JP5373685B2 - Surface treatment equipment - Google Patents

Description

  The present invention relates to a surface treatment apparatus, and is suitable for application to, for example, a surface treatment apparatus that performs surface treatment of an object to be processed by electric discharge. Here, the surface treatment includes improving wettability at the time of printing on a film or the like or improving adhesion at the time of applying an adhesive to a seal.

  2. Description of the Related Art Conventionally, surface treatment apparatuses that modify the surface of an object to be processed such as a film using a discharge phenomenon such as corona discharge or atmospheric plasma are known. This type of surface treatment apparatus is configured to generate corona discharge between a long discharge electrode held in a discharge section and an earth roll, and an earth roll so as to cross the film with the discharge electrode. The film can be transported up and modified by irradiating the surface of the film with corona discharge.

  For example, as a surface treatment apparatus of this type, Japanese Patent Application No. 2008-289274 (Patent Document 1) discloses a surface treatment apparatus in which a duct is provided in a discharge portion in order to discharge ozone generated in the discharge portion. Yes. In practice, this surface treatment apparatus is provided with an exhaust fan, and ozone generated in the discharge part by the exhaust fan can be discharged to the ozone treatment apparatus through the duct together with the air in the discharge part. Yes.

Japanese Patent Application No. 2008-289274

  By the way, dusting powder is sprinkled on the surface of the film to be surface-treated by such a surface treatment apparatus in order to prevent charging between the films. For this reason, in such a surface treatment apparatus, when the ozone in the discharge part is sucked into the duct together with air, dusting dust sprinkled on the film and dust that is floating may be sucked into the duct. In this case, there is a problem that dust such as dusting powder and dust adheres to the surface of the discharge electrode in the discharge section (hereinafter referred to as the electrode surface) before reaching the duct.

  In this case, in such a surface treatment apparatus, it is necessary to remove dust from the inside of the discharge part or the electrode surface, but since the gap between the electrode surface and the earth roll is very narrow, it adheres to the electrode surface from the gap. It was difficult to remove the dust directly. For this reason, in this type of surface treatment device, the discharge part itself, which does not need to be removed from the main body of the apparatus, is removed from the main body of the apparatus each time, and the dust adhering to the inside of the discharge part or the electrode surface is removed. There was a problem that it was difficult to do.

  In addition, when replacing the discharge electrode in the discharge unit, in the same way as when removing dust, the discharge unit itself, which does not need to be removed from the main body of the device, should be removed from the main body of the device and replaced. As a result, there is a problem that it is difficult to perform maintenance easily.

  Therefore, the present invention has been made in view of such a situation, and an object thereof is to provide a surface treatment apparatus capable of performing maintenance more easily than in the past.

In order to solve such a problem, in the present invention, in the invention described in claim 1, the discharge by the discharge electrode is applied to the surface of the workpiece to which dusting powder passing over the earth roll is sprinkled so as to cross the discharge electrode. In the surface treatment apparatus for modifying the surface of the workpiece to which the dusting powder is sprinkled by the discharge, a support shaft arranged in parallel to the earth roll, and a predetermined gap with the earth roll. The discharge electrode is provided and disposed, and a discharge holding unit supported on the support shaft by a slide rotation unit and the discharge holding unit are detachably connected to one end, and ozone generated by discharge of the discharge electrode A discharge pipe that discharges the discharge holding portion to the exhaust portion at the other end, and the slide rotation portion slides the discharge holding portion along the support shaft to thereby remove the discharge. Is disengaged from the tube, by rotating the discharge holding portion around the support shaft in a direction away from the ground roll, and wherein the exposing the discharge electrode to the outside.

  The invention according to claim 2 further includes a rotation restricting portion that restricts a rotation angle of the discharge holding portion when the discharge holding portion is rotated in a direction away from the earth roll. .

  According to a third aspect of the present invention, when the discharge holding portion rotated in a direction away from the earth roll is rotated in a direction approaching the earth roll, the rotation angle of the discharge holding portion is set. An earth roll side rotation restricting portion for restricting is provided.

  According to a fourth aspect of the present invention, the discharge holding portion includes a discharge portion for holding the discharge electrode and a duct portion fixed to the discharge portion, and the duct portion is detachably attached to the discharge pipe. It is connected.

  According to a fifth aspect of the present invention, the discharge tube has a double tube structure, the discharge holding portion includes a discharge portion for holding the discharge electrode, and the discharge portion is detachable from the discharge tube. It is connected.

  According to the first aspect of the present invention, since the discharge electrode can be exposed to the outside while the discharge holding portion is supported by the support shaft, the discharge holding portion can be removed without removing the discharge holding portion from the support shaft. The dust adhering to the discharge electrode can be easily removed, and the discharge electrode can be easily replaced, and thus maintenance can be performed more easily than in the past.

It is a schematic explanatory drawing of a surface treatment apparatus. It is the schematic of a surface treatment part and an ozone treatment apparatus. It is the schematic which shows the front structure and upper surface structure of the surface treatment part by 1st Embodiment. It is the schematic which shows the mode of the discharge holding part with a duct of a use state, and the mode of the discharge holding part with a duct of a maintenance state. It is the schematic which shows a mode when the discharge holding part with a duct is made to detach | leave from a fixed duct. It is the schematic which shows a mode when rotating the discharge holding part with a duct and keeping the discharge part away from the earth roll. It is the schematic which shows a mode when the discharge holding part with a duct is positioned. It is the schematic which shows the front structure and upper surface structure of the discharge holding part with a duct by 2nd Embodiment. It is the schematic which shows the mode at the time of use of the discharge holding part with a duct by 2nd Embodiment, and the mode at the time of a maintenance state. It is the schematic which shows the front structure of the surface treatment part by 3rd Embodiment. It is the schematic which shows a mode when the discharge holding part by 3rd Embodiment is rotated and the discharge part is kept away from the earth roll.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

(1) 1st Embodiment (1-1) Whole structure of corona discharge surface treatment apparatus Here, first, the outline of a corona discharge surface treatment apparatus is demonstrated. In FIG. 1, reference numeral 1 denotes a corona discharge surface treatment apparatus as a surface treatment apparatus, and a corona electrode 3 as a discharge electrode provided in the surface treatment unit 2 is disposed with a predetermined gap from a grounded earth roll R1. Has been. In the corona discharge surface treatment apparatus 1, a power supply device 5 and a corona electrode 3 are connected by a conductor 4, and an earth roll R <b> 1 is also electrically connected to the power supply device 5.

  The corona discharge surface treatment apparatus 1 passes between the earth roll R1 and the corona electrode 3 when the film F drawn from the roll R2 passes over the earth roll R1, and at this time, from the corona electrode 3 By irradiating the generated corona discharge to the film F, the film F can be modified.

  Incidentally, the film F as a to-be-processed object in this embodiment can illustrate what the surface is comprised by PP (polypropylene), PE (polyethylene), etc. Moreover, as a size of the film F, For example, a 40 μm thick, 380 mm wide and 1000 m rolled material is used.

  Such a corona discharge surface treatment apparatus 1 is installed in, for example, various packaging machines, and before the printing machine provided in the packaging machine prints characters representing the expiration date on the film F, the film F The planned print location can be modified by irradiating the print planned location with corona discharge. As a result, it is possible to improve the adherence of the ink to the printing scheduled portion modified thereby, and to perform printing with a printing machine with certainty.

  As shown in FIG. 2, the surface treatment unit 2 is connected to an ozone treatment device 6 that treats ozone exhausted from the surface treatment unit 2. The ozone treatment device 6 as an exhaust part includes an exhaust path 7, and a fixed duct 8 of the surface treatment part 2 is connected to the exhaust path 7. The ozone treatment device 6 includes a flow rate detection means 9, a filter 10, an ozone catalyst 11 as an ozone treatment means, an exhaust fan 12 as a delivery means, and an ozone concentration detector 13 in order from the fixed duct 8 side. The exhaust fan 12 is driven and the ozone generated in the surface treatment unit 2 is sucked together with air, and the air and ozone are passed through the exhaust path 7 so as to pass through the ozone treatment device 6. Can be exhausted outside.

(1-2) Detailed Configuration of Surface Treatment Unit Next, the surface treatment unit 2 having the characteristic configuration of the present invention will be described in detail below. Here, FIG. 3A shows a front configuration of the surface treatment unit 2, and FIG. 3B is a schematic diagram showing a top configuration of the surface treatment unit 2. Actually, as shown in FIGS. 3A and 3B, the surface treatment unit 2 is attached to and detached from the fixed duct 8 having one end connected to the ozone treatment apparatus 6 (FIG. 2) and the other end of the fixed duct 8. A duct-equipped discharge holding portion 15 that is freely connected, and a guide portion 16 that slidably supports the duct-equipped discharge holding portion 15 along the longitudinal direction of the earth roll R1 are provided.

  The fixed duct 8 as the discharge pipe according to claim 1 is formed of a hard material having insulation properties such as transparent polycarbonate, and has a configuration formed in a cylindrical shape having a predetermined length. The fixed duct 8 is fixed so that the other end is inserted into a through hole (not shown) formed in the one side frame 22a of the guide portion 16, and a discharge with duct is formed inside the other end. The duct portion 8a of the holding portion 15 is inserted.

  Actually, the fixed duct 8 is formed so that its inner diameter is slightly larger than the outer diameter of the cylindrical duct portion 8a, and the duct portion 8a is partially inserted into the cylindrical hollow portion on the other end side. Configured to get. Thus, the fixed duct 8 can be connected so that the ducted discharge holding section 15 can move while the duct section 8a of the ducted discharge holding section 15 is in communication with the inside.

  Incidentally, inside the fixed duct 8 and the duct portion 8a, the conductor 4 is disposed away from the inner wall by insulating mounting members 23a, 23b, and 23c, and a high voltage is applied to the corona electrode 3 in the discharge portion 20 by the conductor 4. It is made to be able to supply. Here, the conductor 4 is comprised from the one side conductor 4a and the other side conductor 4b which consist of conductive materials. The one-side conductor 4a is formed in a circular tube shape, and has a configuration in which the other-side conductor 4b formed in a circular tube shape or a rod shape is slidably inserted into the hollow portion from the other end.

  The one-side conductor 4a is supported substantially at the center in the duct portion 8a by the insulating mounting member 23a and the insulating mounting member 23b. The other side conductor 4b is supported at substantially the center in the fixed duct 8 by inserting one end of the other side conductor 4b into the other end of the one side conductor 4a and being supported by the insulating mounting member 23c. Thus, the conductor 4 is configured such that the one-side conductor 4a and the other-side conductor 4b expand and contract in conjunction with the movement of the duct-equipped discharge holding portion 15.

  The guide portion 16 has a plate-like one side frame 22a and a plate-like other side frame 22b arranged so as to face the one side frame 22a, and one end portion of the earth roll R1 is The one side frame 22a is fixed to one side wall portion 14a provided rotatably, and the other side frame 14b is provided to the other side wall portion 14b provided with the other end of the earth roll R1 rotatably. 22b is fixed. Thus, between the one side frame 22a and the other side frame 22b, the earth roll R1 is disposed below, and the longitudinal direction of the support shaft 31, the first rotation restricting portion 32 and the second rotation described later. Each longitudinal direction of the restricting portion 33 can be arranged so as to be substantially parallel to the longitudinal direction of the earth roll R1.

  Here, the support shaft 31 has a substantially cylindrical shape, and both ends thereof are fixed to the one side frame 22a and the other side frame 22b by screws N1, respectively. The support shaft 31 is provided with a duct-equipped discharge holding portion 15 slidably along the longitudinal direction, and a duct-equipped discharge holding portion 15 detached from the fixed duct 8 is rotatably provided. . In this connection, the support shaft 31 is provided with two slide set collars 34a, 34b, and the ducted discharge holding portion 15 can move between the slide set collars 34a, 34b. Moreover, the slide set collars 34a and 34b can also position the discharge holding part 15 with a duct in a desired position by sandwiching the discharge holding part 15 with a duct.

  Here, the discharge holding part 15 with a duct as a discharge holding part includes a duct part 8a detachably connected to a fixed duct 8 as a discharge pipe, and a discharge part 20 fixed to the other end of the duct part 8a. The duct portion 8a and the discharge portion 20 are slidably and rotatably provided with respect to the support shaft 31.

  Here, the discharge unit 20 includes a case 25 formed in a box shape including an upper surface, an open lower surface, and four side surfaces, and a plurality of corona electrodes 3 disposed in the case 25 and generating corona discharge. An electrode position adjusting insulator 24 for holding the plurality of corona electrodes 3 is provided on the lower surface side opened in the case 25.

  The case 25 is formed of a rectangular parallelepiped, and the length in the longitudinal direction is shorter than the length of the earth roll R1 and slightly longer than the length of the corona electrode 3, and the longitudinal direction is arranged along the longitudinal direction of the earth roll R1. ing. And the duct part 8a is being fixed to the case 25 so that the inside of the duct part 8a and the inside of the case 25 may be connected.

  As described above, the case 25 covers the corona electrode 3 with the upper surface and the side surface, thereby preventing the ozone generated during the corona discharge from being diffused, and the ozone sucked from the duct portion 8 a via the fixed duct 8. And sent to the ozone treatment device 6.

  As shown in FIG. 4A, the case 25 is formed so that its width is slightly larger than the width of the earth roll R1, and two corona electrodes having a cylindrical shape are formed by the electrode position adjusting insulator 24. 3 is arranged parallel to the longitudinal direction of the earth roll R1, and the two corona electrodes 3 are arranged above the earth roll R1 so as to sandwich the central axis of the earth roll R1.

  The electrode position adjusting insulator 24 is fixed to the upper surface of the case 25 with a screw N2, and can be adjusted such that a plurality of corona electrodes 3 are disposed with a predetermined gap G between the electrode roll and the earth roll R1. The corona discharge from the corona electrode 3 can be reliably irradiated onto the film F passing over R1.

  Incidentally, when an aluminum vapor deposition film having an aluminum layer is directly subjected to local discharge by the electrode body of the corona electrode 3, there is a possibility that a hole is formed in the aluminum layer. Therefore, the corona electrode 3 has a configuration in which an outer periphery of an electrode body (not shown) is covered with an insulator, and this insulator can function as a dielectric to suppress local discharge from the electrode body. . And the corona electrode 3 is preventing the damage of an aluminum layer when surface-treating an aluminum vapor deposition film by suppression of such discharge. In the case of this embodiment, since the electrode body is formed in a columnar shape, the discharge is radiated radially from its peripheral surface, and local discharge can be suppressed. Note that the corona electrode 3 of the present embodiment uses a cylindrical electrode body in which the length of the axial center of the electrode body is 125 mm and the diameter is 16 mm.

  In addition to this configuration, the case 25 of the discharge unit 20 is provided with a slide rotation unit 19 that supports the discharge holding unit with duct 15 on the support shaft 31 so as to be slidable and rotatable. In the case of this embodiment, the slide rotation portion 19 is fixed to the back surface of the case 25, and is fixed to the case support portion 27, and is slidable and rotatable on the support shaft 31. And a bearing portion 26 provided freely.

  As shown in FIG. 3B, the case support portion 27 includes a case fixing surface 27 a that is fixed to the upper surface of the case 25 and a bearing fixing surface 27 b that is fixed to the bearing portion 26. In the case of this embodiment, the case fixing surface 27a has a substantially square shape and has a configuration selected to be smaller than the bearing fixing surface 27b. The case fixing surface 27a is integrally formed at the center of one side in the longitudinal direction of the bearing fixing surface 27b, and the case fixing surface 27a is formed on the upper surface of the case so as to avoid the screw N2 that fixes the upper surface of the case 25 and the electrode position adjusting insulator 24. It is fixed in the central area.

  In the case of this embodiment, the bearing fixing surface 27b includes a substantially rectangular main body surface 27c and a substantially trapezoidal bulging surface 27d formed on the other side in the longitudinal direction of the main body surface 27c. As shown in FIG. 4A, the bearing portion 26 is fixed to the main body surface 27c, and a rotation positioning portion 29 described later is provided on the bulging surface 27d.

  The bearing portion 26 has a columnar main body having substantially the same dimension as the longitudinal direction of the main body surface 27c of the bearing fixing surface 27b, and the main body is fixed to the back surface of the main body surface 27c of the bearing fixing surface 27b with screws N3. Has been. In addition to this configuration, the bearing portion 26 has a through hole (not shown) penetrating the central axis in the longitudinal direction of the main body, and the support shaft 31 is inserted into the through hole, While being able to slide along the support shaft 31, as shown in FIG.4 (B), it has the structure which can be rotated to the direction m1 away from the earth roll R1, or the direction m2 approached by using the support shaft 31 as a rotating shaft.

  As shown in FIG. 4A, the rotation positioning unit 29 includes a corona electrode 3 disposed above the ground roll R1 with a predetermined gap G, and the longitudinal direction of the corona electrode 3 and the ground roll R1. In a state where the longitudinal direction is arranged in parallel (that is, a state where the film F is irradiated with corona discharge, hereinafter referred to as a use state), a first rotation restriction provided in the guide portion 16 By contacting the part 32, the duct-equipped discharge holding part 15 can be maintained in use.

  In practice, the rotation positioning portion 29 is provided on the bulging surface 27d located on the lower surface 32a of the first rotation restricting portion 32 when in use, and one end 29a is the lower surface of the first rotation restricting portion 32. By abutting on 32a, the duct-equipped discharge holding portion 15 can be positioned in use.

  In the case of this embodiment, the rotation positioning portion 29 is made of a screw member, and one end portion 29a which is a screw tip is screwed into a female screw (not shown) drilled in the bulging surface 27d of the bearing fixing surface 27b. The distance from which the one end portion 29a protrudes from the bulging surface 27d can be adjusted.

  Thereby, the rotation positioning part 29 rotates the discharge part 20 to the upper side centering on the support shaft 31, for example, by enlarging the distance which the one end part 29a protrudes from the bulging surface 27d at the time of use. The arrangement state of the corona electrode 3 with respect to the earth roll R1 can be finely adjusted. On the other hand, when the rotation positioning unit 29 is in use, the discharge unit 20 is rotated downward about the support shaft 31 by reducing the distance that the one end 29a protrudes from the bulging surface 27d, for example. The arrangement state of the corona electrode 3 with respect to the earth roll R1 can be finely adjusted.

  Here, in the case of this embodiment, the first rotation restricting portion 32 with which the rotation positioning portion 29 abuts in the use state is made of a square member having a quadrangular cross section, as shown in FIGS. 4 (A) and 4 (B). As shown in the figure, the other side frame 22b is located farther from the grounding roll R1 than the support shaft 31 and above the support shaft 31, and is rotated at the upper corner of the support shaft 31. Only the positioning portion 29 can be brought into contact.

  In addition to such a configuration, the rotation positioning unit 29 is configured so that the discharge holding unit with duct 15 slid along the support shaft 31 and removed from the fixed duct 8 is, as shown in FIG. When the corona electrode 3 is rotated about 90 degrees in the direction m1 away from the earth roll R1 around the center and the corona electrode 3 is exposed to the outside (hereinafter referred to as a maintenance state), the guide portion 16 The discharge holding part with duct 15 can be maintained in a maintenance state by abutting against the second rotation restricting part 33 provided on the main body.

  In practice, when the rotation positioning unit 29 is in the maintenance state, the other end portion 29b abuts on the side surface 33a of the second rotation restriction unit 33, so that the discharge holding unit with duct 15 can be positioned in the maintenance state. .

  In the case of this embodiment, the rotation positioning portion 29 has one end portion 29a, which is a screw tip, screwed into a female screw drilled in the bulging surface 27d of the bearing fixing surface 27b, and the other end portion 29b from the bulging surface 27d. It is comprised so that the distance which protrudes can be adjusted.

  Thereby, the rotation positioning unit 29 rotates the discharge unit 20 downward about the support shaft 31 by, for example, increasing the distance that the other end 29b protrudes from the bulging surface 27d in the maintenance state. The corona electrode 3 can be slightly brought closer to the earth roll R1 side. On the other hand, when the rotation positioning unit 29 is in the maintenance state, for example, by reducing the distance that the other end 29b protrudes from the bulging surface 27d, the discharge unit 20 is rotated upward about the support shaft 31. The corona electrode 3 can be moved slightly away from the earth roll R1.

  Here, in the case of this embodiment, the second rotation restricting portion 33 with which the rotation positioning portion 29 abuts in the maintenance state is formed of a square member having a substantially quadrangular cross section, and FIGS. As shown in FIG. 4, the other side frame 22b is disposed at a lower corner portion (that is, a diagonal position with respect to the first rotation restricting portion 32) closer to the earth roll R1 than the support shaft 31 and below the support shaft 31. As a result, only the rotation positioning portion 29 of the bulging surface 27d can be brought into contact in the maintenance state.

  As shown in FIGS. 5 (A) and 5 (B), the discharge holding portion 15 with the duct hits the main body surface 27c of the slide rotating portion 19 against the slide set collar 34b arranged in the vicinity of the other side frame 22b. The duct portion 8a can be detached from the fixed duct 8 by moving in the direction x1 along the support shaft 31 toward the other side frame 22b side.

  As a result, the discharge holding section 15 with duct is supported by the support shaft 31 only by the slide rotation section 19 and discharges via the slide rotation section 19 around the support shaft 31 as shown in FIG. The part 20 and the duct part 8a rotate integrally, and it can be in a maintenance state in which the corona electrode 3 is away from the earth roll R1 and exposed to the outside. In addition to this configuration, the one side frame 22a of the guide portion 16 has a shape substantially the same as the outer shape of the end portion of the duct portion 8a at a position facing the duct portion 8a in the maintenance state, and the duct A positioning hole 35 selected slightly larger than the outer diameter of the portion 8a is formed.

  As shown in FIG. 7, the discharge holding part 15 with the duct is slid in the direction x2 along the support shaft 31 toward the one side frame 22a as shown in FIG. It can be inserted into the positioning hole 35. Thereby, the discharge holding part with duct 15 can be restricted from rotating around the support shaft 31 by the duct part 8a being inserted into the positioning hole 35 and positioned. Thus, the discharge holding section with duct 15 in the maintenance state rotates in the direction m2 (FIG. 4B) in which the corona electrode 3 approaches the earth roll R1 side with the support shaft 31 as the center, and returns to the use state again. It has been made to be able to prevent.

(1-3) Operation and Effect In the above configuration, in the corona discharge surface treatment apparatus 1, the duct portion 8 a of the discharge holding portion 15 with duct is detachably connected to the fixed duct 8, and the support shaft is supported by the slide rotation portion 19. The discharge holding part with duct 15 is detached from the fixed duct 8 by sliding the discharge holding part with duct 15 along the direction 31 away from the fixed duct 8 (that is, in the direction of the arrow x1 in FIG. 5B). be able to.

  Moreover, in this corona discharge surface treatment apparatus 1, while providing the other side conductor 4b of the conductor 4 which supplies a high voltage to the corona electrode 3 in the discharge part 20 inside the fixed duct 8, it can slide with the other side conductor 4b. One side conductor 4a of the conductor 4 to be inserted into the duct is provided inside the duct portion 8a of the discharge holding portion with duct 15, and when the discharge holding portion with duct 15 is detached from the fixed duct 8, the other side conductor 4b becomes one. It was made to detach | leave from the side conductor 4a. Thereby, in the corona discharge surface treatment apparatus 1, the one side conductor 4 a and the other side conductor 4 b of the conductor 4 can be disposed inside the fixed duct 8 and the duct portion 8 a so as to be energized, and the fixed duct 8 is provided with a duct. When the discharge holding part 15 is detached, the one-side conductor 4a is detached from the other conductor 4b, whereby the ducted discharge holding part 15 can be completely detached from the fixed duct 8.

  Further, in the corona discharge surface treatment apparatus 1, the slide rotation part 19 of the discharge holding part with duct 15 is rotatably provided on the support shaft 31, so that the discharge holding part with duct 15 is supported on the support shaft 31. The discharge unit 20 can be rotated in the direction m1 away from the earth roll R1 by the slide rotation unit 19 while remaining supported by the support shaft 31 without being removed from the ground roll R1.

  Thereby, in the corona discharge surface treatment apparatus 1, the corona electrode 3 of the discharge part 20 which has been arranged so as to face the earth roll R1 with a slight gap G in the state of use is kept away from the earth roll R1. Can be exposed to the outside. Therefore, in this corona discharge surface treatment apparatus 1, for example, dust adhered to the discharge unit 20 or the corona electrode 3 remains in a state of being supported by the support shaft 31 without removing the discharge unit 20 from the surface treatment unit 2. Dust adhering to the surface can be easily removed, and the corona electrode 3 provided in the discharge section 20 can be easily replaced, and thus maintenance can be performed more easily than in the past.

  Further, in this corona discharge surface treatment apparatus 1, by inserting the duct portion 8a of the discharge holding portion with duct 15 in the maintenance state into the positioning hole 35 provided in the one side portion frame 22a, the one side portion frame 22a. The discharge holding part 15 with duct can be positioned in the position, and thus, in a maintenance state, an external force is applied for some reason, and the discharge holding part 15 with duct rotates about the support shaft 31 toward the earth roll R1 side again. It can prevent returning to a normal state.

  Here, in the discharge holding unit with duct 15, the rotation positioning unit 29 provided in the slide rotation unit 19 is simply rotated about the support shaft 31 in the direction m1 away from the earth roll R1. It abuts on the second rotation restricting portion 33 and can be easily positioned in a maintenance state at a predetermined angle. Moreover, in the discharge holding part 15 with a duct, the rotation positioning part 29 provided in the slide rotation part 19 is changed to the first position only by rotating the discharge part 20 around the support shaft 31 in the direction m2 approaching the earth roll R1. It abuts on the one rotation restricting portion 32 and can be easily positioned in a use state at a predetermined angle.

  Moreover, in the rotation positioning part 29, by adjusting the distance which the one end part 29a protrudes from the bulging surface 27d of the bearing fixing surface 27b, as shown in FIG. 4A, the corona electrode 3 with respect to the earth roll R1 is adjusted. The arrangement state can be easily adjusted. Further, in the rotation positioning portion 29, by adjusting the distance that the other end portion 29b protrudes from the bulging surface 27d of the bearing fixing surface 27b, the corona electrode 3 in the maintenance state is adjusted as shown in FIG. The exposure angle can be easily adjusted.

  Incidentally, in the corona discharge surface treatment apparatus 1, after the maintenance is finished, the duct-equipped discharge holding portion 15 is moved in the direction x 1 approaching the other side frame 22 b, the duct portion 8 a is pulled out from the positioning hole 35, and the corona electrode 3 is removed. After the discharge holding part with duct 15 is rotated in the direction m2 approaching the earth roll R1, the discharge holding part with duct 15 is moved in the direction x2 approaching the one side frame 22a, so that the duct part 8a is fixed to the fixed duct 8. In addition, the one-side conductor 4a and the other-side conductor 4b can be connected to each other and can be easily returned to the use state.

(2) Second Embodiment In FIGS. 8 (A) and 8 (B), the same reference numerals are given to the corresponding parts to FIGS. 3 (A) and 3 (B), and reference numeral 41 denotes the second embodiment. A surface treatment part is shown. The surface treatment unit 41 is different from the first embodiment in the positioning method when the discharge holding unit with duct 42 is rotated. In this case, the slide rotation portion 43 provided in the discharge holding portion with duct 42 has the bearing portion 26 fixed to the rectangular bearing fixing surface 44 and the upper surface of the case 25 to the square case fixing surface 45. As shown in FIG. 9A, which is fixed and the same reference numerals are assigned to the corresponding parts to FIG. 4A, a receiving portion 46 having an inverted L-shaped cross section is provided on the back surface of the bearing fixing surface 44. .

  Incidentally, here, in this second embodiment, the discharge holding portion with duct 42 as the discharge holding portion according to claim 1 includes a duct portion 8a detachably connected to the fixed duct 8 as the discharge pipe. The discharge portion 20 is fixed to the other end of the duct portion 8a, and the slide rotation portion 43 is provided so that the duct portion 8a and the discharge portion 20 are slidable and rotatable with respect to the support shaft 31.

  In the case of this embodiment, the receiving portion 46 has a flat fixing surface 47 fixed to the back surface of the bearing fixing surface 44 with a screw N3, and a flat receiving surface 48 suspended from one side of the bearing fixing surface 44. The receiving surface 48 is disposed substantially parallel to the side surface of the case 25.

  Here, a through hole 51 is formed in the second rotation restricting portion 49 of the guide portion 16 so as to penetrate the opposing one side surface 49 a and the other side surface 49 b, and the rotation positioning portion is provided in the through hole 51. 52 can be inserted. The rotation positioning portion 52 is made of a screw member, and is inserted into the through hole 51 so that the tip 53 contacts the receiving surface 48 of the receiving portion 46, and the other side surface of the second rotation restricting portion 49. After the distance at which the tip 53 protrudes from 49b is adjusted, it is fixed to the second rotation restricting portion 49 by a nut 52a.

  The rotation positioning part 52 as the earth roll side rotation restricting part increases, for example, the distance by which the tip part 53 protrudes from the other side surface 49b of the second rotation restricting part 49, so that the discharge part is centered on the support shaft 31. By rotating 20 upward, the arrangement state of the corona electrode 3 with respect to the earth roll R1 can be finely adjusted. On the other hand, the rotation positioning part 52 reduces the distance that the tip part 53 protrudes from the other side surface 49b of the second rotation restriction part 49, for example, so that the discharge part 20 is centered on the support shaft 31 by its own weight. By rotating downward, the arrangement state of the corona electrode 3 with respect to the earth roll R1 can be finely adjusted.

  In addition, as shown in FIG. 8A, a plurality of through holes 51 into which such a rotation positioning portion 52 is inserted are formed at arbitrary positions on the other side surface 49b of the second rotation restricting portion 49. Yes. Thereby, in the surface treatment part 41, when the discharge part 20 is slid along the support shaft 31 according to the modification | reformation position of the film F which passes on the earth roll R1, it penetrates facing the discharge part 20 in each position. By inserting the rotation positioning portion 52 into the hole 51 and adjusting the protruding state of the rotation positioning portion 52 to the receiving portion 46, the arrangement state of the corona electrode 3 with respect to the earth roll R1 can be finely adjusted at each position. It is made like that.

  Further, in such a surface treatment unit 41, similarly to the above-described embodiment, the duct-equipped discharge holding unit 42 is slid along the support shaft 31 in the direction x1 approaching the other side frame 22b (FIG. 8). (B)), the duct portion 8a is detached from the fixed duct 8 as the discharge pipe. Then, as shown in FIG. 9B, the duct-equipped discharge holding unit 42 rotates the corona electrode 3 about 90 degrees around the support shaft 31 in the direction m1 away from the earth roll R1, thereby removing the corona electrode 3 from the outside. In the exposed state (that is, the maintenance state), the discharge holding portion with duct 42 can be maintained in the maintenance state by contacting the first rotation restricting portion 32 as the rotation restricting portion. Yes.

  In the case of this embodiment, the slide rotation part 43 has a predetermined screw N5 provided for fixing the case 25 to the case fixing surface 45 in the maintenance state. By contacting the side surface 32b, the duct-equipped discharge holding portion 42 can be positioned in the maintenance state.

  In the above configuration, even such a surface treatment unit 41 can obtain the same effects as those of the first embodiment described above, and is supported by the support shaft 31 without removing the discharge unit 20 from the surface treatment unit 41. In this state, for example, dust attached to the discharge unit 20 or dust attached to the surface of the corona electrode 3 can be easily removed, and the corona electrode 3 provided in the discharge unit 20 can be easily replaced. be able to.

  Also in the second embodiment, by inserting the duct portion 8a of the discharge holding portion with duct 42 in the maintenance state into the positioning hole 35 provided in the one side portion frame 22a, the one side portion frame 22a. Alternatively, the duct-equipped discharge holding portion 42 may be positioned.

(3) Third Embodiment In FIG. 10, in which parts corresponding to those in FIG. 3A are assigned the same reference numerals, 61 denotes a surface treatment section according to the third embodiment. One end side of the surface treatment unit 61 is connected to the ozone treatment apparatus 6 (FIG. 2), and the telescopic duct 62 is configured to be extendable and the discharge holding unit 63 is detachably connected to the other end side of the telescopic duct 62. And the guide portion 16 that supports the discharge holding portion 63 so as to be slidable along the longitudinal direction of the earth roll R1, and is described above in that the duct portion is not provided integrally with the discharge holding portion 63. This is different from the first embodiment.

  Here, in the third embodiment, the discharge holding portion 63 as the discharge holding portion according to claim 1 is detachably connected to the other end side of the telescopic duct 62 as the discharge tube, and is placed in the case 25. The discharge unit 20 is configured to hold the corona electrode 3 by the provided electrode position adjusting insulator 24, and the slide rotation unit 19 is provided so that the discharge unit 20 is slidable and rotatable with respect to the support shaft 31.

  In this case, the telescopic duct 62 as the discharge pipe according to claim 1 is composed of the one side tube 62a and the other side tube 62b formed in a cylindrical shape, and the discharge holding portion 63 is detachably connected to the one side tube 62a. The ozone treatment device 6 (FIG. 2) as a discharge unit is connected to the other side pipe 62b. The telescopic duct 62 is formed such that, for example, the inner diameter of the other side pipe 62b is slightly larger than the outer diameter of the one side pipe 62a, and the one side pipe 62a is partially loosened in the cylindrical hollow portion of the other side pipe 62b. It is comprised so that it can insert. That is, the telescopic duct 62 has a double-pipe structure having an overlap margin composed of the one side pipe 62a and the other side pipe 62b.

  The discharge holding part 63 is composed of the discharge part 20 and the slide rotation part 19, and a duct attachment part to which the one side tube 62 a is detachably connected is provided on the side surface of the case 25 of the discharge part 20. In practice, the duct mounting portion 64 is selected to have substantially the same shape as the outer shape of the one-side tube 62a and the outer diameter is slightly smaller than the inner diameter of the one-side tube 62a. It can be mounted by being fitted into a cylindrical hollow portion.

  In such a surface treatment unit 61 as well, as in the above-described embodiment, the discharge holding unit 63 is slid along the support shaft 31 in the direction x1 approaching the other side frame 22b. It is detached from the side tube 62a. Then, as shown in FIG. 11, the discharge holding unit 63 rotates the corona electrode 3 about 90 degrees around the support shaft 31 in the direction away from the earth roll R <b> 1 by the slide rotation unit 19. It can be in an externally exposed state (ie, a maintenance state).

  In the above configuration, the surface treatment unit 61 can obtain the same effects as those of the first embodiment described above, and the discharge unit 20 is supported by the support shaft 31 without being removed from the surface treatment unit 61. For example, dust attached to the discharge unit 20 or dust attached to the surface of the corona electrode 3 can be easily removed in the state, and the corona electrode 3 provided in the discharge unit 20 can be easily replaced. it can.

  Further, in the third embodiment, only the discharge holding portion 63 is slid without providing the discharge holding portion 63 with the duct portion made of the cylindrical member as in the first and second embodiments described above. The rotating part 19 is supported on the support shaft 31 so as to be rotatable. Thereby, in this surface treatment part 61, compared with the 1st and 2nd embodiment mentioned above, the weight of the discharge holding part 63 can be reduced by the amount that the duct part is not provided. It is possible to reduce the burden on the slide rotation unit 19 that occurs when the discharge holding unit 63 is rotated.

  Furthermore, in the third embodiment, as in the first and second embodiments described above, a duct portion 8a (FIGS. 3A and 3B) that realizes a telescopic structure with the fixed duct 8 is used. )) Is not provided in the discharge holding portion 63, but the discharge holding portion 63 is detachably provided in the expansion / contraction duct 62 having a double tube structure configured to be extendable / retractable. Even if it is slid along the support shaft 31, the expansion duct 62 itself extends following the discharge holding portion 63, so that the ozone generated in the discharge portion 20 can be reliably discharged through the expansion duct 62. it can.

(4) Other Embodiments The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention. For example, in the present invention, the corona electrode 3 can be exposed to the outside by rotating the discharge holding units with ducts 15 and 42 and the discharge holding unit 63 about the support shaft 31 in a direction away from the earth roll R1. Alternatively, the discharge holding units with ducts 15 and 42 and the discharge holding unit 63 may be positioned at various angles.

  Further, for example, in the first embodiment described above, the ducted discharge holding portion 15 in the maintenance state is inserted into the positioning hole 35 formed in the one side frame 22a and positioned. As described above, the discharge holding section with duct 15 and the one side frame 22a may be locked by various metal fittings for positioning.

  Furthermore, in the above-described embodiment, the case where the fixed duct 8 and the duct portion 8a and the conductor 4 configured to be extendable / contractable is provided inside the extendable duct 62 has been described, but the present invention is not limited thereto. Instead, the conductor 4 may be provided outside the fixed duct 8 and the duct portion 8 a and the telescopic duct 62.

  Furthermore, in the above-described third embodiment, the case where the telescopic duct 62 having a double-pipe structure configured to be stretchable is described, but the present invention is not limited to this and does not have a telescopic structure. One simple single tube may be applied.

DESCRIPTION OF SYMBOLS 1 Corona discharge surface treatment apparatus 2 Surface treatment part 3 Corona electrode (discharge electrode)
15,42 Discharge holding part with duct (discharge holding part)
8 Fixed duct (discharge pipe)
31 Support shaft 32 First rotation restricting portion (earth roll side turning restricting portion)
33 Second rotation restricting portion (turn restricting portion)
62 Telescopic duct (discharge pipe)
63 Discharge holding part

Claims (5)

On the surface of the object to be treated dusting powder to pass over the ground roll so as to intersect the discharge electrodes are sprinkled, irradiating the discharge by the discharge electrode, the object to be processed, wherein the dusting powder is sprinkled by the discharge In a surface treatment apparatus for modifying the surface of
A support shaft arranged in parallel with the earth roll;
Disposing the discharge electrode with a predetermined gap from the ground roll, and a discharge holding unit supported by the support shaft by a slide rotation unit;
The discharge holding portion is detachably connected to one end, and includes a discharge pipe that discharges ozone generated by the discharge of the discharge electrode to the exhaust portion of the other end,
The slide rotation part is
By sliding the discharge holding portion along the support shaft, the discharge holding portion is detached from the discharge pipe, and the discharge holding portion is rotated about the support shaft in a direction away from the earth roll, thereby causing the discharge electrode to move. A surface treatment apparatus characterized by being exposed to the outside. The surface treatment apparatus according to claim 1, further comprising a rotation restricting unit that restricts a rotation angle of the discharge holding unit when the discharge holding unit is rotated in a direction away from the earth roll. An earth roll side rotation restricting portion for restricting a rotation angle of the discharge holding portion when the discharge holding portion rotated in a direction away from the earth roll is rotated in a direction approaching the earth roll; The surface treatment apparatus according to claim 1, wherein the surface treatment apparatus is provided. The discharge holding unit is
The discharge part holding the said discharge electrode and the duct part fixed to the said discharge part are provided, The said duct part is connected to the said discharge pipe so that attachment or detachment is possible. The surface treatment apparatus of any one of Claims. The discharge tube has a double tube structure that can be expanded and contracted, the discharge holding unit includes a discharge unit that holds the discharge electrode, and the discharge unit is detachably connected to the discharge tube. The surface treatment apparatus according to claim 1.

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