JP2016197493A - Static eliminator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a static eliminator capable of eliminating static on the opposite sides of a sheet more completely, while allowing compaction.SOLUTION: A static eliminator includes a plurality of first discharge electrodes 12a facing one side 1a of a sheet 1 and arranged on a straight line substantially perpendicular to the direction A of movement of the sheet 1, and applying a DC voltage, and a plurality of second discharge electrodes 13a facing the first discharge electrodes 12a while sandwiching the sheet 1, and arranged on a straight line substantially perpendicular to the direction A of movement of the sheet 1, and applying a DC voltage. In the first and second discharge electrodes 12a, 13a, adjoining discharge electrodes have reverse polarities, and the first and second discharge electrodes 12a, 13a facing each other while sandwiching the sheet 1 have reverse polarities. The distance z between the first and second discharge electrodes 12a, 13a facing each other while sandwiching the sheet 1 is set smaller than the distance x between the adjoining discharge electrodes 12a, 12a, and the distance x between the adjoining discharge electrodes 13a, 13a.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a static eliminator that neutralizes both sides of a sheet that moves with both sides charged.

Conventionally, a static eliminator that neutralizes the surface of a charged sheet is known.
6 includes a positive DC electrode bar 2 and a negative DC electrode bar 3 which are opposed to each other with the sheet 1 therebetween, in order from the upstream side in the moving direction of the sheet 1 moving in the direction of arrow A, and the downstream side thereof. Are provided with a negative DC electrode bar 4, a positive DC electrode bar 5, and a pair of AC electrode bars 6 and 7, which are opposed to each other.
Each of the DC electrode bars 2 to 5 and the AC electrode bars 6 and 7 is formed by arranging a plurality of discharge electrode needles on a straight line extending in the width direction of the sheet 1, and the tip of the discharge electrode needle is placed on the surface 1 a of the sheet 1. Or it is made to oppose 1b.

A positive DC high voltage source 8 is connected to the positive DC electrode bars 2 and 5 and a positive DC high voltage is applied to generate a positive corona discharge to generate positive ions of air. Further, the negative DC high voltage source 9 is connected to the negative DC electrode bars 3 and 4, and a negative DC high voltage is applied to generate a negative corona discharge, thereby generating negative ions of air.
Further, an AC high voltage source 10 is connected to the AC electrode bars 6 and 7 so that positive and negative ions are alternately generated by applying an AC high voltage.

  In such a static eliminator, in the moving process, the charged sheet 1 first irradiates one surface 1a with positive ions generated by the positive DC electrode bar 2 to eliminate negative charges, and then The negative ions generated by the negative DC electrode bar 4 are irradiated to remove the positive charges, and the surface 1a of the sheet 1 is discharged to a certain level, but the remaining charges are generated by the AC electrode bar 6. It is further neutralized with positive and negative ions.

The other surface 1b of the sheet 1 is irradiated with negative ions from the negative DC electrode bar 3 to remove the positive charges, and positive ions are irradiated from the positive DC electrode bar 5 to remove the negative charges. The remaining charges are neutralized by positive and negative ions generated by the AC electrode bar 7.
Note that, in the above neutralization process, the DC electrode bars 2 and 3 and the DC electrode bars 4 and 5 facing each other across the sheet 1 are applied with voltages of opposite polarities. The ions generated by the DC electrode bars 2 to 5 are forcibly guided to the sheet 1.

In the conventional static eliminator, another pair of negative and positive DC electrode bars 4 and 5 and a pair of AC electrode bars 6 are disposed downstream of the upstream pair of positive and negative DC electrode bars 2 and 3. , 7 are provided for the following reason.
Since each of the DC electrode bars 2 to 5 is applied with a DC high voltage of either positive or negative polarity, all the discharge electrode needles in one DC electrode bar have the same polarity. Therefore, the polarity of ions generated by corona discharge with one DC electrode bar is either positive or negative.

On the other hand, even if the surface of the charged sheet 1 is biased to either positive or negative polarity as a whole, there is almost no charge of one polarity.
For this reason, when trying to remove the charge on the surface of the sheet 1 to a certain level, it is not sufficient to irradiate only one of the positive and negative ions, but the DC electrode bar having the opposite polarity along the moving direction of the sheet 1 It is necessary to provide it.
That is, as shown in FIG. 6, it is essential to provide the negative DC electrode bar 4 downstream of the positive DC electrode bar 2 and the positive DC electrode bar 5 downstream of the negative DC electrode bar 3.

Further, the influence of the downstream DC electrode bars 4 and 5 is more intense on the surfaces 1a and 1b of the sheet 1 that have passed through the DC electrode bars 2 to 5 arranged as described above.
On one surface 1a, positive ions are first irradiated and the negative charges are eliminated, but the positive ions are guided to the surface 1a by the lines of electric force directed to the sheet 1, and therefore forced. The surface 1a may be positively reverse-charged by the positive ions guided to.
Thus, the charge of the reversely charged portion or the portion that was originally positively charged is neutralized by negative ions radiated from the downstream negative DC electrode bar 4. However, since the negative ions are also forcibly guided by the lines of electric force directed to the sheet 1 as described above, not only the positive charges are removed, but the surface 1a is easily negatively charged reversely. Therefore, the surface 1a of the sheet 1 that has passed through the positive and negative DC electrode bars 2 and 4 is often negatively reversely charged.

  Similarly, the other surface 1b side tends to be positively reversely charged by the positive DC electrode bar 5 located on the downstream side. Thus, even after the sheet 1 passes through the DC electrode bars 4 and 5 on the downstream side, charges remain on the surfaces 1a and 1b. In order to neutralize the remaining charges, the AC electrode bars 6 and 7 are provided.

JP 2008-004397 A

As described above, the conventional static eliminator generates only one polarity ion in each of the DC electrode bars 2, 3, 4, and 5, and is attracted to the opposing electrode bar so that both surfaces 1 a, Since ions having opposite polarities are forcibly guided to 1b, an electric double layer in which the electric field E is closed through the thickness of the sheet 1 is formed (see FIG. 7).
For the sake of explanation, FIG. 7 shows the thickness of the sheet 1 large, but the thickness of the sheet 1 is actually about several tens [μm] to 1 [mm]. In such a sheet 1, since the positive and negative charges on the surfaces 1a and 1b of the sheet 1 form an electric double layer that forms a closed electric field E through the thickness of the sheet 1, the apparent charging potential is low. Become. Thus, since the apparent charging potential of the sheet 1 is low, even if an AC high voltage having the same phase is applied to the AC electrode bars 6 and 7 in order to eliminate the charge, the sheet 1 is generated by the AC electrode bars 6 and 7. The force attracting the ions to the sheet 1 was weak, and it was almost impossible to neutralize all the charges on the surfaces 1a and 1b of the sheet 1. That is, in the conventional static eliminator, it is easy to form an electric double layer, and it is also difficult to neutralize the formed electric double layer.

On the other hand, there is an application for neutralizing a sheet printed by a so-called electrophotographic image forming process using static electricity.
When the sheet 1 passes through the electrophotographic image forming process, both surfaces 1a and 1b are charged. However, when the thickness of the sheet 1 is small as described above, the electric double layer as described above is easily formed, and the sheet 1 is formed in the printing press. Even if the charge removal step is provided, the sheet 1 is not easily discharged. However, as long as the electric field E is closed as described above, there is no problem even if the charges 1 are not sufficiently removed from the surfaces 1a and 1b of the sheet 1.

  However, when the sheet 1 that does not appear to be charged as described above is discharged from the printing machine and stacked on the tray 11, the stacked sheets 1 and 1 come into contact as shown in FIG. Thus, these distances become almost zero and become smaller than the thickness of the sheet 1. Therefore, the charges on both sides of the sheet 1 are more likely to be combined with the charges on the other sheets 1 that are in contact than the charges on both sides of the sheet 1 itself. For example, the negative charge on one surface 1a of the second sheet 1 shown in FIG. 8 is more positive than the positive charge on the other surface 1b of the sheet 1 than the positive charge on the surface 1b of the upper sheet 1. The attractive force with the electric charge increases. Therefore, a strong suction force f is generated between the stacked sheets 1 and 1 due to positive and negative charges. Although the charge on the surface 1b of the lowermost sheet 1 is not shown in FIG. 8, the charge on the surface 1b remains as it is.

When the suction force f is generated, the stacked sheets 1 and 1 are bonded to each other by the suction force f. As a result, it becomes difficult to peel the sheets 1 one by one, and the subsequent process does not proceed smoothly.
Therefore, in order to remove the sheet 1 before being stacked on the tray 11 almost completely, it is conceivable to use a neutralizing device in the printing press. However, as described above, in the conventional neutralizing device shown in FIG. Since the charges on both surfaces 1a and 1b of the sheet 1 cannot be completely eliminated, there is a problem that the stacked sheets 1 are adsorbed.

Moreover, the conventional static eliminator is provided with at least two sets of DC electrode bars 2, 3, 4 and 5 and a pair of AC electrode bars 6 and 7 sandwiching the sheet 1 along the moving direction of the sheet 1. Is essential. For this reason, the static eliminator has a large dimension in the moving direction of the sheet 1 and is difficult to reduce in size. Further, if the sheet 1 is reversely charged by the DC electric bars 4 and 5, in order to eliminate the charge, a set of positive and negative DC electrode bars must be provided further downstream to generate ions for discharging. In some cases, the static eliminator becomes larger.
In addition, there are many cases where the larger static eliminator cannot be installed in space.
An object of the present invention is to provide a static eliminator that can completely eliminate static electricity on both sides of a sheet and that can be miniaturized.

The present invention is premised on a static eliminator that neutralizes both surfaces of the sheet by irradiating both surfaces of the moving sheet with positive ions and negative ions generated by discharge.
According to a first aspect of the present invention, there is provided a plurality of first discharge electrodes that are arranged on a straight line facing one surface of the sheet and substantially perpendicular to the moving direction of the sheet, and applying a DC voltage; A plurality of second discharge electrodes which are arranged on a straight line which is opposed to the first discharge electrode and is substantially orthogonal to the moving direction of the sheet, and which applies a DC voltage; In the electrodes, the polarity of the adjacent discharge electrodes is reversed, the first discharge electrode and the second discharge electrode facing each other across the sheet are reversed in polarity, and the first and second discharge electrodes facing each other across the sheet are opposed to each other. The distance between the 1 and 2 discharge electrodes is smaller than the distance between adjacent discharge electrodes.
Note that the electrodes facing each other with the sheet interposed therebetween do not necessarily face each other. A case where the sheet is slightly deviated in the width direction or the moving direction is also included in the above-described facing.

  According to a second aspect of the present invention, the first and second discharge electrodes are provided at a position upstream with respect to the moving direction of the sheet, and the position is located downstream of the first and second discharge electrodes. One AC electrode that is opposed to one surface of the sheet and substantially orthogonal to the moving direction of the sheet, and the other AC electrode that is opposed to the one AC electrode across the sheet and that is substantially orthogonal to the moving direction of the sheet. An AC electrode is provided.

  According to the first invention, when the first discharge electrode and the second discharge electrode having opposite polarities are arranged across the sheet, the vicinity of the sheet becomes a zero potential surface, and positive ions and negative ions are placed in the vicinity of the sheet. It can guide efficiently and contribute to static elimination. In addition, since the plurality of first discharge electrodes and second discharge electrodes are alternately arranged positively and negatively along the direction orthogonal to the moving direction of the sheet, even between adjacent discharge electrodes having different polarities. A zero potential surface is formed, and ions generated by the positive and negative discharge electrodes diffuse toward the adjacent discharge electrodes. However, since the distance between the first and second discharge electrodes facing each other across the sheet is made smaller than the distance between adjacent discharge electrodes, the force acting on the ions is the force toward the sheet. It becomes stronger than the force toward the adjacent discharge electrodes.

In other words, the generated positive ions and negative ions are attracted in the direction of the adjacent discharge electrodes and are strongly attracted in the sheet direction and move toward the sheet. Will be mixed at the same time. For this reason, the positive and negative charges on both sides of the sheet are discharged simultaneously, and reverse charging as in the case of forcibly irradiating ions of only one polarity hardly occurs, and the electric double layer is not easily formed.
Therefore, efficient and almost perfect discharge can be achieved with only a pair of first and second discharge electrodes sandwiching the sheet.
Since it is possible to remove electricity almost completely with only one set of first and second discharge electrodes, the device can be reduced in size. For example, even when the electricity removal device is attached to a printing press, the degree of freedom in selecting the installation location is reduced. Go up.

  According to the second aspect of the present invention, even if some charges that could not be removed by the DC first and second discharge electrodes remain, they can be removed by the positive and negative ions generated by the AC electrode.

It is a schematic block diagram of the static elimination apparatus of 1st Embodiment. It is the figure which showed polarity arrangement | positioning of the discharge electrode of 1st Embodiment. It is explanatory drawing about the relationship between arrangement | positioning of a discharge electrode, and the ion for static elimination. It is a schematic block diagram of the static elimination apparatus of 2nd Embodiment. It is the figure which showed polarity arrangement | positioning of the discharge electrode of 2nd Embodiment. It is a schematic block diagram of the conventional static elimination apparatus. It is sectional drawing of the electrically charged sheet | seat. It is explanatory drawing of the state which the charged sheet | seat laminated | stacked.

The first embodiment of the present invention shown in FIG. 1 is a static eliminator that neutralizes the surfaces 1a and 1b of the sheet 1 moving in the direction of arrow A at the same time. The sheet 1 is, for example, a leaf sheet output from a printing machine equipped with an image forming process using electrophotography.
As shown in FIG. 1, the static eliminator of this embodiment includes first and second DC electrode bars 12, 13, in order from the upstream side along the movement direction, at positions facing both surfaces 1 a and 1 b sandwiching the sheet 1. First and second AC electrode bars 14 and 15 are provided.

  The first and second DC electrode bars 12 and 13 and the first and second AC electrode bars 14 and 15 are rod-like members each having a length straddling the sheet 1 in the width direction, and a plurality of discharge electrode needles are arranged on a straight line. It is arranged and configured. The first and second DC electrode bars 12 and 13 are connected to DC high voltage sources 16 and 17, respectively, and the AC high voltage source 18 is connected to the first and second AC electrode bars 14 and 15. The first and second AC electrode bars 14 and 15 include a ground electrode (not shown), and discharge is generated between the ground electrode and a discharge electrode needle (not shown).

The first AC electrode bar 14 is one AC electrode of the present invention, and the second AC electrode bar 15 is the other AC electrode.
Each of the electrode bars 12 and 14 is provided with electrode bars 13 and 15 that are opposed to each other with the sheet 1 interposed therebetween, which is the same as the conventional static eliminating device.
However, the first and second DC electrode bars 12 and 13 of the first embodiment are not composed only of discharge electrode needles of either positive or negative polarity, but as shown in FIGS. The positive and negative discharge electrode needles 12a and 13a are alternately arranged.
It should be noted that the discharge electrode needles 12a and 13a facing each other with the sheet 1 interposed therebetween do not necessarily face each other and may be slightly shifted in the width direction or the moving direction of the sheet 1.

FIG. 2 is a view of the first and second DC electrode bars 12 and 13 as viewed from the cross-section in the width direction of the sheet 1 in FIG. 1. The discharge electrode needles 12 a and the second DC electrodes of the first DC electrode bar 12 are shown in FIG. The arrangement of the discharge electrode needles 13a of the bar 13 is shown.
As shown in FIG. 2, the first DC electrode bar 12 provided on the one surface 1a side of the sheet 1 has positive and negative discharge electrode needles 12a alternately arranged in the longitudinal direction thereof. A discharge electrode is formed.

Further, as shown in FIG. 2, the plurality of discharge electrode needles 13 a of the second electrode bar 13 facing the first DC electrode bar 12 are opposed to the discharge electrode facing the surface 1 b facing the sheet 1. The needle 12a is disposed with a reverse polarity. On the surface 1b side, the discharge electrode needles 13a of the second DC electrode bar 13 are arranged so as to alternate between positive and negative in the width direction of the sheet 1, and constitute the second discharge electrode of the present invention. Yes.
The DC high voltage sources 16 and 17 connected to the first and second DC electrode bars 12 and 13 are power sources for applying positive or negative DC high voltage to the discharge electrode needles 12a and 13a according to the arrangement. It is.

2 and 3, in the first and second DC electrode bars 12, 13, the distance between the discharge electrode needles 12a, 12a adjacent to each other in the width direction of the sheet 1, the distance between 13a, 13a is x, and the sheet 1 is When the distance between the discharge electrode needles 12a and 13a facing each other is z, the distance z is smaller than the distance x, that is, distance x> distance z.
The distance between the tips of the electrode needles 12a and 13a is also referred to as the distance z even when the tips of the opposing electrode needles 12a and 13a are not facing each other.

The reason why distance x> distance z as described above will be described below.
In the first and second DC electrode bars 12 and 13 of this embodiment, the discharge electrode needles 12a and 13a that are opposed to each other with the sheet 1 interposed therebetween are set to have opposite polarities. Therefore, considering the electric field formed by only the first and second DC electrode bars 12 and 13, the position indicated by the alternate long and short dash line L in FIG. It becomes surface L.
Therefore, a force directed from the discharge electrode needle 12a toward the zero potential surface L acts on positive and negative ions generated by the first discharge electrode needle 12a on the surface 1a side. Therefore, if the sheet 1 is provided in the vicinity of the zero potential plane L, the positive ions and the negative ions are guided to the vicinity of the sheet 1.

Moreover, the polarities of the discharge electrode needles 12a, 12a adjacent in the longitudinal direction of the first electrode bar 12 are opposite to each other, and the potential is zero near the center of the space between the adjacent discharge electrode needles 12a, 12a (not shown). There will be a zero potential plane. Therefore, a force directed toward the adjacent discharge electrode needle 12a acts on the ions generated by the specific discharge electrode needle 12a.
When the distance x between the adjacent discharge electrode needles 12a and 12a is smaller than the distance z between the opposing discharge electrode needles 12a and 13a, ions generated at the tip of the discharge electrode needle 12a are adjacent to the discharge electrode needle 12a. It becomes easy to be attracted to.
If many ions generated by each discharge electrode needle 12a are attracted to the adjacent discharge electrode needle 12a, the amount of ions that reach the vicinity of the surface 1a of the sheet 1 among the ions generated by the first DC electrode bar 12 Therefore, the generated ions do not contribute to charge removal efficiently.

Therefore, in the first embodiment, the distance z between the discharge electrode needles facing each other is made smaller than the distance x between the adjacent discharge electrode needles 12a and 12a, so that the generated positive ions and negative ions are more efficient. To reach the vicinity of the surface 1 a of the sheet 1.
The same applies to the other surface 1b side of the sheet 1. In this embodiment, the distance x between the discharge electrode needles 13a, 13a of the second DC electrode bar 13 is also made larger than the distance z, and the positive and negative ions are formed on the other surface 1b as well as the surface 1a side. Can efficiently reach the vicinity of the surface 1b.

  In the static eliminator of the first embodiment as described above, positive ions and negative ions generated alternately in the width direction of the sheet 1 by the first DC electrode bar 12 and the second DC electrode bar 13 are The sheet 1 is strongly guided toward the vicinity of both surfaces 1a and 1b. However, the ions generated at the tips of the discharge electrode needles 12a and 13a repel ions of the same polarity and are directed toward the zero potential surface formed between the adjacent discharge electrode needles 12a and 12a and between the 13a and 13a. Therefore, it spreads in the width direction of FIG.

Moreover, since the electric potential is almost zero in the vicinity of each surface 1a, 1b of the sheet 1 as described above, the polarity of ions existing there is not biased to one side. Therefore, positive ions and negative ions are mixed almost uniformly in the vicinity of the surfaces 1a and 1b, and charges of any polarity on the surfaces 1a and 1b are efficiently discharged.
As described above, since the center of the opposing electrode needles 12a and 13a becomes the zero potential surface L, the sheet 1 is placed between the opposing electrodes in order to efficiently remove both surfaces 1a and 1b of the sheet 1 simultaneously. It is preferable to provide it at the center of the distance z.

  As described above, by setting the opposite electrodes across the sheet 1 to have opposite polarities, positive ions and negative ions are efficiently led to the vicinity of the sheet 1, but do not contribute to static elimination of the sheet 1. For example, when the excess ions reach the vicinity of the surface 1a but there is no charge attracting the ions on the surface 1a side, the ions are neutralized by combining with the ions of the opposite polarity simultaneously introduced to the vicinity, Adsorbs to nearby ground metal and disappears. Compared to the conventional case where only ions of one polarity are forcibly guided to the sheet 1, the surface 1a is less reversely charged. This also applies to the other surface 1b side. That is, with the first and second DC electrode bars 12 and 13 only, almost perfect neutralization of both surfaces 1a and 1b is possible.

Further, in the first embodiment, positive ions and negative ions are alternately generated by the first and second AC electrode bars 14 and 15 provided on the downstream side of the first and second DC electrode bars 12 and 13. The charges slightly left on the surfaces 1a and 1b of the sheet 1 can be removed. Note that even if the sheet 1 passes through the first and second DC electrode bars 12 and 13, charges remain on the surfaces 1 a and 1 b because the moving sheet 1 is displaced from the zero potential surface L due to vibration or the like. It happens when it happens. This is because if the sheet 1 is separated from the zero potential plane L, necessary positive and negative ions may not reach the vicinity of the sheet 1.
As described above, in the static eliminator of the first embodiment, for example, positive ions discharged simultaneously from the printing machine and charged in the course of the charged sheet 1 passing between the first and second DC electrode bars 12 and 13. In addition, the surfaces 1a and 1b can be efficiently neutralized simultaneously by the negative ions, and more complete neutralization can be realized by the first and second AC electrode bars 14 and 15. As a result, it is possible to prevent the stacked sheets 1 from adhering to each other electrostatically.

  The static eliminator of the first embodiment does not require two sets of DC electrode bars as in the conventional static eliminator shown in FIG. 6, and only one set of the first and second DC electrode bars 12 and 13 is sufficient. Accordingly, the size of the sheet 1 in the moving direction can be reduced. Therefore, for example, the degree of freedom in installing at the sheet discharge port of the printing press increases.

Further, in the first embodiment, after the charge removal by the first and second DC electrode bars 12 and 13, the charge removal process by the first and second AC electrode bars 14 and 15 is further provided. The appropriate DC high voltage value to be applied to the first and second DC electrode bars 12 and 13 is set according to the distance, and the distance x between the adjacent discharge electrode needles and the opposing discharge electrode needles are set according to the DC high voltage value. If the distance z between them is set appropriately, the first and second AC electrode bars 14 and 15 can be omitted. This is because, as described above, only the first and second DC electrode bars 12 and 13 can simultaneously guide positive ions and negative ions to both surfaces of the sheet 1 without deviation.
If the first and second AC electrode bars 14 and 15 can be omitted, the size of the sheet 1 in the moving direction can be further reduced to reduce the size of the static eliminator. Therefore, the degree of freedom of installation of the static eliminator is further increased. Go up.

In the second embodiment shown in FIGS. 4 and 5, the third and second DC electrode bars 12 and 13 and the first and second AC electrode bars 14 and 15 are arranged along the moving direction of the sheet 1. , 4 DC electrode bars 19 and 20 are different from the first embodiment. Other configurations are the same as those of the first embodiment, and the same reference numerals as those of the first embodiment are assigned to the same components as those of the first embodiment, and detailed descriptions thereof are omitted.
The third and fourth DC electrode bars 19 and 20 are each a rod-like member having a length straddling the sheet 1 in the width direction, and are configured by arranging a plurality of discharge electrode needles on a straight line, and each DC high voltage. Connected to sources 21 and 22.

FIG. 5 is a diagram showing the polarity arrangement of the electrodes when the static eliminator of the second embodiment is viewed from the surface 1a side. The discharge electrode needles 12a and the third DC electrode bars of the first DC electrode bar 12 are shown. 19 shows the polarity arrangement of the 19 discharge electrode needles 19a and the discharge electrodes of the first AC electrode bar 14.
As shown in FIG. 5, the first DC electrode bar 12 provided on the one surface 1a side of the sheet 1 and on the upstream side alternately arranges positive and negative discharge electrode needles 12a in the longitudinal direction, The third DC electrode bar 19 on the downstream side is similarly configured by alternately arranging positive and negative discharge electrode needles, but the first DC electrode bar 12 is arranged along the moving direction of the sheet 1. The discharge electrode needles 12a and the discharge electrode needles 19a of the third DC electrode bar 19 have opposite polarities.

Further, the discharge electrode needles 19a and 20a of the third and fourth DC electrode bars 19 and 20 are also arranged in the same manner as the discharge electrode needles 12a and 13a, and the discharge electrode needles adjacent to each other have opposite polarities. The discharge electrode needles facing each other across 1 are opposite in polarity.
Therefore, the DC high voltage sources 21 and 22 are power supplies that apply a positive or negative DC high voltage to the discharge electrode needles 19a and 20a of the third and fourth DC electrode bars 19 and 20.
As a result, positive and negative ions are alternately generated in both the width direction and the movement direction of the sheet 1.
Further, also in the third and fourth DC electrode bars 19 and 20, the distance x is set between the adjacent discharge electrode needles 19a and 19a and 20a and 20a, and the relationship between the distance x and the distance z between the opposing discharge electrode needles. Is set such that distance x> distance z.

  Further, as shown in FIG. 5, the discharge electrode needles 12a of the first DC electrode bar 12 and the discharge electrode needles 19a having the opposite polarity of the third DC electrode bar 19 arranged at intervals in the moving direction of the sheet 1; And the distance y is larger than the distance z, that is, distance y> distance z. The reason for this is that the electric field lines along the moving direction of the sheet 1 generated between the first DC electrode bar 12 and the third DC electrode bar 19 are led to the vicinity of the surface 1a of the sheet 1. This is to prevent the amount of ions from decreasing.

If the distance y is smaller than the distance z, for example, the amount of ions attracted to the discharge electrode needle 19a side among the ions generated at the tip of the discharge electrode needle 12a increases, and the amount of ions reaching the vicinity of the surface 1a. Will decrease. Similarly, since the ions generated by the discharge electrode 19a are also attracted to the discharge electrode 12a side, in the second embodiment, the distance y is greater than the distance z.
Similarly, on the other surface 1b side of the sheet 1, the distance y between the second DC electrode bar 13 and the fourth DC electrode bar 20 facing the surface 1b is set larger than the distance z. The ions generated by the discharge electrode needles 13a and 20a are efficiently guided to the vicinity of the surface 1b toward the zero potential surface L.

In the second embodiment, positive and negative ions are simultaneously introduced to both surfaces 1a and 1b of the sheet 1 from the first and second DC electrode bars 12 and 13, and third and fourth DC electrodes are provided on the downstream side. The bars 19 and 20 function in the same manner as the first and second DC electrode bars 12 and 13 to remove static electricity, and further remove the charges remaining slightly by the first and second AC electrode bars 14 and 15.
In the second embodiment, after the charge removal by the first and second DC electrode bars 12 and 13, a charge removal process by the third and fourth DC electrode bars 19 and 20 and the first and second AC electrode bars 14 and 15 is further provided. Thus, the generation amount of positive and negative ions is increased, and the both surfaces 1a and 1b can be more completely neutralized at the same time.

  The perfect and almost perfect static elimination means that the surface charges on the surfaces 1a and 1b of the sheet 1 are made almost zero, and adhesion between the laminated sheets 1 that causes various troubles. This is a state where no occurrence occurs. Even if the measured surface potential is zero as the whole of the surfaces 1a and 1b, the state in which charges that generate an attractive force that causes the stacked surfaces 1a and 1b to stick to each other remains is perfect here. It is not static neutralized.

2 and 5 show four discharge electrode needles, this is for explanation, not the actual number of discharge electrode needles. The number of discharge electrode needles is set according to the distance x, the distance z, the applied voltage, the width of the sheet 1, and the like. For example, when used for a printing press, the distance x is set to 30 [mm], z is set to 25 [mm], the applied voltage is set to -9 [kV] and +9 [kV], and the number is set according to the size of the sheet 1. doing.
In the first and second embodiments, the same voltage is applied to the opposing first and second AC electrode bars 14 and 15 by the AC high voltage source 18, but the applied voltage to the first AC electrode bar 14. And the phase of the voltage applied to the second AC electrode bar 15 may be shifted. For example, if the voltages applied to the first and second AC electrode bars 14 and 15 are reversed in phase, the ions generated on both sides of the sheet 1 and the counter electrode have opposite polarities, and the ions are converted into the sheet 1 It is also possible to easily reach the vicinity of the surfaces 1a and 1b.

  This is useful for applications where it is desired to completely eliminate both sides of printed sheets.

1 sheet 1a, 1b (sheet) surface 12 (first discharge electrode) first DC electrode bar 12a (first discharge electrode) discharge electrode needle 13 (second discharge electrode) second DC electrode bar 13a (second discharge electrode) discharge electrode needle 14 first AC electrode bar 15 second AC electrode bar 16 DC high voltage source 17 DC high voltage source 18 AC high voltage source x Distance between adjacent electrodes z Distance between opposing electrodes

Claims (2)

In the static eliminator that neutralizes both sides of the sheet by irradiating both sides of the moving sheet with positive ions and negative ions generated by discharge,
A plurality of first discharge electrodes which are arranged on a straight line facing one surface of the sheet and substantially perpendicular to the moving direction of the sheet, and for applying a DC voltage;
A plurality of second discharge electrodes that are arranged on a straight line that is substantially orthogonal to the moving direction of the sheet and that faces the first discharge electrode across the sheet, and that applies a DC voltage;
The first and second discharge electrodes have opposite polarities of adjacent discharge electrodes, and opposite polarities of the first discharge electrode and the second discharge electrode facing each other across the sheet,
The static eliminator which made the distance between the 1st, 2nd discharge electrodes which oppose on both sides of the said sheet | seat smaller than the distance between adjacent discharge electrodes. The first and second discharge electrodes are provided at a position upstream with respect to the moving direction of the sheet, and are positioned downstream of the first and second discharge electrodes and face one surface of the sheet. And one AC electrode substantially orthogonal to the moving direction of the sheet,
2. The static eliminator according to claim 1, further comprising: the other AC electrode that is opposed to the one AC electrode across the sheet and is substantially orthogonal to the moving direction of the sheet.

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