JP2017013416A - Spray device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a spray device which further inhibits floating mist from flowing to the outside of a housing (3).SOLUTION: A spray device (1) is used to spray a liquid to a rotary roller (11) configured to rotate and includes: a box shaped housing (3) having a spray opening (2) facing the rotary roller (11); a spray nozzle (4) which sets a spray direction toward the opening (2) of the housing (3) in the housing (3); a spray mask (5) which is disposed between the spray nozzle (4) and the housing (3) and inhibits spray at an outer portion of a spray pattern (14) of the spray nozzle (4); and mist shields (7)(8).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a spray device that is useful when applied to a dampening water supply device for a newspaper rotary press.

  In an offset newspaper rotary press used for newspaper printing or the like, it is necessary to supply dampening water to the plate cylinder. The thickness of the dampening water film on the plate cylinder is usually a few microns. In order to form this water film, a dampening water roller rotating in contact with the plate cylinder is used. That is, first, dampening water is supplied to the surface of the dampening water roller (rotating roller), and then transferred from the dampening water roller directly to the plate cylinder via a plurality of rollers.

  Various techniques have been studied for supplying dampening water to the dampening water roller, but at present, the spray method is mainly used in newspaper rotary presses. In the spray method, a plurality of spray nozzles are arranged along the longitudinal direction of the dampening water roller to form a spray device, and dampening water is sprayed on the surface of the dampening water roller.

  The spray device is required to have a function of preventing spray mist from being scattered in addition to the original function of the spray device. Not all of the fountain solution sprayed by the spray device will adhere to the fountain solution roller. A part of the spray does not reach the surface of the dampening water roller, but is scattered as a floating mist. This floating mist is condensed in the printing press and dripped onto the printing paper, causing printing defects.

  Patent Document 1 describes a technique for reducing floating mist. This spray device includes a box-shaped housing having an opening toward the dampening water roller. Spray nozzles are arranged side by side at the bottom of the housing. What is characteristic is that a mist shield mechanism for preventing scattering of mist is provided at the upper and lower ends of the opening of the housing. This mist shield mechanism is provided with ducts having openings toward the dampening water roller at the upper and lower ends of the opening of the housing, and discharges high-pressure air from the duct. As a result, the scattered mist generated in the housing does not flow out of the housing. Further, foreign matter such as ink mist does not enter the housing from the outside of the housing. That is, the mechanism of the mist shield has a function of shielding the inside and the outside of the housing with respect to the floating mist by combining the duct and the high-pressure air.

  The spray device described in Patent Document 2 has a configuration in which a spray mask for forming a spray pattern is provided in an opening portion of a housing. The spray pattern from the nozzle is typically conical. The spray mask suppresses the outside of the spray pattern with a lot of floating mist. It is said that the suppressed spray is collected in the housing and does not go out of the housing. Although it has a simple structure, it is difficult to produce an effect as a measure for suppressing floating mist.

  The technique described in Patent Document 3 is an example of a cleaning apparatus, but a technique applicable to a spray apparatus is also described. The technique described here is provided with high-pressure air nozzles at the upper and lower ends of the opening so as to prevent the occurrence of the inside of the housing from flowing out of the housing.

International Publication No. 2009/041582 JP 2001-301116 A Japanese Patent Laid-Open No. 6-115057

  However, even with the techniques described in Patent Literature 1, Patent Literature 2, and Patent Literature 3, mist flowing out of the housing may not be sufficiently suppressed. This is because the cause of the mist in the housing flowing out of the housing is complex.

In order to obtain the floating mist suppression effect with the technique described in Patent Document 1, a relatively large amount of high-pressure air is required.
In the technique described in Patent Document 2, floating mist generated in a large amount in the housing is pushed out of the housing through the gap between the dampening water roller and the housing.
The technique described in Patent Document 3 consumes a larger amount of high-pressure air than the technique described in Patent Document 1.

  This invention is made in view of such a situation, and it aims at providing the spray apparatus which can suppress further the mist which flows out of a housing further. Another object of the present invention is to provide a spray device that can suppress floating mist to the outside of the housing even if the consumption of high-pressure air is reduced.

  In order to solve the above-mentioned problems, a spray device according to the present invention is a spray device for spraying a liquid toward a rotating rotating roller, and a box-shaped housing having a spray opening toward the rotating roller, and the housing A spray nozzle disposed in a direction of spraying toward the spray opening of the housing, and disposed between the spray nozzle and the spray opening, and spraying an outer portion of the spray pattern of the spray nozzle. A spray mask for masking, and a mist shield provided at an upstream side and a downstream side in the rotation direction of the rotating roller at an end of the housing on the spray opening side, and the mist shield is a longitudinal portion of the rotating roller. A duct structure extending in the direction and having an opening toward the surface of the rotating roller. It has been a major feature to be.

  The spray device of the present invention is characterized in that the mist shield includes a high-pressure air supply tube for supplying high-pressure air into the duct structure.

  Furthermore, the spray device of the present invention is mainly characterized in that only the mist shield on the downstream side in the rotation direction of the rotating roller includes a high-pressure air supply tube for supplying high-pressure air into the duct structure.

  The present invention reduces the floating mist in the vicinity of the rotating roller by dividing the inside of the spray device housing roughly into two parts by a spray mask and suppressing excess spray by the spray mask. Furthermore, the mist flowing out of the housing is reduced by the mist shield provided at the opening end of the housing. Thereby, there exists an effect that it can be set as the spray apparatus which can suppress further the outflow of the floating mist to the exterior of a housing.

It is a side view of the spray device concerning one embodiment of the present invention. It is sectional drawing between MN of FIG. 3 is an enlarged view of a mist shield 8. FIG. This is another embodiment of the mist shield 8. This is another embodiment of the mist shield 7.

  FIG. 1 is a side view of a spray device according to an embodiment of the present invention. 1 is a spray device, and 11 is a dampening water roller (rotating roller). The dampening water roller 11 rotates in the clockwise direction on the drawing as indicated by an arrow 12. 3 is a housing. The housing 3 supports the main components of the spray device 1. The housing 3 is an elongated box having an opening 2 (also referred to as a spray opening) toward the outer peripheral surface 13 of the dampening water roller 11.

  4 is a spray nozzle. The spray nozzle 4 is disposed in the housing 3 on the side facing the opening 2. 14 is a spray pattern. The spray pattern 14 is a fan-shaped pattern drawn by the spray of dampening water discharged from the spray nozzle 4. The spray pattern 14 spreads in a fan shape starting from the spray nozzle 4 and reaches the outer peripheral surface 13 of the fountain solution roller 11. The housing 3 is an elongated box, and a plurality of spray nozzles 4 are provided along the longitudinal direction. The actual number of spray nozzles 4 depends on the length of the dampening water roller 11 and the spread angle of the spray pattern 14.

  5 is a spray mask. The spray mask 5 is provided between the spray nozzle 4 and the opening 2 and has a mask opening 15. The mask opening 15 changes the shape of the spray pattern 14. The spray mask 5 suppresses (masks) a part of the spray pattern 14 so that the spray on the outer peripheral portion of the spray pattern 14 does not reach the opening 2. The spray mask 5 divides the interior of the housing 3 into two, an opening side chamber 23 and a nozzle side chamber 24.

  7 and 8 are mist shields. The mist shields 7 and 8 are provided at the end portions 16 and 17 on the opening 2 side of the housing 3. The mist shield 7 is provided on the upstream side with respect to the rotational direction 12 of the dampening water roller 11, and the mist shield 8 is provided on the downstream side.

  FIG. 3 is an enlarged view of the mist shield 8. As shown in FIG. 3, the mist shield 8 includes a housing 3, a first plate member 8 </ b> A, a second plate member 8 </ b> B, and a high-pressure air supply tube 10. Provided. The first plate-like member 8 </ b> A is installed on the inner side of the housing 3 so as to be substantially parallel to the housing 3, and the lower part thereof is bent and connected to the housing 3.

  The housing 3 and the first plate-like member 8 </ b> A form an opening 19 facing the dampening water roller 11 at the upper part, and form a duct 22 in the enclosed space. The second plate-like member 8B is installed further inward (right side in the drawing) than the first plate-like member 8A and substantially parallel to the housing 3 and the first plate-like member 8A, and the lower part thereof is bent. Connected to the housing 3. The first plate-like member 8A and the second plate-like member 8B form an opening 18 facing the dampening water roller 11 in the upper part thereof, and form a duct 20 in the enclosed space.

  The mist shield 8 has a duct structure provided with openings 18 and 19 toward the outer peripheral surface 13 of the dampening water roller 11. Here, the duct structure is a structure having a pipe-like shape. For example, the duct 20 and the duct 22 in FIG. 3 both have a pipe-like structure extending in the longitudinal direction (rotational axis direction) of the dampening water roller 11, and if there are no openings 18 and 19, Is also a structure that becomes a pipeline. Therefore, the duct structure can be said to be a pipe line having an opening toward the dampening water roller 11 in the present invention.

  The duct 20 that forms the opening 18 is provided with a high-pressure air supply tube 10 that supplies high-pressure air (the high-pressure air supply tube is also simply referred to as a tube). The tube 10 is a hollow structure and includes a plurality of air nozzles 21. The tube 10 is supplied with high-pressure air from a high-pressure air source (not shown). Then, air blows out from the air nozzle 21. Air is supplied from the duct 20 toward the outer peripheral surface 13 of the dampening water roller 11. The duct 22 forming the opening 19 is provided adjacent to the duct 20. In addition, since the tube 10 should just be a structure which can supply high pressure air, the selection range of a shape and a raw material is wide, and the cross section may be a metal tube with a rectangle.

  Thus, it can be said that the mist shield 8 includes the duct 22, the duct 20, the opening 19, the opening 18, and the high-pressure air supply tube 10 including the air nozzle 21.

  Since the mist shield 7 has the same configuration as the mist shield 8, a description thereof will be omitted, but the first plate-like member 8A, the second plate-like member 8B, the duct 22, the duct 20, and the high-pressure air supply tube 10 of the mist shield 8 are These correspond to the first plate-like member 7A, the second plate-like member 7B, the duct 30, the duct 31, and the high-pressure air supply tube 9 of the mist shield 7 (see FIGS. 1 and 5), respectively.

FIG. 2 is a cross-sectional view taken along line MN in FIG. When viewed in cross section, the outer peripheral surface 13 of the fountain solution roller 11 is visible from the spray nozzle 4 side through the mask opening 15 of the spray mask 5. The spray pattern 14 is elliptical when viewed in the cross-sectional view of FIG. 2, the Y direction is wider than the mask opening 15, and the X direction partially overlaps the spray pattern 14 of the adjacent spray nozzle 4. 25 is a graph of the water amount distribution of the spray nozzle 4. 26 is the amount of water blocked by the spray mask 5. 27 is the amount of water passing through the mask opening 15.
That is, when the water amount 26 and the water amount 27 are added, the water amount 25 is obtained.

  The operation of the above configuration will be described. The housing 3 has a box shape and surrounds the spray pattern 14 discharged from the spray nozzle 4 as a whole. As a result, it can be said that the floating mist is reduced as compared with the case where the housing 3 is an open type.

  With reference to FIG. 1, when the dampening water roller 11 rotates, a boundary layer is formed on the outer peripheral surface 13 thereof. The boundary layer pulls the air in the housing 3 to the outside as the dampening water roller 11 rotates, and pulls the air outside the housing 3 to the inside of the housing 3. Further, there is a gap of about 5 mm between the end portions 16 and 17 of the housing 3 and the outer peripheral surface 13. This gap causes the floating mist inside the housing 3 to flow out of the housing 3 regardless of the presence or absence of the boundary layer.

  The mist shield 7 and the mist shield 8 provided on the housing 3 reduce floating mist flowing out from the housing 3 and reduce foreign matters such as ink mist flowing into the housing 3. Referring also to FIG. 3, the mist shield 8 blows air out of the duct 20, thereby reducing the flow of floating mist between the open side chamber 23 inside the housing 3 and the outside of the housing 3. The duct 22 is provided adjacent to the duct 20. The action of the duct 22 can be expected to capture the mist that has risen in the duct 20.

  In order to observe the mist flowing out of the housing 3, an image is taken by shining light near the housing 3 with a strong light source. In addition to the observation of the image, when the housing 3 removed after the experiment is observed, the amount of floating mist captured by the duct 20 and the duct 22 can be measured as the liquid amount. Although the action of the duct 20 cannot be clearly confirmed in the image, the trapped floating mist is captured to the extent that it can be measured as the amount of liquid, so it can be confirmed that there is an action of capturing the floating mist. However, since the amount of capture is such that it cannot be clearly confirmed in the image, a practical mist shield effect can be obtained even when only the duct 20 for supplying high-pressure air is used to simplify the structure. The mist shield 7 has the same effect as the mist shield 8.

  With reference to FIG. 1, the spray mask 5 has an action of suppressing floating mist inside the opening-side chamber 23. The generation source of the floating mist inside the housing 3 is a spray discharged from the spray nozzle 4. On the other hand, when the spray pattern 14 is analyzed by the spray analysis system alone, it can be seen that the spray outside the spray pattern 14 is mainly floating mist. Therefore, if the outer part of the spray pattern 14 does not enter the opening side chamber 23, the floating mist in the opening side chamber 23 decreases. Actually, when the action of the spray mask 5 was confirmed in the previous image photographing, it was confirmed that the mist flowing out of the housing 3 was surely reduced.

As described above, the housing 3, the spray mask 5, and the mist shields 7 and 8 can reduce floating mist that flows out of the housing 3 together.
Further, the amount of air supplied to the duct 20 can be reduced by the action of the spray mask 5 as compared with the conventional case, and thus there is an effect of reducing energy consumption.

  FIG. 4 shows another embodiment of the mist shield 8. In addition to the configuration of the mist shield 8 of FIG. 3, the mist shield 8 of FIG. 4 further includes a duct 28, a plate-like member 8 </ b> C for forming the duct 28, and a high-pressure air supply tube 29. The tube 29 is supplied with high-pressure air equivalent to that of the tube 10. In this way, the structure is complicated, but the shielding action of the mist shield 8 is enhanced. Furthermore, it has been confirmed that the total amount of high-pressure air supplied to the tubes 10 and 29 has a high shielding effect even when the air supply amount is equal to that in the embodiment shown in FIG.

  FIG. 5 shows another embodiment of the mist shield 7. FIG. 1 shows an example in which the upstream mist shield 7 and the downstream mist shield 8 have the same structure with respect to the rotation direction 12 of the dampening water roller 11. However, since the upstream mist shield 7 has a constant rotation direction of the dampening water roller 11, if the distance between the end 16 of the housing 3 and the outer peripheral surface 13 of the dampening water roller 11 is short, the mist shield 7 is simplified. Also good. Actually, although it should be confirmed by an experiment, when the end portion 16 and the outer peripheral surface 13 are close to each other, the influence of the boundary layer of the outer peripheral surface 13 is large, so that the floating mist from the opening side chamber 23 to the upstream side is small. Therefore, the duct 31 can be made not to have a high-pressure air supply tube as in the embodiment shown in FIG.

DESCRIPTION OF SYMBOLS 1 Spraying device 2 Opening 3 Housing 4 Spray nozzle 5 Spray mask 7, 8 Mist shield 9 High pressure air supply tube 10 High pressure air supply tube 11 Dampening water roller (rotating roller)
12 rotational direction 13 outer peripheral surface 14 spray pattern 15 mask opening 16 end 17 end 18 opening 19 opening 20 duct 21 air nozzle 22 duct 23 opening side chamber 24 nozzle side chamber 25 water amount distribution graph 26 water amount blocked by spray mask 27 mask opening Amount of water passing through 28 duct 29 high pressure air supply tube 30 duct 31 duct

Claims (3)

In a spraying device for spraying liquid towards a rotating rotating roller,
A box-shaped housing having a spray opening toward the rotating roller;
A spray nozzle disposed in the housing with a spray direction directed toward the spray opening of the housing;
A spray mask that is disposed between the spray nozzle and the spray opening and suppresses spraying of an outer portion of the spray pattern of the spray nozzle;
A mist shield provided on the upstream side and the downstream side in the rotational direction of the rotating roller at the spray opening side end of the housing,
The spray device, wherein the mist shield has a duct structure extending in a longitudinal direction of the rotating roller and having an opening toward a surface of the rotating roller.   The spray device according to claim 1, wherein the mist shield includes a high-pressure air supply tube that supplies high-pressure air into the duct structure.   2. The spray device according to claim 1, wherein only the mist shield on the downstream side in the rotation direction of the rotating roller includes a high-pressure air supply tube that supplies high-pressure air into the duct structure.