KR200339205Y1 - Fluorescent lamp and control device of power divide mode - Google Patents

Abstract

The present invention relates to a fluorescent lamp capable of power distribution and its control device, the present invention, a plurality of glass tubes adjacent to each other in a plurality of glass tubes are connected to each other through a connecting member, a glass tube connected through the connecting member The plurality of glass tubes may be divided into a plurality of pairs to form a shape, and the plurality of glass tubes may be connected to each other, but the electrical operation may be divided, and the case accommodating the plurality of glass tubes may include an upper side of the glass tube connected to the plurality of glass tubes. It consists of a plurality of divided forms corresponding to the divided form, and form a guide hole for connecting the connection line drawn from the glass tube formed at each end of the pair with the control circuit inside the ballast, The glass tube is the same as the shape of the lamp, but the power supplied to the lamp is divided by a certain ratio. Corresponding to the form to be used by the allocation to scale, it does not exert stress on the electronic components, and it relates to a fluorescent lamp and a control device is a power distribution as possible to produce a high quality light through.

Description

Fluorescent lamp and control device of power distribution method

The present invention relates to a fluorescent lamp capable of power distribution and a control device thereof, and more particularly, a plurality of glass tubes adjacent to each other in a plurality of glass tubes are connected to each other through a connecting member, and a plurality of glass tubes connected through the connecting member are provided in pairs. The plurality of glass tubes are connected to each other, but the electrical operation is divided, and the case accommodating the plurality of glass tubes includes a divided form of the glass tube having an upper side connected to the plurality of glass tubes. Comprising a plurality of forms in response to each other, and form a guide hole for connecting the connection line drawn from the two pairs of glass tubes each of the pair and the control circuit inside the ballast, in the shape of a general fluorescent lamp Same as, but the power supplied to the lamp of the glass tube divided by a certain ratio In response to the state by allowing the dispensing at a predetermined ratio, it does not exert stress on the electronic components, and it relates to a fluorescent lamp and a control device is a power distribution as possible to produce a high quality light through.

In general, lighting fixtures that emit light, such as incandescent bulbs and fluorescent lamps, are attached to a predetermined position (especially on the ceiling) of an office, home, or building to emit light according to the user's choice when it is dark or dark. It brightens the surroundings and replaces incandescent lamps or lamps after a certain period of use.

Among such lighting fixtures, fluorescent lamps are roughly classified into a transformer type and a ballast type.

Small fluorescent lamps, which are commonly used and easily available, have a ballast on the top of the lamp and a screw portion for use in ordinary incandescent lamp sockets.

Currently, socket-type lamp sockets for incandescent lamps and fluorescent lamps are widely used for indoor lighting in homes, offices, and businesses, or for internal lighting such as refrigerators and microwave ovens.

On the other hand, commercially available fluorescent lamps of 25W or less have a glass tube structure of 3U tube lamps or less, 50W or less of 4U tube lamps, and 80W or more 100W, 120W or more high-power lamps It works with 4U tube lamp, 5U tube lamp, 6U tube lamp.

In addition, the general fluorescent lamp as described above has a form in which the glass tube forming the lamp is connected to one, for example, when one of the high-power lamp of 120W, a high temperature problem in the electrical circuit occurs, As a result, the electric and electronic parts, etc. are given a lot of problems in quality.

The present invention is proposed to solve the above problems of the prior art,

An object of the present invention, a predetermined number of glass tubes adjacent to each other in a plurality of glass tubes are connected to each other through a connecting member, and the plurality of glass tubes connected through the connecting member to form a plurality of pairs, the plurality of glass tubes are connected to each other However, the electrical operation is to be divided, and the case for accommodating the plurality of glass tubes, the upper side connected to the plurality of glass tubes is configured in a plurality of divided forms corresponding to the divided form of the glass tube, each of the pair By forming the guide hole for connecting the connection line drawn from both ends of the glass tube and the control circuit inside the ballast, it looks the same as the shape of a general fluorescent lamp, but divides the power supplied to the lamp by a certain ratio By dispensing at a certain ratio according to the shape of the glass tube, It does not have to stress on the components, and provide them with high-quality fluorescent lamps and a control device that has a power distribution to produce a lamp.

The present invention for achieving the above object,

A connecting member 120 for connecting the plurality of glass tubes adjacent to each other in a plurality of glass tubes so as to interlock with each other, a plurality of glass tubes 110 each having a pair of glass tubes connected through the connecting member 120, respectively; 3 'divided into 1' divided area (a), 2 'divided area (b), and 3' divided area (c) so as to be connected according to the structure of the glass tube 110, and the connection is drawn out from the glass tube. A power distribution for distributing the power supplied to the fluorescent lamp at a predetermined ratio by two or more powers by receiving the oscillation voltage output from the control device and the case 140 having a guide hole for connecting a line to a control circuit inside the ballast; A device (Power Divider) 2000 and a bulb (BULB) for supplying power to a plurality of divided fluorescent lamps to light the lamp by receiving a predetermined ratio of power output separately from the power distribution device. Property that is characterized in that on the device configurations.

A fluorescent lamp capable of power distribution according to the present invention for achieving the above object,

The plurality of glass tubes 110 has a plurality of forms in which a plurality of glass tubes adjacent to each other are connected to each other through a connecting member 120 and a predetermined number of glass tubes connected through the connecting member 120 are formed in pairs. In addition, the case 140 is configured such that an accommodating space for accommodating the plurality of glass tubes 110 is formed inward, and the arrangement of the glass tubes 110 is connected to each other two by three to divide the first division region. (A), the second divided region (B), and the third divided into the form of the divided region (C), the two glass tubes of each divided region are electrically connected to each other through the connecting member 120, divided each The regions are characterized in that their structural configuration is such that the structures are connected to each other but the electrical operation is divided.

In addition, the connection member 120 according to the present invention is configured to pass through each one of the two glass tubes between the two adjacent glass tubes, so that the two glass tubes are electrically connected to each other, the connection of each of the divided regions Two pairs of glass tubes through the member 120, one side of the glass tube is formed with a connection line 131 for connection to the (+) connection terminal of the ballast, the other side of the glass tube (-) connection Connection line 132 for connection to the terminal is formed, the connection line 131, 132 is configured to be connected to the control circuit of the ballast through the guide hole 141, 142 of the case 140 It is characterized by enemy configuration.

In addition, the case 140 according to the present invention,

It has a connection structure on the upper side corresponding to the structure of the glass tube 110, the upper side of the case 140, the first 'division region (a), the second' division region so as to be connected to correspond to the shape of the glass tube. (b) having a shape divided into 3 'divided regions (c), a guide hole 141 for connecting the (+) connection line 131 to a control circuit inside the ballast, and (-) It is characterized in that the device configuration is configured to form a guide hole 120 for connecting the connection line 132 and the control circuit inside the ballast.

In addition, the fluorescent lamp according to the present invention, the shape is arranged in a two-row arrangement or a single row of a circular, quadrilateral or triangular shape, the glass tubes are connected to each other, but the electrical operation is divided into a plurality of, the adjacent glass tube through a connecting member In connection with each other, the glass tubes between the regions are divided by each other, so that one electric power is equally distributed and distributed by the number of divided regions.

1 is a perspective view showing an embodiment of a fluorescent lamp capable of power distribution according to the present invention,

2 is a plan sectional view of a fluorescent lamp capable of power distribution according to FIG. 1;

3 is a circuit diagram showing the configuration of a ballast capable of power distribution according to the present invention,

4 is a perspective view showing another embodiment of a fluorescent lamp capable of power distribution according to the present invention,

5 is a cross-sectional view of the fluorescent lamp capable of power distribution according to FIG. 4.

<Explanation of symbols for the main parts of the drawings>

100 ..... Fluorescent Lamp

110 ..... Glass Tube

121, 122, 123, 124 ..... Connecting member

131 ..... (+) connection line

132 ..... (-) connection line

141, 142 .....

1000 ..... Control

2000 ..... Power Distribution Unit

(A), (B), (C) ..... First and second and third partitions

(a), (b), (c) ..... 1 'and 2' and 3 'partitions

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the "power distribution type fluorescent lamp and its control device" of the present invention according to the above technical concept as follows.

1 is a perspective view showing an embodiment of a power distribution capable fluorescent lamp according to the present invention, Figure 2 is a plan view showing a cross-sectional view of the power distribution fluorescent lamp according to FIG.

As shown in this, the fluorescent lamp 100 according to the present invention is composed of a plurality (6) of the glass tube 110 and the case 140 for receiving and fixing the glass tube, the plurality of glass tube 110 Silver, two glass tubes adjacent to each other are connected to each other through a connecting member 120 has a three-part divided form consisting of two pairs each, and the case 140 accommodates the plurality of glass tubes 110 inward. An accommodation space is formed.

Looking at the structure of the fluorescent lamp capable of power distribution according to the present invention configured as described in more detail as follows.

First, the fluorescent lamp 100 has an external shape and a structure having a "U" type shape of a general fluorescent lamp, but is adjacent to six glass tubes 110 as shown in FIG. 2. Two glass tubes are connected to each other in pairs, and a total of three pairs are formed. The two adjacent glass tubes each formed in the pair are connected to each other through each connection member 121, 122, and 123 on one side thereof.

That is, the fluorescent lamp 100 is divided into two by arranging the glass tubes 110 two by one, so that the shape of the first division A, the second division B, and the third division C The two glass tubes of each divided area are electrically connected to each other through the connecting member 120, and each divided area is connected to each other in structure but the electrical operation is divided.

The two glass tubes of the first partition A are electrically connected to each other through the first connecting member 121, and the two glass tubes of the second partition B are electrically connected to each other through the second connecting member 122. Are connected to each other, and the two glass tubes of the third partition C are electrically connected to each other through the third connecting member 123, and the first, second and third partitions A, B, and C are connected to each other. ) Are divided into each other.

Here, the connection members 121, 122, 123, the two glass tubes are electrically connected to each other by penetrating one side of the two glass tubes between two adjacent glass tubes, and each of the three divided The three pairs of glass tubes are connected to each other in structure but the electrical operation is divided.

In addition, the pair of two glass tubes formed in each of the divided regions through the connecting member 120, the connection line 131 for connecting to the positive connection terminal of the ballast is formed on one glass tube, the other one One side of the glass tube of the connection line (132) is formed for connection to the (-) connection terminal, the connection line 131, 132 is the control of the ballast through the guide hole 141, 142 of the case 140 Connected by a circuit.

On the other hand, the case 140 is connected to the glass tube 110, has a connection structure on the upper side corresponding to the structure of each glass tube (110).

That is, since the structure of the glass tube 110 is divided into three, the upper side surface of the case 140 may be connected to correspond to the shape of the glass tube so that the first 'divided area (a), the second' divided area (b), A guide hole 141 for connecting the (+) connection line 131 drawn out from the glass tube with a control circuit inside the ballast, having a shape divided into 3 'divided regions (c), and ( A guide hole 142 for connecting the connection line 132 to the control circuit inside the ballast is formed.

Here, referring to Figure 3 attached to the control circuit as follows.

3 is a circuit diagram showing the configuration of a ballast capable of power distribution according to the present invention.

As shown in the drawing, the photocell circuit unit 1100 includes a varistor B1 for stabilizing an AC voltage interposed between the power supply 1101 for supplying power and the both ends of the power supply 1101. ), A fuse F1 that prevents the circuit from being damaged due to a short circuit due to a short circuit when the input AC voltage is higher than the set voltage, and rectifies the DC power output from the power supply unit 1101 and outputs the DC power. Connected to the DC converter 1103 and the DC converter 1103 to reduce the resistance when exposed to bright light and increase the resistance in the dark to convert the output power of the DC converter 1103. First and second amplifying units connected to the device PC and the photoelectric device PC to compare the voltage converted to the internal resistance of the photoelectric device PC with a reference voltage, and amplify the difference voltage and output the amplified voltage. 110 5) 1107 and a thyristor (SCR) 1109 connected to the first and second amplifiers 1105 and 1107 to switch the voltage output from the first and second amplifiers 1105 and 1107. ), A bridge diode (BD) 1111 connected to the thyristor 1109 to rectify the voltage output from the thyristor 1109, and a bridge diode 1111 to supply power to the DC converter 1200. It consists of a triac (TA1) that supplies or cuts off the power supply.

The DC converter 1200 includes a bridge diode BD for rectifying the AC power supplied from the photo cell circuit unit 1100 to a DC power and smoothing capacitors C5 and C6.

In addition, the fluorescent lamp driving circuit unit 1300 is connected to the bridge diode BD and the smoothing capacitors C5 and C6 of the DC converter 1200 to generate an oscillation voltage for turning on the fluorescent lamp 100. , T2) and the oscillation coils L1, L2 and L3 connected to the power transistors T1 and T2 to generate frequencies of 25 KHz to 30 Khz according to the coil values, and output from the power transistors T1 and T2. A power divider 2000 for distributing the power supplied to the fluorescent lamp 100 at a predetermined ratio by two or more electric powers, and being separated from the power divider 2000 and outputted The first bulb BULB for supplying electric power to the glass tube of the first divided area A of the fluorescent lamp 100 divided into three sections by receiving a predetermined ratio of power, and the power distribution device 2000. Fluorescent lamp divided into 3 parts by receiving a certain ratio of power output A second bulb BULB for supplying electric power to the glass tube of the second division area B and lighting the lamp, and a predetermined ratio of electric power separated from the power distribution device 2000 and then outputted. The third bulb (BULB) for supplying power to the glass tube of the third divided region (C) of the divided fluorescent lamp 100 to turn on the lamp, and is connected between the oscillation coil (L3) and the bulb ballast A capacitor (C10) that protects the lamp and the ballast by canceling the surge voltage generated when it is connected to it, and a thermistor switch (1301) that senses the temperature inside the ballast and turns off the lamp when the detected temperature is greater than the reference temperature. It is composed of

In addition, the fluorescent lamp driving circuit unit 1300 includes a plurality of diodes D5, D6, D7, D8, and D9 that protect the power transistors T1 and T2, and an overcurrent applied to the base of the power transistor T2. The diaak (DIAC-1) which prevents it is provided.

Looking at the operation of the ballast of the power distribution system according to the present invention configured as described above are as follows.

First, the photocell circuit unit 1100 is supplied with commercial power (AC120V to AC220V), and determines whether to turn on the photoelectric device (PC) according to the amount of ambient light. If it is determined to be lit, the bridge diode BD of the DC converter 1200 and the smoothing capacitors C5 and C6 are converted to DC power, and the power transistors T1 and T2 of the fluorescent lamp driving circuit unit 1300 are turned on. The on and turn-off operation is repeated, and thus high frequency oscillation occurs through the oscillation coils L1, L2, and L3, and the lamp is turned on by the generated high frequency.

Here, the fluorescent lamp according to the present invention, the shape is arranged in a two-row arrangement or a single row of circular, quadrilateral or triangular shape, the glass tubes are connected to each other, but the electrical operation is divided (first, second, third) Partition to be operated.

For example, 120W high-power lamps cause problems in quality due to excessive electrical / electronic components and the like. This is configured to divide the operation into two or three at the time of the initial production of the lamp, through the power distribution device 2000 as described above to distribute the power equally divided by the divided number to output.

That is, by dividing into three, 40W x 3 is operated so that the sum of the outputs is 120W, so the output is 120W to 40W, so that high-quality lamps can be produced without burdening electronic components.

In other words, each of the 120W power input through the power distribution device 2000 is divided into three 40W and outputted, and the fluorescent lamp 100 is supplied from the first, second, and third bulbs, respectively. To make it light.

In addition, in the above description, the shape of the fluorescent lamp will be described with respect to a three-division structure, but the present invention may be changed according to the structure to be designed such as two-division or four-division in addition to the three-division. 4 and 5, the distribution scheme of the power distribution apparatus also has two or more multi-division schemes corresponding to the shape of the fluorescent lamp.

On the other hand, when the periphery of the photocell circuit unit 1100 is bright, the power is cut off by the DC converter 1200 or the fluorescent lamp driving circuit unit 1300, and the light is not turned on. Turn on Triac (TA1).

The optoelectronic device PC inputs a voltage higher than a reference voltage to the first and second amplifiers P1 and P2 of the first and second amplifiers 1105 and 1107.

The first and second amplifiers P1 and P2 compare the input voltage with a reference voltage, amplify the difference voltage to a predetermined level, and output the same to the gate of the thyristor SCR 1109. Here, the capacitor C2 of the second amplifier P2 prevents the lamp from being turned off when the lamp is turned on and the surroundings are momentarily brightened.

In addition, the thyristor 1109 performs a switching operation according to the voltage applied to the gate to control the operation of the bridge diode 1111.

In addition, the DC conversion unit 1103 of the photocell circuit unit 1100 receives power output from the power supply unit 1101 and smoothes the DC power to the first and second amplifiers 1105 and 1107 and other circuits. To supply.

Meanwhile, the AC voltage input to the DC converter 1200 is rectified by the bridge diode BD and the smoothing capacitors C5 and C6 to DC power.

The DC converter 1200 supplies the voltage rectified by the DC power through the resistor R11, the diode D5, the capacitor C7, and the DIAC-1 of the fluorescent lamp driving circuit unit 1300. Output to transistors T1 and T2.

Particularly, the power transistors T1 and T2 oscillate at frequencies of 25 kHz to 30 kHz according to the values of the oscillation coils L1, L2, and L3 connected to the base, and the oscillation voltages are CT coils, first and second and The high voltage is instantaneously supplied to both ends of the divided lamps through the capacitors C9, C10, and C11 of the third bulb BULB.

In addition, the capacitor C12 connected between the oscillation coil L3 and the bulb cancels the surge voltage generated when the lamp is connected to the ballast to eliminate flicker of the lamp.

The thermistor switch 1301 detects the temperature inside the ballast and turns off the lamp by shutting off the power of the fluorescent lamp driving circuit unit 1300 when the detected temperature is greater than the set temperature.

4 is a view showing a perspective view of another embodiment of a power distribution capable fluorescent lamp according to the present invention, Figure 5 is a plan view showing a cross-sectional view of the power distribution fluorescent lamp according to FIG.

As shown in this, the fluorescent lamp 100 according to the present invention is composed of a plurality (6) of the glass tube 110 and the case 140 for receiving and fixing the glass tube, the plurality of glass tube 110 Silver, three glass tubes adjacent to each other are connected to each other through a connecting member 120 has a divided form consisting of a pair of three each, and the case 140 accommodates the plurality of glass tubes 110 inward. An accommodation space is formed.

Looking at the structure of the fluorescent lamp capable of power distribution according to the present invention configured as described in more detail as follows.

First, the fluorescent lamp 100 has an external shape and a structure having a "U" type shape of a general fluorescent lamp, but adjacent to six glass tubes 110 as shown in FIG. 4. Three glass tubes are connected to each other in pairs, and a total of two pairs are formed, and the three adjacent glass tubes each of the pairs are connected to each other through respective connecting members 121, 122, 123, and 124 on one side thereof. do.

That is, the fluorescent lamp 100 is divided into two, each of the glass tube 110 is connected to each other divided into a first divided area (A), a second divided area (B) in the form, each divided area The three glass tubes of are electrically connected to each other through the connecting member 120, each of the divided regions are connected to each other in the structure but the electrical operation is divided.

The three glass tubes of the first partition A are electrically connected to each other through the first and second connecting members 121 and 122, and the three glass tubes of the second partition B are third and fourth. The first and second divided regions A and B are electrically connected to each other through connecting members 123 and 124.

Here, the connecting members 121, 122, 123, 124, the three glass tubes are electrically connected to each other by penetrating one side of the three glass tubes between the adjacent three glass tubes, and further divided into two Each of the two pairs of glass tubes is connected to each other in structure but the electrical operation is divided.

In addition, three pairs of glass tubes each paired through the connection member 120 in each of the divided regions, one side of the glass tube is formed with a connection line 131 for connection to the (+) connection terminal of the ballast, the other One side of the glass tube of the connection line (132) is formed for connection to the (-) connection terminal, the connection line 131, 132 is the control of the ballast through the guide hole 141, 142 of the case 140 Connected by a circuit.

On the other hand, the case 140 is connected to the glass tube 110, has a connection structure on the upper side corresponding to the structure of each glass tube (110).

That is, since the structure of the glass tube 110 is divided into two, the upper surface of the case 140 may be divided into the first 'divided area (a) and the second' divided area (b) so as to be connected corresponding to the shape of the glass tube. It has a split form, and its structure is a guide hole 141 for connecting the (+) connection line 131 with the control circuit inside the ballast, and the (-) connection line 132 is controlled inside the ballast. Guide holes 142 for connection with the circuit are formed.

As described above, the fluorescent lamp according to the present invention is arranged in a two-row arrangement or a one-row arrangement of circular, quadrilateral, or triangular forms, and the glass tubes are connected to each other, but the electrical operation is divided (first and second divisions). Area) to operate.

For example, when the lamp is initially manufactured, it is configured to divide into two or three pieces, and as described above, adjacent glass tubes are connected through a connecting member, and the glass tubes between the regions are divided by one, so that one electric power is equalized by the number of divided regions. To be distributed and supplied.

That is, by dividing into two, 60W x 2 is operated so that the sum of the outputs is 120W, so that the output is 120W to 60W, so that it is possible to produce high quality lamps without burdening electronic components.

In other words, a certain number of glass tubes are connected to each other through the connecting member, and the glass tubes that are not connected to each other are divided so as to distribute 120W of power into two by 60W so that the fluorescent lamps are turned on.

As described above, the present invention can be designed in various forms according to the structure to be designed, such as two divisions or four divisions in addition to the three divisions.

As described above, in the detailed description of the present invention, a specific embodiment of a fluorescent lamp capable of power distribution will be described. However, the present invention may be modified in various ways without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the embodiments described, but should be defined by the equivalents of the utility model registration claims described below and equivalents of the utility model registration claims.

According to the above-described invention "power distribution type fluorescent lamp and its control device",

A certain number of glass tubes adjacent to each other in the plurality of glass tubes are connected to each other through a connecting member, and the glass tube connected through the connecting member is divided into a plurality of pairs to form a shape, the plurality of glass tubes are connected to each other, but the electrical operation is divided In addition, the case for accommodating the plurality of glass tubes, the upper side connected to the plurality of glass tubes in the form of a plurality of forms corresponding to the divided form of the glass tube, each of the pair of both end glass tube Guide holes for connecting the drawn-out connection line to the control circuit inside the ballast are formed, and the shape is identical to that of a general fluorescent lamp, but the power supplied to the lamp corresponds to the shape of a glass tube divided by a predetermined ratio. By distributing it at a certain ratio so that the electronic parts are unreasonable. Do, and have the advantage of being able to produce high-quality light through it.

Appearance is the same as the shape of a general fluorescent lamp, it has the advantage that can be used to distribute the power supplied to the lamp at a constant ratio.

In addition, as described above, the shape of the present invention is arranged in two rows or one row in a circle, a quadrilateral, or a triangular shape, and the glass tubes are connected to each other, but the electrical operation is to operate by dividing, to produce a high quality lamp Has

Claims (8)

In the ballast comprising a plurality of glass tubes, a fluorescent lamp and a control device including a case for receiving and fixing the glass tube, A connection member 120 connecting the plurality of glass tubes adjacent to each other in the plurality of glass tubes so as to interlock with each other; A plurality of glass tubes 110 each divided into a plurality of glass tubes connected through the connection member 120; 3 'divided into 1' divided area (a), 2 'divided area (b), and 3' divided area (c) so as to be connected according to the structure of the glass tube 110, and the connection is drawn out from the glass tube. A case 140 formed with a guide hole for connecting the line to the control circuit inside the ballast; A power divider 2000 that receives the oscillation voltage output from the control device and distributes the power supplied to the fluorescent lamp at a predetermined ratio to two or more electric powers; A power distribution type fluorescent lamp comprising a bulb (BULB) configured to light a lamp by supplying power to a plurality of divided fluorescent lamps by receiving a predetermined ratio of power output from the power distribution device. Control unit. The method of claim 1, wherein the glass tube, The arrangement of the glass tubes is connected to each other, divided into three and divided into three types of first divided regions (A), second divided regions (B), and third divided regions (C), and a plurality of glass tubes of each divided region. Are electrically connected to each other through the connecting member, and the divided regions are connected to each other in structure but electrical operation is divided. The method according to claim 1 or 2, The two glass tubes of the first partition A are electrically connected to each other through the first connecting member 121, and the two glass tubes of the second partition B are electrically connected to each other through the second connecting member 122. Are connected to each other, and the two glass tubes of the third partition C are electrically connected to each other through the third connecting member 123, and the first, second and third partitions A, B, and C are connected to each other. And each of the electrical operation is divided into a fluorescent lamp of the power distribution method and its control device. The method of claim 1, Each of the plurality of glass tubes made up of a pair through the connection member 120 of each divided region, one connection line 131 for connecting to the positive connection terminal of the ballast is formed on one glass tube, the other One side of the glass tube is formed with a connection line 132 for connection to the (-) connection terminal, the connection line 131, 132 is the control circuit of the ballast through the guide hole 141, 142 of the case 140 Power distribution fluorescent lamp and its control device, characterized in that connected to. The method of claim 1, wherein the case 140, Guide hole 141 for connecting the (+) connection line 131 with the control circuit inside the ballast, and guide hole 120 for connecting the (-) connection line 132 with the control circuit inside the ballast. The fluorescent lamp of the power distribution method and its control apparatus characterized in that it is formed. The glass tube of claim 1, wherein 2 rows or 1 row of circular, quadrilateral, or triangular shapes are arranged, and a plurality of adjacent glass tubes are connected through a connecting member, and the glass tubes between the regions are divided with each other so that one electric power is equally divided by the number of divided regions. A power distribution type fluorescent lamp and its control device to be distributed and supplied. The method of claim 1, wherein the bulb BULB, The first bulb BULB for turning on the lamp by supplying electric power to the glass tube of the first divided area A among the CF lamps L, which are divided and output from the power splitter 400, to be output. )Wow; The second bulb BULB which turns on the lamp by supplying electric power to the glass tube of the second divided area B of the CF lamp L divided into three sections by receiving the power of a predetermined ratio separated and output from the power splitter 400. )Wow; The third bulb BULB to turn on the lamp by supplying power to the glass tube of the third divided region (C) of the CF lamp (L) divided by the power splitter 400 to output a certain ratio of power output from the splitter (400) Power distribution type fluorescent lamp and its control device comprising a). The method of claim 1, A power distribution method comprising: distributing 120W of power input through the power distribution device into three 40W outputs, respectively, and lighting the fluorescent lamps by being supplied from the first, second, and third bulbs, respectively. Fluorescent lamps and controls thereof.