JP5332603B2 - Beverage filling method and apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a beverage filling method and a beverage filling apparatus for performing an efficient manufacturing of a beverage packaged item without filling beverage in a false bottle and shipping it as it is. <P>SOLUTION: A bottle 1 is molded through a blow molding from a heated preform 6, the bottle is inspected after its molding operation, and either mist or gas of hydrogen peroxide is blown against the bottle while heat applied to the preform is left after the inspection, the bottle is rinsed with sterile air, and after this rinsing operation, the bottle is filled with beverage and sealingly closed. Since the beverage is filled in the bottle only that is normally formed and already inspected, it is possible to supply an appropriate beverage packaged item in the market. Additionally, since either mist or gas of hydrogen peroxide is blown against the bottle while heat added to the preform is left, it is possible to sterilize the bottle with a small amount of hydrogen peroxide, and further when the bottle is made of PET, even if a decreased bottle temperature causes an amount of adsorption of hydrogen peroxide against the bottle wall to be increased, it is possible to prevent this adsorption from being generated. Accordingly, even if the bottle is made of PET, it is possible to discharge residual hydrogen peroxide out of the bottle appropriately through air rinsing operation and further it is possible to eliminate sterile water rinsing operation consuming a large amount of water afterward and requiring a large-scale facility. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a beverage filling method and apparatus for continuously performing from bottle molding to sterilization of a bottle with hydrogen peroxide to beverage filling.

  As a conventional beverage filling device, a molding part for forming a bottle from a preform by blow molding, a sterilization part for sterilizing a bottle molded by the molding part with hydrogen peroxide mist, and an air rinse for a bottle sterilized by the sterilization part An air rinsing unit that is connected to a filling unit that fills and seals the bottle air-rinsed with the air rinsing unit, and a traveling unit that continuously travels the bottle from the molding unit to the filling unit through the sterilizing unit and the air rinsing unit is provided. A portion in which a part from the forming part to the filling part is covered with a chamber is known. According to this beverage filling apparatus, the sterilization effect by the hydrogen peroxide mist can be enhanced by using the heat applied to the bottle at the molding stage (see, for example, Patent Document 1).

  Also known is a beverage filling device in which a bottle forming part and a beverage filling part are connected and covered with a clean room, and a sterile preform is supplied to the forming part so that the sterilization part is omitted. (For example, refer to Patent Document 2).

JP 2006-111295 A JP-A-11-291331

  According to the conventional beverage filling device, it is possible to continuously perform from bottle molding to sterilization of bottles with hydrogen peroxide to beverage filling. Since it is sent, there is a possibility that a defective bottle will be filled with a beverage and shipped as it is. For example, when a bottle is sent to the sterilization process with insufficient temperature, sterilization may be incomplete, and such a bottle may be filled with a beverage and shipped. In addition, there is a risk that the bottle with a scratch or the like is filled with the beverage and shipped.

  In addition, in conventional beverage filling devices, when sterilizing and filling while transporting a bottle, the bottle bodies may come into contact with each other, and hydrogen peroxide does not sufficiently adhere to the bottle body. There is a risk that the bottle may be sterilized poorly or may be damaged.

  Furthermore, in the conventional beverage filling device, for example, when some trouble occurs in the bottle molding unit and the wheel in the molding unit stops, all the wheels in the beverage filling device stop. However, if all the wheels are stopped, there is a problem that all the bottles present in the beverage filling apparatus have to be discarded due to defective molding, excessive adhesion of hydrogen peroxide, and the like.

  Therefore, an object of this invention is to provide the drink filling method and apparatus which can eliminate the said various problems.

  In order to solve the above problems, the present invention employs the following configuration.

  In addition, although the referential mark of drawing is attached | subjected with a parenthesis, this invention is not limited to this.

That is, the invention according to claim 1 is a bottle (1) in which a bottle (1) is formed by blow molding from a heated preform (6) and the residual heat of heat applied to the preform (6) is retained. For the bottle (1) that has reached a predetermined temperature , the temperature of the portion that is likely to generate a cold spot is inspected, while the heat applied to the preform (6) remains in the bottle (1). A beverage filling method of spraying hydrogen oxide mist (α) or gas (β), air rinsing the bottle (1) with aseptic air (γ), and then filling the bottle (1) with the beverage (a) and sealing it. adopt.

As described in claim 2 , in the beverage filling method according to claim 1 , after rinsing the bottle (1) with air (γ) containing hydrogen peroxide gas (β), rinsing with sterile water, Thereafter, the bottle (1) can be filled with the beverage (a) and sealed.

As described in claim 3 , in the beverage filling method according to claim 1 or 2 , a running path is provided for continuously running the molded bottle (1) until the bottle is sealed. Each is formed by a row of wheels (36a etc.) with grippers (28a etc.) around which grippers (28 etc.) grip the neck (1a) of the bottle (1) around each wheel (36a etc.) And the bottle (1) can be passed from the upstream wheel to the downstream wheel.

The invention according to claim 4 includes a molding part (7) for molding a bottle (1) from a heated preform (6) by blow molding, and a bottle (1) molded by the molding part (7). Sterilization part (9) sterilized with hydrogen peroxide mist (α) or gas (β), and air rinse part (96) for rinsing bottle (1) sterilized with sterilization part (9) with aseptic air (γ) And the filling part (10) for filling the beverage (a) to the bottle (1) air-rinsed by the air rinse part (96), and the sterilization part (9) and the air rinse part ( 96), a traveling means for continuously traveling the bottle (1) on the traveling path to the filling part (10) is provided, and at least a portion from the sterilization part (9) to the filling part (10) is a chamber (9a). Etc.) in beverage filling equipment covered with Molded in the molding section (7), the inspection unit to perform temperature tests prone parts cold spots on the bottle (1) which holds the heat of the residual heat added to said preform (8) is, the molding unit ( 7) and the sterilization part (9) are connected to them, and the inspection part (8) has a temperature at a part where the cold spot is easily generated by the temperature inspection at a predetermined temperature. Exclusion means (53a etc.) for excluding the bottle (1) determined not to reach from the travel path is provided, and the travel means is arranged in a row from the molding part (7) to the filling part (10). And a wheel (19a, etc.) arranged in a circle, and the neck (1a) of the bottle (1) around the wheel (19a, etc.) and swiveling, and the bottle (1) from the upstream wheel to the downstream wheel Gripper to hand to ( The gripper (28 etc.) is required for the sterilization of the bottle (1) in the sterilization part (9) by the heat applied to the preform (6) and remaining in the bottle (1). A beverage filling device is adopted in which the running speed is controlled so as to be maintained to a certain extent.

As described in claim 5 , in the beverage filling device according to claim 4 , air (γ) containing hydrogen peroxide gas (β) is sprayed on the bottle (1) by the air rinse section (96). Can be.

As described in claim 6 , in the beverage filling device according to claim 4 , the wheel (36a, etc.) is divided into a desired number of rows and is driven by a separate servo motor (S1, etc.) for each row. Can be.

As described in claim 7 , in the beverage filling device according to claim 4 , the gripper (28 etc.) traveling in the inspection section (8) is subjected to a matte surface treatment. Can do.

According to the first aspect of the present invention, the bottle (1) is molded from the heated preform (6) by blow molding, and a cold spot is likely to occur in the bottle that retains the residual heat of the heat applied to the preform. The temperature of the part is inspected, and only for the bottle that has reached the predetermined temperature, the mist (α) or gas of hydrogen peroxide is added to the bottle (1) while the heat applied to the preform (6) remains. Since it is a beverage filling method in which (β) is sprayed, the bottle (1) is air-rinsed with sterile air (γ), and then the beverage (a) is filled into the bottle (1) and sealed, the inspection is normally formed. Only the used bottle (1) can be filled with the beverage (a). Accordingly, an appropriate beverage package can be supplied to the market. Further, since the mist or gas of hydrogen peroxide is sprayed on the bottle (1) while the heat applied to the preform (6) remains, the bottle (1) can be sterilized with a small amount of hydrogen peroxide. When the bottle (1) is made of PET, the amount of hydrogen peroxide adsorbed to the bottle wall increases as the bottle temperature decreases, but this adsorption can be prevented. Therefore, even if the bottle (1) is made of PET, residual hydrogen peroxide can be properly removed from the bottle (1) by air rinsing, and a large amount of water is consumed later, and aseptic is required for large-scale equipment. Water rinsing can be omitted.

As described in claim 2 , in the beverage filling method according to claim 1 , after rinsing the bottle (1) with air (γ) containing hydrogen peroxide gas (β), rinsing with sterile water, Thereafter, when the bottle (1) is filled with the beverage (a) and sealed, the sterilizing effect of the bottle (1) can be further enhanced and the residual hydrogen peroxide in the bottle (1) is reduced. be able to.

As described in claim 3 , in the beverage filling method according to claim 1 or 2 , a running path is provided for continuously running the molded bottle (1) until the bottle is sealed. Each is formed by a row of wheels (36a etc.) with grippers (28a etc.) around which grippers (28 etc.) grip the neck (1a) of the bottle (1) around each wheel (36a etc.) When the bottle (1) is transferred from the upstream wheel to the downstream wheel, the residual heat is reduced when the preform (6) is heated despite the inspection process. Before long, the bottle (1) can be quickly sterilized effectively with hydrogen peroxide. Further, after the sterilization, the hydrogen peroxide can be promptly sent to the air rinse section (96) before adsorbing to the bottle wall, and the hydrogen peroxide can be prevented from remaining in the bottle (1).

Moreover, according to the invention which concerns on Claim 4 , the shaping | molding part (7) which shape | molds a bottle (1) by blow molding from the heated preform (6), and the bottle (1) shape | molded by the shaping | molding part (7) ) Sterilizing with hydrogen peroxide mist (α) or gas (β), and an air rinsing unit (96) for rinsing the bottle (1) sterilized with sterilizing unit with aseptic air (γ). The bottle (1) air-rinsed by the air rinse part (96) is connected to the filling part (10) for filling the beverage (a), and the sterilization part (9) and the air rinse part (96) from the molding part (7). ) Through which the bottle (1) continuously travels on the traveling path to the filling part (10), and at least a place from the sterilization part (9) to the filling part (10) is a chamber (9a etc. In beverage filling equipment covered with Molded in the molding section (7), the inspection unit to perform temperature tests prone parts cold spots on the bottle (1) which holds the heat of the residual heat added to said preform (8) is, the molding unit ( 7) and the sterilization part (9) are connected to them, and the inspection part (8) has a temperature at a part where the cold spot is easily generated by the temperature inspection at a predetermined temperature. Exclusion means (53a etc.) for excluding the bottle (1) determined not to reach from the travel path is provided, and the travel means is arranged in a row from the molding part (7) to the filling part (10). And a wheel (19a, etc.) arranged in a circle, and the neck (1a) of the bottle (1) around the wheel (19a, etc.) and swiveling, and the bottle (1) from the upstream wheel to the downstream wheel Gripper to hand to ( The gripper (28 etc.) is required for the sterilization of the bottle (1) in the sterilization part (9) by the heat applied to the preform (6) and remaining in the bottle (1). Since the running speed is controlled so as to be maintained to a certain extent, the beverage (a) can be filled only in the inspected bottle (1) that has been normally molded. Accordingly, an appropriate beverage package can be supplied to the market.

  The traveling means for conveying the bottle (1) from the molding (7) to the filling part (10) is a wheel (19a etc.) arranged in a line from the molding part (7) to the filling part (10). A gripper (28, etc.) that grips and swivels the neck (1a) of the bottle (1) around each wheel (19a, etc.) and delivers the bottle (1) from the upstream wheel to the downstream wheel. The gripper (28, etc.) is added to the preform (6) and the heat remaining in the bottle (1) is maintained to the extent necessary for sterilization of the bottle (1) in the sterilization section (9). Since the traveling speed is controlled so as to sag, the bottle (1) is provided so that the residual heat when the preform (6) is heated is not cooled despite the presence of the inspection part (8). Promptly sent to the sterilization section (9) It can be properly sterilized Te. Therefore, a beverage package that has been sterilized normally can be supplied to the market.

  Further, since the bottle (1) is conveyed by gripping the neck (1a) with a gripper (28 etc.), the bottles (1) are prevented from contacting each other. Compared to the conventional air bottle transport system, this gripper (28 etc.) transport system reduces the bioburden that enters the sterilization section (9) from the molding section (7), and the product sterility assurance level (Sterility Assurance Level (SAL) is improved. Furthermore, deformation, scratches, breakage, etc. of the bottle (1) are prevented. Furthermore, conventionally, when switching the size and shape of the bottle, it has been necessary to replace the screw and guide used for introducing the bottle from the air conveyance path to the filling portion according to the size and shape of the body of the bottle. This work can be eliminated. Since the shape and size of the neck of the bottle are constant regardless of the shape and size of the bottle body, the conventionally required screw and guide can be omitted by adopting the gripper bottle transport method. In addition, replacement work and the like can be eliminated.

  Also, since positive pressure means (84, etc.) is provided to positively pressurize the inside of the inspection section (8) than in the molding (7) and the sterilization section (9), the bacteria to the inspection section (8) Intrusion of hydrogen peroxide and hydrogen peroxide can be prevented, and inspection equipment can be protected from contamination by bacteria and corrosion by hydrogen peroxide.

As described in claim 5 , in the beverage filling device according to claim 4 , air (γ) containing hydrogen peroxide gas (β) is sprayed on the bottle (1) by the air rinse section (96). In this case, the sterilizing effect of the bottle (1) can be further enhanced, and the residual hydrogen peroxide in the bottle (1) can be reduced.

As described in claim 6 , in the beverage filling device according to claim 4 , the wheel is divided into a desired number of rows and is driven by a separate servo motor (such as S 1) for each row. In such a case, the wheels belonging to each of the inspection unit (8), the sterilization unit (9), the filling unit (10), and the like are driven by mutually separate servo motors (S1 etc.), so that each unit is operated synchronously. be able to.

As described in claim 7 , in the beverage filling device according to claim 4 , the gripper (28, etc.) installed in the inspection section (8) is subjected to a matte surface treatment. In this case, reflection of light by a gripper or the like can be prevented, and an accurate inspection can be performed.

  The form for implementing this invention is demonstrated below.

<Embodiment 1>
First, the beverage package manufactured by the beverage filling apparatus will be described. As shown in FIG. 1, the beverage package includes a bottle 1 as a container and a cap 2 as a lid. Reference symbol a indicates a beverage filled in the bottle 1.

  The body of the bottle 1 has a substantially cylindrical shape, but may have other shapes such as a rectangular tube shape. The bottom of the body is closed at the bottom, and a neck 1a having a circular opening is provided on the upper side.

  A male screw 3 is formed on the neck 1 a of the bottle 1, a female screw 4 is formed on the cap 2, and the opening of the neck 1 a of the bottle 1 is sealed by screwing the female male screws 4, 3. A support ring 5 is formed on the neck 1 a of the bottle 1 below the male screw 4. As will be described later, the bottle 1 travels in the beverage filling apparatus while being held by the gripper via the support ring 5.

  As will be described later, the bottle 1 is formed by blow molding a substantially test tubular PET preform 6. The bottle 1 is not limited to PET, and other resins such as polypropylene and polyethylene can also be used. The preform 6 is formed by injection molding or the like, and includes a substantially test tubular main body and a neck 1 a similar to the bottle 1. The male thread 3 is formed on the neck 1a simultaneously with the molding of the preform 6.

  The cap 2 is formed by injection molding or the like using a resin such as polyethylene or polypropylene, and the female screw 4 is formed simultaneously with the molding of the cap 2.

  Next, a beverage filling apparatus for filling the bottle 1 with the beverage a will be described.

  As shown in FIG. 2, the beverage filling apparatus includes a molding unit 7 for the bottle 1, an inspection unit 8 for inspecting the molded bottle 1, a sterilization unit 9 for the bottle 1, an air rinse unit 96 for the bottle 1, And a filling unit 10 for filling and sealing the beverage a in the bottle 1.

  The whole of the bottle forming part 7 is covered with a chamber 7a. In the chamber 7a of the molding unit 7, a supply port for the preform 6 and a discharge port for the bottle 1 are provided.

  A preform feeder 11 is installed in the vicinity of the chamber 7 a of the molding unit 7. A large number of preforms 6 shown in FIG. The preform feeder 11 is configured to feed the preforms 6 in an upright state with the neck 1a up as shown in FIG. Yes.

  Since the preform feeder 11 is a known machine, the description thereof is omitted.

  As shown in FIG. 2, an upstream wheel train, a downstream wheel train, and a turntable train provided between both the upstream and downstream wheel trains are disposed in the chamber 7a of the molding unit 7. .

  The starting wheel 13a in the upstream wheel train is a horizontal wheel and is connected to the preform conveyor 12. Around the start wheel 13a, a number of grippers (not shown) for gripping the neck 1a of the preform 6 are provided at a constant pitch. These grippers also rotate along with the rotation of the starting wheel 13a, and the preform 6 supplied from the preform conveyor 12 is gripped near the support ring 5 and conveyed to the next intermediate wheel 13b. The intermediate wheel 13b is arranged vertically, and a large number of forks (not shown) are provided around the intermediate wheel 13b at a constant pitch. The intermediate wheel 13b receives the preform 6 such that the preform 6 gripped by the gripper of the starting wheel 13a with the fork is received under the support ring 5, and then rotates upward to bring the preform 6 into an inverted state. The end wheel 13c is a horizontal wheel having a gripper similar to that of the start end wheel 13a, and the preform 6 inverted by the intermediate wheel 13b is gripped and received by the gripper.

  The turntable row includes first to sixth turntables 14a, 14b, 14c, 14d, 14e, and 14f arranged in a ring shape. Between these turntables 14a, 14b, 14c, 14d, 14e and 14f, an endless chain 15 is stretched. This chain 15 extends long around the third turntable 14c to form a detour. A long detour portion of the chain 15 travels in a heating chamber 16 attached to the chamber 7a. The chain 15 can continuously travel in one direction indicated by an arrow in FIG. 2 along with the rotation of the first to sixth turntables 14a, 14b, 14c, 14d, 14e, and 14f.

  A large number of mandrels 17 shown in FIG. 3B are connected to the chain 15 at a constant pitch. The mandrel 17 is able to run on the turntables 14a, 14b, 14c, 14d, 14e, and 14f while being pulled by the chain 15. The mandrel 17 is supported on the chain 15 so as to be capable of rotating about its axis.

  The first turntable 14a is connected to the end wheel 13c of the upstream wheel train, and each mandrel 17 is placed in the neck 1a of the inverted preform 6 held by the gripper of the end wheel 13c as shown in FIG. ) And the preform 6 is received.

  A heater 16a is provided on the wall surface in the heating chamber 16 as shown in FIG. The mandrel 17 that has received the preform 6 travels along the heater 16a in the heating chamber 16, and the preform 6 held in each mandrel 17 is heated by the heater 16a as shown in FIG. This heating raises the preform 6 to a temperature at which blow molding is possible. In addition, each mandrel 17 rotates with its preform 6 when its buttocks come into contact with a rail (not shown) during traveling, so that the preform 6 is uniformly heated below its neck 1a.

  A large number of blow molding dies 18 as shown in FIG. 3D are provided around the fifth turntable 14e at a constant pitch. The blow molding die 18 can rotate with the rotation of the fifth turntable 14e.

  The blow mold 18 can be divided into two symmetrically. When the heated preform 6 arrives from the fourth turntable 14d, the blow mold 18 rotates around the fifth turntable 14e while FIG. As shown, the preform 6 is sandwiched together with the mandrel 17. A through hole is formed at the center of the mandrel 17, and then a blow nozzle 19 is inserted into the preform 6 into the through hole. The bottle 1 is molded inside the mold 18 by blowing a gas such as air from the blow nozzle 19 into the preform 6.

  The blow mold 18 is opened when the sixth turntable 14f is approached, and the bottle 1 is released. As shown in FIG. 4E, the bottle 1 released from the blow molding die 18 passes through the sixth turntable 14f toward the first turntable 14a while being held by the mandrel 17.

  The starting wheel 19a in the downstream wheel train is connected to the first turntable 14a, and the terminal wheel 19b is in contact with the discharge port of the chamber 7a of the molding unit 7.

  When the bottle 1 held on the mandrel 17 as shown in FIG. 4 (E) arrives by the rotation of the first turntable 14a, the starting wheel 19a grips the bottle with the gripping tool 98 as shown in FIG. Remove from 17 and flip up and down to erect.

  The end wheel 19b has a gripper 28 as shown in FIG. The gripper 28 has a pair of sandwiching pieces 28a and 28b that sandwich the neck 1a of the bottle 1 from the outside. The base portions of the pair of sandwiching pieces 28a and 28b are supported by the wheel 19b so as to be rotatable by vertical pins. A pair of meshing gears 30a and 30b are fixed to the base portions of the sandwiching pieces 28a and 28b via vertical pins. Further, a cam follower 31 a is connected to one gear 30 b via a lever 31, and the other gear 30 a is connected to a wheel 19 b via a lever 32 and a spring 33. The pair of sandwiching pieces 30a and 30b is always urged in the opening direction by the tensile force of the spring 33. On the other hand, the cam 34 with which the cam follower 31a contacts is fixed to a frame (not shown) inside the wheel 19b.

  As a result, when the wheel 19b rotates, the gripper 28 opens the pair of pinching pieces 28a and 28b and receives the neck 1a of the bottle 1 from the gripper 20 of the starting wheel 19a by the sliding contact action between the cam follower 31a and the cam 34. The neck 1a of the bottle 1 is sandwiched, and the bottle 1 is swung to the next inspection unit 8 while being held suspended. When the gripper 28 reaches the inspection portion 8, the pair of sandwiching pieces 28a and 28b are opened by the sliding contact action between the cam follower 31a and the cam 34, and the bottle 1 is transferred to the wheel train on the inspection portion 8 side.

  When the gripper 28 of the end wheel 19b receives the bottle 1 from the gripping tool 98 of the start end wheel 19a, the gripper 28 grips and transports the neck 1a of the bottle 1 below the support ring 5, as shown in FIG.

  As shown in FIG. 2, the inspection unit 8 of the bottle 1 is connected to the molding unit 7 of the bottle 1. The entire inspection unit 8 is also covered with a chamber 8a. As shown in FIG. 15, a passage 35 a for the bottle 1 is provided in the partition wall 35 between the molding unit 7 and the chamber 7 a.

  As shown in FIG. 2, a wheel train connected to a terminal wheel 19 b that is a traveling means of the bottle 1 on the molding unit 7 side is connected in the chamber 8 a of the inspection unit 8. Specifically, this wheel train is composed of three wheels 36a, 36b, and 36c, and the travel path of the bottle 1 is set on the outer periphery thereof. Further, a gripper 28 similar to the gripper 28 in the end wheel 19b is provided around each wheel 36a, 36b, 36c. The gripper 28 delivers the bottle 1 from the start end wheel 36a to the end wheel 36c via the intermediate wheel 36b while holding the neck 1a of the bottle 1 and turning around the wheels 36a, 36b, 36c. Thereby, the bottle 1 continuously travels on the travel path around the wheels 36a, 36b, and 36c in the inspection unit 7 from the terminal wheel 19b in the molding unit 7. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in a suspended state. As shown in FIG. 9, the gripper 28 grips the neck 1a of the bottle 1 above the support ring 5 at the start end wheel 36a, and grips the neck 1a of the bottle 1 below the support ring 5 at the intermediate wheel 36b. The bottle 1 is transported from the upstream side to the downstream side in the inspection unit 8 so that the neck 1a of the bottle 1 is gripped above the support ring 5 by the end wheel 36c.

The starting wheel 36a in the inspection unit 8 that contacts the terminal wheel 19b on the molding unit 7 side of the bottle 1 has an end wheel on the molding unit 7 side when a turntable or wheel on the bottle molding unit 7 side is stopped in an emergency. In order to prevent interference between the bottle 1 held by the gripper 28 attached to 19b and the gripper 37 of the starting wheel 36a on the inspection unit 8 side, gripper interference preventing means is provided.

  Since the gripper interference preventing means is provided, the gripper 37 of the starting wheel 36a in the inspection unit 8 has a different structure from the gripper 28 as shown in FIG.

  That is, as shown in FIG. 10, a plurality of grippers 37 are attached to the starting end wheel 36a in the inspection unit 8 at a predetermined pitch, and each gripper 37 has a pair of sandwiching pieces 37a sandwiching the neck 1a of the bottle 1 from the outside. 37b, and the base portions of the pair of sandwiching pieces 37a and 37b are rotatably supported on the wheel 36a by vertical pins, respectively, and the base portions of the sandwiching pieces 37a and 37b are engaged with a pair of meshing gears 38a, 38b is fixed.

  Further, a cam follower 39 a is connected to one gear 38 a via a lever 39. On the opposite side of the lever 39 from the cam follower 39a, the lever 39 is connected to one sandwiching piece 37a through a pin 40a and an arc-shaped elongated hole 40b. The other pinching piece 37b is integral with the other gear 38b, and a piston rod 42a of the piston / cylinder device 42 is connected to the pinching piece 37b via a pin 41a and an arcuate long hole 41b. The piston / cylinder device 42 is supported by the wheel 36a. A torsion spring (not shown) is attached between the gears 38a, 38b and the wheel 36a, and the pair of sandwiching pieces 37a, 37b are always urged in the closing direction by the torsional force of the torsion spring. Further, the cam follower 39a is constantly pressed against the cam 43.

  Thus, when the starting wheel 36a on the inspection unit 8 side rotates, the gripper 37 opens the pair of sandwiching pieces 37a and 37b by the sliding contact action between the cam follower 39a and the cam 43, and the grip of the terminal wheel 19b on the molding unit 7 side. After the neck 1a of the bottle 1 is received from 28, the neck 1a of the bottle 1 is sandwiched, and the bottle 1 is swung while being held in a suspended state. The pinching pieces 37a and 37b rotate in the opening direction against the torsional force of the torsion spring. At this time, the pins 40a and 41a slide in the arc-shaped elongated holes 40b and 41b.

However, some abnormality may occur on the molding unit 7 side, and the turntable train or wheel train on the molding unit 7 side may stop urgently. At that time, as shown in FIG. 10, the piston rod 42a of the piston / cylinder device 42 is contracted, and the pair of sandwiching pieces 37a and 37b in the closed state are expanded at an angle of about 180 degrees. Thereby, interference between the bottle 1 gripped by the gripper 28 attached to the terminal wheel 19b on the molding part 7 side and the gripper 37 of the starting wheel 36a on the inspection part 8 side is prevented. In this case, since the starting wheel 36a and the row following the wheel 36b following this continue to rotate, the bottle 1 introduced into the inspection section 8 continues to travel downstream.

  The gripper interference prevention means is not limited to the above-described configuration. When the gripper 28 having the structure shown in FIG. 7 is slidable in the radial direction of the wheel 36a by the piston / cylinder device 42 or the like, the interference is avoided. The gripper 28 may be retracted radially inward. Further, the gripper 28 as shown in FIG. 7 may be pivotally supported by a pin or the like so as to be bent above or below the wheel 36a, and the gripper 28 may be bent upward or downward when avoiding interference.

  As shown in FIGS. 4 (G) and 8, the cylindrical portion of the bottle 1 such as a cylindrical shape or a rectangular tube shape is imaged at a predetermined position around the start wheel 36 a in the chamber 8 a in the inspection portion 8. As a bottle body inspection unit that determines whether the bottle 1 is good or bad, a lamp 44 that is an illumination unit and a camera 45 that is an imaging unit are provided. Irradiation light from the lamp 44 is transmitted through the body of the bottle 1, and the camera 45 receives the transmitted light and images the body of the bottle 1. The image of the body of the bottle 1 is processed by an image processing device (not shown), and it is determined whether there is an abnormality such as a scratch, a foreign object, or a discoloration.

  As shown in FIG. 4 (H), FIG. 5 (I) (J) (K) and FIG. 8, along with the intermediate wheel 36b adjacent to the starting wheel 36a, the temperature of the bottle 1 is detected to determine whether the bottle 1 is good or bad. As temperature inspection means for discriminating between the temperature sensor 46 and the support ring 5 of the neck portion 1a of the bottle 1, the support ring inspection means for discriminating the quality of the bottle 1 as the support ring inspection means and the camera 47 of the imaging means. As a bottle neck top surface inspection means for picking up an image of the ring-shaped top surface 1b of the neck 1a of the bottle 1 which should be flat and smooth to determine whether the bottle 1 is good or bad, a lamp 49 of the illumination means and a camera 50 of the imaging means are used. As a bottle bottom portion inspection unit that images the bottom of the bottle 1 to determine whether the bottle 1 is good or bad, a lamp 51 of an illuminating unit and a camera 52 of an imaging unit are sequentially provided.

  In addition, the arrangement | positioning order of the said various test | inspection means can be changed suitably, and a position can also be changed suitably. Further, it can be omitted as appropriate, and other inspection means can be added for other inspection items.

  The temperature sensor 46 is an infrared radiation thermometer, for example, but other thermometers can also be used. As shown in FIG. 4 (H), the temperature sensor 46 is installed to face the support ring 5 and the bottom of the neck 1a of the bottle 1, respectively.

  The bottle 1 is gripped by the grip 28 while retaining the residual heat in the molding unit 7 and is detected by the temperature sensor 46 while traveling around the start wheel 36a and the intermediate wheel 36b at a predetermined speed. . The residual heat of the bottle 1 is necessary for properly sterilizing the bottle 1 with hydrogen peroxide later, and the temperature detected by the temperature sensor 46 is preferably 50 ° C. or higher.

  If any of the temperatures of the bottle 1 detected by the two temperature sensors 46 does not reach the predetermined temperature, the bottle 1 is determined as a defective product. That is, the bottle 1 that has not reached the predetermined temperature may be insufficiently sterilized even if it is sterilized later with hydrogen peroxide. On the contrary, the bottle 1 in which the temperature of the two places of the bottle 1 has reached the predetermined temperature can be sufficiently sterilized by the subsequent sterilization with hydrogen peroxide.

  The two locations of the bottle 1 facing the temperature sensor 46 are portions where the thickness of the resin is large and a cold spot is likely to occur, but the temperature sensor 46 is not limited to the two locations, and the shape of the bottle 1 It can be appropriately increased or decreased depending on the size, the type of the molding die, and the like. For example, it is also possible to install the temperature sensor 46 only on the bottom of the bottle 1 where the cold spot is particularly likely to occur.

  Further, since the temperature of the thin portion of the bottle 1 is lower than that of the thick portion and the heat easily escapes, for example, the temperature sensor 46 may be provided to face the thin portion of the body portion of the bottle 1. . Thereby, only the bottle 1 which maintained the residual heat of minimum temperature required for subsequent sterilization can be conveyed to the sterilization part 9. FIG.

  As shown in FIGS. 5 (I) and 8, the lamp 47 as the support ring inspection means is provided in an annular shape above the support ring 5 of the bottle neck 1a. Specifically, it is configured by arranging LEDs in a ring shape. The camera 48 is arranged so that the illumination light of the lamp 47 receives the light reflected by the upper surface of the support ring 5. The support ring 5 is imaged by the camera 48. At this time, as shown in FIG. 9, the gripping pieces 28 a and 28 b of the gripper 28 hold the neck portion below the support ring 5, so that shooting of the support ring 5 is hindered by the gripping pieces 28 a and 28 b of the gripper 28. There is nothing. By this support ring inspection means, the state of the upper surface of the support ring 5 in particular is intensively inspected.

  The image of the support ring 5 taken by the camera 48 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation. Since the support ring 5 is a place where a purchaser of the bottle 1 as a beverage package may touch when opening the cap, the presence of scratches or deformation is not preferable. The bottle 1 in which scratches, deformations, etc. occur in the support ring 5 exceeding the allowable value is determined as a defective product.

  As shown in FIG. 5 (J) and FIG. 8, the lamp 49 as the bottle neck top surface inspection means is provided in an annular shape above the top surface 1b of the bottle neck 1a. Specifically, it is configured by arranging LEDs in a ring shape. The camera 50 is arranged so that the illumination light of the lamp 49 receives light reflected by the top surface 1b. The top surface 1b is imaged by the camera 50. The image of the top surface 1b captured by the camera 50 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation. Since the top surface 1b of the bottle neck 1a is a portion that seals the inside of the bottle 1 when it hits the ceiling of the cap 2 (see FIG. 1), it needs to be flat and smooth. For this reason, the bottle 1 in which a crack, a deformation | transformation, etc. produced in the top | upper surface 1b is judged to be a defective product.

  As shown in FIGS. 5K and 8, the lamp 51 as the bottle bottom portion inspection means is provided in an annular shape below the bottom portion of the bottle 1. Specifically, it is configured by arranging LEDs in a ring shape. The camera 52 is disposed above the neck 1 a of the bottle 1 so that the illumination light of the lamp 51 receives light transmitted through the bottom of the bottle 1. The camera 52 images the bottom of the bottle 1. An image of the bottom of the bottle 1 taken by the camera 52 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch, a foreign object, or a color change.

  Although not shown, the gripper 28 that travels in the inspection unit 8 has a matte surface treatment. Thereby, it is possible to prevent an inspection error caused by the illumination light from the various lamps 47, 49, 51 being reflected by the gripper 28. Further, a viewing window (not shown) is provided in the chamber 8a of the inspection unit 8, and a light shielding glass is provided in the window so that light outside the chamber 8a does not enter the chamber 8a.

  As shown in FIG. 11, the terminal wheel 36c that contacts the intermediate wheel 36b from the downstream side has a gripper 28 similar to the gripper 28 of the intermediate wheel 36b. When the terminal wheel 36c rotates, the gripper 28 opens the pair of pinching pieces 28a and 28b by the sliding contact action between the cam follower 31a and the cam 53, and receives the neck 1a of the bottle 1 from the grip 28 of the intermediate wheel 36b. One neck 1a is sandwiched and the bottle 1 is swung to the next sterilization unit 9 while being held suspended. When the grip 28 reaches the sterilizing unit 9, the pair of sandwiching pieces 28a and 28b are opened by the sliding contact action between the cam follower 31a and the cam 53, and the bottle 1 is transferred to the wheel on the sterilizing unit 9 side. The cam 53 is fixed to a stationary frame (not shown) inside the terminal wheel 36c.

  The terminal wheel 36c is provided with a removing means for removing the bottle 1 that has been determined to be defective by the inspection in the inspection unit 8 from the traveling path.

  The exclusion means has a gripper opening mechanism as shown in FIGS. The gripper opening mechanism cams an additional cam follower 31b having the same shape as the cam follower 31a further added to the pivot 54 of the cam follower 31a, and an additional cam 55 having a partly different shape from the cam 53 in contact with the additional cam follower 31b. 53 below. Further, only a part of the cam 53 is provided as a separate body and a movable cam portion 53a is provided.

  The movable cam portion 53a is slidably inserted in a radial direction in a trace where a part of the stationary cam 53 is cut off. And it is connected with the piston rod 56a of the piston and cylinder apparatus 56 connected with the flame | frame which is not shown inside the wheel 36c. Further, a concave portion 55a into which the additional cam follower 31b is fitted is formed in a portion of the additional cam 55 corresponding to the movable cam portion 53a.

  In addition, the exclusion means is provided with a cylindrical shooter for eliminating defective bottles indicated by reference numeral 57 in FIGS.

  When the inspection unit 8 issues a signal indicating that the bottle 1 is determined to be defective, the piston / cylinder device initially in the extended state as shown in FIG. 12 (A) is shown in FIG. The movable cam 53a is retracted inward in the radial direction of the cam 53 as shown in FIG. For this reason, the additional cam follower 31b is immersed in the recess 55a of the additional cam 55, and the pair of sandwiching pieces 28a, 28b of the gripper 28 changes from the closed state indicated by the two-dot chain line to the open state indicated by the solid line, thereby causing a defective bottle. Release 1 The defective bottle 1 falls below the gripper 28 and is sent from the shooter 57 to a predetermined stacking unit. For the non-defective bottle 1, the movable cam portion 53 a is held at the position shown in FIG.

  As shown in FIG. 2, the sterilization unit 9 of the bottle 1 is connected to the inspection unit 8 of the bottle 1. The entire sterilizing part 9 is also covered with a chamber 9a.

  As shown in FIG. 2, a wheel train connected to a terminal wheel 36 c that is a traveling means of the bottle 1 on the inspection unit 8 side is connected in the chamber 9 a of the sterilization unit 9. Specifically, this wheel train is composed of two wheels 58a and 58b, and the traveling path of the bottle 1 is set on the outer periphery thereof. A gripper 28 similar to the gripper 28 shown in FIG. 7 is provided around each of the wheels 58a and 58b.

  The gripper 28 sequentially transfers the bottle 1 from the start wheel 58a to the end wheel 58b while gripping and turning the neck 1a of the bottle 1 around the wheels 58a and 58b. Thereby, the inspected non-defective bottle 1 continuously travels on the traveling path from the terminal wheel 36 c in the inspection unit 8 to the terminal wheel 58 b in the sterilization unit 9. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in an upright suspended state.

  In the chamber 9a of the sterilizing section 9, a condensed mist of hydrogen peroxide as a sterilizing agent is placed on the bottle 1 at a predetermined position around the intermediate wheel 58b that contacts the starting wheel 58a from the downstream side, as shown in FIG. A spray tube 59 is provided as a condensed mist supply means for supplying α. The spray tube 59 is fixed at a fixed position so that the nozzle hole at the tip of the spray tube 59 can directly face the opening of the neck portion 1a of the non-defective bottle 1 that runs immediately below the spray tube 59.

  As shown in FIG. 6 (L), a tunnel 60 is provided along the bottle traveling path below the spray pipe 59 as necessary.

  There may be one or a plurality of spray tubes 59, and they are installed along the periphery of the intermediate wheel 58b. In the illustrated example, it is installed around the intermediate wheel 58b, but it can also be installed around another wheel.

  The hydrogen peroxide condensation mist α is generated by condensing hydrogen peroxide sprayed and heated by the mist generating device 61 shown in FIG.

  The mist generating device 61 includes a hydrogen peroxide supply unit 62 that is a two-fluid spray that supplies an aqueous solution of hydrogen peroxide that is a sterilizing agent in the form of droplets, and a hydrogen peroxide supplied from the hydrogen peroxide supply unit 62. And a vaporizing section 63 for heating and vaporizing the spray to a temperature not lower than the boiling point and not higher than the non-decomposition temperature. The hydrogen peroxide supply unit 62 introduces an aqueous solution of hydrogen peroxide and compressed air from the hydrogen peroxide supply channel 62a and the compressed air supply channel 62b, respectively, and sprays the aqueous solution of hydrogen peroxide into the vaporization unit 63. ing. The vaporizing unit 63 is a pipe having a heater 63a sandwiched between inner and outer walls, and heats and vaporizes the spray of hydrogen peroxide blown into the pipe. The vaporized hydrogen peroxide gas is ejected as a condensed mist α from the spray tube 59 toward the opening of the neck 1 a of the bottle 1.

  The bottle 1 is conveyed around the wheel 58b with its neck 1a facing upward, and the lower end of the spray tube 59 opens toward the neck 1a of the bottle 1 above the traveling path. The hydrogen peroxide condensation mist α sent into the spray tube 59 is continuously blown out from the nozzle hole at the lower end of the spray tube 59 toward the neck 1 a of the bottle 1. The hydrogen peroxide condensation mist α that has blown out flows into the bottle 1 from the neck 1 a of the traveling bottle 1 to sterilize the inner surface of the bottle 1, and the other hydrogen peroxide condensation mist α passes outside the bottle 1. It flows and sterilizes the outer surface of the bottle 1. At this time, since the bottle 1 travels in the tunnel 60, the condensed mist α uniformly contacts the outer surface of the bottle 1.

  As shown in FIG. 2, the air rinse part 96 of the bottle 1 is connected to the sterilization part 9 of the bottle 1. The air rinse part 96 is also entirely covered with a chamber 96a.

  In the chamber 96a of the air rinse part 96, as shown in FIG. 2, the wheel row | line | column connected with the termination | terminus wheel 58b which is the running means of the bottle 1 by the side of the said sterilization part 9 is connected. Specifically, this wheel train is composed of four wheels 58c, 58d, 58e, and 92a, and the travel path of the bottle 1 is set on the outer periphery thereof. A gripper 28 similar to the gripper 28 shown in FIG. 7 is provided around each wheel 58c, 58d, 58e, 92a.

  The gripper 28 sequentially transfers the bottle 1 from the start wheel 58c to the end wheel 92a while holding the neck 1a of the bottle 1 and turning around the wheels 58c, 58d, 58e, and 92a. As a result, the inspected non-defective bottle 1 continuously travels on the travel path from the terminal wheel 58b in the sterilizing unit 9 to the terminal wheel 92a in the air rinse unit 96. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in an upright suspended state.

  Around the intermediate wheel 58c of the next stage contacting the intermediate wheel 58b from the downstream side, air rinsing means for supplying the bottle 1 with aseptic heated air or room temperature air to clean the bottle 1 is provided.

  As shown in FIGS. 6 (M) and 14, the air rinsing means includes a nozzle 64 that discharges aseptic heated air γ or room temperature air.

  As shown in FIG. 14, a wheel 58 c that rotates with power from a predetermined drive source is horizontally attached to a turning shaft 66 that stands on a machine base 65. A column 66a extends upward from the surface of the wheel 58c, and a manifold 67 into which the heated air γ flows is fixed to the upper end of the column 66a. From the upper center of the manifold 67, a conduit 68 extends upward on an extension line of the axis of the pivot shaft 66, and this conduit 68 is held by a frame member of the chamber 9 a connected to the machine base 65 via a bearing 69. Thereby, the manifold 67 can rotate around the turning shaft 66 integrally with the wheel 58c.

  Further, another support column 70 extends upward from the surface of the wheel 58 c, and the gripper 28 of the bottle 1 is attached to the upper portion of the support column 70. A number of supports 70 and grippers 28 are arranged around the wheel 58c at a predetermined pitch. Since many grippers 28 are connected to the wheel 58c via the support column 70, the gripper 28 rotates with the rotation of the wheel 58c.

  These grippers 28 have the same structure as that shown in FIG. Further, for example, when the mist generating device 61 of the sterilizing unit 9 is defective and the bottle 1 with poor sterilization is generated, as an excluding means for removing the bottle 1 from the traveling path, the one shown in FIGS. 11 and 12 A similar mechanism is provided. In FIG. 2, what is indicated by reference numeral 71 is a shooter for dropping the sterilized defective bottle 1 that should be excluded from the running path of the bottle 1 by this exclusion means.

  A supply pipe 72 of heated air γ extends from around the manifold 67 toward each gripper 28, and the nozzle 64 is attached to the tip of each supply pipe 72. The nozzle 64 is fixed to the column 70, and the nozzle hole at the tip of the nozzle 64 faces the opening of the neck 1 a of the bottle 1 held by the gripper 28. As a result, when the wheel 58 c rotates, the nozzle 64 turns around the turning shaft 66 together with the bottle 1 held by the gripper 28, and blows heated air γ into the bottle 1.

  Another stationary conduit 74 is connected to the upper end of the conduit 68 of the manifold 67 through a seal member 75. The conduit 68 is rotated integrally with the manifold 67 with respect to the conduit 74, and the seal member 75 prevents the heated air γ from leaking from the connection portion of both the tubes 68 and 74.

  On the upstream side of the conduit 74, a hot air supply device including a blower 76, a ULPA (Ultra Low Penetration Air Filter) filter 77, and an electric heater 78 is provided. The air drawn from the blower 76 is purified by the ULPA filter 77, heated to a predetermined temperature by the electric heater 78, and sent as heating air γ into the conduit 74. The heated air γ is aseptic air and is heated to a temperature of 100 ° C. or higher, for example. This heated air γ reaches the manifold 67 and blows out from the nozzle 64 into the bottle 1 through each supply pipe 72 or flows out of the bottle 1.

  The conduit from the conduit 74 to the nozzle 64 through the manifold 67 is formed as short as possible, so that the heated air γ reaches the bottle 1 without condensation.

  When heated air γ is blown into the bottle 1 from the nozzle 64, the entire surface of the inner surface of the bottle 1 is uniformly contacted, and the excess hydrogen peroxide blown from the spray pipe 59 is removed.

  The heating air γ may be blown in a range in which all of the hydrogen peroxide condensation mist α drifting inside the bottle 1 can be discharged. When the temperature of the heated air γ is equal to or higher than the heat resistance temperature of the bottle 1, care should be taken because if the blowing time is too long, the bottle 1 may be heated beyond the heat resistance temperature and may be deformed.

  If necessary, the sterilized air at room temperature may be mixed with the condensed mist of low-concentration hydrogen peroxide to gasify the hydrogen peroxide, and the nozzle 64 may be used to prevent condensation. You may make it supply.

  Thus, the sterilized heated air γ is supplied into the bottle 1 and the air rinsing process is performed, whereby the bottle 1 is heated from the inner surface, and the sterilization effect by the condensed mist α of hydrogen peroxide is enhanced.

  In the illustrated example, the nozzle 64 blows heated air γ into the bottle 1 in a state of coming out of the bottle 1. However, each nozzle 64 is provided so as to be movable up and down, and the heated air γ is blown into the bottle 1. Sometimes it is also possible to enter the bottle 1.

  The gripper 28 at least from the start wheel 36a in the inspection unit 8 to the end wheel 92a in the sterilization unit 9 described above has the heat remaining in the bottle 1 when the bottle is molded in the molding unit 7 at the sterilization unit 9. The traveling speed is controlled so as to be maintained to the extent necessary for sterilization of the bottle 1.

  That is, as shown in FIG. 2, the inspection unit 8 is provided with a servo motor S1 that drives all the wheels 36a, 36b, 36c in the inspection unit 7 so as to be mechanically interlocked, and the sterilization unit 9 and the air rinse unit 96 are provided. In addition, a servo motor S2 for driving all the wheels 58a, 58b, 58c, 58d, 58e, and 92a in the sterilizing unit 9 and the air rinsing unit 96 so as to be dynamically linked is provided. The traveling speed of the gripper 28 is adjusted by the control of the servo motors S1 and S2, and as a result, the gripper is kept in a state in which the heat remaining in the bottle 1 at the time of bottle molding is maintained to the extent necessary for sterilization in the sterilization unit 9. The bottle 1 held by 28 arrives directly under the spray pipe 59. Further, the bottle sprayed with the condensed mist α of hydrogen peroxide from the spray tube 59 in the sterilization unit 9 quickly reaches the air rinse unit 96.

  The temperature of the bottle 1 immediately below the spray pipe 59 is desirably maintained at 50 ° C. or higher. By being maintained at 50 ° C. or higher, the bactericidal effect due to the condensed mist α of hydrogen peroxide is appropriately exhibited. In particular, the neck 1a of the bottle 1, the thick portion of the meat such as the bottom, and the portion where the condensate mist α is difficult to reach such as the bottom are difficult to sterilize. Since the portion is in a high temperature state, a high bactericidal effect can be obtained even with a small amount of condensed mist α.

  In this beverage filling device, a positive pressure means is provided for positive pressure in the inspection unit 8 than in the molding unit 7 and the sterilization unit 9.

  That is, as shown in FIG. 15, an atmosphere blocking chamber 79 is provided between the chamber 8 a of the inspection unit 8 and the chamber 9 a of the sterilization unit 9. A partition wall 35 having an opening 35a for the bottle 1 is provided between the chamber 7a of the molding unit 7 and the chamber 8a of the inspection unit 8, and partition walls 80 and 81 similar to the partition wall 35 are provided in the inspection unit 8. They are provided between the chamber 8a and the atmosphere blocking chamber 79, and between the atmosphere blocking chamber 79 and the chamber 9a of the sterilizing unit 9. Further, between the chamber 9a of the sterilization section 9 and the chamber 96a of the air rinse section 96, a similar partition wall 82 sprays a hydrogen peroxide condensed mist α from the spray pipe 59 and a hydrogen peroxide gas β. It is provided so as to be separated from the place to be.

  An air supply duct 83 is connected to the chamber 8a of the chamber 8a of the inspection unit 8 as a means for supplying purified air. The air supply duct 83 is connected to an air supply blower 84, a filter 85, and a heater 97. And are provided. Since the air is heated by the heater 97 and this air contacts the bottle 1 running in the chamber 8a, the cooling of the bottle 1 is prevented or further heated. In addition, if the residual heat at the time of shaping | molding of the bottle 1 is a grade which does not interfere with the sterilization effect in the sterilization part 9, the heating by this heater 97 is omissible.

  When clean air is blown into the chamber 8a of the inspection unit 8 by the air supply means, the chamber 8a of the inspection unit 8 is positively pressurized to, for example, about 3 Pa, which is higher than the atmospheric pressure.

  An exhaust duct 86 is connected to the atmosphere blocking chamber 79 as exhaust means, and an exhaust blower 87 and a filter 88 are provided in the exhaust duct 86. An exhaust duct 89 is connected to a portion of the chamber 9 a of the sterilization unit 9 adjacent to the atmosphere blocking chamber 79 as necessary, and the exhaust duct 89 is connected to the exhaust duct 86 connected to the atmosphere blocking chamber 79. Connected. By exhausting by this exhausting means, the atmosphere blocking chamber 79 is maintained at 0 Pa, which is about the same as the atmospheric pressure.

  In addition, although not shown, a supply air duct is connected to the chamber 10a in the chamber 10a of the filling unit 10 to be described later, and the supply air blower and filter are connected to the supply duct. And are provided. By this air supply means, clean air is blown into the chamber 10a of the filling unit 10 at a pressure of about 20 to 100 Pa. This air flows into the chamber 9a of the sterilizing unit 9 through the chamber 96a of the air rinsing unit 96. After the inside of the chamber 9a of the sterilizing unit 9 is positively pressurized to about 10 Pa, the duct 89 of the chamber 9a of the sterilizing unit 9 is used. And flows from the duct 86 of the atmosphere blocking chamber 79 to the outside of the chambers 9a and 79.

  In addition, the inside of the chamber 7a of the molding part 7 is maintained at 0 Pa, which is approximately the same as the atmospheric pressure. In addition, an air nozzle 90 for blocking the passage port 81a with an air curtain is provided in the passage port 81a of the bottle 1 in the partition wall 81 between the atmosphere blocking chamber 79 and the chamber 9a of the sterilization unit 9 as necessary. .

  By such positive pressure generating means, hydrogen peroxide mist α and gas β flowing into the chamber 9a of the sterilization unit 9 are discharged from the duct 89 to the outside of the chamber 9a, and flow into the chamber 8a of the inspection unit 8. The purified air flows toward the chamber 7a of the molding unit 7 and the atmosphere blocking chamber 79, and prevents the inflow of contaminated air or air containing hydrogen peroxide into the chamber 8a of the inspection unit 8. . Even if air is drawn from the chamber 7 a of the molding unit 7 into the chamber 8 a of the inspection unit 8 as the bottle 1 travels, the air is exhausted from the atmosphere blocking chamber 79, and the chamber of the sterilization unit 9 Since the inflow into 9a is prevented, the contamination in the sterilization part 9 is prevented appropriately.

  As shown in FIG. 2, the filling portion 10 is connected to the air rinse portion 96.

  The filling portion 10 is also entirely covered with a chamber 10a. A partition (not shown) is provided between the air rinse unit 96 and the chamber 96a, and a passage port for the bottle 1 is provided in the partition.

  As shown in FIG. 2, a wheel train connected to a terminal wheel 92 a that is a traveling means of the bottle 1 on the air rinse part 96 side is connected in the chamber 10 a of the filling part 10.

  Specifically, this wheel train is composed of four wheels 94c, 94d, 94e, 94f, and the traveling path of the bottle 1 is set on the outer periphery thereof. Further, around each wheel 94c, 94d, 94e, 94f, a gripper 28 similar to the gripper 28 shown in FIG. 7 is provided.

  In the chamber 10a of the filling unit 10, the gripper 28 holds the neck 1a of the bottle 1 around each wheel 94c, 94d, 94e, 94f and turns, while sequentially turning the bottle 1 from the start wheel 94c to the end wheel 94f. Deliver. Thereby, the bottle 1 continuously travels in the filling portion 10 from the start end wheel 94c to the end wheel 94f. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in an upright suspended state.

  In the chamber 10a of the filling unit 10, the starting wheel 94c is a large-diameter wheel, and a beverage filling machine is installed at a predetermined position around the wheel 94c. As shown in FIG. 6 (N), the beverage a previously sterilized is filled into the bottle 1 by the nozzle 95 of this beverage filling machine. The nozzle 95 travels synchronously with the bottle 1 and fills the bottle 1 with a certain amount of beverage a while traveling along the bottle 1.

  Further, a capper is installed at a predetermined position around the intermediate wheel 94e downstream of the beverage filling machine. As shown in FIG. 6 (O), the cap 2 is attached to the neck 1a of the bottle 1 by this capper. Thereby, the bottle 1 is sealed.

  The bottle 1 filled with the beverage a and sealed with the cap 2 is released from the gripper 28 of the end wheel 94f and discharged from the outlet of the chamber 10a to the outside of the beverage filling device.

  In addition, since a drink filling machine and a capper are well-known apparatuses, those detailed description is abbreviate | omitted.

  In addition, as shown in FIG. 2, the filling unit 10 is provided with two servomotors S5 and S6 for driving the wheels 94c, 94d, 94e, and 94f in the filling unit 10 so as to be dynamically linked in a predetermined combination. . Of these, the first servo motor S5 drives the starting wheel 94c where the beverage filling machine is placed, and the second servo motor S6 is the wheel 94d downstream of the intermediate wheel 94c where the beverage filling machine is placed. , 94e, 94f are driven.

  As a result, even if the wheel and gripper structures in the inspection unit 8, the sterilization unit 9, the air rinse unit 96, and the filling unit 10 are different from each other, the servo motors S1, S2, S5, and S6 are controlled. The gripper can be driven synchronously, and the bottle 1 can be smoothly and continuously traveled from the molding part 7 to the filling part 10.

  In the above embodiment, the molding unit 7 is driven by a normal electric motor (not shown), but the wheel and turntable of the molding unit 7 can also be driven by a servo motor.

  Next, the operation of the beverage filling apparatus will be described.

  (1) First, a preform 6 as shown in FIG. 3A is prepared. The preform 6 is molded by injection molding (not shown) and then put into the preform feeder 11 of this beverage filling apparatus.

  The preform 6 is supplied into the molding unit 7 by the conveyor 12 of the preform supplier 11.

  (2) The preform 6 that has been conveyed by the conveyor 12 in a state as shown in FIG. 3A is received by the gripper of the starting wheel 13a that rotates continuously in the molding section 7, and is inverted by the gripper of the intermediate wheel 13b. State.

  The inverted preform 1 is placed on the mandrel 17 of the first turntable 14a from its neck 1a as shown in FIG. 3B.

  As shown in FIG. 3C, the mandrel 17 covered with the preform 6 travels in the heating chamber 16 while rotating, and the preform 6 continuously travels in the heating chamber 16 while rotating together with the mandrel 17. . Thereby, the preform 6 is heated uniformly and rises to a temperature at which blow molding is possible.

  (3) The heated preform 6 is sandwiched between blow molding dies 18 and air is blown from a blow nozzle 19 penetrating the mandrel 17 as shown in FIG. As a result, the bottle 1 is molded in the mold 18.

  The molded bottle 1 is taken out from the mold 18 together with the mandrel 17 by opening the mold 18, and as shown in FIG. 4 (E), the first bottle 1F passes through the sixth turntable 14f in an inverted state. Head to the turntable with 14a.

  (4) As shown in FIG. 4 (F), the bottle 1 held on the mandrel 17 in the first turntable 14a is gripped by the gripping tool 98 of the starting wheel 19a and brought into an upright state. At this time, the gripping tool 98 grips the upper side of the support ring 5 of the neck 1 a of the bottle 1. Subsequently, the bottle 1 is received by the gripper 28 as shown in FIG. 7 of the end wheel 19b. At this time, as shown in FIG. 9, the gripper 28 grips the lower side of the support ring 5 of the neck 1 a of the bottle 1.

  (5) The gripper 37 of the start end wheel 36a of the inspection unit 8 grips and receives the upper side of the support ring 5 of the neck 1a of the bottle 1 from the end wheel 19b of the forming unit 7. The bottle 1 rotates while being held by the gripper 37.

  During this turning movement, as shown in FIG. 4 (G), the body of the bottle 1 is inspected by the bottle body inspection means. In this inspection, an image of the body portion of the bottle 1 taken by the camera 45 is processed by an image processing device (not shown), and it is determined whether there is an abnormality such as a scratch, a foreign object, or a color change.

  (6) The bottle 1 is transferred from the gripper 37 of the start wheel 36a to the gripper 28 of the intermediate wheel 36b, and the gripper 28 of the intermediate wheel 36b supports the neck 1a as shown in FIGS. The lower side of the ring 5 is gripped to perform a turning motion.

  During this turning motion, as shown in FIG. 4 (H), the temperature of the bottle 1 is detected by the temperature sensor 46 of the temperature inspection means. When the temperature detected by the temperature sensor 46 does not reach, for example, 50 ° C., the bottle 1 is determined to be defective.

  (7) Subsequently, as shown in FIG. 5I, the surface condition of the support ring 5 of the bottle 1 is inspected by the support ring inspection means. In this inspection, an image on the upper surface of the support ring 5 photographed by the camera 48 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation.

  (8) Following the inspection of the support ring 5, as shown in FIG. 5 (J), the surface state of the top surface 1b of the bottle neck 1a is inspected by the bottle neck top surface inspection means. In this inspection, the image of the top surface 1b of the bottle neck 1a taken by the camera 50 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation.

  (9) Following the inspection of the top surface 1b of the bottle neck 1a, as shown in FIG. 5 (K), the bottom of the bottle 1 is inspected by the bottle bottom inspection means. In this inspection, an image of the bottom of the bottle taken by the camera 52 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch, a foreign object, or a color change.

  (10) The bottle 1 that has undergone the above various inspections is held by the gripper 28 shown in FIG. 11 of the terminal wheel 36 c of the inspection unit 8. When an abnormal signal is generated by any of the various inspection means, as shown in FIG. 12, the gripper opening mechanism is actuated, and the pair of sandwiching pieces 28a, 28b of the gripper 28 is indicated by a solid line from a closed state indicated by a two-dot chain line. The state changes to the open state, and the defective bottle 1 is released.

  As a result, the defective bottle 1 with scratches on the body, bottom, neck top surface 1b, and support ring 5 of the bottle 1 is removed from the traveling path, and is sterilized with hydrogen peroxide in a later sterilization step. However, the bottle 1 having a temperature at which a sufficient sterilizing effect cannot be obtained is also excluded from the travel path.

  On the other hand, for the non-defective bottle 1, since the movable cam portion 53a is held at the position shown in FIG.

  (11) The non-defective bottle 1 is transferred continuously from the gripper 28 of the end wheel 36c of the inspection unit 8 to the gripper 28 of the start end wheel 58a of the sterilization unit 9, and thereafter continuously transferred to the gripper 28 of the downstream wheel. To do.

  When the non-defective bottle 1 travels while being held by the gripper 28 around the intermediate wheel 58b, it passes directly under the spray tube 59 as shown in FIG. 6 (L). Thereby, the condensed mist α of hydrogen peroxide discharged from the spray pipe 59 is sprayed toward the bottle 1, and the inner surface and the outer surface of the bottle 1 are sterilized. As described above, since only the non-defective bottles 1 with moderate heat remaining arrive, these bottles 1 travel downstream after being properly sterilized by the condensed mist α of hydrogen peroxide.

  (12) When the bottle 1 sprayed with the condensed mist α of hydrogen peroxide in the sterilization unit 9 travels while being held by the gripper 28 around the intermediate wheel 58c, as shown in FIG. The heated air γ is blown from 64. Thereby, the inner surface and the outer surface of the bottle 1 are air-rinsed, and excess hydrogen peroxide adhering to the inner and outer surfaces of the bottle 1 is removed.

  It is desirable that the bottle 1 sprayed with the condensed mist α of hydrogen peroxide from the spray tube 59 in the sterilization unit 9 reaches the air rinse unit 96 within 0.5 to 5 seconds. If it is less than 0.5 seconds, the time required for sterilization is too short and the sterilization effect is insufficient, and if it is longer than 5 seconds, hydrogen peroxide penetrates into the inner wall of the PET wall of the bottle 1 and the residual value of hydrogen peroxide. Therefore, it becomes necessary to provide a sterile water rinsing unit 91 according to the second embodiment to be described later.

  Here, the test results showing the grounds are shown below.

The present inventors measured the sterilization effect and residual hydrogen peroxide concentration on B. subtilis spores using a PET bottle with a capacity of 500 ml. The results are shown in Table 1 below.

The evaluation method is as follows.
Sterilization effect (Log Reduction) = Log (number of adherent bacteria / number of surviving bacteria)
Indicator fungus: B. subtilis var.niger ATCC9372
Residual hydrogen peroxide concentration measurement: Measured by the oxygen electrode method Sterilization process: The bottle was released from the blow mold, and a condensed mist of hydrogen peroxide was sprayed on the bottle and air rinsed. The supply of hydrogen peroxide was 30 μL. Hydrogen peroxide condensation mist was sprayed within 30 seconds after releasing the bottle. This is because the higher the temperature of the bottle after mold release, the higher the sterilization effect by hydrogen peroxide, and when the heat escapes from the bottle and cools, the hydrogen peroxide condenses on the PET wall surface of the bottle and is easily adsorbed on the PET inner layer. It is.

  As is apparent from Table 1, when the air rinse is started 2 seconds after spraying hydrogen peroxide, the residual hydrogen peroxide becomes less than 0.5 ppm, and the sterilization effect becomes 6 Log or more.

  (13) As shown in FIG. 15, a positive pressure means is provided on the traveling path of the bottle 1 from the molding unit 7 through the inspection unit 8 to the sterilization unit 9 to provide a chamber for the sterilization unit 9. The surplus of the hydrogen peroxide mist α flowing into the chamber 9a is discharged from the ducts 86 and 89 to the outside of the chamber 9a, and the purified air flowing into the chamber 8a of the inspection section 8 is discharged into the chamber 7a of the molding section 7. And the atmosphere blocking chamber 79 to prevent the contaminated air and the air containing hydrogen peroxide from flowing into the chamber 8a of the inspection unit 8.

  Even if air is drawn from the chamber 7 a of the molding unit 7 into the chamber 8 a of the inspection unit 8 as the bottle 1 travels, the air is exhausted from the atmosphere blocking chamber 79, and the chamber of the sterilization unit 9 Since the inflow into 9a is prevented, the contamination in the sterilization part 9 is prevented appropriately.

  (14) When the bottle 1 is being conveyed to the sterilization unit 9 and subsequent parts through the inspection unit 8, when some abnormality occurs on the molding unit 7 side and the wheel train on the molding unit 7 side stops urgently, 11, the piston rod 42 a of the piston / cylinder device 42 is contracted, and the pair of sandwiching pieces 37 a and 37 b that are in a closed state are expanded at an angle of about 180 degrees as shown in FIG. To do.

Thereby, interference between the bottle 1 gripped by the gripper 28 attached to the terminal wheel 19b on the molding part 7 side and the gripper 37 of the starting wheel 36a on the inspection part 8 side is prevented.

  In addition, since the starting wheel 36a and the row of wheels following this continue to rotate, the bottle 1 introduced into the inspection unit 8 continues to travel downstream. Therefore, the normally molded bottle 1 is inspected by the inspection unit 8, and the bottle 1 that has passed through the inspection unit 8 is directed to the sterilization unit 9, thereby preventing the bottle 1 from being wasted. Further, even if the molding unit 7 is stopped, it can be operated after the inspection unit 8, so that the bottle 1 continues to run continuously after the sterilization unit 9 and stops in the sterilization unit 9. In addition, sterilization failure due to cooling of the bottle 1 is prevented, and only the appropriate bottle 1 is filled with a beverage.

  (15) The air-rinsed bottle 1 reaches the filling unit 10 and travels while being gripped by the gripper 28 around the wheel 94c, as shown in FIG. 6 (N), from the nozzle 95 of the beverage filling machine. A predetermined amount of beverage a is filled.

  (16) The bottle 1 filled with the beverage a travels while being gripped by the gripper 28 around the wheel 94e. At that time, as shown in FIG. 6 (O), the cap 1 is put on the neck 1a by the capper. It is done. Thereby, the bottle 1 is sealed and it is set as a drink packaging body.

  The bottle 1 which became a drink packaging body is sent out from this drink filling apparatus.

<Embodiment 2>
Next, a second embodiment of the beverage filling apparatus for filling the bottle 1 with the beverage a will be described.

  As shown in FIG. 16, the beverage filling apparatus includes a molding unit 7 for the bottle 1, an inspection unit 8 for inspecting the molded bottle 1, a sterilization unit 9 for the bottle 1, an air rinse unit 96 for the bottle 1, The bottle 1 includes a sterile water rinse section 91 and a filling section 10 that fills the bottle 1 with the beverage a and seals it.

  Since the part from the bottle forming part 7 to the sterilizing part 9 is the same as that in the first embodiment, the description thereof is omitted.

  As shown in FIG. 16, the air rinse part 96 of the bottle 1 is connected to the sterilization part 9 of the bottle 1. The air rinse part 96 is also entirely covered with a chamber 96a.

  In the chamber 96a of the air rinse part 96, as shown in FIG. 16, the wheel row | line | column connected with the terminal wheel 58b which is the running means of the bottle 1 by the side of the said sterilization part 9 is connected. Specifically, this wheel train is composed of three wheels 58c, 58d, and 58e, and the traveling path of the bottle 1 is set on the outer periphery thereof. A gripper 28 similar to the gripper 28 shown in FIG. 7 is provided around each wheel 58c, 58d, 58e.

  The gripper 28 sequentially transfers the bottle 1 from the start end wheel 58c to the end wheel 58e while gripping and turning around the neck 1a of the bottle 1 around each wheel 58c, 58d, 58e. As a result, the inspected non-defective bottle 1 continuously travels on the travel path from the terminal wheel 36b in the sterilizing unit 9 to the terminal wheel 58e in the air rinse unit 96. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in an upright suspended state.

  Around the start wheel 58c, air rinsing means for cleaning the bottle 1 by supplying the bottle 1 with hydrogen peroxide gas β heated air γ, which is a sterilizing agent, is provided.

  As shown in FIGS. 17 (M1) and 20, the air rinsing means includes a nozzle 64 that discharges heated air γ mixed with hydrogen peroxide gas β.

  As shown in FIG. 20, a wheel 58 c that rotates with power from a predetermined drive source is horizontally attached to a turning shaft 66 that stands on a machine base 65. A column 66a extends upward from the surface of the wheel 58c, and a manifold 67 into which the heated air γ mixed with the hydrogen peroxide gas β flows is fixed to the upper end of the column 66a. From the upper center of the manifold 67, a conduit 68 extends upward on an extension line of the axis of the pivot shaft 66, and this conduit 68 is held by a frame member of the chamber 9 a connected to the machine base 65 via a bearing 69. Thereby, the manifold 67 can rotate around the turning shaft 66 integrally with the wheel 58c.

  Further, another support column 70 extends upward from the surface of the wheel 58 c, and the gripper 28 of the bottle 1 is attached to the upper portion of the support column 70. A number of supports 70 and grippers 28 are arranged around the wheel 58c at a predetermined pitch. Since many grippers 28 are connected to the wheel 58c via the support column 70, the gripper 28 rotates with the rotation of the wheel 58c.

  These grippers 28 have the same structure as that shown in FIG. Further, for example, when the mist generating device 61 of the sterilizing unit 9 is defective and the bottle 1 with poor sterilization is generated, as an excluding means for removing the bottle 1 from the traveling path, the one shown in FIGS. 11 and 12 A similar mechanism is provided. In FIG. 2, what is indicated by reference numeral 71 is a shooter for dropping the sterilized defective bottle 1 that should be excluded from the running path of the bottle 1 by this exclusion means.

  A supply pipe 72 of heated air γ mixed with hydrogen peroxide gas β extends from the periphery of the manifold 67 toward each gripper 28, and the nozzle 64 is attached to the tip of each supply pipe 72. The nozzle 64 is fixed to the column 70, and the nozzle hole at the tip of the nozzle 64 faces the opening of the neck 1 a of the bottle 1 held by the gripper 28. Accordingly, when the wheel 58c rotates, the nozzle 64 turns around the turning shaft 66 together with the bottle 1 held by the gripper 28, and the heated air γ mixed with the hydrogen peroxide gas β is blown into the bottle 1.

  A pipe 74 a is connected to the upper end of the conduit 68 of the manifold 67 through a seal member 75. The conduit 68 is rotated integrally with the manifold 67 with respect to the pipe 74a, and the seal member 75 prevents the leakage of the gas β from the connecting portion of both the pipes 68 and 74a. A plurality of mist generating devices 61 shown in FIG. 13 are attached to the piping 74a, and condensed mist α of hydrogen peroxide is supplied from each mist generating device 61 into the piping 74a. The number of operating mist generating devices 61 is determined according to the amount of gas β required for sterilization of the bottle 1.

  A hot air supply device including a blower 76, a ULPA (Ultra Low Penetration Air Filter) filter 77, and an electric heater 78 is provided on the upstream side of the pipe 74 a. The air drawn from the blower 76 is purified by the ULPA filter 77, heated to a predetermined temperature by the electric heater 78, and sent as hot air γ into the heating tube 74a. The heated air γ is aseptic air heated to a temperature equal to or higher than the dew point of hydrogen peroxide, for example, 100 ° C. or higher. The heated air γ gasifies the condensed mist α of hydrogen peroxide sent from the mist generating device 61 and conveys it to the manifold 67. The heated air γ mixed with the hydrogen peroxide gas β blows out from the nozzle 64 into the bottle 1 through each supply pipe 72 or flows out of the bottle 1.

  The pipe line extending from the pipe 74a to the nozzle 64 through the manifold 67 is formed as short as possible. Therefore, the hydrogen peroxide gas β reaches the bottle 1 on the hot air γ without condensation.

  When heated air γ mixed with hydrogen peroxide gas β is blown into the bottle 1 from the nozzle 64, the hydrogen peroxide gas β uniformly contacts the entire inner surface of the bottle 1, and promptly touches the inner surface of the bottle 1. Sterilize.

  The concentration of the hydrogen peroxide gas β mixed in the heated air γ is desirably 1 mg / L (L is the volume of the hydrogen peroxide gas in the gas mixture) to 10 mg / L, more desirably 2 mg / L to 8 mg / L.

  In this manner, the bottle 1 is heated from the inner surface by supplying the sterilized heated air γ and hydrogen peroxide gas β into the bottle 1, so that the condensed mist α of hydrogen peroxide and the gas β are heated. The bactericidal effect by increases. In addition, the hydrogen peroxide gas β contained in the heated air γ more reliably sterilizes, for example, the bottom portion in the bottle 1, which was insufficiently sterilized by the hydrogen peroxide condensation mist α.

  In addition, the blowing time of the heated air γ containing hydrogen peroxide gas β can discharge all the hydrogen peroxide condensation mist α drifting inside the bottle 1, and the sterilization failure due to the hydrogen peroxide condensation mist α. As long as it can be compensated for, When the temperature of the heated air γ containing the hydrogen peroxide gas β is equal to or higher than the heat resistance temperature of the bottle 1, if the blowing time is too long, the bottle 1 may be heated above the heat resistance temperature and may be deformed. So be careful. The blowing time of the heated air γ containing the hydrogen peroxide gas β is set to 2 to 5 seconds, for example.

  If necessary, the sterilized air at room temperature may be mixed with the condensed mist of low-concentration hydrogen peroxide to gasify the hydrogen peroxide, and the nozzle 64 may be used to prevent condensation. You may make it supply.

  In this manner, aseptic heating air γ containing hydrogen peroxide gas β is supplied into the bottle 1 and an air rinsing process is performed, the bottle 1 is heated from its inner surface, and the condensed mist α and excess of hydrogen peroxide are heated. The bactericidal effect by hydrogen oxide gas β is enhanced. Further, due to the hydrogen peroxide gas β contained in the heated air γ, the sterilization by the condensed mist α of hydrogen peroxide supplied from the spray tube 59 is insufficient. Sterilized.

  In the illustrated example, the nozzle 64 is blown out of the bottle 1 with heated air γ containing hydrogen peroxide gas β into the bottle 1, but each nozzle 64 is provided so as to be movable up and down. When the heated air γ containing the hydrogen oxide gas β is blown into the bottle 1, it is possible to enter the bottle 1. In addition, for the purpose of removing foreign substances, a nozzle may be inserted from the state in which the bottle 1 is inverted, and air rinsing may be performed.

  The gripper 28 at least from the start end wheel 36a in the inspection unit 8 to the end wheel 58b in the sterilization unit 9 described above has the heat remaining in the bottle 1 when the bottle is formed in the molding unit 7 at the sterilization unit 9. The traveling speed is controlled so as to be maintained to the extent necessary for sterilization of the bottle 1.

  That is, as shown in FIG. 16, the inspection unit 8 is provided with a servo motor S1 that drives all the wheels 36a, 36b, 36c in the inspection unit 7 so as to be mechanically interlocked, and the sterilization unit 9 and the air rinse unit 96 are provided. In addition, a servo motor S2 for driving all the wheels 58a, 58b, 58c, 58d, and 58e in the sterilizing unit 9 and the air rinsing unit 96 so as to be dynamically interlocked is provided. The traveling speed of the gripper 28 is adjusted by the control of the servo motors S1 and S2, and as a result, the gripper is kept in a state in which the heat remaining in the bottle 1 at the time of bottle molding is maintained to the extent necessary for sterilization in the sterilization unit 9. The bottle 1 held by 28 arrives directly under the spray pipe 59. Further, the bottle 1 sprayed with the condensed mist α of hydrogen peroxide from the spray tube 59 in the sterilization unit 9 quickly reaches the air rinse unit 96.

  The temperature of the bottle 1 immediately below the spray pipe 59 is desirably maintained at 50 ° C. or higher. By being maintained at 50 ° C. or higher, the bactericidal effect due to the condensed mist α of hydrogen peroxide is appropriately exhibited. In particular, the neck 1a of the bottle 1, the thick portion of the meat such as the bottom, and the portion where the condensate mist α is difficult to reach such as the bottom are difficult to sterilize. Since the portion is in a high temperature state, a high bactericidal effect can be obtained even with a small amount of condensed mist α.

  Also in this beverage filling device, a positive pressure means for making the inside of the inspection part 8 more positive than the inside of the molding part 7 and the inside of the sterilization part 9 is provided in the same manner as in the first embodiment. Since the configuration of the positive pressure means is the same as that in the first embodiment, its detailed description is omitted.

  As shown in FIG. 16, a sterile water rinse part 91 is connected to the air rinse part 96. The entire sterile water rinse part 91 is also covered with a chamber 91a. A partition wall (not shown) is provided between the sterilization unit 9 and the chamber 9a, and a passage port for the bottle 1 is provided in the partition wall.

  As shown in FIG. 16, a wheel train connected to a terminal wheel 58e, which is a traveling means of the bottle 1 on the sterilizing unit 9 side, is connected in the chamber 91a of the sterile water rinsing unit 91. Specifically, this wheel train is composed of three wheels 92a, 92b, and 92c, and the travel path of the bottle 1 is set on the outer periphery thereof.

  A gripper 28 similar to the gripper 28 shown in FIG. 7 is provided around the start wheel 92a and the end wheel 92c.

  A large number of grippers 20 as shown in FIGS. 18A and 18B are provided around the large-diameter intermediate wheel 92b at a constant pitch.

  The gripper 20 has a pair of sandwiching pieces 20a and 20b that sandwich the neck 1a of the bottle 1 from the outside. The pair of sandwiching pieces 20 a and 20 b are supported by the base 21 so as to be rotatable by vertical pins 22, respectively, and are always pulled in a closing direction by a tension spring 23. Thereby, as shown in FIG. 18B, the pair of sandwiching pieces 20a and 20b always tries to grip the neck 1a of the bottle 1. A cylindrical vertical shaft 24 is attached to the base portion 21 so as to be slidable in the radial direction of the starting wheel 19a while being fitted to the bases of both sandwiching pieces 20a and 20b, and is connected to the vertical shaft 24. Similarly, the cam follower 25 is attached to be slidable in the radial direction of the start wheel 19a.

  On the inner side of the intermediate wheel 92b, it engages with the groove of the cam follower 25, and the cam follower 25 and the vertical shaft 24 are slid in the radial direction of the starting wheel 19a at a predetermined position to open the gripping pieces 20a and 20b of the gripper 20 Alternatively, a cam (not shown) for switching to the closed state is arranged. When the intermediate wheel 92b rotates and the gripper 20 faces the bottle 1 held by the gripper 28 of the wheel 92a, the gripping pieces 20a and 20b of the gripper 20 grip the neck 1a of the bottle 1 below the support ring 5. Then, the bottle 1 is transported in a suspended state.

  Further, as shown in FIGS. 18A and 18B, the gripper 20 is provided with a horizontal pivot 26 that protrudes in the circumferential direction of the start wheel 19a, and is supported by the start wheel 19a via the horizontal pivot 26. The On the other hand, as shown in FIG. 19, there is provided a cam 27 that is curved in an arc shape around the turning axis of the starting wheel 19a. Each gripper 20 comes into contact with the cam 27. When the gripper 20 receives the bottle 1 by turning of the intermediate wheel 92b and turns, the gripper 20 is turned upside down by the guide of the cam 27 with the horizontal pivot 26 as a fulcrum. As a result, as shown in FIGS. 17 (M1) and 17 (M2), the bottle 1 is also turned upside down and its neck 1a is turned upside down.

  The bottle 1 that has passed through the air rinse part 96 as shown in FIG. 17 (M1) travels while being gripped by the gripper 28 in an upright state around the start wheel 92a in the sterile water rinse part 91, as shown in FIG. As shown in M2), the vehicle travels in an inverted state by the gripper 20 of the intermediate wheel 92b. At that time, the hot water nozzle 93 is inserted from the neck portion 1 a, and hot water w of sterile water is injected into the bottle 1. The warm water w cleans the inside of the bottle 1 and flows out of the bottle 1 from the neck 1a. After washing with the warm water w, the bottle 1 is returned to the upright state by the gripper 20 of the intermediate wheel 92b, received by the gripper 28 of the end wheel 92c, and conveyed to the next filling unit 10.

  The warm water w is sterile water, and the temperature is about 60 ° C. to 70 ° C., but it may be normal temperature.

  As shown in FIG. 16, the filling part 10 is connected to the sterile water rinse part 91.

  The filling portion 10 is also entirely covered with a chamber 10a. A partition wall (not shown) is provided between the sterilized water rinse section 91 and the chamber 91a, and a passage port for the bottle 1 is provided in the partition wall.

  As shown in FIG. 16, a wheel train connected to a terminal wheel 92 c that is a traveling means of the bottle 1 on the aseptic water rinsing unit 91 side is connected in the chamber 10 a of the filling unit 10.

  Specifically, this wheel train is composed of six wheels 94a, 94b, 94c, 94d, 94e, 94f, and the traveling path of the bottle 1 is set on the outer periphery thereof. A gripper 28 similar to the gripper 28 shown in FIG. 7 is provided around each wheel 94a, 94b, 94c, 94d, 94e, 94f.

  In the chamber 10a of the filling unit 10, the gripper 28 holds the neck 1a of the bottle 1 around the wheels 94a, 94b, 94c, 94d, 94e, and 94f, and turns the bottle 1 from the starting wheel 94a to the terminal wheel. It passes to 94f in order. Thereby, the bottle 1 continuously travels in the filling portion 10 from the start end wheel 94a to the end end wheel 94f. Since the gripper 28 grips the neck 1a of the bottle 1 with its pinching pieces 28a and 28b during traveling, the bottle 1 travels in an upright suspended state.

  In the chamber 10a of the filling unit 10, the predetermined intermediate wheel 94c is a large-diameter wheel, and a beverage filling machine is installed at a predetermined position around the wheel 94c. As shown in FIG. 6 (N), the beverage a previously sterilized is filled into the bottle 1 by the nozzle 95 of this beverage filling machine. The nozzle 95 travels synchronously with the bottle 1 and fills the bottle 1 with a certain amount of beverage a while traveling along the bottle 1.

  Further, a capper is installed at a predetermined position around the intermediate wheel 94e downstream of the beverage filling machine. As shown in FIG. 6 (O), the cap 2 is attached to the neck 1a of the bottle 1 by this capper. Thereby, the bottle 1 is sealed.

  The bottle 1 filled with the beverage a and sealed with the cap 2 is released from the gripper 28 of the end wheel 94f and discharged from the outlet of the chamber 10a to the outside of the beverage filling device.

  In addition, as shown in FIG. 16, the sterile water rinsing section 91 is provided with a servo motor S3 that drives the wheels 92a, 92b, and 92c in the interior so as to be mechanically linked. Further, the filling unit 10 is provided with three servo motors S4, S5, and S6 that drive the wheels 94a, 94b, 94c, 94d, 94e, and 94f in the filling unit 10 so as to be mechanically linked in a predetermined combination. Of these, the first servo motor S4 drives the wheels 94a, 94b upstream of the intermediate wheel 94b where the beverage filling machine is placed, and the second servo motor S5 is the intermediate where the beverage filling machine is placed. The wheel 94c is driven, and the third servo motor S6 drives the wheels 94d, 94e, 94f on the downstream side of the intermediate wheel 94c on which the beverage filling machine is placed.

  As a result, even if the structures of the wheel and gripper in the inspection unit 8, the sterilization unit 9, the air rinse unit 96, the sterile water rinse unit 91, and the filling unit 10 are different from each other, the servo motors S1 to S6 The gripper can be driven synchronously by the control, and the bottle 1 can be smoothly and continuously traveled from the molding unit 7 to the filling unit 10.

  In the second embodiment, the molding unit 7 is driven by a normal electric motor (not shown), but the wheel and turntable of the molding unit 7 can also be driven by a servo motor.

  Next, the operation of the beverage filling apparatus will be described.

  (1) First, a preform 6 as shown in FIG. 3A is prepared. The preform 6 is molded by injection molding (not shown) and then put into the preform feeder 11 of this beverage filling apparatus.

  The preform 6 is supplied into the molding unit 7 by the conveyor 12 of the preform supplier 11.

  (2) The preform 6 that has been conveyed by the conveyor 12 in a state as shown in FIG. 3A is received by the gripper of the starting wheel 13a that rotates continuously in the molding section 7, and is inverted by the gripper of the intermediate wheel 13b. State.

  The inverted preform 1 is placed on the mandrel 17 of the first turntable 14a from its neck 1a as shown in FIG. 3B.

  As shown in FIG. 3C, the mandrel 17 covered with the preform 6 travels in the heating chamber 16 while rotating, and the preform 6 continuously travels in the heating chamber 16 while rotating together with the mandrel 17. . Thereby, the preform 6 is heated uniformly and rises to a temperature at which blow molding is possible.

  (3) The heated preform 6 is sandwiched between blow molding dies 18 and air is blown from a blow nozzle 19 penetrating the mandrel 17 as shown in FIG. As a result, the bottle 1 is molded in the mold 18.

  The molded bottle 1 is taken out from the mold 18 together with the mandrel 17 by opening the mold 18, and as shown in FIG. 4 (E), the first bottle 1F passes through the sixth turntable 14f in an inverted state. Head to the turntable with 14a.

  (4) As shown in FIG. 4 (F), the bottle 1 held on the mandrel 17 in the first turntable 14a is gripped by the gripping tool 98 of the starting wheel 19a and brought into an upright state. At this time, the gripping tool 98 grips the upper side of the support ring 5 of the neck 1 a of the bottle 1. Subsequently, the bottle 1 is received by the gripper 28 as shown in FIG. 7 of the end wheel 19b. At this time, as shown in FIG. 9, the gripper 28 grips the lower side of the support ring 5 of the neck 1 a of the bottle 1.

  (5) The gripper 37 of the start end wheel 36a of the inspection unit 8 grips and receives the upper side of the support ring 5 of the neck 1a of the bottle 1 from the end wheel 19b of the forming unit 7. The bottle 1 rotates while being held by the gripper 37.

  During this turning movement, as shown in FIG. 4 (G), the body of the bottle 1 is inspected by the bottle body inspection means. In this inspection, an image of the body portion of the bottle 1 taken by the camera 45 is processed by an image processing device (not shown), and it is determined whether there is an abnormality such as a scratch, a foreign object, or a color change.

  (6) The bottle 1 is transferred from the gripper 37 of the start wheel 36a to the gripper 28 of the intermediate wheel 36b, and the gripper 28 of the intermediate wheel 36b supports the neck 1a as shown in FIGS. The lower side of the ring 5 is gripped to perform a turning motion.

  During this turning motion, as shown in FIG. 4 (H), the temperature of the bottle 1 is detected by the temperature sensor 46 of the temperature inspection means. When the temperature detected by the temperature sensor 46 does not reach, for example, 50 ° C., the bottle 1 is determined to be defective.

  (7) Subsequently, as shown in FIG. 5I, the surface condition of the support ring 5 of the bottle 1 is inspected by the support ring inspection means. In this inspection, an image on the upper surface of the support ring 5 photographed by the camera 48 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation.

  (8) Following the inspection of the support ring 5, as shown in FIG. 5 (J), the surface state of the top surface 1b of the bottle neck 1a is inspected by the bottle neck top surface inspection means. In this inspection, the image of the top surface 1b of the bottle neck 1a taken by the camera 50 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch or deformation.

  (9) Following the inspection of the top surface 1b of the bottle neck 1a, as shown in FIG. 5 (K), the bottom of the bottle 1 is inspected by the bottle bottom inspection means. In this inspection, an image of the bottom of the bottle taken by the camera 52 is processed by an image processing device (not shown) to determine whether there is an abnormality such as a scratch, a foreign object, or a color change.

(10) The bottle 1 that has undergone the above various inspections is held by the gripper 28 shown in FIG. 11 of the terminal wheel 36 c of the inspection unit 8. When an abnormal signal is generated by any of the various inspection means, as shown in FIG. 12, the gripper opening mechanism is actuated, and the pair of sandwiching pieces 28a, 28b of the gripper 28 is indicated by a solid line from a closed state indicated by a two-dot chain line. The state changes to the open state, and the defective bottle 1 is released.

  As a result, the defective bottle 1 with scratches on the body, bottom, neck top surface 1b, and support ring 5 of the bottle 1 is removed from the traveling path, and is sterilized with hydrogen peroxide in a later sterilization step. However, the bottle 1 having a temperature at which a sufficient sterilizing effect cannot be obtained is also excluded from the travel path.

  On the other hand, for the non-defective bottle 1, since the movable cam portion 53a is held at the position shown in FIG.

  (11) The non-defective bottle 1 is transferred continuously from the gripper 28 of the end wheel 36c of the inspection unit 8 to the gripper 28 of the start end wheel 58a of the sterilization unit 9, and thereafter continuously transferred to the gripper 28 of the downstream wheel. To do.

  When the non-defective bottle 1 travels while being held by the gripper 28 around the intermediate wheel 58b, it passes directly under the spray tube 59 as shown in FIG. 6 (L). Thereby, the condensed mist α of hydrogen peroxide discharged from the spray pipe 59 is sprayed toward the bottle 1, and the inner surface and the outer surface of the bottle 1 are sterilized. As described above, since only the non-defective bottles 1 with moderate heat remaining arrive, these bottles 1 travel downstream after being properly sterilized by the condensed mist α of hydrogen peroxide.

  (12) When the bottle 1 sterilized by the hydrogen peroxide condensation mist α travels around the intermediate wheel 58c while being held by the gripper 28, as shown in FIG. The gas β and hot air γ are blown. Thereby, the inner surface and the outer surface of the bottle 1 are air rinsed, and the hydrogen peroxide adhering to the inner and outer surfaces of the bottle 1 is removed.

  (13) As shown in FIG. 15, a positive pressure means is provided on the traveling path of the bottle 1 from the molding unit 7 through the inspection unit 8 to the sterilization unit 9 to provide a chamber for the sterilization unit 9. The surplus of hydrogen peroxide mist α and gas β flowing into 9a is discharged out of the chamber 9a through ducts 86 and 89, and the purified air flowing into the chamber 8a of the inspection section 8 is formed into the molding section 7. The air flows toward the chamber 7a and the atmosphere blocking chamber 79, and the inflow of contaminated air or hydrogen containing hydrogen peroxide into the chamber 8a of the inspection unit 8 is blocked.

  Even if air is drawn from the chamber 7 a of the molding unit 7 into the chamber 8 a of the inspection unit 8 as the bottle 1 travels, the air is exhausted from the atmosphere blocking chamber 79, and the chamber of the sterilization unit 9 Since the inflow into 9a is prevented, the contamination in the sterilization part 9 is prevented appropriately.

  (14) When the bottle 1 is being conveyed to the sterilization unit 9 and subsequent parts through the inspection unit 8, when some abnormality occurs on the molding unit 7 side and the wheel train on the molding unit 7 side stops urgently, 11, the piston rod 42 a of the piston / cylinder device 42 is contracted, and the pair of sandwiching pieces 37 a and 37 b that are in a closed state are expanded at an angle of about 180 degrees as shown in FIG. To do.

Thereby, interference between the bottle 1 gripped by the gripper 28 attached to the terminal wheel 19b on the molding part 7 side and the gripper 37 of the starting wheel 36a on the inspection part 8 side is prevented.

  In addition, since the starting wheel 36a and the row of wheels following this continue to rotate, the bottle 1 introduced into the inspection unit 8 continues to travel downstream. Therefore, the normally molded bottle 1 is inspected by the inspection unit 8, and the bottle 1 that has passed through the inspection unit 8 is directed to the sterilization unit 9, thereby preventing the bottle 1 from being wasted. Further, even if the molding unit 7 is stopped, it can be operated after the inspection unit 8, so that the bottle 1 continues to run continuously after the sterilization unit 9 and stops in the sterilization unit 9. In addition, sterilization failure due to cooling of the bottle 1 is prevented, and only the appropriate bottle 1 is filled with a beverage.

  (15) The bottle 1 sprayed with the hydrogen peroxide condensation mist α in the sterilization unit 9 enters the air rinse unit 96 and is air rinsed around the wheel 58c as shown in FIG. 17 (M1). The excess of hydrogen peroxide adhering to the bottle 1 is removed from the bottle by air rinsing.

  (16) The air-rinsed bottle 1 is fed from the gripper 28 of the terminal wheel 58e of the air rinse part 96 into the sterile water rinse part 91, and upstream around the wheels 92a, 92b, 92c in the sterile water rinse part 91 Travel downstream from the road. The bottle 1 is turned upside down by the gripper 20 of the intermediate wheel 92b, and the inside is washed with aseptic hot water w as shown in FIG. 17 (M2). Thereby, excess hydrogen peroxide or the like is removed from the bottle 1.

  If the hydrogen rinse gas β is not included in the air rinse air, this sterile water rinse can be omitted, but a sterile water rinse may be performed if necessary.

  The bottle 1 after being washed is returned to the upright state with the neck 1a facing upward by the reversing operation of the gripper 20.

  (17) When the bottle 1 rinsed with sterile water reaches the filling unit 10 and travels while being gripped by the gripper 28 around the wheel 94c, as shown in FIG. A predetermined amount of beverage a is filled from 95.

  (18) The bottle 1 filled with the beverage a travels while being gripped by the gripper 28 around the wheel 94e, and the cap 1 covers the neck 1a with the cap as shown in FIG. 6 (O). It is done. Thereby, the bottle 1 is sealed and it is set as a drink packaging body.

  The bottle 1 which became a drink packaging body is sent out from this drink filling apparatus.

  The present invention can be implemented in various forms without being limited to the above-described embodiments.

  For example, the container to which the beverage filling device of the present invention is applied is not limited to a PET bottle, and can be applied to various resin containers. In addition, beverages can be filled not only with liquids, but also with beverages containing granular materials, lumps, etc., and with high viscosity. The molding of the bottle is not limited to injection blow, and can be molded by various molding methods such as direct blow and injection molding.

It is a front view of the bottle which is a drink package manufactured by the drink filling device concerning the present invention. 1 is a schematic plan view of a beverage filling device according to the present invention. The process performed with the drink filling apparatus which concerns on this invention is shown, (A) is supply to the drink filling apparatus of a preform, (B) is supply to the shaping | molding part of a preform, (C) is heating of a preform, (D) shows blow molding, respectively. The process performed with the drink filling apparatus which concerns on this invention is shown, (E) is discharge | emission of the bottle from a shaping | molding die, (F) is the grip of the neck part of a bottle with a gripper, (G) is a test | inspection of a bottle trunk | drum, (H ) Indicates the bottle temperature test. The process performed with the drink filling apparatus which concerns on this invention is shown, (I) shows the test | inspection of the support ring of a bottle, (J) shows the test | inspection of the neck top surface of a bottle, (K) shows the test | inspection of a bottle bottom part, respectively. The process performed with the drink filling apparatus which concerns on this invention is shown, (L) is sterilization by the condensation mist of the hydrogen peroxide of a bottle, (M) is an air rinse of a bottle, (N) is a drink filling, (O) is a capping. The sealing by is shown respectively. It is a schematic plan view which shows the gripper which conveys a bottle with a wheel. In FIG. 2, it is the elements on larger scale of the test | inspection part. In FIG. 8, it is a IX-IX line arrow directional view. It is a schematic plan view which shows the gripper provided with the interference prevention means with a wheel. It is a schematic top view which shows the gripper provided with the defective bottle exclusion means with a wheel. (A) and (B) show the non-operating state and the operating state of the defective bottle removing means, respectively. It is a partial notch front view of a mist production | generation apparatus. It is a partial notch front view of an air rinse apparatus. It is explanatory drawing which shows a positive pressure means, and is a XV-XV arrow directional view in FIG. It is a schematic plan view of the drink filling apparatus which concerns on other embodiment of this invention. FIG. 16 shows a part of the process performed in the beverage filling apparatus shown in FIG. 16, where (M1) is a bottle air rinse performed after sterilization of the bottle by hydrogen peroxide condensation mist, and (M2) is a bottle sterile water rinse. Show. The gripper which can flip a bottle up and down is shown, (A) shows the state which a pair of clip piece opened, and (B) shows the closed state, respectively. It is a partial notch top view which shows the cam apparatus for turning the gripper shown in FIG. 18 upside down. It is a partial notch front view of the air rinse apparatus in the drink filling apparatus shown in FIG.

DESCRIPTION OF SYMBOLS 1 ... Bottle 1a ... Bottle neck 1b ... Top 5 ... Support ring 6 ... Preform 7 ... Molding part 8 ... Inspection part 9 ... Sterilization part 9a ... Chamber 10 ... Filling part 14a ... Turntable 19a, 19b, 36a ... Wheel 28, 37 ... gripper 42 ... piston / cylinder device 45, 48, 50, 52, ... camera 46 ... temperature sensor 53a ... movable cam part 84 ... blower a ... beverage w ... warm water α ... hydrogen peroxide condensation mist β ... excessive Hydrogen oxide gas γ… Hot air S1… Servo motor

Claims (7)

For bottles that form a bottle from a heated preform by blow molding, inspect the temperature of the portion that tends to generate a cold spot for the bottle that retains the residual heat of the heat applied to the preform, and that reaches a predetermined temperature Only when the heat applied to the preform remains, the bottle is sprayed with hydrogen peroxide mist or gas, air-rinsed with sterile air, and then the bottle is filled with beverage and sealed. A beverage filling method.   2. The beverage filling method according to claim 1, wherein after rinsing the bottle with air containing hydrogen peroxide gas, aseptic water rinsing is performed, and then the beverage is filled in the bottle and sealed. . The beverage filling method according to claim 1 or 2 , wherein a running path is provided for continuously running the molded bottle until the bottle is sealed, and the running path is formed by a row of wheels each provided with a gripper. A beverage filling method characterized in that the gripper swivels around each wheel while gripping the neck of the bottle and delivers the bottle from the upstream wheel to the downstream wheel. A molded part for forming a bottle from a heated preform by blow molding, a sterilizing part for sterilizing a bottle molded in the molding part with hydrogen peroxide mist or gas, and a bottle sterilized in the sterilizing part with aseptic air An air rinsing part for air rinsing and a filling part for filling and sealing a bottle air-rinsed in the air rinsing part are connected, and the bottle is continuously connected to the filling part through the sterilizing part and the air rinsing part on the traveling path In a beverage filling apparatus provided with traveling means for traveling, and at least a portion from the sterilizing unit to the filling unit covered with a chamber, the beverage is molded by the molding unit and retains the residual heat of the heat applied to the preform. inspection unit to perform temperature tests prone parts cold spots on bottles, are connected to these between the molded section and the sterilization section It is provided so as, in the inspection unit, the removing means to eliminate bottle temperature of the portion susceptible to the cold spot is not reached the predetermined temperature from the traveling road is provided by the temperature test The traveling means includes a wheel arranged in a row from the molding unit to the filling unit, and a swivel gripping the neck of the bottle around each wheel and turning the bottle from the upstream wheel to the downstream wheel. The gripper is controlled so that the heat applied to the preform and the heat remaining in the bottle is maintained to a level necessary for sterilization of the bottle in the sterilization unit. Beverage filling device characterized by the above.   5. The beverage filling apparatus according to claim 4, wherein air containing hydrogen peroxide gas is blown onto the bottle at the air rinse section.   5. The beverage filling apparatus according to claim 4, wherein the wheel is divided into a desired number of rows and is driven by a separate servo motor for each row.   5. The beverage filling apparatus according to claim 4, wherein the gripper traveling in the inspection section is subjected to a matte surface treatment.

Images