG. 9 (d).
Subsequently, a filament 5b that forms a pair with the filament 5a is disposed in the glass bulb 6, and a discharge gas is sealed inside through an exhaust pipe (not shown in FIG. 9) provided in communication with the glass bulb 6. Thus, an arc tube for a fluorescent lamp is obtained.

  In this method, the filament 5 a fixed to the support member 7 a is inserted in a direction substantially parallel to the straight portion 3. Since the insertion direction and angle are not changed during the insertion process, the process is simple. Furthermore, there is little possibility that the filament 5a and the support member 7a will contact the fluorescent layer deposited on the inner surface of the glass bulb 6. For this reason, damage to the fluorescent layer and breakage of the filament 5a are unlikely to occur.

  As mentioned above, although the manufacturing method of the arc tube for fluorescent lamps concerning this invention was demonstrated, showing Embodiment 2, this invention is not limited to the said embodiment.

  In the second embodiment, the filament 5 a is moved toward the glass bulb 6 and inserted. However, the glass bulb 6 may be inserted close to the fixed filament 5 a and the support member 7.

The end portion of the straight portion 3 is sealed by fitting the stem 8 to the opening portion of the end portion of the straight portion 3 and applying a force from the outside while heating the end portion, but is not limited to this method. For example, after fitting the stem 8, the gap between the stem 8 and the opening may be sealed with sealing glass or the like. Further, without using the stem 8, the opening at the end of the straight portion 3 may be heated and sealed by applying a force from the outside.
The use of a stem is preferable because the shape of the end after sealing can be easily made uniform, and the height Ha of the filament 5a can be controlled more accurately.

  In Embodiment 2, after the filament 5a is disposed, the filament 5b is disposed, but the order is not particularly limited.

A filament 5b that is paired with the filament 5a (not shown in FIG. 9) has a support member 7b fixed in advance to a stem that fits the opening at the end of the spiral portion 2, and the stem is fitted into the opening. The ends are heated and sealed by applying a force from the outside, but the present invention is not limited to this method.
After fitting the stem, the gap between the stem and the fitting portion may be sealed with sealing glass or the like.
Or you may seal by applying a pressure from the outside, heating the edge part of the spiral part 2. FIG.
The use of a stem is preferable because the shape of the end portion after sealing is easily uniformed and the arrangement position of the filament 5b after sealing can be more accurately controlled.

In the second embodiment, an exhaust pipe communicating with the glass bulb 6 is provided, and the discharge gas is sealed inside by replacing the internal gas through the exhaust pipe. However, the sealing method is not particularly limited.
For example, the glass bulb 6 may be disposed in a chamber replaced with a discharge gas, and both ends may be sealed in the chamber.

The mercury amalgam 4 is inserted into the glass bulb 6 in a state where the mercury amalgam 4 is disposed on the stem 8, but the method for arranging or enclosing the mercury amalgam 4 is not particularly limited. Mercury amalgam 4 may be charged directly into the glass bulb 6.
The method of arranging the mercury amalgam 4 on the stem 8 is more preferable because the mercury amalgam 4 can be reliably arranged at the coldest point.

The fluorescent lamp arc tube and the manufacturing method thereof according to the present invention have been described with reference to the embodiments.
Since the fluorescent lamp arc tube according to the present invention has a spiral portion, a long arc tube can be accommodated in a limited volume, and high illuminance can be obtained even in a small size. For this reason, it can be suitably used for a small fluorescent lamp with a built-in ballast.

(Embodiment 3)
Next, a ballast-equipped fluorescent lamp 11a according to Embodiment 3 of the present invention will be described with reference to FIG.
The fluorescent lamp 11a with a built-in ballast includes the fluorescent tube arc tube 1 according to Embodiment 1 of the present invention, and further includes an electronic ballast 9 and a resin cover 10 with the electronic ballast 9 built therein. The fluorescent lamp arc tube 1 is fixed to a cover 10.

  The fluorescent lamp arc tube 1 is the same as the fluorescent lamp arc tube 1 according to the first embodiment of the present invention.

  The electronic ballast 9 is connected between a power source and filaments 5a and 5b (not shown) disposed inside the fluorescent lamp arc tube 1, and serves to apply a voltage to the filaments 5a and 5b. And the role of controlling the lamp current to an appropriate value.

The cover 10 serves to insulate the electric circuit portion (including the electronic ballast 9) of the fluorescent lamp 11a with a built-in ballast from the outside.
Further, the fluorescent lamp arc tube 1 and the electronic ballast 9 are physically shielded to protect the electronic ballast 9 from heat generated from the fluorescent lamp arc tube 1 during discharge.
Furthermore, the cover 10 also has a role of physically protecting the electronic ballast 9 and the connection between the electronic ballast 9 and the fluorescent lamp arc tube 1.

When the ballast built-in fluorescent lamp 11a is turned on, the electronic ballast 9 first applies a preheating voltage to the filaments 5a and 5b. The filaments 5a and 5b to which the preheating voltage is applied generate heat and heat the emitter applied to the surface.
Next, the electronic ballast 9 applies a starting voltage to the filament. Then, discharge starts in the fluorescent lamp arc tube 1.
When the discharge starts, the electronic ballast 9 controls the lamp current so that the fluorescent lamp arc tube 1 maintains stable illuminance and high luminous efficiency.

When the electronic ballast 9 applies the preheating voltage and the starting voltage to the filament, the fluorescent lamp arc tube 1 can be turned on more quickly. For this reason, the ballast-equipped fluorescent lamp 11a is excellent in the rise in brightness immediately after lighting.
During stable lighting, since the electronic ballast 9 controls the lamp current to an appropriate value, the ballast-equipped fluorescent lamp 11a can maintain stable illuminance and high luminous efficiency.

Furthermore, since the electronic ballast 9 is protected by the cover 10, the electronic ballast 9 that applies a high voltage can be used more safely.
Moreover, since the cover 10 suppresses the heat generated from the fluorescent lamp arc tube 1 from being transmitted to the electronic ballast 9, the electronic ballast 9 can be operated more stably.

  Although the ballast built-in fluorescent lamp according to the present invention has been described with reference to the third embodiment, the scope of the present invention is not limited to the third embodiment.

  The fluorescent lamp arc tube 1 is arranged such that the straight portion is along the rotational axis of the spiral of the spiral portion and substantially orthogonal to the rotational surface of the spiral of the spiral portion, but the shape is not limited to this. Any fluorescent tube for a fluorescent lamp according to the present invention can be suitably used.

  Although an inverter type is used as the electronic ballast 9, any known electronic ballast such as a glow type or a rapid type can be used.

  The cover 10 is made of resin. Usually, polybutylene terephthalate (PBT) excellent in heat resistance and insulation is used, but it is not limited as long as it has desired heat resistance, insulation, and mechanical strength.

In the third embodiment, the cover 10 is provided with a base that is screwed into the incandescent bulb socket at a position facing the fluorescent lamp arc tube 1 with the cover 10 interposed therebetween.
The fluorescent lamp with a built-in ballast including the electronic ballast 9 and the base is particularly preferable because it can be used by being attached to a conventional lighting device for incandescent bulbs.

Furthermore, a translucent globe can be added to the ballast-equipped fluorescent lamp according to the present invention.
The globe is fixed by a cover and covers the fluorescent lamp arc tube.
As a material for the globe, glass having excellent translucency and heat resistance is usually used, but a resin may be used as long as these conditions are satisfied, and is not particularly limited.

The ballast built-in fluorescent lamp according to the present invention has been described with reference to the second embodiment.
It goes without saying that the ballast-equipped fluorescent lamp according to the present invention is more preferable if the temperature of the coldest point provided at the end of the straight line portion can be lowered and stabilized.
Hereinafter, embodiments for implementing the ballast-equipped fluorescent lamp of the present invention in a more preferable form will be described with reference to FIGS. 11 and 12.

(Embodiment 4)
FIG. 11 shows a ballast-equipped fluorescent lamp 11b according to Embodiment 3 of the present invention. FIG. 12 is a diagram in which a part of the fluorescent lamp arc tube 1b is cut out from the ballast-equipped fluorescent lamp 11b.

  The fluorescent lamp arc tube 1b used in the fluorescent lamp 11b with a built-in ballast has an end portion of the straight portion 3 extending toward the inside of the cover 10, and 15 mm from the end portion is accommodated in the cover 10. Between the inside of the cover 10 and the fluorescent lamp arc tube 1b, a hole through which the straight portion 3 provided in the cover 10 is inserted, and an electronic ballast 9 and a fluorescent lamp arc tube also provided in the cover 10 are provided. It is physically shielded except for a hole for passing a conducting wire for electrical connection with 1b.

  Since the space between the inside of the cover 10 and the fluorescent lamp arc tube 1b is physically shielded, heat generated from the fluorescent lamp arc tube 1b during discharge can be prevented from being transmitted to the inside of the cover 10. . By accommodating the end portion of the straight portion 3 in the cover 10, it is possible to prevent the influence of heat generated in the filaments 5a and 5b and the discharge path, particularly heat generated from the filament 5b (not shown) arranged in the spiral portion. it can. For this reason, the temperature of the coldest point provided in the edge part of the linear part 3 can be made lower and more stable, and it is more preferable.

Further, as shown in FIG. 12, in the ballast-equipped fluorescent lamp 11 b, the filament 5 a disposed in the straight portion 3 is located outside the cover 10.
The height from the cover 10 to the filament 5a is 15 mm, and the height Ha from the end of the straight portion 3 to the filament 5a is 30 mm.

By disposing the filament 5 a at a position outside the cover 10, it is possible to suppress the heat generated from the filament 5 a from being transmitted to the end of the linear portion 3 and the cover 10.
For this reason, the temperature of the coldest point provided in the edge part of the linear part 3 can be made lower and stabilized.
Furthermore, it is possible to suppress the heat generated from the filament 5a from being transmitted to the electronic ballast 9 incorporated in the cover 10. As a result, the electronic ballast 9 can be operated more stably, which is more preferable.

  As mentioned above, although the fluorescent lamp with a built-in ballast of the present invention has been described with reference to the fourth embodiment, other forms are possible.

Of the fluorescent lamp arc tube 1b, the length of the portion accommodated in the cover is 15 mm, but is not limited thereto. Preferably it is 2-50 mm, More preferably, it is 5-30 mm.
If it is less than 2 mm, it is not sufficient to prevent the influence of heat generated from the fluorescent lamp arc tube 1b.

The position of the filament 5a disposed in the straight line portion is 15 mm, but is not limited thereto. The height from the cover is preferably 1 to 30 mm, more preferably 2 to 20 mm.
If it is less than 1 mm, it cannot fully suppress that the heat which arises from the filament 5a is transmitted in a cover.

As described above, the fluorescent lamp arc tube of the present invention is a fluorescent lamp arc tube having a spiral portion, and even when mercury amalgam that releases mercury vapor at a relatively low temperature is used, the illuminance is lowered during stable lighting. Can be prevented. This fluorescent lamp arc tube has a straight portion at one end, and one filament is disposed on the straight portion, so that the insertion of the filament is easy and the productivity is excellent.
According to the method for manufacturing a fluorescent lamp arc tube according to the present invention, the filament disposed in the straight portion is inserted in a direction substantially parallel to the straight portion. Since the orientation and angle of the filament are not changed during the insertion process, the process is simple. Furthermore, there is little possibility that a filament and a support member will contact the fluorescent layer deposited on the inner surface of the glass bulb. For this reason, damage to the fluorescent layer and breakage of the filament hardly occur, and the fluorescent lamp arc tube according to the present invention can be obtained with high productivity.
The arc tube for a fluorescent lamp of the present invention is particularly suitable for a fluorescent lamp with a built-in ballast.

DESCRIPTION OF SYMBOLS 1, 1b Luminescent tube for fluorescent lamps 2 Spiral part 3 Straight line part 4 Mercury amalgam 5a, 5b Filament 6 Glass bulb 7a, 7b Support member 8 Stem 9 Electronic ballast 10 Cover 11a, 11b Ballast built-in fluorescent lamp 12 Sealing part L Straight part length Ha Height of the filament 5a measured from the end of the straight part 3

Claims (7)

A glass bulb having a spiral part and having a straight part at least at one end;
A pair of filaments disposed in the glass bulb;
A mercury amalgam that releases mercury vapor into the glass bulb;
An arc tube for a fluorescent lamp comprising:
Among the pair of filaments, at least one of the filaments is disposed in a position where the height from the end of the linear portion is 20 mm or more within the linear portion.
A fluorescent tube for a fluorescent lamp. The linear portion is disposed along a rotational axis of the spiral of the spiral portion;
The fluorescent tube for a fluorescent lamp according to claim 1, wherein: The straight portion is disposed so as to be substantially orthogonal to the spiral rotation surface of the spiral portion.
The fluorescent tube for a fluorescent lamp according to claim 2, wherein: A method for manufacturing a fluorescent lamp arc tube according to any one of claims 1 to 3,
After inserting the filament from the end of the linear portion in a direction substantially parallel to the linear portion,
Sealing the end of the straight portion;
A method of manufacturing an arc tube for a fluorescent lamp. An arc tube for a fluorescent lamp according to any one of claims 1 to 3,
An electronic ballast electrically connected between a power source and the filament to apply a voltage to the filament;
A cover containing the electronic ballast;
A fluorescent lamp with a built-in ballast, comprising: A fluorescent lamp with a built-in ballast according to claim 5,
At least a part of the linear portion is accommodated in the cover;
This is a fluorescent lamp with a built-in ballast. The one filament disposed in the linear portion is disposed at a position located outside the cover when the fluorescent lamp arc tube is fixed to the cover.
The fluorescent lamp with a built-in ballast according to claim 6, wherein:

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