JP6916540B2 - Water drop removal device and water drop removal method - Google Patents

Description

The present invention relates to a water droplet removing device and a water droplet removing method for removing water droplets from a cap portion attached to a container, and in particular, a cap attached to a container such as a PET bottle or a bottle can filled with a liquid such as a beverage. The present invention relates to a water droplet removing device for removing water droplets from a portion and a water droplet removing method.

A container inspection device that inspects a container conveyed by a conveyor during transportation has been conventionally known. This container inspection device takes an image of the container with a camera and inspects the container based on the image of the container. If water droplets adhere to the outer surface of the container when the container is imaged with a camera, the water droplets appear dark, and the container inspection device cannot obtain correct inspection results. Therefore, on the upstream side of the container inspection device, a plurality of air nozzles for ejecting compressed air are arranged along the conveyor's transport path, and compressed air is applied to the container being transported to remove water droplets.

The above-mentioned inspection of the container is carried out after filling the container with a liquid such as a beverage, closing the opening of the container with a cap portion, and then washing the container and the cap portion with rinse water. Therefore, the water droplets adhere not only to the container but also to the cap portion on the container. Since the water droplets adhering to the cap portion may move to the container, it is necessary to remove the water droplets from the cap portion as well. In a conventional water droplet removing device, compressed air is sent to an air nozzle by a compressor, and a jet of compressed air is sent from the air nozzle to a cap portion on a container to remove water droplets from the cap portion.

Japanese Unexamined Patent Publication No. 2012-153372 Japanese Unexamined Patent Publication No. 2012-78120

However, the compressor requires a lot of electric power, which inevitably increases the running cost. In particular, with the recent increase in speed of production lines, it is necessary to increase the flow rate of compressed air in order to reliably remove water droplets, and the power consumption tends to increase further. Against this background, there is an increasing demand for removing water droplets with less power consumption.

Therefore, the present invention provides a water droplet removing device and a water droplet removing method capable of efficiently removing water droplets from a cap portion on a container with a smaller flow rate of air, and as a result, reducing power consumption. ..

In one aspect, it is a water droplet removing device for removing water droplets from a cap portion attached to a container, the first oblique slit nozzles arranged on both sides of the transport path of the cap portion, and the transport of the cap portion. A first upper slit nozzle arranged above the path, a second diagonal slit nozzle arranged on both sides of the transfer path of the cap portion, and a horizontal slit nozzle arranged on both sides of the transfer path of the cap portion. the provided along the conveying direction of the cap portion, the first oblique slit nozzle, the first upper slit nozzle, are arranged before Symbol second oblique slit nozzle, and in the order of the horizontal slit nozzle, A water droplet remover is provided.

In one aspect, it is a water droplet removing device for removing water droplets from a cap portion attached to a container, the first oblique slit nozzles arranged on both sides of the transport path of the cap portion, and the transport of the cap portion. A first upper slit nozzle arranged above the path, a second diagonal slit nozzle arranged on both sides of the transfer path of the cap portion, and a horizontal slit nozzle arranged on both sides of the transfer path of the cap portion. When the second upper Bei slit nozzle Eteori disposed above the conveying path of the cap portion, along a conveying direction of the cap portion, the first oblique slit nozzle, the first upper slit nozzle the second oblique slit nozzle, said horizontal slit nozzle, and are arranged in the order of the second upper slit nozzle, the water droplet removal device is provided.
In one aspect, the horizontal slit nozzle is located at the same height as the support ring of the container.
In one aspect, the horizontal slit nozzles are at least one set of horizontally elongated slit nozzles facing each other.
In one aspect, the first diagonal slit nozzle is at least one set of diagonal slit nozzles facing each other, and the second diagonal slit nozzle is at least one set of diagonal slit nozzles facing each other.
In one aspect, the first oblique slit nozzle and the second oblique slit nozzle are inclined obliquely downward along the conveying direction of the cap portion.

In one aspect, it is a water droplet removing device for removing water droplets from a cap portion attached to a container, the first oblique slit nozzles arranged on both sides of the transport path of the cap portion, and the transport of the cap portion. a first upper slit nozzle disposed above the path, and a second oblique slit nozzles arranged on both sides of the conveying path of the cap portion, provided with a middle empty box, the first oblique slit nozzle It said first upper slit nozzle, and the second oblique slit nozzle communicates with the interior space of the hollow box, water droplets removal device is provided.
In one aspect, the first oblique slit nozzle and the second oblique slit nozzle are formed on a plate detachably fixed to the hollow box, and the first upper slit nozzle is the hollow box. It is formed in a first flow path structure that is detachably fixed to the water flow path structure.
In one aspect, the water droplet removing device further comprises a blower connected to the hollow box.

In one aspect, it is a water droplet removing method for removing water droplets from a cap portion attached to a container, in which air is blown from a first oblique slit nozzle to both sides of the cap portion while the container is conveyed by a conveyor. After that, air is blown from the first upper slit nozzle to the upper surface of the cap portion while the container is conveyed by the conveyor, and then air is blown from the second oblique slit nozzle while the container is conveyed by the conveyor. Is sprayed on both sides of the cap portion, and then air is blown from the horizontal slit nozzle to both sides of the support ring of the container located below the cap portion while transporting the container on the conveyor. Provided is a method for removing water droplets by blowing air from a second upper slit nozzle onto the upper surface of the cap portion while transporting the container by the conveyor.

In one aspect, the air is air sent from a blower.

According to the present invention, a slit nozzle is adopted as an air nozzle. The slit nozzle can remove water droplets from a relatively wide range with a small flow rate. Air is first blown from the first diagonal slit nozzle to both sides of the cap portion, then from the first upper slit nozzle to the upper surface of the cap portion, and further from the second diagonal slit nozzle to the cap portion. It is sprayed on both sides. When the cap portion is transported together with the container, a large amount of water droplets adhere to the side surface of the cap portion (particularly, the rear portion of the side surface in the traveling direction of the cap portion). The first oblique slit nozzle can guide an obliquely spread air jet from both sides of the cap portion to the side surface of the cap portion and remove water droplets.

Most of the water droplets are removed from the cap portion, but some of the water droplets move from the side surface to the upper surface of the cap portion. Therefore, the first upper slit nozzle guides the jet of air from above the cap portion to the upper surface of the cap portion to remove water droplets. Most of the water droplets are removed from the cap portion, but some of the water droplets move from the upper surface to the side surface of the cap portion. Therefore, the second oblique slit nozzle guides an obliquely spread air jet from both sides of the cap portion to the side surface of the cap portion to remove water droplets. Since the amount of water droplets adhering to the side surface at this stage is considerably small, the jet of air supplied from the second oblique slit nozzle can remove the water droplets from the side surface. In this way, the jet of air is guided to the cap portion in the order of the side surface, the upper surface, and the side surface of the cap portion, so that water droplets can be efficiently removed with a small flow rate of air.

Further, according to the present invention, the horizontal slit nozzle can guide a jet of air to the support ring of the container and remove water adhering to the upper and lower parts of the support ring. In particular, it is difficult to remove water existing in the gap between the lower end of the cap portion and the support ring of the container. According to the present invention, the horizontal slit nozzle can guide a horizontally long jet of air to the support ring and remove water from the gap between the lower end of the cap portion and the support ring of the container.

Further, according to the present invention, the second upper slit nozzle guides a jet of air from above the cap portion to the upper surface of the cap portion to remove water droplets. Since the amount of water droplets adhering to the upper surface of the cap portion at this stage is quite small, the jet of air supplied from the second upper slit nozzle removes all the water droplets remaining on the upper surface of the cap portion from the cap portion. Can be removed.

As described above, according to the present invention, the slit nozzles arranged as described above can efficiently remove water droplets by a jet of air. Therefore, as the air supply source, a blower (blower) having a lower air flow rate can be used instead of the compressor. Blowers require less power consumption than compressors. Therefore, the running cost required for removing water droplets can be reduced.

It is a front view which shows one Embodiment of the water drop removal device. FIG. 5 is a cross-sectional view taken along the line AA shown in FIG. FIG. 2 is a cross-sectional view taken along the line BB shown in FIG. It is the figure which looked at the container and the cap part carried by a conveyor from the top. It is a side view of the container and the cap part carried by a conveyor. It is the figure which looked at the 1st diagonal slit nozzle and the cap part on a container from the side. It is the figure which looked at the 1st upper slit nozzle and the cap part from the top. It is the figure which looked at the horizontal slit nozzle and the cap part from the side.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a front view showing an embodiment of a water droplet removing device for removing water droplets from a cap portion attached to a container, and FIG. 2 is a cross-sectional view taken along the line AA shown in FIG. Is a cross-sectional view taken along the line BB shown in FIG. Examples of containers described below include containers such as PET bottles or bottle cans filled with liquids such as beverages.

The water droplet removing device includes a hollow box 5, two sets of first diagonal slit nozzles 11 and 12, a first upper slit nozzle 13, one set of second diagonal slit nozzle 14, and one set of horizontal slits. It includes a nozzle 15 and a second upper slit nozzle 16. The first diagonal slit nozzles 11 and 12, the first upper slit nozzle 13, the second diagonal slit nozzle 14, the horizontal slit nozzle 15, and the second upper slit nozzle 16 communicate with each other in the internal space of the hollow box 5. ing.

The slit nozzles 11 to 16 are fixed to the hollow box 5. The hollow box 5 and the slit nozzles 11 to 16 are arranged above the conveyor 100 for transporting the container 1. The conveyor 100 is a conveyor such as a belt conveyor, and is configured to linearly convey a large number of containers. A cap portion 2 is attached to the container 1, and the opening of the container 1 is closed by the cap portion 2. The cap portion 2 is linearly conveyed by the conveyor 100 together with the container 1.

In the present embodiment, the hollow box 5 includes a first hollow box 5A and a second hollow box 5B arranged on both sides of the transport path CL of the cap portion 2. The first hollow box 5A and the second hollow box 5B have a first side wall 6 and a second side wall 7 located on both sides of the transport path CL of the cap portion 2, respectively. In one embodiment, the hollow box 5 may be a single hollow box having a first side wall 6 and a second side wall 7 located on both sides of the transport path CL of the cap portion 2.

The water droplet removing device further includes a branch box 20 connected to the first hollow box 5A and the second hollow box 5B, and a blower (blower) 23 connected to the branch box 20. The branch box 20 is arranged above the first hollow box 5A and the second hollow box 5B, and communicates with the first hollow box 5A and the second hollow box 5B through two pipes 25. The blower 23 communicates with the branch box 20 through the blower duct 28. Therefore, the first hollow box 5A and the second hollow box 5B communicate with the blower 23 through the branch box 20, the pipe 25, and the blower duct 28.

The water droplet removing device further includes a branch box 20, a first hollow box 5A, a second hollow box 5B, and an elevating device 30 that raises and lowers the slit nozzles 11 to 16. The elevating device 30 is connected to the branch box 20. The first hollow box 5A, the second hollow box 5B, and the slit nozzles 11 to 16 can move up and down integrally with the branch box 20. The relative height of the slit nozzles 11 to 16 with respect to the cap portion 2 attached to the container 1 on the conveyor 100 can be adjusted by the elevating device 30. The lifting device 30 is composed of a combination of a ball screw mechanism and a servomotor, a manual type position adjusting mechanism (for example, a combination of a vertically extending bolt and a nut), and the like. The configuration of the elevating device 30 is not particularly limited as long as the mechanism can achieve the positioning of 16.

In the present embodiment, the first diagonal slit nozzles 11 and 12 include a set of the first diagonal slit nozzles 11 on the upstream side and a set of the first diagonal slit nozzles 12 on the downstream side. The slit nozzles 11 to 16 include a first diagonal slit nozzle 11 on the upstream side, a first diagonal slit nozzle 12 on the downstream side, a first upper slit nozzle 13, and a second diagonal slit nozzle 13 along the transport direction of the cap portion 2. The diagonal slit nozzle 14, the horizontal slit nozzle 15, and the second upper slit nozzle 16 are arranged in this order.

The first diagonal slit nozzles 11 on the upstream side are arranged on both sides of the transport path CL of the cap portion 2 and face each other. The first diagonal slit nozzle 12 on the downstream side is also arranged on both sides of the transport path CL of the cap portion 2 and faces each other. The first upper slit nozzle 13 is arranged above the transport path CL of the cap portion 2 and faces downward. The second oblique slit nozzles 14 are arranged on both sides of the transport path CL of the cap portion 2 and face each other. The horizontal slit nozzles 15 are arranged on both sides of the transport path CL of the cap portion 2 and face each other. The second upper slit nozzle 16 is arranged above the transport path CL of the cap portion 2 and faces downward.

Each of the first oblique slit nozzles 11 and 12 and the second oblique slit nozzle 14 is inclined obliquely downward along the conveying direction of the cap portion 2. There are two reasons why these diagonal slit nozzles 11, 12, and 14 are tilted diagonally. The first reason is that the jet of air is continuously applied from the upper part to the lower part of the cap portion 2 to push the water droplets on the cap portion 2 downward. In order to achieve this purpose, the angles of the first oblique slit nozzles 11 and 12 and the second oblique slit nozzle 14 with respect to the transport direction of the cap portion 2 are preferably 20 to 60 degrees, more preferably 30 to 50 degrees. Is the range of. The second reason is to prevent the container 1 from tipping over due to the jet of air from the oblique slit nozzles 11, 12, and 14 when the conveyor 100 is stopped. If a vertically long slit nozzle is provided instead of the diagonal slit nozzles 11, 12, and 14, when the conveyor 100 is stopped, the jet of air from the vertically long slit nozzle hits the cap portion 2 in a biased manner, and the container 1 falls. Resulting in. The oblique slit nozzles 11, 12, and 14 can prevent the container 1 from tipping over.

The first upper slit nozzle 13 and the second upper slit nozzle 16 are horizontally long slit nozzles extending in the horizontal direction, and extend perpendicularly to the transport path CL of the cap portion 2. The horizontal slit nozzle 15 is a horizontally long slit nozzle extending in the horizontal direction, and extends in parallel with the transport path CL of the cap portion 2.

The first oblique slit nozzles 11 and 12 are formed on a plate 41 fixed to the first side wall 6 and the second side wall 7, respectively. These plates 41 are detachably attached to the first side wall 6 and the second side wall 7 by screws 45. Therefore, by removing the screw 45, the first oblique slit nozzles 11 and 12 together with the plate 41 can be removed from the first hollow box 5A and the second hollow box 5B.

The first upper slit nozzle 13 is formed in the first flow path structure 51 fixed to the upper wall of the first hollow box 5A. The first flow path structure 51 has an air passage 55 inside, and the first upper slit nozzle 13 communicates with the passage 55. The passage 55 communicates with the internal space of the first hollow box 5A through a through hole 56 formed in the upper wall of the first hollow box 5A. The first flow path structure 51 is detachably attached to the upper wall of the first hollow box 5A by a screw 57. Therefore, by removing the screw 57, the first upper slit nozzle 13 together with the first flow path structure 51 can be removed from the first hollow box 5A.

In one embodiment, the first flow path structure 51 in which the first upper slit nozzle 13 is formed may be detachably attached to the second hollow box 5B. In this case, the air passage 55 in the first flow path structure 51 communicates with the internal space of the second hollow box 5B.

The second oblique slit nozzle 14 and the horizontal slit nozzle 15 are also formed on the plate 41. Therefore, by removing the screw 45, the second diagonal slit nozzle 14 and the horizontal slit nozzle 15 can be removed from the first hollow box 5A and the second hollow box 5B together with the plate 41.

The second upper slit nozzle 16 is formed in the second flow path structure 61 fixed to the upper wall of the second hollow box 5B. The second flow path structure 61 has an air passage 65 inside, and the second upper slit nozzle 16 communicates with the passage 65. The passage 65 communicates with the internal space of the second hollow box 5B through a through hole 66 formed in the upper wall of the second hollow box 5B. The second flow path structure 61 is detachably attached to the upper wall of the second hollow box 5B by a screw 67. Therefore, by removing the screw 67, the second upper slit nozzle 16 together with the second flow path structure 61 can be removed from the second hollow box 5B.

In one embodiment, the second flow path structure 61 in which the second upper slit nozzle 16 is formed may be detachably attached to the first hollow box 5A. In this case, the air passage 65 in the second flow path structure 61 communicates with the internal space of the first hollow box 5A.

When the blower 23 is activated, air is sent to the branch box 20 through the blower duct 28, and further to the first hollow box 5A and the second hollow box 5B through the pipe 25. The slit nozzles 11 to 16 communicate with the internal spaces of the first hollow box 5A and the second hollow box 5B. Therefore, the air that fills the internal spaces of the first hollow box 5A and the second hollow box 5B is ejected toward the transport path CL through the slit nozzles 11 to 16.

FIG. 4 is a top view of the container 1 and the cap portion 2 conveyed by the conveyor 100. As shown in FIG. 4, when the cap portion 2 is conveyed together with the container 1, a large amount of water droplets adhere to the side surface of the cap portion 2 (particularly, the rear portion of the side surface in the traveling direction of the cap portion 2). FIG. 5 is a side view of the container 1 and the cap portion 2 conveyed by the conveyor 100. As shown in FIG. 5, the container 1 includes a support ring 3 located below the cap portion 2. An annular gap is formed between the lower end of the container 1 and the support ring 3, and water tends to collect in this gap.

The water droplet removing device guides a jet of air from the slit nozzles 11 to 16 to the cap portion 2 on the container 1 conveyed by the conveyor 100 in order, and removes water droplets from the cap portion 2. More specifically, while transporting the container 1 by the conveyor 100, air is blown from the first oblique slit nozzles 11 and 12 to both sides of the cap portion 2, and then air is blown from the first upper slit nozzle 13 to the cap portion. After spraying on the upper surface of 2, air is blown from the second oblique slit nozzle 14 to both sides of the cap portion 2. Further, while transporting the container 1 by the conveyor 100, air is blown from the horizontal slit nozzle 15 to both sides of the support ring 3 of the container 1, and then air is blown from the second upper slit nozzle 16 onto the upper surface of the cap portion 2. ..

The first oblique slit nozzle 11 is arranged so as to face each other on both sides of the transport path CL of the cap portion 2. The first oblique slit nozzle 12, the second oblique slit nozzle 14, and the horizontal slit nozzle 15 are also arranged in the same manner. According to such an arrangement, the jet of air is simultaneously supplied to the cap portion 2 from both sides of the cap portion 2, and the water droplets can be removed from the cap portion 2 while preventing the water droplets from being biased.

Hereinafter, the function of each slit nozzle will be described in detail. FIG. 6 is a side view of the first diagonal slit nozzles 11 and 12 and the cap portion 2 on the container 1. FIG. 6 illustrates only one of the two first oblique slit nozzles 11 facing each other and only one of the two first oblique slit nozzles 12 facing each other.

The first oblique slit nozzles 11 and 12 are inclined obliquely with respect to the transport path CL of the cap portion 2 when viewed from the side. In this embodiment, two sets of first diagonal slit nozzles 11 and 12 are arranged. This is because an air jet is supplied to the side surface of the cap portion 2 to which many water droplets are attached, and most of the water droplets are first removed from the side surface of the cap portion 2. In one embodiment, three or more sets of first diagonal slit nozzles may be arranged. When the amount of water droplets adhering to the side surface of the cap portion 2 is small, only one set of diagonal slit nozzles may be arranged.

The first oblique slit nozzles 11 and 12 are located at the same height as the entire cap portion 2 attached to the container 1 on the conveyor 100. The length (longitudinal dimension) of the first diagonal slit nozzles 11 and 12 is longer than the height (longitudinal dimension) of the cap portion. The upper ends of the first oblique slit nozzles 11 and 12 are located higher than the cap portion 2, and the lower ends of the first oblique slit nozzles 11 and 12 are located lower than the support ring 3 of the container 1. Therefore, the first oblique slit nozzles 11 and 12 can guide the jet of air spreading diagonally from both sides of the cap portion 2 to the cap portion 2 and remove water droplets from the entire side surface of the cap portion 2. In particular, the first oblique slit nozzles 11 and 12 can continuously guide an air jet from the upper part to the lower part of the cap portion 2 and push water droplets on the side surface of the cap portion 2 downward. Further, since the first oblique slit nozzles 11 and 12 can also blow air onto the support ring 3 of the container 1, the air jet removes water from the gap between the cap portion 2 and the support ring 3. can do.

Most of the water droplets are removed from the cap portion 2, but some of the water droplets move from the side surface to the upper surface of the cap portion 2. Therefore, the first upper slit nozzle 13 guides the jet of air from above the cap portion 2 to the upper surface of the cap portion 2, and removes water droplets from the upper surface of the cap portion 2. FIG. 7 is a top view of the first upper slit nozzle 13 and the cap portion 2. The first upper slit nozzle 13 is a horizontally long slit nozzle extending across the transport path CL of the cap portion 2. The first upper slit nozzle 13 is located above the cap portion 2 and faces downward. As shown in FIG. 7, the length (dimension in the longitudinal direction) of the first upper slit nozzle 13 is longer than the diameter of the cap portion 2. This is because a horizontally long jet of air removes water droplets from the entire upper surface of the cap portion 2.

The first upper slit nozzle 13 guides a jet of air from above the cap portion 2 to the upper surface of the cap portion 2 and removes water droplets. Most of the water droplets are removed from the cap portion 2, but some of the water droplets move from the upper surface to the side surface of the cap portion 2. Therefore, the second oblique slit nozzle 14 guides an obliquely spread air jet from both sides of the cap portion 2 to the side surface of the cap portion 2, and removes water droplets from the side surface of the cap portion 2. Since the amount of water droplets adhering to the side surface at this stage is considerably small, the jet of air supplied from the second oblique slit nozzle 14 can remove the water droplets from the side surface. In this way, the jet of air is guided to the cap portion 2 in the order of the side surface, the upper surface, and the side surface of the cap portion 2, so that water droplets can be efficiently removed with a small flow rate of air. Since the shape, dimensions, inclination angle, and relative position of the second diagonal slit nozzle 14 with respect to the cap portion 2 are the same as those of the first diagonal slit nozzles 11 and 12, the overlapping description thereof will be omitted.

Further, according to the present embodiment, the horizontal slit nozzle 15 can guide the jet of air to the support ring 3 of the container 1 and remove the water adhering to the upper part and the lower part of the support ring 3. FIG. 8 is a side view of the horizontal slit nozzle 15 and the cap portion 2. In FIG. 8, only one of the two horizontal slit nozzles 15 facing each other is shown.

The horizontal slit nozzle 15 is a horizontally long slit nozzle extending in parallel with the transport path CL of the cap portion 2. As shown in FIG. 7, the horizontal slit nozzle 15 is located at the same height as the support ring 3 of the container 1. Therefore, the horizontal slit nozzle 15 can guide a horizontally long jet of air to the support ring 3 and remove water adhering to the upper and lower parts of the support ring 3. In particular, it is difficult to remove the water existing in the gap between the lower end of the cap portion 2 and the support ring 3 of the container 1. According to the present embodiment, the horizontal slit nozzle 15 guides a horizontally long jet of air to the support ring 3 and removes water from the gap between the lower end of the cap portion 2 and the support ring 3 of the container 1. can.

Further, according to the present embodiment, the second upper slit nozzle 16 guides the jet of air from above the cap portion 2 to the upper surface of the cap portion 2, and removes water droplets from the upper surface of the cap portion 2. Since the amount of water droplets adhering to the upper surface at this stage is quite small, the jet of air supplied from the second upper slit nozzle 16 causes all the water droplets remaining on the upper surface of the cap portion 2 to be removed from the cap portion 2. Can be removed. Since the shape and dimensions of the second upper slit nozzle 16 and the relative position with respect to the cap portion 2 are the same as those of the first upper slit nozzle 13, the overlapping description thereof will be omitted.

As described above, according to the present embodiment, the slit nozzles 11 to 16 can efficiently remove water droplets by a jet of air. Therefore, as the air supply source, a blower (blower) 23 having a lower air flow rate can be used instead of the compressor. The blower 23 requires less power consumption than the compressor. Therefore, the running cost required for removing water droplets can be reduced.

The plate 41 on which the oblique slit nozzles 11, 12, 14 and the horizontal slit nozzle 15 are formed can be removed from the first hollow box 5A and the second hollow box 5B. Similarly, the first flow path structure 51 in which the first upper slit nozzle 13 is formed and the second flow path structure 61 in which the second upper slit nozzle 16 is formed are in the first hollow box 5A. And can be removed from the second hollow box 5B. Therefore, by attaching the plate 41, the first flow path structure 51, and the second flow path structure 61 on which the slit nozzles of different sizes are formed to the first hollow box 5A and the second hollow box 5B, the water droplet removing device Can be used to remove water droplets on cap portions of different sizes.

Further, the elevating device 30 can change the position of the slit nozzles 11 to 16 in the vertical direction. The elevating device 30 can arrange the slit nozzles 11 to 16 at an optimum height at the position of the cap portion 2 on the container 1 conveyed by the conveyor 100. Therefore, the water droplet removing device can be used for removing water droplets on cap portions attached to containers of various sizes.

The water droplet removing device according to the present embodiment can be incorporated into an existing conveyor. In particular, since the slit nozzles 11 to 16 described above are fixed to the hollow box 5, it is not necessary to adjust the relative position between the slit nozzles 11 to 16. Moreover, since the hollow box 5 is compact, it can be arranged above the existing conveyor.

The above-described embodiment is described for the purpose of enabling a person having ordinary knowledge in the technical field to which the present invention belongs to carry out the present invention. Various modifications of the above embodiment can be naturally made by those skilled in the art, and the technical idea of the present invention can be applied to other embodiments. Therefore, the present invention is not limited to the described embodiments, but is construed in the broadest range according to the technical idea defined by the claims.

1 Container 2 Cap part 3 Support ring 5 Hollow box 5A 1st hollow box 5B 2nd hollow box 6 1st side wall 7 2nd side wall 11, 12 1st diagonal slit nozzle 13 1st upper slit nozzle 14 2nd diagonal Slit nozzle 15 Horizontal slit nozzle 16 Second upper slit nozzle 20 Branch box 23 Blower (blower)
25 Piping 30 Lifting device 41 Plate 45 Screw 51 First flow path structure 55 Passage 56 Through hole 57 Thread 61 Second flow path structure 65 Passage 66 Through hole 67 Thread 100 Conveyor CL Conveyor path

Claims (11)

A water droplet removal device for removing water droplets from the cap part attached to the container.
The first diagonal slit nozzles arranged on both sides of the transport path of the cap portion and
The first upper slit nozzle arranged above the transport path of the cap portion and
Second diagonal slit nozzles arranged on both sides of the transport path of the cap portion ,
It is provided with horizontal slit nozzles arranged on both sides of the transport path of the cap portion.
Along the conveying direction of the cap portion, the first oblique slit nozzle, the first upper slit nozzle, before Symbol second oblique slit nozzle, and the are arranged in the order of the horizontal slit nozzle, the water droplet removal device .. A water droplet removal device for removing water droplets from the cap part attached to the container.
The first diagonal slit nozzles arranged on both sides of the transport path of the cap portion and
The first upper slit nozzle arranged above the transport path of the cap portion and
Second diagonal slit nozzles arranged on both sides of the transport path of the cap portion,
Horizontal slit nozzles arranged on both sides of the transport path of the cap portion,
Second upper Bei slit nozzle Eteori disposed above the conveying path of the cap portion,
The first diagonal slit nozzle, the first upper slit nozzle, the second diagonal slit nozzle, the horizontal slit nozzle, and the second upper slit nozzle are arranged in this order along the transport direction of the cap portion. is, water droplets removal device. The water droplet removing device according to claim 1 or 2, wherein the horizontal slit nozzle is located at the same height as the support ring of the container. The water droplet removing device according to any one of claims 1 to 3, wherein the horizontal slit nozzle is at least one set of horizontally long slit nozzles facing each other. The first diagonal slit nozzle is at least one set of diagonal slit nozzles facing each other.
The water droplet removing device according to any one of claims 1 to 4, wherein the second diagonal slit nozzle is at least one set of diagonal slit nozzles facing each other. The water droplet removing device according to any one of claims 1 to 5, wherein the first oblique slit nozzle and the second oblique slit nozzle are inclined obliquely downward along the conveying direction of the cap portion. A water droplet removal device for removing water droplets from the cap part attached to the container.
The first diagonal slit nozzles arranged on both sides of the transport path of the cap portion and
The first upper slit nozzle arranged above the transport path of the cap portion and
Second diagonal slit nozzles arranged on both sides of the transport path of the cap portion,
Equipped with a medium-empty box,
The first oblique slit nozzle, the first upper slit nozzle, and the second oblique slit nozzle communicates with the interior space of the hollow box, water droplets removal device. The first oblique slit nozzle and the second oblique slit nozzle are formed on a plate detachably fixed to the hollow box.
The water droplet removing device according to claim 7, wherein the first upper slit nozzle is formed in a first flow path structure detachably fixed to the hollow box. The water droplet removing device according to claim 7 or 8, wherein the water droplet removing device further includes a blower connected to the hollow box. It is a water droplet removal method for removing water droplets from the cap part attached to the container.
While transporting the container on a conveyor, air is blown from the first oblique slit nozzle to both sides of the cap portion, and then air is blown to both sides of the cap portion.
While transporting the container on the conveyor, air is blown from the first upper slit nozzle onto the upper surface of the cap portion, and then air is blown onto the upper surface of the cap portion.
While transporting the container on the conveyor, air is blown from the second oblique slit nozzle to both sides of the cap portion , and then air is blown to both sides of the cap portion.
While transporting the container on the conveyor, air is blown from the horizontal slit nozzle to both sides of the support ring of the container located below the cap portion, and then air is blown from the horizontal slit nozzle to both sides of the support ring of the container.
A method for removing water droplets, in which air is blown onto the upper surface of the cap portion from a second upper slit nozzle while the container is conveyed by the conveyor. The method for removing water droplets according to claim 10 , wherein the air is air sent from a blower.

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