JP2000243115A - Desk lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To minimize the leak of light with a simple structure and release the heat generated from a fluorescent tube to efficiently light the fluorescent tube. SOLUTION: An air passing route 24 extending from the housing space 11 of a shade 12 to the upper part of the shade 12 through a vent hole 21 is formed, and the high-temperature air within the housing space 11 is released to the upper part of the shade 12 through the air passing route 24. According to this, the air temperature in the housing space 11 and, in its turn, the temperature of the fluorescent tube 15 itself can be reduced with hardly leaking the light emitted from a fluorescent tube 15 to increase the energy efficiency of the fluorescent tube 15.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a desk lamp used on a desk.

[0002]

There have been various types of desk lamps of this type. These desk lamps have been tried to improve the luminous flux per unit power, that is, energy efficiency, from the viewpoint of energy saving. For example, although it varies depending on the type of fluorescent tube, the fluorescent tube has the highest energy efficiency when the coldest temperature of the tube wall is 30 to 45 ° C. Therefore, in order to approach this temperature, a structure for dissipating the heat generated from the fluorescent tube can be considered, but this structure has hardly been studied in a conventional desk lamp.

[0003] On the other hand, for ceiling lights and the like,
As described in, for example, US Pat. No. 66513, there is known a reflector having a ventilation hole formed in the reflector. However, if ventilation holes are formed in the reflector, in the case of ceiling lights, light leaked from the reflection holes will be reflected on the ceiling and illuminate the room,
This is not a problem, but it was not as effective with a desk lamp as the amount of light shining on the desk was reduced. Some ceiling lights have a structure that seems to reduce light leakage, but these structures are complicated, and it has been difficult to apply these structures to a desk lamp.

The present invention solves the above problems, and provides a desk lamp which has a simple structure to minimize light leakage and radiates heat generated from the fluorescent tube to efficiently light the fluorescent tube. The purpose is to:

[0005]

According to the present invention, there is provided a desk lamp having a shade having an opening at a lower portion and having an accommodation space for accommodating a fluorescent tube, and a ventilation hole extending from the lower portion of the shade to the upper portion of the shade. An air circulation path for lowering the temperature in the accommodation space by connecting the accommodation space and the upper part of the shade is formed.

According to the present invention, high-temperature air in the storage space is discharged to the upper part of the shade through the air circulation path from the air circulation space to the upper part of the shade, and the low-temperature air is stored in the storage space. Is supplied from below
The temperature of the air in the storage space is kept low, and thus the temperature of the fluorescent tube is kept low.

In the desk lamp according to the present invention, a socket for a fluorescent tube is provided at a base end of the shade, and a ventilation space is formed at a tip end of the shade so as to be continuous with the housing space. In the accommodation space excluding the ventilation space, a reflection plate is provided so as to cover the upper part of the fluorescent tube, an air circulation path from the ventilation space to the upper part of the shade is formed, and the tip of the fluorescent tube is located in the ventilation space. It is configured to do so.

According to the present invention, the high-temperature air in the housing space is discharged from the air circulation path formed at the tip of the shade without being hindered to the upper part of the shade. The air at the base end of the space also moves to the ventilation space at the tip of the shade, and is discharged from the air flow path to the upper part of the shade, so that the temperature of the air in the accommodation space and, consequently, the temperature of the fluorescent tube are more efficient. In addition to being kept low, the light emitted from the fluorescent tube hardly leaks above the shade because only the tip of the fluorescent tube is located in the ventilation space.

Further, in the desk lamp of the present invention, in claim 1, a socket for a fluorescent tube is provided at a base end of the shade, and a reflecting plate is provided in the housing space so as to cover an upper portion of the fluorescent tube. A first vent is formed at the tip of the sail, a second vent is formed at the tip of the reflector, and the air from the accommodation space to the upper part of the shade is formed by the first and second vents. A flow path is formed, and the tip of the fluorescent tube is positioned below the first and second ventilation holes.

According to the present invention, as described above, high-temperature air in the storage space is discharged to the upper part of the shade through an air flow path extending to the upper part of the shade through the second and first ventilation holes, As a result, the air at the base end of the housing space also moves to the distal end, and is discharged to the upper part of the shade via the air circulation path, so that the temperature of the air in the housing space and, consequently, the temperature of the fluorescent tube become higher. In addition to being efficiently kept low, only the tip of the fluorescent tube is located below the second ventilation hole, so that the light emitted from the fluorescent tube is reflected downward without leaking almost to the upper side of the shade.

Further, in the desk lamp according to the present invention, a fluorescent lamp socket is provided at a base end of the shade, and a ventilation space is formed continuously with the housing space.
A reflection plate is provided in the accommodation space excluding the ventilation space so as to cover the upper part of the fluorescent tube, and an air circulation path from the ventilation space to the upper part of the shade is formed.

According to the present invention, the air around the base end of the fluorescent tube, which has the highest temperature in the housing space, is discharged to the upper part of the shade via the air circulation path. The air at the center and the tip of the housing space also moves to the ventilation space at the base end and is discharged to the upper part of the shade through the air circulation path, so that the temperature of the air in the housing space, and thus the temperature of the fluorescent tube, Not only is more efficiently kept low, but also because only the base end of the fluorescent tube is located in the ventilation space, light emitted from the fluorescent tube hardly leaks above the shade.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to FIGS. Reference numeral 1 denotes a desk lamp. The desk lamp 1 includes a base 2 and a support 3.
And a lamp 4. A bulging portion 5 is formed in the base portion 2, and a switch 6 is provided above the bulging portion 5.
And a mounting portion 7. And the mounting portion 7
, A base end 3A of the support 3 is attached.
The column 3 is mounted on the mounting portion 6 such that the axial direction of the base end 3A is vertical, and is rotatable about this axis in a horizontal direction within a range of 90 degrees.
A lamp 4 is attached to a tip 3B of the support 3 via a rotation mechanism 8. The rotation axis of the rotation mechanism 8 is formed in the vertical direction, and the lamp 4 can be rotated in the horizontal direction within a range of 180 degrees around this axis.

The lamp 4 comprises a control unit 10 containing a lighting circuit 9 and a shade 12 having a receiving space 11 with an open lower part. The shade 12 includes a socket 14 attached to the base end 13, a fluorescent tube 15 electrically connected to the socket 14, and the inside of the housing space 11 covering the fluorescent tube 15. A reflector 16 made of metal such as aluminum provided on the upper part and a lamp holder 17 for holding the fluorescent tube 15 are provided. The reflection plate 16 includes:
A ventilation space 20 is formed between the shade 12 and the reflector 16 at a central portion 19 excluding the base end 13 and the tip end 18 of the sail 12. space
A slit-shaped ventilation hole 21 is formed in the central upper portion 19 of the shade 12 in communication with 20. The lower portion of the ventilation hole 21 is covered with the reflector 16, and openings 22, 23 are provided between the base 12 and the tip 18 of the reflector 16 with the shade 12, respectively. Are formed. An air circulation path 24 is formed from the storage space 11 to the upper part of the shade 12 through the openings 22, 23, the ventilation space 20, and the ventilation hole 21.
Further, a base 15A of the fluorescent tube 15 is located near the opening 22 formed on the base end 13 side of the shade 12, and the opening 23 formed on the tip 18 side of the shade 12. In the vicinity, the tip 15B of the fluorescent tube 15 is located. In this example, an FPL-27 type is used as the fluorescent tube 15.

Next, the operation of the present embodiment will be described. First, when the switch 6 is closed, the fluorescent tube 15 connected to the socket 14 is turned on by the lighting circuit 9. Some time after the lighting, the temperature of the air in the housing space 11 increases due to the heat generated by the fluorescent tubes 15, and the reflector 16 is heated to a high temperature. The air in the ventilation space 20 is heated by the heat from the reflection plate 16. The air in the ventilation space 20 is released from the ventilation hole 21 to the upper part of the shade 12 by being heated, and accordingly, the air that has become hot at the proximal end 13 and the distal end 18 of the shade 12 is removed. , Flows into the ventilation space 20 from the openings 22 and 23. Further, along with the flow of the air, the air having a high temperature in the central portion 19 of the housing space 11 also moves to the base end portion 13 or the front end portion 18 and flows into the ventilation space 20 from the openings 22 and 23. In this manner, the heated air in the storage space 11 is released through the air circulation path 24 from the storage space 11 to the upper part of the shade 12 through the openings 22, 23, the ventilation space 20, and the ventilation hole 21. At the same time, low-temperature air flows into the housing space 11 from below the housing space 11. As a result, the temperature of the air around the accommodation space 11 decreases, and thus the fluorescent tube 15
The temperature of itself is also low. Therefore, the luminous flux per unit power of the fluorescent tube 15, that is, the energy efficiency can be improved. In addition, most of the fluorescent tube 15 is located below the reflecting plate 16 and the base 15A and the tip 15B are only slightly separated from the reflecting plate 16, so that the light emitted from the fluorescent tube 15 is effectively leaked. Can be reflected downward.

The lighting circuit 9 is an inverter circuit, which supplies approximately 70 to 75% of the rated power of the fluorescent tube 15 to the fluorescent tube 15, which will be described in detail. FIG. 3 shows the relationship between the electric power [W] and the luminous flux [lm],
FIG. 4 shows power [W] and luminous flux [lm / unit power].
W]. The curve shown by the solid line in FIG. 3 is an actually measured value, and the straight line shown by the dashed line is a proportional value.
In addition, this proportional value is defined as the reference point A using the value of the luminous flux at 22.6 W (approximately 84% of the rated value) which is the electric power actually set by the applicant in the conventional inverter lighting circuit. And the origin. As shown in FIG.
The luminous flux does not decrease in proportion to the power, and at point D (19.7 W / about 73% of the rated value), the difference between the measured value of the luminous flux and the proportional value becomes maximum. That is, as shown in FIG. 4, the energy efficiency is maximum at this point D. In addition, the energy efficiency has a steep gradient near point B (21.3 W / about 79% of the rated value). In FIG. 3, point F (17.5 W / about 65% of the rated value) and point G (1
6.6 W / about 61% of the rated value), and the energy efficiency is lower than that of the point A in FIG. In addition, the fluorescent tube did not light up at the measurement point of the power lower than the point G. Therefore, it can be said that the energy efficiency is high between the point B and the point F. If the inverter lighting circuit is configured to control the energization in this power range, a lighting fixture with high energy efficiency can be obtained. Since the gradient from the point B to the point C (20.2 W / about 75% of the rated value) is steep, and there is a large difference in energy efficiency in this section, it is desirable to set the power to the point C or lower. In addition, the gradient is steep below point E (18.7 W / 69% of the rated value), and if the power is too low, it becomes dark even if the energy efficiency is high. It is desirable to set to.

As described above, the desk lamp of the present invention forms an air circulation path from the storage space of the shade to the upper part of the shade through the opening, the ventilation space, and the ventilation hole, and the air circulation path forms the air in the storage space. By releasing high-temperature air to the upper part of the shade, it is possible to increase the energy efficiency of the fluorescent tube by lowering the temperature of the air in the storage space and, consequently, the temperature of the fluorescent tube itself, with little leakage of the light emitted by the fluorescent tube. it can.

Next, regarding a second embodiment of the present invention,
A description will be given based on FIGS. Note that portions common to the above-described embodiments are denoted by common reference numerals, and description thereof is omitted. The lamp 4 includes a control unit 10 that houses the lighting circuit 9 and a shade 31 that has a housing space 30 with an open lower part. The shade 31 has a socket 14 attached to the base end 32 side, a fluorescent tube 15 electrically connected to the socket 14, and an inside of the accommodation space 30 so as to cover the fluorescent tube 15 from above. A reflector 16 made of metal such as aluminum provided on the upper part and a lamp holder 17 for holding the fluorescent tube 15 are provided. At the tip 33 of the shade 31, a ventilation space 34 continuous with the accommodation space 30 is formed, and the ventilation space 34 and the shade 31
Except for the base end portion 32, the reflection plate 16 is provided in the housing space 30. And, at the tip 33 of the shade 31,
A slit-shaped ventilation hole 35 is formed.
Thus, the ventilation space 34 communicates with the outside of the shade 31. Further, the tip 15B of the fluorescent tube 15 is located in the ventilation space. In this way, an air circulation path 36 is formed from the ventilation space 34 formed on the distal end portion 33 side of the housing space 30 to the upper part of the shade 31 via the ventilation hole 35.

Next, the operation of the present embodiment will be described. Note that the description of the actions common to the above-described embodiment is omitted. After a while after the fluorescent tube 15 turns on,
The temperature of the air in the housing space 30 increases due to the heat generated by the fluorescent tubes 15. The air in the ventilation space 30 is released from the ventilation space 34 to the upper part of the shade 31 through the ventilation hole 35 by being heated, and further along with the flow of the air, the accommodation space 30
The air having a high temperature inside also moves to the ventilation space 34 and is discharged from the ventilation hole 35 to the upper part of the shade 31. In this manner, the heated air in the storage space 30 is released from the ventilation space 34 through the air circulation path 36 through the ventilation hole 35 to the upper part of the shade 31, and at the same time, the low temperature Air flows into the accommodation space 30. Due to this, the accommodation space
The temperature of the air inside 30 decreases, and therefore the temperature of the fluorescent tube 15 itself also decreases. The following operation is the same as in the above embodiment. FIG. 7 shows a fluorescent tube according to the second embodiment.
It shows the temperature of the 15 tube walls. As shown in this figure, the temperature of the tip end 15B of the fluorescent tube 15 is lowered by about 5 ° C., and the one in which the vent hole 35 is formed is sufficiently cooled as compared with the one in which the vent hole 35 is closed. I understand. At this time, the average illuminance at a position 30 cm away from the fluorescent tube 15 is improved by 11 lx, and the average illuminance at a position 60 cm away is improved by 6 lx. Considering that the reflector 16 and the like are almost the same, the luminous flux also increases. It can be said that. Therefore, it can be said that the energy efficiency is improved.

As described above, the desk lamp of the present invention forms an air circulation path from the ventilation space to the upper part of the shade via the ventilation hole, and locates the tip of the fluorescent tube in this ventilation space. It is possible to increase the energy efficiency of the fluorescent tube by lowering the temperature of the air in the housing space, that is, the temperature of the fluorescent tube itself, with almost no leakage of light emitted from the fluorescent tube.

Next, regarding a third embodiment of the present invention,
A description will be given based on FIG. Note that portions common to the above-described embodiments are denoted by common reference numerals, and description thereof is omitted. The lamp 4 includes a control unit 10 containing a lighting circuit 9,
It comprises a shade 41 having an accommodation space 40 with an open lower part. The shade 41 has a socket 14 attached to the base end 42 side, a fluorescent tube 15 electrically connected to the socket 14, and an inside of the accommodation space 40 so as to cover the fluorescent tube 15 from above. A reflection plate 43 made of metal such as aluminum provided on the upper part and a lamp holder 17 for holding the fluorescent tube 15 are provided. Further, a first vent hole 46 having a slit shape is formed at the tip portion 44 of the shade 41. The reflector 43 is provided except for the base end 42 of the shade 41, and a slit-shaped second ventilation hole 47 is formed on the tip 44 side of the reflector 43. .
In this way, an air flow path 48 extending from the tip end 44 side of the accommodation space 40 to the upper side of the shade 41 via the second ventilation hole 47 and the first ventilation hole 46 is formed. The distal end 15B of the fluorescent tube 15 is located below the first ventilation hole 46 and the second ventilation hole 47.

Next, the operation of the present embodiment will be described. Note that the description of the actions common to the above-described embodiment is omitted. After a while after the fluorescent tube 15 turns on,
The temperature of the air in the housing space 40 increases due to the heat generated by the fluorescent tubes 15. The air on the distal end portion 44 side of the storage space 40 is heated, so that the first vent hole formed on the distal end portion 44 of the shade 41 from the second vent hole formed on the distal end portion 44 side of the reflector 43 is heated. Go through 46 to the top of shade 41. Further, with the flow of the air, the high-temperature air in the storage space 40 also moves to the tip portion 44 side, and is discharged from the second ventilation hole 47 to the upper part of the shade 41 through the first ventilation hole 46. Is done. In this way, the heated air in the storage space 40 flows through the air circulation path 48 from the tip end 44 side of the storage space 40 to the upper part of the shade 41 through the second ventilation hole 47 and the first ventilation hole 46. And at the same time, low-temperature air flows into the storage space 40 from below the storage space 40. As a result, the temperature of the air in the storage space 40 decreases, and the temperature of the fluorescent tube 15 itself also decreases. At this time, the light emitting portion of the fluorescent tube 15 except for the base 15B is all below the reflector 43, and most of the light except for light leaking slightly from the tip 15B of the fluorescent tube 15 to the second ventilation hole 47 is downward. The light emitted from the fluorescent tube 15 can be used effectively. The following operation is the same as in each of the above embodiments.

As described above, in the desk lamp of the present invention, the first ventilation hole and the second ventilation hole are formed at the distal ends of the shade and the reflector, and the distal end of the fluorescent tube is provided below these ventilation holes. By arranging the fluorescent tube, the light emitted from the fluorescent tube can be effectively used without substantially leaking the light, and the temperature of the air in the accommodation space, that is, the temperature of the fluorescent tube itself can be lowered, and the energy efficiency of the fluorescent tube can be increased.

Next, regarding a fourth embodiment of the present invention,
This will be described with reference to FIG. Note that portions common to the above-described embodiments are denoted by common reference numerals, and description thereof is omitted. The lamp 4 includes a control unit 10 containing a lighting circuit 9,
It is composed of a shade 51 having a storage space 50 whose lower part is open. The shade 51 has a socket 14 attached to the base end 52 side, a fluorescent tube 15 electrically connected to the socket 14, and an inside of the accommodation space 50 so as to cover the fluorescent tube 15 from above. A reflective plate 53 made of metal such as aluminum provided on the upper part, and a lamp holder 17 for holding the fluorescent tube 15 are provided. At the base end 52 of the shade 51, a ventilation space 54 that is continuous with the housing space 50 is formed, and, except for the ventilation space 54, the reflection plate 53
Is provided. A slit-shaped ventilation hole 55 is formed at the base end 52 of the shade 51.
55 allows the ventilation space 54 to communicate with the outside of the shade 51. In this way, an air circulation path 56 from the ventilation space 54 to the upper part of the shade 51 via the ventilation hole 55 is formed. Note that the base 15 of the fluorescent tube 15 is provided in the ventilation space 54.
A is located.

Next, the operation of the present embodiment will be described. Note that the description of the actions common to the above-described embodiment is omitted. After a while after the fluorescent tube 15 turns on,
The temperature of the air in the housing space 50 increases due to the heat generated by the fluorescent tubes 15. In particular, in the vicinity of the base 15A of the fluorescent tube 15, the temperature of the fluorescent tube 15 and the surrounding air is highest. The air in the base end 52 side of the housing space 50, that is, the air in the ventilation space 54 is discharged from the ventilation space 54 to the upper part of the shade 51 through the ventilation hole 55 by being heated. Further, along with the flow of the air, the air which has become high temperature in the accommodation space 50 also flows into the ventilation space 54.
To the upper part of the shade 51 through the ventilation hole 55. In this manner, the heated air in the storage space 50 is released through the air circulation path 56 from the ventilation hole 54 to the upper part of the shade 51 through the ventilation hole 55, and at the same time, the storage space 50
The low-temperature air flows into the storage space 50 from below. As a result, the temperature of the air in the storage space 50 decreases, and the temperature of the fluorescent tube 15 itself also decreases. At this time, the fluorescent tube 15
Except for the base 15B, the light emitting portion is all below the reflector 43, and almost all the light emitted from the fluorescent tube is reflected downward, so that the light from the fluorescent tube 15 can be used effectively. Further, since the vicinity of the hottest base 15A is radiated most efficiently, the temperature of the air in the housing space 50 becomes lower, and the temperature of the fluorescent tube 15 itself becomes lower. The following operation is the same as in each of the above embodiments.

As described above, in the desk lamp of the present invention, the light emitted from the fluorescent tube is formed by forming the ventilation hole at the base end of the shade and communicating with the ventilation space and positioning the base of the fluorescent tube in the ventilation space. Light can be used effectively with little leakage, and heat is dissipated in the hottest areas, lowering the temperature of the air in the housing space and, consequently, the temperature of the fluorescent tube itself, thereby improving the energy efficiency of the fluorescent tube. Can be further enhanced.

It should be noted that the present invention is not limited to the above embodiment, and various modifications can be made within the gist of the invention. For example, in the present embodiment, the ventilation hole is formed in a slit shape, but may be formed in another shape, for example, a round hole shape. In this embodiment, an FPL type fluorescent tube is used as the fluorescent tube. However, other types, for example, FML type, FDL type, and FHT type are used.
And FUL type fluorescent tubes. Further, in the fourth embodiment, the ventilation hole is provided only in the portion facing the base, but the ventilation hole may reach the portion facing the base end of the light emitting portion of the fluorescent tube. As in the embodiment, a reflector may be provided at the base end of the shade, and a slit-shaped ventilation hole may be formed in the reflector.

[0028]

The desk lamp of the present invention has a shade having an opening at the lower portion and having an accommodation space for accommodating the fluorescent tube, and a ventilation hole extending from the lower portion of the shade to the upper portion of the shade to provide the accommodation space and the lamp. By forming an air flow path that lowers the temperature in the storage space by communicating with the upper part of the sail, the high-temperature air in the storage space passes through the air flow path from the air flow space to the upper part of the shade, and the air flows through the upper part of the shade. It is discharged to the upper part and low-temperature air is supplied from below the housing space, so that the air temperature in the housing space is kept low, and the temperature of the fluorescent tube is kept low. Efficiency can be improved.

In the desk lamp according to the present invention, a fluorescent tube socket is provided at a base end of the shade, and a ventilation space is formed at a leading end of the shade so as to be continuous with the housing space. In the accommodation space excluding the ventilation space, a reflection plate is provided so as to cover the upper part of the fluorescent tube, an air circulation path from the ventilation space to the upper part of the shade is formed, and the tip of the fluorescent tube is located in the ventilation space. The high-temperature air in the storage space is released from the air circulation path formed at the tip of the shade without being hindered to the upper part of the shade, and accordingly, the air at the base end side of the storage space is The air also moves to the ventilation space at the tip of the shade, and is discharged from the air circulation path to the upper part of the shade, so that the temperature of the air in the accommodation space and, consequently, the temperature of the fluorescent tube can be suppressed more efficiently. Not, by only the tip portion of the fluorescent tube is positioned in the ventilation space, the light hardly leaks to the shade upper emitted by the fluorescent tube, it is possible to further improve the energy efficiency of the fluorescent tube.

Further, in the desk lamp of the present invention, in claim 1, a socket for a fluorescent tube is provided at a base end of the shade, and a reflecting plate is provided in the housing space so as to cover an upper portion of the fluorescent tube. A first vent is formed at the tip of the sail, a second vent is formed at the tip of the reflector, and the air from the accommodation space to the upper part of the shade is formed by the first and second vents. A flow path is formed, and the tip of the fluorescent tube is located below the first and second ventilation holes. The air is discharged to the upper part of the shade via the air flow path extending to the upper part of the shade via the first ventilation hole. Is released to the top of the Not only is the air temperature, and thus the temperature of the fluorescent tube, more efficiently kept low, but also the light emitted from the fluorescent tube is almost above the shade because only the tip of the fluorescent tube is located below the second ventilation hole. Since the light is reflected downward without leaking, the light from the fluorescent tube can be effectively used, and the energy efficiency of the fluorescent tube can be further improved.

Further, in the desk lamp according to the present invention, a fluorescent lamp socket is provided at a base end of the shade, and a ventilation space is formed continuously with the housing space.
A reflector is provided in the accommodation space excluding the ventilation space so as to cover the upper part of the fluorescent tube, and an air circulation path from the ventilation space to the upper part of the shade is formed. The air around the proximal end of the pipe is discharged to the upper part of the shade via the air circulation path, and along with this, the air at the center and the tip side of the storage space also moves to the ventilation space at the proximal end, and By being released to the upper part of the shade via the distribution channel, not only the air temperature in the storage space, and thus the temperature of the fluorescent tube can be more efficiently kept low,
Because only the base end of the fluorescent tube is located in the ventilation space,
Since the light emitted from the fluorescent tube hardly leaks above the shade, the energy efficiency of the fluorescent tube can be further improved.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a lamp showing the first embodiment of the present invention.

FIG. 3 is a graph showing a relationship between power consumption and luminous flux according to the present invention.

FIG. 4 is a graph showing a relationship between power consumption and energy efficiency of the present invention.

FIG. 5 is a sectional view of a lamp showing a second embodiment of the present invention.

FIG. 6 is a sectional view taken along line AA of the second embodiment of the present invention.

FIG. 7 is a table showing the relationship between the presence or absence of a ventilation hole, temperature, and illuminance in the second embodiment of the present invention.

FIG. 8 is a bottom view of a lamp showing a third embodiment of the present invention.

FIG. 9 is a sectional view of a lamp showing a fourth embodiment of the present invention.

[Explanation of symbols]

 11 Storage space 12 Seeds 14 Socket 15 Fluorescent tube 16 Reflector 24 Air flow path 30 Storage space 31 Seeds 36 Air flow path 40 Storage space 41 Seeds 43 Reflector 46 First air hole 47 Second air hole 48 Air flow path 50 Storage space 51 Cade 53 Reflector 56 Air flow path

Claims (4)

[Claims] 1. A shade having an opening at a lower portion and an accommodation space for accommodating a fluorescent tube, and a ventilation hole extending from the lower portion of the shade to the upper portion of the shade to communicate the accommodation space with the upper portion of the shade. A desk lamp, wherein an air flow path for lowering the temperature in the housing space is formed. 2. A fluorescent tube socket is provided at a base end of the shade, and a ventilation space is formed at a distal end of the shade so as to be continuous with the housing space. A reflector is provided so as to cover the upper part of the lamp, an air flow path is formed from the ventilation space to the upper part of the shade, and the tip of the fluorescent tube is located in the ventilation space. 1. The desk lamp according to 1. 3. A fluorescent tube socket is provided at a base end of the shade, a reflector is provided in the housing space so as to cover an upper part of the fluorescent tube, and a first ventilation hole is provided at a distal end of the shade. Forming a second ventilation hole at the tip of the reflector, forming an air flow path from the housing space to the upper part of the shade by the first and second ventilation holes, The desk lamp according to claim 1, wherein the tip of the fluorescent tube is located below the ventilation hole and the second ventilation hole. 4. A fluorescent tube socket is provided at a base end of the shade, and a ventilation space is formed continuously with the accommodation space, and an upper portion of the fluorescent tube is covered in the accommodation space excluding the ventilation space. 2. A desk lamp according to claim 1, wherein a reflection plate is provided on the base, and an air circulation path from the ventilation space to the upper part of the shade is formed.