JP2015197888A - Reading device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reading device capable of reading out data from a target storage medium.SOLUTION: Antenna units 31-34 are arranged so that they are adjacent to each other upward and downward. Each antenna unit 31-34 is provided with: a housing part 41-44 which a card body containing an RFID chip is pushed into or pulled out from; and an antenna 136 which performs data communication with the card body housed in the housing part 41-44 by radio. Each antenna unit 31-34 is provided with a metal magnetic field rectification part 137, and the magnetic field rectification part 137 prevents a magnetic field 222 from the antenna 136 of each one of the adjacent antenna units 31-34 from reaching the housing part 41-44 of the other of the antenna units 31-34.

Description

  The present invention relates to a reading device that reads data by wireless communication.

  In a manufacturing factory or the like, a management post 801 as shown in FIG. 7 is used to manage the manufacturing process.

  .. Are provided on the front surface of the management post 801, and a card body can be inserted into each card accommodation portion 811,. Each card body incorporates an RFID chip and is configured to read and write data.

  As these card bodies, there are, for example, product cards 821,... In which data of products to be manufactured are stored, and ID cards 822,... Owned by the workers. The product card 821 to be manufactured and the owned ID card 822 are configured to be inserted into any empty space of the card housing portion 811.

  The management post 801 has a built-in antenna that communicates with the RFID chip. By acquiring the RFID chip data from a signal received by the antenna, the management post 801 is inserted into the card housing portion 811,. The data is read from all the cards 821,. The data read from each of the cards 821,..., 822,... Is sent to a server (not shown), and the server operates according to the data from the product card 821. An instruction is transmitted to the management post 801 for display, and progress management for each worker can be performed in accordance with data from the ID card 822.

  FIG. 8 is a diagram illustrating a factory having four work areas. In the factory, a work area A831 for performing a first work, a work area B832 for performing a second work, and a work for performing a third work. An area C833 and a work area D834 for performing a fourth work are provided. The first to fourth management posts 801a to 801d are installed in each work area A to D831 to 834, and data from each management post 801a to 801d installed in each work area A to D831 to 834 is stored. By receiving the server, it is configured to be able to acquire who is working on what product in which work area 831-834.

  In such a system, it is necessary to install management posts 801a to 801d for each of the work areas 831 to 834.

  For this reason, it is necessary to secure the installation space for the management posts 801a to 801d in each of the work areas 831 to 834, which is an obstacle to space saving.

  In order to solve this problem, each of the card accommodating portions 811,... Is made to correspond to each of the work areas 831 to 834, and a plurality of work areas 831 to 834 can be managed by one management post 801. The present applicant has come up with a plan to do so.

  However, in such a management post, when data is read from the card body stored in the predetermined card storage unit 811, the card body stored in the card storage unit 811, 811 adjacent to the upper stage or the lower stage is used. There arises a problem that data is also read out.

  In this case, it becomes impossible to recognize which work area 831 to 834 corresponds to the read data.

  The present invention has been made in view of such a conventional problem, and an object of the present invention is to provide a reading device capable of reading data from a target storage medium.

  In order to solve the above-described problem, the reading apparatus according to claim 1 of the present invention includes a storage unit in which a storage medium is detachably stored and an antenna that communicates with the storage medium stored in the storage unit. A reading device in which a plurality of reading units are arranged adjacent to each other, and a magnetic field rectifying unit that blocks a magnetic field from an antenna of one reading unit arranged adjacent to the accommodation unit of the other reading unit Provided.

  That is, the reading device is provided with a plurality of reading units, and each reading unit is provided with a storage unit that stores a storage medium and an antenna that communicates with the storage medium stored in the storage unit. It has been.

  For this reason, for example, when managing a plurality of work areas with the reading device, a plurality of work areas can be managed without increasing the installation space by assigning a reading unit to each work area to be managed. Can do.

  At this time, the reading device is provided with a plurality of reading units, and the antenna of the predetermined reading unit reads data from a storage medium accommodated in the accommodating unit of the reading unit adjacent to the reading unit. It is possible to end up.

  Therefore, in the present invention, there is provided a magnetic field rectifying unit that prevents the magnetic field from the antenna of one reading unit arranged adjacent from reaching the housing unit of the other reading unit. For this reason, the malfunction of reading data from the storage medium of the accommodating part in the reading part arrange | positioned adjacently is prevented.

  Further, in the reading device according to claim 2, the antenna is configured by a planar loop antenna, and the housing portion is provided on a front surface facing the loop antenna, while the magnetic field rectifying portion is housed by the loop antenna. A U-shaped cross-section is formed by a front plate portion arranged on the rear side, a rear plate portion provided on the back side of the loop antenna, and a continuous plate portion connecting the rear plate portion and the front plate portion. It was formed and arranged so that the connecting plate portion is located on the side of the adjacent reading portion.

  That is, the antenna is configured by a planar loop antenna, and a magnetic field enters and exits from the loop antenna in a direction perpendicular to the plane direction of the loop antenna. And the accommodating part is provided in the front which this loop antenna opposes, and the data from the storage medium accommodated in this accommodating part are read by the said loop antenna.

  Further, the magnetic field rectifying unit for preventing the magnetic field from reaching the accommodating unit of the adjacent reading unit is formed in a U-shaped cross section by a front plate unit, a rear plate unit, and a continuous plate unit. It arrange | positions so that a board part may be located in the reading part side which adjoins.

  For this reason, the magnetic field from the antenna of an adjacent reading part is interrupted | blocked by the said connection board part.

  Further, the front plate extending from the continuous plate located on the side of the adjacent readout unit is disposed between the loop antenna and the accommodating portion, and the rear plate extended from the continuous plate The part is provided on the back side of the loop antenna.

  Therefore, the magnetic field flowing from the loop antenna to the adjacent reading unit side flows to the adjacent reading unit side by looping through the front plate unit, the connecting plate unit, and the rear plate unit. Is blocked.

  Furthermore, in the reading device according to a third aspect, the length of the rear plate portion is set so that the front end of the rear plate portion reaches or approaches the center line passing through the coil center of the loop antenna.

  That is, the rear plate portion of the magnetic field rectifying portion is set to a length that reaches or approaches a center line that passes through the coil center of the loop antenna.

  For this reason, the flow of the magnetic field toward the adjacent reading unit with the center line as a boundary is blocked by the rear plate unit.

  In addition, in the reading device according to claim 4, the storage medium includes a loop-type medium-side antenna, and the front plate portion is arranged so as not to disturb a magnetic field from the loop antenna to the medium-side antenna. It was set shorter than the rear plate.

  That is, the front plate portion of the magnetic field rectifying unit is set shorter than the rear plate portion, and is configured so that the magnetic field from the loop antenna to the medium side antenna provided in the storage medium is not hindered. Yes. Thereby, communication is performed between the loop antenna and the medium-side antenna.

  As described above, in the reading device according to the first aspect of the present invention, the magnetic field for preventing the magnetic field from the antenna of one reading unit arranged adjacent to the receiving unit of the other reading unit from being blocked. Since the rectifying unit is provided, it is possible to prevent a problem that data is erroneously read from the storage medium in the storage unit of the reading unit arranged adjacently.

  Therefore, by storing the storage medium to be read out in the storage unit, only the data of the storage medium to be read out stored in the storage unit can be selectively read out.

  Therefore, when a plurality of work areas are managed by the reading device, only the data from the storage medium in the storage unit to which each work area is assigned is selectively read by assigning a reading unit to each work area to be managed. be able to.

  As a result, it is possible to recognize which work area corresponds to the data by grasping which data is read by which reading unit. The work status in the work area can be confirmed.

  According to a second aspect of the present invention, the antenna includes a planar loop antenna, and a magnetic field enters and exits from the loop antenna in a direction perpendicular to the plane direction of the loop antenna. The storage unit is provided in front of the magnetic field from the loop antenna, and data from the storage medium stored in the storage unit can be efficiently read out by the loop antenna.

  The magnetic field rectifying unit that prevents the magnetic field from reaching the accommodating unit of the adjacent reading unit is formed in a U-shaped cross section by the front plate unit, the rear plate unit, and the continuous plate unit, and the continuous plate The units are arranged so as to be located on the side of the adjacent reading unit.

  For this reason, the magnetic field from the antenna of an adjacent reading part can be interrupted | blocked by the said connection board part. As a result, it is possible to prevent data reading from the storage medium accommodated in the accommodation unit of the readout unit in the adjacent readout unit.

  Further, the front plate extending from the continuous plate located on the side of the adjacent readout unit is disposed between the loop antenna and the accommodating portion, and the rear plate extended from the continuous plate The part is provided on the back side of the loop antenna.

  For this reason, the magnetic field flowing from the loop antenna to the adjacent reading unit side is looped by the magnetic path formed by the front plate unit, the connecting plate unit, and the rear plate unit, to the adjacent reading unit side. The flow of the magnetic field can be prevented. Thereby, data reading from the storage medium accommodated in the adjacent reading unit by the antenna of the reading unit can be prevented.

  Further, in the reading device according to the third aspect, the rear plate portion of the magnetic field rectifying portion is set to have a length that reaches or approaches a center line passing through the coil center of the loop antenna.

  For this reason, the flow of the magnetic field to the adjacent reading unit side with the center line as a boundary can be blocked by the rear plate unit. As a result, data reading from the storage medium accommodated in the adjacent reading unit by the antenna of the reading unit can be reliably prevented.

  In addition, in the reading device according to claim 4, the front plate portion of the magnetic field rectifying unit is set shorter than the rear plate portion, and the medium side provided on the storage medium from the loop antenna It is configured so that the magnetic field to the antenna is not obstructed. Thereby, communication can be reliably performed between the loop antenna and the medium-side antenna.

It is a perspective view of one embodiment of the present invention. It is explanatory drawing which shows the utilization form of the embodiment. It is a block diagram which shows the same embodiment. It is sectional drawing which shows the principal part of the embodiment. It is a front view which shows the antenna unit of the embodiment. It is AA sectional drawing of FIG. It is explanatory drawing which shows a prior art example. It is explanatory drawing which shows the conventional usage form.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing a reading device 1 according to the present embodiment, and shows an example in which the reading device 1 is used in a manufacturing factory.

  FIG. 2 is a diagram showing a usage form of the reading device 1, and is configured so that the work in the first to fourth work areas 11 to 14 can be managed by one reading device 1 in a manufacturing factory. Yes. The reading device 1 is connected to a server (not shown), and data obtained by the reading device 1 is configured to be sent to this server.

  As shown in FIG. 1, the reading device 1 includes a unitized control unit 21 and an antenna unit constituting a reading unit of the present invention, and the antenna unit connected to the control unit 21. Are set to the same width so that the number of connections can be increased or decreased.

  The control unit 21 is provided at the uppermost stage of the reading device 1, and the first antenna unit 31 is connected to the lower stage of the control unit 21. A second antenna unit 32 is connected to the lower stage of the first antenna unit 31, and a third antenna unit 33 is connected to the lower stage of the second antenna unit 32. A fourth antenna unit 34 is connected to the lower stage of the third antenna unit 33, and the antenna units 31 to 34 are provided adjacent to each other in the vertical direction.

  As shown in FIG. 2, the first antenna unit 31 is related to manage work in the first work area 11, and the second antenna unit 32 is connected to the second antenna unit 32. It is related so as to manage work in the work area 12. The third antenna unit 33 is associated to manage work in the third work area 13, and the fourth antenna unit 34 manages work in the fourth work area 14. To be related.

  As shown in FIG. 1, the antenna units 31 to 34 have the same configuration, and first to fourth accommodating portions 41 to 44 are provided on the front surfaces of the antenna units 31 to 34. ing. Each accommodating part 41-44 is comprised so that it can hold | maintain in the state which inserted the card | curd body, and is comprised so that a card | curd body can be accommodated freely. The card body incorporates an RFID chip as a storage medium, and is configured such that data can be read and written in a contactless manner by wireless communication using radio waves.

  As these card bodies, there are a product card 51 in which data of a product to be manufactured is stored, an ID card 52 in which data of an owned worker is stored, and each worker manufactures at the start of work. The product card 51 corresponding to the product and the owned ID card 52 are configured to be inserted into the accommodating portions 41 to 44 of the antenna units 31 to 34 corresponding to the work areas 11 to 14 where the work is performed.

  Each of the antenna units 31 to 34 is configured to perform data communication with an RFID chip built in the card body housed in the housing portions 41 to 44 of the antenna units 31 to 34, and the antenna units 31 to 34 are configured to perform data communication. The data acquired in (1) is collected by the control unit 21.

  FIG. 3 is a block diagram showing a configuration of the reading device 1, and the control unit 21 is connected to a satellite 61, an Ethernet 62, an RS232C 63, and an AC adapter 64. The control unit 21 is configured with a main CPU 65 as a center, and a WIFI module 66 is connected to the main CPU 65. A WIFI antenna 67 is connected to the WIFI module 66, and the WIFI antenna 67 is configured to be able to communicate with a server via an access point (not shown).

  The main CPU 65 is connected to a graphic LCD 71, a 7-segment LED 72, and a 7-color LED 73, and can be configured to perform various displays using the graphic LCD 71, the 7-segment LED 72, and the 7-color LED 73. Has been. The main CPU 65 is connected to a power switch 74 and a call switch 75. The power switch 74 is used to turn on / off the power of the reading device 1, and the call switch 75 can call an administrator. Has been.

  A sub CPU 81 is connected to the main CPU 65, and a wiring 83 constituting a data bus 82 is connected to the sub CPU 81. The main CPU 65 is connected to a wiring 85 constituting an antenna control transmission line 84 and a wiring 87 constituting an antenna control reception line 86. The data bus 82, the antenna control transmission line 84, and the Each wiring 83, 85, 87 constituting the antenna control receiving line 86 is connected to a connector connecting portion 89 provided on the substrate 88 of the control unit 21.

  Each of the antenna units 31 to 34 includes an antenna substrate 101. The antenna substrate 101 has an upstream connector connection portion 102 for connection with an upstream unit and a connection with a downstream unit. A downstream connector connecting portion 103 is provided.

  A wiring 111 constituting the antenna control transmission line 84 is connected to the upstream connector connecting portion 102, and this wiring 111 is connected to an input of the control register 112. The output of the control register 112 is connected to a wiring 113 constituting the antenna control transmission line 84, and this wiring 113 is connected to the downstream connector connection portion 103.

  The upstream connector connecting portion 102 is connected to a wiring 121 constituting the data bus 82, and this wiring 121 is connected to the RFID controller 122 and also connected to the downstream connector connecting portion 103. Has been.

  The upstream connector connection portion 102 is connected to a wiring 131 that constitutes the antenna control reception line 89. The wiring 131 is connected to the downstream connector connection portion 103, while being connected to a connection terminal. 135 is configured to be connected to the output of the control register 112 (shown only in the fourth antenna unit 34).

  The control register 112 is configured to store a signal transmitted from an upstream unit. In an initial state when the power is turned on, “0000B” is stored (the control register 112 has 4 bits). The case where it is configured will be described as an example). The control register 112 is configured to output the currently stored data when the data is sent from the upstream unit, and to newly store the sent data. In the initial state in which “0000B” is stored, when “0001B” is sent from the upstream unit, “0000B” is sent to the downstream unit, and then “0000B” is sent from the upstream unit. “0001B” is stored.

  The RFID register 122 is connected to the control register 112, and a loop type antenna 136 is connected to the RFID controller 122. The RFID controller 122 is configured to transmit and receive radio waves via the antenna 136, and the radio waves are transmitted to the antenna units 31 to 34 by the magnetic field rectifying component 137 as a magnetic field rectifying unit. It is comprised so that it may transmit / receive toward the accommodating parts 41-44.

  As a result, the RFID controller 122 operates in accordance with the data stored in the control register 112 to perform data communication with the RFID chip built in the card body accommodated in the accommodating portions 41 to 44 of the antenna units 31 to 34. It is configured to do so.

  Specifically, for example, when it is defined that the operation is not performed on the least significant bit of the storage data of the control register 112 and the data reading process is performed when the second bit is “1”, the storage When the data becomes “0010B”, the RFID controller 122 transmits and receives radio waves via the antenna 136, so that a predetermined number of RFID chips built in the card bodies accommodated in the corresponding accommodating portions 41 to 44 are transmitted. The storage data is configured to be read, and the read data is configured to be sent to the control unit 21 via the data bus 82. Thereby, the data acquired by the antenna units 31 to 34 can be collected by the control unit 21.

  In the reading device 1, the connector connecting portion 89 of the control unit 21 is connected to the upstream connector connecting portion 102 of the first antenna unit 31 via an antenna cable 141, and One antenna unit 31 is configured to exchange data with the control unit 21. The downstream connector connecting portion 103 of the first antenna unit 31 is connected to the upstream connector connecting portion 102 of the second antenna unit 32 via an antenna cable 141, and the second antenna The unit 32 is configured to exchange data with the first antenna unit 31 and the control unit 21.

  The downstream connector connecting portion 103 of the second antenna unit 32 is connected to the upstream connector connecting portion 102 of the third antenna unit 33 via an antenna cable 141, and the third antenna unit The unit 33 is configured to exchange data with the second antenna unit 32 and the control unit 21. The downstream connector connecting portion 103 of the third antenna unit 33 is connected to the upstream connector connecting portion 102 of the fourth antenna unit 34 via an antenna cable 141, and the fourth antenna The unit 34 is configured to exchange data with the third antenna unit 33 and the control unit 21 (the third unit 33 is not shown).

  Thereby, the first to fourth antenna units 31 to 34 are connected to the control unit 21 in series.

  In the fourth antenna unit 34 connected to the end, the output of the control register 112 is connected to the upstream connector connecting portion 102 by the connection terminal 135, and the data output from the control register 112 is The antenna units 31 to 33 provided on the upstream side are configured to be input to the control unit 21 via the antenna control reception line 86.

  FIG. 4 is a cross-sectional view showing a main part of the reading device 1, and shows a state in which the antenna units 31 to 34 are connected vertically.

  A first support column 202 extending toward the back side is provided on the wall surface 201 that forms the back side of each of the housing portions 41 to 44 of the antenna units 31 to 34. The first support column 202 The antenna substrate 101 is supported. The length of the first support column 202 is set to be short, and the antenna substrate 101 supported by the first support column 202 is configured to be close to the wall surface 201.

  As shown in FIG. 5 (illustrated with the first antenna unit 31 as an example), the antenna 136 is integrally formed on the antenna substrate 101 by a printed wiring 212 formed in an elliptical shape. And a planar loop antenna formed on the antenna substrate 101. As shown in FIG. 4, the antenna substrate 101 is disposed so as to face the wall surface 201 of each of the housing portions 41 to 44, and the housing portions 41 to 44 are disposed in front of the antenna 136 facing each other. Has been placed.

  A second column 221 extending toward the back side is provided on the lower surface of the first column 202 on the wall surface 201 that forms the back side of each of the accommodating portions 41 to 44. The length of the column 221 is set longer than that of the first column 202. The magnetic field rectifying component 137 is supported on the second support column 221, and the magnetic field 222 from the antenna of one of the antenna units 31 to 34 disposed adjacent to the second support column 221 is the accommodating portion 41 of the other antenna unit 31 to 34. It is comprised so that it may not reach -44.

  Specifically, the first antenna unit 31 and the second antenna unit 32 arranged adjacent to each other in the vertical direction will be described as an example. The antenna 136 of the second antenna unit 32 arranged in the lower stage will be described. From the antenna 136 of the first antenna unit 31 arranged at the upper stage, and the magnetic field from the antenna 136 of the first antenna unit 31 arranged at the upper stage at the lower stage. Further, the second antenna unit 32 is configured not to reach the second accommodating portion 42.

  The magnetic field rectifying component 137 is made of a metal plate, and the magnetic field rectifying component 137 is formed in a U-shaped cross section. The magnetic field rectifying component 137 is formed in a horizontally long shape and extends along the antenna 136 formed on the antenna substrate 101, and is set to have a length extending over the entire length in the length direction. Yes.

  As shown in FIG. 6 (illustrated by taking the first antenna unit 31 as an example), the magnetic field rectifying component 137 includes a front plate portion 231 disposed on the front side that is closer to the housing portion 41 than the antenna 136, and A rear plate portion 232 provided on the back side of the antenna 136 and a continuous plate portion 233 connecting the rear plate portion 231 and the front plate portion 232 are formed in a U-shaped cross section, and the magnetic field rectification The component 137 is disposed so that the continuous plate portion 233 is positioned on the second antenna unit 32 side adjacent to the lower stage.

  In the magnetic field rectifying component 137, the rear plate portion 232 is fixed to and supported by the second support column 221, and the lower edge portion of the antenna substrate 101 is interposed between the front plate portion 231 and the rear plate portion 232. It is configured to be arranged. As shown in FIGS. 5 and 6, the length of the rear plate portion 232 is set so that the tip thereof is close to the center line 242 that passes through the coil center 241 of the antenna 136. The height of the upper end of the rear plate portion 232 is set to be substantially equal to the height of the center line 242.

  6 shows a state in which the tip of the rear plate portion 232 is close to the center line 242. However, even if the magnetic field rectifying component 137 and the antenna substrate 101 are attached to each other, they may be slightly shifted up and down. The state where the front end of the rear plate portion 232 reaches the center line 242 is ideal.

  On the other hand, card bodies such as the product card 51 and the ID card 52 accommodated in the accommodating portion 41 (illustrated by taking the product card 51 as an example in FIGS. 4 and 6) are connected to the RFID chip. The medium-side antenna 251 including a loop-type loop antenna is incorporated, and the medium-side antenna 251 includes the antenna of the antenna substrate 101 in a state where the card body (51) is accommodated in the accommodating portion 41. 136 is configured to face 136. Thus, radio waves can be exchanged between the medium-side antenna 251 and the antenna 136, and data communication can be performed between the RFID chip and the RFID controller 122.

  The card body (51) is supported from below by a support piece 261 at the bottom of the housing 41, and the antenna 136 of the antenna board 101 is at a height position from the lower edge to the upper edge of the medium-side antenna 251. The magnetic field 222 output from the antenna 136 can pass through the inside of the medium antenna 251.

  Further, the card bodies (illustrated by taking the product card 51 as an example) accommodated in the accommodating portions 41 to 44 of the antenna units 31 to 34 are adjacent to the upper side as shown in FIG. It arrange | positions and it is comprised so that it may arrange | position below the said connection board part 233 of the said magnetic field rectification component 137 in the antenna units 31-34. Therefore, a loop path through which the magnetic field 222 that has passed through the inside of the medium side antenna 251 loops is ensured between the medium side antenna 251 provided on the card body (51) and the upper magnetic field rectifying component 137. (See FIGS. 4 and 6).

  The length dimension of the front plate portion 231 of the magnetic field rectifying component 137 is set shorter than the rear plate portion 232, and the card body (51) is supported by the support piece 261 of the housing portion 41. In this state, the medium-side antenna 251 is arranged at a height position below the lower edge. Accordingly, the front plate portion 231 is configured not to obstruct the magnetic field 222 from the antenna 136 to the medium side antenna 251.

  In the present embodiment having the above configuration, the reading device 1 is provided with antenna units 31 to 34 as four-stage reading units, and each antenna unit 31 to 34 has an RFID as a storage medium. The housings 41 to 44 in which the card body containing the chip is housed, and the antenna 136 that communicates with the RFID chip built in the card body housed in the housing parts 41 to 44 are provided.

  For this reason, when performing management of the plurality of work areas 11 to 14 with the reading device 1, by assigning the antenna units 31 to 34 to the work areas 11 to 14 to be managed, the installation space is not expanded. Management of four work areas 11 to 14 can be performed.

  At this time, the reading apparatus 1 is provided with first to fourth antenna units 31 to 34 adjacent to each other, and the antenna 136 of a predetermined antenna unit 31 to 34 is adjacent to the antenna units 31 to 34. It is conceivable that data is also read from the card body accommodated in the accommodating portions 41 to 44 of the antenna units 31 to 34.

  Therefore, in the embodiment of the present application, the magnetic field 222 that prevents the magnetic field 222 from the antenna 136 of one of the antenna units 31 to 34 disposed adjacently from reaching the accommodating portions 41 to 44 of the other antenna unit 31 to 34 is prevented. A rectifying component 137 is provided. For this reason, it is possible to prevent a problem that data is erroneously read from the card body of the accommodating portions 41 to 44 in the antenna units 31 to 34 arranged adjacent to each other.

  For this reason, the card body that is the target of data reading is accommodated in the accommodating portions 41 to 44 by being accommodated in the accommodating portions 41 to 44 of the antenna units 31 to 34 corresponding to the work areas 11 to 14 where the work is performed. Only the data of the card body to be read can be selectively read.

  Thereby, in the control unit 21 of the reading device 1, the data collected from each antenna unit 31 to 34 is the card body of the antenna unit 31 to 34 assigned to which work area 11 to 14. Can be distinguished. Therefore, it is possible to check the work status in the plurality of work areas 11 to 14 by the single reading device 1.

  The antenna 136 is a flat loop antenna, and a magnetic field 222 enters and exits from the antenna 136 in a direction perpendicular to the surface direction of the antenna 136. And the said accommodating parts 41-44 are provided in the front surface in which the magnetic field 222 from this antenna 136 goes in / out, The data from the card | curd body accommodated in this accommodating parts 41-44 are efficiently received by the said antenna 136. FIG. Can be read out automatically.

  The magnetic field rectifying component 137 that prevents the magnetic field 222 from reaching the accommodating portions 41 to 44 of the adjacent antenna units 31 to 34 is cross-sectionally coupled by the front plate portion 231, the rear plate portion 232, and the continuous plate portion 233. It is formed in a letter shape, and is arranged so that the connecting plate portion 233 is located on the side of the antenna units 31 to 34 adjacent to the lower side.

  For this reason, as illustrated in FIG. 4, the magnetic field 222 from the antenna 136 of the lower second antenna unit 32 is blocked by the connecting plate portion 233 in the magnetic field rectifying component 137 of the upper first antenna unit 31. can do. Thereby, in the second antenna unit 32, data reading from the card body accommodated in the first accommodating portion 41 of the first antenna unit 31 can be prevented.

  Further, the front plate portion 231 extending from the front end of the continuous plate portion 233 located on the side of the adjacent antenna units 31 to 34 is disposed between the antenna 136 and the accommodating portions 41 to 44. A rear plate portion 232 extending from the rear end of the continuous plate portion 233 is provided on the back side of the antenna 136.

  For this reason, by looping the magnetic field 222 flowing from the antenna 136 toward the lower antenna units 31 to 34 through a magnetic path including the front plate portion 231, the continuous plate portion 233, and the rear plate portion 232, The flow of the magnetic field 222 toward the lower antenna units 31 to 34 can be prevented. As a result, for example, as shown in FIG. 4, data reading from the card body of the third antenna unit 33 by the antenna 136 of the second antenna unit 32 can be prevented.

  Further, the rear plate portion 232 of the magnetic field rectifying component 137 has a length that reaches or approaches a center line 242 that passes through the coil center 241 of the antenna 136.

  Therefore, adjacent antenna units 31 to 34 with the center line 242 as a boundary, specifically, as shown in FIG. 6, the first antenna unit 31 has a lower side from the coil center 241 of the antenna 136. The flow of the magnetic field 222a flowing toward the second antenna unit 32 can be blocked by the rear plate portion 232, and thus the flow of the magnetic field 222a toward the second antenna unit 32 can be blocked. Therefore, it is possible to reliably prevent data reading from the card body accommodated in the lower second antenna unit 32 by the antenna 136 of the first antenna unit 31.

  In addition, the length dimension of the front plate portion 231 of the magnetic field rectifying component 137 is set shorter than the rear plate portion 232 as shown in FIG. 6 (illustrated by taking the first antenna unit 31 as an example). In the state where the card body (51) is supported by the support piece 261 of the housing portion 41, the front plate portion 231 is below the lower edge of the medium antenna 251 built in the card body (51). It is comprised so that it may be arrange | positioned in the height position of the side. Accordingly, the front plate portion 231 is configured not to obstruct the magnetic field 222 from the antenna 136 to the medium side antenna 251.

  Therefore, communication can be reliably performed between the antenna 136 of the antenna substrate 101 and the medium-side antenna 251.

DESCRIPTION OF SYMBOLS 1 Reading apparatus 31 1st antenna unit 41 1st accommodating part 51 Card for product 52 ID card 136 Antenna 137 Magnetic field rectification component 231 Front plate part 232 Rear plate part 233 Connection board part 241 Coil center 242 Center line 251 Medium side antenna

Claims (4)

A reading device in which a storage unit in which a storage medium is removably stored and a plurality of reading units including an antenna that communicates with the storage medium stored in the storage unit are arranged adjacent to each other,
A reading apparatus comprising: a magnetic field rectifying unit that blocks a magnetic field from an antenna of one reading unit arranged adjacent to an accommodation unit of the other reading unit. The antenna is constituted by a planar loop antenna, and the housing portion is provided on the front surface facing the loop antenna,
The magnetic field rectification unit includes a front plate portion disposed closer to the housing portion than the loop antenna, a rear plate portion provided on the back side of the loop antenna, and the rear plate portion and the front plate portion. 2. The reading device according to claim 1, wherein the connecting plate portion is formed in a U-shaped cross section and is arranged so that the connecting plate portion is positioned on the adjacent reading portion side.   3. A reading apparatus according to claim 2, wherein the length of the rear plate portion is set so that the front end of the rear plate portion reaches or approaches a center line passing through the coil center of the loop antenna. The storage medium includes a loop-type medium antenna,
4. The reading apparatus according to claim 3, wherein the front plate portion is set shorter than the rear plate portion so as not to disturb a magnetic field from the loop antenna to the medium side antenna.

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