JPH08136128A - Moisture wiping device for surface of cylinder - Google Patents

Abstract

PURPOSE: To enable a complete moisture removal to be attained in compliance with a severe condition in which a complete removal of moisture is required. CONSTITUTION: This device is comprised of a conveyor 32 for raising some cylinders 31 in one row and transporting them in a horizontal direction; a pair of annular wiping belts 35, 35' arranged at each of both sides of the conveyor 32, run in a different speed in the same direction as that of the conveyor 32 and for wiping off adhered moisture while being contacted with barrels of the cylinders 31; and a vacuum device comprising vacuum rollers 41, 41' abutting against each of the wiping belts 35, 35' so as to suck and remove moisture contained in the wiping belts 35, 35' while being rotated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for wiping off moisture adhering to the surface of a cylindrical body such as a bottle on a conveyor which is horizontally transferred.

[0002]

2. Description of the Related Art An example of a conventional water wiping device of this type is disclosed in Japanese Patent Laid-Open No. 194985/1982, which will be described with reference to FIGS. 4 and 5
In FIG. 1, 1 is a chain conveyor for horizontally transporting beer bottles 2 washed in water and standing up in a row in the direction of the arrow. A plurality of 5 are arranged in the height direction. The V-belt 5 moves in the same direction as the moving direction of the conveyor 1 and in contact with the surface of the bottle 2 at a speed higher than the moving speed of the conveyor 1. On the other side of the conveyor 1 facing the V-belt 5, a wiping belt 8 wound around a driving roller 6 and a driven roller 7 is arranged. The wiping belt 8 is made of nylon base cloth mixed with synthetic fibers and wool and has a good water absorbing property. And then move.
A holding plate 9 is provided on the back of the wiping belt 8 that comes into contact with the bottle 2 so that the wiping belt 8 is not displaced inwardly due to the contact with the bottle 2. Reference numerals 10 and 10 'denote a pair of squeezing rollers made of nylon or the like, and a plurality of sets are arranged so as to sandwich the wiping belt 8. Aperture rollers 10, 10 '
The support shafts 11 and 11 ′ are engaged with long grooves 15 formed on the surfaces of the upper support member 12 and the bracket 14 projecting from the lower support member 13 that face each other. As shown in detail in FIG. 6, female screw portions 16 are provided in the upper and lower ends of the support shaft 11, and bolts 17 are screwed into the female screw portions 16 to make the roller 1
It is designed so that 0 does not separate from any position on the long groove 15. Further, a tension coil spring 18 is provided above the bolt 17.
Is fixed at one end, and the other end of the coil spring 18 is connected to the hook 19
And the hook 19 is engaged with the eyebolt 20. The eyebolt 20 is also provided on the support shaft 11 ′ so as to be laterally provided so as to pass through the bolt 22 screwed into the screw portion 21 so as to be recessed. Reference numeral 23 denotes a nut screwed to the eyebolt 20. By adjusting the nut 23, the clamping pressure of the coil spring 18 on the wiping belt 8 of the rollers 10, 10 ′ can be adjusted. Also, the bolt 22 has a nut 24
Are tightly screwed together to fix the roller 10 ′ at an arbitrary position on the long groove 15.

This conventional example is as described above, and the beer bottles 2 washed with water and erected upright on the conveyor 1 in a row are sequentially provided between the V belt 5 and the wiping belt 8 on the surface thereof. Are transferred in contact with each other, and while being transferred between the both belts 5 and 8, they are rotated toward the wiping belt 8 by the V belt 5, and the water adhering to the surface is wiped off by the wiping belt 8. At this time, the bottle 2 rotates several times, and the surface of the bottle 2 is evenly contacted with the wiping belt 8 over the entire circumference, and the wiping belt 8 is held by the holding plate 9 so as to be constantly in contact with the surface of the bottle 2. Therefore, the wiping is sure and smooth. Then, the bottle 2 from which the water has been wiped is further transferred by the conveyor 1 and sent to a coating film forming process (not shown).
Further, the wiping belt 8 which has absorbed water by wiping is squeezed by the squeezing rollers 10 and 10 ′ having an appropriate nip pressure by the coil spring 18 during transportation.

[0004]

The above-mentioned conventional example has been proposed as a device for removing water after washing in order to form a coating film on the surface of a glass container which is recycled by being recycled. However, an apparatus that handles a container such as a cylinder or a glass bottle close to the cylinder (hereinafter referred to as a cylinder) requires a step of removing water after almost washing with water. And when removing the defective cylinders by inspecting the cylinders that have been washed with water before inserting the contents, and removing the defective cylinders, the small amount of water remaining on the surface of the cylinder sharply affects the quality of the inspection. However, there is a problem that the yield is reduced with respect to the actual number of non-defective products, and it is necessary to completely remove water. In the conventional device as described above, for example, the water transferred to the V-belt 5 reattaches to the cylinder. Alternatively, there is a method of blowing away the moisture with compressed air, but the water droplets escape and remain on the back side of the cylindrical body, resulting in insufficient removal of the moisture. The present invention is intended to solve such a conventional problem, and provides a moisture removing device for the surface of a cylinder, which is capable of completely removing moisture in conformity with the severe conditions required to completely remove moisture. It is what

[0005]

For this reason, according to the present invention, a conveyor for vertically transporting cylinders in a row and a conveyor for horizontally transferring the cylinders are provided on both sides of the conveyor and run in the same direction as the conveyor but at different speeds. Then, a pair of annular wiping belts for contacting the body of the cylindrical body to wipe off adhering water, and a vacuum for sucking and removing water contained in the wiping belts by rotating while contacting with the wiping belts respectively. It is composed of a device, which is a means for solving the problem. In the present invention,
The vacuum device is formed in a hollow cylindrical shape having a plurality of suction holes, a vacuum roller having a felt liner attached to the outer periphery thereof, and a vacuum pump connected to the inside of the vacuum roller.

[0006]

[Operation] A cylinder that has been washed with water and has water on its surface is erected on a slat (chain) conveyor and horizontally transferred.
Two annular wiping belts are arranged on both sides of this slat conveyor, and the two are passed through while being in contact with both sides of the barrel body. The two wiping belts are made of felt having good water absorption and air permeability, and are wrapped around a driving roller and a driven roller, respectively, and the side in contact with the cylinder is run in the same direction as the conveyor and at different speeds. A squeeze roller for squeezing out the water absorbed by the wiping belts is provided on the return side of the two wiping belts. This squeezing roller is wrapped with a felt made of the same material as the wiping belt, is composed of a vacuum roller that can suck in the outside air, and is connected to a vacuum pump for sucking air. The vacuum roller is constantly pressed against the wiping belt by a tension spring and is rotated by friction. As described above, when the cylindrical body having water on its surface is sent to the wiping belt portion by the slat conveyor, it is sandwiched between the two wiping belts and travels at an average speed of both speeds, but both speeds are different. Therefore, the cylinder rotates due to the speed difference, and the side surface of the cylinder sequentially contacts the wiping belt to wipe off the water. Since the cylindrical body is rotated by 180 ° or more before exiting the wiping belt portion, the water around the entire circumference of the cylindrical body is wiped off. Moisture that has moved to the wiping belt moves to the vacuum roller section provided on the return side of the wiping belt, is squeezed here and moves to the vacuum roller, and is drawn to a vacuum while the vacuum roller makes one revolution, and then the outside air At the same time, it is removed from the vacuum roller and discharged via the vacuum pump.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the wiping device of the present invention will be described below with reference to FIGS. 1 is a plan view of the wiping device, FIG. 2 is a front view, and FIG. 3 is a sectional view taken along line AA of FIG. In these drawings, 31 is a cylindrical body such as a bottle, 32 is a slat (chain) conveyor for horizontally transferring the cylindrical body 31 washed in water and standing in a row in the direction of arrow B, 33 is its guide rail, 34 Is its frame, 35, 35 'are annular wiping belts, 36, 36' and 37, 37 'are drive rollers and driven rollers around which said wiping belts 35, 35' are wound, 38, 38 '(Fig. 2). ) Is each drive roller 3
6, 36 'and driven units of driven rollers 37, 37', 39, 39 'are geared motors for driving the driving rollers 36, 36', and 40, 40 'are fixed to the frame 34 via brackets. The wiping belt 3
Belt guides provided on the inner back of the 5,35 ', 41,4
1'is a vacuum roller, and 42,42 'are a pair of upper and lower, respectively, and the vacuum rollers 41,41' are provided at one end.
Rotatably supporting the arm, 43 and 43 '(FIG. 1) are bearing units that rotatably support the other ends of the arms 42 and 42' on the frame 34, and 44 and 44 'are the vacuum rollers 41 and 41. 'The wiping belt 3
5, a tension (coil) spring for urging it toward the 35 'side, 45 a vacuum pump, 46, 46' the vacuum rollers 41, 41 'and the vacuum pump 4
5 is an air pipe connecting 47, 47 'is a rotary joint provided between the vacuum rollers 41, 41' and the air pipes 46, 46 ', and 48 is the air pipes 46, 46'.
Is a three-pronged joint for branching (Fig. 3). The wiping belts 35, 35 'are made of water-absorbing and air-permeable felt, and the tensioner (not shown) changes the position of the mounting bolts of the bearing units 37, 37' in the long grooves to adjust the winding length. It is configured to be. As shown in FIG. 3, the vacuum rollers 41, 41 'are rotatably supported by the arms 42, 42', and are cylindrical roller shafts having a large number of pores, elliptical holes, slit-shaped elongated holes or the like formed on their side surfaces. The cylinders 49, 49 'and this roller shaft cylinder 4
The wiper belts 35, 35 'wound around the outer circumferences of the belts 49, 49' and felt liners 50, 50 'formed by laminating thick annular felts of the same material as each other. The inner chamber of 49 'is a rotary joint 47, 4
It communicates with the vacuum pump 45 via 7'and air piping 46,46 '. This vacuum roller 41, 4
1'is constantly pressed against the wiping belts 35, 35 'by the tension springs 44, 44' so that the pressing force can be adjusted, and is rotated by a frictional force.

The operation of the wiping device having the above structure will be described. Before
Cylinders 31, 31 ... Washed in the process are slatted
It is placed on the bearer 32 in an upright state and fed in the direction of arrow B in FIG.
Two wiping belts 35, 3 that are placed side by side
It is sandwiched between the 5'and two places on the left and right to wipe belts 35, 3
It moves in contact with the surface of 5 '. Each wiping belt 35,3
The belt guides 40, 40 'on the inner back surface of the 5'are wiped off.
The belts 35, 35 'are pushed by the tubular body 31 and escape to the outside.
To prevent the gap between the two wiping belts 35, 35 '.
Is adjusted so as to sandwich each cylinder 31 with an appropriate pressure.
It Speed v of wiping belt 35₁Is the speed of the wiping belt 35 '
Degree v ₂It is configured to be slower,
While moving at the average speed of both, the speed difference v of both₁−
v₂Rotation in the direction of arrow C (Fig. 1) at an angular velocity ω proportional to
It The rotation angle of the cylindrical body 31 is the angular velocity ω and the contact length (axial distance).
Distance) Determined by l and set to be 180 ° or more.
Set. Therefore, the cylindrical body 31 has the wiping belts 35, 35 '.
From both sides with the wiping belt 35 or 35 'while passing between
It comes into contact and wipes off the water around it. Wipe that has absorbed water
The take belts 35, 35 'are reversed by the drive rollers 36, 36'.
And the vacuum rollers 41, 41 'provided on the return side
Go to the section and squeeze here with felt liner 50, 50 '
And is sucked and the moisture is felt liner 50, 50 '
, And then drilled in the roller shaft cylinders 49, 49 'together with the outside air.
Collected in the vacuum pump 45 through the pores
It is discharged from a discharge port (not shown). Felt liner 5
0, 50 'is worn by contact with the wiping belts 35, 35'.
Rotation occurs due to rubbing force, and the water content becomes
Vacuum pump 45 sucks and removes with negative pressure
Then start the squeezing operation again.

[0009]

As described in detail above, the wiping device of the present invention has the following advantages. (1) By wiping from both sides with two wiping belts at the same time, the wiping efficiency is improved without increasing the speed difference between the wiping belts, and after wiping each wiping belt. Since the water content is low, the removal of water from the surface of the cylinder is ensured and the wiping ability in continuous wiping operations is improved. (2) Moisture on the wiping belt squeezed out by the rollers is removed by suction instead of flowing down and removed, so that the water remaining on the wiping belt is sufficiently reduced and the wiping is completed.
Further, even if the wiping belt is not strongly sandwiched by the rollers, the water content of the wiping belt can be removed, so that the durability time of the wiping belt becomes long. (3) Since the wiping belt is moved in the same direction as the cylinder moved by the conveyor, the behavior of the cylinder when entering and leaving the wiping belt is stable, and the cylinder does not fall down. The operating rate can be improved and the processing capacity can be improved.

[Brief description of drawings]

FIG. 1 is a plan view of an embodiment of a wiping device of the present invention.

FIG. 2 is a front view of an embodiment of the wiping device of the present invention.

FIG. 3 is a sectional view taken along line AA of FIG. 2;

FIG. 4 is a plan view of a conventional wiping device.

FIG. 5 is a sectional view taken along line II-II of FIG.

6 is an enlarged cross-sectional view taken along the line III-III of FIG.

[Explanation of symbols]

 31 Cylindrical body 32 Slat conveyor 35, 35 'Wiping belt 41, 41' Vacuum roller 45 Vacuum pump 50, 50 'Felt liner

Claims (2)

[Claims] 1. A conveyor for vertically transporting a cylinder in a row and horizontally transferring the same, and the conveyors are respectively arranged on both sides of the conveyor, run in the same direction as the conveyor at different speeds, and contact with the body of the cylinder. And a vacuum device that sucks and removes the water contained in the wiping belt by rotating the wiping belt by abutting against each of the wiping belts. Water wiper for body surface. 2. The vacuum device is formed in a hollow cylindrical shape having a plurality of suction holes, a vacuum roller having a felt liner attached to the outer periphery thereof, and a vacuum pump connected to the inside of the vacuum roller. The water wiping device for the surface of the cylinder according to claim 1.