JP6489304B2 - Containment box system - Google Patents

Description

  The present invention relates to a storage box system, and more particularly to a storage box system that controls locking and unlocking of electric keys of a plurality of storage boxes.

  In an apartment house such as a condominium, a storage box for each resident is installed in the entrance lobby or the like so that the resident can indirectly receive deliveries delivered by mail or courier.

  Patent Document 1 discloses a mailbox system that manages locking and unlocking of such a storage box (mailbox). According to this, the mailbox for every resident is installed side by side vertically and horizontally. One control box is electrically connected to the plurality of mailboxes by signal lines.

  The control box is provided with an IC card reader. When the resident sets the IC card in the IC card reader, the control box reads the ID code registered in the IC card with the IC card reader, and the ID code Controls the electric lock on the mailbox door corresponding to, and unlocks it.

  Each mailbox is equivalent in the row direction and the column direction at each of intersections of a plurality of signal lines extending in the horizontal direction (row direction) and a plurality of signal lines extending in the vertical direction (column direction). Connected to the signal line and connected to the control box via the matrix wiring. As a result, the control box can individually unlock a desired mailbox by selecting signal lines in the row direction and column direction for inputting and outputting signals.

JP-A-5-266366

  However, the conventional storage box system as disclosed in Patent Document 1 has a problem that it takes time and labor to wire a cable connecting the control box and each storage box.

  This invention is made | formed in view of such a situation, and it aims at providing the accommodation box system which can reduce the burden of wiring work.

  In order to achieve the above object, a storage box system according to one aspect of the present invention is a storage box system in which a plurality of storage boxes having the same configuration connected in series to a control unit by signal line groups are individually controlled by the control unit. Each of the storage boxes has a signal line group composed of 1st to Mth horizontal signal lines and one vertical signal line, where M is a positive integer, between the front-stage storage box and the rear-stage storage box. A first connector and a second connector for connecting to the storage box, the first connector being directly connected to the second connector of the previous storage box when the storage boxes are arranged in a line; and The first horizontal signal line and the vertical signal line among the second connector directly connected to the first connector of the receiving box in the rear stage and the signal line group connected via the first connector Are connected to the internal circuit portion, and the No. 2 to No. M horizontal signal lines and the No. 1 horizontal signal line of the signal line group connected through the second connector are connected to the No. 1 to No. M horizontal signal lines. And a relay unit connected to the vertical signal line.

  According to this aspect, if the storage boxes having the same configuration are arranged in an arbitrary order, the storage boxes arranged in a row can be connected in series and controlled by the control unit. The installation work of the storage box is performed quickly and easily.

  In the storage box system according to another aspect of the present invention, a plurality of storage boxes are connected in series to each of a plurality of relay boxes connected in series to the control unit, and each of the relay boxes has N as a positive integer. A signal line group consisting of No. 1 to N number of vertical signal lines and No. 1 to No. M horizontal signal lines is connected between the preceding relay box and the subsequent relay box. 3 connectors and a fourth connector, when the relay boxes are arranged in a line, a third connector directly connected to the fourth connector of the preceding relay box and a third connector of the subsequent relay box A fifth connector for connecting a signal line group consisting of a fourth connector, No. 1 to M-th horizontal signal lines and one vertical signal line to an accommodation box, No. 1 to M-th horizontal signal lines among the fifth connector connected directly to the first connector of the storage box and the signal line group connected via the third connector when the storage box is disposed adjacent to 1st to Mth horizontal signal lines in the signal line group connected through the fourth connector and 1st to Mth horizontal signals in the signal line group connected through the fifth connector. Connected to the signal line, the 2nd to Nth vertical signal lines are connected to the 1st to N-1th vertical signal lines in the signal line group connected via the fourth connector, and the 1st And a second relay unit that connects the vertical signal line to one vertical signal line in the signal line group connected via the fifth connector.

  In the storage box system according to still another aspect of the present invention, the storage box may be a mail box, a delivery box, or a private box.

  In the storage box system according to yet another aspect of the present invention, the control unit can control the electric lock of the storage box.

  In the storage box system according to still another aspect of the present invention, the control unit may determine an abnormality based on a current flowing through a circuit unit of the storage box.

  In the storage box system according to still another aspect of the present invention, a plurality of storage boxes can be arranged in series in the vertical direction.

  In the storage box system according to still another aspect of the present invention, a plurality of relay boxes can be arranged in series in the horizontal direction.

  According to the present invention, the burden of wiring work can be reduced.

Perspective view showing the mailbox system from the front Mailbox perspective view Mailbox perspective view Relay box perspective view Relay box perspective view Control box perspective view System configuration diagram showing internal configuration related to wiring of mailbox system The figure which showed the signal line group which connects between the control part of a control box, and the horizontal relay board | substrate of the relay box of the 1st row The figure which showed the signal line group which connects between the horizontal relay boards of two adjacent relay boxes The figure which showed the signal line group which connects between the horizontal relay board | substrate of the relay box of b row, and the vertical relay board | substrate of the 1st mailbox in b row. The figure which showed signal line group Lv which connects between the vertical relay boards of two adjacent mailboxes The block diagram which showed the b row horizontal relay board | substrate as a horizontal relay board | substrate of arbitrary positions Configuration diagram showing an a-th vertical relay board in the b-th row as a vertical relay board at an arbitrary position

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a perspective view showing the mailbox system from the front side.

  In the mailbox system 10 and the entrance lobby of an apartment house shown in the figure, for example, when the back side is installed on a wall or on a pedestal part of a predetermined height, a predetermined height is set. Placed in position.

  The mailbox system 10 is arranged at the bottom of the arrangement area of the mailboxes 12 with a plurality of mailboxes 12, 12,... Having the same configuration arranged in the vertical direction (vertical) and the horizontal direction (horizontal). A plurality of relay boxes 14, and a control box 16 disposed in the periphery of the arrangement region of the mail boxes 12.

  The schematic configuration of the mailbox 12 will be described. All of the plurality of mailboxes 12 in FIG. 1 have the same configuration and have a rectangular parallelepiped outer shape.

  2 and 3 are perspective views showing the mailbox 12 from the upper right and lower right sides of the front side.

  As shown in these drawings, the mail box 12 is provided with a housing portion 22 that is a space for housing mail items inside, a box body 20 having an opening 22A on the front side, and a front side of the box body 20. And a door 24 for releasably closing the opening 22A.

  The door 24 is provided so as to be openable and closable with respect to the opening 22A, and is locked so as not to be opened by locking with an electric lock.

  In addition, the door 24 is provided with a loading port 26 through which a visitor can post a mail item into the accommodating portion 22 of the box body 20.

  On the upper surface 12U of the mailbox 12 (box body 20), as shown in FIG. 2, an output connector having a plurality of contact terminals for electrical connection to the mailbox 12 arranged one stage above. 32 and four positioning pins 34 for positioning the positions in the front-rear direction and the left-right direction are projected. The output connector 32 is disposed, for example, in the vicinity of the right edge and at a substantially central position in the front-rear direction. The positioning pins 34 are disposed at each of the four corners of the upper surface 12U.

  As shown in FIG. 3, the lower surface 12 </ b> B of the mailbox 12 (box body 20) has a plurality of electrical connections for electrical connection to the mailbox 12 or the relay box 14 arranged one step below. An input connector 30 having contact terminals and four positioning holes 36 for positioning the positions in the front-rear direction and the left-right direction are provided.

  The input connector 30 is embedded on the inner side of the lower surface 12B at a position opposite to the position of the output connector 32, that is, at the same position as the output connector 32 in the front-rear direction and the left-right direction. The input connector 30 can be coupled to the output connector 32 as a mechanical structure, and the contact terminals at the corresponding positions are connected to each other by coupling the input connector 30 and the output connector 32.

  Each of the four positioning holes 36 is formed at a position opposite to each of the four positioning pins 34 projecting from the upper surface 12U, and a portion protruding from the upper surface 12U of the positioning pin 34 is completely inside. It has a shape and a size to be engaged in the inserted state.

  According to the thus configured mailbox 12, four positioning pins 34 on the upper surface 12U of one of the two mailboxes 12 and four positioning holes on the lower surface 12B of the other mailbox 12 are provided. 36, when the mailboxes 12 are brought close to each other in the vertical direction, the positioning pins 34 and the positioning holes 36 are fitted, and the upper surface 12U of the lower mailbox 12 and the upper mailbox 12 are The lower surface 12B comes into contact.

  As a result, the two mailboxes 12 are arranged one above the other in a state where they are positioned at positions that coincide with the front-rear direction and the left-right direction. Further, the protruding portion from the upper surface 12U of the output connector 32 of the lower mailbox 12 enters the inner side of the input connector 30 portion of the upper mailbox 12 from the lower surface 12B, and the input connector 30 and the output connector thereof. 32 and the two mailboxes 12 are electrically connected.

  Therefore, an arbitrary number of mailboxes 12 can be arranged in the vertical direction in an arbitrary order in this manner, and the input connector 30 and the output connector 32 of the adjacent mailboxes 12 are vertically connected. Mailboxes 12 arranged in a line in the direction are electrically connected.

  The configuration of the mailbox 12 shown in FIGS. 2 and 3 is an example and may be different. For example, instead of providing the door 24 on the front side of the mail box 12, a door may be provided on the back side of the mail box 12 for picking up mails posted in the mail box 12. In this case, a space where the resident faces the door of the mailbox 12 is required on the back side of the mailbox system 10.

  Next, the schematic configuration of the relay box 14 will be described. All of the plurality of relay boxes 14 in FIG. 1 have the same configuration, and the length in the front-rear direction and the length in the left-right direction are the same as those of the mail box 12. It has a rectangular parallelepiped outer shape.

  4 and 5 are perspective views showing the relay box 14 from the upper right and lower left sides of the front side.

  As shown in these drawings, the relay box 14 is thinner in the vertical direction than the mail box 12, and a relay board, which will be described later, is accommodated therein.

  As shown in FIG. 4, the right side surface 14 </ b> R of the relay box 14 includes an output connector 52 having a plurality of contact terminals for electrical connection to the relay box 14 arranged on the right side of one row, and a front-rear direction. Two positioning pins 54 for positioning the position in the vertical direction are projected. The output connector 52 is disposed at a substantially central position in the front-rear direction, and the positioning pins 54 are disposed near the front end and the rear end.

  On the left side surface 14L of the relay box 14, an input connector having a plurality of contact terminals for electrical connection to the relay box 14 or the control box 16 arranged on the left side in a row as shown in FIG. 50 and two positioning holes 56 for positioning the positions in the front-rear direction and the vertical direction are provided.

  The input connector 50 is embedded on the inner side of the left side surface 14L at a position that is directly opposite to the position of the output connector 52, that is, at a position that is the same as the output connector 52 in the front-rear direction and the vertical direction. Further, the input connector 50 can be connected to the output connector 52 as a mechanical structure, and the contact terminals at the corresponding positions are connected by connecting the input connector 50 and the output connector 52.

  Each of the two positioning holes 56 is formed at a position opposite to each of the two positioning pins 54 protruding from the right side surface 14R, and a portion protruding from the right side surface 14R of the positioning pin 54 is completely formed. It has a shape and a size to be engaged in a state of being fitted inside.

  On the upper surface 14U of the relay box 14, as shown in FIG. 4, a branch connector 60 having a plurality of contact terminals for electrical connection to the mail box 12 arranged one step above, Four positioning pins 62 for positioning in the left-right direction are projected.

  The arrangement of the branch connector 60 and the four positioning pins 62 on the upper surface 14U matches the arrangement of the output connector 32 and the four positioning pins 34 on the upper surface 12U of the mailbox 12.

  The branch connector 60 has the same mechanical structure as the output connector 32 of the mailbox 12 and can be connected to the input connector 30 of the mailbox 12. Then, by connecting the branch connector 60 and the input connector 30 of the mailbox 12, the contact terminals at the corresponding positions are connected to each other.

  According to the relay box 14 configured in this way, two positioning pins 54 on the right side surface 14R of one relay box 14 of the two relay boxes 14 and two on the left side surface 14L of the other relay box 14 are provided. When the positions of the relay holes 14 are made close to each other by aligning the positions with the positioning holes 56, the positioning pins 54 and the positioning holes 56 are fitted, and the right side surface 14R of the left relay box 14 and the right relay box. 14 is in contact with the left side surface 14L.

  As a result, the two relay boxes 14 are arranged on the left and right in a state where the two relay boxes 14 are positioned at positions matching the front-rear direction and the vertical direction. Further, the protruding portion of the output connector 52 of the left relay box 14 from the right side 14R enters the inner side of the input connector 50 of the right relay box 14 from the left side 14L. The connector 52 is connected and the two relay boxes 14 are electrically connected.

  Therefore, an arbitrary number of relay boxes 14 can be arranged side by side in the left-right direction in this way, and one row in the left-right direction (by connection between the input connector 50 and the output connector 52 of the relay box 14 adjacent to the left and right) The relay boxes 14 arranged in the first stage are electrically connected.

  Further, the mail boxes 12 are arranged on the upper side of each relay box 14, and the positions of the four positioning pins 62 on the upper surface 14U of the relay box 14 and the four positioning holes 36 on the lower surface 12B of the mail box 12 are aligned and moved up and down. When approaching, the positioning pin 62 and the positioning hole 36 are fitted, and the upper surface 14U of the relay box 14 and the lower surface 12B of the mail box 12 come into contact with each other.

  As a result, the relay box 14 and the mail box 12 are arranged vertically in a state where they are positioned at positions that coincide with the front-rear direction and the left-right direction. Further, the protruding portion from the upper surface 14U of the branch connector 60 of the relay box 14 enters the inner side of the lower surface 12B at the input connector 30 portion of the mail box 12, and the branch connector 60 and the input connector 30 are connected. Thus, the relay box 14 and the mail box 12 are electrically connected.

  Therefore, the mailboxes 12 stacked in a plurality of stages can be arranged above each of the relay boxes 14 arranged in the left-right direction in this way, and the mailboxes 12 in each column are arranged at the lowermost stage. It is electrically connected to the relay box 14.

  In particular, since the mailboxes 12 have the same configuration, the order of arrangement may be arbitrary, and it is necessary to connect between the mailboxes 12 and between the mailboxes 12 and the relay boxes 14 using cables or the like. Therefore, complicated wiring work can be eliminated.

  Next, a schematic configuration of the control box 16 will be described.

  FIG. 6 is a perspective view of the control box 16 as viewed from diagonally above and to the right on the front side.

  As shown in the figure, the control box 16 has a rectangular parallelepiped outer diameter whose length in the front-rear direction is the same as that of the mail box 12, and various information is input to the front face 16F or various information is stored. An IC card reader 82 for reading information on the operation panel 80 and the IC card to be displayed is provided.

  On the right side surface 16R of the control box 16, an output connector 90 having a plurality of contact terminals for electrical connection to the relay box 14 arranged on the right side, and positions in the front-rear direction and the up-down direction are positioned. Two positioning pins 92 are projected.

  The positional relationship between the output connector 90 and the two positioning pins 92 matches the positional relationship between the output connector 52 and the two positioning pins 54 on the right side surface 14 </ b> R of the relay box 14.

  The output connector 90 has the same mechanical structure as the output connector 52 of the relay box 14 and can be connected to the input connector 50 of the relay box 14. Then, by connecting the output connector 90 of the control box 16 and the input connector 50 of the relay box 14, the contact terminals at the corresponding positions are connected to each other.

  According to the control box 16 configured as described above, the relay box 14 is disposed on the right side of the control box 16, the two positioning pins 92 on the right side surface 16 </ b> R of the control box 16, and 2 on the left side surface 14 </ b> L of the relay box 14. When the positions of the two positioning holes 56 are adjusted to approach each other in the left-right direction, the positioning pins 92 and the positioning holes 56 are fitted, and the left side surface 14L of the relay box 14 abuts on the right side surface 16R of the control box 16.

  Thus, the control box 16 and the relay box 14 are arranged on the left and right in a state where they are positioned in a predetermined positional relationship in the front-rear direction and the up-down direction. Further, the protruding portion of the output connector 90 of the control box 16 from the right side surface 16R enters the inner side of the input connector 50 of the relay box 14 from the left side surface 14L, and the output connector 90 and the input connector 50 are connected to each other. The control box 16 and the relay box 14 are electrically connected by being connected.

  Therefore, the control box 16 can be arranged side by side on the left side of the leftmost relay box 14 among the relay boxes 14 arranged side by side in the left-right direction, and the control box 16 is electrically connected to the relay box 14. A control box 16 is electrically connected to the mailboxes 12 at each stage in each row via the relay box 14.

  The control box 16 mainly controls the locking and unlocking (locking / unlocking) of the mail box 12. For example, a resident has an IC card in which a unique ID code is stored. When the ID card is set (contacted) on the IC card reader 82, the control box 16 reads the ID code of the IC card by the IC card reader 82. Then, the electric lock of the mailbox 12 corresponding to the ID code is set to the unlocked state. Thereby, the resident can open the door 24 of his / her mailbox 12 and can take out the mail in the mailbox 12.

  Further, the control box 16 locks the electric lock so that the door 24 does not open when a certain time elapses from the unlocking or when the IC card is set in the IC card reader 82 again. .

  Next, an internal configuration relating to wiring of the mailbox system 10 will be described.

  FIG. 7 is a system configuration diagram showing an internal configuration of wiring of the mailbox system 10.

  As shown in the figure, the control box 16 is equipped with a control unit 100 for comprehensively controlling the entire system. An operation panel 80 and an IC card reader 82 provided in the control box 16 are connected to the control unit 100, and the control unit 100 displays various types of information on the operation panel 80 and also uses the operation panel 80 and the IC card reader 82. Various processes are performed according to the acquired information.

  The control unit 100 is a horizontal relay board 102 that relays a signal from the control unit 100, and a plurality of horizontal relay boards 102 of the same configuration mounted in each of the above-described relay boxes 14 connect between them. They are connected in series via the signal line group Lh having the same configuration.

  Here, in the mailbox system 10 of FIG. 1, the column number of the column in which the relay box 14 directly connected to the control box 16 is arranged is 1 (first column), and one column (right side in FIG. 1) The column number is incremented by 1 every time the column is shifted to (). In addition, the stage number of the stage (or row) where the relay box 14 is arranged is set to 0 (0th stage), and the stage number is incremented by 1 each time a stage is moved up one level. The position of the a-th row in the b-th row is represented by (a, b). a represents an arbitrary integer of 0 to m, b represents an arbitrary integer of 1 to n, m represents the number of stages in which the mailboxes 12 are arranged (the uppermost stage number), and n represents the mailbox 12 Indicates the number of columns arranged (column number in the rightmost column). Note that m may be a value that differs depending on the column, that is, a value that changes according to b.

  At this time, when distinguishing components having the same configuration represented by the same reference numerals, the reference numerals (a, b) indicating the positions are attached to the reference numerals. For example, 102 (0, 1), 102 (0, 2),..., 102 (in order from those directly connected to the control unit 100 of the control box 16 are arranged on the horizontal relay board 102 having the same configuration in FIG. 0, n), and Lh (0, 1), Lh (0, 2),..., Lh (0, n) are attached to the signal line group Lh having the same configuration based on the position of the connection destination. doing.

  Each of the horizontal relay boards 102 (0, b) is a vertical relay board 104 that relays signals, and a plurality of vertical relay boards 104 (104) of the same configuration mounted on each of the mailboxes 12 in the b-th column. (1, b) to 104 (m, b)) are connected in series via a signal line group Lv (Lv (1, b) to Lv (m, b)) that connects them.

  A circuit unit 106 (106 (a, b)) mounted on the mail box 12 is connected to each of the vertical relay boards 104 (a, b). The circuit unit 106 indicates an arbitrary circuit provided in the mailbox 12, and for example, whether or not voltage (and current) is supplied from the control unit 100 such as an electric lock, LED, sensor, or the voltage of the supplied voltage. A circuit whose state changes depending on a value or the like is shown.

  Although details are omitted, for example, the electric lock includes a solenoid actuator including an electromagnetic coil (solenoid) and a plunger (movable iron core) that is movable by magnetism generated by the electromagnetic coil. Then, the plunger moves to a different position depending on whether or not voltage is supplied from the control unit 100 to the electromagnetic coil, and the door 24 of the mail box 12 is locked and unlocked.

  In such a system configuration, a configuration of a signal line for the control unit 100 to individually supply a voltage to the circuit unit 106 of each mailbox 12 will be described.

  First, the configuration of the signal line group Lh will be described. FIG. 8 shows a connection between the control unit 100 of the control box 16 and the horizontal relay board 102 (0, 1) of the relay box 14 (0, 1) in the first row. The signal line group Lh (0, 1) to be performed is shown.

  As shown in the figure, the control unit 100 has a total of M + N connection terminals including connection terminals x (1) to x (M) and connection terminals y (1) to y (N). M indicates the maximum number of columns of the mailbox 12 that can be controlled by the control box 16, and N indicates the maximum number of columns of the mailbox 12 that can be controlled by the control box 16. Since M and N are numbers determined in the design stage, the mail is so set as to satisfy the condition that the number m of the mailboxes 12 in the mailbox system 10 in FIG. 1 is M or less and the number of columns n is N or less. Boxes 12 are arranged.

  The control unit 100 is connected between the connection terminal x (a) of the connection terminals x (1) to x (M) and the connection terminal y (b) of the connection terminals y (1) to y (N). Only by generating a potential difference, that is, in the control unit 100, the connection terminal x (a) and the connection terminal y (b) are made conductive through the power supply, and the other connection terminals are made non-conductive. Thus, a predetermined voltage is supplied only to the circuit unit 106 (a, b), for example, only the mailbox 12 (a, b) is unlocked.

  Further, the control unit 100 is configured to detect a current flowing through each of the connection terminals x (1) to x (M) or the connection terminals y (1) to y (N) (each circuit unit 106 (1, 1). ) To 106 (m, n), and a current difference is generated between the connection terminal x (a) and the connection terminal y (b). When the current flowing through the connection terminals is not detected by the detection means (when the detected current is equal to or less than a predetermined threshold), it is determined that an abnormality such as disconnection has occurred, and predetermined warning means (to the operation panel 80) Warning display, warning lamp lighting, warning sound, etc.).

  The connection terminals x (1) to x (M) and y (1) to y (N) are connected to the contact terminals of the output connector 90 (see FIG. 6) not shown in the figure in the control box 16. Connected through.

  On the other hand, as illustrated as a part of the horizontal relay board 102 (0, 1) of the relay box 14 (0, 1) in FIG. A total of M + N connection terminals including terminals cx (1) to cx (M) and connection terminals cy (1) to cy (N) are provided. The connection terminals cx (1) to cx (M) and cy (1) to cy (N) of the terminal portion c are contacts of the input connector 50 (see FIG. 5) not shown in the figure in the relay box 14. It is connected to the terminal via a signal line.

  Then, by connecting the output connector 90 of the control box 16 and the input connector 50 of the relay box 14 (0, 1), the respective connection terminals x (1) to x (M), y (1) to y of the control unit 100. (N) and the connection terminals cx (1) to cx (M) and cy (1) to cy (N) of the terminal portion c in the horizontal relay substrate 102 (0, 1) are signal lines hx (1). ~ Hx (M) and hy (1) ~ hy (N).

  The signal lines hx (1) to hx (M) connected to the connection terminals x (1) to x (M) of the control unit 100 are referred to as horizontal signal lines, and the values 1 to M in parentheses are horizontal. The line number in the signal line shall be indicated. The signal lines hy (1) to hy (N) connected to the connection terminals y (1) to y (N) of the control unit 100 are referred to as vertical signal lines, and the values 1 to N in parentheses are vertical. The line number in the signal line shall be indicated.

  FIG. 9 shows a signal line group Lh (0, b) connecting between the horizontal relay boards 102 of the two adjacent relay boxes 14, and the horizontal relay board 102 of the bth relay box 14 (0, b). A signal line group Lh (0, b) connecting between (0, b) and the horizontal relay board 102 (0, b-1) of the relay box 14 (0, b-1) in the b-first row. Show.

  In the same figure, as illustrated as a part of the horizontal relay board 102 (0, 1) of the relay box 14 (0, b), the horizontal relay board 102 of the relay box 14 has the terminal portion c as described above. A total of M + N connection terminals including connection terminals cx (1) to cx (M) and connection terminals cy (1) to cy (N) are provided.

  On the other hand, as illustrated as a part of the horizontal relay board 102 (0, b-1) of the relay box 14 (0, b-1) in FIG. As a result, a total of M + N connection terminals including connection terminals dx (1) to dx (M) and connection terminals dy (1) to dy (N) are provided. The connection terminals dx (1) to dx (M) and dy (1) to dy (N) of the terminal portion d are connected to the output connector 52 (see FIG. 4) not shown in FIG. It is connected to the terminal via a signal line.

  Then, by connecting the output connector 52 of the relay box 14 (0, b-1) and the input connector 50 of the relay box 14 (0, b), the terminal portion d of the horizontal relay board 102 (0, b-1). Each connection terminal dx (1) to dx (M), dy (1) to dy (N), and each connection terminal cx (1) to cx (M) of the terminal portion c in the horizontal relay substrate 102 (0, b) , Cy (1) to cy (N) are connected by horizontal signal lines hx (1) to hx (M) and vertical signal lines hy (1) to hy (N) as in FIG.

  Next, the configuration of the signal line group Lv will be described. FIG. 10 shows the horizontal relay board 102 (0, b) of the relay box 14 (0, b) in the b-th row and the first-stage mail in the b-th row. A signal line group Lv (1, b) connecting the vertical relay substrate 104 (1, b) of the box 12 (1, b) is shown.

  As illustrated as a part of the horizontal relay board 102 (0, b) of the relay box 14 (0, b) in the figure, the horizontal relay board 102 of the relay box 14 has a connection terminal ex ( A total of M + 1 connection terminals including 1) to ex (M) and the connection terminal ey (1) are provided. Each connection terminal ex (1) to ex (M), ey (1) of the terminal portion e is connected to each contact terminal of a branch connector 60 (see FIG. 4) not shown in the figure in the relay box 14. Connected through.

  On the other hand, as illustrated as a part of the vertical relay board 104 (1, b) of the mailbox 12 (1, b) in FIG. A total of M + 1 connection terminals including terminals px (1) to px (M) and connection terminal py (1) are provided. The connection terminals px (1) to px (M) and py (1) of the terminal portion p are connected to the contact terminals of the input connector 30 (see FIG. 3) not shown in the figure in the mailbox 12. Connected through.

  Then, by connecting the branch connector 60 of the relay box 14 (0, b) and the input connector 30 of the mail box 12 (1, b), the connection terminals ex (1) ˜ ex (M), ey (1) and the connection terminals px (1) to px (M), py (1) of the terminal portion p of the vertical relay substrate 104 (1, b) are connected to the horizontal signal line vx ( 1) to vx (M) and the vertical signal line vy (1).

  FIG. 11 shows a signal line group Lv (a, b) connecting between the vertical relay boards 104 of two adjacent mailboxes 12, and the a-1st mailbox 12 (a-1) in the b-th column. , B) and the vertical relay board 104 (a, b) of the a-th mailbox 12 (a, b) in the b-th row. A line group Lv (a, b) is shown.

  As illustrated as a part of the vertical relay board 104 (a, b) of the mailbox 12 (a, b) in the figure, the vertical relay board 104 of the mailbox 12 has the terminal portion p as described above. A total of M + 1 connection terminals including connection terminals px (1) to px (M) and connection terminal py (1) are provided.

  On the other hand, as illustrated as a part of the vertical relay board 104 (a-1, b) of the mailbox 12 (a-1, b) in FIG. As a result, a total of M + 1 connection terminals including connection terminals qx (1) to qx (M) and connection terminal qy (1) are provided. The connection terminals qx (1) to qx (M), qy (1) of the terminal portion q are connected to the contact terminals of the output connector 32 (see FIG. 2) not shown in the figure in the mailbox 12. Connected through.

  Then, by connecting the output connector 32 of the mailbox 12 (a-1, b) and the input connector 30 of the mailbox 12 (a, b), the terminal portion p of the vertical relay board 104 (a-1, b) is connected. Each connection terminal px (1) to px (M), py (1) and each connection terminal qx (1) to qx (M), qy (1) of the terminal portion q in the vertical relay substrate 104 (a, b). Are connected via the horizontal signal lines vx (1) to vx (M) and the vertical signal line vy (1) as in FIG.

  Next, the configuration of the horizontal relay substrate 102 will be described. FIG. 12 is a configuration diagram showing the b-th row of horizontal relay boards 102 (0, b) as the horizontal relay board 102 at an arbitrary position.

  As shown in the figure, the above-described terminal portion c, terminal portion d, and terminal portion e are provided on the horizontal relay substrate 102 (0, b).

  The terminal portion c has (M + N) connection terminals including connection terminals cx (1) to cx (M) and cy (1) to cy (N), and each of the connection terminals cx (1) to cx. (M), cy (1) to cy (N) include horizontal signal lines hx (1) to hx (M) and vertical signal lines hy (1) to hy in the signal line group Lh (0, b). (N) is connected.

  The terminal portion d has (M + N) connection terminals including connection terminals dx (1) to dx (M) and dy (1) to dy (N), and each of the connection terminals dx (1) to dx. (M), dy (1) to dy (N) include horizontal signal lines hx (1) to hx (M) and vertical signal lines hy (1) to hy in the signal line group Lh (0, b + 1). (N) is connected.

  The terminal portion e has (M + 1) connection terminals including connection terminals ex (1) to ex (M) and ey (1), and each of the connection terminals ex (1) to ex (M) and ey. The horizontal signal lines vx (1) to vx (M) of the signal line group Lv (1, b) and the vertical signal line vy (1) are connected to (1).

  On the horizontal relay board 102 (0, b), the connection terminals dx (1) to dx (N) of the terminal part d are signals of the connection terminals cx (1) to cx (M) of the terminal part c. They are connected via lines ix (1) to ix (M).

  In addition, the connection terminals cy (2) to cy (N) of the terminal portion c are connected to the connection terminals dy (1) to dy (N-1) of the terminal portion d of the signal lines iy (2) to iy (N). ).

  According to this, each horizontal signal line hx (1) to hx (M) in the signal line group Lh (0, b) is equal to each horizontal signal line hx having the same line number in the signal line group Lh (0, b + 1). (1) to hx (M) are connected as they are.

  Also, the vertical signal lines hy (2) to hy (N) in the signal line group (0, b) are the vertical signal lines hy (1) each having a smaller line number by 1 in the signal line group Lh (0, b + 1). To hy (N-1).

  On the other hand, on the horizontal relay board 102 (0, b), the signal lines jx (1) to jx (M) are branched from the signal lines ix (1) to ix (M), and the connection terminals ex of the terminal portion e are connected. (1) to ex (M). Accordingly, the connection terminals cx (1) to cx (M) of the terminal part c are also connected to the connection terminals ex (1) to ex (M) of the terminal part e.

  In addition, the connection terminal ey (1) of the terminal portion e is connected to the connection terminal cy (1) of the terminal portion c via the signal line iy (1).

  According to this, the horizontal signal lines hx (1) to hx (M) in the signal line group Lh (0, b) are the horizontal signal lines vx having the same line number in the signal line group Lv (1, b). (1) to vx (M).

  The vertical signal line hy (1) in the signal line group Lh (0, b) is connected to the vertical signal line vy (1) having the same line number in the signal line group Lv (1, b).

  Next, the configuration of the vertical relay substrate 104 will be described. FIG. 13 is a configuration diagram showing the a-stage vertical relay board 104 (a, b) in the b-th row as the vertical relay board 104 at an arbitrary position.

  As shown in the figure, the vertical relay substrate 104 (a, b) is provided with the terminal part p and terminal part q described above and a terminal part r connected to the circuit part 106 (a, b).

  The terminal portion p has (M + 1) connection terminals including connection terminals px (1) to px (M) and py (1), and each of the connection terminals px (1) to px (M) and py. (1) is connected to the horizontal signal lines vx (1) to vx (M) and the vertical signal line vy (1) of the signal line group Lv (a, b).

  The terminal part q has (M + 1) connection terminals including connection terminals qx (1) to qx (M) and qy (1), and each of the connection terminals qx (1) to qx (M), qy. (1) is connected to the horizontal signal lines vx (1) to vx (M) and the vertical signal line vy (1) of the signal line group Lv (a + 1, b).

  The terminal part r has two connection terminals including connection terminals rx (1) and ry (1), and the connection terminals rx (1) and ry (1) are connected to the circuit part 106 in the mailbox 12. Two terminals for supplying a voltage (power supply) necessary for the operation (a, b) are connected via a signal line.

  On the vertical relay substrate 104 (a, b), the connection terminals px (1) to dx (M-1) of the terminal part q are connected to the connection terminals px (2) to px (M) of the terminal part p. The signal lines fx (2) to fx (M) are connected to each other.

  Further, the connection terminal qy (1) of the terminal portion q is connected to the connection terminal py (1) of the terminal portion p via the signal line fy (1).

  According to this, each horizontal signal line vx (2) to vx (M) in the signal line group Lv (a, b) is equal to each horizontal signal line having a smaller line number by 1 in the signal line group Lv (a + 1, b). vx (1) to vx (M-1) are connected.

  The vertical signal line vy (1) in the signal line group Lv (a, b) is connected to the vertical signal line vy (1) having the same line number in the signal line group Lv (a + 1, b).

  On the other hand, on the vertical relay substrate 104 (a, b), the connection terminal rx (1) of the terminal part r is connected to each connection terminal px (1) of the terminal part p via the signal line fx (1). The

  The signal line gy (1) is branched from the signal line fy (1) and connected to the connection terminal ry (1) of the terminal r. Accordingly, the connection terminal py (1) of the terminal part r is also connected to the connection terminal py (1) of the terminal part p.

  According to this, the horizontal signal line vx (1) and the vertical signal line vy (1) in the signal line group Lv (a, b) are connected to the circuit unit 106 (a, b).

  According to the signal line configuration of the mailbox system 10 described above, one of the two terminals that supplies a voltage to the circuit unit 106 (a, b) of the mailbox 12 (a, b) at an arbitrary position. Includes a horizontal signal line hx (a) in the signal line group Lh (0,1) to Lh (0, b) and a horizontal signal line vx in the signal line group Lv (1, b) to Lv (a, b). The connection terminal x (a) of the control unit 100 is connected via (a), vx (a-1),..., Vx (1). Further, the other terminal for supplying a voltage to the circuit unit 106 (a, b) is connected to the vertical signal lines hy (b), hy (b−) in the signal line groups Lh (0, 1) to Lh (0, b). 1),..., Hy (1) and the vertical signal line vy (1) in the signal line group Lv (1, b) to Lv (a, b) via the connection terminal y (b ) Is connected.

  That is, one terminal of the circuit units 106 (a, 1) to 106 (a, n) of the a-th mailboxes 12 (a, 1) to 12 (a, n) is connected to the connection terminal x of the control unit 100. (A) is connected, and the other terminals of the circuit units 106 (1, b) to 106 (m, b) of the mailboxes 12 (1, b) to 12 (m, b) in the b-th column are connected to the control unit. A matrix wiring to which 100 connection terminals y (b) are connected is configured.

  Therefore, as described above, the control unit 100 connects the connection terminal x (a) of the connection terminals x (1) to x (M) and the connection terminal y (of the connection terminals y (1) to y (N). By generating a potential difference only with respect to b), a voltage is supplied only to the circuit section 106 (a, b) of the mailbox 12 (a, b), and the solution of the mailbox 12 (a, b) is restored. Controls such as locks can be performed individually.

  As mentioned above, although the system which controls the mailbox 12 was demonstrated in the said embodiment, this invention is not only a mailbox, but the delivery box which has an electric lock etc. which locks and unlocks a door which can be opened and closed, and private. The storage box may be of any type such as a box, and can be applied to a system that controls the electric lock.

  Lh, Lv: Signal line group, x (1) to x (M), y (1) to y (N), cx (1) to cx (M), cy (1) to cy (N), dx ( 1) to dx (M), dy (1) to dy (N), ex (1) to ex (M), ey (1), px (1) to px (M), py (1), qx ( 1) to qx (M), qy (1), rx (1), ry (1) ... connection terminal, hx (1) to (M) ... horizontal signal line, hy (1) to hy (N) ... vertical Signal lines, ix (1) to ix (M), iy (1) to iy (N), jx (1) to j (M), fx (1) to fx (M), fy (1), gy ( 1) Signal line, c, d, e, p, q, r ... Terminal part, 10 ... Mailbox system, 12 ... Mailbox, 14 ... Relay box, 16 ... Control box, 20 ... Box body, 24 ... Door 26 ... Box, 30, 50 ... Input connector, 32, 52, 90 ... Output connector, 34, 54, 62, 92 ... Positioning pin, 36, 56 ... Positioning hole, 60 ... Branch connector, 80 ... Operation panel, 82 ... IC Card reader, 100 ... control unit, 102 ... horizontal relay board, 104 ... vertical relay board, 106 ... circuit part

Claims (4)

A storage box system for individually controlling a plurality of storage boxes of the same configuration connected in series to the control unit by a signal line group;
Each of the storage boxes
For connecting a signal line group composed of 1st to Mth horizontal signal lines and one vertical signal line between the front box and the rear box, where M is a positive integer. A first connector and a second connector, which are directly connected to the second connector of the front-stage storage box when the storage boxes are arranged in a line, and directly to the first connector of the rear-stage storage box A second connector to be coupled;
Of the signal line group connected via the first connector, the first horizontal signal line and the vertical signal line are connected to an internal circuit unit, and the second to Mth horizontal signal lines and vertical signal lines are connected. A relay unit for connecting the first to M-1 horizontal signal lines and the vertical signal lines of the signal line group connected via the second connector;
Equipped with a,
The plurality of storage boxes are connected in series to each of the plurality of relay boxes connected in series to the control unit,
Each of the relay boxes is
A signal line group consisting of No. 1 to No. N vertical signal lines and No. 1 to No. M horizontal signal lines, where N is a positive integer, between the preceding relay box and the subsequent relay box. A third connector and a fourth connector to be connected with each other, wherein when the relay boxes are arranged in a line, the third connector directly connected to the fourth connector of the preceding relay box and the relay box of the latter A fourth connector directly connected to the third connector;
A fifth connector for connecting a signal line group composed of No. 1 to No. M horizontal signal lines and one vertical signal line to a storage box, and when the storage box is disposed adjacent to the relay box A fifth connector directly connected to the first connector of the storage box;
Among the signal line groups connected via the third connector, the 1st to Mth horizontal signal lines are connected to the 1st to Mth horizontal lines of the signal line group connected via the fourth connector. A signal line is connected to the 1st to Mth horizontal signal lines of the signal line group connected via the fifth connector, and the 2nd to Nth vertical signal lines are connected to the fourth connector. Are connected to No. 1 to N-1 vertical signal lines of the signal line group connected via the first connector, and the No. 1 vertical signal line is connected to the No. 5 signal line group via the fifth connector. A second relay unit connected to one vertical signal line,
A plurality of the storage boxes are arranged in series in the vertical direction,
A storage box system in which a plurality of relay boxes are arranged in series in the horizontal direction . The storage box system according to claim 1, wherein the storage box is a mail box, a delivery box, or a private box. Wherein the control unit accommodating box system according to claim 1 or 2 for controlling the electric lock of the storage box. The said control part is a storage box system of any one of Claims 1-3 which judges abnormality based on the electric current which flows into the circuit part of the said storage box.

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