JP5563786B2 - Beverage container vibration measuring apparatus and beverage container vibration measuring method - Google Patents

Description

  The present invention relates to a method and a vibration measuring apparatus for measuring vibration applied when a beverage container is transported in a production line or the like for performing a washing process or a beverage filling process on the beverage container.

  2. Description of the Related Art Conventionally, in a production line that performs washing processing, beverage filling processing, and the like on such a beverage container, for example, a transportation line (conveyor line) configured by connecting a plurality of transportation conveyors is used. The beverage container is transported. In a production line, a plurality of beverage containers supplied and arranged on a conveyance line are continuously conveyed, and a beverage container is passed through a washing process and a beverage filling process for the inner and outer surfaces of the beverage container. Shipped as a product.

  In such a beverage production line, it is necessary to grasp the state of the beverage container continuously conveyed by the conveyance line from the viewpoint of quality control. Therefore, for example, in a beer production line, it is proposed that a bar code or an ID tag is pasted on an individual beer keg container, which is an example of a beverage container, and the transport route of the beer keg container is managed. (For example, refer to Patent Document 1).

JP 2001-31178 A

  In such a beer barrel container transfer line, conveyor wear occurs over time in the transfer conveyor, and in particular, a step or a speed difference occurs at a connecting portion (crossover portion) between the conveyors. In such a case, when the beer barrel container passes through the connecting portion, vibration and impact are applied to the beer barrel container, and depending on the degree, leakage of the contents product (barrel leakage) from the beer barrel container. ) And beer barrel containers may fall over (barrel collapse). Even if such barrel leakage or barrel collapse does not occur, the beer barrel container itself may be damaged (dented, scratched, etc.).

  Such problems of barrel leakage and barrel collapse are difficult to solve simply by managing the transport path using a barcode or ID tag attached to the beer barrel container. Therefore, conventionally, when such a problem occurs, the operator estimates the location that causes the conveyor step or the like in the transport line, and after manually measuring and examining each location, the problem location is identified and resolved. The method to take is taken. In such a method, labor and time are required for investigation and resolution, and there is also a problem that the experience of a skilled operator is required to identify the problem location.

  Accordingly, an object of the present invention is to solve the above-mentioned problems, and is added to a beverage container transported on a transport line configured by connecting a plurality of transport conveyors at the time of transport. An object of the present invention is to provide a beverage container type vibration measuring apparatus and a beverage container vibration measuring method capable of easily measuring a vibration level to be measured and identifying a problem portion in a transport line.

  In order to achieve the above object, the present invention is configured as follows.

  According to the first aspect of the present invention, a container main body having an outer shell having substantially the same shape as a plurality of beverage containers to be conveyed on a conveyance line constituted by connecting a plurality of conveyors for conveyance; A sensor for detecting vibration that is fixed inside the container body and detects vibration applied to the container body during transportation, and vibration data that is fixed inside the container body and measured by the sensor for detecting vibration is associated with time. A container-type vibration measuring apparatus for beverages, comprising: a data storage unit for storing data; and a power supply that is fixed to the inside of the container body and supplies electric power for causing the vibration detection sensor and the data storage unit to function. I will provide a.

  According to the second aspect of the present invention, in the first aspect, the beverage container is a beer barrel container, and the vibration detection sensor, the data storage unit, and the power source are arranged in the sealed container body. A container-type vibration measuring apparatus for beverages is provided.

  According to the third aspect of the present invention, the vibration detection sensor is fixed substantially at the center of the bottom inner wall of the container main body, and the vibration detection sensor is added to the container main body via the bottom of the container main body during transport. The container-type vibration measuring apparatus for beverages according to the second aspect, which detects vertical vibrations, is provided.

  According to the fourth aspect of the present invention, the vibration detection sensor is fixed to the side wall of the container main body, and the vibration detection sensor detects the horizontal vibration applied to the container main body during the conveyance. A beverage container type vibration measuring apparatus according to the second aspect is provided.

  According to the fifth aspect of the present invention, the weight adjusting weight member is the container main body so that the weight of the beverage container-type vibration measuring device is the same as the weight of the beer barrel container filled with the specified amount of beer. The beverage container-type vibration measuring device according to any one of the second to fourth aspects, which is disposed inside, is provided.

  According to the sixth aspect of the present invention, from the second aspect, a wired or wireless communication device that transmits vibration data stored in the data storage unit to the outside of the container body is further provided in the container body. A beverage container-type vibration measuring apparatus according to any one of the fifth aspects is provided.

  According to the seventh aspect of the present invention, a container body having an outer shell substantially the same shape as a plurality of beverage containers conveyed on a conveyance line configured by connecting a plurality of conveyance conveyors; A beverage container-type vibration measuring device comprising a vibration detection sensor fixed inside the container body and a data storage unit for storing vibration data measured by the vibration detection sensor is conveyed on a conveyance line, The vibration measurement of the beverage container is characterized in that the vibration added to the container body is measured by the vibration detection sensor and the measured vibration data is stored in the data storage unit in association with the information on the transport position. Provide a method.

  According to the eighth aspect of the present invention, the beverage container is a beer barrel container, and the barrel-type vibration measuring device in which the vibration detection sensor and the data storage unit are arranged in the sealed container body is provided in the transport line. The method for measuring vibration of a beverage container according to the seventh aspect is provided.

  According to the ninth aspect of the present invention, in the barrel-type vibration measuring device, the vibration detection sensor is fixed to substantially the center of the bottom inner wall of the container body, and is transported to the container body via the bottom of the container body. The vibration measuring method for a beverage container according to an eighth aspect is provided, in which the vertical vibration to be added is measured.

  According to the tenth aspect of the present invention, in the barrel-shaped vibration measuring device, the vibration detection sensor is fixed to the side wall of the container body, and the barrel-shaped vibration measuring device is transported together with the plurality of beer barrel containers on the transport line, A vibration measurement method for a beverage container according to an eighth aspect, wherein the horizontal vibration applied to the container body during conveyance is detected.

  According to the eleventh aspect of the present invention, it is determined whether or not the vibration data stored in the data storage unit exceeds the allowable vibration value, and an alarm is output when the allowable vibration value is exceeded. To a vibration measuring method for a beverage container according to any one of the tenth aspect.

  According to the twelfth aspect of the present invention, the transport line is a line that carries in and out a plurality of beer keg containers for at least the cleaning process and the beer filling process for the beer keg containers, and the plurality of beer keg containers In addition, the vibration measurement of the beverage container according to any one of the eighth to eleventh aspects is performed by continuously measuring vibration data when the barrel-shaped vibration measuring device is conveyed to the cleaning process and the beer filling process. Provide a method.

  According to the present invention, the vibration detection sensor, the data storage unit, and the power source are fixed inside the container body, and the outer shell of the container body is formed in substantially the same shape as the beverage container. Therefore, by transporting the beverage container type vibration measuring device on the transport line, the vibration applied to the container body is measured by the vibration detection sensor, and the measured vibration data is associated with the transport position and stored in the data. Can be stored. In particular, since the outer shell of the container body is formed in substantially the same shape as the beverage container, the vibration level actually added to the beverage container as a product is determined using the measured vibration data. I can grasp it. Further, since the vibration data is stored in association with the measurement time in the data storage unit, the problem occurrence point (transport position) in the transport line is specified based on the measurement time of the vibration data exceeding the allowable value. be able to. Therefore, it is possible to easily identify a location where a transport trouble such as a container collapse may occur in the transport line by analyzing the vibration data. Therefore, it is possible to prevent troubles such as damage to beverage containers and leakage of contents that occur in the transportation process, or it is possible to quickly cope with transportation troubles.

Schematic external view of the beer barrel type vibration measuring apparatus according to one embodiment of the present invention (with the lid closed) Schematic external view of the beer barrel vibration measuring apparatus of the present embodiment (with the lid open) The bottom enlarged view in the internal space of the container main body of the beer barrel type vibration measuring device of this embodiment Schematic diagram of the state in which the beer barrel type vibration measuring device of the present embodiment is being transported together with the beer barrel container in the beer production process transport line The graph which shows one Example of the vibration data measured by the beer barrel type vibration measuring device The graph which shows another Example of the vibration data measured by the beer barrel type vibration measuring device (normal conveyance state) The graph which shows another Example of the vibration data measured by the beer barrel type vibration measuring device (barrel leak occurrence) Graph showing another example of vibration data measured by a beer barrel-type vibration measuring device (cause of barrel collapse)

  Embodiments according to the present invention will be described below in detail with reference to the drawings.

  FIG. 1 shows a schematic external view of a beer barrel type vibration measuring apparatus 10 which is an example of a beverage container type vibration measuring apparatus according to an embodiment of the present invention, and a state in which a lid of the beer barrel type vibration measuring apparatus 10 is removed. A schematic external view of this is shown in FIG.

  As is apparent from FIGS. 1 and 2, in the present embodiment, vibrations added to the beer barrel container during transport are measured in a transport line where the beer barrel container is transported as an example of a beverage container. The beer barrel type vibration measuring apparatus 10 will be described.

  As shown in FIG. 1 and FIG. 2, a beer barrel vibration measuring apparatus 10 includes a container body 11 having substantially the same outer shell as a beer barrel container that is filled with a beer that is a product and shipped, and a container body 11. And a vibration detection sensor 12 for detecting vibration applied to the container main body 11 when the container main body 11 is conveyed. Further, on the inner side of the beer barrel type vibration measuring apparatus 10, a data recording unit 13 for recording vibration data measured by the vibration detection sensor 12 in association with a measurement time, a vibration detection sensor 12 and a data recording unit 13 are provided. A battery 14 that is a power source for supplying electric power necessary for electrical functioning is fixed. In addition, as such a beer barrel container, the 10L barrel container, the 20L barrel container, the 30L barrel container, etc. distribute | circulate, for example, In this embodiment, a 20L barrel container is demonstrated as an example.

  As shown in FIG. 2, in the internal space of the container main body 11, the data recording unit 13 and the battery 14 are fixed to the cylindrical inner wall of the container main body via a plurality of brackets (fixing members) 15. Further, as shown in the enlarged bottom view in the internal space of the container body 11 shown in FIG. 3, the vibration detection sensor 12 is fixed to the approximate center of the inner wall surface of the bottom 16 of the container body 11. The vibration detection sensor 12, the data recording unit 13, and the battery 14 are electrically connected to each other by a plurality of cables 17 for power supply or signal transmission.

  As shown in FIGS. 1 and 2, an opening 18 for attaching and maintaining each device is provided on the side surface (cylindrical circumferential surface) of the container main body 11. It can be closed (sealed) (see FIG. 1). In addition, a handle 20 for manually handling the beer barrel vibration measuring apparatus 10 is provided on the upper portion of the container body 11.

  As the vibration detection sensor 12 used in the beer barrel type vibration measuring apparatus 10, for example, a sensor that detects vibration in one direction is used, and as such a sensor, there is a piezoelectric acceleration pickup sensor. A piezoelectric acceleration pickup sensor is a sensor that uses a piezoelectric element as a seismic spring, and at the same time, is used as an electromechanical transducer. Such a sensor outputs an electrical signal proportional to the vibration acceleration generated in one direction as measurement data. Piezoelectric accelerometers are broadly classified into two types, compression type and shear type (shear type), depending on the difference in how force is applied to the piezoelectric element. The compression type employs a structure in which a piezoelectric element is sandwiched between the base and weight of the sensor, and the shear type fixes the piezoelectric element between a post and a weight that are set up perpendicular to the base. Structure is adopted. As the vibration detection sensor 12 of the present embodiment, it is preferable to use a shear type that is less affected by base distortion and rapid temperature change. In the beer barrel type vibration measuring apparatus 10 of the present embodiment, the vibration detection sensor 12 is attached so as to measure the vibration in the longitudinal direction (vertical direction) of the cylinder of the container body 11.

  In the beer barrel vibration measuring apparatus 10 having such a configuration, vibration in the detection direction (vertical direction) added to the container body 11 is measured by the vibration detection sensor 12, and the measured vibration data is converted into vibration acceleration. It outputs to the data recording part 13 as a proportional electrical signal, and vibration data is continuously recorded (stored) in association with the measurement time in the data recording part 13. When the operator wants to check the recorded vibration data, he can remove the lid 19 and access the data recording unit 13 through the opening 18 to check or take out the necessary vibration data. The data recording unit 13 may be a case where vibration data is recorded on a sheet or the like in addition to a case where vibration data is electrically held (stored) as electronic data.

  Next, a method for measuring vibration applied to a beer barrel container in a beer manufacturing process (production line) using the beer barrel container using such a beer barrel vibration measuring apparatus 10 will be described. To do.

  As shown in the schematic diagram of FIG. 4, in the beer manufacturing process, a plurality of transfer conveyors 22 are connected to each other to form a transfer line 23 for continuously transferring a plurality of beer barrel containers 21. In such a conveyance line 23, for example, a cleaning processing device (not shown) that performs a cleaning process on the inner and outer surfaces of the beer barrel container 21, and a beer filling process for the beer barrel container 21 are performed. A plurality of beer barrel containers 21 arranged on the conveyor 22 for conveyance are continuously conveyed (in / out) to the filling processing apparatus.

  As shown in FIG. 4, the beer barrel vibration measuring apparatus 10 having substantially the same outer shell shape is transported along with the beer barrel container 21 that is sequentially transported by the transport line 23. The beer barrel vibration measuring apparatus 10 transported by the transport line 23 is added to the container main body 11 through its bottom 16 (in FIG. 4, it is a part disposed on the transporting conveyor 22) during transport. The vibration in the Z direction (vertical direction) shown in the figure is measured by the vibration detection sensor 12. The measured vibration data is continuously recorded in a state associated with the measurement time by the data recording unit 13.

  Here, an example of the vibration data recorded by the data recording unit 13 is shown in the graph of FIG. In the graph of FIG. 5, the vertical axis indicates the vibration level (voltage: V), and the horizontal axis indicates the measurement time (T1 to T9). Moreover, the conveyance position of the beer barrel type vibration measuring apparatus 10 on the conveyance line 23 is obtained by acquiring the data on the conveyance speed of the conveyor 22 for conveyance or the data on the relationship between the conveyance position and the time in advance. Can be grasped in association with each of the above.

  In the graph of FIG. 5, a vibration level of −1.000 V to +0.750 V is detected at time T1, which is the timing when the beer barrel vibration measuring device 10 is placed on the conveyor 22 for conveyance. After that, when the beer barrel vibration measuring apparatus 10 is transported by the transport line 23 and passes through the connecting portion (crossing portion) between the transporting conveyors 22 in the time interval T1-T2, −0.500V to +0. A vibration level of 375 V is detected. In the time interval T2-T5, the vibration level is within −0.125V to + 0.125V, and the vibration level during normal conveyance is detected. Further, in the time section T5-T6, the vibration level of about −0.250V to + 0.250V is detected after passing through the connecting portion of the transfer conveyor 22 again.

  From the vibration data shown in the graph of FIG. 5, the magnitude of the vibration level added to the beer barrel container 21 when the beer barrel container 21 is transported by the transport line 23 can be grasped. The transport position where the level increases can be easily specified on the transport line 23 based on the relationship data between the measurement times T1 to T9 and the transport position. Therefore, it is possible to determine whether or not the maintenance of the transfer line 23 is necessary in accordance with the magnitude of the vibration level at a transfer position where the specified vibration level is large (a connecting portion of the transfer conveyor 22). .

  Next, another example of the vibration data measured by the beer barrel vibration measuring apparatus 10 is shown in the graphs of FIGS.

  The graph of FIG. 6 shows the vibration level when the beer barrel container 21 is normally transported in the transport line 23. Here, the normal conveyance is a conveyance state that does not cause problems such as barrel leakage (content leakage), barrel collapse, and barrel container damage to the beer barrel container 21 during conveyance. Such vibration data is acquired by conveying the beer barrel type vibration measuring apparatus 10 together with the beer barrel container 21 through the conveyance line 23.

  In the graph of FIG. 6, in the time section T11-T12, the beer barrel vibration measuring device 10 is placed on the conveyor 22 for conveyance, and a vibration level of -1.0V to + 0.75V is detected at that time. . Moreover, in time section T13-T14 and T18-T19, the beer barrel type vibration measuring apparatus 10 passes the connection part (crossing part) between the conveyors 22 for conveyance, In this case, -0.6V- + 0. A vibration level of 4V is detected. From these detection results, it can be seen that the vibration level when the beer barrel container 21 is normally transported by the transport line 23 is about -0.6V to + 0.4V.

  The graph of FIG. 7 shows the vibration level when a barrel leakage (content leakage) occurs in the beer barrel container 21 in the transport line 23. Specifically, in the time interval T24-T25 in FIG. 7, an impact is applied in the beer barrel container 21, and a barrel leak occurs at that time, and a vibration level of -2.6V to + 3.6V is detected. Yes. Therefore, it can be seen that as the vibration level approaches −2.6 V to +3.6 V, there is a higher possibility that the beer barrel container 21 will leak in the transport line 23.

  The graph in FIG. 8 shows the vibration level when the beer barrel container 21 falls down (side down) in the transport line 23. Specifically, in the time interval T39-T40 in FIG. 8, an impact is applied by the beer barrel vibration measuring device 10, and the barrel collapses at that time, and a vibration level of −1.6V to + 4.4V is generated. It has been detected. Therefore, it can be seen that as the vibration level approaches −1.6 V to +4.4 V, the possibility of the barrel collapse of the beer barrel container 21 in the transport line 23 increases.

  Thus, by acquiring vibration levels as in the above-described embodiments in advance, it is possible to grasp vibration levels that may cause barrel leakage, barrel collapse, or damage of the beer barrel container 21 during transportation. be able to. Based on such vibration level data, it is possible to set an allowable value of the vibration level that does not cause a conveyance trouble. By using such an allowable value of the vibration level, for example, when the vibration data recorded by the data recording unit 13 is analyzed and the vibration level exceeds the allowable value, the conveyance line 23 It is possible to check the transfer position in the case and take improvement measures such as maintenance, and to prevent occurrence or early improvement of transfer troubles.

  In addition, this invention is not limited to the said embodiment, It can implement with another various aspect. For example, in FIG. 3, the vibration detection sensor 12 is installed in the approximate center of the inner wall of the bottom 16 of the container body 11, but the installation position of the vibration detection sensor 12 depends on the type of vibration to be detected and the beer barrel container 21. The position can be changed to a suitable position depending on the conveying posture.

  For example, when the beer barrel container 21 is transported upside down (that is, the bottom 16 is on the upper side), the vibration detection sensor 12 is preferably installed on the upper inner wall. By installing the vibration detection sensor 12 at a position closer to the conveyor 22 for conveyance, it is possible to measure with high accuracy.

  Further, for example, when it is desired to measure the vibration in the horizontal direction, it is necessary to set the measurement direction of the vibration detection sensor 12 as the horizontal direction. In this case, for example, it is preferable to install the vibration detection sensor 12 on the cylindrical inner peripheral surface (side wall inner surface) of the container body 11. In addition, in order to prevent the barrel collapse of the beer barrel container 21, it is effective to measure the vibration in the vertical (vertical) direction.

  In the beer barrel vibration measuring apparatus 10, the outer shell shape of the container body 11 is substantially the same as that of the beer barrel container 21. Thus, by detecting vibration in the state where the container body 11 having the same shape is transported on the transport line 23, data close to the vibration level actually added to the beer barrel container 21 can be acquired. it can. From this point of view, for example, the weight difference is adjusted so that the weight of the beer barrel vibration measuring apparatus 10 is substantially the same as the weight of the beer barrel container 21 in a state where a specified amount of beer is filled. It is also effective to install the weight member in the container body 11. In this case, it is desirable to adjust the arrangement of the weight members provided in the container body 11 so that the weight balance (for example, the position of the center of gravity) actually approaches the beer barrel container 21.

  Moreover, since the beer barrel type vibration measuring apparatus 10 is transported together with the beer barrel container 21 in the cleaning process and the filling process, it is difficult for heat due to high temperature cleaning or the like to be transferred into the container body 11. It is preferable to provide a heat insulating material on the inner wall surface of the container body 11 and further improve the sealing performance of the container body 11.

  Moreover, you may provide the radio | wireless communication apparatus which transmits the vibration data recorded (memory | storage) in the container main body 11 of the beer barrel type vibration measuring apparatus 10 with the data recording part 13 with respect to the exterior. By providing the wireless communication device in this way, the measured vibration data is transmitted by the wireless communication device and displayed in real time on an external monitor or the like while the beer barrel vibration measuring device 10 is transported by the transport line 23. It becomes possible. For example, in the transport line 23, the beer barrel vibration measuring device 10 is transported together with the plurality of beer barrel containers 21, so that the operator can grasp the transport state (vibration level state) of the beer barrel container 21 in real time. Therefore, it is possible to prevent the occurrence of a transportation trouble or to deal with it at an early stage. In addition, the vibration data transmitted in this way is input to an external control device, and it is determined whether or not an allowable value of a preset vibration level is exceeded. , It is possible to promptly notify the operator that the vibration level has been exceeded. Note that a wired communication device may be used instead of the wireless communication device.

  Moreover, the beer barrel type vibration measuring apparatus 10 can be used other than the manufacturing process of beer. For example, the vibration added to the beer barrel container 21 in the distribution process can be measured by loading the beer barrel type vibration measuring device 10 together with the beer barrel container 21 shipped from the factory on a transport vehicle. In such a case, if a transport trouble (such as a barrel leak) occurs in the distribution process from the factory to the storefront, it is possible to easily identify the location where the trouble occurred, and a transport trouble for the product being shipped. Can be effectively prevented.

  Moreover, although this embodiment demonstrated as an example about the case where a beverage container is a beer barrel container, it is possible to apply the vibration measuring apparatus and method of this embodiment with respect to various other forms of beverage containers. it can. For example, when the beverage is beer, the present invention can also be applied to container forms such as cans and bottles. In the case of cans, the cans may be damaged by rubbing between the cans in the transport line, and the degree of such rubbing between the cans can be grasped by measuring the vibration in the horizontal direction. Also, in the case of bottles, label wear due to rubbing between bottles may occur, and the degree of rubbing between bottles can be grasped by measuring horizontal vibration.

  It is to be noted that, by appropriately combining arbitrary embodiments of the various embodiments described above, the effects possessed by them can be produced.

DESCRIPTION OF SYMBOLS 10 Beer barrel type vibration measuring apparatus 11 Container main body 12 Vibration detection sensor 13 Data recording part 14 Battery 15 Bracket 16 Bottom part 17 Cable 18 Opening part 19 Cover 20 Handle 21 Beer barrel container 22 Conveyor for conveyance 23 Conveyance line

Claims (9)

Have a shell of a plurality of beverage containers substantially the same shape to be conveyed by a plurality of conveyer connecting to the configured conveying line on a container body which beer is not filled,
A vibration detection sensor that is fixed to the inside of the container body and detects vibrations added to the container body during transportation on the transportation line;
A data storage unit fixed inside the container body and storing vibration data measured by the vibration detection sensor in association with time;
A power source that is fixed to the inside of the container body and supplies power for functioning the vibration detection sensor and the data storage unit ;
The beverage container is a beer barrel container, and a vibration detection sensor, a data storage unit, and a power source are arranged in a sealed container body,
The weight member for weight adjustment is arranged in the container body so that the weight of the beverage container-type vibration measuring device is the same as the weight of the beer barrel container filled with the specified amount of beer. A container-type vibration measuring apparatus for beverages. A vibration detection sensor is fixed at substantially the center of the bottom inner wall of the container main body, and the vibration detection sensor detects vertical vibration applied to the container main body through the bottom of the container main body during transportation. The container-type vibration measuring apparatus for beverages according to claim 1 . Vibration detecting sensor on the side wall of the container body is fixed, the vibration detecting sensor detects the vibration in the horizontal direction is added to the container body during transport, beverage containers vibration according to claim 1 measuring device. The beverage according to any one of claims 1 to 3 , further comprising a wired or wireless communication device that transmits vibration data stored in the data storage unit to the outside of the container body. Container-type vibration measuring device. Have a shell of a plurality of beverage containers substantially the same shape to be conveyed by a plurality of conveyer connecting to the configured conveying line on a container body which beer is not filled, the container body A beverage container-type vibration measuring device comprising a vibration detection sensor fixed inside and a data storage unit for storing vibration data measured by the vibration detection sensor, transported in a transport line,
Vibration of beverage containers as well as measured by the vibration detecting sensor vibrations to be added to the container body, the Ru is stored in the data storage unit the measured vibration data correlated with the information of the transport position when the conveyance on the conveying line A measuring method,
The beverage container is a beer barrel container, and a barrel-type vibration measuring device in which a vibration detection sensor and a data storage unit are arranged in a sealed container body is conveyed by a conveyance line,
The weight adjustment weight member is arranged in the container main body so that the weight of the beverage container-type vibration measuring device is the same as the weight of the beer barrel container filled with the specified amount of beer. , Method for measuring vibration of beverage container. In the barrel-type vibration measuring device, the vibration detection sensor is fixed to the approximate center of the inner wall of the bottom of the container body, and measures the vertical vibration applied to the container body through the bottom of the container body during transport. The method for measuring vibration of a beverage container according to claim 5 . In the barrel-type vibration measuring device, the vibration detection sensor is fixed to the side wall of the container body, and the barrel-type vibration measuring device is transported along the transport line along with a plurality of beer barrel containers, and added to the container body during transport. The vibration measurement method of the beverage container according to claim 5 , wherein horizontal vibration is detected. The vibration data stored in the data storage unit determines whether or not the vibration allowable value is exceeded, and outputs an alarm when the vibration allowable value is exceeded, according to any one of claims 5 to 7 . Method for measuring vibration of beverage container. The conveyance line is a line that carries in and out a plurality of beer barrel containers for at least the cleaning process step and the beer filling process step for the beer barrel containers, and the barrel type vibration measuring device is cleaned with the plurality of beer barrel containers. The vibration measurement method for a beverage container according to any one of claims 5 to 8 , wherein vibration data at the time of conveyance to the beer filling process is continuously measured.

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