KR100561447B1 - Voltage applying apparatus for a printer - Google Patents

Abstract

Disclosed is a voltage application device of a printing press for applying a voltage to a developing roller of a printing press and a charging wire and a grid of a charger. The apparatus for applying a voltage of the disclosed printer is provided to elevate together with each of the developing roller, the charging wire and the grid, and one end thereof has a plurality of lifting electrodes connected to each of the developing roller, the charging wire, and the grid, and one end of the printing machine. A plurality of fixed electrodes fixed to the main frame of the printer so as to be connected to respective power supplies and the other end of which is positioned at a predetermined interval apart from each other of the other end of the elevating electrode, and the other end of each of the elevating electrodes It is provided between the other end of each of the electrodes provided with a plurality of electrode connecting springs to connect the other end of each of the lifting electrode and the other end of each of the fixed electrode when the developing roller, the charging wire and the grid, respectively It features. Here, the electrode connection spring is a compression coil spring, the upper end is fixed to the bottom of the other end of each of the fixed electrode, the lower end is the other end of each of the elevating electrode when the developing roller, the charging wire and the grid respectively rise It is preferable to be in contact with the upper surface. Therefore, even if there is an influence of disturbance, the compression coil spring enables the voltage to be applied to the developing roller, the charging wire, and the grid more stably.

Description

Voltage applying apparatus for a printer

1 is a view showing a schematic structure of a conventional printing press,

2 is a perspective view showing a voltage applying device of a printing press according to the present invention;

3 is an exploded perspective view illustrating a coupling structure of the first fixed electrode and the first fixed block shown in FIG. 2;

4 is an exploded perspective view illustrating a coupling structure of the second and third lifting electrodes shown in FIG. 2 and the second lifting blocks;

5 is an exploded perspective view illustrating a coupling structure of the second and third fixed electrodes and the second fixed block illustrated in FIG. 2;

6a and 6b are views for explaining the connection and separation operation of the first elevating electrode and the first fixed electrode according to the lifting of the developing roller.

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

10 ... photosensitive belt 40 ... development
41 ... developing roller 42 ... squeeze roller
44 ... Bearings

45 ... developing roller support block 50 ... developing frame

70 ... Daejeon 71 ... Daejeon Wire

72 grid 73 charging block

110,210,310 ... first, second, third lifting electrodes

120,220,320 ... first, second, third fixed electrode

130,230,330 ... Spring for first, second and third electrode connection

140,240,340 ... Spring for first, second and third power connection

150,250,350 ... first, second, third contact plate

160,260 ... 1st, 2nd lifting blocks 170,270 ... 1st, 2nd fixed blocks

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voltage applying device of a printing press. More particularly, the present invention relates to a developing roller and a voltage applying device of a printing press that can stably apply voltage to a charger.

Generally, a printer such as a printer or a copier forms a latent electrostatic image on a photosensitive medium such as a photosensitive drum or a photosensitive belt, develops the electrostatic latent image with a toner having a predetermined color, and transfers the image onto a recording sheet to produce a desired image. It is a device to get. The printer is roughly classified into wet and dry according to the toner used. In the wet type, a developer in which a toner is mixed with a volatile liquid carrier is used. Wet printing machines using such a developer have better print quality than the dry method using a powdered toner, and can prevent damage caused by harmful toner dust, and the use thereof is gradually increasing.

1 is a view showing a schematic structure of a conventional printing press.

As shown, the conventional printing machine of the photosensitive belt 10 of the endless track, the drive roller 21, the backup roller 22 and the tension roller 23 for rotating the photosensitive belt 10 in a given path It has three rollers.

In addition, a main charging unit 60 is provided adjacent to one side of the photosensitive belt 10 to uniformly charge the surface of the photosensitive belt 10 to a predetermined potential (for example, 650 V), and the lower portion of the photosensitive belt 10 is provided. A laser scanning unit (LSU) 30 for irradiating a laser beam to the photosensitive belt 10 to form an electrostatic latent image according to an image signal, and a developer comprising a toner having a predetermined color in a region where the electrostatic latent image is formed and a liquid carrier The developing device 40 which adheres and develops is provided.

As described above, the developing solution attached to the photosensitive belt 10 by the developing unit 40 is dried by the dry roller 81 and the heat roller 82 provided after the developing unit 40, and thus the electrostatic latent image of the photosensitive belt 10 is applied. A toner image remaining only toner is formed. The toner image is transferred to the recording paper 93 by a transfer roller 91 provided in parallel with the backup roller 22 with the photosensitive belt 10 interposed therebetween. The recording paper 93 is supplied between the transfer roller 91 and a fixing roller 92 provided in parallel with a predetermined distance therebetween, and the toner transferred to the recording paper 93 is fixed to the fixing roller 92. Is heated and pressurized and fixed to the recording paper to form a desired image.

On the other hand, in the case of a color printer, four LSUs 30 and four developing units 40 of Y, M, C, and K, which separately contain a developer having a plurality of colors, for the combination of colors, and the above, respectively. After the development is completed in the developing device 40, four chargers 70 are provided to charge the surface of the photosensitive belt 10 to a uniform potential again. In addition, the four developing units 40 and the four charging units 70 are installed and supported together in the developing frame 50. The developer frame 50 is installed to be detachable inside the main body of the printer so that the developer 40 and the charger 70 can be replaced or repaired.

Each of the four developing units 40 includes a developing roller 41 for attaching a developer to the electrostatic latent image region of the photosensitive belt 10, and a squeeze roller 42 for removing a liquid carrier from the developer attached to the photosensitive belt 10. ) Is installed. The developing roller 41 has a voltage of approximately 450 V (hereinafter referred to as a first voltage) for charging the developer so that the developer can be attached to the surface of the photosensitive belt 10 charged at a predetermined potential (for example, 650 V). Is applied.

The charger 70 is installed to be adjacent to the surface of the photosensitive belt 10, the charging wire 71 is discharged by receiving a voltage from a power source, and surrounds and supports the charging wire 71 to discharge The grid 72 which functions to sustain smoothly is provided. A high voltage of about 5.5 kV (hereinafter referred to as a second voltage) is applied to the charging wire 71, and a potential for charging the photosensitive belt 10 to the grid 72, for example, a voltage of 650 V ( (Hereinafter referred to as a third voltage) is applied.

As described above, in the conventional printing press, different voltages are applied to the charging wires 71 and the grids 72 of the developing roller 41 and the charger 70, and thus the developing roller 41 and the charging wire are applied. A voltage application device for applying a voltage by connecting the power supply installed inside the main body of the printer 71 and the grid 72 is provided.

However, the developing roller 41 and the charger 70 are raised to be adjacent to the photosensitive belt 10 during the printing operation of the printing press, and lowered to be spaced apart from the photosensitive belt 10 by a predetermined interval when the printing is stopped. Therefore, the voltage application device needs to apply a voltage to each of the developing roller 41 and the charger 70 only when they rise. In addition, the contact between the developing roller 41, the charging wire 71 and the grid 72 and the power source may be deteriorated due to the influence of disturbance such as vibration or external impact of the printing press. The problem of instability can arise.

The present invention has been made to solve the above problems of the prior art, in particular, a voltage applying device of a printing machine employing a compression coil spring to more stably apply voltage to a developing roller and a charger moving up and down in a printing press. The purpose is to provide.

In order to achieve the above object, the apparatus for applying a voltage of a printing machine according to the present invention may apply different voltages to a developing roller of a developing machine, a charging wire of a developing machine, and a charging wire and a grid of the developing machine, which are supported to be liftable by a developing frame provided in a main frame of the printing machine. An apparatus for applying a voltage of a printer for applying, comprising: a plurality of elevating electrodes provided to elevate together with each of the developing roller, a charging wire, and a grid, and having one end connected to each of the developing roller, a charging wire, and a grid; A plurality of fixed electrodes, one end of which is connected to a power source provided in the main body of the printer, and the other end of which is fixed to the main frame of the printer so as to be spaced apart from each other by a predetermined interval on the other end of the lifting electrode; And the other end of each of the lifting electrodes and the other end of each of the fixed electrodes, connecting the other end of each of the lifting electrodes to the other end of each of the fixed electrodes when the developing roller, the charging wire, and the grid are raised. It is characterized in that it comprises a; a plurality of springs for the electrode connection.

Here, the electrode connection spring is a compression coil spring, the upper end is fixed to the bottom of the other end of each of the fixed electrode, the lower end is the other end of each of the elevating electrode when the developing roller, the charging wire and the grid respectively rise It is preferable to be in contact with the upper surface.

Therefore, even if there is an influence of disturbance, it is possible to apply voltage to the developing roller and the charger more stably by the compression coil spring.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the voltage applying device of the printer according to the present invention.

2 is a perspective view showing a voltage application device of the printing press according to the present invention.

As shown in FIG. 2, the voltage applying device of the printing machine according to the present invention includes a developing roller 41 and a charger 70 of a developing device installed to be elevated on a developing frame (not shown) installed in the main frame of the printing machine. A device for applying different voltages to the charging wires 71 and the grids 72, respectively, including elevating electrodes 110, 210, and 310, fixed electrodes 120, 220, and 320, and a spring 130 for electrode connection. , 230 and 330.

The developing roller 41 is installed in the developing machine of the printing press, and serves to attach the developing solution to the electrostatic latent image area of the photosensitive belt. A first voltage (for example, 450 V) is applied to the developing roller 41 to charge the developer. Then, the developing roller 41 is supported by the developing roller support block 45 installed so as to be elevated in the developing frame (not shown), and is raised and lowered together with the developing roller support block 45. That is, a bearing 44 is installed on the developing roller support block 45, and the rotating shaft 43 of the developing roller 41 is rotatably coupled to the bearing 44.

The charger 70 is installed to be adjacent to the surface of the photosensitive belt, and surrounds and supports the charging wire 71 which discharges by receiving a voltage from a power source, and surrounds and supports the charging wire 71 and sustains the discharge smoothly. It has a grid (72) that performs a function to make, and is supported by the charger support block (73). A second voltage (a high voltage of about 5.5 mA) is applied to the charging wire 71, and a third voltage (eg, 650 V) is applied to the grid 72. And, the charger support block 73 is installed in the developing frame so as to be lifted by the lifting means not shown.

In this way, a first voltage is applied to the developing roller 41 among the voltage applying devices for applying a voltage to the developing roller 41, the charging wire 71, and the grid 72, which are installed to be elevated on the developing frame. The voltage application device will be described first.

The voltage applying device for applying the first voltage to the developing roller 41 includes a first elevating electrode 110, a first fixed electrode 120, and a first electrode connecting spring 130.

The first lifting electrode 110 is installed to move up and down together with the developing roller 41. To this end, a first elevating block 160 for supporting the first elevating electrode 110 is provided on an outer side of the developing roller support block 45, and a predetermined portion of the first elevating block 160 is provided on the first elevating block 160. 1 protruding electrode fixing pin 161 for fixing the elevating electrode 110 to a predetermined position. Therefore, since the first lifting electrode 110 is seated and supported by the first lifting block 160, the first lifting electrode 110 can move up and down together with the developing roller 41. In addition, one end of the first elevating electrode 110 to connect the first elevating electrode 110 with one end of the developing roller 41 so that a first voltage may be applied to the developing roller 41. A voltage applying spring 112 is provided between the portion and the outer ring of the bearing 44 that supports the rotating shaft 43 of the developing roller 41. At this time, the bearing 44 should be made of a metal material through which current can flow. As such, since the voltage applying spring 112 that acts as a buffer between the first elevating electrode 110 and the bearing 44 is provided, the developing roller 41 may be affected by disturbance such as vibration or external shock. The voltage can be applied stably.

The first fixed electrode 120 is installed inside the first fixing block 170 fixed to the main frame (not shown) of the printer. A first power connection spring 140 is installed at one end of the first fixed electrode 120, and the first power connection spring 140 is fixed to a power source provided in the main body of the printer. Contact 150. The other end of the first fixed electrode 120 is positioned above the other end of the first lifting electrode 110 at a predetermined interval apart. As such, the first power supply connection spring 140 that acts as a buffer between the first fixed electrode 120 and the power source is installed, so that the first fixed electrode 120 and the power source are not affected by disturbance. The connection can be kept stable.

The first electrode connecting spring 130 is installed between the other end of the first lifting electrode 110 and the other end of the first fixed electrode 120, and the first roller when the developing roller 41 is raised. The other end of the first elevating electrode 110 and the other end of the first fixed electrode 120 serves to connect. That is, the upper end of the first electrode connection spring 130 is fixedly installed on the bottom of the other end of the first fixed electrode 120, the lower end of the first lifting electrode when the developing roller 41 is lowered The other end of the 110 is separated from the predetermined interval and when the developing roller 41 is raised so as to contact the upper surface of the other end of the first elevating electrode 110 so that a voltage can be applied to the developing roller 41 from the power source. do. It is preferable to use a compression coil spring as the spring for the first electrode connection 130 to play such a role.

A coupling structure of the first fixed electrode 120 and the first fixed block 170 will be described in detail with reference to FIG. 3.

Referring to FIG. 3, the first fixing block 170 of FIG. 2 is formed by combining a first fixing block base 171 and a first fixing block cap 172. The locking jaw 176 is protruded from the side of the first fixed block base 171 for these coupling, and the locking hook is caught on the locking jaw 176 at the side of the first fixed block cap 172. 177). In addition, a predetermined portion of the first fixed block base 171 is formed to protrude an electrode fixing pin 173 for fixing the first fixed electrode 120 at a predetermined position, and one end of the screw 141 will be described later. Is provided with a screw fastening hole 174 to be fastened.

The first fixed electrode 120 is coupled to the first fixed block base 171. To this end, the first fixed electrode 120 is provided with a fixing pin insertion hole 123 into which the electrode fixing pin 173 is fitted. In addition, a screw insertion hole 124 into which a screw 141 to be described later is inserted is provided at one end of the first fixed electrode 120, and an upper end of the first electrode connection spring 130 is provided at the bottom of the other end. A spring engaging protrusion 121 to be fitted is provided.

One end of the first fixing block cap 172 is provided with a spring insertion hole 175 into which the first power connection spring 140 is inserted. The first power connection spring 140 is inserted into the spring insertion hole 175 and fastened to be fixed to one end of the first fixed electrode 120 by a screw 141.

Hereinafter, referring to FIG. 2 again, a voltage applying device for applying a voltage to the charging wire 71 and the grid 72 of the charger 70 will be described.

The voltage applying device for applying the second voltage and the third voltage to the charging wire 71 and the grid 72, respectively, includes second and third lifting electrodes 210 and 310, and second and third fixed electrodes. 220 and 320, and second and third electrode connection springs 230 and 330.

The second elevating electrode 210 and the third elevating electrode 310 are installed to be elevated together with the charger 70. To this end, a second lifting block 260 is provided at one end of the charger 70 to support the second lifting electrode 210 and the third lifting electrode 310. Here, the second elevating electrode 210 is inserted into the second elevating block 260, one end thereof is connected to the charging wire 71, the third elevating electrode 310 is the second It is coupled to the upper portion of the elevating block 260 and one end thereof is connected to the grid (72).

The second fixed electrode 220 and the third fixed electrode 320 are installed in the second fixing block 270 fixedly installed on the main frame (not shown) of the printer. One end of each of the second fixed electrode 220 and the third fixed electrode 320 is provided with a second and third power connection spring 240, respectively, and the second and third power connection spring 240. , 340 is in contact with the second and third contact plates 250 and 350 which are fixed to the power source provided in the main body of the printer. In addition, the other ends of the second fixed electrode 220 and the third fixed electrode 320 may be positioned apart from each other on the other end of each of the second and third lifting electrodes 210 and 310. As such, the second and third power connection springs 240 and 340, which respectively act as a buffer between the second and third fixed electrodes 220 and 320 and the power source, are respectively installed, so that the second and third fixed electrodes 220 and 320 may be disturbed. The connection between the second and third fixed electrodes 220 and 320 and the power source may be stably maintained.

The second electrode connection spring 230 is installed such that an upper end thereof is fixed to a bottom surface of the other end of the second fixed electrode 220. The lower end of the second electrode connection spring 230 is separated from the other end of the second elevating electrode 210 by a predetermined interval when the charger 70 descends, and when the charger 70 is raised. The second lifting electrode 210 is installed to be in contact with the other end of the upper surface. Therefore, when the charger 70 is raised, the second voltage may be applied to the charging wire 71 from the power supply through the second electrode connection spring 230. On the other hand, the third electrode connection spring 330 is installed so that the upper end is fixed to the bottom of the other end of the third fixed electrode (320). The lower end of the third electrode connection spring 330 is separated from the other end of the third elevating electrode 310 by a predetermined interval when the charger 70 descends, and when the charger 70 is raised. The third elevating electrode 310 is installed to be in contact with the other end of the upper surface. Therefore, when the charger 70 is raised, the third voltage may be applied to the grid 72 from the power supply through the third electrode connection spring 330. As the second and third electrode connection springs 230 and 330 which play such a role, it is preferable to use a compression coil spring.

4 is an exploded perspective view illustrating a coupling structure of the second and third lifting electrodes 210 and 310 and the second lifting block 260 shown in FIG. 2.

Referring to FIG. 4, the second elevating block 260 of FIG. 2 is formed by combining a second elevating block base 261 and a second elevating block cap 262. The second lifting block base 261 is fixedly installed at one end of the charger support block 73. In addition, an electrode fixing pin 263 for fixing the second elevating electrode 210 to a predetermined position is formed on a predetermined portion of an upper surface of the second elevating block base 261.

The second lifting electrode 210 is coupled to an upper portion of the second fixed block base 261. To this end, the second lifting electrode 210 is provided with a fixing pin insertion hole 213 into which the electrode fixing pin 263 is fitted. The charging wire 71 is connected to the protrusion 214 formed at one end of the second elevating electrode 210.

The second elevating block cap 262 is coupled to an upper portion of the second elevating block base 261 after the second elevating electrode 210 is coupled. Engagement projections 76 and 266 are protruded from the side of the charger support block 73 and the side of the second elevating block base 261 for these coupling, and the side of the second elevating block cap 262. There is provided a locking ring 267 to be caught by the locking jaw (76, 266). In addition, an electrode fixing pin 264 for fixing the third elevating electrode 310 to a predetermined position is formed on a predetermined portion of the upper surface of the second elevating block cap 262.

The third lifting electrode 310 is connected to one end of the grid 72 to be integrally formed with the grid 72, and is coupled to an upper portion of the second lifting block cap 262. To this end, the third lifting electrode 310 is provided with a fixing pin insertion hole 313 to which the electrode fixing pin 264 is fitted. A locking groove 74 is formed at a side surface of the grid 72, and a locking jaw 75 is inserted into the locking groove 74 at the side of the charger support block 73.

As described above, the second lifting block 260 of FIG. 2 supports and lifts the second lifting electrode 210 and the third lifting electrode 310 at the same time.

5 is an exploded perspective view illustrating a coupling structure of the second and third fixed electrodes 220 and 320 and the second fixed block 270 shown in FIG. 2.

Referring to FIG. 5, the second fixed block 270 of FIG. 2 is formed by combining a second fixed block base 271 and a second fixed block cap 272. A locking hook 276 is formed on one side of the second fixing block base 271 to protrude, and the locking hook is caught on the locking jaw 276 on one side of the second fixing block cap 272. 277 is provided. In addition, electrode fixing pins 273 and 373 for fixing the second fixed electrode 220 and the third fixed electrode 320 to a predetermined position are formed at a predetermined portion of the second fixed block base 271. Both ends thereof are provided with screw fastening holes 274 and 374 to which screws 241 and 341 which will be described later are fastened. In addition, a separation wall 278 is formed on the second fixed block base 271 to prevent contact between the second fixed electrode 220 and the third fixed electrode 320.

The second fixed electrode 220 and the third fixed electrode 320 are coupled to the second fixed block base 271. To this end, fixing pin insertion holes 223 and 323 into which the electrode fixing pins 273 and 373 are fitted are provided in the second and third fixed electrodes 220 and 320, respectively. One end of each of the second and third fixed electrodes 220 and 320 is provided with screw insertion holes 224 and 324 into which screws 241 and 341 which will be described later are inserted, and the bottom of each other end of the second and third fixed electrodes 220 and 320. Spring coupling protrusions 221 and 321 to which upper ends of the second and third electrode connection springs 230 and 330 are fitted are respectively provided.

Spring insertion holes 275 and 375 into which the second and third power connection springs 240 and 340 are inserted are provided at both sides of the second fixing block cap 272, respectively. The second and third power connection springs 240 and 340 are inserted into the spring insertion holes 275 and 375, respectively, so that the second and third fixed electrodes 220 and 320 are formed by screws 241 and 341. It is fastened to be respectively fixed to one end of the.

6A and 6B are views for explaining the connection and disconnection operation of the first elevating electrode and the first fixed electrode according to the raising and lowering of the developing roller, and FIG. 6A illustrates a state in which the developing roller is lowered so that no voltage is applied. 6B illustrates a state in which a developing roller is raised to apply a voltage.

First, referring to FIG. 6A, the developing roller 41 is lowered to be spaced apart from the photosensitive belt 10 by a predetermined interval when printing of the printing press is stopped. Accordingly, the developing roller support block 45, the first lifting block 160, and the first lifting electrode 110 are also lowered together. On the other hand, since the first fixed electrode 120 is installed inside the first fixed block 170 fixedly installed on the main frame 20 of the printer, the first fixed electrode 120 maintains a constant position without falling. Therefore, the first electrode connecting spring 130 fixedly installed at the other end of the first fixed electrode 120 and the other end of the first elevating electrode 110 are spaced apart from each other by a predetermined interval. Meanwhile, the first power connection spring 140 connected to one end of the first fixed electrode 120 is in contact with the first contact plate 150, and the first contact plate 150 is a printer. It is installed on the circuit board 25 provided in the main body and is connected to a power source for applying a first voltage. In this state, the first voltage is not applied to the developing roller 41.

Next, referring to FIG. 6B, the developing roller 41 is raised to be adjacent to the photosensitive belt 10 during the printing operation of the printing press. Accordingly, the developing roller support block 45, the first lifting block 160, and the first lifting electrode 110 also rise together. On the other hand, the first fixed electrode 120 does not rise but maintains a constant position. Therefore, the first electrode connection spring 130 is in contact with the rising first lifting electrode 110 is compressed to a predetermined length. On the other hand, the first power connection spring 140 is maintained in contact with the first contact plate 150. As such, when the developing roller 41 is raised, the first elevating electrode 110 and the first fixed electrode 120 are connected by the first electrode connecting spring 130. The first voltage is applied from the power supply. In addition, even if there is an influence of disturbance in the state where the first elevating electrode 110 and the first fixed electrode 120 are connected, the connection state is stably maintained by the elastic force of the first electrode connection spring 130. Therefore, the voltage can be applied to the developing roller 41 more stably.

Meanwhile, a connection and disconnection operation of the second and third lifting electrodes and the second and third fixed electrodes installed to apply a voltage to the charging wire and the grid of the charger, the first lifting electrode and the first fixed electrode, respectively. For example, as described above. In addition, when a plurality of developing rollers and a plurality of chargers are provided, such as a color printer, a voltage application device according to the present invention is applied to each of the developing rollers and the chargers.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

As described above, the apparatus for applying a voltage of the printer according to the present invention includes: a developing roller moving up and down, a lifting electrode connected to a charging wire and a grid, and a fixed electrode connected to each power source provided in the printer main body; Compression coil spring for connecting the electrode interposed between the lifting electrode and the fixed electrode is provided. Therefore, even if there is an influence of disturbance such as vibration of the printer or external shock, the connection between the elevating electrode and the fixed electrode is stably maintained by the elastic force of the compression coil spring for connecting the electrode, so that it is more stable to the developing roller, the charging wire, and the grid. There is an effect that can be applied to the voltage.

Claims (6)

In a voltage applying device of a printing press for applying different voltages to a developing roller of a developing machine, a charging wire of a charger, and a grid, respectively supported by a developing frame installed in a main frame of a printing machine: A plurality of elevating electrodes provided to elevate together with the developing roller, the charging wire and the grid, and one end thereof connected to each of the developing roller, the charging wire and the grid; A plurality of fixed electrodes, one end of which is connected to a power source provided in the main body of the printer, and the other end of which is fixed to the main frame of the printer so as to be spaced apart from each other by a predetermined interval on the other end of the lifting electrode; And It is installed between the other end of each of the lifting electrodes and the other end of each of the fixed electrodes, so as to connect the other end of each of the lifting electrodes and the other end of each of the fixed electrodes when the developing roller, the charging wire and the grid respectively rise. A plurality of electrode connection springs; The elevating electrode connected to the developing roller is coupled to and supported by a first elevating block provided on the side of the developing roller support block supporting the developing roller, and the elevating electrode connected to the charging wire and the grid supports the charger. The voltage applying device of the printing machine, characterized in that coupled to the second lifting block provided on one end of the charger support block. The method of claim 1, The electrode connecting spring is a compression coil spring, the upper end of which is fixed to the bottom of the other end of each of the fixed electrodes, and the lower end of the spring to the upper end of each of the lifting electrodes when the developing roller, the charging wire and the grid are raised. Device for applying a voltage to a printer, characterized in that it is intended to be used. The method according to claim 1 or 2, The voltage applying spring is installed between one end of the elevating electrode connected to the developing roller and the outer ring of the bearing supporting the rotating shaft of the developing roller, so that the voltage is applied to the developing roller through the voltage applying spring. The voltage application device of the printing press characterized by the above-mentioned. The method according to claim 1 or 2, One end of each of the fixed electrodes is provided with a spring for power connection, and a contact plate is fixedly installed at each power source provided in the main body of the printer, thereby contacting each of the fixed electrodes by contact of the power connection spring and the contact plate. Apparatus for applying a voltage of the printer, characterized in that the power supply is connected. delete The method according to claim 1 or 2, The fixed electrode for applying a voltage to the developing roller is installed inside the first fixed block fixedly installed on the main frame of the printing press, and the fixed electrode for applying voltage to the charging wire and the grid is the main of the printing press. The voltage application device of the printing press, characterized in that is installed together inside the second fixed block fixed to the frame.

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