JP7199707B2 - Game machine shutter device - Google Patents

Description

The present invention relates to a game machine shutter device.

For example, as described in Patent Literature 1 below, there is known a game machine shutter device that covers the display surface of a display device of a game machine. This game machine shutter device includes a plurality of substantially rectangular shielding plates extending in the vertical direction. Each shielding plate can be slid in the left-right direction while maintaining its plate thickness direction perpendicular to the game board. These shielding plates are stacked in the front-rear direction (thickness direction of the game board) on the sides (left and right) of the display device and slightly forward (on the player's side) (fully open state). Each shielding plate is slid in the horizontal direction and arranged so as to cover the display device (fully closed state).

Japanese Patent No. 4313349

In the shutter device of Patent Document 1, each shielding plate simply slides in the left-right direction. Therefore, in the fully closed state (the state in which the shielding plates are arranged so as to cover the display device), there is a step in the front-rear direction at the boundary between the adjacent shielding plates. The appearance quality of the device is poor.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a game machine shutter device with improved appearance quality in a fully closed state. In addition, in the description of each constituent element of the present invention below, in order to facilitate understanding of the present invention, the symbols corresponding to the embodiments are described in parentheses, but each constituent element of the present invention is It should not be construed as being limited to the configurations of the corresponding portions indicated by the reference numerals in the embodiment.

In order to achieve the above object, the game machine shutter device (1) according to the present invention includes shielding plates (111, 112) parallel to plate-like portions (121, 122, PB) arranged to face a player. , an actuator (213, 23) for sliding the shielding plate in a first direction parallel to the front surface of the plate-like portion; a guide member (212) slidably contacting an end portion in a second direction parallel to the front surface of the shutter device for guiding the movement of the shield plate in the first direction, the shutter device for a game machine comprising: First projections (PLa ₁₁₁ , PRa ₁₁₁ , PLa ₁₁₂ , PRa ₁₁₂ ) and second projections (PLb ₁₁₁ , PRb) projecting from the end of the shielding plate in the second direction and spaced apart in the first direction ₁₁₁ , PLb ₁₁₂ , PRb ₁₁₂ ), the protrusion height of the first protrusion is set smaller than that of the second protrusion, and the guide member is arranged to be shifted in the second direction. a portion (212a) and a second guide portion (212b), the first guide portion being spaced apart in the second direction from the end portion of the shielding plate, the first guide portion and the end portion of the shielding plate; and a second guide portion disposed between, wherein the first guide portion includes a first linear portion (Sa ₂₁₂ ) extending linearly in the first direction, and an end of the first linear portion first groove portions ( _S212U , _S212D ) having first inclined portions ( _Sb212 ) obliquely extending from the portion toward the front or rear in the first direction, and the second guide portion includes the first groove portion second groove portions (GU _212M , GD _212M ) arranged so as to deviate in the first direction when viewed from above, the second straight portion (Ga ₂₁₂ ) extending linearly in the first direction, and the second A second groove portion having a second inclined portion (Gb _212M ) obliquely extending in the first direction and forward or backward from an end portion of the straight portion is provided, and the extending direction of the first inclined portion and the second inclined portion are provided. and the distance in the first direction between the first inclined portion and the second inclined portion is the same as the distance between the first convex portion and the second convex portion. The first protrusion is guided by the first groove of the first guide part, and the second protrusion is guided by the second groove.

In the game machine shutter device according to the present invention, the shield plate is guided by the first guide portion and the second guide portion. That is, the shielding plate moves in the first direction along the first guide portion and the second guide portion. According to this, for example, from a state (fully open state) in which the shielding plate is arranged so as to be superimposed on the front side of the plate-shaped portion (on the player side), the shielding plate is moved to the straight line between the first guide portion and the second guide portion. After moving along the part, it can be moved backward along the inclined parts of the first guide part and the second guide part. Also, for example, after the shielding plate is moved along the linear portions of the first guide portion and the second guide portion from a state in which the shielding plate is superimposed on the rear side of the plate-like portion (on the side opposite to the player) , along the inclined portions of the first guide portion and the second guide portion. This makes it possible to realize a state (fully closed state) in which the plate-like portion and the shielding plate are arranged in the first direction and the front surface of the plate-like portion and the front surface of the shielding plate are positioned on the same plane. Therefore, according to the present invention, it is possible to improve the appearance quality of the game machine shutter device in the fully closed state.

Also, the first guide portion and the second guide portion are provided to be shifted in the first direction and the second direction (the direction parallel to the plate-like portion), and are not shifted in the front-rear direction. According to this, compared with the case where the first guide portion and the second guide portion are shifted in the front-rear direction, it is possible to reduce the size (thickness) of the game machine shutter device.

Furthermore, according to the present invention, compared to the case where the actuator for moving the shielding plate in the first direction and the actuator for moving the shielding plate in the front-rear direction are provided separately, the configuration of the entire device can be simplified.

Further, in one aspect of the shutter device for a game machine of the present invention, it further includes an actuator that moves the predetermined plate-like portion in the first direction.

According to this, the gap between the shielding plate and the plate-like portion can be reduced in the fully closed state. Therefore, it is possible to further improve the appearance quality of the game machine shutter device in the fully closed state.

1 is an exploded perspective view of a pachinko machine to which a game machine shutter device according to an embodiment of the present invention is applied; FIG. 1 is a perspective view of a game machine shutter device in a fully open state; FIG. 1 is a perspective view of a game machine shutter device in a fully closed state; FIG. It is a front view of a first shielding plate. It is a front view of a second shielding plate. It is an exploded perspective view of a linear motion device on the left side. It is the perspective view which looked at the guide plate shown in FIG. 6 from diagonally back. FIG. 7 is a right side view of the guide plate shown in FIG. 6; FIG. 7 is an exploded perspective view of the front linear motion mechanism shown in FIG. 6; FIG. 7 is an exploded perspective view of the rear linear motion mechanism shown in FIG. 6; FIG. 4 is an exploded perspective view showing the engagement of the first shielding plate, the guide plate and the front linear motion mechanism; FIG. 5 is a cross-sectional view showing the engagement of the first shielding plate, the guide plate and the front linear motion mechanism; FIG. 4 is a side view showing the positional relationship between the first shielding plate and the second shielding plate in the fully closed state; FIG. 10 is a side view showing the positional relationship between the first shielding plate and the second shielding plate in a state on the way from the fully open state to the fully closed state; It is a side view which shows the positional relationship of the 1st shielding board and the 2nd shielding board in a fully open state.

A game machine shutter device 1 according to an embodiment of the present invention will be described. First, an outline of a pachinko machine PM as a game machine to which the game machine shutter device 1 is applied will be described. As shown in FIG. 1, the pachinko machine PM is a substantially rectangular parallelepiped device extending vertically. In the following description, the height direction (vertical direction) of the pachinko machine PM is referred to as the vertical direction. Also, the width direction of the pachinko machine PM is called the left-right direction, and the depth direction of the pachinko machine PM is called the front-back direction.

The pachinko machine PM includes a game board PB, a game ball launcher BS, and the like, as shown in the figure. The game board PB is a substantially rectangular plate member extending in the vertical direction. The game board PB is arranged to face the player. That is, the board thickness direction of the game board PB coincides with the front-rear direction. The game ball launcher BS is arranged below the game board PB. The game ball shooting device BS shoots game balls (not shown) one by one toward the game board PB.

An opening OP is provided substantially in the center of the game board PB. A case CA in which the display device DD and the game machine shutter device 1 are assembled is arranged behind the opening OP. The case CA is a box-shaped member that opens forward (toward the player). A display device DD is arranged in the center of the case CA. A liquid crystal display, an organic EL display, or the like is used as the display device DD. The display device DD is connected to a control device (not shown) and displays an image according to a control signal supplied from the control device. A frame-like border decoration EP is attached to the periphery of the opening OP (see FIG. 1).

As will be described later in detail, the game machine shutter device 1 raises and lowers a shielding plate 10 extending in the left-right direction using a direct-acting device 20 (see FIGS. 2 and 3). As a result, the display surface of the display device DD is switched between a visible state and an invisible state.

The shielding plate 10 is composed of a pair of upper and lower first shielding plates 111 and 112 and a pair of upper and lower second shielding plates 121 and 122 . The first shielding plate 111 and the first shielding plate 112 are vertically symmetrical. Also, the second shielding plate 121 and the second shielding plate 122 are vertically symmetrical. Therefore, the configurations of the first shielding plate 111 and the second shielding plate 121 will be described below, and the description of the configurations of the first shielding plate 112 and the second shielding plate 122 will be omitted.

The first shielding plate 111 is, as shown in FIG. 4, a substantially rectangular plate member extending in the left-right direction. The first shielding plate 111 is arranged such that its plate thickness direction coincides with the front-rear direction. The horizontal dimension of the lower half of the first shielding plate 111 is slightly smaller than the horizontal dimension of the upper half. That is, the boundary between the upper half SLa ₁₁₁ and the lower half SLb ₁₁₁ of the left end surface SL ₁₁₁ of the first shielding plate 111, and the upper half SRa ₁₁₁ and the lower half of the right end surface SR ₁₁₁ of the first shielding plate 111 A step is provided at each boundary with the SRb ₁₁₁ .

The upper half portion SLa ₁₁₁ and the lower half portion SLb ₁₁₁ are provided with a convex portion PLa ₁₁₁ and a convex portion PLb ₁₁₁ extending leftward, respectively. A cross section perpendicular to the extending direction of the projection PLa ₁₁₁ and the projection PLb ₁₁₁ has a circular shape. The convex portion PLa ₁₁₁ and the convex portion PLb ₁₁₁ have the same outer diameter. The protrusion PLb ₁₁₁ is positioned below the protrusion PLa ₁₁₁ . The upper half SLa ₁₁₁ of the left end surface SL ₁₁₁ and the tip end surface (left end surface) of the projection PLb ₁₁₁ are positioned within the same plane. That is, when the lower half SLb ₁₁₁ is used as a reference, the leftward protrusion height of the protrusion PLa ₁₁₁ is greater than the leftward protrusion height of the protrusion PLb ₁₁₁ . The upper half portion SRa ₁₁₁ and the lower half portion SRb ₁₁₁ are provided with a convex portion PRa ₁₁₁ and a convex portion PRb ₁₁₁ similar to the convex portion PLa ₁₁₁ and the convex portion PLb ₁₁₁ , respectively. The first shielding plate 112 is also a plate-like member similar to the first shielding plate 111, and includes the protrusions PLa ₁₁₁ and PLb ₁₁₁ and the protrusions PLa ₁₁₂ and protrusions similar to the protrusions PRa ₁₁₁ and PRb ₁₁₁ . PLb ₁₁₂ and projection PRa ₁₁₂ and projection PRb ₁₁₂ (see FIG. 11).

The second shielding plate 121 is a rectangular plate member extending in the left-right direction, as shown in FIG. The second shielding plate 121 is arranged so that its plate thickness direction coincides with the front-rear direction.

The linear motion device 20 is composed of linear motion devices 20L and 20R. The linear motion device 20L and the linear motion device 20R are symmetrical. Therefore, the configuration of the linear motion device 20L will be described below, and the description of the linear motion device 20R will be omitted.

The linear motion device 20L includes a front linear motion mechanism 21, a rear linear motion mechanism 22, and an electric motor 23, as shown in FIG.

The front linear motion mechanism 21 includes a support plate 211 , a guide plate 212 , a slide mechanism 213 and a front lid 214 . The support plate 211 includes a substrate portion 211a and a peripheral wall portion 211b. The substrate portion 211a is a substantially rectangular flat plate portion extending in the vertical direction. The plate thickness direction of the substrate portion 211a coincides with the front-rear direction. The peripheral wall portion 211b extends along the upper, lower and left sides of the front surface of the substrate portion 211a. The peripheral wall portion 211b is perpendicular to the substrate portion 211a. A rib R _211a extending in the vertical direction is provided on the front surface of the substrate portion 211a. The rib R _211a is arranged at the central portion in the width direction (horizontal direction) of the substrate portion 211a. The rib R _211a extends linearly in the vertical direction from the upper end of the substrate portion 211a to the central portion of the substrate portion 211a in the vertical direction. Further, a through hole TH _211a penetrating in the front-rear direction is formed in a central portion of the substrate portion 211a and located slightly below the rib R _211a . Further, guide plate support portions 211c, 211d, and 211e for supporting the guide plate 212 described below are provided on the right end surface of the substrate portion 211a. The guide plate support portions 211c, 211d, and 211e protrude rightward from the upper end portion, the lower end portion, and the central portion in the vertical direction of the right end surface of the substrate portion 211a.

The guide plate 212 is a substantially rectangular plate member extending in the vertical direction. The guide plate 212 is arranged such that its plate thickness direction coincides with the left-right direction. The guide plate 212 is fixed to the guide plate support portions 211 c , 211 d and 211 e of the support plate 211 .

The guide plate 212 consists of a first guide portion 212a and a second guide portion 212b. The first guide portion 212a is a plate-like portion extending in the vertical direction. The second guide portion 212b is formed on the right surface of the first guide portion 212a.

The second guide portion 212b extends upward and downward from a plate-shaped base portion 212M parallel to the first guide portion 212a, and from the front end of the base portion 212M, which is arranged in the middle portion in the vertical direction of the first guide portion 212a. It has a leading edge 212UF and a leading edge 212DF. In other words, the base portion 212M, the front edge portion 212UF and the front edge portion 212DF protrude rightward when viewed from the first guide portion 212a. The first guide portion 212a and the second guide portion 212b are integrally formed. The first guide portion 212a and the second guide portion 212b are not solid, but hollow and open leftward, and have a plurality of ribs R ₂₁₂ inside (see FIG. 7).

A slit S _212U is formed in an upper portion 212U and a lower portion 212D of the portion of the first guide portion 212a that is exposed when viewed from the right side of the guide plate 212 (the portion that is not covered by the second guide portion 212b). and slits S _212D are respectively formed (see FIG. 8). The slit S _212U and the slit S _212D are vertically symmetrical. Therefore, the configuration of the slit S _212U will be described below, and the description of the slit S _212D will be omitted. The slit S _212U is composed of a straight portion Sa ₂₁₂ extending linearly in the vertical direction and an inclined portion Sb ₂₁₂ extending obliquely downward and rearward from the lower end of the straight portion Sa ₂₁₂ . The width of the slit _S212U is slightly larger than the outer diameter of the protrusion _PLa111 .

The base portion 212M is formed with a groove portion GU _212M entering downward from its upper end and a groove portion GD _212M entering upward from its lower end. The groove GU _212M and the groove GD _212M are vertically symmetrical. Therefore, the configuration of the groove portion GU _212M will be described below, and the description of the groove portion GD _212M will be omitted. The groove portion GU _212M is composed of a straight portion Ga ₂₁₂ extending linearly in the vertical direction and an inclined portion Gb ₂₁₂ extending obliquely downward and rearward from the lower end of the straight portion Ga ₂₁₂ . The width of the groove GU _212M is slightly larger than the outer diameter of the protrusion PLb ₁₂₁ . The straight portion Ga ₂₁₂ is arranged below the straight portion Sa ₂₁₂ of the slit S _212U . The inclined portion Gb ₂₁₂ is arranged below the inclined portion Sb ₂₁₂ of the slit S _212U . The slope Gb ₂₁₂ is parallel to the slope Sb ₂₁₂ . The distance between the inclined portion Gb ₂₁₂ and the inclined portion Sb ₂₁₂ of the slit S _212U is the same as the distance between the convex portion PLb ₁₁₁ and the convex portion PLa ₁₁₁ .

The slide mechanism 213 is arranged in front of the substrate portion 211a, as shown in FIG. The slide mechanism 213 includes a rack 213a and pinion gear 213b, and a rack 213c and pinion gear 213d. The rack 213a comprises a support plate portion SP _213a and a tooth portion TP _213a . The support plate portion SP _213a is a substantially rectangular flat plate portion. The plate thickness direction of the support plate portion SP _213a coincides with the front-rear direction. The support plate part SP _213a comprises a protruding part PP _213a . The protruding portion PP _213a protrudes rearward from the upper right corner of the support plate portion SP _213a . A groove GP _213a that opens to the right and extends in the front-rear direction is formed in the protrusion PP _213a . The tooth portion TP _213a extends downward from the lower right corner of the support plate portion SP _213a . The tooth portion TP _213a is an elongated plate-like portion parallel to the support plate portion SP _213a , and a plurality of teeth T _213a are formed on the left end surface thereof. These teeth T _213a are arranged vertically. These teeth T _213a mesh with the pinion gear 213b. The pinion gear 213b is a spur gear.

The rack 213c comprises a support plate portion SP _213c and a tooth portion TP _213c . The support plate portion SP _213c is a substantially rectangular flat plate portion. The plate thickness direction of the support plate portion SP _213c coincides with the front-rear direction. The support plate part SP _213c comprises a protruding part PP _213c . The protruding portion PP _213c protrudes rearward from the lower right corner of the support plate portion SP _213c . The protrusion PP _213c is formed with a groove GP _213c that opens to the right and extends in the front-rear direction. The tooth portion TP _213c extends upward from the upper left corner of the support plate portion SP _213c . The tooth portion TP _213c is an elongated plate-like portion parallel to the support plate portion SP _213c , and a plurality of teeth T _213c are formed on the right end surface thereof. These teeth T _213c are arranged vertically. These teeth T _213c mesh with the pinion gear 213d. The pinion gear 213d is a spur gear. The diameter of the pinion gear 213d is slightly smaller than the diameter of the pinion gear 213b. The pinion gear 213d is provided on the rear surface of the pinion gear 213b.

The front cover 214 is a rectangular plate member extending vertically (see FIG. 6). A front lid 214 is attached to the front surface of the support plate 211 .

The rear linear motion mechanism 22 is attached to the rear surface of the support plate 211 . The rear linear motion mechanism 22 has a support plate 221 , a guide shaft 222 and a slide mechanism 223 .

The support plate 221 includes a substrate portion 221a and a peripheral wall portion 221b. The substrate portion 221a is a substantially rectangular flat plate portion extending in the vertical direction. The plate thickness direction of the substrate portion 221a coincides with the front-rear direction. The peripheral wall portion 221b extends along the upper, lower and left sides of the front surface of the substrate portion 221a. The peripheral wall portion 221b is perpendicular to the substrate portion 221a. Further, a through hole TH _221a is formed in the central portion of the substrate portion 221a so as to penetrate therethrough in the front-rear direction. Further, guide shaft supporting portions SPa _221a , SPb _221a , and SPc _221a for supporting the guide shaft 222 described below are formed on the substrate portion 221a. These guide shaft support portions SPa _221a , SPb _221a , and SPc _221a are spaced apart in the vertical direction at the central portion in the width direction (horizontal direction) of the substrate portion 221a. That is, the guide shaft support portion SPa _221a is formed at the upper end portion of the _{substrate portion 221a} . The guide shaft support portion SPb _221a is formed at the lower end of the substrate portion _221a . The guide shaft support portion SPc _221a is formed at the center portion of the substrate portion 221a in the vertical direction.

The guide shaft 222 is a round bar extending vertically. The upper end portion, the lower end portion and the central portion of the guide shaft 222 are supported by the guide shaft support portions SPa _221a , SPb _221a and SPc _221a respectively.

The slide mechanism 223 is arranged between the substrate portion 221a and the substrate portion 211a. The slide mechanism 223, as shown in FIG. 10, includes a rack 223a and a pinion gear 223b, and a rack 223c and a pinion gear 223d. The rack 223a comprises a support plate portion SP _223a and tooth portions TP _223a . The support plate portion SP _223a is a substantially rectangular flat plate portion extending in the vertical direction. The plate thickness direction of the support plate portion SP _223a coincides with the front-rear direction. A tab plate portion BP _223a is formed on the support plate portion SP _223a . The tab plate portion BP _223a protrudes rightward from the upper portion of the right end surface of the support plate portion SP _223a . The tab plate portion BP _223a is a rectangular plate-like portion extending in the vertical direction. The plate thickness direction of the tab plate portion BP _223a coincides with the front-rear direction. Further, a cylindrical portion CP _223a is formed on the support plate portion SP _223a . The cylindrical portion CP _223a extends vertically at the left edge portion of the front surface of the support plate portion SP _223a . The inner diameter of the tubular portion CP ₂₂₃ a is substantially the same as the outer diameter of the guide shaft 222 . The tooth portion TP _223a is provided on the left surface of the cylindrical portion CP _223a . The tooth portion TP223a is composed of a plurality of teeth _T223a . These teeth T _223a are arranged vertically. These teeth T _223a mesh with the pinion gear 223b. The pinion gear 223b is a spur gear. The diameter of pinion gear 223b is smaller than the diameter of pinion gear 223d.

The rack 223c comprises a support plate portion SP _223c and a tooth portion TP _223c . The support plate portion SP _223c is a substantially rectangular flat plate portion extending in the vertical direction. The plate thickness direction of the support plate portion SP _223c coincides with the front-rear direction. The plate thickness direction of the support plate portion SP _223c coincides with the front-rear direction. A tab plate portion BP _223c is formed on the support plate portion SP _223c . The tab plate portion BP _223c protrudes rightward from the lower portion of the right end surface of the support plate portion SP _223c . The tab plate portion BP _223c is a rectangular plate-like portion extending in the vertical direction. The plate thickness direction of the tab plate portion BP _223c coincides with the front-rear direction. Further, a cylindrical portion CP _223c is formed on the support plate portion SP _223c . The tubular portion CP _223c extends vertically at the left edge of the front surface of the support plate portion SP _223c . The inner diameter of the tubular portion CP 223 _c is substantially the same as the outer diameter of the guide shaft 222 . Further, an arm portion AP _223c is formed on the cylindrical portion CP _223c . The arm part AP _223c is a substantially rectangular plate-like part extending in the left-right direction. The plate thickness direction of the arm portion AP _223c coincides with the front-rear direction. The tooth portion TP _223c extends upward from the upper left corner of the arm portion AP _223c . The tooth portion TP _223c is a parallel elongated plate-like portion of the arm portion AP _223c , and a plurality of teeth T _223c are formed on the right end surface thereof. These teeth T _223c are arranged vertically. These teeth T _223c mesh with the pinion gear 223d. The pinion gear 223d is a spur gear. The diameter of the pinion gear 223d is slightly smaller than the diameter of the pinion gear 223b. The pinion gear 223d is provided on the rear surface of the pinion gear 223b.

The electric motor 23 has a stepping motor and a reduction gear.

The rack 213a is arranged on the upper right part of the front surface of the support plate 211 (see FIG. 6). The rack 213c is arranged on the lower left part of the front surface of the support plate 211 . A pinion gear 213b, a pinion gear 213d and a through hole TH _211a are arranged coaxially. The pinion gear 213d is arranged between the pinion gear 213b and the substrate portion 211a. A tooth T _213a of the rack 213a meshes with the pinion gear 213b, and a tooth T _213c of the rack 213c meshes with the pinion gear 213d. A front cover 214 is attached to the front side of the support plate 211 . When the front lid 214 is attached to the support plate 211 , a space is formed between the front surface of the substrate portion 211 a and the rear surface of the front lid 214 . The slide mechanism 213 is accommodated in this space. That is, the base plate portion 211a and the front lid 214 restrict the movement of the slide mechanism 213 in the front-rear direction. The protrusions PP _213a and PP _213c protrude rearward through spaces extending vertically above and below the guide plate support portion 211c of the support plate ₂₁₁ , respectively. The vertical distance from the vertical center of the support plate 211 to the projection PP _213a is the same as the vertical distance from the vertical center of the support plate 211 to the projection PP _213c .

The rack 223 a is arranged on the upper right part of the front surface of the support plate 221 . The cylindrical portion CP _223a is fitted in the upper half portion of the guide shaft 222 (between the guide shaft support portion SPa _221a and the guide shaft support portion SPc _221a ). A rack 223 c is arranged on the front surface of the support plate 221 at the lower left portion. The tubular portion CP _223c is fitted in the lower half portion of the guide shaft 222 (between the guide shaft support portion SPb _221a and the guide shaft support portion SPc _221a ). A pinion gear 223b, a pinion gear 223d and a through hole TH _221a are arranged coaxially. The pinion gear 223d is arranged between the pinion gear 223b and the substrate portion 221a. A tooth T _223a of the rack 223a meshes with the pinion gear 223b, and a tooth T _223c of the rack 223c meshes with the pinion gear 223d. The rear linear motion mechanism 22 configured as described above is attached to the rear side of the front linear motion mechanism 21 . That is, the slide mechanism 223 is housed in the space between the substrate portions 211a and 221a. In the linear motion device 20L, the through hole _TH221a , the pinion gear 223d, the pinion gear 223b, the through hole _TH211a , the pinion gear 213d, and the pinion gear 213b are arranged coaxially. The vertical distance from the vertical central portion of the support plate 221 to the lower end of the tab plate portion BP _223a and the vertical distance from the vertical central portion of the support plate 221 to the upper end of the tab plate portion BP _223c They are almost identical.

The output shaft of the electric motor 23 is inserted into the through hole TH _221a , the pinion gear 223d, the pinion gear 223b, the through hole TH _211a , the pinion gear 213d, and the pinion gear 213b from behind the linear motion device 20L.

The pinion gears 213b, 213d, 223b, and 223d are integrally driven to rotate (forward or reverse) by the electric motor 23, thereby moving the racks 213a and 213c in opposite directions. At this time, the left end surface of the support plate portion SP _213a of the rack 213a and the right surface of the rib R _211a of the substrate portion 211a are in sliding contact, and the right surface of the rack 213a and the left surface of the guide plate 212 are in sliding contact. That is, the rack 213a moves vertically while being guided by the substrate portion 211a and the guide plate 212. As shown in FIG. On the other hand, the right end surface of the support plate portion SP _213c of the rack 213c and the left surface of the guide plate 212 are in sliding contact, and the left end surface of the tooth T _213c of the rack 213c and the peripheral wall portion 211b of the support plate 211 are in sliding contact. That is, the rack 213c moves vertically while being guided by the peripheral wall portion 211b and the guide plate 212 . On the other hand, the racks 223a and 223c are guided by the guide shaft 222 and move vertically.

As shown in FIG. 11, the projections PLa ₁₁₁ and PRa ₁₁₁ of the first shielding plate 111 are inserted into the slits S _212U and S _212U from the right and left sides of the linear motion devices 20L and 20R, respectively. The tip portions of the projections PLa ₁₁₁ and PRa ₁₁₁ are accommodated and supported in the grooves GP _213a and GP _213a of the linear motion devices 20L and 20R, respectively. Furthermore, the convex portions PLa ₁₁₂ and PRa ₁₁₂ of the first shielding plate 112 are inserted into the slits S _212D and S _212D from the right and left sides of the linear motion devices 20L and 20R, respectively. The tips of the protrusions PLa ₁₁₂ and PRa ₁₁₂ are accommodated and supported in the grooves GP _213c and GP _213c of the linear motion devices 20L and 20R, respectively.

Left and right ends of the rear surface of the second shielding plate 121 are fixed to the front surfaces of the tab plate portions BP _213a and BP _213a of the linear motion devices 20L and 20R. Left and right ends of the rear surface of the second shielding plate 122 are fixed to the front surfaces of the tab plate portions BP _213c and BP _213c of the linear motion devices 20L and 20R.

Next, the opening and closing operation of the shielding plate 10 of the game machine shutter device 1 will be described. For example, in a normal state during a game, the game machine shutter device 1 is set to the following fully open state (see FIGS. 2 and 13).
- By arranging the racks 213a, 213a of the linear motion devices 20L, 20R at the upper end of their movable ranges, the first shielding plate 111 is arranged at the upper ends of their movable ranges.
- By arranging the racks 213c, 213c of the linear motion devices 20L, 20R at the lower end of their movable ranges, the first shielding plate 112 is arranged at the lower ends of their movable ranges.
- By arranging the racks 223a, 223a of the linear motion devices 20L, 20R at the upper end of their movable ranges, the second shielding plate 121 is arranged at the upper ends of their movable ranges.
- By arranging the racks 223c, 223c of the linear motion devices 20L, 20R at the lower end of their movable ranges, the second shielding plate 122 is arranged at the lower ends of their movable ranges.

In the fully open state, the first shielding plates 111 and 112 are arranged in front of the second shielding plates 121 and 122 . The first shielding plate 111 and the second shielding plate 121 are positioned slightly above the upper end of the display device DD, and the first shielding plate 112 and the second shielding plate 122 are positioned slightly below the lower end of the display device DD. there is That is, the entire display surface of the display device DD can be visually recognized from the front.

In the fully open state, the projections PLa ₁₁₁ and PRa ₁₁₁ are inserted into the upper end portions of the straight portions Sa ₂₁₂ and Sa ₂₁₂ of the slits S _212U and S _212U , and their tip end portions protrude outside the guide plate 212. , into the front ends of the grooves GP _213a , GP _213a (see FIG. 12). Also, the convex portions PLb ₁₁₁ and PRb ₁₁₁ do not enter the slits S _212U and S _212U and are positioned to the right and left of the straight portions Sa ₂₁₂ and Sa ₂₁₂ , respectively. The projections PLa ₁₁₂ , PRa ₁₁₂ are inserted into the upper ends of the straight portions Sa ₂₁₂ , Sa ₂₁₂ of the slits S _212D , S _212D , and their distal ends protrude to the outside of the guide plate 212 to form the grooves GP _213c , GP. _213c . Also, the convex portions PLb ₁₁₂ and PRb ₁₁₂ do not enter the slits S _212D and S _212D and are positioned to the right and left of the straight portions Sa ₂₁₂ and Sa ₂₁₂ , respectively.

Here, behind the first shielding plates 111 and 112, the second shielding plates 121 and 122 are arranged to face each other. Furthermore, the front edge portions 212UF, 212UF of the guide plate 212 are positioned in front of the projections PLb ₁₁₁ , PRb ₁₁₁ . The front edge portions 212DF, 212DF of the guide plate 212 are positioned in front of the projections PLb ₁₁₂ , PRb ₁₁₂ . This restricts the rotation of the first shielding plate 111 around the central axis of the projections PLa ₁₁₁ and PRa ₁₁₁ and the rotation of the first shielding plate 112 around the central axis of the projections PLa ₁₁₂ and PRa ₁₁₂ . .

For example, when a predetermined game event occurs in the pachinko machine PM while the game machine shutter device 1 is in the fully open state (see FIG. 13), the game machine shutter device 1 is shifted to the fully closed state as described below. be. That is, the electric motors 23 of the linear motion devices 20L and 20R are synchronously driven forward by a control device (not shown). As a result, the racks 213a, 213a descend and the racks 213c, 213c ascend. That is, the first shielding plate 111 and the second shielding plate 121 descend, and the first shielding plate 112 and the second shielding plate 122 ascend. Here, the diameter of the pinion gear 223b is smaller than the diameter of the pinion gear 213b. Therefore, the descending speed of the second shielding plate 121 is smaller than the descending speed of the first shielding plate 111 (about half). Also, the diameter of the pinion gear 223d is smaller than the diameter of the pinion gear 213d. Therefore, the rising speed of the second shielding plate 122 is smaller than the rising speed of the first shielding plate 112 (about half). Incidentally, the diameter of the pinion gear 213d is slightly smaller than the diameter of the pinion gear 213b. Therefore, compared with the descending speed of the first shielding plate 111, the ascending speed of the first shielding plate 112 is slightly smaller. Also, the diameter of the pinion gear 223d is slightly smaller than the diameter of the pinion gear 223b. Therefore, the rising speed of the second shielding plate 122 is slightly smaller than the descending speed of the second shielding plate 121 .

Next, the lowering mode of the first shielding plate 111 and the second shielding plate 121 will be described. As described above, the protrusions PLa ₁₁₁ and PRa ₁₁₁ are inserted into the grooves GP _213a and GP _213a of the racks 213a and 213a, respectively. Therefore, when the racks 213a, 213a begin to descend from the fully open state, the first shielding plate 111 begins to descend. At that time, the base ends of the projections PLa ₁₁₁ and PRa ₁₁₁ are guided by the straight portions Sa ₂₁₂ and Sa ₂₁₂ of the slits S _212U and S _212U . Therefore, the first shielding plate 111 moves vertically downward in the initial stage of its downward movement. That is, at this stage, the first shielding plate 111 does not move in the front-rear direction. Although the second shielding plate 121 also begins to descend at the same time, the descending speeds of the two differ as described above. Therefore, the positions of the first shielding plate 111 and the second shielding plate 121 are shifted in the vertical direction, and the shift gradually increases.

When the racks 213a, 213a are further lowered, the projections PLb ₁₁₁ , PRb ₁₁₁ reach the upper ends of the straight portions Ga ₂₁₂ , Ga ₂₁₂ of the groove GU _212M . At this stage, the convex portions PLa ₁₁₁ and PRa ₁₁₁ have not yet reached the lower ends of the straight portions Sa ₂₁₂ and Sa ₂₁₂ of the slits S _212U and S _212U . Therefore, while the convex portions PLa ₁₁₁ and PRa ₁₁₁ are guided by the straight portions Sa ₂₁₂ and Sa ₂₁₂ and the convex portions PLb ₁₁₁ and PRb ₁₁₁ are guided by the straight portions Ga ₂₁₂ and Ga ₂₁₂ , the first shielding plate 111 , and move vertically downward. At the same time that the convex portions PLa ₁₁₁ and PRa ₁₁₁ reach the lower ends of the straight portions Sa ₂₁₂ and Sa ₂₁₂ , the convex portions PLb ₁₁₁ and PRb ₁₁₁ reach the lower ends of the straight portions Ga ₂₁₂ and Ga ₂₁₂ . At this point, the upper end of the first shielding plate 111 is positioned slightly below the lower end of the second shielding plate 121 (see FIG. 14).

When the racks 213a and 213a are further lowered, the convex portions _PLa111 and _PRa111 are guided by the inclined portions _Sb212 and _Sb212 , and the convex portions _PLb111 and _PRb111 are guided by the inclined portions _Gb212 and _Gb212 . , the first shielding plate 111 obliquely moves downward and rearward. At that time, the tips of the projections PLa ₁₁₁ and PRa ₁₁₁ move toward the rear ends of the grooves GP _213a and GP _213a .

When the racks 213a, 213a are further lowered, the protrusions _PLa111 , _PRa111 reach the tips (lower ends (rear ends)) of the slopes _Sb212 , _Sb212 , and the protrusions _PLb111 , _PRb111 reach the slopes Gb. ₂₁₂ , Gb reach the tip (lower end (rear end)) of ₂₁₂ (see FIG. 15).

On the other hand, the second shielding plate 121 only moves vertically downward during the whole process of its descent, and does not move in the front-rear direction.

Further, the operation mode of the first shielding plate 112 and the second shielding plate 122 and the operation mode of the first shielding plate 111 and the second shielding plate 121 are substantially vertically symmetrical. That is, the first shielding plate 112 moves vertically upward in the initial stage of its rising process. When the lower end of the first shielding plate 112 is positioned slightly above the upper end of the second shielding plate 122, the first shielding plate 112 moves upward and backward. In addition, the second shielding plate 122 only moves vertically upward during the entire rising process, and does not move in the front-rear direction.

The controller for the electric motor 23 monitors, for example, the vertical position of the rack 213a. Based on the vertical position of the rack _213a , the controller controls the projections _PLa111 and _PRa111 to reach the tips (lower ends (rear ends)) of the inclined portions _Sb212 and _Sb212 , It is detected that the PRb ₁₁₁ has reached the tip (lower end (rear end)) of the inclined portions Gb ₂₁₂ and Gb ₂₁₂ . The controller then stops the electric motor 23 . This completes the transition from the fully open state to the fully closed state of the game machine shutter device 1 .

In the fully closed state, the first shielding plates 111, 112 and the second shielding plates 121, 122 are vertically arranged in front of the display device DD. 122 covers the front of the display device DD. That is, the display surface of the display device DD cannot be visually recognized from the front. Also, the front surfaces of the first shielding plates 111 and 112 and the second shielding plates 121 and 122 are located in the same plane. In other words, there is no step at the boundaries between the first shielding plates 111 and 112 and the second shielding plates 121 and 122 . Moreover, there is almost no gap between the first shielding plates 111 and 112 and the second shielding plates 121 and 122 .

As described above, the first shielding plates 111 and 112 are pulled rearward between the second shielding plates 121 and 122 in the process of shifting from the fully open state to the fully closed state. As a result, the front surfaces of the first shielding plates 111 and 112 and the second shielding plates 121 and 122 are finally located on the same plane in the fully closed state. Therefore, according to this embodiment, the appearance quality of the shielding plate 10 in the fully closed state is improved.

Furthermore, from the fully open state, the second shielding plate 121 is lowered at a lower speed than the first shielding plate 111 and the second shielding plate 122 is raised at a lower speed than the first shielding plate 112 . As a result, the lower end of the second shielding plate 121 substantially abuts against the upper end of the first shielding plate 111 that has been drawn in backward, and the lower end of the second shielding plate 121 is in contact with the lower end of the first shielding plate 112 that has been drawn in rearward. The upper ends are substantially in contact with each other. Therefore, in the fully closed state, the gap (vertical gap) between the first shielding plate 111 and the second shielding plate 121 and the gap (vertical gap) between the first shielding plate 112 and the second shielding plate 122 gap) hardly occurs. According to this, it is possible to further improve the appearance quality of the game machine shutter device 1 in the fully closed state.

Also, when the first shielding plates 111 and 112 are pulled backward, the first shielding plates 111 and 112 and the second shielding plates 121 and 122 are kept parallel. In order to realize this operation mode, for example, a slit S _212U and a groove GU _212M are provided to guide the protrusion PLa ₁₁₁ and the protrusion PLb ₁₁₁ , respectively. These slits S _212U and grooves GU _212M are displaced in the vertical and horizontal directions, and are not displaced in the front-rear direction. According to this, compared with the case where the guide mechanism for guiding the upper end and the lower end of the end surface of the first shielding plate 111 is shifted in the front-rear direction, it is possible to reduce the size (thickness) of the shutter device 1 for a game machine. .

Further, by simply lowering the racks 213a and 213a and raising the racks 213c and 213c from the fully opened state, the first shielding plates 111 and 112 move along the inclined portion and move backward at the end of the operation process. be drawn in. Therefore, according to this embodiment, the configuration of the entire device can be simplified compared to the case where an actuator for moving the first shielding plate 111 in the vertical direction and an actuator for moving it in the front-rear direction are provided separately.

Furthermore, the implementation of the present invention is not limited to the above-described embodiments, and various modifications are possible without departing from the object of the present invention.

For example, the second shielding plates 121 and 122 may be omitted. In this case, for example, the first shielding plates 111 and 112 and the game board PB may be positioned on the same plane in the fully closed state.

Further, in the above embodiment, the first shielding plates 111 and 112 are arranged so as to overlap in front of the second shielding plates 121 and 122 in the fully opened state. The first shielding plates 111 and 112 are retracted obliquely rearward so that the front surfaces of the first shielding plates 111 and 112 and the second shielding plates 121 and 122 are positioned in the same plane. Alternatively, in the fully open state, the first shielding plates 111 and 112 are arranged so as to overlap behind the second shielding plates 121 and 122, and the first shielding plates 111 and 112 are pushed obliquely forward, The front surfaces of the first shielding plates 111 and 112 and the second shielding plates 121 and 122 may be arranged on the same plane. In this case, the inclined portion Sb ₂₁₂ of the slit S212U and the inclined portion Gb ₂₁₂ of the groove portion GU _212M extend obliquely forward and downward, and the inclined portion Sb ₂₁₂ of the slit S212D and the inclined portion Gb ₂₁₂ of the groove portion GD _212M extend forward and upward. It should be installed obliquely.

Further, for example, the game machine shutter device 1 may be arranged by being rotated by 90° around a central axis extending in the front-rear direction. That is, the first shielding plates 11, 112 and the second shielding plates 121, 122 may be moved in the horizontal direction.

DESCRIPTION OF SYMBOLS 1... Shutter device for game machines 10... Shield plate 11... First shield plate 20... Linear motion device 21... Front side linear motion mechanism 22... Rear side linear motion mechanism 23... Electric motor 111... First first shield plate Shielding plate 112 First shielding plate 121 Second shielding plate 122 Second shielding plate 211 Supporting plate 212 Guide plate 212a First guide portion 212b Second guide portion 213 Slide mechanism 221 Support plate 222 Guide shaft 223 Slide mechanism GD _{212M Groove} GU _{212M Groove} Ga ₂₁₂ Straight portion Gb ₂₁₂ Inclined portion PLa ₁₁₁ Convex PLa ₁₁₂ Convex Part, PLb ₁₁₁ ... Convex part, PLb ₁₁₂ ... Convex part, PM ... Pachinko machine, S _212D ... Slit, S _212U ... Slit

Claims (2)

a shielding plate parallel to the plate-shaped portion arranged facing the player;
an actuator that slides the shielding plate in a first direction parallel to the front surface of the plate-like portion;
The end portion of the shielding plate is in sliding contact with the end portion in the second direction perpendicular to the first direction and parallel to the front surface of the plate-like portion to guide the movement of the shielding plate in the first direction. A shutter device for a game machine, comprising a guide member for
a first protrusion and a second protrusion projecting from the end of the shielding plate in the second direction and spaced apart in the first direction;
The protrusion height of the first protrusion is set smaller than that of the second protrusion,
the guide member includes a first guide portion and a second guide portion that are arranged to be shifted in the second direction, the first guide portion being spaced apart in the second direction from the end portion of the shielding plate; a second guide portion disposed between the first guide portion and the end portion of the shielding plate;
The first guide portion includes a first straight portion linearly extending in the first direction and a first inclined portion obliquely extending forward or backward in the first direction from an end of the first straight portion. A first groove having
The second guide portion is a second groove portion arranged so as to be displaced in the first direction when viewed from the first groove portion, the second straight portion extending linearly in the first direction, and the second guide portion. A second groove portion having a second inclined portion obliquely extending forward or backward in the first direction from an end portion of the straight portion,
An extending direction of the first inclined portion and an extending direction of the second inclined portion are parallel, and a distance in the first direction between the first inclined portion and the second inclined portion is equal to the first inclined portion. is the same as the distance between the convex portion and the second convex portion,
The first convex portion is guided by the first groove portion of the first guide portion,
The second protrusion is guided by the second groove,
Shutter device for game machines. In the game machine shutter device according to claim 1,
further comprising an actuator that moves the plate-like portion in the first direction,
Shutter device for game machines.

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