JP7297315B2 - packaging equipment - Google Patents

Description

TECHNICAL FIELD The present invention relates to a packaging device for wrapping a belt-shaped film around an article such as a container.

2. Description of the Related Art Conventionally, as a device for packaging a container with a lid containing contents such as food, there is a packaging device that wraps a belt-shaped film around the outer periphery of the container. In recent years, food manufacturers have started to partially wrap the outer circumference of cup noodles, lunch boxes, and other containers sold at supermarkets and convenience stores with film in an effort to reduce material costs and create attractive products. There is a demand for equipment with high packaging capacity that can be mass-produced without loss.

For example, Patent Document 1 discloses a technique in which a product is brought into contact with a vertically extending film to which a predetermined tension is applied by a tension roller provided in a film transfer path, and the film is wrapped around the product. disclosed. However, in the packaging apparatus described in Patent Document 1, when the film is wrapped around a lightweight container such as food while being in contact with the film, a response delay in tension adjustment occurs due to the movement of the tension roller. The container is pulled backward in the transport direction by the film. In addition, if the transport speed of the container is increased in order to increase the packaging capacity per unit time of the packaging apparatus and achieve mass production, the energy given to the film increases. Therefore, the frequency of tension adjustment of the tension roller tends to be high, which tends to be complicated.

Collection of well-known and commonly used techniques (sequel, packaging industry) February 24, 1981 Patent Office JP 2017-56990 A

For this reason, Patent Literature 2 proposes a packaging device for feeding a film by controlling the rotation of a drive (feeding) roller without using a tension roller. However, in the packaging apparatus described in Patent Document 2, if the conveying speed of the container is increased and the container is brought into contact with the film in order to increase the packaging capacity, packaging defects such as the joints of the upper and lower films coming off occur. It has been found. The reason for this is thought to be that the upper and lower films sandwiched by the sealer begin to heat-seal each other, and before finishing the heat-sealing, a large external force is applied.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a packaging apparatus capable of increasing productivity by reducing the load on the film connection points until the end of one packaging cycle.

In order to solve the above problems, the packaging apparatus of the present invention employs the following means. First, the invention according to claim 1 is provided with a first conveyor (13) having a mounting surface for conveying an article (W) placed on the mounting surface, and an article (W) conveyed by the first conveyor (13). Based on the article detection means (61) for detecting the arrival of the article (W) and the detection information of the article (W) detected by the article detection means (61), from the end portion (13E) on the placement surface A second conveyor (14) that temporarily stops conveying when the received article (W) is conveyed to a specific position (K), an end portion (13E) on the placing surface and the second conveyor (14). A belt-shaped film (F) is wound and guided at a position spaced apart vertically through the gap (S) so that it can extend in the vertical direction through the gap (S) of the transport start end (14S). Upper film support means (26, 29) and lower film support means (27, 29, 34, 35) arranged in the same manner, and said film ( An upper film conveying means (24a) for feeding the film (F), and a lower film conveying means (24b, 31) for feeding the film (F) toward the lower film supporting means (27, 29, 34, 35). ) and at least one of the upper film transport means (24a) and the lower film transport means (24b, 31) (24a, 24b). An original roll (21) arranged as a supply source of the film (F) sent out, a second film conveying means (23) for pulling out the film (F) from the original roll (21), and the original Between the reverse roll (21) and the second film conveying means (23), a printing means (22) for printing on the film (F), and a side on which the printing means (22) is arranged. It is a part of the film transport path (20) and forms a film transport path (20a) between the second film transport means (23) and one of the film transport means (24a), and the printing means film feeding amount adjusting means (25) for compensating for the shortage of the film feeding amount by said second film feeding means (23) with respect to the film feeding amount by said one of said film feeding means (24a) accompanying the printing process by (22); Then, while the front part (7) of the article (W) facing the downstream side of the conveying direction of the article (W) is in contact with the film (F) extending in the vertical direction, the article (W) is moved to the above An upper film (F5) that passes over the article (W) and extends to the rear (8) side of the article (W) after passing over the conveying start end (14S) of the second conveyor (14) and the lower film (F6) extending to the rear (8) side of the article (W) through the lower side of the article (W). A pair of sealing bodies (41, 42, 51, 52) that open and close in the vertical direction and are spaced apart from each other, sandwiching and welding sealing means; The seal body (41, 42, 51, 52) and cutting means for cutting the film (F), and the first film conveying means (24) cuts the article (F) based on the information detected by the article detecting means (61). W) specifies the second conveyor (14) after contacting the film (F) extending in the vertical direction and crossing the conveying start end (14S) of the second conveyor (14) A prescribed area ( Z1, Z2), the first film conveying means (24) is driven to send out the film (F), and the article (W) is moved to the specific position ( Although the film (F) contacts the article (W) until it reaches K), the film (F) is arranged so that the article (W) cannot be pulled backward in the conveying direction by the film (F). ), and the connection caused by the approach of the sealing bodies (41, 42, 51, 52) after the second conveyor (14) temporarily stops conveying the article (W) The first film conveying means (24) is driven to feed the first film so that the force for pulling the film (F) applied to the location (F3) is less than the force capable of releasing the connection at the connection location (F3). The film (F) for the remaining film length of the film length required for one package, which was not satisfied by the film feeding by means, ), and the second conveyor (14) moves the article (W) along with the closing operation of the pair of seal bodies (41, 42, 51, 52). When a force attracting the article (W) to the upstream side in the conveying direction is generated in the film (F), the conveying of the article (W) is kept temporarily stopped.

According to the first aspect of the present invention, the packaging device draws out the film (F) from one of the film conveying means (24a) and the second film conveying means (23), and these film conveying means (23, 24a) ) is provided with a film feeding amount adjusting means (25) capable of adjusting the difference in the feeding amount of the film (F) occurring during the period ). With this configuration, even if the film feeding amount by the second film transporting means (23) is less than the film feeding amount by one of the film transporting means (24a) due to the printing process by the printing means (22), the shortage is compensated for. can compensate. The timing of sending the film (F) by one of the film conveying means (24a) is one packaging cycle (after cutting the film (F) sandwiched by the sealing bodies (41, 42, 51, 52), the next It is only a part of the timing in the cycle of wrapping the film (F) around the article (W) to be processed, sandwiching the film (F) with the sealing bodies (41, 42, 51, 52) and cutting it. In addition, the shorter the time until the next article (W) arrives, the shorter the film feeding operation of one of the film conveying means (24a) is stopped. From this, the film feeding speed when one of the film conveying means (24a) feeds the film (F) is the second film conveying means ( 23) is faster than the film feeding speed. Therefore, on the upstream side and the downstream side of the film feeding amount adjusting means (25), the feeding timing and film feeding speed of the film (F) corresponding to one packaging length (the length used for one packaging) are instantaneous. are different. As the number of packages per minute (packaging capacity) increases, the difference in film feeding amount becomes more conspicuous. can. The first film conveying means (24) is configured such that the film (F) is sent out by the first film conveying means until the article (W) reaches the specific position (K) of the second conveyor (14). . The first film feed means moves the film (F) to the article ( The film (F) is fed out in such a way that the film (F) in contact with the article (W) cannot cause the article (W) to be pulled backward in the conveying direction. Thereby, the load applied to the connection point (F3) can be reduced. For example, in order to position the connection point (F3) in the specified area (Z1, Z2), it is not necessary to pull the upper or lower film (F) after the article (W) is placed on the film (F). may In addition, the first film conveying means (24) is operated by the second film conveying means after the second conveyor (14) temporarily stops conveying the article (W), and the film conveying by the first film conveying means is insufficient. The remaining length of the film (F) required for one package is further fed out. The second film feeding means has a force that pulls the film (F) applied to the connection point (F3) as the seal bodies (41, 42, 51, 52) approach and is capable of releasing the connection of the connection point (F3). The film (F) is fed out so that the With these configurations, the film (F) can be wrapped around the article (W) and sandwiched while suppressing the force with which the film (F) is pulled by the article (W). Therefore, the load applied to the connecting portion (F3) can be reduced so that the connection of the film (F) is not released until the end of one packaging cycle. Furthermore, when the force to attract the article (W) to the upstream side in the conveying direction of the article (W) is generated in the film (F) due to the closing operation of the pair of seal bodies (41, 42, 51, 52), the second Since the conveying of the article (W) by the conveyor (14) is kept suspended, the load on the connecting point (F3) can be reduced at the end of one packaging cycle.

Next, the invention according to claim 2, which is dependent on claim 1, is such that the one (24a) of the film conveying means is adapted to the film supporting means (26) when the film (F) is cut by the cutting means. , 27, 29, 34, 35) so as to extend in the vertical direction, the connection point (F3) of the film (F) is set corresponding to the next coming article (W). and a third film feeding means for pulling out the film (F) from the film feeding amount adjusting means (25) so as to be positioned at the set position (Q, M).

According to the second aspect of the invention, the film is supported so as to extend vertically so as to correspond to the article (W) that comes next when the film (F) is cut by the cutting means. From the connection point (F3) of (F) to the set position (Q, M), until the article (W) abuts on the film (F) extending in the vertical direction and is placed on the film (F) It is not necessary to feed the film (F) quickly in order to align the connection point (F3) with the article (W) in a short period of time.

Next, the invention according to claim 3, which is dependent on claim 1 or claim 2, is an upper part of the article (W) that inclines at a predetermined angle or more when the article (W) passes over the second conveyor (14). 5), and the rotating body (73) pulls the upper part (5) of the article (W) in contact with the article (W) to the downstream side in the conveying direction. It rotates at the same speed as the traveling speed of the second conveyor (14), and temporarily when the upper film (F5) and the lower film (F6) are sandwiched by the pair of seal bodies (41, 42). characterized in that the rotation stops at

According to the third aspect of the invention, the rotating body (73) is capable of contacting only the upper portion (5) of the article (W) inclined at a predetermined angle or more when the article (W) passes over the second conveyor (14). ) is set at a height position so as to come into contact with the upper portion (5) of the article (W) when the article (W) is tilted at a predetermined angle or more from the normal posture. With this configuration, when the article (W) is tilted backward by a predetermined angle or more due to contact with the conveying start end (14S) of the second conveyor (14), the upper portion (5) of the article (W) is moved in the conveying direction. It is possible to suppress the inclination of the article (W) by pulling it downstream. In addition, since the rotating body (73) temporarily stops rotating when the upper film (F5) and the lower film (F6) are sandwiched between the pair of sealing bodies (41, 42), Even if the article (W) is tilted at a predetermined angle or more due to the nipping of the films (F5, F6) by the bodies (41, 42), the force for sending the article (W) downstream in the conveying direction can be suppressed. It is possible to suppress the application of excessive force to the connection point (F3) between the upper film (F5) and the lower film (F6) positioned in the front part (7) of W), and the connection state of the connection point (F3) can be suppressed. can be maintained well.

Next, the invention according to claim 4, which is dependent on any one of claims 1 to 3, is characterized in that the first conveyor (13) is arranged in the horizontal direction intersecting the conveying direction of the article (W). The article (W) whose size of the bottom (6) of the article (W) is narrower than the film width of the lower film (F6) is transferred from the end (13E) on the placement surface of the first conveyor (13) to the article (W). Pushing means for pushing the article (W) in contact with the rear portion (8) of the article (W) when passing to the conveying start end (14S) of the second conveyor (14), The pushing means has a support body (75) which is movable along the transport direction and which is movable in the lateral direction, and the support body (75) is mounted on the mounting surface. The article (W) is brought into contact with the rear portion (8) of the article (W) to push the article (W) to the specific position (K) on the second conveyor (14), and the seal bodies (51, 52) are formed into films. The rear part (8) of the article (W) is supported until (F) is clamped, and then the article (W) is released from the support by moving in the lateral direction from the article (W). Characterized by

According to the fourth aspect of the invention, after the article (W) moves from the placement surface of the first conveyor (13) to the second conveyor (14) and is placed on the film (F), the sealing member (51) is placed on the film (F). , 52) grips the film (F), the article (W) does not contact the mounting surface of the second conveyor (14) (or the contact area is reduced), and the frictional force is reduced, so that the article (W) does not slide. However, since the rear part (8) of the article (W) is supported by the support (75), the sealing bodies (51, 52) hold the film (F). The article (W) can be maintained in a proper position with a stable attitude until it is clamped.

Next, according to the invention according to claim 5, which is dependent on any one of claims 1 to 4, the pair of seal bodies (51, 52) is formed in one seal body (52). A cutting blade (55) is accommodated in the blade accommodating groove (54), and is formed so as to move forward and backward toward a receiving groove (53) formed in the other seal body (51). In addition, the seal body (51, 52) formed on the front side in the conveying direction through the cutting blade (55) has a seal width formed on the rear side of the seal surface (56) of the seal body (51, 52). It is characterized by being narrower than the sealing width of the sealing surface (56) of (51, 52).

According to the fifth aspect of the invention, the film (F) sandwiched between the pair of seal bodies (51, 52) is welded by the heat transmitted from the seal surface (56), and positioned in front and behind in the article conveying direction. Between the connection points (F3, F4), cutting is performed by a cutting blade (55) housed in one of the sealing bodies (51, 52). The sealing surface (56) is set so that the front side of the cutting blade (55) is narrower than the rear side thereof in the article conveying direction. As a result, the length of the connecting portion (F3) of the film (F) supported by the film supporting means (26, 29, 34, 35) when cut by the cutting means is set to the rear portion (8) of the article (W). can be longer than the connection point (F4) in . Therefore, the film (F) wrapped around the article (W) remains with a connection portion (F4) having a relatively short length, so that the appearance of the article (W) is improved. In addition, since the film (F) extending in the vertical direction by the film supporting means (26, 29, 34, 35) has a relatively long connecting portion (F3), the connecting portion (F3) can be easily connected when transferring the film. It becomes difficult to release the connection at the point (F3).

Next, in the invention according to claim 6, which is dependent on any one of claims 1 to 5, the upper part (5) of the article (W) is conveyed from the bottom part (6) of the article (W). The pair of sealing bodies (51, 52) sandwiching the upper film (F5) and the lower film (F6) wound around the article (W) protruding rearward in the direction The cutting blade (55) is accommodated in the cutting blade accommodation groove (54) formed in (52), and the cutting blade (55) is directed toward the receiving groove (53) formed in the upper seal body (51). The thickness (T1) of the upper sealing body (51), which is the forward side in the conveying direction through the cutting blade (55), is larger than the thickness (T1) of the lower sealing body (51). It is characterized by being formed thinner than the thickness (T2) of the front side of the seal body (52).

According to the sixth aspect of the invention, the pair of sealing bodies (51, 52) in the sealing means is configured such that the upper portion (5) of the article (W) is positioned rearward in the conveying direction from the bottom portion (6) of the article (W). According to the shape of the projecting article (W), the thickness dimension (T1) of the upper sealing body (51), which is on the forward side in the conveying direction from the cutting blade (55), is changed to the thickness dimension of the lower sealing body (52). It can be set thinner than (T2). As a result, the distance between the closed pair of seal bodies (51, 52) and the rear side of the article (W) can be made closer. That is, since the film (F) can be sandwiched in a state where the rear side of the article (W) is closer to the pair of seal bodies (51, 52), the length of the film (F) for one package can be set short. . In addition, when a heat-shrinkable film (F) is used for packaging, the area where the film (F) and the pair of sealing bodies (51, 52) approach on the rear side of the article (W) is widened. , the region where the heat-shrinkable film (F) shrinks can be widened. Therefore, the film packaging for the container (W) can be made tighter.

In the present invention, the film is used until the end of one packaging cycle (the cycle from cutting the film sandwiched by the sealing body to wrapping the film around the next incoming article, sandwiching the film with the sealing body, and cutting it). It is possible to provide a packaging device that can improve productivity by reducing the load on the connection points of the two.

BRIEF DESCRIPTION OF THE DRAWINGS It is the schematic which showed the whole packaging apparatus which concerns on 1st Embodiment. FIG. 4 is a diagram showing a state in which containers are conveyed by an intermediate conveyor in the first embodiment; (a) In 1st Embodiment, it is the figure which showed the state by which the film was wound around the container conveyed to the specific area|region. (b) A diagram showing a state in which a film wound around a container is sandwiched. (c) After the film has been cut, the container is conveyed by the discharge conveyor. (d) is a diagram showing a state in which the film is sent out and the connecting portion of the film in the film transport path is set at a predetermined height position. It is the schematic which showed the whole packaging apparatus which concerns on 2nd Embodiment. FIG. 9 is a diagram showing a state in which containers are conveyed by an intermediate conveyor in the second embodiment; (a) In 2nd Embodiment, it is the figure which showed the state in which the film was wound around the container conveyed to the specific position. (b) A diagram showing a state in which a film wound around a container is sandwiched. (c) After the film has been cut, the container is conveyed by the discharge conveyor. (d) is a diagram showing a state in which the film is sent out and the connection point of the film in the film transfer path is set at a predetermined height position. It is an enlarged view of the seal body portion of the packaging device according to the second embodiment.

<First embodiment>
First, the packaging device according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. The packaging apparatus according to the present embodiment is an apparatus for wrapping a belt-shaped film F around the outer periphery of a container W (goods) for packaging. The structure is such that the drawn film F is sent out correspondingly to the transported container W and is welded.

FIG. 1 is a schematic diagram of a packaging machine. The packaging apparatus according to the present embodiment includes a container conveying mechanism for conveying a container W (goods), a film conveying mechanism for conveying a film F from two directions, a film F sandwiched and welded, and a connecting portion thereof. A pair of seal bodies 41 and 42 for cutting between F3 and F4, and a control unit (not shown) for issuing a drive command to these are provided.

The container W used in this embodiment is composed of a container body W1 having an upper opening and a lid W2 closing the opening. The opening of the container body W1 is closed by the lid W2 after the contents are accommodated therein. The container W is wrapped with the film F so as to cover the top surface 5 (upper portion), the front portion 7 and the bottom surface 6 (bottom portion), and the film F is sealed at the rear portion 8 side for packaging.

As shown in FIGS. 1 to 3, the container transport mechanism is provided with a plurality of conveyors connected in series for transporting the containers W placed at predetermined intervals. forming. These conveyors are arranged in this order from the upstream side of the conveying direction: an introduction conveyor 11, an intermediate conveyor 13 (first conveyor), and a discharge conveyor 14 (second conveyor). are doing. A bypass conveyor 15 is connected to the delivery end side of the discharge conveyor 14 , and a heater conveyor 16 is connected to the delivery end side of the bypass conveyor 15 . An article detection device 61 (article detection means) for detecting the arrival of the container W conveyed by the intermediate conveyor 13 is arranged at the end portion 13E on the placement surface of the intermediate conveyor 13. As shown in FIG.

Above and below the container conveying path 10, a film conveying mechanism that forms the film conveying path 20 through a gap S between the end portion 13E of the mounting surface of the intermediate conveyor 13 and the conveying start portion 14S of the discharge conveyor 14 is arranged. is set. The film transfer mechanism is configured to transfer the film F from two directions, that is, from the upper side and the lower side. A roller 23, a delivery roller 24, a dancer roller 25, guide rollers 26 and 27, and a support roller 29 are arranged. A holding roller 28 is arranged between the terminal end portion 13E of the placement surface of the intermediate conveyor 13 and the transport start end portion 14S of the discharge conveyor 14 .

Further, between the terminal end portion 13E on the mounting surface of the intermediate conveyor 13 and the conveying start end portion 14S of the discharge conveyor 14, there is provided a space for welding the upper film F5 and the lower film F6 of the film F wound around the container W. A pair of seal bodies 41 and 42 are provided.

The film transfer mechanism is configured such that the film F pulled out from the original fabric roll 21 is transferred via a plurality of rollers. A pull-out roller 23 is arranged as a second film conveying means for pulling out the film F from the original roll 21 . A strip-shaped non-shrinkable film F1 is wound around the original roll 21 on the upper side, and a strip-shaped heat-shrinkable film F2 is wound around the raw roll 21 on the lower side. The pull-out roller 23 is rotationally driven by a motor (not shown) driven and controlled by the control unit, pulls out these films F (non-shrinkable film F1, heat-shrinkable film F2) from the original roll 21, and moves the dancers. It is configured to send out to the roller 25 .

A printing device 22 (printing means) is arranged between the raw fabric roll 21 and the pull-out roller 23 on the upper side of the film transfer mechanism. On the non-shrinkable film F1 pulled out from the original roll 21, the printing device 22 prints information on the contents based on the information on the printing timing transmitted from the control section. Specifically, for each length used for one package, information on the contents is set to be printed in two places so as to be positioned on the top face 5 and the front part 7 of the container W, respectively. Further, when the printing process is performed, the feeding speed of the film pulled out by the pull-out roller 23 is controlled so as to be suppressed to a speed that can correspond to the processing capability of the printing device 22 . Further, in the vicinity of the downstream side of the printing device 22, there is provided a judging means (not shown) for judging whether printing by the printing device 22 is good or bad. The determination means is operated and controlled by the controller.

The delivery roller 24 is rotationally driven by a motor (not shown) that is driven and controlled by the control unit, pulls out the film F delivered by the delivery roller 24 from the dancer roller 25, and is arranged downstream of the film transport path 20. It is configured to send out toward the support roller 29 . The delivery roller 24 is driven and controlled based on the detection information of the container W detected by the article detection device 61 and the information regarding the article feeding amount by the pulse of the encoder attached to the intermediate conveyor 13 . The structure for sending out the film F from the dancer roller 25 toward the pull-out support roller 29 in this manner corresponds to the "first film conveying means" of the present invention. The delivery roller 24a in the upper film transport path 20a corresponds to the "upper film transport means" for feeding the film F toward the support roller 29, and the delivery roller 24b in the lower film transport path 20b corresponds to the support roller 29. It corresponds to the "lower film conveying means" that sends out the film F toward the roller 29, and these delivery rollers 24a and 24b are included in the "first film conveying means".

Dancer rollers 25 are arranged between the pull-out rollers 23 and delivery rollers 24 on the upper and lower sides of the film transport mechanism, respectively. The dancer roller 25 has two fixed rollers 25a and three movable rollers 25b below them, and the film F is transported alternately between the movable rollers 25b and the fixed rollers 25a. Thus, when there is a difference between the amount of film pulled out by the pull-out roller 23 and the amount of film fed by the delivery roller 24, the movable roller 25b advances and retreats in the vertical direction to adjust the length of the transported film F. . For example, in the upper film transport path 20a, even if the amount of film pulled out by the pull-out roller 23 decreases due to the printing process, the necessary film feed amount by the feed roller 24a is compensated. The structure for compensating for the shortage of the film feeding amount by the pull-out roller 23 with respect to the film feeding amount by the delivery roller 24a in this way corresponds to the "film feeding amount adjusting means" in the present invention. The film transfer mechanism may be configured such that the dancer roller 25 is arranged only in the upper film transfer path 20a where the printing device 22 is arranged.

The guide rollers 26 and 27 and the support roller 29 serve as film support means for the film F to extend vertically through the gap S between the end portion 13E on the placement surface of the intermediate conveyor 13 and the conveyance start portion 14S of the discharge conveyor 14. The film F is wound and guided at positions vertically spaced apart from each other with a gap S therebetween. Specifically, two guide rollers 26 are provided on the upstream side surface of the upper seal member 41 in the container conveying direction, and two guide rollers 27 are provided on the upstream side surface of the lower seal member 42 in the container conveying direction. are arranged. Two support rollers 29 are arranged between the delivery roller 24 and the guide rollers 26 and 27 in the upper and lower film transport paths 20, respectively.

With this configuration, the non-shrinkable film F1 sent out by the delivery roller 24a is guided by the guide roller 26 via the support roller 29 in the film transfer path 20a on the upper side of the film transfer mechanism. In the film transfer path 20b, the heat-shrinkable film F2 sent out by the delivery roller 24b is wound around and guided by the guide roller 27 via the support roller 29. As shown in FIG. The configuration of the guide roller 26 and the support roller 29 in the upper film transfer path 20a corresponds to the "upper film support means" of the present invention. The configuration of the guide rollers 27 and support rollers 29 in the lower film transfer path 20b corresponds to "lower film support means".

The holding roller 28 is disposed between the terminal end portion 13E on the mounting surface of the intermediate conveyor 13 and the conveying starting end portion 14S of the discharge conveyor 14, and conveys the container of the film F extending vertically in the film conveying path 20. It is configured to be located on the downstream side in the direction. As a result, the film F in the film transfer path 20 contacts the discharge conveyor 14 and the lower seal member 42 even before the film F is wrapped around the container W and sandwiched between the pair of seal members 41 and 42 . can prevent

The pair of seal bodies 41 and 42 are configured such that the upper seal body 41 and the lower seal body 42 are opened and closed to approach and separate from each other along the vertical direction crossing the container conveying direction by a driving means constituted by a motor or a cylinder. It is said that The lower end of the upper seal body 41 has a seal surface 46 and a cutting blade housing groove 44 , and the upper end of the lower seal body 42 has a seal surface 46 and a receiving groove 43 . The receiving groove 43 and the cutting blade accommodating groove 44 are formed along the left-right direction crossing the container conveying direction, and the sealing surfaces 46 are formed in front and rear of the receiving groove 43 and the cutting blade accommodating groove 44 in the conveying direction, respectively. ing. A cutting blade 45 is housed in a cutting blade housing groove 44 of the upper sealing body 41 . The cutting blade 45 is configured to move back and forth toward the receiving groove 43 of the lower seal body 42 . A heater is embedded in the upper and lower sealing bodies 41 and 42, and the film F is sandwiched between the heated sealing surfaces 46 of the upper sealing body 41 and the heated lower sealing body 42. are welded together.

The pair of seal bodies 41 and 42 is formed by a film F (hereinafter referred to as a vertical film) which extends vertically through a gap S at the front portion 7 of the container W in the conveying direction based on detection information of the container W by the article detection device 61 . 14S of the discharge conveyor 14 while coming into contact with the film F extending in the direction of the container W, the film F wound around the container W is clamped and welded. Specifically, the timing of closing the seal bodies 41 and 42 is controlled based on the detection information of the container W and the position information of the container W obtained from the pulses of the encoders attached to the intermediate conveyor 13 and the discharge conveyor 14. be. The height position at which the film F is sandwiched between the seal bodies 41 and 42 is preset corresponding to the container W. As shown in FIG. In addition, the sealing bodies 41 and 42 separate the overlapping portions of the upper film F5 extending above the container W and the lower film F6 extending below the container W in the longitudinal direction in the container conveying direction. It is sandwiched and welded at the position. In other words, the sealing bodies 41 and 42 are configured such that the film F is sandwiched between the upper and lower sealing surfaces 46 in front of and behind the receiving groove 43 . As a result, the film F is welded such that the connection points F3 and F4 are positioned in front of and behind the receiving groove 43, respectively. The configuration for holding and welding the overlapping upper film F5 and lower film F6 in this manner corresponds to the "sealing means" of the present invention.

After the pair of seal bodies 41 and 42 sandwich and weld the upper film F5 and the lower film F6, the cutting blade 45 embedded in the upper seal body 41 advances and retreats to cut the film F. be done. Specifically, the pair of seal bodies 41 and 42 cut the film F at positions where the film F is sandwiched by the seal surfaces 46 , that is, between connection points F 3 and F 4 positioned before and after the receiving groove 43 . As a result, the connection point F3 of the film F extending in the vertical direction in the film transfer path 20 and the connection point F4 on the rear 8 side of the container W are separated. In this manner, the cutting blade 45 is advanced and retracted to cut the film F sandwiched between the seal bodies 41 and 42 so that the connection points F3 and F4 are spaced apart in the forward and rearward directions in the conveying direction of the container W. The configuration corresponds to the "cutting means" of the present invention.

The film transfer mechanism is configured to feed the non-shrinkable film F1 and the heat-shrinkable film F2 in two stages while the container W is being wrapped once, based on the detection information and the position information of the container W. As shown in FIG. Specifically, until the container W comes into contact with the film F extending in the vertical direction and reaches the specific position K of the discharge conveyor 14 after crossing the conveying start end 14S of the discharge conveyor 14, the first time After the discharge conveyor 14 temporarily stops conveying the container W, the second film feeding is performed. The film feeding control unit includes the cut pitch of the non-shrinkable film F1 (film length required for one package), the first and second feeding amounts of the non-shrinkable film F1, the heat-shrinkable film The cut pitch of F2 (film length required for one package), the first feeding amount and the second feeding amount of the heat-shrinkable film F2, the film return amount, etc. are input and set. Note that these input settings may be configured to be set via a touch panel.

In the first film feeding, based on the detection information and the position information of the container W, the container W comes into contact with the film F extending in the vertical direction, and is discharged after passing the transport start end 14S of the discharge conveyor 14. Until reaching the specific position K of the conveyor 14, the connection point F3 of the film F extending in the vertical direction is positioned in a specified area Z1 (located on the front part 7 side of the container W) determined by the relationship with the container W on the discharge conveyor 14. At the same time, the film F is fed out by driving the feeding rollers 24a and 24b so that the film F is positioned within the set height range spaced upward from the bottom surface 6). Further, the film F is slack so that the film F does not pull back the container W backward in the conveying direction even though the film F contacts the container W until the container W reaches the specific position K of the discharge conveyor 14 . It is set to be sent out at once. Note that the timing of the first film feed may be any time from when the container W comes in contact with the film F to when it reaches the specific position K on the discharge conveyor 14 .

The total amount of film feeding from above and below for the first time is less than the length of one package, and the container W is conveyed to a specific position K on the discharge conveyor 14, and the discharge conveyor 14 temporarily runs. When the film is stopped, the film F does not excessively remain with respect to the container W placed on the discharge conveyor 14, and the top surface 5, the front part 7 and the bottom surface 6 of the container W can be covered. is set to the length of In addition, the positional relationship between the non-shrinkable film F1 and the heat-shrinkable film F2 wound around the container W is such that the connection point F3 is positioned downward on the front portion 7 side, and the connection point F4 is positioned upward on the rear portion 8 side. It is set. The structure for performing the first film feeding in this manner corresponds to the "first film feeding means" of the present invention.

In the second film feeding, after the discharge conveyor 14 temporarily stops conveying the container W based on the detection information and the position information of the container W, the film joins the connection point F3 caused by the approach of the pair of seal bodies 41 and 42 . The feeding rollers 24a and 24b are driven so that the force for pulling the film F is less than the force capable of releasing the connection at the connection point F3, and the film F is fed out at once so as to be slackened. The connection point F3 of the film F is set to be positioned in a specified area Z1 (a set range of height located on the front portion 7 side of the container W and spaced upward from the bottom surface 6). In addition, the film feeding amount for the second time is set to the remaining film length of the film length required for one package, which was not covered by the film feeding for the first time. In other words, when the pair of seal bodies 41 and 42 are closed, the length of the film F surrounding the outer periphery of the container W, the receiving groove 43, and the pair of seal bodies 41 and 42 upstream of the receiving groove 43 are determined. It is set to the remaining length that can secure the length obtained by adding the width and the width of the sealing surface 46 downstream of the receiving groove 43 in the conveying direction. The structure for performing the second film feeding in this way corresponds to the "second film feeding means" of the present invention.

When the film F is sandwiched and cut between the connection points F3 and F4, the film F on the upstream side of the container transport is wound around the support roller 29 and the guide rollers 26 and 27 in the film transport path 20. It is guided and supported so as to extend vertically through the gap S between the intermediate conveyor 13 and the discharge conveyor 14 . In the film transfer mechanism, after the film F is clamped, the height position of the connection point F3 is positioned at the set position Q (see FIG. 3(d)) preset in correspondence with the next container W to come. , the third film feeding is performed. Specifically, the non-shrinkable film F1 is pulled out from the dancer roller 25 on the upper side, and the roller rotates in the film transfer path 20b on the lower side in the direction opposite to the direction in which the heat-shrinkable film F2 is sent out. As a result, the height position of the connecting portion F3 moves downward to the set position Q so that the printed portion of the product content on the non-shrinkable film F1 is located on the top surface 5 and the front portion 7 of the container W. It's becoming

The timing of the third film feed may be after the overlapping films F are sandwiched between the upper and lower seal members 41 and 42 . For example, when the sealing bodies 41 and 42 are closed, the upper delivery roller 24a is driven to pull out the non-shrinkable film F1, and the lower delivery roller 24b is driven after the film F is cut at the connection point F3. Alternatively, after the film F is cut, the feeding roller 24a on the upper side may be driven to pull out the film F. As shown in FIG. Further, after the nipping of the film F is released, the lower delivery roller 24b may be driven simultaneously with the upper delivery roller 24a. In this manner, the film F supported on the film transfer path 20 is pulled out from the dancer roller 25 so that the height position of the connection point F3 is positioned at the set position Q corresponding to the next container W. corresponds to the "third film feeding means" of the present invention.

The introduction conveyor 11 in the container transport mechanism has a belt on the placement surface, and the belt is driven to run by a motor (not shown) controlled by the control unit to transport the containers W at a constant speed at predetermined intervals. It is said that The conveying speed of the introduction conveyor 11 is set according to the target production quantity. A guide 71 for laterally supporting the container W is arranged along the conveying direction of the introduction conveyor 11 . This is intended to suppress displacement of the container W with respect to the film F. The guides 71 for supporting the containers W are similarly arranged on the intermediate conveyor 13 and the discharge conveyor 14 as well.

The intermediate conveyor 13 has a belt on its mounting surface, and the belt is driven to run by a motor (not shown) controlled by the controller. The intermediate conveyor 13 is set to run at a constant speed faster than the introduction conveyor 11 in order to separate the containers W delivered from the introduction conveyor 11 from the following containers W. An upper belt 72 for maintaining the posture of the container W is arranged above the intermediate conveyor 13 . The upper belt 72 is set so that the height position from the mounting surface is higher than the height of the containers W, and is driven by a motor (not shown) controlled by the controller at the same speed as the intermediate conveyor 13 travels. Driven to run. As a result, when the posture of the container W on the intermediate conveyor 13 is tilted, the top surface 5 of the container W is in contact with the upper belt 72 so that the posture is maintained.

The discharge conveyor 14 is a shuttle-type conveyor whose mounting surface is a belt. It is configured to retreat to the downstream side and return to the upstream side so as to reduce the gap S between the mounting surface of the intermediate conveyor 13 and the terminal end portion 13E when the lower seal member 42 moves downward. In addition, the discharge conveyor 14 places the containers W from the end portion 13E on the placement surface of the intermediate conveyor 13 based on the detection information of the containers W by the article detection device 61, and also loads the containers W received from the intermediate conveyor 13. It is configured such that the transport is temporarily stopped at a specific position K and then transported. Specifically, the discharge conveyor 14 is driven to run at a faster speed than the intermediate conveyor 13 when the containers W are placed on the discharge conveyor 14 from the intermediate conveyor 13 . When the container W is conveyed to the specific position K of the discharge conveyor 14, the traveling drive is stopped. When the upper and lower sealing members 41 and 42 are closed, the film F is forced to attract the container W to the upstream side in the conveying direction.

Above the discharge conveyor 14, two auxiliary rollers 73 (rotary running bodies) and a product retainer 74 made of sponge or the like are disposed downstream of the two auxiliary rollers 73 as article support means. The auxiliary rollers 73 contact only the top surface 5 of the container W, which is inclined at a predetermined angle or more, when the container W passes from the terminal end 13E on the placement surface of the intermediate conveyor 13 to the discharge conveyor 14. , and is driven to rotate by a motor (not shown) controlled by a control unit so as to pull the belt to the downstream side of the conveying direction and to achieve the same speed as the running speed of the discharge conveyor 14 .

The height dimension from the mounting surface of the discharge conveyor 14 to the lower part of the auxiliary roller 73 is set higher than the height dimension of the container W. As shown in FIG. That is, the auxiliary roller 73 does not always contact the container W when the container W passes from the intermediate conveyor 13 to the discharge conveyor 14, but is configured to contact only the top surface 5 of the container W inclined at a predetermined angle or more. It is Specifically, when the container W passes over the discharge conveyor 14, the container W receives a backward force from the film F, or the container W comes into contact with the conveying start end 14S of the discharge conveyor 14, thereby causing the container W to move. In some cases, the posture is tilted backward by a predetermined angle or more. The auxiliary roller 73 has a function of avoiding these and restricting the container W from tilting backward by a predetermined angle or more, and returning the backward tilting container W to its original posture by the rotational driving force.

When the container W is conveyed to the specific position K of the discharge conveyor 14, the rotational drive of the auxiliary roller 73 is temporarily stopped in the same way as the discharge conveyor 14 is driven, and the pair of seal bodies 41 and 42 seal the upper film F5. When the film F6 on the lower side is nipped, the travel drive of the discharge conveyor 14 and the rotation drive of the auxiliary roller 73 are set to stop continuously. In this way, by temporarily stopping the driving of the discharge conveyor 14 and the auxiliary roller 73 when the seal bodies 41 and 42 are closed, the state in which the container W advances and pulls the film F is avoided. . As a result, even if the container W is tilted at a predetermined angle or more by holding the films F5 and F6 by the seal bodies 41 and 42, the force for sending the container W downstream in the conveying direction is suppressed. Excessive force is suppressed from being applied to the connection point F3 between the upper film F5 and the lower film F6 positioned in the portion 7, and the connection state of the connection point F3 is maintained in good condition.

The product retainer 74 is configured to move up and down by a cylinder controlled by the control unit, and when the film F is sandwiched between the pair of seal bodies 41 and 42, the top surface 5 of the container W is positioned corresponding to the height position of the top surface 5 of the container W. It is set to descend until just before contacting the surface 5. As a result, when the posture of the container W is tilted, the top surface 5 comes into contact with the product retainer 74, so the posture of the container W is maintained. In this manner, the product presser 74 has a function of supporting the container W so as not to greatly tilt backward when the film F is pinched together with the auxiliary roller 73 .

A holding roller 28 is arranged between the end portion 13E on the placement surface of the intermediate conveyor 13 and the transport start end portion 14S of the discharge conveyor 14 to support the belt-shaped film F extending in the vertical direction from the downstream side in the container transport direction. is set. The holding roller 28 is arranged to prevent the film F wrapped around the container W on the discharge conveyor 14 from coming into contact with the side surface of the lower sealing body 42 and being heated.

As shown in FIG. 1, the bypass conveyor 15 is arranged adjacent to the conveying terminal side of the discharge conveyor 14, and the belt bearing the mounting surface is driven to run by a motor (not shown) controlled by the controller. be. A bypass product detection device 62 is provided on the conveying start end side of the bypass conveyor 15, and a container W wrapped with a film F of one package length that is determined to be defective in printing by the printing quality determination device. is set to be detected when the

When a defectively printed container W is detected by the bypass product detection device 62, the bypass conveyor 15 is tilted at a predetermined timing as indicated by the two-dot chain line in FIG. It is configured to be excluded to the outside. Specifically, a motor (not shown) controlled by the control section is driven to the conveying end portion of the bypass conveyor 15 based on discrimination information by the discriminating means, information on the film feeding amount, product detection information by the bypass product detection device 62, and the like. 15E descends. In addition, the bypass conveyor 15 is driven to run at a variable speed, but when the container W is transferred from the discharge conveyor 14 to the bypass conveyor 15, it is set to run and drive so as to have the same speed as the discharge conveyor 14. ing. This is intended to prevent the film F from being displaced with respect to the container W. As shown in FIG.

The heater conveyor 16 is connected to the conveying end side of the bypass conveyor 15, and an endless belt made of a metal mesh that serves as a mounting surface is fixed by a motor (not shown) controlled by a control unit. is driven at a speed of Inside the endless belt of the heater conveyor 16, a hot air device 76 is provided on the side of the beginning of the transfer, and a heater 77 is provided on the downstream side of the hot air device 76 in the transfer. In addition, when the container W detected by the hot-air product detection device 63 near the conveying end of the bypass conveyor 15 is conveyed to a preset position, the heater conveyor 16 moves the container W from the hot-air device 76 to the rear portion 8 side of the container W. It is configured such that hot air is blown only to the lower film F6 (heat-shrinkable film F2). The hot air device 76 is based on product detection information from the hot air product detection device 63 and information on the container conveying amount based on encoder pulses attached to a motor (not shown) that drives the bypass conveyor 15 and the heater conveyor 16 to run. ON/OFF of the hot air blowing operation is switched and controlled.

Further, the heater conveyor 16 is configured to thermally shrink the lower film F6 in contact with the bottom surface 6 of the container W by the heat of the heater 77 while conveying the container W. As shown in FIG. The amount of heat received by the film F6 per unit area from the heater 77 per unit time is set to be smaller than the amount of heat received by the film F6 per unit area from the hot air device 76 per unit time. It is configured so that the temperature can be set by

Next, the movement and action of the packaging device according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. 3(a) to 3(d), the display of the reference numerals is partially omitted, and the reference numerals are displayed using FIG. 2 as a representative diagram.

1 and 2, in the container transport mechanism, the container W is placed on the intermediate conveyor 13 from the introduction conveyor 11 and transported. When the container W reaches the end portion 13E on the placement surface of the intermediate conveyor 13, it is detected by the article detection device 61. As shown in FIG. In the film transfer path 20 , the film F extends vertically through a gap S between the end portion 13 E on the placement surface of the intermediate conveyor 13 and the transport start end portion 14 S of the discharge conveyor 14 .

In the film transfer mechanism, the film F (non-shrinkable film F1, heat-shrinkable film F2) wound on the upper and lower original fabric rolls 21 is pulled out based on the detection information of the container W by the article detection device 61. Rollers 23 draw out each. In the upper film transfer path 20a, the non-shrinkable film F1 is printed based on the information about the printing timing sent from the control unit. Incidentally, the film feeding speed of the drawing roller 23 is controlled according to the throughput of the printing device 22 . Further, when a difference in film feeding amount occurs between the drawing roller 23 and the delivery roller 24a due to the printing process, the movable roller 25b of the dancer roller 25 advances and retreats in the vertical direction according to the film feeding amount of the delivery roller 24a. . As a result, the required length of film F is sent out by the delivery roller 24a. Furthermore, between the printing device 22 and the dancer roller 25, the quality of printing is determined by the determining means.

By the time the container W comes into contact with the film F extending in the vertical direction and reaches the specific position K of the discharge conveyor 14 after crossing the transport start end 14S of the discharge conveyor 14, the detection information and the position of the container W are detected. Based on the information, the first film feeding is performed by the feeding rollers 24a and 24b. The total length of the film F sent from above and below is less than the length of one package, and the film F is not excessively left over, and the container W contacts the film F. It is set so as not to be pulled back backward in the container conveying direction. As a result, the force with which the container W pulls the film F is suppressed, and the load applied to the connecting portion F3 of the film F is reduced.

Referring to FIG. 3(a), the container W moves from the intermediate conveyor 13 to the discharge conveyor 14 while contacting the vertically extending film F. As shown in FIG. When the container W is placed on the discharge conveyor 14 , the discharge conveyor 14 is driven to run at a speed faster than the intermediate conveyor 13 . As the container W winds the film F, it advances downstream by the discharge conveyor 14 and moves to a specific position K. - 特許庁Then, when the container W reaches the specific position K, the travel drive of the discharge conveyor 14 and the rotational drive of the auxiliary roller 73 are temporarily stopped. At this time, the film F wound around the container W is such that the non-shrinkable film F1 is in contact with the top surface 5 as the upper film F5, and the heat-shrinkable film F2 is in contact with the bottom surface 6 as the lower film F6. It extends to the rear 8 side. In addition, the connection point F3 is positioned downward on the front portion 7 side of the container W. As shown in FIG.

Referring to FIG. 3(b), after the discharge conveyor 14 temporarily stops transporting the container W, the delivery rollers 24a and 24b deliver the film for the second time. The total length of the film F fed from above and below is set to the remaining length of the film required for one package, which was not covered by the first film feed. As a result, the force that pulls the film F and is applied to the joint F3 as the seal bodies 41 and 42 approach each other is less than the force that can release the connection at the joint F3.

The discharge conveyor 14 retreats to the downstream side of the container conveyance so that the gap S between the terminal end 13E on the mounting surface of the intermediate conveyor 13 and the conveyance start end 14S of the discharge conveyor 14 widens, and the container W reaches the specific position K. Later, when the pair of seal bodies 41 and 42 are closed, the upper film F5 and the lower film F6 are sandwiched while overlapping each other, and are welded on the seal surfaces 46 of the seal bodies 41 and 42 . With the closing operation of the pair of seal bodies 41 and 42, the container W is attracted to the upstream side in the conveying direction via the film F. As shown in FIG. At this time, the running of the discharge conveyor 14 and the rotation of the auxiliary roller 73 are temporarily stopped, and the product retainer 74 is temporarily lowered to a height just before contacting the top surface 5 of the container W. Thereby, the inclination of the container W is restricted.

When the film F is welded, the cutting blade 45 cuts the film F between the connection points F3 and F4. Referring to FIG. 3(c), after the film F is cut, the upper sealing member 41 rises, the lower sealing member 42 lowers, and the discharge conveyor 14 returns to the container transport upstream side. A connection point F4 away from the vertically extending film F in the film transfer path 20 is located above the front portion 7 of the container W. As shown in FIG.

When the film F is cut and the clamping of the film F by the pair of seal bodies 41 and 42 is released, the stopping drive of the discharge conveyor 14 and the rotary drive of the auxiliary roller 73 are resumed, and the film F is wound. The container W thus loaded is conveyed downstream by the discharge conveyor 14 . At this time, in the film transfer mechanism, the film is delivered for the third time. As shown in FIG. 3(d), in the upper film transport path 20a, the delivery roller 24a is driven, the non-shrinkable film F1 is pulled out from the dancer roller 25, and in the lower film transport path 20b, The delivery roller 24b rotates in the reverse direction. As a result, the connection point F3 is moved to the lower set position Q where it is set.

When the container W around which the film F is wrapped is transferred from the discharge conveyor 14 to the bypass conveyor 15, the bypass conveyor 15 is driven and driven so that there is no difference in the conveying speed between the discharge conveyor 14 and the bypass conveyor 15. be done. This is intended to prevent the film F from being displaced with respect to the container W. As shown in FIG. At the beginning of the conveying end of the bypass conveyor 15, when a container W wrapped with a film F of one packaging length, which is determined to be defective in printing by the quality determination means for printing, arrives, it is detected by the bypass product detection device 62. be done. In this case, based on the product detection information of the bypass product detection device 62, the bypass conveyor 15 tilts at a predetermined timing, as shown by the two-dot chain line in FIG. Eliminated.

When the container W around which the film F is wound passes through the transfer end portion 15E of the bypass conveyor 15, it is detected by the hot air product detection device 63 and moves from the bypass conveyor 15 to the heater conveyor 16. When the container W is transferred to the heater conveyor 16, the traveling drive is controlled so that there is no difference in the conveying speed between the discharge conveyor 14 and the bypass conveyor 15. FIG. When the container W detected by the product detection device 63 is transported to a preset position on the heater conveyor 16, the hot air device 76 blows only the lower film F6 (heat-shrinkable film F2) on the rear 8 side of the container W. Hot air is blown. As a result, only the lower film F6 shrinks so as to tighten the container W. As shown in FIG. At this time, the bottom surface 6 side of the lower film F6 also begins to receive heat from the heater 77 of the heater conveyor 16, but the amount of heat received from the heater 77 per unit time per unit area of the lower film F6 is received from the hot air device 76. Since the amount of heat is less than the amount of heat per unit time, the bottom surface 6 side of the lower film F6 does not shrink instantaneously, but slowly shrinks over time while being conveyed by the heater conveyor 16, completing the shrink packaging. In addition, the upper film F5 (non-shrinkable film F1) maintains the state without shrinkage of the printed portions located on the top surface 5 and the front portion 7 of the container W. As shown in FIG.

The packaging device according to the first embodiment has the following effects.
(1) In the packaging apparatus, the film F is pulled out by the feed roller 24a as the upper film transport means and the pull-out roller 23 as the second film transport means, and the feeding of the film F generated between these rollers 23 and 24 is performed. A dancer roller 25 (film feeding amount adjusting means) capable of adjusting the amount difference is provided. With this configuration, even if the film feeding amount by the drawing roller 23 is less than the film feeding amount by the delivery roller 24a due to the printing process by the printing device 22, the shortage can be compensated. The timing of feeding the film F by the delivery roller 24a is only part of the timing in one packaging cycle. In addition, the shorter the time until the next container W arrives, the shorter the time during which the feeding roller 24a stops the film feeding operation. For this reason, the film feeding speed when the delivery roller 24a feeds the film F is faster than the film feeding speed by the drawing roller 23 at which the printing device 22 such as a thermal printer can print at the maximum. For this reason, the timing and film feeding speed for feeding the film F corresponding to the length of one package (the length used for one package) are momentarily different between the upstream side and the downstream side of the film transfer path 20a from the dancer roller 25. ing. As the number of packages per minute (packaging capacity) increases, the difference in film feeding amount becomes more pronounced.
(2) The delivery rollers 24a and 24b are configured such that the film F is delivered by the first film delivery means until the container W reaches the specific position K of the delivery conveyor 14. As shown in FIG. The delivery rollers 24a and 24b are arranged so that the connection point F3 is positioned in a specified area Z1 determined by the relationship with the container W on the discharge conveyor 14, and the film F contacts the container W, but the film F pushes the container W backward in the conveying direction. Feed the film F in such a way that it cannot be pulled back into. Thereby, the load applied to the connection point F3 can be reduced. For example, it is not necessary to pull the upper or lower film F after the container W is placed on the film F in order to position the connection point F3 in the specified area Z1. In addition, after the discharge conveyor 14 temporarily stops conveying the container W, the delivery rollers 24a and 24b are moved by the second film feeding means to the length required for one package, which was not satisfied by the film feeding by the first film feeding means. , and the film F corresponding to the remaining length is further fed out. The second film feeding means feeds the film F so that the force that pulls the film F applied to the connection point F3 as the seal bodies 41 and 42 approach is less than the force that can release the connection of the connection point F3. With these configurations, the film F can be wrapped around the container W and pinched while suppressing the force with which the film F is pulled by the container W. Therefore, the load applied to the connection point F3 can be reduced so that the connection of the film F is not released until the connection point F3 finishes cooling and hardening, that is, until the end of one packaging cycle. Furthermore, when the closing operation of the pair of seal bodies 41 and 42 causes the film F to attract the container W to the upstream side in the conveying direction of the container W, the conveying of the container W by the discharge conveyor 14 continues to be temporarily stopped. Therefore, the load applied to the connection point F3 at the end of one packaging cycle can be reduced.
(3) The feeding roller 24 is set to perform the third film feed for moving the position of the connection point F3 of the film F cut by the cutting blade 45 . As a result, when the film F is cut by the cutting blade 45, the delivery roller 24 moves the connection point F3 of the film F supported so as to extend in the vertical direction so as to correspond to the next coming container W. In order to align the connection point F3 with respect to the container W in a short period of time from when the container W comes into contact with the film F extending in the vertical direction until it is placed on the film F, the film is quickly adjusted to the set position Q. No need to send F.
(4) The auxiliary roller 73, which can contact only the top surface 5 of the container W which is tilted at a predetermined angle or more when the container W passes over the discharge conveyor 14, is arranged to move the container W when the container W is tilted at a predetermined angle or more from its normal posture. The height position is set so as to be in contact with the top surface 5 of the. With this configuration, when the container W being transported receives a backward force from the film F or comes into contact with the transport start end 14S of the discharge conveyor 14, and the container W tilts backward by a predetermined angle or more, the container W The tilt of the container W can be suppressed by retracting the top surface 5 of the container W toward the downstream side in the conveying direction. Further, since the rotation of the auxiliary roller 73 is temporarily stopped when the upper film F5 and the lower film F6 are sandwiched by the pair of seal bodies 41 and 42, the films F5 and F6 by the seal bodies 41 and 42 are prevented from rotating. Even if the container W is tilted by a predetermined angle or more due to the clamping of the container W, the force for sending the container W downstream in the conveying direction can be suppressed. It is possible to suppress the application of excessive force to the connection point F3, and to maintain a good connection state of the connection point F3.
(5) Guide rollers 26 and 27 are provided on the side surfaces of the pair of seal bodies 41 and 42, respectively, and are configured to wind and guide the film F in the film transfer path 20. As shown in FIG. As a result, the film F fills the gap S between the end portion 13E on the mounting surface of the intermediate conveyor 13 and the conveying start portion 14S of the discharge conveyor 14 without coming into contact with the side surface of the upper seal member 41 and the side surface of the lower seal member 42. It extends vertically through Therefore, it is possible to suppress the heat transfer of the seal bodies 41 and 42 to the film F in the film transfer path 20 .
(6) A holding roller 28 is disposed in the gap S between the terminal end portion 13E on the mounting surface of the intermediate conveyor 13 and the transport start end portion 14S of the discharge conveyor 14 to hold the film F in the film transport path 20 in the container transport direction. It is configured to be held from the downstream side. As a result, until the film F is wrapped around the container W, welded and cut, the heat-shrinkable film F2 in the film transport path 20 is discharged even if it is pulled downstream in the container transport direction. Contact with the conveyor 14 and the lower sealing body 42 can be prevented.
(7) The auxiliary roller 73 and the product presser 74 are arranged above the discharge conveyor 14, and support the container W from the top surface 5 side when the film F is wrapped around the container W and sandwiched. It is configured. When the pair of seal bodies 41 and 42 are closed, the auxiliary roller 73 is not driven together with the discharge conveyor 14 and is in a stopped state. As a result, it is possible to prevent the film F from being pulled forward and to prevent the container W from being greatly inclined. Therefore, the force applied to the film F wound around the container W can be limited to the force that the film F is tightened by closing the seal bodies 41 and 42 . Moreover, since the product presser 74 descends so as to contact the tilted top surface 5 of the container W, the posture of the container W can be maintained.
(8) Of the lower film F2 wound around the container W by the hot air device 76, only the film F6 on the rear 8 side of the container W is thermally shrunk. is lightly tightened, positional displacement of the film F with respect to the container W is suppressed. Thereafter, the heater 77 causes the film F6 on the bottom surface 6 side of the container W to shrink, so that the container W is strongly clamped by the film F wound around the container W. Therefore, it is possible to stably pack the film F without displacing the printed portion of the film F with respect to the container W and without disconnecting the connecting portion F3.

<Second embodiment>
Next, a second embodiment will be described with reference to FIGS. 4 to 7. FIG. The packaging apparatus according to the present embodiment is an apparatus for wrapping a belt-shaped film F around the outer periphery of a container W for packaging. The film F is pulled out from the reverse roll 21, and the film F is wound by the winding device 32 provided on the other side.

FIG. 4 is a schematic diagram of a packaging device. The packaging apparatus according to the present embodiment includes a container transport mechanism for transporting a container W (goods), a film transport mechanism for feeding and winding the film F in one direction, and a film F sandwiched and welded. A pair of seal bodies 51 and 52 to be cut between the connection points F3 and F4, and a control section (not shown) for issuing a drive command to these are provided.

The container W used in this embodiment is composed of a container body W1 having an upper opening and a lid W2 closing the opening. The opening of the container body W1 is closed by the lid W2 after the contents are accommodated therein. The container W is wrapped with the film F so as to cover the top surface 5 (upper portion), the front portion 7 and the bottom surface 6 (bottom portion), and the film F is sealed at the rear portion 8 side for packaging. The relationship between the widths of the container W and the film F is such that the entire bottom surface 6 of the container W can be placed on the film F.

As shown in FIGS. 4 to 6, the container transport mechanism is provided with a plurality of conveyors connected in series in order to place and transport the containers W at predetermined intervals. forming. These conveyors are arranged in this order from the upstream side of the conveying direction: an introduction conveyor 11, an intermediate conveyor 13 (first conveyor), and a discharge conveyor 14 (second conveyor). are doing. An article detection device 61 (article detection means) for detecting the arrival of the container W conveyed by the intermediate conveyor 13 is arranged on the conveying end side of the intermediate conveyor 13 .

A film transport path 20 is formed above and below the container transport path 10 through a gap S between the terminal end 13E on the placement surface of the intermediate conveyor 13 on which the container W is placed and the transport start end 14S of the discharge conveyor 14. A film transport mechanism is provided for. The film transfer mechanism includes a film roll 21, a pull-out roller 23, a supply roller 24a, a dancer roller 25, a guide roller 26, and a support roller 29, respectively, in a film transfer path 20a above the container transfer path 10. . In addition, a winding roller 31, a winding device 32, and a support roller 34 are arranged in the film transport path 20b below the container transport path 10. As shown in FIG.

Between the terminal end portion 13E of the placement surface of the intermediate conveyor 13 and the conveying start end portion 14S of the discharge conveyor 14, a pair of fuses for welding the upper film F5 and the lower film F6 of the film F wound around the container W is provided. Seal bodies 51 and 52 are provided.

The film transfer mechanism is configured such that a belt-shaped heat-shrinkable film F2 (film F) is wound around a raw roll 21, and the film F is transferred in one direction via a plurality of rollers. The film F sandwiched between the pair of seal bodies 51 and 52 and cut is sent to the winding device 32 by the winding roller 31 . A pull-out roller 23 is provided as a second film conveying means for pulling out the film F from the original roll 21 . The pull-out roller 23 is driven to rotate by a motor (not shown) driven and controlled by the control unit, pulls out the film F from the film roll 21 , and feeds it to the dancer roller 25 .

A printing device 22 (printing means) is arranged between the raw fabric roll 21 and the pull-out roller 23 . The film F pulled out from the film roll 21 is printed with information on the content by the printer 22 based on information on print timing transmitted from the control unit. Specifically, for each length used for one package, information on the contents is set to be printed in two places so that the information is positioned on the top face 5 and the front part 7 of the container W, respectively. Further, when performing the printing process, the feeding speed of the film pulled out by the pull-out roller 23 is controlled so as to be suppressed to a speed that can correspond to the processing capability of the printing device 22 . Further, in the vicinity of the downstream side of the printing device 22, there is provided a judging means (not shown) for judging the quality of printing by the printing device 22, and its operation is controlled by the control section.

The delivery roller 24a is rotationally driven by a motor (not shown) driven and controlled by the control unit, pulls out the film F delivered by the pull-out roller 23 from the dancer roller 25, and is arranged downstream of the film transport path 20. It is configured to send out toward the support roller 29 . The delivery roller 24a is driven and controlled based on the detection information of the container W detected by the article detection device 61 and the information regarding the article feeding amount by the pulse of the encoder attached to the intermediate conveyor 13. FIG. In this way, the structure in which the feed roller 24a in the upper film transport path 20a feeds the film F toward the support roller 29 corresponds to the "upper film transport means" of the present invention, and the "first film transport means" of the present invention. included in "film transport means".

A dancer roller 25 is arranged between the pull-out roller 23 and the delivery roller 24a in the upper film transport path 20a. The dancer roller 25 has two fixed rollers 25a and three movable rollers 25b below them, and the film F is transported alternately between the movable rollers 25b and the fixed rollers 25a. As a result, when the amount of film pulled out by the pull-out roller 23 decreases due to printing by the printing device 22, the movable roller 25b advances and retreats in the vertical direction to compensate for the required film feed amount by the delivery roller 24a. In this way, along with the printing process by the printing device 22, the structure that compensates for the shortage of the film feeding amount by the drawing roller 23 with respect to the film feeding amount by the delivery roller 24a is the "film feeding amount adjusting means" of the present invention. Equivalent to.

The guide rollers 26 and the support rollers 29 serve as upper film support means for the film F to extend vertically through the gap S between the terminal end portion 13E on the mounting surface of the intermediate conveyor 13 and the conveying start end portion 14S of the discharge conveyor 14. The film F is wound and guided at positions spaced vertically with a gap S therebetween so that the film F can be wound thereon. Specifically, two guide rollers 26 are disposed on the side surface of the upper seal member 41 on the upstream side in the container transport direction in the upper film transport path 20 a , and are supported between the delivery roller 24 a and the guide roller 26 . Two rollers 29 are provided.

The holding roller 28 is arranged between the intermediate conveyor 13 and the discharge conveyor 14, and is positioned upstream in the container conveying direction from the film F extending in the vertical direction. Therefore, after the film F wound around the container W is pinched and cut at the connection points F3 and F4, the film F on the winding device 32 side is not caught by the holding roller 28 at the connection point F3. , and a winding roller 31 to be wound by a winding device 32 . As a result, when the film F is wound by the winding device 32 and the connection point F3 is moved, disconnection of the connection point F3 is prevented, and the film F moves from the film transfer path 20 to the intermediate conveyor 13 side. You can prevent it from flowing.

The winding roller 31 and the winding device 32 are configured to be rotationally driven by a motor controlled by the control section, and wind the film F after welding and cutting in the film transfer path 20 . A movable roller 33 capable of circular motion is arranged between the winding roller 31 and the winding device 32 . This is intended to adjust the difference in film feed amount that occurs in the film transport mechanism. Further, the take-up roller 31 is configured to feed the film F toward the support roller 34 so that the connection point F3 moves upward in the second film feeding, which will be described later. Thus, the structure in which the winding roller 31 in the lower film transport path 20b feeds the film F toward the support roller 34 corresponds to the "lower film transport means" of the present invention. The configuration in which the winding roller 31 winds up or feeds out the film F is included in the "first film conveying means" of the present invention.

Between the holding roller 28 and the take-up roller 31, a supporting roller 34 and a movable roller 35 capable of circular motion are arranged as lower film supporting means. As a result, the film F fed out by the delivery roller 24a is guided by the guide roller 26 through the support roller 29 in the film transport path 20a on the upper side of the film transport mechanism, and the film transport path 20a on the lower side is guided. In 20b, the film F is wound around the winding roller 31 via the supporting roller 34 and the movable roller 35. As shown in FIG.

The pair of seal bodies 51 and 52 are configured such that the upper seal body 51 and the lower seal body 52 are moved toward and away from each other along the vertical direction intersecting the container conveying direction by a driving means composed of a motor or a cylinder. be. As shown in FIG. 7, the upper seal body 51 has a receiving groove 53 and a seal surface 56 at its lower end portion, and the lower seal body 52 has a cutting blade accommodating cutting blade 55 at its upper end portion. It has a groove 54 and a sealing surface 56 . The receiving groove 53 and the cutting blade accommodating groove 54 are formed along the lateral direction crossing the container conveying direction, and the sealing surfaces 56 are formed in front and behind the receiving groove 53 or the cutting blade accommodating groove 54 in the conveying direction. there is A cutting blade 55 is accommodated in a cutting blade accommodation groove 54 of the lower sealing body 52 . The cutting blade 55 is configured to move back and forth toward the receiving groove 53 of the upper seal body 51 by a drive means. A heater is embedded inside the upper and lower sealing bodies 51 and 52, and the film F is sandwiched between the heated sealing surfaces 56 of the upper sealing body 51 and the heated lower sealing body 52. are welded together.

The pair of seal bodies 51 and 52 have thickness dimensions of the upper seal body 51 and the lower seal body 52 corresponding to the inverted trapezoidal container W in which the top surface 5 of the container W protrudes rearward in the conveying direction from the bottom surface 6 . The configuration is different in shape from that (see FIG. 7). Specifically, the thickness T1 of the upper seal body 51 on the front side in the conveying direction through the cutting blade 55 is formed thinner than the thickness T2 of the lower seal body on the front side. As a result, the distance between the pair of seal bodies 51 and 52 in the closed state and the rear side of the container can be made closer. That is, since the film F is welded with the pair of seal bodies 51 and 52 closer to the rear side of the container, the length of the film F for one package can be set shorter. In addition, the area where the film F wrapped around the container rear side and the pair of seal bodies 51 and 52 approach is widened, and the area where the heat-shrinkable film F shrinks can be widened.

Based on the detection information of the container W by the article detection device 61, the pair of seal bodies 51 and 52 convey the discharge conveyor 14 while the front portion 7 in the conveying direction of the container W comes into contact with the film F extending in the vertical direction. It is set so that the film F wound around the container W is clamped and welded after crossing over to the start end 14S. Specifically, the timing of closing the seal bodies 51 and 52 is controlled based on the detection information of the container W and the position information of the container W obtained from the pulses of the encoders attached to the intermediate conveyor 13 and the discharge conveyor 14. be. The height positions at which the film F is sandwiched between the seal bodies 51 and 52 are preset corresponding to the container W. As shown in FIG. The sealing bodies 51 and 52 separate the overlapping portions of the upper film F5 extending above the container W and the lower film F6 extending below the container W in the longitudinal direction in the container conveying direction. Clamp in place and weld. In other words, the sealing bodies 51 and 52 are configured such that the film F is sandwiched between the upper and lower sealing surfaces 56 in front of and behind the receiving groove 53 . As a result, the film F is welded such that the connection points F3 and F4 are located in front of and behind the receiving groove 53, respectively. The configuration for holding and welding the overlapping upper film F5 and lower film F6 in this manner corresponds to the "sealing means" of the present invention.

After the pair of seal bodies 51 and 52 sandwich and weld the upper film F5 and the lower film F6, the cutting blade 55 embedded in the lower seal body 52 advances and retreats to cut the film F. It has become. Specifically, the pair of seal bodies 51 and 52 are positioned at a position where the film F is sandwiched by the seal surface 56, that is, between connection points F3 and F4 located in front of and behind the receiving groove 53 and the cutting blade housing groove 54. Cut the film F. As a result, the connection point F3 of the film F extending vertically in the film transfer path 20 and the connection point F4 on the rear portion 8 side of the container W are separated. In this manner, the cutting blade 55 is advanced and retracted to cut the film F sandwiched between the seal bodies 51 and 52 so that the connection points F3 and F4 are spaced apart in the forward and rearward directions in the conveying direction of the container W. The configuration corresponds to the "cutting means" of the present invention.

The sealing width of the sealing surfaces 56 of the sealing bodies 51 and 52 formed on the front side in the conveying direction of the container W through the cutting blade 55 is greater than the sealing width of the sealing surfaces 56 formed on the rear side. It is formed narrower than the width. In other words, in the longitudinal direction of the film F, the welded and cut film F is longer at the connecting point F3 on the winding device 32 side than at the connecting point F4 on the rear 8 side of the container W. , the dimensions of the sealing surface 56 are set. As a result, when the film F is wound by the winding device 32, the welding strength is maintained so that the joint F3 of the film F does not come off.

The film transfer mechanism is configured to feed the film F in two steps while one container W is being packaged, based on detection information and position information of the container W. As shown in FIG. Specifically, until the container W comes into contact with the film F extending in the vertical direction and reaches the specific position K of the discharge conveyor 14 after crossing the conveying start end 14S of the discharge conveyor 14, the first time After the discharge conveyor 14 temporarily stops conveying the container W, the second film feeding is performed. Information about the cut pitch of the film F, the first and second feed amounts of the film F, and the film winding amount is input and set in the film feed controller. Note that these input settings may be configured to be set via a touch panel.

In the first film feeding, based on the detection information and the position information of the container W, the container W comes into contact with the film F extending in the vertical direction, and is discharged after passing the transport start end 14S of the discharge conveyor 14. Until reaching the specific position K of the conveyor 14, the connection point F3 of the film F extending in the vertical direction is defined by the specified area Z2 determined by the relationship with the container W on the discharge conveyor 14 (the container W reaching the specific position K The delivery roller 24a is driven to deliver the film F so that the film F is positioned in the film collection area positioned closer to the take-up roller 31 than the film F to be wound. Further, the film F is slackened so that the film F contacts the container W until the container W reaches the specific position K of the discharge conveyor 14, but the film F does not cause the container W to be pulled backward in the conveying direction. It is set to be sent out at once. Note that the timing of the first film feed may be any time from when the container W comes into contact with the film F until it reaches the specific position K on the discharge conveyor 14 . Further, in the first film feed in this embodiment, the position of the connection point F3 is maintained at the set position M without the winding roller 31 being rotated in reverse. may be set so that the film F is sent out toward the support roller 34 by reversely rotating so that the roller moves upward.

The total film feeding amount for the first time is less than the length of one package. The length of the film F is set to such an extent that the top surface 5, the front portion 7 and the bottom surface 6 of the container W can be covered without excess film F. The structure for performing the first film feeding in this manner corresponds to the "first film feeding means" of the present invention.

In the second film feeding, after the discharge conveyor 14 temporarily stops conveying the container W based on the detection information and the position information of the container W, the film F is applied to the joint F3 caused by the approach of the seal bodies 51 and 52. The feeding roller 24a and the take-up roller 31 are driven so that the force for pulling the film F is lower than the force capable of releasing the connection at the connection point F3, and the film F is sent out at once so as to slack. Also, the connection point F3 of the film F is set to be positioned in the specified area Z2 (the film collection area located on the winding roller 31 side from the location of the film F scheduled to be wound around the container W that has reached the specific position K). The take-up roller 31 rotates in the reverse direction so that the connection point F3 moves upward, and feeds the film F toward the support roller 34. You can narrow the gap. It should be noted that the setting may be such that only the feeding roller 24a is driven to feed out an appropriate amount of film F to the container W.

The film feeding amount of the second time is set to the remaining film length of the film length required for one package which was not filled in the first film feeding. In other words, when the pair of seal bodies 51 and 52 are closed, the length of the film F surrounding the outer periphery of the container W, the receiving groove 53, and the pair of seal bodies 51 and 52 upstream of the receiving groove 53 are determined. It is set to the remaining length that can secure the length obtained by adding the width and the width of the sealing surface 56 downstream of the receiving groove 53 in the conveying direction. The structure for performing the second film feeding in this way corresponds to the "second film feeding means" of the present invention.

When the film F is sandwiched and cut between the connection points F3 and F4, the film F on the upstream side of the container transport is wound and guided by the support roller 29 and the guide roller 26 in the film transport path 20. and is supported so as to extend vertically through the gap S between the intermediate conveyor 13 and the discharge conveyor 14 . After the film F is clamped, the film transfer mechanism has a set position M (see FIGS. 6A and 6D) in which the height position of the connection point F3 is set in advance so as to correspond to the next coming container W. ), the third film feed is performed. Specifically, the film F is pulled out from the dancer roller 25, and the film F in the film transfer path 20b on the lower side is wound by the winding device 32. As shown in FIG. As a result, the height position of the connecting portion F3 moves downward to the set position M so that the printed portion of the product content on the film F is located on the top surface 5 and the front portion 7 of the container W. .

The timing of the third film feed may be after the overlapping films F are sandwiched between the upper and lower seal members 51 and 52 . For example, the delivery roller 24a may be driven to pull out the film F when the seal bodies 51 and 52 are closed, or the delivery roller 24a may be driven to pull out the film F after the film F is cut. . Further, after the nipping of the film F is released, the winding roller 31 may be set to be driven simultaneously with the delivery roller 24a. In this way, after the film F is nipped, the film F supported in the film transfer path 20 is positioned at the set position M corresponding to the next container W, where the height position of the joint F3 is positioned. , the structure for pulling out the film F from the dancer roller 25 corresponds to the "third film feeding means" of the present invention.

The introduction conveyor 11 in the container conveying mechanism has a belt as a mounting surface, and the belt is driven to run by a motor controlled by the control unit, and conveys the containers W at a constant speed at predetermined intervals. The conveying speed of the introduction conveyor 11 is set according to the target production quantity. A guide 71 for supporting the container W from the side is arranged along the conveying direction of the introduction conveyor 11 . Thereby, the displacement of the container W with respect to the film F is suppressed. The guides 71 for supporting the containers W are similarly arranged on the intermediate conveyor 13 and the discharge conveyor 14 as well.

The intermediate conveyor 13 has a belt as the mounting surface, and the belt is driven to run by a motor controlled by the controller. The intermediate conveyor 13 is set to run at a constant speed faster than the introduction conveyor 11 in order to separate the containers W delivered from the introduction conveyor 11 from the following containers W.

Further, the intermediate conveyor 13 is provided with a container supporting moving body 75 (supporting body) as a pushing means. The container support moving body 75 is configured to be movable along the conveying direction of the container W and to be movable in the horizontal direction crossing the conveying direction. Further, the container support moving body 75 abuts on the rear portion 8 of the container W placed on the intermediate conveyor 13 to push the container W to the specific position K on the discharge conveyor 14, and the seal members 51 and 52 hold the film F. It supports the rear portion 8 of the container W until it is clamped, then moves in the horizontal direction from the container W to release the support of the container W, returns to the upstream side in the conveying direction, and continues until the next container W arrives. configured to wait.

In this embodiment, since the film F is fed in one direction, the film F exerts a force to pull the container W backward on the bottom surface 6 side of the container W. As shown in FIG. In addition, the size of the bottom surface 6 in the left-right direction intersecting the conveying direction of the container W is narrower than the width of the lower film F6. slippery compared to when it is closed). Therefore, when the seal bodies 51 and 52 are closed, the container W is likely to be pulled rearward in the container conveying direction. The container support moving body 75 abuts on the rear portion 8 of the container W to move the container W when the container W passes from the terminal end portion 13E of the mounting surface of the intermediate conveyor 13 to the conveying start end portion 14S of the discharge conveyor 14. It is arranged for pushing and has a function of maintaining the posture of the container W without tilting backward.

The container support moving body 75 delivers the containers W at a speed slightly higher than the speed of the intermediate conveyor 13 in order to prevent the containers W from being disturbed at the moment the containers W pass from the intermediate conveyor 13 to the discharge conveyor 14 . is set. The speed of the discharge conveyor 14 is the same as the movement speed of the container support moving body 75 from the moment the container W reaches the discharge conveyor 14 until it stops. Further, the container support moving body 75 is configured to return to the standby position upstream of the container transport after releasing the support of the container W. As shown in FIG.

The discharge conveyor 14 is a shuttle-type conveyor whose mounting surface is a belt. It is configured to retreat to the downstream side and return to the upstream side so as to reduce the gap S between the mounting surface of the intermediate conveyor 13 and the terminal end portion 13E when the lower seal member 52 moves downward. Further, the discharge conveyor 14 places the containers W from the end portion 13E on the placement surface of the intermediate conveyor 13 based on the detection information of the containers W by the article detection device 61, and the containers W received from the intermediate conveyor 13 are placed thereon. It is configured such that the transportation is temporarily stopped and then the transportation is performed. Specifically, the discharge conveyor 14 is driven to run at a faster speed than the intermediate conveyor 13 when the containers W are placed on the discharge conveyor 14 from the intermediate conveyor 13 . When the container W is conveyed to the specific position K of the discharge conveyor 14, the traveling drive is stopped. When the upper and lower sealing bodies 51 and 52 are closed, even when the film F generates a force that attracts the container W to the upstream side in the conveying direction of the container W, the stopping state of the traveling drive continues.

A mechanism is provided downstream of the discharge conveyor 14 in conveying the container to remove the container W, which is determined to be defective in printing by the determining means, from the system.

Next, the movement and action of the packaging device according to the second embodiment will be described with reference to FIGS. 4 to 7. FIG. 6(a) to (d), the display of some symbols is omitted, and the symbols are displayed using FIG. 5 as a representative diagram.

4 and 5, in the container transport mechanism, the container W is placed on the intermediate conveyor 13 from the introduction conveyor 11 and transported. When the container W reaches the end portion 13E on the placement surface of the intermediate conveyor 13, it is detected by the article detection device 61. As shown in FIG. In the film transfer path 20, the film F (heat-shrinkable film F2) extends vertically through the gap S between the terminal end 13E on the placement surface of the intermediate conveyor 13 and the transport start end 14S of the discharge conveyor 14. are doing. Note that the connection point F3 is located below the container transport path 10 .

In the film transfer mechanism, the film F wound around the original fabric roll 21 is pulled out by the pull-out roller 23 based on the detection information of the container W by the article detection device 61 . The film F is subjected to print processing based on the information regarding the print timing transmitted from the control unit. Incidentally, the film feeding speed of the drawing roller 23 is controlled according to the throughput of the printing device 22 . Further, when a difference in film feeding amount occurs between the drawing roller 23 and the delivery roller 24a due to the printing process, the movable roller 25b of the dancer roller 25 advances and retreats in the vertical direction according to the film feeding amount of the delivery roller 24a. . As a result, the required length of film F is sent out by the delivery roller 24a. Furthermore, between the printing device 22 and the dancer roller 25, the quality of printing is determined by the determining means.

As shown in FIG. 6(a), the container W comes into contact with the vertically extending film F, and while the lower portion of the rear portion 8 of the container W is supported by the container support moving body 75, the conveying start end portion 14S of the discharge conveyor 14 is moved. By the time the container W arrives at the specific position K of the discharge conveyor 14 after crossing over, the first film feeding is performed by the delivery roller 24a based on the detection information and the position information of the container W. The length of the film F to be sent out is less than the length of one package, and the film F does not remain excessively. It is set not to be pulled back. Therefore, the container supporting moving body 75 only comes into contact with the rear portion 8 of the container W and does not receive a large force.

Then, when the container W reaches the specific position K, the drive of the discharge conveyor 14 and the movement of the container support moving body 75 are temporarily stopped. At this time, the film F wrapped around the container W extends to the rear portion 8 side of the container W through the upper and lower portions of the container W. As shown in FIG.

Referring to FIG. 6(b), after the discharge conveyor 14 temporarily stops transporting the container W, the delivery roller 24a and the take-up roller 31 perform the second film delivery. The length of the film F to be delivered is set to the remaining length of the film required for one package, which was not covered by the first film delivery. As a result, the force that pulls the film F and is applied to the joint F3 as the seal bodies 51 and 52 approach each other is less than the force that can release the connection at the joint F3.

The discharge conveyor 14 retreats to the downstream side of the container conveyance so that the gap S between the terminal end 13E on the mounting surface of the intermediate conveyor 13 and the conveyance start end 14S of the discharge conveyor 14 widens, and the container W reaches the specific position K. Later, when the pair of seal bodies 51 and 52 are closed, the upper film F5 and the lower film F6 are sandwiched in an overlapping state and welded on the seal surfaces 56 of the seal bodies 51 and 52 . When the pair of sealing bodies 51 and 52 are closed, the force that attracts the container W to the upstream side in the conveying direction is generated in the film F, and the conveying of the container W by the discharge conveyor 14 continues to be temporarily stopped. Further, the heat-shrinkable film F partially shrinks at the rear portion 8 of the container W due to the heat of the heater embedded in the upper and lower sealing members 51 and 52 .

When the film F is welded, the cutting blade 55 cuts the film F between the connection points F3 and F4. Referring to FIG. 6(c), when the upper seal member 51 and the lower seal member 52 begin to separate after the film F is cut, the discharge conveyor 14 resumes running, and the container support moving body 75 It moves laterally from the container W, releases the support of the container W, and starts moving toward the standby position on the intermediate conveyor 13 . At this time, the film feeding mechanism performs the third film delivery.

As shown in FIG. 6(d), the film F is pulled out from the dancer roller 25 by the delivery roller 24a and transferred to the winding device 32 by the winding roller 31. As shown in FIG. As a result, the connection point F3 of the film F extending vertically in the film transport path 20 moves to the set position M below the container transport path 10 .

The packaging apparatus according to the second embodiment has the following effects in addition to the effects (1) to (3) described in the first embodiment.
(1) The packaging machine can package the container W using the heat-shrinkable film F2. When the heat-shrinkable film F2 is wrapped around the container W and pinched, it shrinks due to the heat of the pair of seal bodies 51 and 52, and the container W is tightened. As a result, the film F is brought into closer contact with the container W, thereby improving the stability of packaging.
(2) In this embodiment, the heat-shrinkable film F2 is transported in one direction and wrapped around the outer periphery of the container W. That is, since the entire film F wound around the container W is heat-shrinkable, the film F is welded by the pair of seal bodies 51 and 52, and the heat of the heater embedded in the seal bodies 51 and 52 causes the container W to shrink. The film F on the rear 8 side of is thermally shrunk, and the tightening of the container W is completed. As a result, the container W can be placed on the heater conveyor 16 and the container W can be tightened by shrinking the film F without blowing hot air against the film F on the side surface of the container. In addition, since packaging can be performed without applying heat to the film F on the top surface 5 and the front portion 7 side of the container W, the printed portion of the film F is kept in that state without shrinking.
(3) After the container W moves from the mounting surface of the first conveyor 13 to the discharge conveyor 14 and is placed on the film F, the container W is placed on the discharge conveyor 14 until the film F is sandwiched by the seal bodies 51 and 52 . Since it does not come into contact with the placement surface (or the contact area decreases), and the frictional force decreases, the container W becomes slippery and the position of the container W tends to shift. By doing so, the container W can be maintained in a stable posture and at an appropriate position until the film F is sandwiched between the seal bodies 51 and 52 .
(4) The film F sandwiched between the pair of seal bodies 51 and 52 is welded by the heat transferred from the seal surface 56, and one of the seal bodies 51 , 52 by cutting blades 55 . The sealing surface 56 is set so that the front side of the cutting blade 55 is narrower than the rear side thereof in the container conveying direction. As a result, the connection point F3 of the film F supported by the guide roller 26 and the support rollers 29, 34, and 35 when cut by the cutting blade 55 is made longer than the connection point F4 at the rear portion 8 of the container W. be able to. Therefore, since the film F wound around the container W has a relatively short connection portion F4, the appearance of the container W is improved. In addition, since the film F extending in the vertical direction by the guide roller 26 and the support rollers 29, 34, and 35 has a relatively long connecting portion F3, the connecting portion F3 is connected when the film F is transported. is difficult to release.
(5) The pair of seal bodies 51 and 52 are arranged forwardly of the cutting blade 55 in the container conveying direction so as to match the shape of the container W in which the top surface 5 of the container W protrudes rearward in the container conveying direction from the bottom surface 6 of the container W. The thickness T1 of the upper sealing body 51, which serves as the side, can be set thinner than the thickness T2 of the lower sealing body 52. As shown in FIG. Thereby, the distance between the pair of seal bodies 51 and 52 in the closed state and the rear portion 8 side of the container W can be made closer. That is, since the film F can be held while the sides of the container W are closer to each other than the pair of seal bodies 51 and 52, the length of the film F for one package can be set short. Further, when the heat-shrinkable film F2 is used for packaging, the area where the film F and the pair of seal bodies 51 and 52 approach on the rear 8 side of the container becomes wider, and the heat-shrinkable film F shrinks. The area to be processed can be widened. Therefore, the film packaging for the container W can be made tighter.
(6) A guide roller 26 is provided on the side surface of the upper seal member 51 to wind and guide the film F in the film transfer path 20 . As a result, the film F extends vertically through the gap S between the end portion 13E on the mounting surface of the intermediate conveyor 13 and the transport start portion 14S of the discharge conveyor 14 without coming into contact with the side surface of the upper seal member 51. . Therefore, the transfer of heat from the upper seal member 51 to the film F in the film transfer path 20 can be suppressed.
(7) A holding roller 28 is disposed in the gap S between the terminal end portion 13E on the mounting surface of the intermediate conveyor 13 and the transport start end portion 14S of the discharge conveyor 14 to hold the film F in the film transport path 20 in the container transport direction. It is configured to be held from the downstream side. As a result, the film F is wound by the winding device 32 via the winding roller 31 without the connecting portion F3 being caught by the holding roller 28 . Therefore, when the film F is wound by the winding device 32 and the connection point F3 is moved, disconnection of the connection point F3 can be prevented.
(8) Since the film F in the film transport path 20 is transported by the third film transport means so that the connection point F3 is positioned below the container transport path 10, the subsequent container W does not include the connection point F3. A film F is wound. As a result, the film-wrapped container W has only one connection point F4 on the rear portion 8 side. Therefore, it is possible to provide products with better appearance.

<Change example>
(1) For the first film feed, control may be performed to feed the film F so as to follow the amount of the container W entering the discharge conveyor 14 (second conveyor).
(2) For the second film feed, the film F is controlled to follow changes in the positions of the upper and lower seal bodies 41, 42, 51, and 52 that accompany the closing operations of the upper and lower seal bodies 41, 42, 51, and 52. may be performed. Alternatively, only one of the film conveying means may be driven. For example, a configuration may be adopted in which only the upper delivery roller 24a is driven to deliver an appropriate amount of film F to the container W.
(3) The first conveyor and the second conveyor of the present invention are not limited to conveyors having a belt as the mounting surface, and the containers W placed on the conveyor are pushed by the container support moving body 75 or the like. It may be configured to push.
(4) The packaging apparatus according to the second embodiment has a configuration in which the heat-shrinkable film F2 is sent out from one direction and wrapped around the container W. can be
(5) The packaging apparatus according to the first embodiment has the upper belt 72 disposed above the intermediate conveyor 13 (first conveyor). It may be configured not to
(6) The packaging apparatus according to the first embodiment is configured such that the dancer rollers 25 as film feeding amount adjusting means are disposed above and below the film transfer mechanism. On the other side, the dancer roller 25 may be omitted.
(7) Instead of the auxiliary roller 73 as the rotating member, an endless belt is rotated, and the container W in contact with the belt is driven to rotate so as to be pulled downstream in the conveying direction, or the rotation is stopped. You may make it switch the control to carry out.
(8) Articles to be packaged by the present packaging apparatus are not limited to containers W with lids, but may be articles such as foodstuffs and medicines that are assembled or stacked.

F: Film F1: Non-shrinkable film F2: Heat-shrinkable film F3, F4: Connection point F5: Upper film F6: Lower film W: Container (article) 5: Top surface (upper part) 6: Bottom surface (bottom part) 7 : Front part 8: Rear part 11: Introduction conveyor 13: Intermediate conveyor (first conveyor)
13E: terminal end on the mounting surface 14: discharge conveyor (second conveyor)
14S: Conveyance starting end 15: Bypass conveyor 16: Heater conveyor 20: Film transfer path 20a: Upper film transfer path 20b: Lower film transfer path 21: Original fabric roll 22: Printer (printing means)
23: Pull-out roller (second film conveying means)
24a, 24b (24): delivery roller (first film transport means)
25: Dancer roller (film feeding amount adjusting means)
26, 27: Guide rollers (film supporting means) 28: Holding rollers 29, 34, 35: Support rollers (film supporting means)
31 (24): Winding roller (first film conveying means)
32: Winding Device 41: Upper Seal Body 42: Lower Seal Body 43: Receiving Groove 44: Cutting Blade Accommodating Groove 45: Cutting Blade 46: Seal Surface 51: Upper Seal Body 52: Lower Seal Body 53: Receiving Groove 54 : Cutting blade accommodating groove 55: Cutting blade 56: Seal surface 61: Article detection device (article detection means)
73: Auxiliary roller (rotary running body) 74: Product presser 75: Container supporting moving body (supporting body) S: Gap K: Specific positions Z1, Z2: Specified areas Q, M: Set positions

Claims (6)

a first conveyor having a placement surface for conveying an article placed on the placement surface;
article detection means for detecting the arrival of the article conveyed by the first conveyor;
a second conveyor that temporarily stops conveying when the article received from the end portion of the placement surface is conveyed to a specific position based on detection information of the article detected by the article detection means;
A band-shaped film is wound and guided at positions separated vertically through the gap so that it can extend in the vertical direction through the gap between the end portion of the mounting surface and the conveying start portion of the second conveyor. an upper film support means and a lower film support means arranged in such a manner;
a first film conveying means having an upper film conveying means for conveying the film toward the upper film supporting means and a lower film conveying means for conveying the film toward the lower film supporting means;
an original fabric roll disposed as a supply source of the film sent out by at least one of the upper film transport means and the lower film transport means;
a second film conveying means for pulling out the film from the original roll;
a printing means for performing a printing process on the film between the original fabric roll and the second film conveying means;
A part of the film transport path on the side where the printing means is arranged and forms a film transport path between one of the second film transport means and the film transport means, and printing by the printing means film feeding amount adjusting means for compensating for the shortage of the film feeding amount by the second film transporting means with respect to the film feeding amount by the one of the film transporting means during processing;
After the article crosses over to the conveying start end of the second conveyor while the front portion of the article facing the downstream side in the conveying direction of the article is in contact with the film extending in the vertical direction, the article is A portion where an upper film extending from above to the rear side of the article and a lower film extending from below the article to the rear side of the article overlap each other with the conveying direction of the article. a sealing means that is sandwiched and welded by a pair of sealing bodies that open and close in the vertical direction and are spaced close to each other;
It is embedded in the sealing body and sandwiched by the sealing body so that the connecting portions of the upper film and the lower film connected by the sealing means are located in front and rear in the conveying direction of the article. A cutting means for cutting the film is provided,
The first film conveying means is configured to detect the film after the article contacts the film extending in the vertical direction and crosses over the conveying start end of the second conveyor based on detection information by the article detecting means. The first film is conveyed so that the joint portion of the film extending in the vertical direction is positioned in a specified area determined by the relationship with the article on the second conveyor until reaching a specific position on the second conveyor. While driving the means to send out the film, the film may cause the article to be pulled backward in the conveying direction even though the film contacts the article until the article reaches the specific position of the second conveyor. a first film feeding means for feeding the film so as not to
After the conveying of the article is temporarily stopped by the second conveyor, the second conveyor is arranged so that the force that pulls the film applied to the connecting portion due to the approach of the sealing member is less than the force that can release the connection of the connecting portion. 1 film conveying means is driven to transfer the remaining film length of the film length required for one package, which was not completed by the film feeding by the first film feeding means, so that the connection portion of the film is the specified region. It has a second film feeding means for feeding so as to be positioned at
The second conveyor continues the temporary stop state of conveying the article when a force attracting the article to the upstream side in the conveying direction of the article is generated in the film due to the closing operation of the pair of seal bodies. A packaging device characterized by: The one of the film conveying means is supported by the film supporting means so as to extend in the vertical direction when the film is cut by the cutting means. 2. The packaging apparatus according to claim 1, further comprising third film feeding means for pulling out said film from said film feeding amount adjusting means so as to be positioned at a set position set corresponding to said article. a rotating body capable of contacting only the upper part of the article that is inclined at a predetermined angle or more when the article passes over the second conveyor,
The rotary traveling body rotates at the same speed as the traveling speed of the second conveyor so as to draw the upper part of the article in contact with the downstream side in the conveying direction, and the upper film and the lower film are separated by the pair of sealing bodies. 3. The packaging device according to claim 1, wherein the rotation is temporarily stopped when the is clamped. In the first conveyor, the size of the bottom of the article in the left-right direction that intersects the conveying direction of the article is narrower than the film width of the lower film. a pushing means for contacting the rear portion of the article and pushing the article when passing to the conveying start end of the second conveyor;
The pushing means has a support that is movable along the conveying direction and movable in the lateral direction,
The support body abuts against the rear part of the article placed on the placement surface, pushes the article to the specific position on the second conveyor, and pushes the article until the film is sandwiched between the seal bodies. 4. The packaging device according to any one of claims 1 to 3, wherein the rear part is supported, and then the article is unsupported by moving in the lateral direction from the article. The pair of seal bodies are formed so that a cutting blade is housed in a cutting blade housing groove formed in one of the seal bodies, and the cutting blade can move back and forth toward a receiving groove formed in the other seal body. In addition, the seal width of the seal surface of the seal body formed on the front side in the conveying direction through the cutting blade is formed narrower than the seal width of the seal surface of the seal body formed on the rear side. 5. A packaging machine according to any one of claims 1 to 4, characterized in that the The pair of sealing bodies sandwiching the upper film and the lower film wound around the article, the upper part of which protrudes rearward in the conveying direction from the bottom of the article, is formed in the lower sealing body. The cutting blade is accommodated in the cutting blade accommodating groove formed so that the cutting blade can move back and forth toward the receiving groove formed in the upper seal body,
The thickness of the upper seal body, which is the front side in the conveying direction through the cutting blade, is formed thinner than the thickness of the front side of the lower seal body. The packaging device according to any one of claims 1 to 5.

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