KR850000139B1 - Fluorescent lamp device - Google Patents

Abstract

A fluorescent lamp, which is compatible with an incandescent lamp, consists of a transparent or semi-transparent outer case (1) covering a lamp (20), a screw part (3) which can be inserted into an incandescent lamp socket and holds a PTC (35) as an ballast, and a cap (15) that holds a starter (31). The PTC has a heat-sink (43) for radiating any overheating to maintain the necessary resistance in case of higher-voltage of the rated power source.

Description

Fluorescent lamp device

1 to 5 show an embodiment of the present invention,

1 is a front view showing the appearance of a fluorescent lamp device.

2nd section.

3 is an exploded perspective view.

4 is a diagram illustrating a lighting circuit.

5 is an operation characteristic diagram of a ballast composed of a static characteristic thermistor,

6, 7 and 8 are perspective views each showing a modified example of the temperature adjusting member.

The present invention relates to a fluorescent lamp device that can be used in place of an incandescent lamp. Recently, as energy-saving bonds are greatly proposed as a social request, development of power-saving lamps is also required in the light source field. By the way, fluorescent lamps are superior to incandescent bulbs in light efficiency (1 m / W) and are more advantageous than incandescent bulbs as power-saving light sources. Therefore, in recent years, there has been a demand for the development of a lamp that can be inserted into a threaded socket instead of an incandescent lamp by mounting a straight fluorescent lamp on the threaded clasp. In general, however, fluorescent lamps require a glowstarter as a start-up aid and at the same time a ballast to maintain stable lighting discharges. Therefore, when fluorescent lamps are mounted in sockets for incandescent lamps, the lamp tube or ballast shall be maintained as an integrated unit with the lamp. However, since ballasts generally use inductance, they generate heat according to the current limit, and because light tubes are equipped with thermally active switches, the operating characteristics are easily affected by ambient temperature conditions. For this reason, when the lighting tube and the ballast are provided in contact with each other, the lighting tube may be affected by the heat generated by the ballast, and the contact may be closed while the lamp is turned on, and the lamp may turn off. In order to prevent this, it is necessary to install the lighting tube in isolation from the ballast. Therefore, while maintaining the straight fluorescent lamp in the outer tube, install a clasp on one end of the outer tube, pinch the pin on the other end, accommodate the light tube in the cap, and accommodate the ballast in the clasp. The configuration is considered. However, to accommodate the ballast in the clasp, the ballast is required to be small and lightweight. Therefore, it is considered to employ a ballast such as a nonlinear selection characteristic thermistor having the same characteristics as the fifth degree. It can be formed from ceramic-based crystals, and is compact and lightweight, which is convenient to accommodate in the clasp. In addition, the above-described static characteristics have the following advantages. That is, since the temperature of the lamp itself is low at the start of the lamp, the resistance value is small, so that a large current flows through the filament, thereby increasing the amount of heat generated and increasing the release of hot electrons, thereby facilitating the discharge. In addition, when the lamp is turned on, the self-heats due to the large current at the start-up, the temperature becomes higher than the specific temperature t ₁ , and the lamp is supplied with the current necessary for discharge. When the current value changes due to the change in the power supply voltage, the heat generation amount changes and the resistance value changes statically accordingly, so that the lamp current can be stably maintained by controlling the change in the power supply voltage by itself. Ballasts composed of such static characteristics thermistors are advantageous not only in configuration but also in electrical characteristics.

However, since the static characteristic thermistor generates heat when the current flowing therein is large and the resistance value increases, when the power supply voltage is greatly increased, the heat generation amount is large and the temperature rise becomes remarkable. As a result, the resistance value increases, but when the resistance value exceeds a certain value, the lamp current is not supplied to the lamp and the lamp is turned off. The present invention has been studied in view of such circumstances, and an object thereof is to use a static characteristic thermistor as a ballast, and to provide a temperature regulating member to a ballast composed of the static characteristic thermistor to provide a temperature of the ballast. It is to provide a fluorescent lamp device that regulates the rise and does not turn off. An embodiment of the present invention will now be described with reference to FIGS. 1 to 5.

In the drawing, reference numeral 1 denotes an outer tube, which forms a cylindrical shape with both ends open. The outer tube 1 is formed of a light transmissive material such as synthetic resin such as polycarbonate or glass, but may be a translucent material such as milky white. One end of the outer tube 1 is connected to the clasp sphere (2). The clasp sphere 2 is composed of a threaded clasp 3 such as E27 and an insulating connecting tube 4. As is well known, the screw-type clasp 3 is provided with an eyelet terminal 7 integrally by loading an insulating cement or an adhesive 6 into a sheath 5 formed in a male screw shape, In addition, the cover 8 having a large diameter is embedded in the insulating adhesive 6. In addition, a conductive hole 9 is formed in the insulating adhesive 6. The insulating connecting tube 4 is made of a non-translucent or semi-translucent synthetic resin and is inserted into the opening of the cover 8. The connecting tube 4 is integrally coupled with the cover 8 by the recessed portion 8a deformed by punching a part of the outer surface of the cover 8 with a punch or the like. On the inner surface of the connection tube 4, ribs 10 protruding toward the center direction at four locations perpendicular to each other. … Is formed. This rib 10... … The coupling groove 11 is formed on the upper surface at the same time the stop end portion 12 is formed at the inner end. Then, one end of the outer tube 1 is inserted into the connecting tube 4, and the opening end surface thereof is the rib 10... … Is inserted into the coupling groove (11). In addition, the connecting tube 4 has a locking click (13) on its inner surface. … Is formed, and this locking click 13... … Is a coupling configuration 14 formed on the outer tube 1... … It is fitted in the outer tube (1) and the connecting tube (4) to combine.

On the other hand, the cap 15 is deposited on the other end of the outer tube (1). The cap 15 is in the form of a cylinder having a bottom surface and is formed of a non-transmissive or semi-translucent synthetic resin. The clamping end part 16 is formed in the inner surface of this cap 15, and the holding plate 25 mentioned later is clamped by this clamping end part 16. As shown in FIG. The other end of the outer tube 1 is inserted into the opening of the cap 15. In addition, on the inner surface of the cap 15, the engaging click 13 of the connecting tube 4... … The same click as 17 (...) … Is formed, and this lock click 17... … Is a coupling hole 18 formed in the outer tube 1. … It is fitted in to maintain the coupling between the outer tube (1) and the cap (15).

Thus, the fluorescent lamp 20 is inserted into the outer tube 1. The fluorescent lamp 20 has the same structure as in the prior art, and bipost clasps 21 and 21 are mounted at both ends of the strip, and pins 22 and 21 are respectively provided to these clasps 21 and 21. 22, 22, and 22 protrude. In the bulb, filaments 23a and 23b are formed as shown in the circuit diagram of FIG. 4, and a predetermined amount of mercury and an inert gas are enclosed in the bulb. Both ends of the fluorescent lamp 20 are supported by the holding plates 24 and 25. One holding plate 24 is made of an insulating synthetic resin, and its outer diameter is configured to match the inner diameter of the outer tube 1, and has corners 26 and 26 at its periphery. These corners 26, 26 are ribs 10 formed on the connecting tube 4; … It is abutted and supported by the end surface of the. The holding plate 24 is coupled to the holding plate 24 by penetrating through the insertion holes 27 and 27 into which the pins 22 and 22 of the fluorescent lamp 20 are inserted. The retaining plate 24 connects the corners 26 and 26 to the ribs 10 of the tubing 4. … The position in the axial direction is determined by abutting on the outer surface of the holding plate 24, and the position in the radial direction is regulated by fitting the outer circumference of the holding plate 24 to the inner surface of the outer tube 1. As a result, one end of the fluorescent lamp 20 is determined via the holding plate 24 in the axial direction and the foot diameter direction, and mechanical maintenance is performed.

In addition, the other retaining plate 25 has an outer diameter that matches the inner diameter of the opening of the cap 15, and is to be matched to the pinching end 16 formed in the cap 15. The holding plate 25 is sandwiched between the end portion 16 and the other end opening of the outer tube 1 so that the positions in the axial direction and the radial direction are fixed. In this holding plate 25, pin insertion holes 28 and 28 are formed, and the pins 22 and 22 on the other end side of the fluorescent lamp 20 penetrate. Moreover, the rotation stop grooves 29 and 29 are formed in the holding plate 25, and are fitted in the locking ribs 30 and 30 formed in the cap 15. As shown in FIG. Therefore, the other end of the fluorescent lamp 20 is controlled by the retaining plate 25 in the axial direction and the radial direction, and mechanically maintained. As a result, the fluorescent lamp 20 is positioned on the central axis of the outer tube 1 by the holding plates 24 and 25 at both ends.

Thus, the cap 15 is accommodated in the lighting tube 31 and the noise preventing capacitor 32 as necessary. These lighting tubes 31 and the condenser 32 are both supported by the holding plate 25. The support plate 33, 33, 34 is integrally formed in the holding plate 25, and the lighting tube 31 has these protrusions 33, between the pair of support protrusions 33, 33; It is clamped by the elastic force of (33). Moreover, the capacitor | condenser 32 is fixed by winding the lead wire 32a or 32b to the projection 34. As shown in FIG. On the other hand, the ballast 35 is accommodated in the clasp sphere 2. The ballast 35 is composed of a non-linear static characteristic thermistor having the characteristics as shown in FIG. It is obtained by adding a trace amount of two or more kinds, and is formed in a disk shape with ceramic crystals.

The ballast 35 is a ring 38 formed of a ballast support 36 and a terminal plate 37 each composed of a conductive plate and formed on the ballast support 36. … This prevents movement in the radial direction. The ballast support 36 opposes the cross section of the above-mentioned insulating adhesive 6, and has the protrusion 39 fitted in the through hole 9. As shown in FIG. In addition, 40 is the ballast support 36 and the eyelet terminal (7). It is a lead wire made of spirals to be electrically connected. In addition, the terminal plate 37 is a bending piece 41... … And a connecting piece 42, the terminal plate 37 supports the temperature adjusting member 43. The temperature adjusting member 43 includes a plurality of fins 44. … And the lower pin 44 has a bending piece 41... … This bending piece 41 is made by bending. … Therefore, the temperature adjusting member 43 is engaged with and in surface contact with the connecting piece 42. The shoulder of the temperature adjusting member 43 is caught by the stationary end 12 formed in the ribs 10,... Of the connecting tube 4. The ballast 35 is in surface contact with the terminal plate 37. Further, the terminal plate 37 is in surface contact with the temperature adjusting member 43. The temperature adjusting member 43 is supported by the rib 10 of the connecting tube 4. As shown in FIG.

Reference numerals 45 and 46 denote conductive codes, and are guided in the axial direction along the outer surface of the fluorescent lamp 20 in the outer tube 1. One cord 45 is electrically connected between one of the pins 22 and 22 at both ends of the fluorescent lamp 20, and the other cord 46 is connected to one lead wire of the lighting tube 31. The cells 45 are electrically connected to each other. The cords 45 and 46 are adhered to the clasps 21 and 21 by the adhesive tapes 47 and 47. Reference numeral 48 is another code, which electrically connects the connecting piece 42 of the terminal plate 37 and the other pin 22 of one clasp 21 of the fluorescent lamp 20.

The fluorescent lamp 20, the lighting tube 31, the condenser 32, and the ballast 35 as described above have the same circuit configuration as that of the fourth diagram. That is, the stabilizer 35 is connected in series to the filament 23a of the fluorescent lamp 20. In addition, the lighting tubes 31 are connected in series to the filaments 23a and 23b, and the lighting tubes 31 are parallel to the fluorescent lamp 20 at the time of lighting. The capacitor 32 is connected in parallel to the lighting tube 31. The operation of the fluorescent lamp device having such a configuration will be described.

The clasp 3 of the fluorescent lamp device is inserted into an insulated socket for an incandescent lamp (not shown) instead of an incandescent lamp, and when the power switch 50 is attached, the voltage of the power source 51 is input to the lamp device. As the power source 51 is turned on, a current flows through the lighting tube 31 to cause glow discharge. Since this glow discharge heats and closes the bimetal switch of the lighting tube 31, the lighting tube 31 is closed, and the preheating current flows to both filaments 23a and 23b of the fluorescent lamp 20. When the bimetal switch of the lighting tube 31 is cooled and opened, a sharp current change occurs, so that a high pulse voltage is generated according to the kick voltage, and this high voltage pulse is applied between both filaments 23a and 23b. As a result, the fluorescent lamp 20 lights up.

When the discharge is started in this manner, the discharge current flows, but since the voltage and current at the discharge show negative characteristics, the lamp 20 itself cannot limit the current, and thus the ballast 35 connected in series is provided. Current to suppress the stable discharge. Therefore, when the static thermistor having the characteristics as shown in FIG. 5 is used as the ballast 35, since the temperature of the ballast 35 is low at start-up, the resistance value is small, which causes a large current to flow in the preheating circuit. As a result, the filaments 23a and 23b are heated to a high temperature, whereby the amount of electromagnetic radiation increases and becomes a state in which it is easy to discharge. Therefore, even if the pulse voltage is relatively low, reliable discharge is achieved. In addition, when a large current flows in the start-up preheating process, the stabilizer 35 generates heat by itself and is heated to a specific temperature t ₁ or more, thereby rapidly increasing the resistance value. Therefore, since the current of the lighting circuit is suppressed and only the current necessary for the discharge of the lamp 20 flows, stable discharge is maintained.

When the power supply voltage rises during lighting, the current flowing through the ballast 35 rises, so that the ballast 35 generates heat by itself and regulates the current flowing through the lamp 20. When the power supply voltage is lowered, the ballast 35 has less self-heating and the resistance value becomes smaller, so that the current value flowing through the lamp 20 becomes larger. Thus, the lamp can maintain a stable discharge. By the way, when the power supply voltage rises, for example, the self-heating of the ballast 35 increases, but since the ballast 35 is in contact with the temperature regulating member 43 via the terminal plate 37, Heat is conducted to this temperature adjusting member 43. The temperature correction member 43 has a large heat capacity and a heat radiation fin 44... … Since the heat dissipation is caused by, the temperature rise of the ballast 35 is restricted. Thus, ballast 35, for example, so maintained at a temperature less than that represented by a fifth-degree t ₂ suppresses an increase in the resistance value. That is, since the current value necessary for lighting the lamp 20 is secured, the beam is not turned off.

Since the fluorescent beam device includes the fluorescent beam 20, the lighting tube 31, and the stabilizer 35 as an integrated unit, a separate lighting tube 31 or the ballast 35 may be externally installed even if it is inserted into the socket by replacing the incandescent lamp. Since it can be used without the need for an incandescent light bulb, there is no functional problem. In addition, since the fluorescent beam device accommodates the lighting tube 31 in the cap 15 and the ballast 35 and the temperature adjusting member 43 in the clasp 3, the lighting tube 31 is connected to the ballast 35. The distance is sufficiently maintained so that the light tube 31 is not affected by heat.

In the above embodiment, as the temperature adjusting member 43, the plurality of heat radiation fins 44... … Although the description has been made, the temperature adjusting member according to the present invention is a member 60, 70, 80 having a shape as shown as a modification example in Figs. 6, 7, and 8, respectively. Also possible.

As described in detail above, the present invention installs a cap on one end of the tube other than the light transmissive or semi-transparent, and mounts the cap on the other end, while receiving a straight fluorescent lamp in the other tube, while simultaneously lighting the tube and the tap in the cap. The ballast was installed inside the iron and the temperature adjusting member was delivered to the ballast. Therefore, since the light tube and the ballast are arranged in isolation, the light tube is not affected by heat dissipation of the ballast. And since the ballast uses static characteristic thermistor, it is small and light and can be easily accommodated in the clasp.

Since the temperature regulating member is introduced to the static characteristics thermistor ballast, the temperature rise of the ballast is suppressed by this temperature regulating member. As a result, there is no excessive increase in resistance of the ballast, and there is an advantage of preventing the beam from turning off.

Claims (1)

Connect the threaded clasp 3 to one end of the translucent or semi-transparent outer tube 1, attach the cap 15 to the other end, and receive a straight fluorescent lamp 20 in the outer tube. A fluorescent beam comprising a lighting tube 31 inside and a stabilizer 35 composed of a static characteristic thermistor within the clasp, and a temperature adjusting member 43 that radiates heat to the ballast. Device.

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