JP2011131016A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily find a fraudulent act to a board box. <P>SOLUTION: Sealing is completed by inserting a sealing pin in a cylindrical body of a first box 200A of the board box and locking a locking nail of the sealing pin on a base device located on the rear side or a locking hole of a second box. A cylindrical body 500 includes a cylinder hole 502 where the sealing pin is inserted. A cylindrical body 510 includes a cylinder hole 512 corresponding to an outer diameter of the cylindrical body 500. A cylindrical body 520 includes a cylinder hole 522 corresponding to an outer diameter of the cylindrical body 510. An adhesive is applied between the sealing pin and the cylinder hole at the time of sealing. As a result, the outer diameter of the sealing pin expands every time the sealing is removed by cutting the cylindrical body off the first box since the cylindrical body firmly adheres, and the sealing pin fits in the cylinder hole of the cylindrical body of the next step. If the sealing pin obtained by breaking the other board box is used for sealing a newly forged board box, the sealing pin is not inserted in the same cylindrical body as the one before unsealing since the outer diameter has expanded, and needs to be used for the other cylindrical body. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a slot machine and other gaming machines.

  For example, in a slot machine of a gaming machine, the housing is a gaming surface provided with a box-shaped housing body having an opening on the front side, and the front side closed with an effect display surface, an operation lever, etc. It consists of a front door. A display window is provided on the front door, a reel is installed in the casing body so as to be visible from the display window, and a drive mechanism, a power source and the like are also installed in the casing body. Further, a control board for electronically controlling game contents and effect processing is installed in the casing body together with a reel and the like.

The control board is also equipped with a memory that stores data that defines the game content program and the conditions for generating jackpots, so you can replace the memory or the entire control board, or add or change additional memory. , Fraudulent activities such as frequent jackpots and a large amount of coins become a problem.
For this reason, a locking mechanism that closes the front door and locks it in cooperation with the housing body side is provided, but this alone is insufficient to prevent fraud, and breaks the locked state to the control board. There are frequent cases of unauthorized changes.

Therefore, if a fraudulent act such as storing the control board in a board box and sealing it and opening the board box is made, the trace remains and the control board may have been tampered with. Can be exchanged for a regular one.
On the other hand, since the control board may be regularly inspected and replaced, it is desirable that sealing can be performed multiple times.

As a means for realizing such an aim, there is a game machine box sealing tool previously proposed by the present applicant in Japanese Patent Laid-Open No. 10-314414.
This sealing tool is provided in a substrate box composed of a box main body and a box lid, and has a plurality of sealing portions. Each sealing portion includes a first sealing member disposed on one of the box body or the box lid, a second sealing member disposed on the other, a locking hole provided in the first sealing member, and an engagement thereof. A locking claw that is locked to the locking hole and a sealing metal fitting having a head that is engaged with the second sealing member, the head of the sealing metal fitting being engaged with the second sealing member, and the locking hole Thus, the locking claw of the sealing metal fitting is locked to connect the first sealing member and the second sealing member to seal the substrate box.

When a sealing metal fitting is set for each sealing part and a board box containing a control board is installed for the first time, one sealing part is connected to the first sealing member and the second sealing member as described above. Sealing is performed, and the other sealing portions are in an unconnected state, and the sealing metal fitting is configured to be held on one of the first sealing member and the second sealing member.
As a result, if the board box is opened improperly, there will always be a trace of destruction on either the first sealing member or the second sealing member. Recognize that an action has been performed.

  Even when the board box is properly opened for inspection and replacement of the control board, the sealed portion connecting the first sealing member and the second sealing member is destroyed, but other parts remaining after the inspection and replacement are completed. One of the sealing portions can be sealed a plurality of times by connecting and sealing the first sealing member and the second sealing member with a sealing metal fitting and sequentially repeating this.

JP-A-10-314414

However, in the above-described conventional sealing structure, the second sealing member of the box lid body is destroyed from one substrate box, and the box body is held on the first sealing member in a state where there is no evidence of destruction, while the other The first sealing member of the box body can be destroyed from the substrate box, and the box lid can be secured together with the sealing fitting in a state where the second sealing member has no trace of destruction.
As a result, a new board box containing a control board with an unauthorized change inside is created using the box body and the box lid body having the first and second sealing members, both of which have no trace of destruction. If this is replaced with the control board and the board box in the slot machine housing, there is a possibility that no trace will be obtained despite the illegal act.

  Therefore, in view of the above-described problem, the present invention provides a gaming machine that can easily know that a board box has been opened illegally regardless of whether the board box has a trace of destruction. The purpose is to provide.

According to the present invention, the first member and the second member that are coupled to overlap each other are disposed with their coupling states sealed by the sealing coupling member, and the first member and the second member are used by using the sealing coupling member. In a gaming machine configured so that two members can be resealed, a first member sealing portion provided on the first member and connected to a peripheral portion of the first member by a connecting portion, and a second member provided on the second member A seal part is formed with a two-member seal part,
The seal connecting member connects and seals the first member sealing portion and the second member sealing portion, and the shape thereof changes before and after the seal is released.

As the change of the shape, it is preferable that the outer shape of the seal connecting member is enlarged.
In particular, when the sealing connecting member is a sealing pin and the first member sealing portion is a cylindrical body through which the sealing pin is inserted, the sealing pin is fixed to the cylindrical body at the time of sealing, thereby connecting the peripheral portion to the peripheral portion. After removing the seal and releasing the seal, the outer diameter can be increased by the amount of the cylindrical body.

  According to the present invention, since the shape of the seal connecting member is changed even if it is attempted to obtain and use the seal connecting member used for sealing the other first member and the second member illegally, It can be easily determined by visual recognition whether it is a thing, and since it cannot be applied to the same sealing part in the 1st member and the 2nd member which are obtained illegally, an illegal act can be prevented.

  In particular, when the sealing connecting member is a sealing pin and the first member sealing portion is a cylindrical body, the sealing pin can be easily expanded by simply inserting the sealing pin into the cylindrical body and fixing it when releasing the normal sealing. Can be taken out.

1 is an overall perspective view of a slot machine to which the present invention is applied. It is a front view inside the slot machine shown with the front door removed. It is a front view of a main board unit. It is a side view of a main board unit. It is a disassembled perspective view of a base apparatus. It is a perspective view which shows the back surface of a fixed base part. It is sectional drawing which shows the structure of a rotating shaft part edge part. It is sectional drawing which shows the structure around the window hole in a movable base part. It is a disassembled perspective view of a main controller. It is an expansion perspective view of the overhang | projection part of the main board | substrate. It is a figure which shows the structure of a rail formation part. It is a perspective view which shows the back surface of a 1st box. It is a figure which shows the sealing member of a 1st box. It is a figure which shows the sealing member of a 2nd box. It is a disassembled perspective view of a sealing pin. It is a figure which shows a sealing pin. It is a figure which shows a sealing pin. It is a figure which shows the sealing process of a sealing part. It is a circuit diagram of a light emitting unit. It is a flowchart which shows the flow of lighting color control. It is a front view of the main board | substrate unit in a 2nd Example. It is a disassembled perspective view of a base apparatus. It is a disassembled perspective view of a main controller. It is a perspective view which shows the back surface of a 1st box. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is a disassembled perspective view of a sealing pin. It is a figure which shows a 1st pin. It is a figure which shows a 2nd pin. It is a figure which shows the seal | sticker coupling | bonding state of a 1st seal part. It is a figure which shows the 1st pin of the sealing pin released from the 1st sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 2nd seal part. It is a figure which shows the 1st pin of the sealing pin released from the 2nd sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 3rd seal part. It is an enlarged view which shows the seal part periphery of the 1st box in a 3rd Example. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is a figure which shows a sealing block part. It is a figure which shows the seal | sticker coupling | bonding state of a 1st seal part. It is a figure which shows the 1st pin of the sealing pin released from the 1st sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 2nd seal part. It is a figure which shows the 1st pin of the sealing pin released from the 2nd sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 3rd seal part. It is a figure which shows the sealing pin in a 4th Example. It is an enlarged view showing the circumference of the seal part of the 1st box in the 4th example. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is a figure which shows a sealing block part. It is a figure which shows the seal | sticker coupling | bonding state of a 1st seal part. It is a figure which shows the sealing pin which removed the outer side pin member after releasing from a 1st sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 2nd seal part. It is a figure which shows the sealing pin which removed the outer side pin member after releasing from a 2nd sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 3rd seal part. It is a perspective view which shows the sealing pin in a 5th Example. It is a figure which shows the detail of a sealing pin. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the seal part periphery of a 1st box. It is an enlarged view which shows the surroundings of the sealing part of a 2nd box. It is a front view which shows a sealing block part. It is a figure which shows the seal | sticker coupling | bonding state of a 1st seal part. It is a figure which shows the sealing pin after releasing from a 1st sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 2nd seal part. It is a figure which shows the sealing pin after releasing from a 2nd sealing part. It is a figure which shows the seal | sticker coupling | bonding state of a 3rd seal part.

  Next, an embodiment in which the present invention is applied to a slot machine will be described.

First, the first embodiment will be described.
1 is an overall perspective view of the slot machine, and FIG. 2 is an internal front view with the front door removed.
The casing of the slot machine 1 is composed of a box-shaped casing main body 2 that opens on the front side, and a front door 3 that closes the opening.
The housing body 2 includes a top plate 2a, a bottom plate 2b, a back plate 2c, a left side plate 2d, and a right side plate 2e.
The front door 3 is attached to the housing main body 2 by hinges at upper and lower portions on the left end side, swings horizontally around the hinge, and can open and close the opening of the housing main body 2.
A locking mechanism 4 is provided at the right end of the front door 3 to close the front door 3 in a locked state in cooperation with the housing body 2 side.
On the front side of the front door 3, a gaming panel 5 having a plurality of display windows 6, a coin insertion slot 7, various operation levers and buttons, an operation unit 8 having switches, a coin tray 9, and other effect display units 10 are provided. It is a known game side provided. Details of these are disclosed in, for example, Japanese Patent Application Laid-Open No. 2008-61739.

The inside of the housing body 2 is divided into two vertically by a partition plate 2f.
A hopper device 11 including a storage tank that stores coins and a payout device that pays out coins to the coin tray 8 of the front door 3 and a power supply box 12 are disposed below the partition plate 2f.
Coins inserted from the coin insertion slot 7 of the front door 3 are supplied to the hopper device 11 and stored in a storage tank or discharged to a coin tray 9.
A reel unit 15 is mounted on the upper part of the partition plate 2f. The reel unit 15 supports the reels 14 arranged side by side in a one-to-one correspondence with the display windows 6 of the front door 3 so as to be rotatable on the same axis. .
Above the reel unit 15, a main board unit 20 for controlling the slot machine is mounted on the back plate 2c.

Hereinafter, the configuration of the main board unit 20 will be described in detail.
3 is a front view of the main board unit, FIG. 4 is a side view, and FIG. 5 is an exploded perspective view of the pedestal device.
Unless otherwise specified, the right side in the figure is the right side of the main board unit 20, the left side in the figure is the left side of the main board unit 20, and the near side in the figure is the front side of the main board unit 20, unless otherwise specified. The rear side in the figure will be described as the rear side of the main board unit 20. The same applies to other embodiments.
The main board unit 20 includes a main control device 22 and a pedestal device 25 that supports the main control device on the housing body 2. The main control device 22 controls game contents and effect processing.

The pedestal device 25 is tilted by rotating up and down about a fixed base portion 26 fixed to the back plate 2c of the housing body 2 and a rotation center axis Z supported horizontally by the fixed base portion 26 and extending horizontally. And a movable base portion 28 that can be taken.
The main control device 22 is held by the movable base portion 28, and is slid in a direction (upward) perpendicular to the rotation center axis Z from the holding position shown in FIGS. It can be removed from.

As shown in FIG. 9 to be described later, the main controller 22 is housed in the horizontally long rectangular board box 30 constituted by a pair of front and back first boxes 200 and second boxes 300, and the board box 30. And a flat main substrate 23.
The first box 200 and the second box 300 are formed of a transparent or translucent resin.
By placing the movable base portion 28 holding the main control device 22 in the standing posture shown in FIG. 4A, the substrate box 30 is parallel to the back plate 2c, and the surface of the internal main substrate 23 is While it becomes visible from the front side of the casing body 2, the board box 30 is also tilted toward the front side of the casing body 2 by setting the movable base portion 28 to the tilting posture shown in FIG. The back surface of the main board 23 is configured to be visible.

First, the fixed base portion 26 of the pedestal device 25 will be described with particular reference to FIG.
The fixed base portion 26 is a press-formed product of a metal plate, and is a horizontally long rectangular flat bottom plate portion 40, and a mounting flange portion 42 that extends outward from the left and right after being offset backward from both ends in the width direction (left and right direction) of the bottom plate portion 40. Have
The mounting flange portion 42 is parallel to the surface of the bottom plate portion 40, extends over the bottom plate portion 40, and has a hole 43 through which a screw for attaching to the back plate 2c is inserted.

A posture holding member 56 for holding the movable base portion 28 in a standing posture position by locking the upper portion of the movable base portion 28 is attached to the upper portions of both ends in the width direction of the bottom plate portion 40.
The posture holding member 56 is made of a synthetic resin having flexibility, and is inserted into a mounting hole formed in the bottom plate portion 40 from behind to extend forward of the bottom plate portion 40, and has a claw 57 at the tip.
The bottom plate portion 40 is formed with a cutout portion 44 cut out in a rectangular shape from the upper end thereof. The notch 44 extends substantially over the entire width in the left-right direction of the bottom plate 40 to the position where the posture holding member 56 is attached.

FIG. 6 is a perspective view of the fixed base portion 26 viewed from the back.
From the horizontal lower side of the notch portion 44, an attachment flange portion 46 that is folded back toward the back surface side of the rear bottom plate portion 40 that is offset rearward extends over the entire width thereof, and this attachment flange portion 46 is also attached to the back plate 2c. Has become a department. Reference numeral 47 denotes a hole through which a screw for attaching the attachment flange portion 46 to the back plate 2c is inserted.
The offset amounts of the mounting flange portion 42 and the mounting flange portion 46 are the same. When the fixing base portion 26 is attached to the back plate 2c by the mounting flange portion 42 and the mounting flange portion 46, the bottom plate portion 40 is the same as the back plate 2c. Become parallel.

Further, an attachment frame member 48 made of a metal plate press-molded product is attached to the lower back surface of the bottom plate portion 40.
The mounting frame member 48 fills a part of the space formed between the bottom plate portion 40 and the back plate 2c when the fixed base portion 26 is fixed to the back plate 2c of the housing 2, and the bottom plate portion The mounting flange portion 42 and the mounting flange portion 46 are offset to the rear from 40 and have a rectangular mounting surface portion 50 that is flush with the mounting flange portion 46.

From each of the upper, lower, left, and right sides of the mounting surface portion 50, leg pieces 52 extending substantially along the entire length of the mounting surface portion 50 extend toward the bottom plate portion 40. 54b) and is welded to the bottom plate portion 40.
The joint portion 54a of the leg piece extending from the upper side of the attachment surface portion 50 has its distal end bent further rearward to enhance the rigidity of the attachment frame member 48 itself and the bottom plate portion 40.

The leg piece joint 54b extending from the lower side of the mounting surface portion 50 extends to the lower end of the bottom plate portion 40, and then the tip is bent rearward to form an opening formed between the lower end portion of the bottom plate portion 40 and the back plate 2c. A lower lid portion 55 that closes the portion is formed.
Since the fixed base portion 26 is fixed to the back plate 2c with the upper end portion of the bottom plate portion 40 being in contact with the top plate 2a of the housing body 2, the fixed base portion 26 is connected to the upper end portion of the bottom plate portion 40 and the back plate 2c. Although the opening formed between them is closed by the top plate 2a, an upper lid portion can be provided on the upper end portion of the bottom plate portion 40 as needed.

  Holes 62 through which screws for fixing to the back plate 2c are inserted are provided at two locations on the left and right sides of the mounting surface portion 50. The hole 62 is made to correspond to a later-described window hole 107 of the movable base portion 28, and the height position thereof is close to the lower side of the attachment surface portion 50 that is near the rotation center axis Z of the movable base portion 28.

Returning to FIG. 5, the lower end of the bottom plate portion 40 is bent forward to form a horizontally extending support flange portion 65 for supporting the movable base portion 28.
The front edge of the support flange portion 65 is bent upward to form a cover flange 67, thereby forming a hook shape. The left and right ends of the support flange portion 65 are pivot support plate portions 70 and 71 which are bent upward and face each other.
The shaft support plate portions 70 and 71 are set at positions corresponding to the lower sides of the left and right posture holding members 56 attached to the upper portion of the bottom plate portion 40.

Each shaft support plate 70, 71 is provided with a shaft hole 73 positioned on the same axis (rotation center axis Z).
The right shaft support plate portion 71 is further formed with a lock mounting hole 75 above and ahead of the shaft hole 73.
When the movable base portion 28 is tilted, adjacent portions of the left and right ends of the cover flange 67 become pivot stoppers 68 that come into contact with the abutting portion 87. It is cut out one step lower so as to be in the posture position.

The width of the support flange 65 in the front-rear direction is matched with the width of the lower end of the movable base 28 in the front-rear direction, and the movable base 28 is supported by the fixed base 26 and the rotation of the movable base 28 is described later. A gap formed between the moving shaft portion 86 and the cover flange 67 is minimized.
The height of the cover flange 67 of the support flange portion 65 is higher than the center height of the shaft hole 73 and is set so as to cover the rotating shaft portion 86 from the front.
This makes it difficult for the tip of a tool such as a bar or a screwdriver to be inserted into the gap between the rotating shaft portion 86 and the cover flange 67 and prevents the rotating shaft portion 86 from being destroyed.

Next, the movable base portion 28 will be described.
The movable base portion 28 is made of a transparent synthetic resin having a predetermined rigidity, such as polycarbonate, for example, as shown in FIG. And a side plate portions 84 and 85 extending from the left and right ends of the bottom plate portion 80 toward the surface side.
As will be described later, the main control device 22 (substrate box 30) is placed on the placement portion 82.
A long slit hole 110 is formed on the left and right at the center of the mounting portion 82 in the horizontal width direction.
A columnar rotation shaft portion 86 is integrally formed on the lower surface of the front end of the mounting portion 82. The rotation shaft portion 86 extends to the left and right across the side plate portions 84 and 85.

A shaft hole 88 (see FIG. 7 described later) is formed along the axial center of the rotation shaft portion at both left and right ends of the rotation shaft portion 86.
The mounting portion 82 and the rotation shaft portion 86 are provided with a slit groove 90 perpendicular to the axis of the shaft hole 88 at a position spaced inward from the side plate portions 84 and 85 by a predetermined distance. As will be described later, the shaft hole 88 extends inward beyond the slit groove 90.
Further, at both ends of the rotation shaft portion 86, contact portions 87 extending outward in the radial direction of the rotation shaft portion 86 are provided corresponding to the rotation stoppers 68 of the fixed base portion 26, as described above. When the movable base portion 28 is tilted to the tilting posture position, it comes into contact with the rotation stopper 68.

A rectangular window hole 107 is formed in the bottom plate portion 80 at a predetermined distance from the left and right.
On the back surface of the bottom plate portion 80, as shown in FIG. The screw block 108 is provided with a screw hole 109 opened at the lower end surface thereof.

Returning to FIG. 5, the side plate portions 84 and 85 extend over the entire height of the bottom plate portion 80 with substantially the same front-rear width as the placement portion 82.
At the front ends of the side plate portions 84 and 85, a return portion 112 having a predetermined lateral width (horizontal width) excluding a part of the upper end and the lower end extends inward, and the side plate portions 84 and 85 and the bottom plate portion A protruding step 113 having the same width as that of the return portion 112 extends vertically at the connection portion 80.
As a result, a guide groove 114 having a certain front and rear width is formed on the inner wall of each of the side plate portions 84 and 85 between the return portion 112 and the protruding step portion 113 when the substrate box of the main controller is slid.
A fixing bracket portion 118 that protrudes forward from above the return portion 112 and extends inward (leftward) is provided at a substantially central position in the vertical direction of the side plate portion 85, and a screw is inserted vertically toward the bottom plate portion 80. A hole 119 is formed.

At the upper end portion of the bottom plate portion 80, a locking portion 120 for locking the main control device 22 held by the movable base portion 28 is provided in the center of the lateral width (left and right direction).
When the main control device is mounted on the movable base portion 28, the locking portion 120 engages with a protrusion (not shown) provided on the board box 30 and can be disengaged by elastic deformation. It has become.
Projecting pieces 122 extending upward are formed on the upper end of the bottom plate portion 80 on both the left and right sides of the locking portion 120 so as to be locked in slit grooves described later provided in the upper end portion of the substrate box 30.

FIG. 7 is a cross-sectional view showing the configuration of the end portion of the rotating shaft.
Boss plate portions 124 and 125 that form slits 126 are provided between the lower end portions of the side plate portions 84 and 85 and the end surface of the rotation shaft portion 86. The slit 126 is orthogonal to the rotation center axis Z, and the shaft support plate portions 70 and 71 of the fixed base portion 26 are inserted into the slit 126.
A shaft hole 127 is formed in each boss plate portion 124 and 125 coaxially with the shaft hole 88 of the rotation shaft portion 86.
The support pin 128 is inserted from the shaft hole 127 of the boss plate portion 124 into the shaft hole 88 of the rotation shaft portion 86 through the shaft hole 73 of the shaft support plate portion 70, and the support pin 128 is inserted into the shaft hole of the boss plate portion 125. The movable base portion 28 is rotatably supported with respect to the fixed base portion 26 by being inserted into the shaft hole 88 of the rotation shaft portion 86 through the shaft hole 73 of the shaft support plate portion 71 from 127.

  At this time, the support pin 128 is press-fitted in the shaft hole 127 of the boss plate portions 124 and 125 and the shaft hole 88 of the rotating shaft portion 86, and the head of the support pin 128 is outside the boss plate portions 124 and 125. It is set in the recess 129 formed on the end face so as not to protrude from the outer end face, and the support pin 128 after being attached cannot be removed.

Returning to FIG. 5, a metal plate reinforcing plate 130 is attached to the upper surface of the mounting portion 82. The reinforcing plate 130 has a length extending between the left and right slit grooves 90 of the mounting portion 82 and is superposed on the upper surface of the mounting portion 82, and extends upward from the rear end of the flat plate portion 132. A vertical wall 134 superimposed on the surface of the bottom plate portion 80 and a shaft support plate portion 136 that extends downward from both left and right ends of the flat plate portion 132 and is inserted into the slit groove 90 are provided.
The shaft support plate 136 is provided with a hole 137 positioned coaxially with the shaft hole 88 of the rotating shaft portion 86 in a state of being inserted into the slit groove 90, and the hole 137 has the same diameter as the shaft hole 88.

The front surface of the bottom plate portion 80 has a region 116 corresponding to the reinforcing plate 130 that is recessed by the thickness of the reinforcing plate, so that the surface of the bottom plate portion 80 forms a smooth flat surface including the reinforcing plate 130 and its periphery. It has become.
The flat plate portion 132 of the reinforcing plate 130 is formed with slit holes 138 that are aligned with the slit holes 110 of the mounting portion 82, and rectangular window holes 142 are formed at positions that respectively overlap the window holes 107 of the bottom plate portion 80. ing.

FIG. 8 is a view showing a fixing structure of the reinforcing plate and the bottom plate part in the window hole 142 part.
The cut-and-raised piece when forming the window hole 142 of the reinforcing plate 130 is bent backward from the upper side of the window hole 142 to form a bracket part 144. The bracket portion 144 passes through the window hole 107 of the bottom plate portion 80 and overlaps the lower end surface of the screw block 108.
The reinforcing plate 130 is fixed to the movable base portion 28 by screwing the fixing screw into the screw hole 109 of the screw block 108 from below through the insertion hole 145 formed in the bracket portion 144.
Since the rigidity of the movable base portion 28 is increased by the reinforcing plate 130, even if an attempt is made to squeeze the sealing portion, the bending of the substrate box 30 held by the movable base portion 28 is suppressed, and illegal acts are prevented. Make it difficult.

  As shown in FIGS. 5 and 7, a coaxial lock mounting hole 89 is formed in the lower end portion of the side plate portion 85 and the boss plate portion 125. The position of the lock attachment hole 89 is set so as to overlap with the lock attachment hole 75 of the fixed base portion 26 when the movable base portion 28 is in the standing posture position. For example, by attaching a padlock or the like, Can be prohibited.

In the base device 25 having the above configuration, first, a mounting screw is inserted into the hole 43 of the mounting flange portion 42 from the front surface side of the fixed base portion 26, and the corresponding position inside the back plate 2 c of the housing body 2 is previously set. Screw into the provided nut.
Further, with the movable base portion 28 in the standing posture position, a mounting screw is inserted into the hole 62 of the mounting frame member 48 through the window hole 142 of the reinforcing plate 130 of the movable base portion and the window hole 107 of the bottom plate portion 80. The screw is fixed to the back plate 2c by being screwed into a nut portion provided in advance at a corresponding position inside the back plate 2c of the housing body 2.
Further, a screw is inserted from the outside into an insertion hole formed in the back plate 2 c in advance, and is screwed into a nut provided in the hole 47 of the mounting flange portion 46.
Thereby, since the fixed base part 26 is fixed to both the front and the back with respect to the back plate 2c, it cannot be removed from the back plate 2c only from one of the front and the back.

In particular, when the substrate box 30 is held on the movable base portion 28, the window holes 107 and 142 of the movable base portion are closed by the substrate box 30, so that the tip of the screw driver is inserted into these window holes from the front of the movable base portion 28. Can not be inserted.
Further, since the hole 62 of the mounting frame member 48 is in the vicinity of the rotation center axis Z, the tip of the screw driver cannot be inserted even when the movable base portion 28 is tilted.

Next, the configuration of the main controller 22 will be described.
FIG. 9 is an exploded perspective view of the main controller 22.
The substrate box 30 includes a first box 200 on the front side and a second box 300 on the back side.
The main board 23 is attached to the inside of the first box 200 by screws (not shown) through a pair of small holes 24 provided at the corners located on the diagonal line. On the main board 23, a wiring pattern 154 including a power supply line and the like is formed, and various electronic components including an IC chip such as a CPU and a ROM, a socket, and the like are mounted.
The main board 23 has a projecting portion 150 that extends downward and is inserted into a block receiving portion 219 described later of the first box 200, and the projecting portion 150 has a hole 152. The hole 152 is aligned with a cylindrical body 240 to be described later when the main board 23 is attached.

FIG. 10 is an enlarged perspective view around the hole 152 in the overhanging portion. The main board 23 (the overhanging portion 150) has four pieces of fixed-side terminals G (G1, G2, G3, G4) at equal intervals along the periphery of the hole 152. ) Is provided. Each of the fixed side terminals G is fixed to the front surface of the main board 23 and temporarily bulges away from the wall surface while extending toward the center of the hole 152, and then folded back and passes through the hole 152 to pass through the main board 23. It extends to the back surface side of the, and the tip is inclined in a direction away from the hole center.
Two adjacent fixed-side terminals G1 and G2 are connected to a power supply line 154a formed on the main board 23. The other fixed side terminals G3 and G4 are connected to each other by a short-circuit line 154b.

The first box 200 has a main substrate housing portion 201 that can accommodate relatively tall electronic components on the main substrate 23, and a lower step portion 202 is formed on the periphery thereof. Yes.
The step portion 202 is formed with a plurality of socket insertion holes 203 through which sockets on the main board are inserted.
A sticking frame 204 for sticking a sealing history recording sheet is set on the surface of the main board housing part 201.

At the right end of the first box 200, a fixed surface 205 is formed at the approximate center in the vertical direction. The fixed surface 205 is set to overlap the back surface of the fixed bracket portion 118 of the movable base portion 28 when the substrate box 30 is placed on the movable base portion 28, and is used for fixing the substrate box 30 to the movable base portion 28. A screw hole 206 is provided.
A flat portion 207 is adjacent to the inside (left side) of the fixed surface 205 with a step, and when the substrate box 30 is fixed to the movable base portion 28, it is continuous with the surface of the fixed bracket portion 118. Yes.
The surfaces of the flat surface portion 207 and the fixing bracket portion 118 cooperate to form a seal application surface of a seal seal (not shown). That is, by sticking the seal seal across both the flat surface portion 207 and the fixed bracket portion 118, once it is peeled off, a trace of being peeled off is left on the seal sticking surface.

On the side walls 210 at both left and right ends of the first box 200, rail forming portions 211 that protrude outward are provided over the entire height in the vertical direction.
The second box 300 has a bottom plate portion 301 that faces the back surface of the main board 23 attached to the first box 200. A grid-like rib 302 is provided on the inner surface of the bottom plate portion 301 to increase the rigidity. Rail forming portions 311 are provided on the side walls 310 at both left and right ends of the bottom plate portion 301 so as to protrude outward over the entire height in the vertical direction.

FIG. 11 is a view showing rail forming portions of the first box 200 and the second box 300.
(A) is a side view of the rail formation part 211, (b) is an AA part enlarged sectional view in (a), (c) is a side view of the rail formation part 311, (d) is B- in (c). B section expanded sectional drawing, and (e) are sectional drawings which show a combined state.
The rail forming portion 211 is provided with a plurality of ribs 211b that stand up outward from the rear end edge of the side wall 210 and extend in the vertical direction. A plurality of L-shaped hooking portions 212 formed of pieces extending upward from the rear end are formed.
In addition, a strip plate portion 211 a having a constant width extending over the entire height in the vertical direction of the side wall 210 is formed in parallel to the side wall 210 so as to be connected to the hook portions 212.

The rail forming portion 311 has an L-shape that includes a piece that stands outward from the side wall 310 and extends in the board height direction (front-rear direction) and a piece that extends downward from the front end along the front edge of the side wall 310. The plurality of hook portions 312 are provided so as to line up and down in a row at a predetermined interval.
Further, a vertical wall portion 311a having a constant width extending from the side wall 310 to the entire height in the vertical direction is formed, and this vertical wall portion 311a connects the rear ends of the pieces extending in the front-rear direction of the hook portion 312. Yes.

The first box 200 and the second box 300 are coupled by the engagement of the plurality of hooks 212 and the hooks 312 to form a hollow box-shaped substrate box 30.
That is, at a position where the second box 300 is shifted upward by a predetermined amount with respect to the back surface of the first box 200, the hooking portion 312 of the second box is placed between the hooking portion 212 of the first box and the first box and the first box. The hooks 212 and 312 are engaged with each other by overlapping the two boxes and then sliding the second box 300 downward relative to the first box 200.

In particular, as shown in FIG. 11 (e), in the coupled state of the first box 200 and the second box 300, the rear end edge of the strip plate portion 211a abuts on the vertical wall portion 311a and the outside of the vertical wall portion 311a. The side edge is set to be flush with the outer surface of the band plate portion 211a.
Thereby, the rail formation part 211 of the 1st box and the rail formation part 311 of the 2nd box cooperate, and form the rail 32 extended in the up-down direction of a board | substrate box.

Returning to FIG. 9, on the upper end wall 209 of the first box 200, an opposing wall 213 extending across the entire width in the left-right direction is provided, and behind the opposing wall 213 (on the second box side), parallel to the opposing wall 213. A plurality of engaging protrusions 214 are provided in a line in the left-right direction.
In the coupled state of the first box 200 and the second box 300, the upper end wall 308 of the second box 300 overlaps the upper end wall 209 of the first box 200, and the front end surface 308a of the upper end wall 308 extends over the entire width in the left-right direction. It is set to be a contact surface with the opposing wall 213 of one box 200.
Further, the upper end wall 308 of the second box 300 receives the engagement protrusion 214 of the first box when the first box 200 is slid to the coupling position with the second box 300 immediately after the front end surface 308a. An engagement hole 316 is formed.

The lower end portion of the first box 200 is provided with cutout recesses 221 at both left and right ends, and an elongated rectangular recess 220 in which three cylindrical bodies 240 are arranged is provided in the central portion therebetween.
Between the rectangular recessed part 220 and the notch recessed part 221, the connection fixing | fixed part 215 provided with the screw hole 216 (refer FIG. 3, FIG. 12) opened to the back surface (2nd box side) of the 1st box 200 is set.

The second box 300 is provided with a notch space 320 corresponding to the rectangular recess 220 of the first box 200, and a rectangular fixing corresponding to the connection fixing part 215 of the first box 200 on both sides thereof. Block 304 is provided.
The notch space 320 is partitioned by an upper wall 321 extending in the left-right direction and a side wall 322 in the vertical direction, and the side wall 322 forms one wall surface of the fixed block 304.
The fixing block 304 has a hole 305 corresponding to the screw hole 216 of the connection fixing part 215 of the first box in the coupled state of the first box and the second box, and the screw is passed from the hole 305 to the screw hole 216. By screwing, the first box 200 and the second box 300 are fixed to each other.

A plurality of engagement blocks 317 are formed on the back surface (outer surface) of the second box 300 in the left-right direction so as to extend downward from the upper end wall 308 and form slit grooves 318 between the bottom plate portion 301 and the back surface.
When the substrate box 30 is held on the movable base portion 28, the protruding piece 122 (see FIG. 5) of the movable base portion 28 is inserted into the slit groove 318 and locked.

On the lower end wall 222 (see FIG. 18) of the first box 200, a projecting piece 218 directed downward is provided at the center in the left-right direction.
The protruding piece 218 has a length that is approximately one third of the width of the first box 200 and extends to the left and right. When the substrate box 30 is held by the movable base 28, the mounting portion of the movable base is provided. 82 and the slit holes 110 and 138 of the reinforcing plate 130 are inserted and locked.

As shown in FIG. 3, the sealing portion 34 (34a, 34b, 34c) is arranged in the rectangular recess 220 adjacent to the lower end portion of the substrate box 30 in the lateral direction. Reference numerals A to C are attached to indicate the order of sealing.
As will be described later, different color names are attached to the signs A to C adjacent to each other. In FIG. 9, the color names are not shown for simplicity.
The sealing portion 34 seals and joins the first box 200 and the second box 300, and the cylindrical body 240 in the rectangular recess 220 is a sealing member in the first box 200.

FIG. 12 shows the back surface of the first box 200. A cover wall 270 corresponding to the rectangular recess 220 is provided on the back surface. The cover wall 270 extends rearward after extending the rear end edge of the lower end wall 222 of the first box 200 to form a block receiving portion 219 that accommodates a rectangular block 338 of the second box 300 described later. . The block receiving part 219 opens upward, and both left and right ends are closed.
The above-described connecting and fixing portions 215 are located adjacent to the left and right sides of the block receiving portion 219.
In the cutout space 320 below the second box 300, three rectangular blocks 338 are provided as sealing members so as to correspond to the cylindrical body 240 of the first box 200. Each rectangular block 338 is independent of each other.

Hereinafter, the seal coupling structure of the seal portion 34 in the substrate box 30 will be described in detail.
13A and 13B show the sealing member of the sealing portion 34a (A) in the rectangular recess 220 of the first box 200, where FIG. 13A is a front view and FIG. 13B is a cross-sectional view taken along the line CC in FIG.
The rectangular recess 220 has a bottom wall 242.
A cylindrical body 240 having an axial axis as a sealing member is disposed in the rectangular recess 220, and the cylindrical body 240 is connected to the upper inner wall and the lower inner wall of the rectangular recess 220 by upper and lower fragile connecting portions 244 at the front end portion thereof. Has been.

The bottom wall 242 of the rectangular recess 220 has a cylindrical body 240 when viewed from the front and a hole 243 that is notched into a shape having a predetermined gap with respect to the outline of the connecting portion 244. The rear end is located in the hole 243.
Since the bottom wall 242 is not directly connected to the cylindrical body 240, the cylindrical body 240 can be excised by cutting the connecting portion 244.
The cylindrical body 240 has a cylindrical hole 246 having a constant inner diameter into which a sealing pin 400 described later is inserted.
A key groove 249 is formed at the upper end of the cylindrical hole 246 over the entire length in the axial direction.
The bottom wall 223 of the block receiving portion 219 is formed with a through-hole-shaped hook receiver 208 into which a hook 314 (to be described later) of the second box 300 is inserted immediately after the protruding piece 218.

14A and 14B show details of the rectangular block 338 which is a sealing member of the second box 300. FIG. 14A is a front view, FIG. 14B is a cross-sectional view taken along the line DD in FIG. 14A, and FIG. .
The rectangular block 338 includes a front wall 350 extending downward from the upper wall 321 in parallel with the slide surface, and a frame that surrounds the three sides of the front wall 350 and is connected to the upper wall 321 to form a four-image frame together with the upper wall 321. It consists of a wall 351 and a bottomed cylindrical cap portion 352 bulging rearward from the front wall 350. The front wall 350 is provided with a locking hole 353, and the cap portion 352 serves as a receiving space for the tip of a sealing pin 400 described later inserted through the locking hole 353.
The locking hole 353 has a notch 354 on the diameter line in the vertical direction.

As shown in FIG. 18 to be described later, the upper wall 321 of the notch space 320 is the cover of the first box 200 when the second box 300 is slid with each other and overlapped with the first box 200. It contacts the upper edge of the wall 270. The cover wall 270 is set to be flush with the back surface (rear surface) of the first box 200.
A hook 314 extending downward on the extension line of the front wall 350 is formed at the lower end of the rectangular block 338, and this hook 314 is attached to the hook receiver 208 formed on the bottom wall 223 of the block receiving portion 219 of the first box 200. It is designed to be plugged in.
13 and 14 show the sealing portion 34a (A), but the sealing members of the sealing portion 34b (B) and the sealing portion 34c (C) are the same.

The sealing pin 400 will be described.
15 is an exploded perspective view of the sealing pin 400, FIG. 16A is a front view of the sealing pin 400 viewed from the axial direction, FIG. 15B is a side view, FIG. 15C is a rear view, and FIG. It is. 17A is a longitudinal sectional view of the sealing pin 400, and FIG. 17B is a longitudinal sectional view orthogonal to the section of FIG.
The sealing pin 400 is configured by housing a light emitting unit 480 in a pin body 401.
The pin body 401 is made of resin such as PA, PP, POM, PC, or ABS. It has an outer shape composed of a large diameter portion 402 and a small diameter portion 403 having a smaller diameter than the large diameter portion.
The large diameter portion 402 side is the front and the small diameter portion 403 side is the rear.

An axial key rib 404 is formed on the outer peripheral surface of the large diameter portion 402 over the entire length. The position of the rotation direction with respect to the cylindrical body 240 is fixed by the engagement of the key rib 404 and the key groove 249 in the cylindrical hole 246.
The pin body 401 has a large-diameter hole 405 and a small-diameter hole 406 along the outer shape, and both the holes are connected and penetrated.
In the large diameter hole 405, a groove 411 extending in the entire axial direction is formed at a position overlapping the key rib 404.
The small-diameter portion 403 is provided with an elastic portion 407 in the left-right direction perpendicular to the vertical diameter line passing through the key rib 404 (and the groove 411).

The elastic portion 407 is surrounded by a U-shaped slit formed in the cylindrical wall of the small diameter portion 403, has a single shape extending axially rearward from the large diameter portion 402 side, and outward (lateral direction) in the rear end. ) Has a locking claw 408 protruding to the top.
The locking claw 408 has a locking surface 410 whose front end is perpendicular to the axial direction, and its rear outer surface has a cone shape coaxial with the small diameter portion 403 and an inclined surface 409 whose tip is reduced to the diameter of the small diameter portion 403. .
Slit holes 412 are formed in the cylindrical wall of the small diameter portion 403 between the elastic portion 407 and the large diameter portion 402 at four locations at equal intervals in the circumferential direction continuously from the rear end of the large diameter portion 402.

The light-emitting unit 480 is configured by mounting a control circuit 483 including a RAM, a capacitor 484, an LED 485, a diode 486, and a resistor 487 on a disk-shaped substrate 481 whose outer diameter is aligned with the large-diameter hole 405. The control circuit 483 Are provided with four pin-side terminals Q (Q1, Q2, Q3, Q4).
The light emitting unit 480 is arranged with the substrate 481 seated on the stepped portion of the large diameter hole 405 and the small diameter hole 406.

A protrusion 482 is provided on the outer edge of the substrate 481 so as to protrude outward.
The pin-side terminal Q first extends rearward from the substrate 481 along the inner wall of the small diameter hole 406. The pin-side terminals Q are provided at equal intervals in the circumferential direction along the outer periphery of the substrate 481, and are positioned in the slit holes 412 of the small diameter portion 403 by aligning the protrusions 482 of the substrate 481 with the grooves 411 of the large diameter hole 405.
The pin-side terminal Q is bent outward at the rear end edge of the slit hole 412, and further extends rearward after coming out of the small diameter portion 403. Outside the small-diameter portion 403, the pin-side terminal Q tilts away from the outer peripheral surface of the small-diameter portion 403 while extending rearward, ends after changing the direction toward the outer peripheral surface of the small-diameter portion 403 after being separated by a predetermined distance. This forms a mountain that bulges outward.

A disk cap 490 that covers the light emitting unit 480 is attached to the large-diameter hole 405.
The disk cap 490 is made of a transparent resin, and is formed of a disk part 491 having a projection 492 aligned with the large-diameter hole 405 and protruding outward at the outer edge, like the substrate 481, and a hook piece 493 extending rearward from the disk part 491. It has become. Two hook pieces 493 are provided symmetrically with respect to the center in the vicinity of the outer edge of the disk portion 491, and each has a claw 494 facing outward at the tip.

  An engagement recess 413 is formed in the large-diameter hole 405 above the substrate 481 at the seating position. By inserting the disc cap 490 with the protrusion 492 aligned with the groove 411, the claw 494 of the hook piece 493 is engaged. The disc cap 490 is prevented from coming off by engaging with the mating recess 413. In a state where the claw 494 is engaged with the engaging recess 413, the disk portion 491 is in a position that sinks from the opening end of the large-diameter hole 405.

With the claw 494 engaged with the engaging recess 413, the front end (rear end) of the hook piece 493 is set so as to abut or form a minute gap with the substrate 481, so that the light emitting unit 480 is hooked forward. The pin-side terminal Q is regulated by the rear end edge of the slit hole 412 and is held in the rear direction.
The large-diameter hole 405 is sealed at its open end by injecting a transparent ultraviolet curable resin 414 into the front side of the disk cap 490.

18A is a cross-sectional view showing the sealing portion 34 before sealing in a state where the first box 200 and the second box 300 are coupled, and FIG. 18B is a cross-sectional view showing the sealing state in which the sealing pin 400 is inserted. c) is a cross-sectional view taken along line EE in (b).
When the sealing pin 400 is inserted into the cylindrical body 240 from the front end (rear end), the small diameter portion 403 of the pin main body 401 passes through the cylindrical hole 246 and passes through the hole 152 of the main board 23.
The locking claw 408 of the elastic portion 407 protrudes from the small diameter portion 403. However, since the large diameter portion 402 does not enter the cylindrical hole 246 when passing through the hole 152 of the main board 23, the sealing pin 400 is pivoted. By turning it around, the locking claw 408 can pass through the hole 152 while avoiding interference with the fixed terminal G.

Then, as the key rib 404 of the large-diameter portion 402 is further inserted in a state where it is aligned with the key groove 249 of the cylindrical hole 246, the locking claw 408 is engaged with the hole edge of the locking hole 353 of the front wall 350 in the rectangular block 338 of the second box 300. The inclined surface 409 is pushed, and the elastic portion 407 is bent in the inner diameter direction.
When the sealing pin 400 is inserted until the front end of the sealing pin 400 is flush with the front end surface of the cylindrical hole 246, the locking claw 408 comes out of the locking hole 353, the elastic portion 407 is restored, and the locking claw 408 becomes a small diameter portion. 403 protrudes from the outer peripheral surface, and the locking surface 410 is locked to the back surface of the front wall 350.
The state in which the locking claw 408 passes through the locking hole 353 and is locked to the back surface of the front wall 350 is expressed as the locking claw 408 being locked to the locking hole 353 for the sake of simplicity. The same applies hereinafter.
As a result, the locking claw 408 of the sealing pin 400 extending from the first box 200 side protrudes left and right and locks to the front wall 350 of the rectangular block 338 of the second box 300, so that the first box 200 and the second box Box 300 is sealed in a combined state.

On the front side, since the front end of the sealing pin 400 is flush with the front end of the cylindrical body 240, the sealing pin 400 cannot be pulled out.
The locking hole 353 of the front wall 350 where the locking claw 408 of the sealing pin 400 is locked has a notch 354 through which the locking claw 408 can pass vertically. Since the rotation is restricted by the engagement between the key rib 404 and the key groove 249 of the main body 401, the locking claw 408 cannot be rotated to the notch 354 position.
Therefore, the locking claw 408 of the sealing pin 400 inserted from the first box 200 side does not come off from the front wall 350 of the rectangular block 338 in the second box 300, and the connection between the first box 200 and the second box 300 is broken. It will not be released without accompanying.

  On the other hand, the cap portion 352 that surrounds the locking claw 408 locked in the locking hole 353 of the front wall 350 also reaches the outside directly from the outside because the rectangular block 338 itself is surrounded by the cover wall 270. It is not possible. Even if the cover wall 270 is broken, the cap portion 352 further covers the locking claw 408, so that the locking claw 408 of the sealing pin 400 can be removed by a screwdriver or the like unless it is destroyed on a large scale and the trace remains. The part cannot be reached, and the first box 200 and the second box 300 cannot be uncoupled and opened.

FIG. 19 is a circuit diagram of the light emitting unit 480 including an electrical connection with the main board 23.
The control circuit 483 includes a CPU and a RAM therein, and includes power supply terminals Pb1 and Pb2, an input terminal Pi2, and output terminals Pi1, Po1, Po2, and Po3. The RAM stores a CPU control program.
The power supply terminal Pb1 is connected to the pin side terminal Q1 through the diode 486, and the power supply terminal Pb2 is connected to the pin side terminal Q2 through the ground GND. The control circuit 483 operates by receiving a DC power supply between the power supply terminals Pb1 and Pb2.

A capacitor 484 is provided between the power supply terminal Pb1 and the ground GND (pin side terminal Q2).
The output terminal Pi1 is connected to the pin side terminal Q3, and the input terminal Pi2 is connected to the pin side terminal Q4.
An LED 485 is connected to the pin-side terminal Q1 via a voltage adjusting resistor 487. The LED 485 is a full color type and incorporates blue, green, and red light emitting elements Lb, Lg, and Lr, and terminals corresponding to the respective elements are connected to the output terminals Po1, Po2, and Po3.

The pin-side terminals Q1, Q2, Q3, and Q4 are connected to the fixed-side terminals G1, G2, G3, and G4 of the main board, respectively, in the sealed state in which the sealing pin 400 is inserted into the cylindrical body 240 of each sealing portion. belongs to.
While the pin-side terminals Q1 and Q2 are connected to the fixed-side terminals G1 and G2, the control circuit 483 is operated by the power from the main board 23 side, and the capacitor 484 is charged. The capacitor 484 serves as a backup power source as will be described later.

Since the fixed-side terminals G3 and G4 are short-circuited on the projecting portion 150 of the main board 23, when the pin-side terminals Q3 and Q4 are connected to the fixed-side terminals G3 and G4, the output terminal Pi1 and the input terminal Pi2 are electrically connected. When the pin-side terminals Q3 and Q4 are separated from the fixed-side terminals G3 and G4, the output terminal Pi1 and the input terminal Pi2 become non-conductive.
In the control circuit 483, the CPU monitors conduction and non-conduction between the output terminal Pi1 and the input terminal Pi2, and controls the states of the output terminals Po1, Po2, and Po3 based on the change.

FIG. 20 is a flowchart showing the flow of lighting color control of the LED 485 in the control circuit 483.
When power is supplied for the first time and the output terminal Pi1 and the input terminal Pi2 are in a conductive state at the same time, “blue” is stored in the RAM as the lighting color data of the LED 485 as an initial setting of the control program, and the output terminal Po1 is set to L. (Low) and the output terminals Po2 and Po3 are respectively set to H (High).
Here, L of the output terminal is a state in which the output terminal is connected to the ground in the control circuit 483. Therefore, when the output terminal Po1 becomes L, a current flows from the pin side terminal Q1 through the resistor 487 and the light emitting element Lb to the pin side terminal Q2 from the output terminal Po1 through the ground GND, and the light emitting element Lb emits blue light. To do.
Thereafter, for example, the following processing is executed at intervals of 1 sec.

First, in step 100, it is checked whether or not the output terminal Pi1 and the input terminal Pi2 are in a conductive state.
When the output terminal Pi1 and the input terminal Pi2 are electrically connected, the current flow is terminated, and thus the state of each output terminal is maintained as the initial setting.
If the output terminal Pi1 and the input terminal Pi2 are not conducting (non-conducting), the process proceeds to step 101 to check whether the lighting color data of the RAM is “blue”.
When the lighting color data is “blue”, the process proceeds to step 102, and when it is not “blue”, the process proceeds to step 104.
In step 102, the lighting color data in the RAM is changed to “green”, and in step 103, the output terminal Po2 is set to L, and the output terminals Po1 and Po3 are set to H, respectively.

On the other hand, in step 104, it is checked whether or not the lighting color data in the RAM is “green”.
When the lighting color data is “green”, the process proceeds to step 105, and when it is not “green”, the process proceeds to step 107.
In step 105, the lighting color data in the RAM is changed to “red”, and in step 106, the output terminal Po3 is set to L, and the output terminals Po1 and Po2 are set to H, respectively.
In step 107, it is checked whether or not the lighting color data in the RAM is “red”.
When the lighting color data is “red”, the process proceeds to step 108 where the lighting color data in the RAM is changed to “white”, and in step 109, the output terminals Po1, Po2, Po3 are all set to L.
If the lighting color data in the RAM is not “red”, the current flow is terminated.

Here, since the non-conduction between the output terminal Pi1 and the input terminal Pi2 occurs when the seal is released, the pin-side terminals Q1 and Q2 and the fixed-side terminals G1 and G2 are disconnected at the same time, and the power from the main board 23 is removed. Supply is cut off. Therefore, the LED 485 is turned off.
However, the capacitor 484 connected between the power supply terminals Pb1 and Pb2 and charged during the power supply from the main board 23 becomes a backup power supply, and the control circuit 483 continues the operation state. This state is maintained until the next seal.
The above-described control flow is executed at intervals of 1 sec, but the execution cycle is the connection state between the pin-side terminals Q3 and Q4 and the fixed-side terminals G3 and G4 (conduction between the output terminal Pi1 and the input terminal Pi2). It may be arbitrarily set within a range shorter than the time required for releasing the seal and disconnecting and then connecting again (resealing).

  When the pin-side terminals Q3 and Q4 are connected to the fixed-side terminals G3 and G4 by the second sealing and the output terminal Pi1 and the input terminal Pi2 are electrically connected, the pin-side terminals Q1 and Q2 are simultaneously connected to the fixed-side terminals G1 and G2. Since power is supplied to the LED 485 from the main board 23, the output terminal Po2 is held at L, so that the light emitting element Lg connected to the output terminal Po2 emits green light.

Similarly, when the second seal is released, the control circuit 483 resets the output terminal Po2 to H and sets the output terminal Po3 to L. The output terminal Po1 remains H. The state of each of these output terminals updated again is held until the next sealing.
In the third sealing, since the output terminal Po3 is L, the LED 485 is connected to the output terminal Po3 by the power supply from the pin side terminals Q1 and Q2 connected to the fixed side terminals G1 and G2. The light emitting element Lr that emits light emits red light.
Further, when the third seal is released, all of the output terminals Po1 to Po3 are set to L, so that the LED 485 is lit white by mixing three colors at the next power supply.

The main control device 22 having the above configuration is assembled as follows, and is attached to the pedestal device 25 attached in the housing body 2.
First, the main board 23 is attached to the inside of the first box 200, and the first box 200 and the second box 300 are coupled by the engagement of the hook portion 212 and the hook portion 312. A main control device 22 in which 23 is accommodated is formed.

That is, the hooking portion 212 of the first box 200 is placed between the hooking portions 312 of the second box 300 at a position where the first box 200 is shifted downward by a predetermined amount with respect to the second box 300. The hooks 212 and 312 are engaged with each other by overlapping the boxes and then sliding the first box 200 upward relative to the second box 300.
Then, by screwing a screw from the hole 305 of the fixing block 304 of the second box 300 into the screw hole 216 of the connecting and fixing part 215 of the first box 200 facing each other, the first box and the first box are brought into a coupled state. The substrate box 30 is fixed. Rails 32 are formed on the side walls of the substrate box 30.

The initial sealing of the substrate box 30 is performed by inserting the sealing pin 400 into the cylindrical body 240 of the sealing portion 34a located at the A position from the front side (first box side).
The seal coupling structure is as shown in FIG.
The board box 30 formed with this seal coupling structure is inserted between the side plate portions 84 and 85 from the upper end of the movable base portion 28 tilted with respect to the fixed base portion 26, and the rails 32 on the side walls are moved to the movable base portion. The lower end is seated on the reinforcing plate 130 on the mounting portion 82 while sliding in the guide groove 114 of the side plate portion.
Thereafter, when the movable base portion 28 is set in the standing posture position, the operation is easy.

In the above-described placement state, the board box 30 is fixed to the movable base portion 28 by screwing a screw into the screw hole 206 of the fixing surface from the hole 119 of the fixing bracket portion 118 that overlaps the fixing surface 205 of the first box 200. Then, a sealing seal is pasted over both the flat portion 207 and the fixing bracket portion 118 following the fixing surface 205.
Further, since the left and right protruding pieces 218 formed at the lower end of the substrate box 30 are inserted into the mounting portion 82 of the movable base portion 28 and the slit holes 110 and 138 of the reinforcing plate 130, the substrate box 30 is movable with the substrate box 30. Even if a driver or the like is inserted between the base portions 28, the space between the two cannot be opened.

In this way, when the main controller 22 (board box 30) is initially sealed in the pedestal device 25, when the power connector or the like is connected to the socket and the slot machine is turned on, the LED 485 of the sealing pin 400 The light emitting element Lb emits light. Since this light emission passes through the disk cap 490 and the ultraviolet curable resin 495, the sealing pin 400 appears to light blue from the outside.
The sealing history recording sheet affixed to the affixing frame 202 is defined so that the date and time of sealing the sealing part 34a (A) and the name of the person who sealed it are written. The same applies to the next sealing part (B). It has been established.
Therefore, it is possible to easily determine whether or not the main controller 22 has been illegally disassembled by comparing the description content of the sealing history recording sheet with the evidence of excision of the sealing portion.

When the main board 23 is removed from the board box 30 due to a malfunction or inspection of the main control apparatus 22, the main control apparatus 22 is removed from the pedestal apparatus 25, and the sealed sealing portion 34a (A) is unsealed. The main board 23 is removed from the board box 30.
To release the seal, the substrate box 30 is slid upward and removed from the movable base 28, and then the connecting portion 244 connecting the cylindrical body 240 to the upper inner wall and the lower inner wall of the rectangular recess 220 is cut. The sealing pin 400 is rotated together with the cylindrical body 240, and the locking claw 408 locked to the front wall 350 of the rectangular block 338 in the second box 300 is aligned with the notch 354 of the locking hole 353, thereby sealing. The pin 400 is released from the rectangular block 338.
Thereby, the substrate box 30 can be opened.

The sealing pin 400 assembled to the cut cylindrical body 240 can be pulled out of the cylindrical body 240 by pushing the locking claw 408 inward in the radial direction to bend the elastic portion 407 and pushing it from the rear. Can be reused.
When the repair or inspection of the main board 23 is completed, the main board 23 is accommodated in the board box 30 and the main controller 22 is reassembled.

In the resealing, the sealing part 34a of the substrate box 30 is not used because the cylindrical body 240 is cut off, so the sealing part 34b (B) on the right side is sealed.
When the seal pin 400 releases the seal at the A position, the pin-side terminals Q3 and Q4 are disconnected from the fixed-side terminals G3 and G4, and the output terminal Pi1 and the input terminal Pi2 of the control circuit 483 are disconnected. Since the state of the output terminal has been updated, the light emitting element Lg of the LED 485 emits light in the state of being inserted into the cylindrical body 240 at the B position, and the sealing pin 400 is lit in green.

Similarly, when the sealing at the B position is released, and then the sealing pin 400 is inserted into the cylindrical body 240 at the C position, the head of the sealing pin 400 causes the light emitting element Lr of the LED 485 to emit light, and the sealing pin 400 is lit red. Change to state.
That is, the state of the sealing pin 400 is changed every time the seal is released as a history display of the seal release.
In this way, in addition to the recording of the sealing history recording sheet, the lighting color of the sealing pin 400 at the new sealing position after release of the seal changes, so check the match between the color name and the lighting color near the position code By doing so, it can confirm that it is a regular sealing state.

  On the other hand, even if the other board box is destroyed and the sealing pin 400 is obtained illegally, when the output terminal Pi1 and the input terminal Pi2 are disconnected from the main board 23, the output terminals Po1 to Po1 of the control circuit are not connected. Since the state of Po3 is renewed, when inserted into the tubular body 240 at the A position to be sealed first in the illegally formed substrate box 30, the sealing pin 400 becomes a normal blue color such as green or red. Since they are lit in different colors, it is easy to know that the board box is not properly formed.

The first embodiment is configured as described above. First, a sealing portion 34 that seals the coupled state of the first box 200 and the second box 300 includes a cylindrical body 240 provided in the first box 200 in the front-rear direction. The rectangular box 338 having the front wall 350 provided with the locking hole 353 in the second box 300, and the locking claw 408 of the sealing pin 400 inserted from the cylindrical body 240 is locked to the locking hole 353. It has become. The rear end of the sealing pin 400 provided with the locking claw 408 is covered with a cap portion 352 connected to the rear side of the front wall 350 to prohibit access.
In addition, since the front end of the sealing pin 400 is set so as to be flush with the front end of the cylindrical body 240 in a state of being inserted into the cylindrical body 240, the sealing pin 400 cannot be forcibly pulled out by grasping only the sealing pin 400. . Similarly, since the rotation is restricted by the engagement of the key rib 404 and the key groove 249, it is not possible to rotate only the sealing pin 400 and pull the locking claw 408 in accordance with the notch 354.
Thereby, the connection state between the first box 200 and the second box 300 can be sealed and the safety when returning the main board 23 to the manufacturer or the like can be ensured.

  Since the sealing pin 400 includes the light emitting unit 480 and the lighting color is changed every time the seal is released and used for the next sealing, it is possible to easily determine that the sealing pin is an illegally used sealing pin. In addition, when there are a plurality of sealed portions as in the embodiment, it is easy to determine whether the regular substrate box is properly sealed by comparing with the lighting color set individually for each sealed portion. This has the effect of being able to discriminate between.

The light emitting unit 480 includes an LED 485, a control circuit 483, a capacitor 484, and pin-side terminals Q1 to Q4. The control circuit 483 is in a sealed state in which the sealing pin 400 is inserted from the cylindrical body 240. The pin-side terminals Q3 and Q4 connected to the fixed-side terminals G3 and G4 provided in the non-connected state are detected to release the seal, while in the sealed state, the pin-side terminals Q1 and Q2 are connected to the fixed-side terminals G1 and G1, The power is supplied by connecting to G2, the capacitor 484 is charged and the LED 485 is turned on, and the LED 485 is not turned on in the seal release state.
Since the LED 485 that requires a large amount of power is not turned on in the seal release state, the control circuit 483 can detect the release of the seal even while the power of the gaming machine is turned off using the capacitor 484 as a backup power source. The sealing pin 400 that accommodates 480 can be made compact.

  The control circuit 483 is intermittent at a 1 sec cycle set shorter than the time required for the pin-side terminals Q3 and Q4 and the fixed-side terminals G3 and G4 to be connected again after the seal is released and disconnected. Since the control flow is executed and monitored automatically, the power consumed by the control circuit 483 is saved.

  Since the front end opening of the sealing pin 400, that is, the front side of the disk cap 490 is filled with a transparent ultraviolet curable resin 414 and sealed, the LED 485 can be turned on and visible through the ultraviolet curable resin 414. In order to take out the constituent member of the light emitting unit 480 including the ultraviolet curable resin 414, it is necessary to scrape the ultraviolet curable resin 414, and the fact that such an attempt has been made remains as a trace.

In this embodiment, the sealing pin 400 is described as being used for sealing the connection between the first box 200 and the second box 300 forming the substrate box 30, but the present invention is not limited to this. The present invention can be applied to sealing, or can also be applied to sealing of a connection portion between a main board 23 and a wiring connector in a board box.
In this embodiment, the number of sealing portions is three (34a, 34b, 34c). However, the number of sealing portions can be further increased. Since, for example, white and other lighting colors can be obtained as a whole by combining the intensities, a plurality of different lighting colors that are equal to or greater than the number of sealing portions may be set.

In addition, the history display mode of the seal release is not only a simple change of the lighting color, for example, “red → blue → green → white” at the first seal, and “red → white → blue → after the first seal release”. After the second seal release, it is possible to change the order of continuous color changes such as “red → green → white → blue”. In this case, it is also effective for fraud in which only the LED is replaced with the one that should be properly lit.
Alternatively, the flashing speed may be changed from low speed → medium speed → high speed in accordance with the number of times of seal release as a mode for displaying the history of seal release. According to this, since monochromatic LED can be used, cost is reduced.

  In the embodiment, the history display mode of the seal release is based on a program stored in the control circuit 483 in advance, but the mode may be switched at the next seal.

Next, a second embodiment will be described. In the first embodiment, the lighting color of the sealing pin is changed. However, in this embodiment, the shape of the sealing pin is changed. Instead of the main board unit 20, a main board unit 20 </ b> A in which the structure of the sealing part at the lower end of the board box is changed is provided.
Below, a different part from 1st Example is demonstrated.

First, the configuration of the main board unit 20A will be described in detail.
21 is a front view of the main board unit, and FIG. 22 is an exploded perspective view of the pedestal device.
The main board unit 20 </ b> A includes a main control device 22 </ b> A and a pedestal device 25 </ b> A that supports the main control device on the housing body 2.
The main controller 22A is a horizontally long rectangular substrate box 30A constituted by a pair of front and back first boxes 200A and second boxes 300A each formed of a transparent or translucent resin, and accommodated in the substrate box 30A. And a flat main substrate 23A (see FIG. 23).
Details of the main controller 22A will be described later.

As shown in FIG. 22, the pedestal device 25A includes a fixed base portion 26A that is fixed to the back plate 2c of the housing body 2, and a rotation center axis Z that is supported by the fixed base portion 26A and extends horizontally (see FIG. 21). ) And a movable base portion 28A that can be tilted up and down to take a tilted posture.
The fixed base portion 26A is formed with a rectangular cutout portion 60 for receiving a sealing block portion 100 protruding from the back surface of the movable base portion 28A, which will be described later, at the center in the lateral width direction below the bottom plate portion 40.
Other configurations of the fixed base portion 26A are the same as those of the fixed base portion 26 of the first embodiment.
When the fixed base portion 26A is viewed from the rear, the cutout portion 60 is covered by the mounting frame member 48 (see FIG. 6).

Next, the movable base portion 28A will be described.
The movable base portion 28 </ b> A is formed with two sealing block portions 100 adjacent to the two window holes 107 at the lower end of the bottom plate portion 80 toward the center in the lateral width (left-right) direction.
The sealing block portion 100 protrudes on the back surface side of the bottom plate portion 80 and also protrudes on the placement portion 82.
Each of the sealing block portions 100 forms a space between the front wall 102 on the mounting portion 82 and the rear wall 103 (see FIG. 32 described later) on the back surface side of the bottom plate portion 80 and opens at the lower end.
Two locking holes 104 into which sealing pins 430 described later are inserted are provided in the front wall 102 protruding on the mounting portion 82 of the sealing block portion 100. The locking hole 104 has a notch 105 at the top and bottom.
The space in the sealing block 100 is divided into sections 101 a and 101 b corresponding to the two locking holes 104. (See FIGS. 32 and 34)

  A metal plate reinforcing plate 130 </ b> A is attached to the upper surface of the mounting portion 82. The reinforcing plate 130A has a length extending between the left and right slit grooves 90 of the mounting portion 82 and extends upward from the rear end of the flat plate portion 132, and the flat plate portion 132 superimposed on the upper surface of the mounting portion 82. A vertical wall 134 superimposed on the surface of the bottom plate portion 80 and a shaft support plate portion 136 that extends downward from both left and right ends of the flat plate portion 132 and is inserted into the slit groove 90 are provided.

The vertical wall 134 is sandwiched between two window holes 142 to form a notch hole 140 that covers the two sealing block portions 100, and in the range of the notch hole 140, the flat plate portion 132 is from the back surface of the vertical wall 134. It extends rearward and covers the opening of the space formed in the sealing block portion 100 in a state where the reinforcing plate 130A is fixed to the movable base portion 28A.
Other configurations of the movable base portion 28A are the same as those of the movable base portion 28 of the first embodiment, and other configurations of the pedestal device 25A are the same as those of the pedestal device 25 of the first embodiment.

Next, the configuration of main controller 22A will be described.
FIG. 23 is an exploded perspective view of the main controller 22A, and FIG. 24 is a perspective view showing the back surface of the first box 200A.
The board box 30A is composed of a first box 200A on the front side and a second box 300A on the back side.
The main board 23A is mounted with various electronic components including an IC chip such as a CPU and a ROM, a socket and the like, but unlike the main board 23 of the first embodiment, the main board 23A does not have the overhanging portion 150, and the whole The shape is rectangular.

At the lower end portion of the first box 200A, a connection fixing portion 215 is set on the back surface (second box side) between a square hole portion 241 and a notch recess portion 221 described later. On the back surface of the first box 200A, a surrounding wall 217 having a predetermined height is provided that partitions the connection fixing portion 215 and opens upward.
The second box 300A is provided with a rectangular fixing block 304 corresponding to the connection fixing portion 215 of the first box 200A. In the coupled state of the first box 200A and the second box 300A, a screw (not shown) is screwed into the screw hole 216 of the connection fixing part 215 from the hole 305 of the fixing block 304, whereby the first box 200A and the second box 300A are connected. Fixed to each other.
The configuration of the substrate box 30A other than the sealing portion described in detail below is the same as that of the substrate box 30 of the first embodiment.

As shown in FIG. 21, at the lower end of the substrate box 30A, as a sealing part, a first sealing part 35, a second sealing part 36, and a third sealing part 37 are sequentially arranged adjacently in the horizontal direction from the left side, The 3rd sealing part 37 is located in the left-right direction center. In the vicinity of the part, symbols A to C are attached to indicate the order of sealing.
The first sealing portion 35 and the second sealing portion 36 (A, B) are for sealing and coupling the substrate box 30A to the movable base portion 28A, and the third sealing portion 37 (C) is the first box 200A and the second sealing portion. The box 300A is sealed and joined.

In FIG. 23, the first box 200A is formed with rectangular hole portions 241, 261, and 241 aligned in one row in the left-right direction, with portions corresponding to the rectangular recesses 220 in the first embodiment partitioned by partition walls 261 a.
The square hole portion 241 has a bottom wall 242 (see FIG. 25).
A partition wall 261a sandwiching the square hole portion 261 extends forward and backward by interrupting the bottom wall 242, and a rear end is connected by a cover wall 270A parallel to the bottom wall 242, and on the back side of the bottom wall 242, as shown in FIG. In addition, a block receiving portion 219A that is open upward and closed at the lower end is formed.

25A and 25B are enlarged views showing the periphery of the sealing portion of the first box 200A. FIG. 25A is a front view, and FIG. 25B is a sectional view taken along the line F-F in FIG. FIGS. 26A, 26B, and 26C are cross-sectional views taken along lines GG, HH, and JJ, respectively, in FIG.
In order to form the first and second sealing portions 35 and 36, the left square hole portion 241 is provided with a sealing member (tubular bodies 500 and 510), and in order to form the third sealing portion 37, the corner at the center of the row A sealing member (tubular body 520) is provided in the hole 261.

The cylindrical body 500 constituting the sealing member of the first sealing portion 35 is disposed in the left-side square hole portion 241 with the axis as the front-rear direction, and at the front end portion thereof, the upper and lower fragile connecting portions 244a are connected to the upper side of the square hole portion 241. It is connected to the inner wall and the lower inner wall. When the connection part 244a is viewed from the front, the connection part with the cylindrical body 500 is particularly thin and the cross-sectional area is small.
The rear end of the cylindrical body 500 is located in front of the bottom wall 242.
The bottom wall 242 of the square hole portion 241 has a hole 243a cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 500 and the connecting portion 244a when viewed from the front. Since the bottom wall 242 is not directly connected to the cylindrical body 500, the cylindrical body 500 can be cut off by cutting the connecting portion 244a.

The cylindrical body 500 has a cylindrical hole 502 having a constant inner diameter into which a sealing pin 430 described later is inserted, and a bottom wall 503 having a small diameter hole 504 at the rear end.
The length of the cylindrical hole 502 is such that the front end of the first pin 432 and the front end of the cylindrical body 500 are aligned when the rear end of the large-diameter portion 433 of the first pin 432 of the sealing pin 430 is brought into contact with the bottom wall 503. And set to be flush with each other.
In particular, as shown in FIG. 26A, a key groove 506 is formed over the entire length in the axial direction at the upper end of the cylindrical hole 502, and the key groove 506 extends to the bottom wall 503.
On the outer peripheral surface of the cylindrical body 500, a key rib 508 protruding in the horizontal right direction at a position perpendicular to the line connecting the upper and lower connecting portions 244a extends from the front end for a predetermined length.

Next, the cylindrical body 510 that forms the sealing member of the second sealing portion 36 is also disposed in the square hole portion 241 with the axis in the front-rear direction, and at the front end portion of the square hole portion 241 by the upper and lower fragile connecting portions 244b. It is connected to the upper inner wall and the lower inner wall.
The front end of the cylindrical body 510 is in the same position as the front end of the cylindrical body 500 in the front-rear direction (axial direction).
When the connection part 244b is viewed from the front, the connection part with the cylindrical body 510 is particularly thin and the cross-sectional area is small.

The bottom wall 242 of the square hole portion 241 has a hole 243b cut out in a shape having a predetermined gap with respect to the outline of the tubular body 510 and the connecting portion 244b when viewed from the front. The rear end of 510 is located in the hole 243b.
Since the bottom wall 242 is not directly connected to the cylindrical body 510, the cylindrical body 510 can be excised by cutting the connecting portion 244b.
The cylindrical body 510 has a cylindrical hole 512 having an inner diameter matching the cylindrical outer diameter of the cylindrical body 500, and a bottom wall 513 having a small diameter hole 514 at the rear end. The diameter of the small diameter hole 514 is the same as that of the small diameter hole 504.
The length from the opening of the cylindrical hole 512 to the front surface of the bottom wall 513 is set to be the same as the axial length of the cylindrical body 500.

A key groove 516 is formed at the right end when viewed from the front of the cylindrical hole 512 in the axial direction from the front end, and grooves 517 are formed at the upper and lower ends on the line perpendicular to the horizontal line connecting the shaft center and the key groove 516 from the front end. It is formed in the axial direction.
The keyway 516 has a size that can receive the entire length of the key rib 508 of the cylindrical body 500.
The groove 517 has a size that can accept a cut mark (stump) of the connecting portion 244a remaining in the cylindrical body 500 after being cut out from the square hole portion 241 as will be described later.
A key rib 518 extends in the axial direction from the front end to a predetermined length on the outer peripheral surface of the cylindrical body 510 so as to overlap the key groove 516.

The cylindrical body 520 that forms the sealing member of the third sealing portion 37 is disposed in the square hole portion 261 with the axis as the front-rear direction.
The partition wall 261 a that defines the square hole portion 261 has a front end that extends to the front of the front ends of the cylindrical bodies 500 and 510. The front end portion of the cylindrical body 520 is connected to the front end portion of the partition wall 261a by the left and right fragile connecting portions 244c. Therefore, the front end is located in front of the front ends of the cylindrical bodies 500 and 510.
The cylindrical body 520 can be excised by cutting the connecting portion 244c.

The cylindrical body 520 has a cylindrical hole 522 having an inner diameter that matches the cylindrical outer diameter of the cylindrical body 510, and a bottom wall 523 having a small diameter hole 524 at the rear end. The diameter of the small diameter hole 524 is the same as that of the small diameter holes 504 and 514.
The length from the opening of the cylindrical hole 522 to the front surface of the bottom wall 523 is set to be the same as the axial length of the cylindrical body 510.

A key groove 526 is formed in the axial direction from the front end at the right end when viewed from the front of the cylindrical hole 522, and the groove 527 is formed in the axial direction from the front end at the upper and lower ends on a line perpendicular to the horizontal line connecting the shaft center and the key groove 526. Is formed.
The key groove 526 has a size that can receive the entire length of the key rib 518 of the cylindrical body 510.
As will be described later, the groove 527 has a size capable of receiving a cut mark of the connecting portion 244b remaining in the cylindrical body 510 after being cut out from the square hole portion 241.
On the bottom wall 223 of the block receiving portion 219A surrounded by the partition wall 261a and the cover wall 270A is a square hole-shaped hook receiver 208 that receives a hook 314 (see FIG. 27) extending from a rectangular block 341 of the second box 300A described later. Is formed.

Next, FIG. 27 is an enlarged view showing the periphery of the sealing portion of the second box 300A, (a) is a front view, and (b) is a sectional view taken along the line KK in (a). FIG. 28 is a cross-sectional view taken along line LL in FIG.
In the center of the notch space 320 of the second box 300A, a rectangular block 341 first extends downward from the upper wall 321 in correspondence with the cylindrical body 520 of the first box 200A, and cover plate portions 334 are downward on both sides thereof. It extends to.

The cover plate portion 334 is offset forward from the back surface of the bottom plate portion 301 so as to correspond to the sealing block portion 100 of the movable base portion 28A. When the substrate box 30A is placed on the movable base portion 28A, the cover plate portion 334 is sealed. It is set so that the surface of the front wall 102 of the stop block portion 100 and the back surface of the cover plate portion 334 are in contact with each other.
The left cover plate portion 334 is formed with a U-shaped notch 335a that passes a rear end of a sealing pin 430, which will be described later, corresponding to the cylindrical body 500 of the first box 200A. Corresponding to 510, a U-shaped notch 335b is similarly formed. Corresponding to the cylindrical body 510 having a larger diameter than the cylindrical body 500, the notch 335b is larger than the notch 335a.

The rectangular block 341 is connected to the upper wall 321 so as to surround the three sides of the front wall 342 and the front wall 342 extending downward in parallel with the sliding surfaces of the first box 200A and the second box 300A. The front wall 342 is provided with a locking hole 344 into which a sealing pin 430 described later is inserted. The locking hole 344 has a notch 345 at the top and bottom. The diameter of the locking hole 344 is the same as the locking hole 104 of the sealing block portion 100 in the movable base portion 28A.
A hook 314 extending downward is formed at the lower end of the rectangular block 341, and this hook 314 is attached to a hook receiver 208 (see FIG. 25) formed on the bottom wall 223 of the block receiving portion 219A of the first box 200A. It is designed to be plugged in.

A slit 336 is formed between the side wall 322 (fixed block 304) and the cover plate portion 334 in the notch space 320 and between the cover plate portion 334 and the rectangular block 341, and the fixed portion 215 of the first box 200A. An enclosing wall 217 provided on the back surface and a partition wall 261 a that defines a square hole portion 261 can enter these slits 336. Accordingly, the first box 200A and the second box 300A are allowed to slide when the board box 30A is assembled.
First and second sealing portions 35 and 36 are formed at a joint portion between the two left cylindrical bodies 500 and 510 and the sealing block portion 100, and a cover is provided between each cylindrical body 500 and 510 and the sealing block portion 100. The plate portion 334 is sandwiched. In addition, a third sealing portion 37 is formed at the mating portion between the cylindrical body 520 at the right end and the rectangular block 341.

Next, the sealing pin 430 will be described.
FIG. 29 is an exploded perspective view of the sealing pin 430. The sealing pin 430 includes a cylindrical first pin 432 and a second pin 450 inserted into the first pin 432, and each is made of a resin such as PA, PP, POM, PC, or ABS.
FIG. 30 shows the first pin 432. (A) is a front view, (b) is a top view, (c) is a side view, (d) is a bottom view, (e) is a back view, and (f) is a cross-sectional view taken along line MM in (b). It is.
The first pin 432 has an outer shape composed of a large diameter portion 433 having a diameter corresponding to the cylindrical hole 502 of the cylindrical body 500 of the first box 200 </ b> A and a small diameter portion 434 having a diameter corresponding to the small diameter hole 504.
The large diameter portion 433 side is the front, and the small diameter portion 434 side is the rear.

An axial key rib 435 is formed on the outer peripheral surface of the first pin 432 over the entire length of the large diameter portion 433 and extends to the front end of the small diameter portion 434.
The key rib 435 corresponds to the key groove 506 of the cylindrical body 500. When the key rib 435 is aligned with the key groove 506, the first pin 432 can be pushed into the cylindrical hole 502 of the cylindrical body 500, and the key rib 435 and the key The position in the rotational direction is also fixed by the engagement of the groove 506.

The first pin 432 has a cylindrical hole 438 composed of a large diameter hole 439 and a small diameter hole 440 along the outer shape.
The large-diameter hole 439 is formed with a slit 441 that extends in the axial direction at a position 180 ° in the circumferential direction with respect to the key rib 435.
The small diameter portion 434 is provided with an elastic portion 443 in the left-right direction perpendicular to the up-down direction connecting the key rib 435 and the slit 441. The elastic portion 443 is surrounded by a U-shaped slit formed in the cylindrical wall of the small diameter portion 434, has a single shape extending from the large diameter portion 433 to the rear in the axial direction, and outward (left-right direction) at the rear end. ) Has a latching claw 444 projecting to).
The locking claw 444 has a locking surface 446 whose front end is perpendicular to the axial direction, and its rear outer surface has a cone shape coaxial with the small-diameter portion 434 and an inclined surface 445 whose tip is reduced in diameter to the diameter of the small-diameter portion 434. .

The distance from the front end of the first pin 432 to the locking surface 446 of the locking claw 444 is cylindrical when the substrate box 30A that combines the first box 200A and the second box 300A is placed on the movable base 28A. Corresponding to the distance from the front end of the body 500 to the back surface of the front wall 102 of the sealing block portion 100 in the movable base portion 28 </ b> A, the locking claw 444 is set to be locked to the back surface of the front wall 102.
On the upper and lower sides of the rear end of the small-diameter portion 434, a notch 447 that engages with a locking claw 456 of a second pin described later is provided.

FIG. 31 is a view showing the second pin 450. (A) is a front view, (b) is a top view, (c) is a side view, (d) is a rear view, and (e) is a sectional view taken along line NN in (b).
The second pin 450 includes a large-diameter portion 451 having a diameter that matches the large-diameter hole 439 of the first pin 432 and a small-diameter portion 452 having a diameter that matches the small-diameter hole 440, and the front end thereof is the large-diameter portion 451. And a cylindrical hole 453 that is closed at the front wall and opens at the rear end of the small diameter portion 452.
The length of the large diameter portion 451 corresponds to the length of the large diameter hole 439, and an axial key rib 454 corresponding to the slit 441 is formed over the entire length.

An elastic portion 455 extends rearward from the rear end of the small diameter portion 452. The elastic portion 455 has a locking claw 456 that protrudes outward (left-right direction) at the rear end. The locking claw 456 has a front end as a locking surface 458 perpendicular to the axial direction, and a rear outer surface of the elastic claw 456 includes a small-diameter portion 452. The inclined surface 457 has a coaxial cone shape and the tip is reduced in diameter to the diameter of the small diameter portion 452.
As shown in FIG. 31 (d), the elastic portions 455 are provided on opposite sides of the diameter line passing through the axis of the second pin 450 and the key rib 454.
When the second pin 450 is pushed in until the front end of the second pin 450 is flush with the front end of the first pin 432, the locking surface 458 is positioned on the bottom end surface of the notch 447 of the small-diameter portion 434. It is set to lock.

The first sealing is performed at the first sealing portion 35 (A).
When sealing, first, the first pin 432 in which an adhesive is applied to the outer peripheral surface of the large-diameter portion 433 is placed from the front end (rear end) of the cylindrical body 500 with the substrate box 30A placed on the movable base portion 28A. Then, the elastic portion 443 of the first pin 432 is bent in the inner diameter direction, and the small diameter portion 434 is in the small diameter hole while the locking claw 444 is retracted to the inner diameter of the small diameter hole 504 (see FIGS. 25 and 26). Enter 504.

When the key rib 435 (see FIG. 30) is further pushed in along the key groove 506 (see FIG. 25 and FIG. 26), the locking claw 444 follows the notch 335a of the cover plate portion 334 following the cylindrical body 500 and the sealing. Passing through the locking hole 104 of the front wall 102 in the stop block portion 100, the elastic portion 443 is restored and the locking claw 444 protrudes from the outer peripheral surface of the small diameter portion 434, and the locking surface 446 is formed on the back surface of the front wall 102. Lock (lock to the locking hole 104).
In this state, the front end of the first pin 432 is flush with the front end of the cylindrical body 500.
(A) of FIG. 32 shows the state which inserted the 1st pin 432 in the cylindrical body 500, (b) is PP sectional drawing in (a).

Next, when the second pin 450 is inserted into the first pin 432 from the front end (rear end), the elastic portion 455 of the second pin 450 is bent in the inner diameter direction, and the locking claw 456 is moved into the small diameter hole 440 (FIG. 30), the small diameter portion 452 (see FIG. 31) enters the small diameter hole 440.
When the locking claw 456 reaches the notch 447 at the rear end of the small diameter portion 434 of the first pin 432, the elastic portion 455 is restored, and the locking claw 456 protrudes from the outer peripheral surface of the small diameter portion 452, The surface 458 engages with the bottom end surface of the notch 447.
FIG. 32 (c) is a view showing a seal coupling state in which the insertion of the second pin 450 into the first pin 432 is completed.

Since the front end of the second pin 450 is flush with the front end of the first pin 432, the second pin 450 cannot be pulled out after that, so that the second pin 450 is held in the first pin 432. Therefore, the elastic portion 443 cannot be bent to unlock the locking claw 444 and the front wall 102 of the sealing block portion 100.
Further, the locking hole 104 of the front wall 102 where the locking claw 444 of the first pin 432 is locked has a notch 105 through which the locking claw 444 can pass up and down, but the first pin 432. Since the rotation is restricted by the engagement of the key rib 435 and the key groove 506 and is adhered to the cylindrical body 500 with an adhesive, the locking claw 444 cannot be rotated to the notch 105 position.
Therefore, the locking claw 444 does not come off from the front wall 102 of the sealing block portion.

Further, only the lower end of the space of the sealing block portion 100 where the rear end of the sealing pin 430 including the locking claw 444 is located is open, but the movable base portion 28A is provided with a reinforcing plate 130A to close the opening. Therefore, the sealing pin 430 cannot be accessed from the opening by a driver or the like, and an external force cannot be applied to the locking claw 444.
Since the second box 300A is sandwiched between the first box 200A and the movable base portion 28A, the substrate box 30A is opened and the main substrate 23A is accessed unless the sealing of the first sealing portion 35 (A) is released. I can't do it.

In order to release the seal, the connecting portion 244a connecting the tubular body 500 to the upper inner wall and the lower inner wall of the square hole portion 241 is cut, the seal pin 430 is rotated together with the tubular body 500, and the movable base portion 28A. The sealing pin 430 is released from the sealing block 100 by aligning the locking claw 444 that is locked to the front wall 102 of the sealing block 100 with the notch 105 of the locking hole 104.
Thereafter, the substrate box 30A can be slid upward relative to the movable base portion 28A, removed from the movable base portion A, and opened.

As shown in FIG. 33, the sealing pin 430 released from the first sealing portion 35 (A) has its first pin 432 bonded integrally to the large-diameter portion 433 and the cylindrical body 500 outside the large-diameter portion. The diameter is enlarged.
In the figure, the cut mark (stump) of the connecting portion 244a is indicated by the same reference numeral 244a.
The code | symbol of the 1st pin which the outer diameter of this large diameter part expanded is set to 432L for identification.
Since the first pin 432L and the second pin 450 are not bonded to each other, the first pin 432L and the second pin 450 are separated from each other by releasing the locking claw 456 of the second pin 450 in the inner diameter direction after being released from the sealing block portion 100. Can do.

Next, the second sealing portion 36 (B) will be described.
Here, the substrate box 30A and the movable base portion 28A are sealed using the sealing pin 430 in which the large-diameter portion 433 of the first pin is enlarged after the first sealing portion 35 (A) is released.
First, the first pin 432L is inserted into the cylindrical body 510, and the locking claw 444 is locked in the locking hole 104 of the front wall 102 of the sealing block portion 100. The first pin 432L has the cylindrical body 500 fixed to the large-diameter portion 433. When the first pin 432L is inserted into the cylindrical body 510, an adhesive is applied to the peripheral surface of the cylindrical body 500 that is the outer periphery of the large-diameter portion. The key rib 508 is applied along the key groove 516 of the cylindrical hole 512 (see FIG. 25).
Thereafter, the second pin 450 is inserted into the first pin 432.
The insertion process of the sealing pin 430 (the first pin 432L and the second pin 450) is the same as the case where the first sealing portion 35 is sealed with the sealing pin 400.
FIGS. 34A and 34B show a seal coupling state by the sealing pin 430 in the second sealing portion 36, where FIG. 34A is a longitudinal sectional view, and FIG.

In a state where the locking claw 444 of the first pin 432L is locked in the locking hole 104 of the front wall 102 of the movable base portion 28A, the front ends of the first pin 432L and the second pin 450 are the front end of the cylindrical body 510. Further, the cut traces of the connecting portion 244a remaining on the cylindrical body 500 are accommodated in the upper and lower grooves 517 of the cylindrical hole 512.
As a result, the sealing pin 430 cannot be rotated from the front surface side, and the locking claw 444 in the sealing block portion 100 cannot be accessed from the back surface side in the same manner as the first sealing portion 35 (A). The substrate box 30A cannot be removed from the movable base portion 28A and opened.

In order to release the seal, the connecting portion 244b connecting the cylindrical body 510 to the upper inner wall and the lower inner wall of the square hole portion 241 is cut, and the sealing pin 430 is rotated together with the cylindrical body 510 to move the movable base portion 28A. The sealing pin 430 is released from the sealing block portion 100 by aligning the locking claw 444 locked to the front wall 102 of the sealing block portion 100 with the notch 105 of the locking hole 104.
As shown in FIG. 35, the sealing pin 430 released from the second sealing portion 36 (B) has a cylindrical body 510 integrally bonded to the outer periphery of the first pin 432L so that the outer diameter of the large diameter portion 433 is further increased. It has been expanded.
The code | symbol of the 1st pin which the outer diameter of this large diameter part 433 expanded further is set to 432LL for identification.

Next, the third sealing portion 37 (C) will be described.
Here, after the second sealing portion 36 (B) is released, the large-diameter portion 433 of the first pin 432 is further expanded to use the sealing pin 430 of the first box 200A and the second box 300A of the substrate box 30A. Seal the bond.
In a state where the first box 200A and the second box 300A are coupled, first, the first pin 432LL is inserted into the cylindrical hole 522 of the cylindrical body 520 from the front end (rear end). At this time, the key rib 518 of the cylindrical body 510 fixed to the outer periphery of the first pin 432L is set along the key groove 526 (see FIG. 25) of the cylindrical hole 522.
As in the first and second sealing portions 35 and 36, an adhesive can be applied to the peripheral surface of the cylindrical body 510 fixed to the outer periphery of the first pin 432L.

When the locking claw 444 passes through the small diameter hole 524 of the bottom wall 523 in the cylindrical body 520 and the locking hole 344 (see FIG. 27) of the front wall 342 of the rectangular block 341 in the process of entering the first pin 432LL. The elastic part 443 of the first pin 432LL bends in the inner diameter direction. Then, when the locking claw 444 passes through the locking hole 344 of the front wall 342, the elastic portion 443 is restored, the locking claw 444 protrudes from the outer peripheral surface of the small diameter portion 434, and the locking surface 446 is the back surface of the front wall 342. To be locked (locked to the locking hole 344).
Thereafter, the second pin 450 is inserted into the first pin 432LL.
FIG. 36A shows a sealing coupling state by the sealing pin 430 in the third sealing portion 37, and FIG. 36B is a cross-sectional view taken along the line RR in FIG. The movable base portion 28A is not shown.
The front ends of the first pin 432LL and the second pin 450 are flush with the front end of the cylindrical body 520, and the cut marks of the connecting portion 244b remaining in the cylindrical body 510 are formed in the grooves 527 above and below the cylindrical hole 522. Be contained.

Since the front end of the second pin 450 is flush with the front end of the first pin 432LL, the second pin 450 cannot be pulled out after that, and therefore the second pin 450 is held in the first pin 432LL. Therefore, the elastic portion 443 cannot be bent to unlock the locking claw 444 and the front wall 342 of the rectangular block 341.
Further, the locking hole 344 of the front wall 342 of the rectangular block 341 to which the locking claw 444 of the first pin 432LL is locked has a notch 345 (see FIG. 27) through which the locking claw 444 can pass vertically. However, since the rotation of the first pin 432LL is restricted by the engagement of the key rib 518 and the key groove 526, the locking claw 444 cannot be rotated to the notch 345 position.
Therefore, the locking claw 444 of the sealing pin 430 inserted from the first box 200A side does not come off from the front wall 342 of the rectangular block 341 in the second box 300A, and the coupling between the first box 200A and the second box 300A is released. It will never be done.

  Further, since the rectangular block 341 is surrounded by the block receiving portion 219A of the first box 200A, the locking claw 444 of the sealing pin 430 locked to the rectangular block 341 is accessed from the back side of the substrate box 30A. I can't. Therefore, the first box 200A and the second box 300A cannot be opened. For example, safety when returning the main board 23A to a manufacturer or the like can be ensured.

  The present embodiment is configured as described above. In the first sealing portion 35 that seals the coupling between the first box 200A and the movable base portion 28A with the second box 300A interposed therebetween, the cylindrical body 500 is attached to the first box 200A. The movable base portion 28A is provided with the sealing block portion 100, and has a locking claw 444 and is inserted into the cylindrical body 500 from the first box 200A side to the movable base portion 28A side. It has a sealing pin 430 that locks into the locking hole 104 of the front wall 102 of the sealing block portion 100 on the rear side of the cylindrical body 500 to obtain a sealing state, and the sealing pin 430 has the first pin 432 at the time of sealing. The outer shape of the first pin 432 is enlarged when the outer periphery and the cylindrical hole 502 of the cylindrical body 500 are fixed with an adhesive, and the cylindrical body 500 is cut off from the first box 200A to release the seal. In, of fraudulently obtained, the first box 200A and can not be applied to the same first sealing portion 35 in the second box 300A, it is possible to prevent fraud.

  Similarly, in the second sealing portion 36 that seals the connection between the first box 200A and the movable base portion 28A, the first box 200A is provided with a cylindrical body 510, and the diameter of the cylindrical hole 512 of the cylindrical body 510 is set to the cylindrical body 500. As for the sealing pin, the first pin 432L having the cylindrical body 500 fixed to the outer periphery is inserted into the cylindrical body 510, and the locking claw 444 is a sealing block on the rear side of the cylindrical body 510. The sealing pin 430 is locked between the outer periphery of the first pin 432L and the cylindrical hole 512 of the cylindrical body 510 with an adhesive during sealing, and is locked in the locking hole 104 of the front wall 102 of the portion 100. Since the outer shape of the first pin 432L is enlarged when the cylindrical body 510 is cut off from the one box 200A and the seal is released, the first seal in the first box 200A and the second box 300A that are illegally obtained is expanded. Can not be applied to part 35 or the second sealing section 36, it is possible to prevent fraud.

In the third sealing portion 37 that seals the connection between the first box 200A and the second box 300A, a cylindrical body 520 is provided in the first box 200A, and the diameter of the cylindrical hole 522 corresponds to the outer diameter of the cylindrical body 510. The second box 300A is provided with a rectangular block 341 having a locking hole 344 in the front wall 342, and the sealing pin is inserted into the cylindrical body 520 with the first pin 432LL having the cylindrical body 510 fixed to the outer periphery. The locking claw 444 is locked in the locking hole 344 of the front wall 342 of the rectangular block 341 on the rear side of the cylindrical body 520 and sealed.
In the first and second sealing portions 35 and 36, the second box 300A is sandwiched between the first box 200A and the movable base portion 28A, so that the coupling of the substrate box 30A including the first box 200A and the second box 300A is sealed. However, since the substrate box itself is sealed at the third sealing portion 37, safety when returning to the manufacturer or the like can be ensured.

As described above, also in this embodiment, the state of the sealing pin 430 changes every time the sealing is released, and the shape of the first pin 432, particularly the outer diameter of the large diameter portion 433, is sequentially increased. .
Therefore, even if the other board box 30A is destroyed and the sealing pin 430 is obtained illegally, the sealing pin is already configured illegally because the outer diameter of the first pin is already expanded like 432L or 432LL. Even a board box disguised as new cannot be inserted into the cylindrical body 500 of the first sealing section 35 (A), which is the initial sealing section, and inserted into the cylindrical bodies 510, 520 of the second or third sealing section. Therefore, it is easy to know that the board box is not properly formed.
In addition, at each sealing part, it is automatically prepared for the outside diameter of the sealing pin by applying an adhesive during the sealing operation of inserting the sealing pin into the cylindrical body, and in the circumferential direction in the fitting area with the cylindrical body Since the entire area can be used as an adhesive surface, a strong fixed state can be easily obtained.

  The sealing pin 430 can be configured in a small size because the same locking claw 444 is used in common in all the first to third sealing portions and no locking claw dedicated to each sealing portion is set. The cost can be reduced because the material can be manufactured, and the space of the sealing portion can be reduced.

  Even when the first pin 432LL of the sealing pin 430 is inserted into the cylindrical body 520 of the third sealing portion 37 (C), an adhesive is applied to the outer periphery of the cylindrical body 510 fixed to the first pin. If applied, the first pin of the sealing pin 430 after the sealing of the third sealing portion 37 is changed to a larger diameter to which the cylindrical body 520 is fixed. It cannot be inserted into any of the objects 500, 510, and 520.

In addition to the adhesive, the tubular bodies 500, 510, etc., which are sequentially fixed to the first pin 432 each time the seal is released, and the large-diameter portion 433, which is directly inside thereof, are engaged with each other in addition to the adhesive. Since the cross-section changing portions of the key rib 435 and the key groove 506 are formed, even if the outer cylindrical body 500 is scraped to obtain the first pin 432 illegally, for example, the key rib 435 is scraped off. It is difficult to restore and recover the first pin 432 having the same key rib shape as the initial state because the portion is damaged.
Not only a pair of key ribs and key grooves, but also a number of more fragile irregularities are provided on the adhesion surface between the members that are fixed to each other, the adhesion area increases, and the shape is easily damaged, such as having a sharp cross-section. Then, it becomes more difficult to scrape the outer cylindrical body, which is effective in preventing fraud. By setting such unevenness at the first pin 432 of the sealing pin 430 and the front end portion of each of the cylindrical bodies 500, 510, and 520, damage to the unevenness due to fraud is easily detected.

Next, a third embodiment will be described.
As in the second embodiment, the shape of the first pin 432 of the sealing pin 430 is enlarged each time the seal is released. In particular, the shape of the cylindrical body that is a sealing member in the sealing portion is changed. Is.
In addition, although it does not distinguish in particular by a code | symbol, compared with 2nd Example, in this example, the rear end of the 1st pin 432 is cut and the small diameter part 434 is slightly shortened.
The main board unit includes a board box 30B including a first box 200B and a second box 300B instead of the board box 30A in the second embodiment. Relatedly, the pedestal device 25A has a movable base portion 28B including a sealing block portion 100B instead of the movable base portion 28A, and the other configuration of the main substrate unit is the main substrate unit described in the second embodiment. Same as 20A.
Below, a different part from 2nd Example is demonstrated.

37A and 37B are enlarged views showing the periphery of the sealing portion of the first box 200B. FIG. 37A is a front view, and FIG. 37B is a cross-sectional view taken along the line S-S in FIG. (A), (b), and (c) of FIG. 38 are cross-sectional views of a TT portion, a U-U portion, and a V-V portion in FIG. 37 (a), respectively.
In order to form the first and second sealing portions 35 and 36 (A, B), the left square hole portion 241 is provided with a sealing member (tubular bodies 500B and 510B), and the third sealing portion 37 (C) is provided. In order to form, the sealing member (cylindrical body 520B) is provided in the square hole part 261 at the center of the row.

A partition wall 261a sandwiching the square hole portion 261 extends forward and backward by interrupting the bottom wall 242, and a rear end is connected by a cover wall 270B parallel to the bottom wall 242, and the block shown in FIG. Similar to the receiving portion 219A, a block receiving portion 219B that opens upward and has a closed lower end is formed.
Two protrusions 272 extending in the vertical direction are formed on the front surface of the cover wall 270B. The shortening of the small diameter portion 434 of the first pin 432 corresponds to the height of the protrusion 272 in the forward direction.
Although not particularly illustrated, the upper opening of the block receiving portion 219B extends forward from the block receiving portion 219A shown in FIG.

The cylindrical body 500 </ b> B that forms the sealing member of the first sealing portion 35 has a hollow pin shape similar to the first pin 432. The cylindrical body 500B is disposed in the square hole portion 241 with the axis in the front-rear direction, and is connected to the upper inner wall and the lower inner wall of the square hole portion 241 by the upper and lower weak connecting portions 244a at the front end portion thereof. When the connection part 244a is viewed from the front, the connection part with the cylindrical body 500B is particularly thin and the cross-sectional area is small.
The bottom wall 242 of the square hole portion 241 has a hole 243a cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 500B and the connecting portion 244a when viewed from the front.
The rear end of the cylindrical body 500B extends rearward through the hole 243a.
Since the bottom wall 242 is not directly connected to the cylindrical body 500B, the cylindrical body 500B can be removed by cutting the connecting portion 244a.

The cylindrical body 500B has an outer shape composed of a large diameter portion 530 and a small diameter portion 531 and has a cylindrical hole 532 composed of a large diameter hole 533 and a small diameter hole 534 along the outer shape.
The large-diameter portion 530 side is the front, and the small-diameter portion 531 side is the rear.
The inner diameters of the large-diameter hole 533 and the small-diameter hole 534 correspond to the outer diameters of the large-diameter portion 433 and the small-diameter portion 434 of the first pin 432 in the sealing pin 430, respectively, so that the sealing pin 430 can be inserted.
The length of the large-diameter hole 533 from the front opening end is set to be the same as the length of the large-diameter portion 433 of the first pin 432, and the rear end of the large-diameter portion 433 of the first pin 432 is connected to the large-diameter hole 533 and the small-diameter. When brought into contact with the stepped portion of the hole 534, the front end of the first pin 432 is aligned with the front end of the cylindrical body 500B so as to be flush with each other.

A key rib 508 that protrudes in the right and left direction at a position perpendicular to the line connecting the upper and lower connecting portions 244a extends from the front end to a predetermined length on the outer peripheral surface of the large diameter portion 530 of the cylindrical body 500B.
An axial keyway 506 is formed in the entire length of the large-diameter hole 533 and the stepped portion of the small-diameter hole 534.
The small diameter portion 531 is provided with an elastic portion 536 in the left-right direction. The elastic portion 536 is sandwiched between slits formed in the axial direction from the rear end of the cylindrical wall of the small diameter portion 531, has a single shape extending toward the rear in the axial direction with the large diameter portion 530 as the root, and outward ( It has a locking claw 537 protruding in the left-right direction). Here, the front end of the locking claw 537 coincides with the front end (rear end) of the small diameter portion 531.
The locking claw 537 has a locking surface 539 whose front end is perpendicular to the axial direction, its rear outer surface has a cone shape coaxial with the small diameter portion 531, and an inclined surface whose outer tip can be reduced to the diameter of the small diameter portion 531. 538.

Next, the cylindrical body 510B that forms the sealing member of the second sealing portion 36 (B) is also disposed in the square hole portion 241 with the axis in the front-rear direction, and the square hole is formed by the upper and lower fragile connecting portions 244b at the front end portion. The part 241 is connected to the upper inner wall and the lower inner wall.
The front end of the cylindrical body 510B is at the same position as the front end of the cylindrical body 500B in the front-rear direction (axial direction).
When the connection part 244b is viewed from the front, the connection part with the cylindrical body 510B is particularly thin and the cross-sectional area is small.

The bottom wall 242 of the square hole portion 241 has a hole 243b cut out in a shape having a predetermined gap with respect to the contour of the cylindrical body 510B and the connecting portion 244b when viewed from the front. The rear end of 510B extends rearward through the hole 243b.
Since the bottom wall 242 is not directly connected to the cylindrical body 510B, the cylindrical body 510B can be excised by cutting the connecting portion 244b.
The cylindrical body 510B is cylindrical in basic shape and has a cylindrical hole 540 having an inner diameter that matches the cylindrical outer diameter of the large diameter portion of the cylindrical body 500B.

A key groove 516 is formed in the axial direction from the front end at the right end when viewed from the front of the cylindrical hole 540, and the upper and lower ends on the line perpendicular to the horizontal (left and right) direction line connecting the shaft center and the key groove 516 from the front end. A groove 517 is formed in the axial direction.
The key groove 516 has a size that can receive the entire length of the key rib 508 of the cylindrical body 500B.
The groove 517 has a size that can accept a cut mark (stump) of the connecting portion 244a remaining in the cylindrical body 500B after being cut out from the square hole portion 241 as described later.
A key rib 518 extends in the axial direction from the front end by a predetermined length so as to overlap the key groove 516 on the outer peripheral surface of the cylindrical body 510B.

The cylindrical body 510 </ b> B is provided with an elastic portion 542 on a horizontal line that connects the axis and the key rib 518 when viewed from the front. The elastic portion 542 is sandwiched between slits formed in the axial direction from the rear end on the cylindrical wall of the cylinder, has a single shape extending from the front side to the rear in the axial direction, and protrudes outward (left and right direction) at the rear end. A locking claw 543 is provided. The front end of the locking claw 543 coincides with the front end (rear end) of the cylindrical body 510B.
The locking claw 543 has a locking surface 545 whose front end is perpendicular to the axial direction, has a cone shape coaxial with the cylindrical tube wall, and an inclined surface 544 whose outer tip can be reduced to the diameter of the cylinder.

The cylindrical body 520 </ b> B that forms the sealing member of the third sealing portion 37 (C) is disposed in the square hole portion 261 with the axis as the front-rear direction.
The partition wall 261a that defines the square hole portion 261 has a front end that extends to the front of the front ends of the cylindrical bodies 500B and 510B. The front end portion of the cylindrical body 520B is connected to the front end portion of the partition wall 261a by the left and right fragile connecting portions 244c. Therefore, the front end is located in front of the front ends of the cylindrical bodies 500B and 510B.
The cylindrical body 520B can be excised by cutting the connecting portion 244c.
The axial length of the cylindrical body 520B is shorter than that of the cylindrical body 510B, but has a cylindrical hole 550 having an inner diameter that matches the cylindrical outer diameter of the cylindrical body 510B.

A key groove 526 is formed at the right end when viewed from the front of the tube hole 550 in the axial direction from the front end over the entire length, and the front end at the upper and lower ends on a line perpendicular to the horizontal line connecting the shaft center and the key groove 526. A groove 527 having a predetermined length is formed in the axial direction.
The key groove 526 receives the entire length of the key rib 518 of the cylindrical body 510B.
As will be described later, the groove 527 has a size capable of receiving a cut mark of the connecting portion 244b remaining in the cylindrical body 510B after being cut from the square hole portion 241.
On the bottom wall 223 of the block receiving portion 219B surrounded by the partition wall 261a and the cover wall 270B, a hook receiver 208 that receives a hook 314 extending from a rectangular block 341B of the second box 300B described later is formed.

Next, FIG. 39 is an enlarged view showing the periphery of the sealing portion of the second box 300B, (a) is a front view, and (b) is a WW section sectional view in (a). 40 is a cross-sectional view taken along a line XX in FIG.
In the center of the notch space 320 of the second box 300B, a rectangular block 341B extends downward from the upper wall 321 in correspondence with the cylindrical body 520B of the first box 200B, and cover plates 334 are provided on both sides thereof. It extends to.

The cover plate portion 334 is offset forward from the back surface of the bottom plate portion 301 so as to correspond to the sealing block portion 100B of the movable base portion 28B. When the substrate box 30B is placed on the movable base portion 28B, the cover plate portion 334 is sealed. It is set so that the surface of the front wall 102 of the stop block portion 100B and the back surface of the cover plate portion 334 are in contact with each other.
The cover plate portion 334 is formed with a U-shaped notch 335c that allows the cylindrical body 500B of the first box 200B to pass therethrough, and similarly, a U-shaped notch 335d that allows the cylindrical body 510B to pass therethrough. Has been. Corresponding to the cylindrical body 510B having a larger diameter than the cylindrical body 500B, the notch 335d may be larger than the notch 335c.

The rectangular block 341B includes a front wall 342B extending downward in parallel with the sliding surfaces of the first box 200B and the second box 300B, and a frame wall 343B extending rearward along each of the three sides of the front wall 342B. The front wall 342B is provided with a locking hole 344B into which a later-described first pin 432KK of the sealing pin 430 is inserted.
In a state where the first box 200B and the second box 300B are coupled, the front wall 342B is located in front of the bottom wall 242 of the square hole portion 241 in the first box 200B.
The locking hole 344B has notches 345B symmetrically on an oblique diameter line. The diameter of the locking hole 344B corresponds to the outer diameter of the cylindrical body 510B. The position of the front wall 342B in the front-rear direction is such that when the cut cylindrical body 510B is inserted until the front end thereof is flush with the front end of the cylindrical body 520B, the locking claws 543 of the cylindrical body 510B are inserted into the locking holes 344B. It is set to lock.
A hook 314 to be inserted into the hook receiver 208 (see FIG. 38) of the first box 200B is formed at the lower end of the rectangular block 341B.

41A and 41B show a sealing block portion of the movable base portion 28B. FIG. 41A is a front view, and FIG. 41B is a cross-sectional view taken along the line YY in FIG.
The movable base portion 28B has the same right sealing block portion 100 as the sealing block portion of the second embodiment, but the left sealing block portion 100B has the first front wall 102B of the sealing block portion 100. The section 101b that is located behind the front wall 102 and that corresponds to the cylindrical body 510B has a second front wall 102C that protrudes slightly forward from the front wall 102.
The first front wall 102B in the section 101a corresponding to the cylindrical body 500B is formed with a locking hole 104 having a notch 105 in the vertical direction, and the second front wall 102C of the section 101b corresponding to the cylindrical body 510B is formed in the first front wall 102B. A locking hole 104K having a larger diameter than the locking hole 104 is formed corresponding to the outer diameter of the cylindrical body 500B. A notch 105K through which the locking claw 537 of the cylindrical body 500B can pass is formed above and below the locking hole 104K.

In a state where the substrate box 30B in which the first box 200B and the second box 300B are joined is placed on the movable base portion 28B, the rear end of the cylindrical body 500B is on the front surface of the first front wall 102B in the sealing block portion 100B. It is supposed to be located.
When the first pin 432 is inserted until its front end is flush with the front end of the cylindrical body 500B, the locking claw 444 of the first pin 432 is set to be locked in the locking hole 104. .
The rear end of the cylindrical body 510B is positioned on the front surface of the second front wall 102C in the sealing block portion 100B.
Then, when the separated cylindrical body 500B is inserted until its front end is flush with the front end of the cylindrical body 510B, the locking claw of the cylindrical body 500B is set to be locked in the locking hole 104K. Yes.
Other configurations are the same as those of the second embodiment.

The first sealing is performed by the first sealing unit 35 (A).
First, the 1st pin 432 which apply | coated the adhesive agent to the outer peripheral surface of the large diameter part 433 is inserted until the front end becomes flush with the front end of the cylindrical body 500B. Thereby, the locking claw 444 of the first pin 432 is locked to the locking hole 104 of the first front wall 102B in the sealing block portion 100B of the movable base portion 28B.
Thereafter, the second pin 450 is inserted into the first pin 432 to prohibit the unlocking of the locking claw 444 and the sealing block portion 100B.
42A and 42B show the seal coupling state in the first sealing portion 35, where FIG. 42A is a longitudinal sectional view, and FIG. 42B is a sectional view taken along the line AA-AA in FIG.
Thereby, the same sealing function as the 1st sealing part in 2nd Example is obtained.

To release the seal, the connecting portion 244a is cut and the sealing pin 430 is rotated together with the cylindrical body 500B to lock the locking claw 444 locked to the first front wall 102B of the sealing block portion 100B. By aligning with the notch 105 of the hole 104, the sealing pin 430 is released from the sealing block portion 100B.
As shown in FIG. 43, the sealing pin 430 released from the first sealing portion 35 (A) has an enlarged outer shape as the first pin 432 is integrally bonded to the large diameter portion 433 and the cylindrical body 500B. It has become.
The code of the first pin whose outer shape is enlarged is 432K for identification.

The next sealing is performed by the second sealing part 36 (B).
Here, the substrate box 30B and the movable base portion 28B are sealed using the sealing pin 430 whose outer shape of the first pin is enlarged after the first sealing portion 35 (A) is released.
First, the first pin 432K is coated with an adhesive on the outer periphery of the large-diameter portion of the cylindrical body 500B that is a part of the first pin 432K. insert.
When the locking claw 537 of the cylindrical body 500B passes through the locking hole 104K of the second front wall 102C in the sealing block portion 100B, the elastic portion 536 bends in the inner diameter direction.
When the locking claw 537 passes through the locking hole 104K of the second front wall 102C, the elastic portion 536 is restored and the locking surface 539 of the locking claw 537 is locked to the back surface of the second front wall 102C (the locking hole). To 104K).
In this state, the front end of the first pin 432K is flush with the front end of the cylindrical body 510B.
Thereafter, the second pin 450 is inserted into the first pin 432.

44A and 44B show a seal coupling state in the second seal portion 36 (B), where FIG. 44A is a longitudinal sectional view, and FIG. 44B is a sectional view taken along the line AB-AB in FIG.
Cut traces of the connecting portion 244a remaining in the cylindrical body 500B of the first pin 432K are accommodated in the upper and lower grooves 517 of the cylindrical hole 540.
The portion of the movable base portion 28B on the side of the sealing pin 430 that is locked with the sealing block portion 100B is changed from the locking claw 444 of the first pin 432 to the locking claw 537 of the cylindrical body 500B fixed to the first pin 432. The sealing function is the same as that of the second sealing part in the second embodiment only by replacing.

To release the seal, the connecting portion 244b connecting the cylindrical body 510B to the upper inner wall and the lower inner wall of the square hole portion 241 is cut, the sealing pin 430 is rotated together with the cylindrical body 510B, and the sealing block portion The sealing pin 430 is released from the sealing block portion 100B by aligning the locking claw 537 locked to the second front wall 102C of the 100B with the notch 105K of the locking hole 104K.
As shown in FIG. 45, the sealing pin 430 released from the second sealing portion 36 (B) has a cylindrical body 510 </ b> B that is integrally bonded to expand the outer shape of the first pin 432.
The code of the first pin whose outer shape is enlarged is 432KK for identification.

In the third sealing portion 37 (C), the second box 200 B and the second box 200 B of the substrate box 30 B are used by using the sealing pin 430 whose outer shape of the first pin is further enlarged after the second sealing portion 36 (B) is released. The bond of box 300B is sealed.
First, the first pin 432KK is inserted into the cylindrical body 520B by bending the elastic portion 542 of the cylindrical body 510B, which is a part of the first pin 432KK, and the key rib 518 is inserted along the key groove 526 of the cylindrical hole 550.
Also at this time, as in the first and second sealing portions 35 and 36, the adhesive can be applied to the peripheral surface in the vicinity of the front end of the cylindrical body 510B fixed to the outer periphery of the first pin 432KK.

When the locking claw 543 passes through the locking hole 344B of the front wall 342B of the rectangular block 341B following the cylindrical body 520B by bending of the elastic portion 542, the elastic portion 542 is restored and the locking surface of the locking claw 543 is restored. 545 is locked to the back surface of the front wall 342B (locked to the locking hole 344B).
Thereafter, the second pin 450 is inserted into the first pin 432KK.
46A and 46B show the seal coupling state in the third sealing portion 37 (C), where FIG. 46A is a longitudinal sectional view and FIG. 46B is a sectional view of the AC-AC portion in FIG. The movable base portion 28B is not shown.
When the locking surface 458 of the locking claw 456 in the second pin 450 is locked to the bottom end surface of the notch 447 of the first pin 432KK, the first pin 432KK (the large diameter portion 433, the cylindrical body 500B, and the cylindrical body 510B). ) And the second pin 450 are all flush with the front end of the cylindrical body 520B, and the cut marks of the connecting portion 244b remaining in the cylindrical body 510B are received in the upper and lower grooves 527 of the cylindrical hole 550. The

The portion of the second box 300B on the side of the sealing pin 430 that is locked to the rectangular block 341B is replaced by the locking claw 543 of the cylindrical body 510B that is fixed to the first pin 432 from the locking claw 444 of the first pin 432. Only the sealing function is the same as that of the third sealing portion in the second embodiment.
Although the cylindrical body 520B and the connecting portion 244c are relatively delicate with respect to the large-sized sealing pin 430, the cover wall 270B having high rigidity is formed by the protrusion 272 so that the rear end of the sealing pin 430 ( Since it abuts on and supports the small-diameter portion 434), there is no possibility of damaging the connecting portion 244c and the like when the sealing pin 430 is inserted.

  The present embodiment is configured as described above, and the first and second sealing portions 35 and 36 obtain a combined seal of the substrate box 30B and the movable base portion 28B, and the third sealing portion 37 seals the substrate box 30B itself. Thus, the same effect as in the second embodiment can be obtained.

Also in this embodiment, the outer shape of the first pin 432 of the sealing pin 430 is enlarged each time the sealing is released.
Therefore, even if another board box 30B is destroyed and a sealing pin is obtained illegally, the outer shape of the sealing pin has already been expanded as 432K or 432KK. Even the mounted board box cannot be inserted into the cylindrical body 500B of the first sealing portion 35, which is the initial sealing portion, and must be inserted into the cylindrical bodies 510B, 520B of the second or third sealing portion. It can be easily known that the board box is not properly formed.

  In this embodiment, in addition to the locking claw 444 of the first pin 432, the cylindrical bodies 500B and 510B of the sealing portions that are sequentially fixed to the first pin 432 are provided with the locking claws 537 and 543, respectively. In the second and subsequent sealing portions 36 and 37, the cylindrical locking claws 537 and 543 that are finally fixed to the sealing pins are the locking holes 104K or the rectangular shape of the second front wall 102C of the sealing block portion 100B. The block 341B is locked in the locking hole 344B of the front wall 342B. For this reason, the sealing pins to which the cylindrical bodies 500B and 510B are fixed have sequentially increased sizes of the locking claws, and even if they are used for the first sealing portion 35 in the illegally obtained board box, the cylindrical body 500B. The locking claw 537 does not fit the locking hole 104 of the first front wall 102B of the sealing block portion 100B, and the locking claw 543 fits the locking hole 104K of the second front wall 102C. Will make it difficult to cheat.

Note that when the first pin 432KK is inserted into the cylindrical body 520B of the third sealing portion 37, if the adhesive is applied to the outer periphery of the cylindrical body 510 fixed to the first pin, the third sealing is performed. The first pin after the sealing of the portion 37 is changed to a larger diameter to which the cylindrical body 520 is fixed. It will be impossible.
Therefore, the same effect as that of the second embodiment can be obtained.

Also in this embodiment, since the concave and convex cross-sections formed by the engagement of the key rib and the key groove are formed on the bonding surfaces between the members fixed to each other in each sealing portion, the key rib It is difficult to restore and recover the first pin 432 having the same key rib shape as the initial state because the portion is damaged.
In addition, it is possible to make it more difficult to recover and recover the first pin that is the same as the initial state by providing a more fragile unevenness on the bonding surface between the members fixed to each other. And by setting unevenness in the 1st pin of a sealing pin, and the front-end part of a cylindrical body, the damage of unevenness by an illegal act is easy to be discovered.

Next, a fourth embodiment will be described.
In the second and third embodiments, the shape of the sealing pin changes in the enlargement direction each time the seal is released, whereas the shape of the sealing pin changes in the reduction direction and is reused. .
The main board unit includes a board box 30C including a first box 200C and a second box 300C instead of the board box 30A in the second embodiment. Relatedly, the pedestal device 25A has a movable base portion 28C including a sealing block portion 100C instead of the movable base portion 28A, and the other configuration of the main substrate unit is the main substrate unit described in the second embodiment. Same as 20A. And the sealing pin 460 is used.
Below, a different part from 2nd Example is demonstrated.

First, the sealing pin 460 will be described.
47A is an external perspective view showing the sealing pin 460, and FIG. 47B is a rear view seen from the rear.
The sealing pin 460 is composed of a plurality of pin members, here, three pin members, and is integrally formed as shown in FIG.
The outermost pin member 461a includes a cylindrical portion 462a having a predetermined length, and an elastic leg 463a that extends in the axial direction from the cylindrical portion 462a while maintaining the wall thickness of the cylindrical portion and includes a locking claw 464a at the tip.
The locking claw 464a has a locking surface 466a perpendicular to the axial direction at the front end, an outer surface of the rear portion of the locking claw 464a having a cone shape coaxial with the cylindrical portion 462a, and an inclined surface whose tip is reduced in diameter to near the outer diameter of the cylindrical portion 462a. 465a.
Two elastic legs 463a are formed at symmetrical positions on the diameter line of the cylindrical portion 462a with the axis interposed therebetween.
A key rib 469a having a predetermined axial length from the front end is formed on the outer peripheral surface of the cylindrical portion 462a. In the circumferential direction of the cylindrical portion 462a, the key ribs 469a are positioned so as to overlap the elastic legs 463a, respectively.

As shown in FIG. 54, the second pin member 461b from the outside includes a cylindrical portion 462b having a predetermined length, and extends in the axial direction from the cylindrical portion 462b while maintaining the wall thickness of the cylindrical portion, and is a locking claw at the tip. It consists of elastic legs 463b with 464b.
The outer diameter of the cylindrical portion 462b is smaller than the inner diameter of the cylindrical portion 462a.
Two elastic legs 463b are formed at symmetrical positions on the diameter line of the cylindrical portion 462b with the axis interposed therebetween.
Each locking claw 464b has a locking surface 466b perpendicular to the axial direction at the front end, a rear outer surface having a cone shape coaxial with the cylindrical portion 462b, and a tip whose diameter is reduced to near the outer diameter of the cylindrical portion 462b. The surface is 465b.
A key rib 469b having a predetermined axial length from the front end is formed on the outer peripheral surface of the cylindrical portion 462b at a symmetrical position on the diameter line of the cylindrical portion 462b.
As shown in FIG. 47 (b), when viewed from the axial direction, the straight line connecting the two elastic legs 463b (locking claws 464b) is inclined 60 ° to the right with respect to the straight line connecting the two key ribs 469b. is doing.

The innermost, that is, the central pin member 461c includes a columnar portion 467 having a predetermined length and an engaging claw 464c extending from the rear end of the columnar portion 467 in the axial direction as shown in FIG. It consists of elastic legs 463c.
The outer diameter of the cylindrical portion 467 is smaller than the inner diameter of the cylindrical portion 462b.
Two elastic legs 463c are formed on the diameter line of the cylindrical portion 467 at symmetrical positions with the axis centered therebetween.
Each locking claw 464c has a locking surface 466c perpendicular to the axial direction at the front end, a rear outer surface having a cone shape coaxial with the columnar portion 467, and a tip whose diameter is reduced to near the outer diameter of the columnar portion 467. The surface is 465c.
A key rib 469 c having a predetermined axial length from the front end is formed on the outer peripheral surface of the cylindrical portion 467 at a symmetrical position on the diameter line of the cylindrical portion 467.
As shown in FIG. 47 (b), when viewed from the axial direction, the straight line connecting the two elastic legs 463c (locking claws 464c) is inclined 60 ° to the left with respect to the straight line connecting the two key ribs 469c. is doing.

The pin members 461a, 461b and 461c are coaxial with each other so that their front ends coincide with each other, and each key rib is aligned on a straight line passing through the axial center, and two pin members are provided symmetrically on a line perpendicular to the straight line. The connecting portions 468a and 468b are connected as shown in FIG. 47 (a).
As a result, the directions of the straight lines connecting the two elastic legs (and therefore the locking claws) of each pin member are different by 60 °.

48 is an enlarged view showing the periphery of the sealing portion of the first box 200C, (a) is a front view, (b) is a cross-sectional view of the AD-AD portion in (a), and (c) is a cylindrical body in (a). It is an enlarged view of 520C. 49A, 49B, and 49C are cross-sectional views of the AE-AE part, the AF-AF part, and the AG-AG part in FIG. 48A, respectively.
In order to form the first and second sealing portions 35 and 36, the left square hole portion 241 is provided with sealing members (tubular bodies 500C and 510C), and in order to form the third sealing portion 37 (C), a row A sealing member (cylindrical body 520 </ b> C) is provided in the central square hole portion 261.

The partition wall 261a that defines the square hole portion 261 extends rearward across the bottom wall 242, has a rear end connected by a rear wall 270C parallel to the bottom wall 242, and opens upward on the back side of the bottom wall 242, and has a lower end. Forms a closed block receiving portion 219C.
A hook receiver 208 that receives a hook 314 extending from a rectangular block 341C of the second box 300C described later is formed on the bottom wall 223 of the block receiver 219C.
The bottom wall 242 in the square hole portion 261 is slightly thinner than in the square hole portion 241, and the rear surface (back surface) is offset forward.

The cylindrical body 500C is disposed in the left-side square hole portion 241 with the axis in the front-rear direction, and is connected to the upper inner wall and the lower inner wall of the square hole portion 241 by upper and lower fragile connecting portions 244a at the front end portion thereof.
The rear end of the cylindrical body 500 </ b> C is located on the front surface of the bottom wall 242.
The bottom wall 242 of the square hole portion 241 has a hole 243Ca cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 500C and the connecting portion 244a when viewed from the front. Since the bottom wall 242 is not directly connected to the cylindrical body 500C, the cylindrical body 500C can be cut by cutting the connecting portion 244a.

The cylindrical body 500C has a cylindrical hole 502C having a constant inner diameter into which the sealing pin 460 is inserted, and a bottom wall 503C having a small diameter hole 504C.
The length from the opening of the cylindrical hole 502C to the front surface of the bottom wall 503C is set to be the same as the length of the cylindrical portion 462a of the pin member 461a in the sealing pin 460, and the rear end of the cylindrical portion 462a When inserted until it comes into contact with 503C, the front end of the sealing pin 460 and the front end of the cylindrical body 500C are aligned and flush with each other.
In the small diameter hole 504C of the bottom wall 503C, a notch 505C through which the elastic leg 463a of the pin member 461a passes is formed on a straight line in the left-right direction passing through the axis.
An axial key groove 506C for receiving the key rib 469a of the pin member 461a is formed at the left and right ends of the cylindrical hole 502C.

Next, the cylindrical body 510C that forms the sealing member of the second sealing portion 36 (B) is also disposed in the square hole portion 241 with the axis in the front-rear direction, and the square hole is formed by the upper and lower weak connecting portions 244b at the front end portion. The portion 241 is connected to the upper inner wall and the lower inner wall.
The front end of the cylindrical body 510C is in the same position as the front end of the cylindrical body 500C in the front-rear direction (axial direction), and the rear end is positioned in front of the bottom wall 242 as in the cylindrical body 500C.

The bottom wall 242 of the square hole portion 241 has a hole 243Cb cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 510C and the connecting portion 244b when viewed from the front.
Since the bottom wall 242 is not directly connected to the cylindrical body 510C, the cylindrical body 510C can be excised by cutting the connecting portion 244b.
The cylindrical body 510C has a cylindrical hole 512C that matches the outer diameter of the cylindrical portion 462b of the pin member 461b in the sealing pin 460, and a bottom wall 513C having a small diameter hole 514C at the rear end.
In the small diameter hole 514C of the bottom wall 513C, a notch 515C through which the elastic leg 463b of the pin member 461b passes is formed on a straight line passing through the axis in the left-right direction.

The length from the opening of the cylindrical hole 512C to the front surface of the bottom wall 513C is set to be the same as the length of the cylindrical portion 462b of the pin member 461b, and the pin is inserted when the rear end of the cylindrical portion 462b contacts the bottom wall 513C. The front end of the member 461b is aligned with the front end of the cylindrical body 510C.
A key groove 516C for receiving the entire length of the key rib 469b of the pin member 461b is formed at a symmetrical position across the axis in the axial direction from the front end of the cylindrical hole 512C, and a line connecting the key grooves 516C is with respect to a straight line in the vertical direction. And tilted 30 ° to the left.
Further, a groove 517C is formed on the front end face of the cylinder hole 512C on a line perpendicular to the line passing through the axis and connecting the key groove 516C. The groove 517C has a size that can accept a cut mark (stump) of the connecting portion 468a remaining on the pin member 461b after being separated from the pin member 461a as described later.

The cylindrical body 520C that forms the sealing member of the third sealing portion 37 (C) is disposed in the square hole portion 261 with the axis in the front-rear direction, and the front end thereof is positioned forward of the front ends of the cylindrical bodies 500C and 510C. ing.
The bottom wall 242 of the square hole portion 261 has a hole 243Cc cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 520C and the connecting portion 244c when viewed from the front.
The rear end of the cylindrical body 520C extends in the hole 243Cc until it is flush with the back surface of the bottom wall 242.
The cylindrical body 520C is connected to the upper inner wall and the lower inner wall of the square hole portion 261 by upper and lower weak connecting portions 244c at the front end thereof. The cylindrical body 520C can be excised by cutting the connecting portion 244c.

The cylindrical body 520C has a cylindrical hole 522C that matches the outer diameter of the cylindrical portion 467 of the pin member 461c in the sealing pin 460, and a bottom wall 523C having a small diameter hole 524C at the rear end thereof.
In the small diameter hole 524C of the bottom wall 523C, a notch 525C through which the elastic leg 463c of the pin member 461c passes is formed on a straight line passing through the axis in the left-right direction.
The length from the opening of the cylindrical hole 522C to the front surface of the bottom wall 523C is set to be the same as the length of the columnar portion 467 of the pin member 461c. The front end of the member 461c is aligned with the front end of the cylindrical body 520C.

A key groove 526C for receiving the entire length of the key rib 469c of the pin member 461c is formed at a symmetrical position across the axis in the axial direction from the front end of the cylindrical hole 522C. And tilted 30 ° to the right.
Further, a groove 527C is formed on the front end face of the cylindrical hole 522C on a line perpendicular to the line passing through the axis and connecting the key groove 526C. The groove 527C has a size that can accept a cut mark (stump) of the connecting portion 468b remaining on the pin member 461c after being separated from the pin member 461b as will be described later.

Next, FIG. 50 is an enlarged view showing the periphery of the sealing portion of the second box 300C, (a) is a front view, and (b) is a cross-sectional view of the AH-AH portion in (a). 51 is a cross-sectional view taken along line AJ-AJ in FIG.
In the center of the notch space 320 of the second box 300C, a rectangular block 341C first extends downward from the upper wall 321 in correspondence with the cylindrical body 520C of the first box 200C, and a cover plate part 334 is formed on both sides thereof. It extends to.

The cover plate portion 334 is offset forward from the back surface of the bottom plate portion 301 so as to correspond to the sealing block portion 100C of the movable base portion 28C. When the substrate box 30C is placed on the movable base portion 28C, the cover plate portion 334 is sealed. It is set so that the surface of the front wall 102 of the stop block portion 100C and the back surface of the cover plate portion 334 are in contact with each other.
The cover plate portion 334 is formed with U-shaped notches 335c and 335d corresponding to the cylindrical body 500C and the cylindrical body 510C, respectively.
Here, the notch 335c is set to a size that allows the elastic leg 463a (and 463b, 463c) of the sealing pin 460 inserted into the cylindrical body 500C of the first box 200C to pass, and the notch 335d is the first box 200C. The size is set to allow the elastic legs 463b (and 463c) of the sealing pin 460 inserted into the cylindrical body 510C to pass therethrough.

The rectangular block 341C includes a front wall 342C extending downward in parallel with the sliding surfaces of the first box 200C and the second box 300C, a frame wall 343C extending rearward along the three sides of the front wall 342C, and a locking hole 344C. And a rear wall 347.
The front wall 342C is disposed such that the front surface of the front wall 342C contacts the back surface of the bottom wall 242 in the square hole portion 261 of the first box 200C in a state where the first box 200C and the second box 300C are coupled.
The rear wall 347 has a circular front shape centered on the locking hole 344C, and the cylindrical wall 348 extends forward from the periphery thereof. The front end of the cylindrical wall 348 is flush with the front surface of the front wall 342C.
The rear wall 347 is connected to the upper wall 321 of the notch space 320 and the frame wall 343C by upper and lower connecting portions 349 in the cylindrical wall 348.

The locking hole 344C of the rear wall 347 has a diameter corresponding to the cylindrical portion 467 of the pin member 461c in the sealing pin 460, and has notches 345C symmetrically on the diameter line in the vertical direction. The notch 345C can pass through the locking claw 464c of the pin member 461c.
As will be described later, when the pin member 461c separated from the pin member 461b is inserted into the cylindrical body 520C until the cylindrical portion 467 contacts the bottom wall 523C, the elastic leg 463c passes through the locking hole 344C and its engagement. The pawl 464c is locked to the back surface of the rear wall 347 (locked to the locking hole 344C).

The front wall 342 </ b> C has a hole 346 cut out in a shape having a predetermined gap with respect to the contours of the rear wall 347 and the connecting portion 349 when viewed from the rear.
A hook 314 to be inserted into the hook receiver 208 of the first box 200C is formed at the lower end of the rectangular block 341C.

52A and 52B show the sealing block portion 100C of the movable base portion 28C, where FIG. 52A is a front view and FIG. 52B is a cross-sectional view of the AK-AK portion in FIG.
The front wall 102 of the sealing block portion 100C is formed with a locking hole 104Ca having a notch 105Ca in the vertical direction corresponding to the cylindrical body 500C in the section 101a. A locking hole 104Cb having a notch 105Cb is formed.
The locking hole 104Ca corresponds to the outer diameter of the cylindrical portion 462a of the pin member 461a, and the locking claw 464a of the pin member 461a can pass through the notch 105Ca.
The locking hole 104Cb corresponds to the outer diameter of the cylindrical portion 462b of the pin member 461b, and the locking claw 464b of the pin member 461b can pass through the notch 105Cb.

When the sealing pin 460 is inserted into the cylindrical body 500C until the cylindrical portion 462a of the pin member 461a abuts against the bottom wall 503C, the elastic leg 463a passes through the locking hole 104Ca and the locking claw 464a becomes the sealing block. It is locked to the back surface of the front wall 102 of the portion 100C (locked to the locking hole 104Ca).
Further, as will be described later, when the cylindrical portion 462b of the pin member 461b separated from the pin member 461a is inserted into the cylindrical body 510C until it abuts against the bottom wall 513C, the elastic leg 463b passes through the locking hole 104Cb and its engagement. The pawl 464b is locked to the back surface of the front wall 102 of the sealing block portion 100C (locked to the locking hole 104Cb).
Other configurations are the same as those of the second embodiment.

The first sealing is performed at the first sealing portion 35 (A).
At the time of sealing, an adhesive is applied to the outer peripheral surface of the cylindrical portion 462a of the pin member 461a while the substrate box 30C is placed on the movable base portion 28C, and is inserted into the cylindrical body 500C from the front end (rear end). Since the elastic leg 463a bends and the locking claw 464a at the tip enters, when the locking claw 464a is aligned with the notch 505C of the bottom wall 503C and the key rib 469a is further pressed into the key groove 506C, the locking claw 464a The cylindrical body 500C is engaged with the notch 335c in the cover plate portion 334 behind the cylindrical body 500C and the engagement hole 104Ca in the front wall 102 of the sealing block portion 100C.

During this time, the other locking claws of the sealing pin 460 are on the axial center side with respect to the diameter of the cylindrical portion 462a, and thus do not interfere with the bottom wall 503C of the cylindrical body 500C.
The rear end of the cylindrical portion 462a contacts the bottom wall 503C of the cylindrical body 500C, and the front end of the sealing pin 460 is flush with the front end of the cylindrical body 500C.
53 (a) is a longitudinal sectional view showing a sealing connection state by the sealing pin 460 in the first sealing portion 35 (A), and FIG. 53 (b) is a sectional view of the AL-AL portion in FIG. 53 (a).

The locking hole 104Ca of the front wall 102 where the locking claw 464a is locked has a notch 105Ca through which the locking claw can pass up and down. Since the rotation is restricted by the combination and the adhesive is adhered to the cylindrical body 500C, the locking claw 464a cannot be rotated to the position of the notch 105Ca.
Therefore, the locking claw 464a does not come off from the front wall 102 of the sealing block portion 100C.

The space of the sealing block portion 100C where the locking claw 464a of the sealing pin 460 is located is open only at the lower end, but the movable base portion 28C is provided with a reinforcing plate 130A including a flat plate portion 132 for sealing. Since the block portion 100C is a closed space, it cannot be accessed from the opening and an external force cannot be applied to the locking claw 464a by a driver or the like.
Since the second box 300C is sandwiched between the first box 200C and the movable base portion 28C, the substrate box 30C is opened to access the main substrate 23A unless the sealing of the first sealing portion 35 (A) is released. I can't do it.

To release the seal, the connecting portion 244a connecting the cylindrical body 500C to the upper inner wall and the lower inner wall of the square hole portion 241 is cut, and the sealing pin 460 is rotated together with the cylindrical body 500C to move the movable base portion 28C. The sealing pin 460 is released from the sealing block portion 100C by aligning the locking claw 464a locked to the front wall 102 of the sealing block portion 100C with the notch 105Ca of the locking hole 104Ca.
As a result, the substrate box 30C can be slid upward relative to the movable base portion 28C, removed from the movable base portion 28C, and opened.

The sealing pin released from the first sealing portion 35 (A) is obtained by expanding the outer diameter of the cylindrical portion 462a by integrally bonding the cylindrical body 500C to the outer periphery of the pin member 461a.
In this embodiment, the connecting portion 468a connecting the cylindrical portion 462a and the cylindrical portion 462b is cut from the sealing pin with a nipper or the like to remove the pin member 461a and the cylindrical body 500C, and the pin member as shown in FIG. A new sealing pin composed of 461b and a pin member 461c is used for the next sealing.
The new sealing pin has a reduced outer shape, and is used as a sealing pin 460S for identification.

Next, the second sealing portion 36 (B) that is the next sealing portion will be described.
Here, the substrate box 30C and the movable base portion 28C are sealed using the sealing pin 460S whose outer shape is reduced.
Since the sealing pin 460S has an outer periphery of the pin member 461b, an adhesive is applied to the outer peripheral surface of the cylindrical portion 462b and is inserted into the cylindrical body 510C from the tip. Since the elastic leg 463b bends and the locking claw 464b at the tip enters, the locking claw 464b is aligned with the notch 515C of the bottom wall 513C, and the key rib 469b is further aligned with the key groove 516C.
Thereby, the locking claw 464b passes through the notch 335d of the cover plate part 334 behind the cylindrical body 510C and is locked to the locking hole 104Cb of the front wall 102 of the sealing block part 100C.
During this time, the other locking claws of the sealing pin 460S are on the axial center side with respect to the diameter of the cylindrical portion 462b, and thus do not interfere with the bottom wall 513C of the cylindrical body 510C.

FIG. 55A is a longitudinal sectional view showing a sealed coupling state in which the sealing pin 460S is inserted into the cylindrical body 510C, and FIG. 55B is a sectional view of the AM-AM portion in FIG.
The rear end of the cylindrical portion 462b of the pin member 461b contacts the bottom wall 513C of the cylindrical body 510C, and the front end of the sealing pin 460S is flush with the front end of the cylindrical body 510C.
The cutting trace of the connecting portion 468a remaining on the pin member 461b is accommodated in the groove 517C at the front end of the cylindrical body 510C.
The sealing action is the same as when the sealing pin 460 is inserted into the cylindrical body 500C in the first sealing portion 35 (A).

  To release the seal, similarly to the first sealing portion 35 (A), the connecting portion 244b connecting the tubular body 510C to the upper inner wall and the lower inner wall of the square hole portion 241 is cut, and the tubular body 510C is cut. The sealing pin 460S is rotated together, and the locking claw 464b locked to the front wall 102 of the sealing block portion 100C of the movable base portion 28C is aligned with the notch 105Cb of the locking hole 104Cb. Release from the sealing block 100C.

The sealing pin released from the first sealing portion 36 is obtained by expanding the outer diameter of the cylindrical portion 462b by integrally bonding the cylindrical body 510C to the outer periphery of the pin member 461b.
The connecting portion 468b connecting the cylindrical portion 462b and the column portion 467 is cut from the sealing pin with a nipper or the like to remove the pin member 461b and the cylindrical body 510C, and as shown in FIG. Used as the sealing pin for the next sealing.
The new sealing pin has a reduced outer shape, and the reference numeral is 460SS for identification.

Next, the third sealing portion 37 will be described.
Here, the connection between the first box 200C and the second box 300C of the substrate box 30C is sealed using the sealing pin 460SS.
FIG. 57A is a longitudinal sectional view showing a sealing coupling state by the sealing pin 460SS, and FIG. 57B is a sectional view of the AN-AN portion in FIG. The movable base portion 28C is not shown.
With the first box 200C and the second box 300C coupled, the sealing pin 460SS is inserted into the cylindrical body 520C from the tip. At this time, an adhesive may be applied to the outer peripheral surface of the cylindrical portion 467.
Since the elastic leg 463c bends and the locking claw 464c at the tip enters, the locking claw 464c is aligned with the notch 525C of the bottom wall 523C, and the key rib 469c is further aligned with the key groove 526C.

As a result, the locking claw 464c advances in the cylindrical wall 348 of the rectangular block 341C in the second box 300C behind the cylindrical body 520C and is locked in the locking hole 344C of the rear wall 347.
The rear end of the cylindrical portion 467 contacts the bottom wall 523C of the cylindrical body 520C, and the front end of the sealing pin 460SS is flush with the front end of the cylindrical body 520C.
The cutting trace of the connecting portion 468b remaining on the pin member 461c is accommodated in the groove 527C at the front end of the cylindrical body 520C.

Since the front end of the sealing pin 460SS is flush with the front end of the front end of the cylindrical body 520C, it cannot be pulled out. Further, the locking hole 344C of the rear wall 347 of the rectangular block 341C to which the locking claw 464c of the sealing pin 460SS is locked has a notch 345C through which the locking claw 464c can pass vertically. Since the rotation of the pin 460SS is restricted by the engagement between the key rib 469c and the key groove 526C, the locking claw 464c cannot be rotated to the notch position.
Therefore, the locking claw 464c of the sealing pin 460SS inserted from the first box 200C side does not come off from the rear wall 347 of the rectangular block 341C in the second box 300C, and the connection between the first box 200C and the second box 300C is released. It will never be done.

  Since the rectangular block 341C is surrounded by the block receiving portion 219C of the first box 200C, the locking claw 464c of the sealing pin 460SS locked to the rectangular block 341C is accessed from the back side of the substrate box 30C. I can't. Therefore, the first box 200C and the second box 300C cannot be opened, and safety when returning the main board 23A to a manufacturer or the like can be ensured.

The present embodiment is configured as described above, and the first and second sealing portions 35 and 36 obtain a combined seal of the substrate box 30C and the movable base portion 28C, and the third sealing portion 37 seals the substrate box 30C itself. In this respect, the same effect as in the second embodiment can be obtained.
Also in this embodiment, the sealing pin 460 has cylindrical pin members 461a and 461b on the outer periphery, and when sealed, between the outer periphery of the outermost pin member and the cylindrical holes 502C and 512C of the cylindrical members 500C and 510C. Since the sealing pin 460 is, for example, released from the sealing at the first sealing portion 35, its state changes and the outer diameter increases.
Therefore, even if another board box is destroyed and a sealing pin is obtained illegally, the sealing body 500C of the first sealing part 35, which is the first sealing part, is a board box improperly constructed and disguised. Can not be inserted into.

  On the other hand, in the next seal following the regular seal release, the pin members 461a and 461b fixed to the cylindrical body are sequentially cut off to use the seal pins 460S or 460SS having a small diameter. Since the size of the cylindrical body 500C to be sealed first in the box 30C is too small to fit, it must be inserted into the cylindrical bodies 510C and 520C of the second or third sealing portion. It is easy to know that is not properly formed.

Further, since the cylindrical holes 500C, 510C, and 520C of the sealing portions have different diameters, the cylindrical portion 462a that is separated from at least the sealing pin 460S is at least used for the first sealing portion 35. The sealing pin 460 must be restored by taking it out of the cylindrical body 500C and re-adhering it to the sealing pin 460S. For this purpose, it is necessary to scrape the cylindrical body 500C. However, the cylindrical portion 462a and the cylindrical body 500C are fixed to each other with an adhesive, and the unevenness due to the key rib 469a and the key groove 506C also contributes. The cylindrical portion 462a is difficult to take out.
As in the case of the second embodiment, it is possible to make it more difficult to take out the cylindrical portion by providing a more fragile unevenness on the bonding surface between the members fixed to each other at each sealing portion. Then, by setting the unevenness at the cylindrical portion of the sealing pin 460 and the front end portion of each cylindrical body, the unevenness of the unevenness due to fraudulent acts can be easily found.

Next, a fifth embodiment will be described.
As in the fourth embodiment, each time the seal is released, the shape of the sealing pin is changed in the reduction direction and used again.
The main board unit includes a board box 30D including a first box 200D and a second box 300D instead of the board box 30A in the second embodiment. Relatedly, the pedestal device 25A has a movable base portion 28D including a sealing block portion 100D instead of the movable base portion 28A, and the other configuration of the main substrate unit is the main substrate unit described in the second embodiment. Same as 20A. And the sealing pin 600 is used.
Below, a different part from 4th Example is demonstrated.

58 (a) is a front perspective view showing the sealing pin 600, (b) is a rear perspective view, FIG. 59 (a) is a front view of the sealing pin 600, (b) is a longitudinal sectional view, and (c) is a longitudinal sectional view. It is a rear view.
The sealing pin 600 is composed of a plurality of, here, three pin members, and is integrally formed in a form in which the respective front ends are sequentially connected by a connecting portion.
The outermost pin member 601a includes a cylindrical portion 602a having a predetermined length and a folded flange 604a which is folded at the front end of the cylindrical portion 602a to form a predetermined ring-shaped gap s1 between the outer peripheral surface of the cylindrical portion. The length of the folded flange 604a is shorter than the cylindrical portion 602a.
The ring-shaped gap s1 is matched with the plate thickness of a cylindrical wall of a cylindrical body 500D described later.
A folded portion extending from the cylindrical portion 602a to the folded flange 604a is defined as a front end wall 603a.
In the ring-shaped gap s1, key ribs 605a are formed to extend between the cylindrical portion 602a and the folded flange 604a at two locations on the diameter line of the cylindrical portion 602a. The key rib 605a extends in the axial direction from the back surface of the front end wall 603a, and its length is shorter than that of the folded flange 604a.

The second pin member 601b from the outside is folded back at the front end of the cylindrical portion 602b and the cylindrical portion 602b having the same length as the cylindrical portion 602a to form a predetermined ring-shaped gap s2 between the outer peripheral surface of the cylindrical portion. The outer diameter of the folded flange 604b is smaller than the inner diameter of the cylindrical portion 602a of the pin member 601a.
The ring-shaped gap s2 is matched with the plate thickness of a cylindrical wall of a cylindrical body 510D described later.
The length of the folded flange 604b is the same as that of the folded flange 604a.
In the ring-shaped gap s2, key ribs 605b stretched between the cylindrical portion 602b and the folded flange 604b are formed at two locations on the diameter line of the cylindrical portion 602b. The key rib 605b extends in the axial direction from the back surface of the front end wall 603b and has the same length as the key rib 605a.

The innermost, that is, the central pin member 601c includes a columnar portion 606, two elastic legs 607 extending in the axial direction from the rear end of the columnar portion 606 and having a locking claw 608 at the tip, and a front end of the columnar portion 606. It consists of a two-surface width portion 613 extending in the axial direction and having the side surface cut off.
The outer diameter of the cylindrical portion 606 is smaller than the inner diameter of the cylindrical portion 602b of the pin member 601b, and the length is longer than the cylindrical portions 602a and 602b.
The elastic legs 607 are provided on a line passing through the axis and perpendicular to the cut-off surface of the two-surface width portion 613 when viewed in the axial direction of the cylindrical portion 606.
The locking claw 608 has a front end as a locking surface 610 perpendicular to the axial direction, and its rear outer surface has a cone shape coaxial with the cylindrical portion 606, and an inclined surface 609 whose tip is reduced in diameter to the outer diameter of the cylindrical portion 606. Yes.
On the outer peripheral surface of the front end of the cylindrical portion 606, key ribs 611 are formed at two left and right positions on a diameter line perpendicular to the line connecting the elastic legs 607.

The pin members 601a, 601b, and 601c are coaxial with each other so that the front end walls 603a, 603b and the front end of the cylindrical portion 606 coincide with each other, and are aligned so that the key ribs 605a, 605b are positioned on the line connecting the elastic legs 607, They are connected by connecting portions 612a and 612b provided symmetrically on the straight line.
The two-surface width portion 613 protrudes forward from the front ends of the pin members 601a and 601b, and the rear portion of the cylindrical portion 606 protrudes from the rear ends of the pin members 601a and 601b.

60 is an enlarged view showing the periphery of the sealing portion of the first box 200D, (a) is a front view, (b) is a cross-sectional view of the AQ-AQ portion in (a), and (c) is a cylindrical body 520D described later. It is a front view expanded further. 61A, 61B, and 61C are cross-sectional views of the AR-AR part, the AS-AS part, and the AT-AT part in FIG. 60A, respectively.
In order to form the first and second sealing portions 35 and 36, the left square hole portion 241 is provided with sealing members (tubular bodies 500D and 510D), and in order to form the third sealing portion 37 (C), a row A sealing member (cylindrical body 520D) is provided in the central square hole portion 261.
The block receiving portion 219C is formed behind the square hole portion 261 as in the fourth embodiment.

The cylindrical body 500D is disposed in the left-side square hole portion 241 with the axis in the front-rear direction, and is connected to the upper inner wall and the lower inner wall of the square hole portion 241 at the rear end portion by upper and lower connecting portions 245a.
The rear end of the cylindrical body 500D is located in front of the bottom wall 242.
The bottom wall 242 of the square hole portion 241 has a hole 243Da cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 500D and the connecting portion 245a when viewed from the front.

The cylindrical body 500D has a cylindrical hole 502D having an inner diameter that matches the outer diameter of the cylindrical portion 602a of the outermost pin member 601a of the sealing pin 600, and includes a bottom wall 503D having a small diameter hole 504D.
The length from the opening of the cylindrical hole 502D to the front surface of the bottom wall 503D is set to be the same as the length from the back surface of the front end wall of the pin member 601a to the rear end of the cylindrical portion 602a.
A slit 509 having a predetermined length is formed in the axial direction at the front end of the cylindrical body 500D so as to receive the key rib 605a of the pin member 601a.

As a result, when the sealing pin 600 is inserted into the cylindrical body 500D with the key rib 605a aligned with the slit 509 and the back surface of the front end wall 603a of the pin member 601a comes into contact with the front end of the cylindrical body 500D, the cylinder is formed. The rear end of the portion 602a contacts the bottom wall 503D.
The small-diameter hole 504D of the bottom wall 503D has a diameter that allows the cylindrical portion 602b of the second pin member 601b to pass therethrough, and the locking claw 608 of the pin member 601c can pass through without any trouble.

Next, the cylindrical body 510D that forms the sealing member of the second sealing portion 36 (B) is also disposed in the square hole portion 241 with the axis in the front-rear direction, and at the rear end portion, the square hole portion 241 is formed by the upper and lower connecting portions 245b. It is connected to the upper inner wall and the lower inner wall.
The front end of the cylindrical body 510D is in the same position as the front end of the cylindrical body 500D in the front-rear direction (axial direction), and the rear end is positioned in front of the bottom wall 242 as in the cylindrical body 500D.
The bottom wall 242 of the square hole portion 241 has a hole 243Db cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 510D and the connecting portion 245b when viewed from the front.

The cylindrical body 510D has a cylindrical hole 512D having an inner diameter matching the outer diameter of the cylindrical portion 602b of the second pin member 601b from the outside of the sealing pin 600, and includes a bottom wall 513D having a small diameter hole 514D. .
The length from the opening of the cylindrical hole 512D to the front surface of the bottom wall 513D is set to be the same as the length from the rear surface of the front end wall of the pin member 601b to the rear end of the cylindrical portion 602b.
A slit 519 having a predetermined length is formed in the axial direction at the front end of the cylindrical body 510D so as to receive the key rib 605b of the pin member 601b.
Thus, when the pin member 601b is inserted into the cylindrical body 510D by positioning so that the key rib 605b is aligned with the slit 519, the cylindrical shape is obtained when the back surface of the front end wall 603b of the pin member 601b contacts the front end of the cylindrical body 510D. The rear end of the portion 602b contacts the bottom wall 513D.

The cylindrical body 520D that forms the sealing member of the third sealing portion 37 (C) is disposed in the square hole portion 261 with the axis in the front-rear direction, and the front end thereof is positioned forward of the front ends of the cylindrical bodies 500D and 510D. Thus, the upper end wall and the lower inner wall of the square hole portion 261 are connected by the upper and lower connecting portions 245c from the front end portion to the middle in the longitudinal direction.
The bottom wall 242 of the square hole portion 261 has a hole 243Dc cut out in a shape having a predetermined gap with respect to the outline of the cylindrical body 520D and the connecting portion 245c when viewed from the front.
The cylindrical body 520D extends into the hole 243Dc, and the rear end is flush with the back surface of the bottom wall 242. However, in the square hole portion 261, the back surface of the bottom wall 242 is offset forward than in the square hole portion 241.

The cylindrical body 520D has a cylindrical hole 522D having an inner diameter that matches the outer diameter of the cylindrical portion 606 of the pin member 601c in the sealing pin 600, and includes a bottom wall 523D having a small diameter hole 524D.
Cutouts 525D that allow the elastic legs 607 of the pin member 601c to pass through are formed on the diameter line on the left and right sides of the small diameter hole 524D.
The length from the opening of the cylindrical hole 522D to the front surface of the bottom wall 523D is set to be the same as the length of the cylindrical portion 606 of the pin member 601c.

  A key groove 526D for receiving the entire length of the key rib 611 of the pin member 601c is formed in a vertically symmetrical position across the axis in the axial direction from the front end of the cylindrical hole 522D, and further, a groove 527D is formed on the diameter line on the left and right of the front end surface. Is formed. The groove 527D has a size that can accept a cut mark (stump) of the connecting portion 612b remaining on the pin member 601c after being separated from the pin member 601b as will be described later.

Next, FIG. 62 is an enlarged view showing the periphery of the sealing portion of the second box 300D, (a) is a front view, and (b) is a cross-sectional view of the AU-AU portion in (a). The cross section of the AV-AV portion in (a) is the same as the cross sectional view of FIG.
In the center of the notch space 320 of the second box 300D, a rectangular block 341D extends downward from the upper wall 321 in correspondence with the cylindrical body 520D of the first box 200D, and cover plate portions 334D are downward on both sides thereof. It extends to.

The front-rear direction position of the cover plate portion 334D is the same as that of the cover plate portion 334 of each of the embodiments described above, and when the substrate box 30D is placed on the movable base portion 28D, the surface of the front wall 102 of the sealing block portion 100D It is set so that the back surface of the cover plate portion 334D is in contact with the surface.
The cover plate portion 334D is formed with U-shaped notches 335Dc and 335Dd opened downward corresponding to the cylindrical body 500D and the cylindrical body 510D, respectively.
The notch 335Dc here has a size width through which the locking claw 608 of the sealing pin 600 inserted into the cylindrical body 500D of the first box 200D can pass.

An embankment comprising a semicircular arc having an inner diameter slightly larger than the arc along the arc and straight portions extending downward in parallel from both ends of the cutout 335Dc through which the elastic leg 608 of the sealing pin 600 passes is provided. A wall 360 stands up toward the front. The height of the bank wall 360 is such that the front end thereof extends in the hole 243Da of the bottom wall 242 in the square hole portion 241 of the first box 200D in the coupled state of the first box 200D and the second box 300D. The thickness is set to be equal to or less than the thickness of the bottom wall 242 so as to be located in the vicinity of the front surface.
The notch 335Dd has a width corresponding to the cylindrical portion 606 of the sealing pin 600, and an upward notch 362 through which the locking claw 608 of the sealing pin 600 inserted into the cylindrical body 510D of the first box 200D can pass. And a notch 363 in the left-right direction.

The rectangular block 341D has the same structure as the rectangular block 341C in the fourth embodiment, and a locking hole 344D formed in the rear wall 347 has a diameter corresponding to the cylindrical portion 606 of the pin member 601c in the sealing pin 600, The only difference is that it has notches 345D symmetrically on the diameter line in the vertical direction. The notch 345D allows the locking claw 608 of the pin member 601c to pass therethrough.
As will be described later, when the pin member 601c separated from the pin member 601b is inserted into the cylindrical body 520D until the cylindrical portion 606 abuts against the bottom wall 523D, the elastic leg 607 passes through the locking hole 344D and its engagement. The pawl 608 is locked to the back surface of the rear wall 347 (locked to the locking hole 344D).

FIG. 63 is a front view showing the sealing block portion 100D of the movable base portion 28D. In addition, since the cross section of the AW-AW part in the drawing is the same as the cross sectional view of FIG.
The front wall 102 of the sealing block portion 100D is formed with a locking hole 104D having notches 105D on the left and right sides corresponding to the cylindrical bodies 500D and 510D.
The locking hole 104D corresponds to the outer diameter of the cylindrical portion 606 of the pin member 601c in the sealing pin 600, and the locking claw 608 of the sealing pin 600 can pass through the notch 105D.

When the sealing pin 600 is inserted into the cylindrical body 500D until the cylindrical portion 602a of the pin member 601a contacts the bottom wall 503D, the elastic leg 607 passes through the locking hole 104D and the locking claw 608 is sealed by the sealing block. It is locked to the back surface of the front wall 102 of the portion 100D (locked to the locking hole 104D).
Further, as will be described later, when the cylindrical portion 602b of the pin member 601b separated from the pin member 601a is inserted into the cylindrical body 510D until it abuts against the bottom wall 513D, the elastic legs 607 are engaged with the cylindrical body 510D. Passing through the hole 104D, the locking claw 608 is locked to the back surface of the front wall 102 (locked to the locking hole 104D).
Other configurations are the same as those of the fourth embodiment.

The first sealing is performed at the first sealing portion 35 (A).
An adhesive is applied to the outer peripheral surface of the cylindrical portion 602a of the pin member 601a, and the sealing pin 600 is inserted into the cylindrical body 500D. An adhesive may also be applied to the ring-shaped gap s1 in the folded flange 604a portion.
64 (a) is a longitudinal sectional view showing a sealing combined state in the first sealing portion 35 (A), and FIG. 64 (b) is a sectional view taken along the line AX-AX in FIG. 64 (a).
The elastic leg 607 of the sealing pin 600 is bent and passes through the locking hole 104D of the front wall 102 in the sealing block portion 100D, and the locking claw 608 is locked to the locking hole 104D.
The front end portion of the cylindrical body 500D enters the ring-shaped gap s1 of the sealing pin 600, and the key rib 605a in the ring-shaped gap s1 is engaged with the slit 509 at the front end.

The locking hole 104D of the front wall 102 with which the locking claw 608 is locked has a notch 105D through which the locking claw 608 can be passed to the left and right. Since the rotation is restricted by the combination and the adhesive is adhered to the cylindrical body 500D, the locking claw 608 cannot be rotated to the position of the notch 105D.
Therefore, the locking claw 608 does not come off from the front wall 102 of the sealing block portion 100D.

Further, only the lower end of the space of the sealing block portion 100D where the locking claw 608 of the sealing pin 600 is located is opened, but the movable base portion 28D is provided with a reinforcing plate 130A, and the inside of the sealing block portion 100D is inside. Since it is a closed space, an external force cannot be applied to the locking claw 608 by a driver or the like by accessing from the opening.
Since the second box 300D is sandwiched between the first box 200D and the movable base portion 28D, the substrate box 30D is opened and the main substrate 23A is accessed unless the sealing of the first sealing portion 35 (A) is released. I can't do it.

To release the seal, the connecting portion 612a connecting the pin members 601a and 601b in the seal pin 600 is cut, leaving the pin member 601a in the cylindrical body 500D in an adhesive state, and the pin member on the inner diameter side The pin members 601b and 601c are rotated by aligning the locking claws 608 that are locked to the front wall 102 of the sealing block portion 100D of the movable base portion 28D with the notches 105D of the locking holes 104D. 601c is released from the sealing block 100D.
Thereby, the substrate box 30D can be removed from the movable base portion 28D and opened.
The sealing pin released from the first sealing portion 35 (A) is a unit in which only the pin members 601b and 601c are integrated, and has a reduced outer diameter as shown in FIG.
The code of the new sealing pin whose outer shape is reduced is 600S for identification.

Next, the second sealing portion 36 (B) that is the next sealing portion will be described.
Here, the substrate box 30D and the movable base portion 28D are sealed using the sealing pin 600S whose outer shape is reduced.
The sealing pin 600S is applied to the outer peripheral surface of the cylindrical portion 602b of the pin member 601b having a new outer periphery, and is inserted into the cylindrical body 510D.
66 (a) is a longitudinal sectional view showing a sealed coupling state in which the sealing pin 600S is inserted into the cylindrical body 510D, and FIG. 66 (b) is a sectional view taken along the line AY-AY in FIG. 66 (a).

As in the first sealing portion 35 (A), the locking claw 608 of the sealing pin 600S is locked in the corresponding locking hole 104D, and the front end portion of the cylindrical body 510D is a ring shape of the pin member 601b. The key rib 605b in the ring-shaped gap s2 is engaged with the slit 519 at the front end of the gap s2.
Thereby, the latching claw 608 cannot be rotated to the notch 105D position.
The sealing action is the same as when the sealing pin 600 is inserted into the cylindrical body 500D in the first sealing portion 35.

In order to release the seal, similarly to the first seal portion 35, the connecting portion 612b connecting the pin members 601b and 601c in the seal pin 600S is cut, and the pin member 601b is in the cylindrical body 510D in an adhesive state. The pin member 601c on the inner diameter side is rotated and the locking claw 608 is aligned with the notch 105D of the locking hole 104D, thereby releasing the pin member 601c from the sealing block portion 100D and also locking The claw 608 can be extracted from the board box 30D through the notch 363 in the cover plate portion 334D.
The only sealing pin released from the second sealing portion 36 (B) is the pin member 601c, and the outer diameter is reduced as shown in FIG.
The code of a new sealing pin whose outer shape is further reduced is 600SS for identification.

Next, the sealing of the third sealing portion 37 (C) will be described.
Here, the connection between the first box 200D and the second box 300D of the substrate box 30D is sealed using the sealing pin 600SS.
68 (a) is a longitudinal sectional view showing a sealed coupling state with the sealing pin 600SS (pin member 601c), and FIG. 68 (b) is a sectional view taken along the line BB-BB in FIG. 68 (a). The movable base portion 28D is not shown.
With the first box 200D and the second box 300D coupled, the sealing pin 600SS is inserted into the cylindrical body 520D. At this time, an adhesive may be applied to the outer peripheral surface of the cylindrical portion 606 of the pin member 601c.

  The rear end of the cylindrical portion 606 contacts the bottom wall 523D of the cylindrical body 520D, the elastic leg 607 passes through the notch 525D of the small diameter hole 524D, and the locking hole of the rear wall 347 of the rectangular block 341D in the second box 300D. Passing through 344D, the locking claw 608 is locked in the locking hole 344D. In this state, the key rib 611 of the pin member 601c is accommodated in the key groove 526D, the cut trace of the connecting portion 612b is accommodated in the groove 527D, and the front end of the cylindrical portion 606 is flush with the front end of the cylindrical body 520D. Yes.

  The locking hole 344D of the rear wall 347 of the rectangular block 341D to which the locking claw 608 of the sealing pin 600SS is locked has a notch 345D through which the locking claw 608 can pass up and down, but the sealing pin 600SS. Since the rotation is restricted by the engagement of the key rib 611 and the key groove 526D, the locking claw 608 cannot be rotated to the notch position and removed from the rear wall of the rectangular block 341D in the second box 300D.

Similarly to the fourth embodiment, since the rectangular block 341D is surrounded by the block receiving portion 219C of the first box 200D, the first box 200D is accessed by accessing the locking claw 608 from the back side of the board box 30D. And the second box 300D cannot be opened.
In order to release the sealing of the third sealing portion 37 (C), the two-surface width portion 613 extends forward from the front end of the cylindrical portion 606 of the sealing pin 600SS. , The engagement between the key rib 611 and the key groove 526D is broken, and the locking claw 608 is pulled out through the notch 345D of the locking hole 344D of the rear wall 347 and sealed from the rectangular block 341D in the second box 300D. The pin 600SS can be opened.

As described above, also in this embodiment, the sealing pin 600 changes its state each time the seal is released, and its outer shape is reduced.
Therefore, even if another board box is destroyed and the sealing pin is obtained illegally, the sealing body 500D of the first sealing part 35, which is the initial sealing part even if the board is improperly configured and pretend to be a new one. On the other hand, the size is too small to fit, and a sealed state cannot be formed. Therefore, since it must be inserted into the cylindrical bodies 510D and 520D of the second or third sealing portion, it can be easily known that the board box is not normally formed.

  Further, since the pin members 601a and 601b in the sealing pin 600S remain in a state of being fixed to the cylindrical bodies 500D and 510D on the substrate box 30D side as the sealing is released, the sealing portions adjacent to the cuts of the connecting portions 612a and 612b. It is also possible to confirm whether or not the sealing pin that is currently inserted is genuine by comparing with the cuts of the connecting portions 612a and 612b on the sealing pin 600S or 600SS side inserted in the.

  Since the sealing pin 600 is provided with the locking claw 608 only on the pin member 601c on the innermost diameter side, and is used in common in all the sealing portions, it is smaller than the fourth embodiment. Since it can be configured, it is possible to reduce the cost because it does not require an extra space in the sealing portion and can be manufactured with a small amount of material.

Further, in the first and second sealing portions, an uneven cross-section is formed by engagement of the key ribs 605a and 605b and the slits 509 and 519 on the adhesive surface between the sealing pins 600 and 600S that are fixed to each other and the cylindrical bodies 500D and 510D on the substrate box 30D side. In the third sealing portion, an uneven surface is formed on the adhesive surface between the sealing pin 600SS and the cylindrical body 520D by engagement of the key rib 611 and the key groove 526D. It is difficult to take out the pin member 601a and the like left on the substrate box 30D side by scraping the cylindrical body.
In addition, it is possible to make it more difficult to take out the pin member 601a and the like remaining on the substrate box 30D side by providing a more fragile unevenness on the bonding surface between the members fixed to each other in each sealing portion. And by setting unevenness in the front end part of a pin member and a cylindrical body, the damage of unevenness by an improper act is easy to be discovered.

In the second to fifth embodiments, the first and second sealing portions 35 and 36 as the sealing portions are sealed between the substrate box and the base device (movable base portion), and the third sealing portion 37 is the substrate box. Although the example which seals the coupling | bonding state of the 1st box and 2nd box to form was shown, it is not limited to this, The number and combination of a sealing part are arbitrary.
Alternatively, the present invention can also be applied to sealing the connection between the main board 23 and the wiring connector in the board box.

Further, in the second to fifth embodiments, the sealing pin and the cylindrical body are fixed by an adhesive. However, it can be arbitrarily selected as long as it does not easily come off, such as cured resin, welding, or fitting. Good.
Further, as a sealing connecting member whose shape changes, a sealing pin whose cylindrical body is fixed and its outer diameter is enlarged, or a sealing pin whose outer diameter is reduced by sequentially separating from the outside having a plurality of pin members is shown. However, the present invention is not limited to these. For example, when a sealing connecting member having a recess, such as a sealing pin having a recessed front end, is filled with a cured resin at the time of sealing, the recess disappears and changes to a flat surface. In addition, the “change in shape” includes a case where the color of the concave portion changes to a color different from the surroundings due to the cured resin.

In the embodiment, the sealing portion is set at the lower end portion of the substrate box. However, the position of the sealing portion may be an upper portion or a side portion of the substrate box.
Further, the insertion direction of the sealing pin into the sealing portion is not limited to the embodiments in the front-rear direction of the substrate box, and may be the left-right direction or the vertical direction.
Furthermore, even if the first embodiment and at least one of the second to fifth embodiments are combined, the shape and lighting state of the sealing connecting member exemplified by the sealing pin may change. Good.

Furthermore, although the embodiment shows an example in which the present invention is applied to a slot machine as a gaming machine, the present invention is not limited to this, and a different type of gaming machine, specifically, a ball-ball type that uses a gaming ball as a gaming medium. You may apply to a game machine, what is called a pachinko machine, etc. For example, a pachinko machine that unlocks a predetermined number of times when a game ball enters a specific area of a special device, a pachinko machine that generates a right when a game ball enters a specific area of a special device, and other roles You may make it implement as game machines, such as a pachinko machine provided with a thing, an arrangement ball machine, and a sparrow ball.
In addition, a non-ballistic gaming machine, for example, a gaming machine main body supported to be openable and closable on an outer frame, is provided with a storage unit and a capture device, and a predetermined number of game balls stored in the storage unit are obtained by the capture device. It may be implemented as a gaming machine in which a pachinko machine and a slot machine are fused, in which rotation of the reel is started by operating a start lever after being taken in.

Hereinafter, the features of the invention extracted from the above-described embodiments will be described together with effects as necessary.
(1) The first member and the second member, which are coupled to overlap each other, are disposed with their coupling states sealed by the sealing coupling member, and the first member and the second member are used by using the sealing coupling member. In a gaming machine in which two members are configured to be resealable,
Forming a sealed portion with a first member sealing portion provided on the first member and a second member sealing portion provided on the second member;
The sealing connecting member connects and seals the first member sealing portion and the second member sealing portion, and the state thereof changes before and after the seal is released.
Even if it is attempted to obtain and use the seal connecting member used for sealing the other first member and the second member illegally, the state of the seal connecting member has changed, so it has already been used for sealing. It turns out that it is possible to prevent fraudulent acts that disguise the sealed structure.
In addition, since one sealing connecting member can be sealed using another sealing location, there is no need to install another sealing connecting member used for the second time or later in the gaming machine, and the sealing connecting member It is possible to prevent the situation from being misappropriated.

  The “first member” and the “second member” in the gaming machine of the present invention are applied to any part that needs to seal the combined state of a plurality of parts in the gaming machine, unless otherwise specified below. For example, it may be a plurality of members (for example, the first box 200 and the second box 300) constituting the substrate box that forms the storage space for storing the control substrate, or the first member and the first member. One of the two members may be a board box that houses the control board, and the other may be a mating part (for example, the pedestal device 25) that attaches and fixes the board box to the gaming machine.

The phrase “the first member and the second member are overlapped and coupled to each other” is not limited to the case where the first member and the second member are overlapped with each other, but the third member coupled to one of the first member and the second member. This includes the case where the members are overlapped with each other.
In addition, the first member and the second member may be one part integrally formed of a single material, or may be formed by combining a plurality of members. Each of the one-member sealing portion and the second member sealing portion may be constituted by a single part or may be formed by combining a plurality of parts.
The seal connecting member is not limited to a bar shape, but also includes an arbitrary shape such as a plate shape or a box shape unless otherwise specified.

Further, the seal connecting member is “to connect and seal the first member sealing portion provided on the first member and the second member sealing portion provided on the second member”. The first member sealing portion and the second member sealing portion may be connected by locking with the member. That is, assuming that the first member sealing portion is located on the front side and the second member sealing portion is located behind the first member sealing portion, the sealing connecting member is locked to the locking portions respectively formed on the first member sealing portion and the second member sealing portion. Or a locking member formed at a portion extending from the first member sealing portion on the tip (rear end) side with the locking portion formed on the first member sealing portion and the second member sealing portion interposed therebetween. As a result, the first member sealing portion and the second member sealing portion may be connected by locking the sealing connecting member to the portion. In the case of locking, a configuration may be adopted in which a locking claw is provided on one of the seal connecting member and the mating member, and a recess or a projection is formed on the other to engage with the locking claw.
Sealing by the seal connecting member includes not only locking by the locking claw described above but also any one or combination of screw fixing, adhesive fixing, and press-fitting fixing.

(2) The seal connecting member includes a lighting means,
The game machine according to (1), wherein the seal connecting member is in a lighting state.
Since it is a light display, it is possible to easily check the state change even when the surrounding environment is dark, and it is also easy to check the surrounding environment itself by the diffusion of light.

(3) The lighting means includes a light emitting unit, a control circuit, and a first connection terminal that forms an electric circuit by being connected to an external contact in a sealed state;
The lighting means is characterized in that the control circuit changes the lighting state of the light emitting unit based on a change from a connection state of the first connection terminal and an external contact point to a non-connection due to release of sealing. To play.
Even if the sealed first member or the second member side is destroyed and the seal is released, the sealed connecting member having no trace of destruction is taken out, and it is illegally used for sealing the newly disguised first member and second member. As shown in the following (4) to (7), for example, the lighting color of the light emitting portion has changed to a different color or the like based on the disconnection of the first connection terminal and the external contact point already associated with the seal release. Therefore, it can be easily determined that an illegal act has been performed.

(4) The lighting means changes the lighting color of the light emitting unit to a color different from that immediately before the release of the seal every time the connection state of the first connection terminal and the external contact is changed to the disconnection due to the release of the seal. The gaming machine according to (3), wherein the gaming machine is changed.
Since the difference in color is particularly easy to identify, the effect of preventing fraud is great.
(5) The lighting means changes the order of change in the lighting color of the light emitting unit before the last seal release every time the connection state of the first connection terminal and the external contact is changed to the non-connection due to the seal release. The gaming machine according to (3), which is different from the order.
Since the control circuit must be changed for impersonation, fraud can be suppressed.
(6) The lighting means changes the flashing speed of lighting of the light emitting part before the last sealing release every time the connection state of the first connection terminal and the external contact is changed to the non-connection due to the release of sealing. The gaming machine according to (3), wherein the game machine is changed.
Compared with the inventions of (4) and (5), since a monochromatic light emitting element can be used for the light emitting portion, the configuration is simple and low cost is realized.

(7) A plurality of the sealing portions are provided,
The seal connecting member is set to be used sequentially in common with each seal part,
The gaming machine according to any one of (3) to (6), wherein the lighting means exhibits different lighting states equal to or more than the number of the sealing portions.
Since the lighting means do not exhibit the same lighting state, it is ensured that the illegally obtained sealing connecting member is illegally obtained regardless of where it is inserted in the plurality of sealing portions, unlike the normal lighting state. Determined.

(8) The gaming machine according to any one of (3) to (7), wherein the lighting means does not light the light emitting unit when the power of the gaming machine is OFF.
(9) The lighting means includes an internal power source for the control circuit, and a second connection terminal that is connected to an external power source in a state where the first member and the second member are sealed by the sealing connecting member. ,
The gaming machine according to any one of (3) to (7), wherein in the sealed state, the external power source is at least one of a driving power source for the light emitting unit and a charging power source for the internal power source.
Even while the power of the gaming machine is turned off, the control circuit can detect the release of the seal (change from the connection state of the first connection terminal and the external contact to the disconnection) by the internal power supply.
In the case where the external power source is used as the driving power source of the light emitting unit, the light emitting unit is driven immediately after the external power source is supplied at the next sealing, and is turned on in a state different from that before the seal is released. Since the internal power supply does not require high power for driving the light emitting unit, the sealing connecting member can be made compact.
Similarly, since the light emitting unit is lit only by the external power source, there is no possibility that the lighting state changes from the setting due to the power consumption of the internal power source.

(10) The second connection terminal is connected to the external power supply by connecting to a power supply terminal provided on a control board attached to either the first member or the second member. The gaming machine according to (9).
For example, when the first member and the second member form a substrate box that accommodates the control board, the configuration is simply realized by simply arranging the power supply terminal on the control board and connecting it to the board power supply. The same applies to an external substrate.

(11) The control circuit changes the connection state between the first connection terminal and the external contact point from the connection state to the non-connection state from the removal of the seal connection member by releasing the seal to the new seal portion using the seal connection member. The gaming machine according to any one of (3) to (10), wherein the monitoring is intermittently performed at a period set shorter than a time required to obtain.
Since the monitoring is intermittent, the power consumed by the control circuit is saved.

(12) The sealing connecting member is a sealing pin,
The gaming machine according to any one of (3) to (11), wherein the first member sealing portion is a cylindrical body through which the sealing pin is inserted.
Since the sealing pin can be inserted between the first member sealing portion and the second member sealing portion by inserting the sealing pin into the cylindrical body, the sealing operation is easy.

(13) The sealing pin houses the lighting means in a cylindrical pin body,
The gaming machine as set forth in (12), wherein the light emitting portion is disposed at a front end portion of the pin body.
It is easy for the confirmer to visually recognize the lighting state.
(14) The gaming machine according to (13), wherein the pin body has an opening at a front end, and the opening is filled with a cured resin after the lighting means is stored.
While it is possible to visually recognize the lighting of the light emitting unit through the cured resin, when trying to take out the lighting means constituent member including the control circuit, the cured resin must be scraped off, and it remains a trace that such an attempt has been made. So cheating becomes difficult.

(15) The gaming machine according to (1), wherein the state of the seal connecting member is its shape, and the shape changes before and after the seal is released.
Since the shape of the seal connecting member after the seal is released is different, it can be easily discriminated whether it is used or not.

(16) The first member and the second member that are coupled to overlap each other are disposed with their coupling states sealed by the sealing coupling member, and the first member and the second member are arranged using the sealing coupling member. In a gaming machine in which two members are configured to be resealable,
A first member sealing portion provided on the first member and connected to a peripheral portion of the first member by a connecting portion; and a second member sealing portion provided on the second member to form a sealing portion;
The sealing connecting member connects and seals the first member sealing portion and the second member sealing portion, and adheres to the first member sealing portion at the time of sealing so that the first member sealing from the first member. The gaming machine is characterized in that the outer shape expands when the part is cut off at the connecting part with the peripheral part and the seal is released.
Since the sealed connecting member whose outer shape is enlarged after the seal is released cannot be applied to the same sealed portion of the first member and the second member obtained illegally, it is possible to prevent cheating.

(17) The seal connecting member has a first locking portion and is spanned from the first member side to the second member side, and the first locking portion is a second rear side of the first member sealing portion. The gaming machine according to (16), wherein the gaming machine is locked to the locking portion to obtain a sealed state.
(18) The sealing connecting member is a sealing pin having a locking claw for locking the first locking portion to the second member sealing portion,
The first member sealing portion is a cylindrical body through which the sealing pin is inserted,
The gaming machine as set forth in (17), wherein the outer diameter of the sealing pin is increased by fixing the cylindrical body to an outer periphery of the sealing pin.
The outer diameter of the sealing pin that is recovered by releasing the seal by excising the connecting portion is increased due to the cylindrical body adhering to the outer periphery.

(19) A plurality of the sealing portions are provided,
The sealing pin is set to be used sequentially for each sealing part,
(18) The gaming machine according to (18), wherein the hole diameter of the cylindrical body of each of the second and subsequent sealing portions is sequentially expanded in conformity with the outer diameter of the expanded sealing pin.
In each sealing portion, inserting the sealing pin into the cylindrical body and fixing it automatically enlarges the outer diameter of the sealing pin.
(20) The gaming machine according to (19), wherein the sealing pin has the same locking claw locked to the second locking portion in common at all sealing portions.
Since only one type of locking claw is required, it can be made compact, and this enables manufacture with a small amount of material, thereby reducing costs and reducing the space for the sealing portion.
(21) The cylindrical body of each sealing portion that is sequentially fixed to the sealing pin includes the locking claw,
The sealing pin is characterized in that, in each of the second and subsequent sealing portions, the locking claw of the cylindrical body that is finally fixed to the sealing pin is locked to the second locking portion (19 ) Gaming machine described in.
Since the sealing pin to which the cylindrical body is fixed has a large locking claw, even when trying to use it for the first sealing portion of the first member and the second member obtained illegally, it fits into the cylindrical body. In addition, the locking claw is not compatible with the second locking portion, which makes it difficult to cheat.

(22) The first member and the second member, which are coupled to overlap each other, are disposed with their coupling states sealed by the sealing coupling member, and the first member and the second member are used using the sealing coupling member. In a gaming machine in which two members are configured to be resealable,
Forming a sealed portion with a first member sealing portion provided on the first member and a second member sealing portion provided on the second member;
The sealing connecting member connects and seals the first member sealing portion and the second member sealing portion, and at the time of sealing, the predetermined portion is fixed to the first member sealing portion to release the seal and A gaming machine characterized in that the outer shape is reduced when a predetermined part is excised.
Since it is difficult to remove the fixed first member sealing portion of the sealing connecting member, the predetermined portion must be left behind on the first member sealing portion side, and the outer shape is reduced by the amount of the predetermined portion being removed. Since the sealing connecting member having a reduced outer shape cannot be applied to the same sealing portion in the first member and the second member obtained illegally, it is possible to prevent fraud.

(23) The seal connecting member has a first locking portion and is spanned from the first member side to the second member side, and the first locking portion is a second rear side of the first member sealing portion. The gaming machine according to (22), wherein the gaming machine is locked to the locking portion to obtain a sealed state.
(24) The sealing connecting member is a sealing pin having a locking claw for locking the first locking portion to the second member sealing portion,
The first member sealing portion is a cylindrical body through which the sealing pin is inserted,
The gaming machine according to (23), wherein the sealing pin has a cylindrical pin member at least on an outermost periphery as the predetermined portion, and the cylindrical pin member and the cylindrical body are fixed to each other.

(25) A plurality of the sealing portions are provided,
The sealing pin is set to be used sequentially for each sealing part,
(24) The gaming machine according to (24), wherein the hole diameter of the cylindrical body in each of the second and subsequent sealing portions is sequentially reduced in alignment with the outer diameter of the reduced sealing pin.
In each sealing part, inserting the sealing pin into the cylindrical body and fixing it automatically reduces the outer diameter of the sealing pin.
(26) The sealing pin is configured by overlapping a plurality of pin members including cylindrical pin members having different diameters in a radial direction,
The hole diameter of the cylindrical body of each sealing portion is sequentially matched to the outer diameter of the pin member,
In each sealing part, it is to fix between the outermost pin member and the cylindrical body,
The game machine according to (25), wherein the sealing pin is used for each of the second and subsequent sealing parts by sequentially cutting the outermost pin member.

(27) The gaming machine according to (25) or (26), wherein the sealing pin has the same locking claw locked to the second locking portion in common in all sealing portions.
Since only one type of locking claw is required, it can be made compact, and this enables manufacture with a small amount of material, thereby reducing costs and reducing the space for the sealing portion.
(28) Each of the pin members fixed to the cylindrical body includes the locking claw,
The game machine according to (26), wherein the sealing pin has the locking claw of the pin member fixed to the cylindrical body locked to the second locking portion in each sealing portion.
Since the sealing pin obtained by cutting the outer pin member fixed to the cylindrical body has a small size of the locking claw, even if it is intended to be used for the first sealing portion of the first member and the second member obtained illegally, for example. In addition to being incompatible with the cylindrical body, the locking claw is also not compatible with the second locking portion, which makes it difficult to cheat.

(29) A key rib is formed on one of the hole of the cylindrical body and the outer periphery of each pin member, and a groove corresponding to the key rib is formed on the other (26) to (28). The gaming machine according to any one of the above.
(30) The pin member includes a folded flange having a gap with an outer peripheral surface at a front end, and a key rib is formed in the gap.
The gaming machine according to any one of (26) to (28), wherein a groove corresponding to the key rib is formed in a front end surface of the cylindrical body.
Since the engaging portion of the key rib and the groove is hidden from the surface, the aesthetic appearance is improved, and illegal acts such as hitting the engaging portion with a driver or the like are prevented.

(31) In any one of (18) to (21) and (24) to (30), fragile irregularities are formed on surfaces of the cylindrical body and the sealing pin that are fixed to each other. The gaming machine described.
The area of contact and engagement increases, and the fixation becomes strong, and the unevenness is easily damaged, so that it becomes more difficult to scrape the outer cylindrical body, which is effective in preventing fraud.
(32) The gaming machine according to (31), wherein the unevenness is provided at a front end portion of the cylindrical body and the sealing pin.
Since the unevenness is at the front end portion that is easily visible, damage to the unevenness due to fraud is likely to be found.

(33) A gaming machine according to any one of (1) to (32), wherein the gaming machine is a pachinko gaming machine. Among them, as a basic configuration of the pachinko gaming machine, an operation handle is provided, and a ball is fired to a predetermined game area in accordance with the operation of the operation handle, and the ball is disposed at a predetermined position in the game area. As a necessary condition for winning a prize (or passing through an operating port), the identification information dynamically displayed on the display device is confirmed and stopped after a predetermined time. In addition, when a special gaming state occurs, a variable winning device (specific winning opening) disposed at a predetermined position in the gaming area is opened in a predetermined manner so that a ball can be won, and a value corresponding to the number of winnings is obtained. Examples include those to which values (including data written on magnetic cards as well as premium balls) are given.

(34) A gaming machine according to any one of (1) to (32), wherein the gaming machine is a slot machine. In particular, as a basic configuration of the slot machine, “variable display means for confirming and displaying the identification information after dynamically displaying an identification information string composed of a plurality of identification information is provided, and operation of the starting operation means (for example, an operation lever) is performed. The dynamic display of the identification information is started due to the stop, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed. The game machine is provided with special game state generating means for generating a special game state advantageous to the player on the condition that the confirmed identification information at that time is the specific identification information. In this case, examples of the game media include coins and medals.

(35) A gaming machine according to any one of (1) to (32), wherein the gaming machine is a fusion of a pachinko gaming machine and a slot machine. In particular, the basic configuration of the fused gaming machine includes “variable display means for confirming and displaying the identification information after dynamically displaying an identification information sequence composed of a plurality of identification information, and operating operation means for starting (for example, an operation lever). ) Is started due to the operation of (), and the dynamic display of the identification information is stopped due to the operation of the operation means for stop (stop button) or when a predetermined time elapses. Special game state generating means for generating a special game state advantageous to the player on the condition that the fixed identification information at the time of stoppage is specific identification information, and using a ball as a game medium, and the identification information The game machine is configured such that a predetermined number of balls are required at the start of the dynamic display, and a large number of balls are paid out when the special gaming state occurs.

In the first embodiment described above, the first box 200 corresponds to the first member in the invention, and the second box 300 corresponds to the second member.
The cylindrical body 240 provided in each of the sealing portions 34a, 34b, 34c corresponds to the first member sealing portion, and the rectangular block 338 having the locking holes 353 in the front wall 350 corresponds to the second member sealing portion, and the locking claws. The sealing pin 400 having 408 corresponds to the sealing connecting member, and in particular, the locking claw 408 forms the first locking portion, and the locking hole 353 in the front wall 350 of the rectangular block 338 forms the second locking portion. .
The light emitting unit 480 housed in the sealing pin 400 constitutes the lighting means in the invention, the LED 485 in the light emitting unit 480 corresponds to the light emitting portion, and the pin side terminals Q3 and Q4 correspond to the first connection terminal. The capacitor 484 corresponds to the internal power supply, and the pin-side terminals Q1 and Q2 correspond to the second connection terminal.
The main board 23 accommodated in the board box 30 including the first box 200 and the second box 300 corresponds to the control board.

In the second embodiment, the first box 200A is the first member in the invention, and the movable base portion 28A in the first and second sealing portions 35, 36 and the second box 300A in the third sealing portion 37 are respectively second. Corresponds to the member.
The cylindrical bodies 500, 510, and 520 correspond to the first member sealing portion, and the sealing block portion 100 having the locking hole 104 in the front wall 102 and the rectangular block 341 having the locking hole 344 in the front wall 342 are respectively provided. Corresponds to the two-member seal.
Then, the sealing pin 430 corresponds to the sealing connecting member, and the locking claw 444 of the first pin 432 constituting this sealing pin corresponds to the first locking portion. Further, the locking hole 104 and the locking hole 344 each constitute a second locking portion.

In the third embodiment, the first box 200B is the first member in the invention, and the movable base portion 28B in the first and second sealing portions 35, 36 and the second box 300B in the third sealing portion 37 are respectively second. Corresponds to the member.
The cylindrical bodies 500B, 510B, and 520B correspond to the first member sealing portion, and the rectangular block includes the sealing block portion 100B having the locking holes 104 and 104K in the front walls 102B and 102C and the locking hole 344B in the front wall 342B. 341B corresponds to the second member sealing portion.
The sealing pin 430 corresponds to the sealing connecting member, and the locking claw 444 of the first pin 432 constituting the sealing pin and the locking claws 537 and 543 of the cylindrical bodies 500B and 510B that are sequentially fixed thereto are respectively provided. Corresponds to the first locking part. In addition, the locking holes 104 and 104K and the locking hole 344B constitute a second locking part.

In the fourth embodiment, the first box 200C is the first member in the invention, and the movable base portion 28C in the first and second sealing portions 35, 36 and the second box 300C in the third sealing portion 37 are respectively second. Corresponds to the member.
Cylindrical bodies 500C, 510C, and 520C correspond to first member sealing portions, and a sealing block portion 100C having locking holes 104Ca and 104Cb in the front wall 102 and a rectangular block 341C having locking holes 344C in the rear wall 347. Each corresponds to a second member sealing portion.
The sealing pin 460 corresponds to the sealing connecting member, and the locking claws 464a, 464b, and 464c of the pin members 461a, 461b, and 461c constituting the sealing pin correspond to the first locking portions, respectively. Further, the locking holes 104Ca and 104Cb and the locking hole 344C constitute a second locking portion, respectively.
The pin members 461a and 461b that sequentially become outer peripheral members of the sealing pin correspond to predetermined portions of the sealing connecting member.

In the fifth embodiment, the first box 200D is the first member in the invention, and the movable base portion 28D in the first and second sealing portions 35 and 36 and the second box 300D in the third sealing portion 37 are respectively second. Corresponds to the member.
Cylindrical bodies 500D, 510D, and 520D correspond to the first member sealing portions, and a sealing block portion 100D having a locking hole 104D in the front wall 102 and a rectangular block 341D having a locking hole 344D in the rear wall 347, respectively. Corresponds to the two-member seal.
The sealing pin 600 corresponds to the sealing connecting member, and the locking claw 608 of the pin member 601c constituting the sealing pin corresponds to the first locking portion. Further, the locking hole 104D and the locking hole 344D each constitute a second locking portion.
Pin members 601a and 601b, which are sequentially outer peripheral members of the sealing pin, correspond to predetermined portions of the sealing connecting member.

  The present invention is particularly useful for ensuring the security of various gaming machines including a board box containing a control board.

DESCRIPTION OF SYMBOLS 1 Slot machine 2 Chassis main body 3 Front door 4 Locking mechanism 5 Game panel 6 Display window 7 Coin slot 8 Operation part 9 Coin tray 10 Effect display part 11 Hopper apparatus 12 Power supply box 14 Reel 15 Reel unit 20, 20A, 20C, 20D Main board unit 22, 22A Main controller 23, 23A Main board (control board)
24 Small hole 25, 25A Pedestal device 26, 26A Fixed base part 28, 28A, 28B, 28C, 28D Movable base part 30, 30A, 30B, 30C, 30D Board box 32 Rail 34, 34a, 34b, 34c Sealing part 35 No. 1 sealing part 36 2nd sealing part 37 3rd sealing part 40 bottom plate part 42 mounting flange part 43 hole 44 notch part 46 mounting flange part 47 hole 48 mounting frame member 50 mounting surface part 52 leg piece 54, 54a, 54b joint part 55 bottom Lid portion 56 Posture holding member 57 Claw 60 Notch portion 62 Hole 65 Support flange portion 67 Cover flange 68 Rotating stopper 70, 71 Shaft support plate portion 73 Shaft hole 75 Lock mounting hole 80 Bottom plate portion 82 Mounting portion 84, 85 Side plate portion 86 Rotating shaft 87 Contact portion 88 Shaft hole 89 Lock mounting hole 90 Slit groove 100, 100B, 10 0C, 100D Sealing block portion 101a, 101b Partition 102 Front wall 102B First front wall 102C Second front wall 103 Rear wall 104, 104K, 104Ca, 104Cb, 104D Locking hole 105, 105K, 105Ca, 105Cb, 105D Notch 107 Window hole 108 Screw block 109 Screw hole 110 Slit hole 112 Return part 113 Projection step part 114 Guide groove 116 Area 118 Fixing bracket part 119 Hole 120 Locking part 122 Projection piece 124, 125 Boss plate part 126 Slit 127 Shaft hole 128 Support pin 129 Recess 130, 130A Reinforcement plate 132 Flat plate part 134 Vertical wall 136 Axle support plate part 137 Hole 138 Slit hole 140 Notch hole 142 Window hole 144 Bracket part 145 Insertion hole 150 Overhang part 152 Hole 154 Wiring Pattern 154a Power supply line 154b Short-circuit line 200, 200A, 200B, 200C, 200D First box 201 Main board housing part 202 Step part 203 Socket insertion hole 204 Adhering frame 205 Fixing surface 206 Screw hole 207 Flat part 208 Hook receiver 209 Upper end wall 210 Side wall 211 Rail formation part 211a Band plate part 211b Rib 212 Hooking part 213 Opposing wall 214 Engagement protrusion 215 Connection fixing part 216 Screw hole 217 Surrounding wall 218 Projection piece 219, 219A, 219B, 219C Block receiving part 220 Rectangular recess 221 Notch recess 222 Bottom wall 223 Bottom wall 240 Cylindrical body 241 Square hole 242 Bottom wall 243, 243a, 243b Hole 243Ca, 243Cb Hole 243Da, 243Db, 243Dc Hole 244, 244a, 244b, 244 c Connecting portion 245a, 245b, 245c Connecting portion 246 Tube hole 249 Key groove 261 Square hole portion 261a Partition wall 270, 270A, 270B, 270C Cover wall 272 Projection 300, 300A, 300B, 300C, 300D Second box 301 Bottom plate portion 302 Rib 304 Fixed block 305 Hole 308 Upper end wall 308a Front end surface 310 Side wall 311 Rail forming part 311a Vertical wall part 312 Hook part 314 Hook 316 Engagement hole 317 Engagement block 318 Slit groove 320 Notch space 321 Upper wall 322 Side wall 334, 334D Cover plate portion 335a, 335b, 335c, 335d, 335Dc, 335Dd Notch 336 Slit 338 Rectangular block 341, 341B, 341C, 341D Rectangular block 342, 342B, 342C Front wall 343, 343B, 343C Frame wall 344, 344B, 344C, 344D Locking hole 345, 345B, 345C, 345D Notch 346 Hole 347 Rear wall 348 Cylindrical wall 349 Connection part 350 Front wall 351 Frame wall 352 Cap part 353 Engagement Stop hole 354 Notch 360 Cut-off wall 362, 363 Notch 400 Sealing pin 401 Pin body 402 Large diameter part 403 Small diameter part 404 Key rib 405 Large diameter hole 406 Small diameter hole 407 Elastic part 408 Locking claw 409 Inclined surface 410 Locking surface 411 Groove 412 Slit hole 413 Engaging recess 414 UV curable resin 430 Sealing pin 432, 432L, 432LL, 432K, 432KK First pin 433 Large diameter portion 434 Small diameter portion 435 Key rib 438 Tube hole 439 Large diameter hole 440 Small diameter hole 441 Slit 443 Bullet Portion 444 Locking claw 445 Inclined surface 446 Locking surface 447 Notch 450 Second pin 451 Large diameter portion 452 Small diameter portion 453 Tube hole 454 Key rib 455 Elastic portion 456 Locking claw 457 Inclined surface 458 Locking surface 460, 460S, 460SS Sealing pin 461a, 461b, 461c Pin member 462a, 462b Cylindrical part 463a, 463b, 463c Elastic leg 464a, 464b, 464c Locking claw 465a, 465b, 465c Inclined surface 466a, 466b, 466c Locking surface 467 Column part 468a, 468b Connecting portion 469a, 469b, 469c Key rib 480 Light emitting unit 481 Substrate 482 Projection 483 Control circuit 484 Capacitor 485 LED
486 Diode 487 Resistance 490 Disc cap 491 Disc part 492 Protrusion 493 Hook piece 494 Claw 500, 500B, 500C, 500D Cylindrical body 502, 502C, 502D Cylindrical hole 503, 503C, 503D Bottom wall 504, 504C, 504D Small diameter hole 505C 525D Notch 506, 506C Keyway 508, 518 Rib 509, 519 Slit 510, 510B, 510C, 510D Cylindrical body 512, 512C, 512D Cylindrical hole 513, 513C, 513D Bottom wall 514, 514C, 514D Small diameter hole 516, 516C Keyway 517, 517C Groove 520, 520B, 520C, 520D Cylindrical body 522, 522C, 522D Tube hole 523, 523C, 523D Bottom wall 524, 524C, 524D Small diameter hole 526, 526C 526D Key groove 527, 527C, 527D Groove 530 Large diameter portion 531 Small diameter portion 532, 540, 550 Tube hole 533 Large diameter hole 534 Small diameter hole 536, 542 Elastic portion 537, 543 Locking claw 538, 544 Inclined surface 539, 545 Stop surface 600, 600S, 600SS Sealing pin 601a, 601b, 601c Pin member 602a, 602b Cylindrical portion 603 Front end wall 604a, 604b Folding flange 605a, 605b Key rib 606 Column portion 607 Elastic leg 608 Locking claw 609 Inclined surface 610 Locking surface 610 611 Key rib 612a, 612b Connecting portion 613 Two-sided width portion G, G1, G2, G3, G4 Fixed side terminal Lb, Lg, Lr Light emitting element Pb1, Pb2 Power supply terminal Pi1, Po1, Po2, Po3 Output terminal Pi2 Input terminal Q, Q1, Q2, Q3, Q4 Pin side terminal s1, s2 Ring-shaped gap Z Rotation center axis

Claims (3)

The first member and the second member, which are coupled to overlap each other, are disposed with their coupling states sealed by the sealing coupling member, and the first member and the second member are re-used using the sealing coupling member. In the gaming machine configured to be sealable, a first member sealing portion provided on the first member and connected to a peripheral portion of the first member by a connecting portion, and a second member provided on the second member Form a sealed part with the sealed part,
The game machine characterized in that the seal connecting member connects and seals the first member seal portion and the second member seal portion, and changes its shape before and after the seal is released.   The sealing connecting member is fixed to the first member sealing portion at the time of sealing, and the outer shape expands when the first member sealing portion is cut from the first member at the connecting portion with the peripheral portion to release the sealing. The gaming machine according to claim 1, wherein: The sealing connecting member is a sealing pin;
The first member sealing portion is a cylindrical body through which the sealing pin is inserted,
The gaming machine according to claim 2, wherein the cylindrical body is fixed to the outer periphery of the sealing pin and the outer diameter is expanded.

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