JP2005052195A - Drum type game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a slot machine which performs effective performance display. <P>SOLUTION: A panel part 14a for performance is provided with a transmission type liquid crystal display panel LCD, a sub reel device 200 provided with sub reels SR1, SR2 and SR3 is disposed on the rear surface side of a display window WD2 formed on the liquid crystal display panel LCD, and a main reel device 100 provided with main reels MR1, MR2 and MR3 is arranged above the panel part 14a for the performance. The diameter of the respective main reels MR1, MR2 and MR3 is relatively small compared to the display window WD2 of the sub reel device 200, and a plurality of patterns whose vertical width is set to ≥25 mm and horizontal width is set to ≥35 mm are formed on respective outer peripheral surfaces. The large-sized sub reels SR1, SR2 and SR3 are provided with a light emitting unit and illumination display by the light emitting unit is performed accompanying the rotation of the sub reels SR1, SR2 and SR3. Then, by images displayed by the liquid crystal display panel LCD and illumination images by the light emitting means displayed at the display window WD2, various performance display is performed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a rotating type gaming machine such as a slot machine, and more particularly to a rotating type gaming machine including a main reel device for presenting a game result and an effect display device for producing an appealing visual effect.
[0002]
[Prior art]
Conventionally, in a slot machine that is a rotating type gaming machine, a main reel device composed of a plurality of reels called main reels is provided, and by allowing a combination of symbols drawn on these reels to be visually observed, The game result is presented to the player. In addition to the basic configuration of such a slot machine, a visual appealing display is provided in order for the player to enjoy the game.
[0003]
Here, a slot machine disclosed in Patent Document 1 is known as a slot machine made paying attention to the importance of the above-described effect display.
[0004]
In the slot machine (1) disclosed in Patent Document 1, a front door (2b) is provided on a housing (2a), and an upper decorative frame (4) is provided on the front door (2b). ), A game panel (6), a title panel (8), a medal insertion part (34), various operation buttons (35, 36a, 36b, 37, 40L, 40C, 40R), a start lever (38), etc. A so-called operation unit provided with the above is provided.
[0005]
Furthermore, a small effect reel (301L, 301C, 301R) is disposed in the upper decorative frame (4) so as to be visible, and a large size for presenting a game result is displayed in the center of the game panel (6). Reels (51L, 51C, 51R) are arranged so as to be visible.
[0006]
The large reels (51L, 51C, 51R) are so-called main reels for presenting game results, and when the start lever (38) is turned on by the player, it is 80 revolutions per minute or less. When the operation buttons (40L, 40C, 40R) are operated to stop in any order, the operation buttons (40L, 40C, 40R) are stopped according to the order, and the game result is presented to the player.
[0007]
That is, the slot machine (1) draws a symbol when the start lever (38) is turned on, and then the operation buttons (40L, 40C, 40R) are stopped. The main reels (51L, 51C, 51R) are stopped, and the symbols of the main reels (51L, 51C, 51R) finally stopped are on the active line in a predetermined combination corresponding to the lottery combination. When they are aligned, a prize is awarded and, for example, a predetermined number of medals are paid out.
[0008]
On the other hand, the production reels (301L, 301C, 301R) have large main reels (51L, 51C, 51R) in the center of the game panel (6) that follow the size of main reels that have been known for a long time. It is miniaturized because of the provided relationship.
[0009]
The slot machine (1) operates the small effect reels (301L, 301C, 301R) independently of the large main reels (51L, 51C, 51R), and the main reels (51L, 51C, 51R) In contrast to presenting the above-described game results, the effect reels (301L, 301C, 301R) perform effect display for the player to enjoy the game by performing various rotation operations.
[0010]
[Patent Document 1]
JP 2002-224270 A
[0011]
[Problems to be solved by the invention]
By the way, in the conventional slot machine, although the production reel is provided by paying attention to the importance of production, there is a problem that the production effect is not sufficiently exhibited because of the small size.
[0012]
For example, since the production reel described in Patent Document 1 is small in size, the number of symbols is extremely small, about five, and the number of symbol combination patterns is also small. There is a problem of not obtaining.
[0013]
In addition, it is possible to increase the number of symbol patterns by drawing a large number of symbols on a small production reel, but simply increasing the number of symbols necessitates a reduction in each symbol. This causes a problem that the performance deteriorates and it is difficult to produce a high visual effect.
[0014]
Although it is possible to increase the number of symbols by increasing the size of the production reel, a large production reel is also installed along with a large main reel in correspondence with the upper decorative frame and game panel with a limited occupation area. It is difficult to arrange in the body.
[0015]
In other words, the above-mentioned front door and the housing facing the player are inevitably limited in size, so even if a large production reel and a large main reel are provided, this is actually realized. The problem becomes difficult.
[0016]
The present invention has been made in view of such a conventional problem, and includes a main reel device and an effect display device, and appropriately presents a game result by the main reel device and more effective effect display by the effect display device. It is an object of the present invention to provide a swivel-type game machine that makes it possible to carry out
[0017]
[Means for Solving the Problems]
The invention according to claim 1 is a rotary type in which a main reel device provided with a plurality of main reels for presenting game results and an effect display device for effect display are arranged on a panel facing the player. In the gaming machine, each of the plurality of main reels has a relatively small diameter as compared with the effect display range of the effect display device, and an outer peripheral surface facing the player has a vertical width of 25 mm or more, A plurality of symbols having a width of 35 mm or more are formed, and the effect display device includes a first display device including an electroluminescence panel in which a transparent window is formed in a region facing the player; And a second effect device having a rotating body disposed on the back side of the transparent window portion of the electroluminescence panel and provided with one or more light emitting means. Together to display an effect image by sensing panel, by causing the electric decoration displayed on said light emitting means with to rotate the rotary member, and performs the effect display.
[0018]
According to a second aspect of the present invention, there is provided the rotary type gaming machine according to the first aspect, wherein the rotating body is provided with the plurality of light emitting means at different positions in a radial direction, and the second effect. The display device performs an electrical decoration display having a depth in the radial direction by the plurality of light emitting means as the rotating body is rotated.
[0019]
According to a third aspect of the present invention, there is provided a rotating game machine according to the first or second aspect, wherein the light emitting means displays a color image as an electric decoration.
[0020]
According to a fourth aspect of the present invention, there is provided a rotating game machine according to any one of the first to third aspects, wherein the light emitting means is formed of a plurality of light emitting diodes.
[0021]
A fifth aspect of the present invention is the swivel type gaming machine according to any one of the first to fourth aspects, wherein, in the panel portion, the main reel device is positioned above or below the effect display device. It is provided in the position of.
[0022]
A sixth aspect of the present invention is the rotary gaming machine according to any one of the first to fifth aspects, wherein the electroluminescence panel is a liquid crystal display panel.
[0023]
According to the first aspect of the present invention, the main reel device provided with the main reel that is smaller than the display range of the effect display device is arranged on the panel portion facing the player. The display area is relatively enlarged, and the effect display device is arranged in the enlarged area.
[0024]
The effect display device includes a first display device formed by an electroluminescence panel facing the player, and a first rotating device that is disposed on the back side of the electroluminescence panel and is provided with one or more light emitting means. 2 production devices.
[0025]
Here, in the electroluminescence panel, a transparent window portion is formed in a portion facing the player, and a second effect device having a rotating body provided with light emitting means on the back surface side of the transparent window portion. Is provided.
[0026]
An effect image is displayed by the electroluminescence panel, and an effect display is performed by causing the light emitting means to perform an electrical display as the rotating body is rotated. In addition, a small-sized main reel is formed with a symbol having a predetermined size in consideration of visibility, and a game result is appropriately presented to the player.
[0027]
In this way, it is possible to perform an effective presentation display while appropriately presenting the game result in the panel unit having a limited occupation area.
[0028]
According to the second aspect of the present invention, the plurality of light emitting means are provided at different positions in the radial direction of the rotating body, and the plurality of light emitting means are illuminated as the rotating body is rotated. By performing the display, an electrical decoration display having a depth in the radial direction is performed. This makes it possible to perform effective presentation display.
[0029]
According to the third or fourth aspect of the present invention, an effect display in the form of a color image or a so-called dot matrix is realized.
[0030]
According to the fifth aspect of the invention, the main reel device and the effect display device are provided by providing the main reel device at a position above the effect display device or the main reel device at a position below the effect display device. Visual effects due to the difference in the relative positional relationship between
[0031]
According to the invention described in claim 6, a liquid crystal display panel is used as the electroluminescence panel, and an image displayed on the liquid crystal display panel and an electric decoration display by the light emitting means as the rotating body is rotated. An effect display is performed depending on the image.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that a slot machine to which the present invention is applied will be described as a preferred embodiment of a rotating type gaming machine.
[0033]
1 is a front view showing the external structure of the slot machine 10 according to the present embodiment, FIG. 2 is a view showing the internal structure of the slot machine 10, and FIG. 3 is an exploded perspective view showing the mounting structure of the liquid crystal display panel. 4 is a diagram showing the structure of the liquid crystal display panel, FIG. 5 is an exploded perspective view schematically showing the structure of the liquid crystal display panel, and FIG. 6 is a control system provided in the slot machine 10. FIG.
[0034]
1 and 2, the slot machine 10 includes a box-shaped base 12 and a front door 11 pivotally supported on the front face of the base 12 so as to be opened and closed.
[0035]
In a room defined by the front door 11 and the base body 12, a small main reel device 100 for presenting a game result to be described later, a transmissive electroluminescence panel as a first effect display device, and a second A large-sized sub reel device 200 as an effect display device is provided.
[0036]
Although details will be described later, in the present embodiment, a transmissive liquid crystal display panel LCD having a backlight is provided as the transmissive electroluminescence panel described above, and the first effect display device and the second effect display device are provided. An effect panel 14a as an effect display device for effect display is configured by combination with the effect display device.
[0037]
The front door 11 includes an upper panel portion 13, a middle panel portion 14, and a lower panel portion 15 that are substantially integrally formed of hard plastic, and is further configured between the middle panel portion 14 and the lower panel portion 15. An operation portion 16 that protrudes slightly toward the player side is integrally provided.
[0038]
The front door 11 is designed to have a width WAA of about 475 mm and a height TA of about 810 mm, and is an area between the upper panel portion 13 and the middle panel portion 14 located above the operation portion 16 (referred to as “front panel portion”). The lateral width is designed to be about 475 mm and the longitudinal width TAA is about 462 mm, similar to the lateral width WAA of the front door 11.
[0039]
In other words, the area of the front door 11 that faces the player (referred to as “front panel portion”) has a width WAA of about 475 mm and a height TA of about 810 mm. The horizontal width of the front panel portion is about 475 mm, and the vertical width TAA is about 462 mm.
[0040]
The upper panel portion 13 is provided with a plurality of effect lamps 13a, 13b, 13c, 13d, 13e on which a design is designed and an effect panel 13f, and effects sound effects are provided on the player side. Sound output parts 13g and 13h are provided.
[0041]
A substantially rectangular transparent window (hereinafter referred to as “first display window”) WD1 is integrally formed at the center of the effect panel 13f, and a small size for presenting game results on the back side of the first display window WD1. The main reel device 100 is disposed.
[0042]
Although details will be described later, the main reel device 100 includes three small rotating reels (hereinafter referred to as “main reels”) MR1, MR2, and MR3, and a start lever BL described later is turned on. When operated, these main reels MR1, MR2, MR3 start rotating operation almost simultaneously, and when stop buttons BP1, BP2, BP3 described later are turned on (stop operation), the order in which the stop operations are performed. Accordingly, predetermined control is performed so that the rotating main reels MR1, MR2, MR3 are sequentially stopped.
[0043]
In addition, on the outer peripheral surfaces of the main reels MR1, MR2 and MR3, a predetermined number and a predetermined size of a pattern are drawn along the circumferential direction, and a first display window formed of a transparent plastic plate or the like. WD1 is designed to have a size such that the symbols drawn on each main reel MR1, MR2, MR3 can be visually recognized one by one.
[0044]
For this reason, for example, when the main reels MR1, MR2, MR3 are stopped, the player displays a total of three symbols arranged in a row along the active line L1 indicated by the one-dot chain line in FIG. Visible through the first display window WD1.
[0045]
The middle panel portion 14 is provided with a substantially rectangular effect panel 14a and effect lamps 14b and 14c provided on both sides of the effect panel 14a.
[0046]
Here, the effect panel 14a protects the liquid crystal display panel LCD having a display area (substantially rectangular display area) substantially the same size as the entire area of the middle panel section 14, and the entire display area of the liquid crystal display panel LCD. And a protective plate PN made of a transparent hard plastic plate (substantially rectangular hard plastic plate).
[0047]
In other words, a substantially rectangular protective plate PN is disposed on the front surface, and the liquid crystal display panel LCD is disposed on the back surface side of the protective plate PN so as to face the display area. The effect image displayed in the display area of the panel LCD is presented to the player side through the protective plate PN.
[0048]
Furthermore, a transparent window portion that simply transmits light is formed in the central portion (region WD2 in a substantially rectangular shape indicated by a dotted line (virtual line)) of the rectangular display region of the present liquid crystal display panel LCD. The area excluding the area (window portion) WD2 is the original display area.
[0049]
A rotating reel (hereinafter referred to as “sub-reel”) that is larger than the main reels MR1, MR2, MR3 described above is provided on the back side of the transparent window portion (hereinafter referred to as “second display window”) WD2 of the liquid crystal display panel LCD. A sub reel device 200 having SR1, SR2, SR3 is arranged.
[0050]
For this reason, the player can see the sub reels SR1, SR2, SR3 located on the back side of the liquid crystal display panel LCD through the second display window WD2, and is further displayed in the display area of the liquid crystal display panel LCD. It is possible to see the image.
[0051]
Furthermore, a predetermined number and a predetermined size of a pattern are drawn on the outer peripheral surface of each of the sub reels SR1, SR2, SR3 along the circumferential direction. For this reason, the player visually observes a plurality of symbols arranged horizontally or diagonally along a plurality of two-dot chain lines (virtual lines) L2 shown in the figure through the second display window WD2. it can.
[0052]
Further, although details will be described later, each of the sub reels SR1, SR2, SR3 is provided with light emitting units RL1, GL1, BL1 formed of high-intensity light emitting diodes, etc., and these light emitting units RL1, GL1, BL1. The lighting image is displayed. For this reason, the player not only displays the symbols drawn on the above-described sub reels SR1, SR2, SR3 and the effect image displayed on the liquid crystal display panel LCD, but also displays electric decorations by the light emitting units RL1, GL1, BL1. Can see.
[0053]
In this way, the effect panel 14a not only displays the effect image of the liquid crystal display panel LCD and the sub reels SR1, SR2, SR3 as described above, but also the symbols drawn on the sub reels SR1, SR2, SR3. By displaying the illumination images by the light emitting units RL1, GL1, and BL1, a variety of effects are displayed.
[0054]
Next, the operation unit 16 includes a medal insertion unit MD for inserting game medals necessary for playing the slot machine game, bet buttons BT1, BT2 for presenting the number of medals per game, A start lever BL for instructing the start of the game, stop buttons BP1, BP2, BP3 for individually stopping the rotating main reels MR1, MR2, MR3, and the front door 11 are locked or unlocked on the base body 12 side. A keyhole KY for inserting a predetermined key for locking is provided.
[0055]
Then, when the player inserts the required number of game medals into the medal insertion part MD or turns on one of the bet buttons BT1 and BT2 to turn on the start lever BL, the game starts. Thus, a so-called role lottery is performed on the main control board 700 to be described later, and the main reels MR1, MR2, MR3 of the main reel device 100 start rotating in a predetermined direction almost simultaneously.
[0056]
When the player continues to stop the stop buttons BP1, BP2, BP3 in a desired order, the main reels MR1, MR2, MR3 associated with the stop buttons BP1, BP2, BP3 are stopped according to the order in which the stop operations are performed. When the predetermined symbols drawn on the main reels MR1, MR2 and MR3 are arranged in a line on the above-mentioned effective line L1 in a combination corresponding to the above-mentioned lottery combination, a prize is awarded. Game medals are paid out.
[0057]
Further, the sub-reel device 200 is sub-reel under the control of the sub-control board 300, which will be described later, at least during the period from when the above-described start lever BL is turned on until all the main reels MR1, MR2, MR3 are stopped. SR1, SR2, SR3 are rotated in various ways, and further, so-called illumination display is performed by the light-emitting units RL1, GL1, BL1 provided on the sub-reels SR1, SR2, SR3, thereby providing an effect display appealing to the player's vision. Do.
[0058]
Further, the liquid crystal display panel LCD is also under the control of the sub control board 300 described later at least during the period from when the above-mentioned start lever BL is turned on until all the main reels MR1, MR2, MR3 are stopped. The effect is displayed with.
[0059]
The lower panel portion 15 has a substantially rectangular effect panel 15a on which a combination of symbols when winning is drawn, effect lamps 15b and 15c provided on the side of the effect panel 15a, and the player's A discharge port 15d and a tray 15e for paying out the acquired game medals, and sound emitting portions 15f and 15g to which a speaker for generating sound effects is attached on the back side are provided.
[0060]
Next, with reference to FIG. 2, the back surface structure of the front door 11 and the internal structure of the base 12 will be outlined. FIG. 2 shows a state in which the front door 11 is unlocked and opened from the base 12.
[0061]
In the figure, a light source (not shown) such as a fluorescent lamp or a high-intensity light-emitting diode constituting each of the effect lamps 13a, 13b, 13c, 13d, and 13e is detachably attached to the upper rear surface of the front door 11. The speakers Q1 and Q2 constituting the sound emitting units 13h and 13g are attached.
[0062]
Although not shown in FIG. 2, the first display window WD1 is located between the speakers Q1 and Q2, and the outer peripheral surfaces of the main reels MR1, MR2 and MR3 are opposed to the first display window WD1 side. The small main reel device 100 is attached.
[0063]
An illumination lamp (not shown) for illuminating the main reels MR1, MR2, MR3 is attached to the side between the first display window WD1 and the main reel device 100.
[0064]
A sub-control board 300 formed of an electric circuit board is attached to the back side of the main reel device 100.
[0065]
Further, the main reel device 100 includes a main reel control board (hereinafter referred to as a “rotating cylinder”) that controls an electric motor (stepping motor) for rotationally driving the main reels MR1, MR2, and MR3 in accordance with a command from the main control board 700. 900) (referred to as “device substrate”) is provided in advance.
[0066]
Below the main reel device 100 and the sub control board 300, a protective plate PN and a liquid crystal display panel LCD constituting the effect panel 14a are attached. Although not shown in FIG. 2, illumination lamps for illuminating the sub reels SR1, SR2, SR3 provided in the sub reel device 200 are attached above and below the back side of the liquid crystal display panel LCD. Yes.
[0067]
That is, as shown in FIG. 3, the middle panel portion 14 is formed with a rectangular opening AN that matches the size of the effect panel 14 a in advance, and a corridor-like concave step on the inner wall portion of the opening AN. A part ST is formed, and a protective plate PN and a liquid crystal display panel LCD are assembled to the concave step part ST from the back side, and a support part F provided in a casing CASE of the liquid crystal display panel LCD is attached to the middle panel. An effect panel 14a is configured in which the display area DSPAN side of the liquid crystal display panel LCD is directed to the front side by being fixed to the portion 14 with screws. An illumination lamp for illuminating the sub reels SR1, SR2, SR3 provided in the sub reel device 200 described above is attached to the back surface of the middle panel portion 14.
[0068]
Further, as shown in the perspective view of FIG. 4A, the housing CASE of the liquid crystal display panel LCD has a drive circuit for displaying an effect image on the liquid crystal display panel LCD in accordance with an instruction from the sub control board 300, and the like. A liquid crystal control board 1000 on which is formed is attached.
[0069]
Furthermore, an opening ANWD2 for generating the second display window WD2 is formed in advance in the central portion on the back side of the housing CASE, and the sub reel device 200 is disposed so as to face the opening ANWD2. The player can view the sub reels SR1, SR2, SR3 via the liquid crystal display panel LCD.
[0070]
That is, as schematically shown in the cross-sectional view of FIG. 4B, in the housing CASE of the liquid crystal display panel LCD, the polarizing filter V1 facing the protective plate PN side, and the glass substrate V2 , A color filter V 3, a transparent electrode V 4, a liquid crystal layer V 5, an alignment layer V 6, a transparent electrode V 7, a glass substrate V 8, and a polarizing filter V 9, and a backlight V 10, A light guide plate (light guide) V12 that guides light from V11 to enter the polarizing filter V9 side is provided.
[0071]
Then, the liquid crystal control substrate 1000 applies an image signal between the transparent electrodes V4 and V7, thereby twisting the liquid crystal molecules of the liquid crystal layer V5 with respect to the polarization direction of the polarizing filters V1 and V9, so that the light guide plate V12 side. The color image IMG0 is formed by controlling the light incident from the light source and mixing the light passing through the color filter V3.
[0072]
However, in the liquid crystal layer V5, a portion a5 corresponding to the opening ANWD2 is a window portion (gap portion) that is not filled with liquid crystal. For this reason, when an image signal is applied between the transparent electrodes V4 and V7, an image is displayed in a portion of the liquid crystal layer V5 that is filled with liquid crystal, whereas the window portion that is not filled with the liquid crystal described above. (Gaps) a5 does not display an image, and light SHin from the sub-reels SR1, SR2, SR3 illuminated by the above-described illumination lamp enters from the opening ANWD2, and in the second display window WD2, the sub-reels SR1, SR2, SR3 The image IMGS is displayed.
[0073]
Further, the structure of the present liquid crystal display panel LCD will be described in detail with reference to FIG.
[0074]
FIG. 5 is an exploded perspective view schematically shown for convenience of description. The polarizing filter V1, the glass substrate V2, the color filter V3, the transparent electrode V4, the liquid crystal layer V5, the alignment layer V6, and the transparent filter are described above. It is the figure which separated and showed the electrode V7, the glass substrate V8, the polarizing filter V9, and the light-guide plate V12.
[0075]
In FIG. 5, the light guide plate V12 is formed with an opening a12 having the same shape as the opening ANWD2 formed in the housing CASE, and a polarizing filter is formed in the rectangular portion a9 corresponding to the opening ANWD2 in the polarizing filter V9. It has not been.
[0076]
No opening is formed in the glass substrate V8, and a transparent electrode V7 is laminated on the front surface of the glass substrate V8.
[0077]
Furthermore, an opening is formed in a rectangular portion of the alignment layer V6 corresponding to the opening ANWD2, and one end of a tube-shaped liquid crystal sealing body CV is connected to the opening, and a transparent electrode is connected to the other end of the liquid crystal sealing body CV. V4 is provided.
[0078]
Further, no opening is formed in the glass substrate V2, and among the color filters V3 laminated on the plate surface of the glass substrate V2, a color filter is not formed in the rectangular portion a3 corresponding to the opening ANWD2. In the polarizing filter V1, the polarizing filter is not formed in the rectangular portion a1 corresponding to the opening ANWD2.
[0079]
Then, the polarizing filter V1, the glass substrate V2, the color filter V3, the transparent electrode V4, the liquid crystal layer V5, the alignment layer V6, the transparent electrode V7, the glass substrate V8, the polarizing filter V9, and the light guide plate V12 are laminated and sandwiched. The structure is realized.
[0080]
Here, a portion defined by the inner wall of the case CASE, the outer wall of the liquid crystal sealing body CV, and the opposing transparent electrode V4 and the alignment layer V6 is a liquid crystal layer V5 filled with liquid crystal. The inside of the liquid crystal sealing body CV is a void portion a5 that is not filled with liquid crystal.
[0081]
Thus, since the liquid crystal sealing body CV provides the gap portion a5 that is not filled with liquid crystal, even if an image signal is applied between the transparent electrodes V4 and V7, an image is not obtained in the gap portion a5. An image is formed only in the region of the liquid crystal layer V5 that is not formed and filled with liquid crystal.
[0082]
Therefore, as described above, in the second display window WD2 corresponding to the gap portion a5 in the display area of the liquid crystal display panel LCD, the sub reels SR1, SR2, SR3 located on the back side of the opening ANWD2 The image IMGS is displayed, and an image based on the above-described image signal is formed only in the region of the liquid crystal layer V5.
[0083]
Further, since the transparent electrodes V4 and V7 of the present liquid crystal display panel LCD are not removed (disconnected) in the portion corresponding to the opening ANWD2, an image is displayed on a general liquid crystal display panel in which liquid crystal is also filled in the gap portion a5. When an image signal to be displayed is applied to the present liquid crystal display panel LCD, only the range of the second display window WD2 is in a so-called blank state (transparent state), and the sub reels SR1, SR2, SR3 can be displayed. It has become.
[0084]
Therefore, the present liquid crystal display panel LCD simply scans the transparent electrodes V4 and V7 with an image signal for displaying a so-called one-frame image, and is in a state of being transparent only within the range of the above-described second display window WD2. State).
[0085]
In the present embodiment, the opening ANWD2 and the light shielding part INS are formed on the back surface of the housing CASE, but instead of the light shielding part INS, a light shielding film having the same shape as the light shielding part INS is deposited on the back surface of the light guide plate V12. Alternatively, a light incident region and a light shielding region having the same shape as the opening ANWD2 may be realized by laminating and printing.
[0086]
In FIG. 2 again, an electric circuit board 400 called a “central display board” is provided below the effect panel 14a. The central display board 400 is electrically connected to bet switches BT1 and BT2 provided on the operation unit 16, a start lever BL, stop buttons BP1, BP2 and BP3, and the switches BT1 and BT2. , BL, BP1, BP2, BP3 output signals are transferred to the main control board 700 side.
[0087]
Below the central display board 400, a selection mechanism G0 that distributes an input inserted from the medal insertion unit MD according to whether it is a regular game medal or a foreign object, and a game medal distributed by the selection mechanism G0 to the base 12 side. A guide member G1 that guides the provided hopper device HP, a guide member G2 that guides the foreign matter distributed by the selection mechanism G0 to the discharge port 15d, and a payout game medal output from the hopper device HP. A guide member G3 for guiding to 15d is provided, and speakers Q3 and Q4 constituting sound emitting portions 15f and 15g are attached in the vicinity of the discharge port 15d.
[0088]
In the base 12, a main power supply device PWU, an auxiliary storage unit SHP for storing game medals overflowing from the hopper device HP, and a sub reel device 200 are provided.
[0089]
When the front door 11 is locked to the base body 12 side, the sub reel device 200 has a predetermined frame in the base body 12 so that the outer peripheral surfaces of the sub reels SR1, SR2, SR3 face the opening ANWD2 of the liquid crystal display panel LCD. It is positioned and attached (reference number omitted).
[0090]
A power supply device substrate 500 corresponding to a so-called switchboard is provided on the side surface of the main power supply device PWU, and an electric motor (stepping motor) for rotating the sub reels SR1, SR2, SR3 is controlled at the upper end of the sub reel device 200. An effect circuit board 600 is provided, and a main control board 700 for centrally controlling the entire slot machine 10 is provided above the effect circuit board 600, and is installed at one end of the inner wall of the base 12 in a game hall or the like. An external concentrated terminal board 800 that can be connected to a management computer called a “Hall computer” is attached.
[0091]
Although details will be described later, an effect control circuit 211 for causing the effect display to be performed by controlling the sub reel device 200 is formed on the effect circuit board 600.
[0092]
The sub-control board 300, the central display board 400, the power supply board 500, the rendering circuit board 600, the main control board 700, the external concentrated terminal board 800, the rotary device board 900, and the liquid crystal control board 1000 are all conductive. The circuit board is formed as a so-called electric circuit board in which electronic components such as an integrated circuit device, a transistor, a resistor, and a capacitor are mounted and connected by wiring on an insulating resin substrate on which a conductive wiring pattern is formed.
[0093]
Next, a control system provided in the slot machine 10 will be described with reference to the block diagram of FIG.
[0094]
First, although not shown in FIG. 2 for convenience of explanation, the main control board 700 includes a spinning device board 900, a sub control board 300, a central display board 400, a power supply board 500, and an external concentrated terminal board 800. Each of them is connected by wiring cables. Further, the effect circuit board 600 and the liquid crystal control board 1000 are connected to the sub-control board 300 by wiring.
[0095]
The main control board 700 is equipped with a semiconductor memory ROM and a microprocessor MPU. The microprocessor MPU executes a system program and a slot machine game program stored in advance in the semiconductor memory ROM. By giving predetermined commands to 900, 300, 400, 500, and 800 to perform distributed control respectively, the progress of the game in the slot machine 10 is centrally controlled.
[0096]
Stepping motors MM1, MM2, and MM3 for rotating the main reels MR1, MR2, and MR3 are connected to the spinning device substrate 900.
[0097]
When a control signal indicating that the main reels MR1, MR2, MR3 should be rotated or stopped is supplied from the main control board 700, the rotator apparatus board 900 controls the power supply to the stepping motors MM1, MM2, MM3. The operation of the main reels MR1, MR2, MR3 is controlled.
[0098]
In other words, when the start lever BL is turned on and a control signal suggesting the start of rotation is supplied from the main control board 700, the rotator apparatus board 900 starts the stepping motors MM1, MM2, and MM3, and The reels MR1, MR2, and MR3 are controlled to rotate at a constant speed of 80 rpm or less.
[0099]
Further, when the stop button BP1 is turned off and the control signal for stopping the main reel MR1 is supplied from the main control board 700, the spinning device board 900 performs braking control on the stepping motor MM1 and stops the stop time. The main reel MR1 is stopped within (190 msec). When the stop button BP2 is turned off and a control signal for stopping the main reel MR2 is supplied from the main control board 700, the stepping motor MM2 is braked and the main reel is reached within the stop time (190 msec). MR1 is stopped. Further, when a control signal for stopping the main reel MR3 is supplied from the main control board 700 by turning off the stop button BP3, the stepping motor MM3 is braked and controlled within the stop time (190 msec). MR3 is stopped.
[0100]
The sub control board 300 is connected to the stage lamps 13a to 13e, 14b, 14c, 15b, and 15c and the speakers Q1 to Q4. When the stage control signal is supplied from the main control board 700, the stage lamps 13a to 13e. , 14b, 14c, 15b, 15c and the speakers Q1 to Q4 are driven to produce an effect appealing to the visual and auditory sense of the player.
[0101]
Further, when the above-described effect control signal is supplied from the main control board 700, the sub control board 300 instructs the effect circuit board 600 to start the stepping motors SM1, SM2, SM3 of the sub reel device 200, and the sub reels SR1, An effect display is performed by rotating SR2 and SR3. Furthermore, the effect display is performed by displaying the light emitting units RL1, GL1, and BL1 provided on the sub reels SR1, SR2, and SR3 in an electrical manner.
[0102]
Further, when the above-described effect control signal is supplied from the main control board 700, the sub control board 300 instructs the liquid crystal control board 1000 to cause the liquid crystal display panel LCD to perform an effect display.
[0103]
The central display board 400 is connected to the bet buttons BT1 and BT2, the start lever BL and the stop buttons BP1, BP2 and BP3, and controls the output signals output from these switches BT1, BT2, BL, BP1, BP2 and BP3. It functions as a relay board that transfers to the board 700.
[0104]
Further, the central display board 400 transfers an output signal output from a game medal detection sensor (not shown) provided in the selection mechanism G0 to the main control board 700, and the number of medals inserted in the medal insertion part MD. In addition to notifying about the introduction of foreign matter and clogging.
[0105]
The main control board 700 detects the number of bets per game when the bet buttons BT1 and BT2 are turned on, and detects that a game start instruction is issued when the start lever BL is turned on. When the stop buttons BP1, BP2, BP3 are stopped in an arbitrary order, it is detected that an instruction to stop the main reels MR1, MR2, MR3 is issued in that order.
[0106]
Here, when the main control board 700 detects that the above-mentioned start lever BL is turned on, a command for lottery apparatus board 900 to rotate the above-mentioned main reels MR1, MR2, MR3 is performed after performing the role lottery. At the same time, the sub-control board 300 is instructed to perform the above-described effects.
[0107]
When the stop buttons BP1, BP2, and BP3 are stopped in any order, the main control board 700 stops the main reels MR1, MR2, and MR3 in the order of the stop operations, and lottery is performed as described above. A command is sent to the spinning device substrate 900 to align the symbols corresponding to the roles on the effective line L1.
[0108]
In addition, the main control board 700 instructs the sub control board 300, and each time the stop buttons BP1, BP2, BP3 are stopped, the effect lamps 13a to 13e, 14b, 14c, 15b, 15c and the speaker Q1 are displayed. The game progress status and the like are notified to the player, etc., by variously changing the effects by the sub reel device 200 and the liquid crystal display panel LCD.
[0109]
The power supply substrate 500 is formed with a power distribution circuit that distributes various power supply voltages generated by the power supply device PWU to the hopper device HP and other places, and supplies system power necessary for the operation of the slot machine 100 from the power distribution circuit. To do.
[0110]
When the power supply device board 500 receives a command to pay out game medals from the main control board 700, it controls the hopper device HP to pay out game medals.
[0111]
The external concentrated terminal board 800 sends a signal indicating the progress of the game in the slot machine 10 output from the main control board 700 to the hall computer described above.
[0112]
Next, the structure of the main reel device 100 will be described with reference to FIGS.
[0113]
7 is a perspective view showing an external structure of the main reel device 100, FIG. 8 is an exploded perspective view of the main reel device 100, and FIG. 9A shows a main reel unit provided in the main reel device 100. FIG. 9B is a side view of the main reel, FIG. 10 is a cross-sectional view of the main reel unit broken away, and FIG. 11 is mounted on the outer periphery of the main reel. FIG.
[0114]
As shown in FIG. 7, the main reel device 100 includes three main reels MR1, MR2, MR3, a reel case main body 101 and a reel case cover 102 that accommodate these cylindrical main reels MR1, MR2, MR3, A sub-control board 300 housed in the housing cases 301 and 302 is attached to the rear surface side of the reel case cover 102.
[0115]
As shown in FIG. 8, the reel case main body 101 is a rectangular tube body molded with plastic, and the outer peripheral surfaces of the three main reels MR1, MR2, MR3 can be visually recognized through the display window WD1. A substantially rectangular opening 103 is formed.
[0116]
The reel case cover 102 is a rectangular housing made of plastic and is fitted to the reel case main body 101 to accommodate the three main reels MR1, MR2, MR3.
[0117]
The spinning device substrate 900 is attached to one end of the reel case cover 102 and supplied from the main control substrate 700 to the stepping motors MM1, MM2, MM3 for rotationally driving the main reels MR1, MR2, MR3. By supplying electric power subjected to pulse width control according to the control signal, the rotation, braking and stopping of the stepping motors MM1, MM2 and MM3 are controlled, and consequently the operation of the main reels MR1, MR2 and MR3 is controlled.
[0118]
The sub-control board 300 includes a microprocessor that performs control for presentation, a read-only memory (ROM) that stores the computer program and presentation data executed by the microprocessor, and various data generated during the execution of the presentation process. An electric circuit equipped with a random access memory (RAM) for temporarily storing is mounted.
[0119]
The main reel MR1 and the stepping motor MM1 are configured as a single first main reel unit assembled to the support plate MS1, and the main reel MR2 and the stepping motor MM2 are configured as a single second main reel unit assembled to the support plate MS2. The main reel MR3 and the stepping motor MM3 are configured as a single third main reel unit assembled to the support plate MS3.
[0120]
In the assembly process, the support plate MS1 in which the main reel MR1 and the stepping motor MM1 are assembled in the slots SL1, SL2, and SL3 formed at equal intervals on the inner wall of the reel case main body 101, the main reel MR2, and the stepping motor. A support plate MS2 to which MM2 is assembled, a main reel MR3 and a support plate MS3 to which a stepping motor MM3 is assembled are respectively mounted, and one end of each of the support plates MS1, MS2, and MS3 is one end of the reel case body 101. It is fixed with screws.
[0121]
Further, all of the first to third main reel units have basically the same size and structure, and the first main reel unit MU1 having the main reel MR1, the stepping motor MM1, and the support plate MS1 is provided. As a representative example, the configuration is as follows.
[0122]
First, as shown in FIGS. 9A and 10, the stepping motor MM1 is fixed to the plate surface of the support plate MS1 formed of metal or hard plastic by screwing or the like.
[0123]
A cylindrical relay shaft 105 formed of hard plastic and having a flange portion 105a is fitted on the rotation shaft 104 of the stepping motor MM1 orthogonal to the support plate MS1, and a relay member formed of hard plastic and having a projection 106a. 106 is fitted in the relay shaft 105.
[0124]
Furthermore, the tip of the relay shaft 105 penetrates the relay member 106 and protrudes toward the main reel MR1.
[0125]
On the other hand, the main reel MR1 is formed of a hard plastic as a whole, and extends radially from the cup-shaped base 107 assembled to the tip of the relay shaft 105 and the base 107 as shown in FIG. 9B. A plurality of arm portions 108, a first annular portion 109 connected to the tip of the arm portion 108, a second annular portion 110 having the same diameter as the first annular portion 109, A plurality of bridge portions 111 that bridge the first annular portion 109 and the second annular portion 110 are integrally formed.
[0126]
Then, the reel tape MTP1 formed of a long plastic sheet on which a plurality of symbols shown in FIG. 11 are printed is mounted on the outer circumference of the first and second annular portions 109 and 110, An outer peripheral surface of the main reel MR1 is formed.
[0127]
Further, a female screw portion 104a is formed at the center of the rotating shaft 104, and through holes 105b and 107a aligned with the female screw portion 104a are also formed at the central portions of the relay shaft 105 and the base 107, respectively. The relay shaft 105, the relay member 106, and the base 107 are fixed to the rotating shaft 104 of the stepping motor MM1 by screwing and tightening the male screw 112 to the female screw portion 104a through the through holes 107a and 105b. Thus, the main reel MR1 is rotated by receiving the driving force of the stepping motor MM1.
[0128]
Although not shown, the stepping motor MM1 incorporates an optical rotary encoder that detects the rotation angle of the rotary shaft 104 with respect to a predetermined reference angle. By rotating the stepping motor MM1 while comparing the angle detection signal output from the control signal supplied from the main control board 700, the rotation of the stepping motor MM1 according to the control signal supplied from the main control board 700 is performed. And the control of braking and stopping, and thus the rotation of the main reel MR1 and the control of braking and stopping are appropriately performed.
[0129]
As described above, the main reel MR1 has a cylindrical shape and is reduced in weight by mounting the reel tape MTP1 on a skeleton formed of lightweight plastic, and a large load is applied to the stepping motor MM1. Not to give.
[0130]
Further, when the base 107 is fixed to the rotating shaft 104, the main reel MR1 is disposed so as to contain the stepping motor MM1, so that a unit structure having a small thickness in the axial direction of the rotating shaft 104 is realized.
[0131]
The second main reel unit having the main reel MR2 and the stepping motor MM2 assembled to the support plate MS2, and the third main reel unit having the main reel MR3 and the stepping motor MM3 assembled to the support plate MS3 are also described above. 11 has the same basic structure as the first main reel unit MU1, and a reel tape MTP2 shown in FIG. 11 is mounted on the main reel MR2, and a reel tape MTP3 is mounted on the main reel MR3.
[0132]
In addition, the main reel device 100 can be downsized by setting the diameters R of the main reels MR1, MR2, MR3 to any value within the range of about 95 mm to about 140 mm.
[0133]
Furthermore, the number K of symbols drawn on each of the reel tapes MTP1, MTP2, and MTP3 is determined to be any number of 12 or more and 15 or less.
[0134]
Furthermore, the vertical width H of the symbols drawn on the reel tapes MTP1, MTP2, and MTP3 is determined to be about 25 mm or more, and the horizontal width W is about 35 mm or more, and a slight gap is provided so that adjacent symbols do not contact each other. It is drawn. That is, the symbol pitch PP is slightly larger than the symbol vertical width H, which makes it easy to visually recognize each symbol.
[0135]
Describing a specific example of this embodiment, as shown in FIG. 11, each reel tape MTP1, MTP2, MTP3 includes, for example, “watermelon”, “grape”, “lemon”, “peach”, and “eggplant”. 13 types are drawn each combining various kinds of symbols. Further, the vertical width H of the symbols drawn on the reel tapes MTP1, MTP2, and MTP3 is determined to be about 26 mm, the horizontal width W is about 35 mm, and the pitch interval PP is about 29.5 mm. The reel tapes MTP1, MTP2, and MTP3 The length L is about 383 mm and the width WT is about 44 mm.
[0136]
Further, in accordance with the length L and width WT of each reel tape MTP1, MTP2, MTP3, the diameter R of each main reel MR1, MR2, MR3 is determined to be about 122 mm and the width is about 44 mm.
[0137]
Furthermore, when the start lever BL is turned on, a role lottery is performed by the microprocessor MPU provided on the main control board 700, and the main reels MR1, MR2, MR3 are controlled by the rotating apparatus board 900. When the stop buttons BP1, BP2 and BP3 are further operated to stop at a rotational speed of 80 rpm or less, the operation is stopped within 190 msec from the time when each stop operation is performed. Then, within the predetermined stop time (190 msec), by moving the symbols for a maximum of 3 frames, the symbols corresponding to the above-mentioned lottery roles are aligned and stopped on the effective line L1. ing.
[0138]
That is, the maximum number of moving frames of the above-described symbol is called “the number of control frames”, and in this embodiment, the number of control frames is determined to be three. Then, when the symbol to be stopped (the symbol corresponding to the lottery role) comes on the active line L1 when the stop operation is performed, the main reels MR1, MR2, MR3 are stopped at that time, On the other hand, when the symbol to be stopped does not come on the effective line L1 at the time of the stop operation, each main reel MR1, MR2, MR3 is set to one symbol or two symbols during the stop time (190 msec). When the symbol to be rotated and the symbol to be stopped thereby comes on the effective line L1, each main reel MR1, MR2, MR3 is stopped there.
[0139]
Next, a sub reel device 200 as a second effect display device will be described with reference to FIGS.
[0140]
12A is a perspective view showing the external structure of the sub reel device 200, FIG. 12B is a perspective view showing the external structure of the sub reel unit provided in the sub reel device 200, and FIG. FIG. 3 is a development view showing reel tapes STP1, STP2, and STP3 mounted on the sub reels SR1, SR2, and SR3.
[0141]
12A, in the sub reel device 200, three cylindrical sub reels SR1, SR2, SR3 are accommodated in a rectangular support case 201 formed of hard plastic, and each sub reel SR1, SR2, SR3 is accommodated. The reel tapes STP1, STP2, and STP3 illustrated in FIG. The reel tapes STP1, STP2, and STP3 have a plurality of symbols that are larger than the symbols drawn on the main reels MR1, MR2, and MR3. Each of the sub reels SR1, SR2, SR3 is designed to have a diameter of about 230 mm and a width of about 80 mm.
[0142]
Basically, by the same unit structure as the main reel device 100 described above, a stepping motor (reference numeral omitted) for rotationally driving the sub reel SR1, a stepping motor (reference numeral omitted) for rotating the sub reel SR2, and a sub reel SR3 A stepping motor SM3 is provided to rotate the motor, and although not shown in FIG. 12A, the above-described effect circuit board 600 is attached to the upper end of the support case 201.
[0143]
Further, referring to FIG. 12B, the structure of the sub reel unit SU3 including the sub reel SR3 and the stepping motor SM3 will be described as a representative as follows.
[0144]
First, the stepping motor SM3 is fixed to one side surface of the support plate 202 made of hard plastic, and the sub reel SR3 is fixed to the tip of the rotating shaft 203 of the stepping motor SM3.
[0145]
The sub reel unit SU3 integrated with the sub reel SR3, the stepping motor SM3, and the support plate 202 is configured. The sub reel unit SU3 is accommodated in the rectangular support case 201, and the support plate 202 and the support case 201 are arranged. It is fixed by screwing.
[0146]
The sub reel unit SU1 having the sub reel SR1 and the sub reel unit SU2 having the sub reel SR2 also have the same structure as the sub reel unit SU3, and these three sub reel units SU1, SU2, SU3 are included in the support case 201. As a result, the sub reel device 200 shown in FIG. 12A is configured.
[0147]
The sub reel SR3 will be described with the sub reel SR3 as a representative. The sub reel SR3 includes a base portion 204 fixed to the rotating shaft 203 of the stepping motor SM3, a plurality of arm portions 205 extending radially from the base portion 204, and an arm portion. An annular ring portion 206, 207 formed concentrically around the rotating shaft 203 is integrally formed at the tip portion of 205, and the reel tape STP3 is mounted on the outer peripheral surface of the ring portion 206, 207. As a result, the overall shape is substantially cylindrical.
[0148]
Further, in the reel tape STP3, three regions where the circumferential angles around the rotation shaft 203 are approximately 0 ° (or 360 °), 120 °, and 240 ° when mounted on the ring portions 206 and 207 are provided. However, this is a transparent region that transmits light emitted from the light emitting units RL1, GL1, and BL1.
[0149]
For example, as illustrated in FIG. 13, between the symbols of “lemon” and “bell” determined at a position of approximately 0 ° (or 360 °), and “lemon” determined at a position of approximately 120 °. Between the symbol of “Cherry” and the symbol of “Saijo” and the numeral “7” determined at a position of approximately 240 ° are respectively transparent areas.
[0150]
Light emitting units RL1, GL1, and BL1 are provided on the back side of the three transparent regions described above.
[0151]
For convenience of explanation, FIG. 13 shows that reel tapes STP1, STP2 and STP3 having the same design pattern are mounted on the sub reels SR1, SR2 and SR3. The positional relationship between the symbols STP2 and STP3 is different, and printing is performed by combining a plurality of predetermined symbols and changing the arrangement.
[0152]
Next, as shown in FIG. 12B, each of the light emitting units RL1, GL1, and BL1 is formed of an elongated electric circuit board that is attached so as to bridge between the ring portions 206 and 207. Each electric circuit board has a predetermined number m (24 or more in the present embodiment) of high-intensity light emitting diodes along the longitudinal direction so as to be within the width of the reel tape STP3 at a predetermined pitch interval. They are arranged in a line.
[0153]
The light emitting unit RL1 includes m red (R) high luminance light emitting diodes LDR11 to LDR1m, the light emitting unit GL1 includes m green (G) high luminance light emitting diodes LDG11 to LDG1m, and the light emitting unit BL1 includes m light emitting units BL1. Blue (B) high-intensity light emitting diodes LDB11 to LDB1m are formed, and as schematically shown in FIGS. 14 (a), 14 (b), and 14 (c), the rotation axis 203 is the center. The ring portions 206 and 207 are attached to the inner peripheral surfaces at an angle of 120 ° to each other.
[0154]
The light-emitting units RL1, GL1, and BL1 are aligned with the above-described three transparent regions, and the reel tape STP3 is mounted, and is emitted from the light-emitting units RL1, GL1, and BL1, and is transmitted through the transparent regions. The effect image is displayed on the side of the observation surface (in other words, the second display window WD2) where the player is positioned by the light to be played.
[0155]
In FIG. 15, the rotary shaft 203 is formed of a hollow tube, and is supported by a bearing 208 provided in the case of the stepping motor SM3, and is rotated by the electromagnetic force of the drive coil 209. It has become. As described above, the base portion 204 of the sub reel SR3 is fixed to the tip portion of the rotating shaft 203.
[0156]
The tube member 210 fixed to the support plate 202 is inserted into the hollow of the rotating shaft 203 without contact, and the first and second transmission units that emit light are inserted into the distal end portion of the tube member 210. Light-emitting devices EL1 and EL2 are attached, and transmission cables CB11 and CB12 that connect the first and second light-emitting devices EL1 and EL2 and the effect control circuit 211 formed in the effect circuit board 600 are connected to the tube member 210. It is arranged along.
[0157]
The first light emitting device EL1 is attached at a position corresponding to the axis center of the rotating shaft 203, and receives power supplied via a transmission cable CB11 from a power supply device 211e described later provided in the effect control circuit 211. It is formed of a high power type light emitting diode or the like with high directivity that is converted into light and emitted.
[0158]
The second light-emitting device EL2 is attached at a position slightly deviated from the above-described axis center, and is sent from the transmission signal generation unit 211b (described later) provided in the effect control circuit 211 via the transmission cable CB12. The signal CS and the transmission signals such as the image signals S1 to Sm are formed by infrared light emitting diodes or the like that convert the signals into infrared light and emit the light at a wide angle.
[0159]
On the other hand, at one end of the inner wall of the rotating shaft 203, first and second light receiving devices PD1 and PD2 as receiving means, that is, a first light receiving device PD1 that receives light from the first light emitting device EL1, A second light receiving device PD2 that receives light from the second light emitting device EL2 is attached.
[0160]
The first light receiving device PD1 is attached to the position corresponding to the axial center of the rotating shaft 203 so as to face the first light emitting device EL1, and has a high power emitted from the first light emitting device EL1. It is formed of a high-power photodiode that photoelectrically converts light. Then, the photoelectrically converted power is supplied to the display control unit 212 fixed to one end of the sub reel SR3 via the transmission cable CB21.
[0161]
The second light receiving device PD2 is mounted at a position slightly deviated from the above-mentioned axis center, and receives a light emitted from the second light emitting device EL2 at a wide angle and photoelectrically converts it to generate a transmission signal. The transmission signal sent from the unit 211b is reproduced and supplied to the display control unit 212 via the transmission cable CB22.
[0162]
In this way, the first light emitting device EL1 and the first light receiving device PD1 are provided without contact, and the second light emitting device EL2 and the second light receiving device PD2 are also provided without contact. Even if the rotating shaft 203 and the sub reel SR3 rotate integrally by receiving the driving force of the stepping motor SM3, the display control unit 212 receives the power and transmission signal supplied from the effect control circuit 211 fixed to the support plate 202 side. It is possible to supply to.
[0163]
In addition, the first light emitting device EL1 and the first light receiving device PD1 are provided at the position of the above-described axial center, and the first light emitting device EL1 emits light with high directivity. High power light is transmitted only between the device EL1 and the first light receiving device PD1.
[0164]
Further, since the light is emitted from the second light emitting device EL2 at a wide angle, the second light emitting device PD2 can receive the light even when the second light receiving device PD2 is attached at the above-described biased position. It is possible to appropriately transmit a transmission signal between the device EL2 and the second light receiving device PD2.
[0165]
At one end of the support plate 202, an angle detection sensor DT is provided close to the rotation shaft 203, and the rotation shaft 203 is rotated by the detection pattern EC and the angle detection sensor DT formed on the peripheral surface of the rotation shaft 203. An optical rotary encoder for detecting a corner is configured.
[0166]
Then, a transmission signal generation unit 211b provided in an effect control circuit 211 described later sends the image signals S1 to Sm to the light emitting units RL1, RL1, in synchronization with the pulse waveform angle detection signal TM output from the angle detection sensor DT. By performing a process for supplying to GL1 and BL1, an electric decoration display is performed, and further, a control unit 211a and a drive circuit 211f provided in the effect control circuit 211 are provided with a stepping motor SM3 based on the angle detection signal TM. Feedback control of the rotation speed.
[0167]
Next, with reference to FIG. 16, the structure of the effect control circuit 211 formed on the effect circuit board 600 and the display control unit 212 provided on the sub reel SR3 side will be described.
[0168]
In FIG. 16, the effect control circuit 211 stores a control unit 211a and a transmission signal generation unit 211b formed by a microprocessor (MPU) or the like, and image data for effect display (hereinafter referred to as “image data for effect”). An image data storage unit 211c formed of a semiconductor memory (ROM), an oscillator 211d that outputs a synchronization signal CLK, a power supply device 211e, and a drive circuit 211f that drives the stepping motor SM3 are provided.
[0169]
In the image data storage unit 211c, a plurality of sets of effect image data are stored in advance by address management.
[0170]
Further, as schematically shown in FIG. 17A, each effect image data is composed of one frame or a plurality of frames corresponding to the effect image of a still image or a moving image. It is stored as bitmap format data capable of displaying the three primary colors red (R), green (G), and blue (B) corresponding to the pixel arrangement of m rows and n columns.
[0171]
The red (R) bitmap data of m rows and n columns in each frame is the light emitting unit RL1, the green (G) bitmap data of m rows and n columns is the light emitting unit GL1, and the blue (B) of m rows and n columns. Bitmap data is associated with the light emitting unit BL1, and as shown in FIG. 17B, m rows of each frame are associated with m rows in each horizontal line of the display range, N columns of each frame are associated with n horizontal lines in the display range.
[0172]
In the present embodiment, the number n of columns in each frame and the number n of horizontal lines are determined to be at least 24 or more.
[0173]
The power supply device 211e supplies power to the first light emitting device EL1 to emit light, thereby supplying power to the first light receiving device PD1 and driving the stepping motor SM3 to the drive circuit 211f. Supply power.
[0174]
The control unit 211a controls the transmission signal generation unit 211b and the drive circuit 211f based on the control data CNT supplied from the sub control board 300 according to the instruction of the main control board 700.
[0175]
Here, the control data CNT includes motor control data MCNT for controlling the start and stop of the stepping motor SM3 and the rotation speed, and display control data VCNT for causing the light emitting units RL1, GL1, and BL1 to perform presentation display. include.
[0176]
Then, the drive circuit 211f drives the stepping motor SM3 in accordance with the motor control data MCNT, and controls starting, stopping, and rotation speed. Further, the control unit 211a rotates the stepping motor SM3 at a rotation speed instructed from the sub-control board 300 side while performing feedback control based on the angle detection signal TM from the angle detection sensor DT.
[0177]
The transmission signal generator 211b reads out the effect image data stored in the image data storage unit 211c in accordance with the display control data VCNT, and further performs PWM modulation (pulse width modulation) on the read effect image data. The series of image signals S1 to Sm are supplied to the second light emitting device EL2, and an image display based on the image signals S1 to Sm is performed in the display control unit 212 described later.
[0178]
Further, the transmission signal generator 211b detects the rotation angle of the sub reel SR3 by comparing the angle detection signal TM from the angle detection sensor DT with the clock signal CLK having a predetermined frequency output from the oscillator 211d. The image signals S1 to Sm are supplied to the second light emitting device EL2 in synchronization with the rotation angle.
[0179]
Further, the display control data VCNT includes a color designation item COL for designating a color to be displayed among the three primary colors of red (R), green (G), and blue (B) and bits of m rows and n columns per frame. Designate display pixel designation item PX for designating which pixel is to be displayed based on bitmap data corresponding to which pixel of the image data for rendering composed of map data, and a frame to be applied to the rendering display. The data structure has a display frame designation item FRM.
[0180]
More specifically, the display control data VCNT includes data in a description format represented by Dmod {COL = color; PX = pixels in m rows and n columns; FRM = frames}, and is illustrated in FIG. As listed, color designation, pixel designation, and frame designation according to each item can be set in detail.
[0181]
For example, if red (R) is described in the color designation item COL, only red is displayed, if red (R) and green (G) are described, only red and green are displayed, and red (R) and green are displayed. When (G) and blue (B) are described, the three primary color displays of red, green and blue are designated.
[0182]
If one or more ranges for effect display are described in the display pixel designation item PX, effect display is performed only with bitmap data corresponding to those ranges, and bits outside these ranges are displayed. All map data is designated to be processed as black background data.
[0183]
In addition, when the display frame designation item FRM describes a range of one or more frames for effect display, the effect display is performed only with bitmap data corresponding to the frame range, and those frames are displayed. Any bitmap data outside the range is specified to be processed as black background data.
[0184]
Note that when black data is PWM-modulated, the duty of the image signal becomes approximately 0%, and even if the image signal having the duty of 0% is supplied to the light emitting diodes of the light emitting units RL1, GL1, and BL1, it cannot be turned on. It has become.
[0185]
Then, the transmission signal generation unit 211b accesses the image data storage unit 211c in memory in synchronization with the angle detection signal TM and the synchronization signal CLK from the oscillator 211d, so that m light emitting units RL1, GL1, and BL1 are provided. When the image data D1 to Dm for controlling the lighting of each light emitting diode provided for each column is read out one column at a time and the image data D1 to Dm for each column is PWM-modulated in units of pixels, the color designation item COL described above is used. PWM modulation is performed according to the display pixel designation item PX and the display frame designation item FRM.
[0186]
That is, as shown in FIG. 14A, the transmission signal generator 211b has both the normal direction passing through the rotation axis 203 and orthogonal to the observation plane, and the angle α formed by the light emitting units RL1 and BL1. When it is detected by the angle detection signal TM that the angle is 60 °, it is determined that the light emitting unit RL1 has reached the predetermined reference position Y1, and as shown in FIG. The red image data D1 to Dm in the first column to be displayed on the horizontal line are read from the image data storage unit 211c, and the image data D1 to Dm are PWM-modulated to generate time-series image signals S1 to Sm. Then, the image signals S1 to Sm are sent to the second light emitting device EL2 side together with the identification signal CS for causing the light emitting unit RL1 to display an image.
[0187]
The transmission signal generator 211b also causes the red image data D1 for the second and subsequent columns to be displayed after the second horizontal line every time the light emitting unit RL1 rotates by an angle of 120 ° / n from the reference position Y1. To Dm are sequentially read from the image data storage unit 211c, and each of the image data D1 to Dm is PWM-modulated to generate time-series image signals S1 to Sm and display the image by the light emitting unit RL1. The image signals S1 to Sm are sent to the second light emitting device EL2 side together with the identification signal CS.
[0188]
Thus, as shown in FIG. 14 (a), the transmission signal generator 211b receives 1 from the image data storage unit 211c while the red light emitting unit RL1 rotates 120 ° from the reference position Y1 to the end of the display range. The red image data for the frame is read for each horizontal line, and the time series image signals S1 to Sm are generated and sent to the second light emitting device EL2, whereby the display controller 212 described later emits red light. A red image is displayed on the unit RL1.
[0189]
Further, as shown in FIG. 14B, the transmission signal generation unit 211b is similar to the case of the red light emitting unit RL1 even while the green light emitting unit GL1 rotates 120 ° from the reference position Y1 to the end of the display range. In addition, green image data for one frame is read from the image data storage unit 211c for each horizontal line, time-series image signals S1 to Sm are generated, and the second signal is used together with an identification signal CS for identifying the light emitting unit GL1. By sending it to the light emitting device EL2, the display controller 212 described later displays a green image by the green light emitting unit GL1.
[0190]
Furthermore, as shown in FIG. 14 (c), the transmission signal generator 211b is configured to emit red and green light emitting units RL1 while the blue light emitting unit BL1 rotates 120 ° from the reference position Y1 to the end of the display range. As in the case of GL1, the blue image data for one frame is read from the image data storage unit 211c for each horizontal line, the time series image signals S1 to Sm are generated, and the light emitting unit GL1 is identified. By sending it to the second light emitting device EL2 together with the identification signal CS, the display controller 212 described later causes the blue light emitting unit BL1 to display a green image.
[0191]
As described above, the transmission signal generation unit 211b performs the effect display by the color image by displaying the red, green, and blue frame images while the light emitting units RL1, GL1, and BL1 face the display range. It comes to let you.
[0192]
However, the transmission signal generation unit 211b performs PWM modulation according to each level on the image data D1 to Dm related to the color specified by the color specifying item COL, and the image data D1 related to the color not specified. About -Dm, PWM modulation is performed as a black level.
[0193]
In addition, among the image data D1 to Dm, data corresponding to the pixels specified by the display pixel specifying item PX is subjected to PWM modulation according to each level, and data corresponding to the pixels not specified. Is subjected to PWM modulation as a black level.
[0194]
Further, the image data D1 to Dm related to the frame specified by the display frame specifying item FRM is subjected to PWM modulation according to the respective levels, and the image data D1 to Dm related to the unspecified frame is black. PWM modulation is applied as a level.
[0195]
Furthermore, during the period τ1 in which the image signals S1 to Sm are output corresponding to the image data D1 to Dm for one column, the light emitting units RL1, GL1, and BL1 shown in FIGS. The time T1 required to move from the reference position Y1 to the final position of the display range, in other words, the time T1 required to rotate 120 ° from the reference angle (0 °) is divided by n horizontal lines ( T1 / n).
[0196]
Further, the individual generation periods Δτ1 of the image signals S1 to Sm are determined by a time (τ1 / m) obtained by dividing the period τ1 by the number m of light emitting diodes provided in the light emitting units RL1, GL1, and BL1, respectively. .
[0197]
In FIG. 16 again, the display control unit 212 provided on the sub reel SR3 side includes a waveform shaping circuit 212a, a power supply circuit 212b, a scanning control circuit 212c, and switching circuits MW11, MW12, and MW13. .
[0198]
Here, the power supply circuit 212b is provided in each light emitting unit by charging the power output from the first light receiving device PD1 to a charging circuit (not shown) and further regulating the charging voltage of the charging circuit. The power supply voltage Vdd for driving the light emitting diode and the power supply voltage Vcc necessary for the operation of the entire display control unit 212 are generated and output.
[0199]
The waveform shaping circuit 212a shapes the identification signal CS and the image signals S1 to Sm output from the second light receiving device PD2, and supplies the waveform shaped identification signal CS and the image signals S1 to Sm to the scanning control circuit 212c. .
[0200]
The scanning control circuit 212c is formed of a circuit including a microprocessor (MPU) having an arithmetic function and a control function, and converts the image signals S1 to Sm supplied from the waveform shaping circuit 212a to the switching circuits MW11, MW12, Transfer to MW13 side. Further, the light emitting unit designated by the identification signal CS is identified, and an enable signal ENij is output to operate the designated light emitting unit. Furthermore, the scanning signal SELm synchronized with each generation period Δτ1 (= τ1 / m) of the image signals S1 to Sm is output to the switching circuits MW11, MW12, and MW13.
[0201]
Note that the switching circuits MW11, MW12, and MW13 are set in an operable state by an enable signal ENij, and sequentially output the image signals S1 to Sm to m output terminals in synchronization with the scanning signal SELm. It is formed by an m output type demultiplexer.
[0202]
Here, m light emitting diodes LDR11 to LDR1m, LDG11 to LDG1m, LDB11 to LDB1m, and m output terminals respectively provided to the switching circuits MW11, MW12, and MW13, are provided in the light emitting units RL1, GL1, and BL1. Are connected in association with each other.
[0203]
Therefore, for example, when the switching circuit MW11 is specified by the identification signal CS, the scanning control circuit 212c operates only the switching circuit MW11 by outputting the enable signal ENij (i = 1, j = 1), and further scans. In synchronization with the signal SELm, the image signals S1 to Sm are supplied in association with the light emitting diodes LDR11 to LDR1m, thereby displaying one horizontal line corresponding to the image signals S1 to Sm. Similarly, when displaying other horizontal lines, the image signals S1 to Sm are supplied only to the light emitting diodes connected to the switching circuit designated by the identification signal CS, and correspond to the image signals S1 to Sm. One horizontal line is displayed.
[0204]
In addition, as described above, the light emitting units RL1, GL1, and BL1 are supplied with the image signals S1 to Sm every time they rotate and move one horizontal line from the reference position Y1, so that all the horizontal lines in the display range. It is possible to display effect images corresponding to the above.
[0205]
As described above, the sub reel unit SU3 rotates the sub reel SR3 to display not only the symbols drawn on the outer peripheral surface but also the light emitting units RL1, GL1, and BL1 provided on the sub reel SR3 with a predetermined effect. An afterimage phenomenon is caused by lighting and blinking based on the image data for use, and an effect display appealing to the player's vision is performed.
[0206]
For example, as shown in FIG. 19A, a color image can be displayed in an effect by turning on and blinking all of the light emitting units RL1, GL1, and BL1. Further, as illustrated in FIG. 5B, only a blue light emitting unit BL1 is turned on and blinked to display a monochrome image, or as illustrated in FIG. 5C, a green light emitting unit. By lighting and blinking GL1 and blue light emitting unit BL1, an image in which two colors are mixed can be displayed.
[0207]
Although the sub reel unit SU3 has been described as a representative, the sub reels SR1, SR2 of the remaining sub reel units SU1, SU2 are also provided with light emitting units RL1, GL1, BL1, respectively, and the light emitting units of these sub reels SR1, SR2 are provided. RL1, GL1, and BL1 are also controlled by a circuit similar to the effect control circuit 211 and the display control unit 212 shown in FIG. 16, and as shown in FIGS. 19A, 19B, and 19C. An effect display can be performed.
[0208]
These three sub reels SR1, SR2, SR3 are individually controlled to rotate, and the light emitting units RL1, GL1, BL1 provided on the sub reels SR1, SR2, SR3 are individually controlled to be lit and blinking. As a result, it is possible to perform a very diverse production display.
[0209]
As described above, according to the slot machine 10 of the present embodiment, by providing the small main reel device 100, the area for effect display can be relatively enlarged, and further expanded. By providing a liquid crystal display panel LCD and a large-sized sub-reel device 200 that has a light-emitting unit as a light-emitting means on a sub-reel as a rotating body in the area of the effect panel 14a, a more enjoyable game It is possible to perform an effect display to receive.
[0210]
For example, as illustrated in FIG. 19D, when the image IMG0 is displayed on the liquid crystal display panel LCD, and the light emitting units RL1, GL1, and BL1 perform illumination display while rotating the sub reels SR1, SR2, and SR3, The effect display can be performed by combining the image IMGS by the electrical display and the image IMG0 described above.
[0211]
Furthermore, even though the main reel device 100 is downsized, the symbols drawn on the outer peripheral surfaces of the main reels MR1, MR2, and MR3 are sized so that they can be easily seen. Can be presented to the player, and the original functions of the main reel device can be fully exhibited.
[0212]
For this reason, the slot machine 10 includes the liquid crystal display panel LCD as the first and second effect display devices and the sub reel device 200, so that the main reel device 100 plays a game while performing more effective effect display. The result can be appropriately presented to the player.
[0213]
[Modification]
Next, a modified example of the sub reel device 200 will be described with reference to FIGS.
[0214]
20 to 22, the same or corresponding parts as those in FIGS. 12 to 16 are denoted by the same reference numerals. In addition, this modification will be described with reference to FIGS. 1 to 19 as appropriate.
[0215]
The sub-reel device 200 according to this modification basically has the same external structure as that shown in FIG. 12, and is composed of three sub-reel units SU1, SU2, SU3. Further, the connection structure between each of the sub reels SR1, SR2, SR3 and the stepping motors SM1, SM2, SM3 is also realized by the same structure as shown in FIG. Further, the outer peripheral surfaces of the respective sub reels SR1, SR2, SR3 are directed to the opening ANWD2 formed in the casing CASE of the liquid crystal display panel LCD, as shown in FIG.
[0216]
However, in each of the sub reels SR1, SR2 and SR3 provided in the sub reel device 200, as schematically shown in FIG. 20, three layers of ring portions having different radii around the base portion 203 are concentrically formed. Furthermore, red, green, and blue light emitting units are provided for each of the ring portions.
[0217]
Here, the structure of the sub reel unit SU3 out of the three sub reel units SU1, SU2, SU3 will be described as a representative.
[0218]
In FIG. 20, the sub reel SR3 of the sub reel unit SU3 includes first ring portions 206a and 207a, second ring portions 206b and 207b, and a third ring portion around the rotation shaft 203 of the stepping motor SM3. 206c and 207c are provided concentrically.
[0219]
In the first ring portions 206a and 207a having the largest diameter, the red (R) light emitting unit RL1, the green (G) light emitting unit GL1, and the blue (B) light emitting unit are provided, as shown in FIG. BL1 is provided at an angle of 120 ° in the circumferential direction.
[0220]
Similarly, the red (R) light emitting unit RL2, the green (G) light emitting unit GL2, and the blue (B) light emitting unit BL2 are also 120 ° in the circumferential direction in the second ring portions 206b and 207b having the medium diameter. It is provided at an angle.
[0221]
Similarly, the red (R) light emitting unit RL3, the green (G) light emitting unit GL3, and the blue (B) light emitting unit BL3 are also provided in the circumferential direction in the third ring portions 206c and 207c having the smallest diameter. It is provided at an angle of °.
[0222]
The light emitting units RL1, RL2, RL3 have m red (R) high-intensity light emitting diodes arranged in a line at a predetermined pitch interval along the width direction of the reel tape STP3, and the light emitting units GL1 , GL2 and GL3 have m green (G) high-intensity light-emitting diodes arranged in a row, and m light-emitting units BL1, BL2 and BL3 are also arranged in a row. Each has a blue (B) high-intensity light emitting diode.
[0223]
Further, the light emitting units RL1 and RL2 and the light emitting units RL2 and RL3 are set at a predetermined angle θ about the rotation axis 203, respectively, so that the light emitting units RL1, RL2, RL3 It is prevented in advance from overlapping toward the side (in other words, the multiple effect display area WD2).
[0224]
Similarly, the light-emitting units GL1, GL2, and GL3 are set to a predetermined angle θ in order to prevent the light-emitting units GL1, GL2, and GL3 from overlapping each other toward the observation surface.
[0225]
Furthermore, the light-emitting units BL1, BL2, and BL3 are similarly set to a predetermined angle θ in order to prevent the light-emitting units BL1, BL2, and BL3 from overlapping each other toward the observation surface.
[0226]
A reel tape STP3 similar to that shown in FIG. 13 is fitted and fixed to the outer periphery of the first ring portions 206a and 207a.
[0227]
However, in the reel tape STP3 of this modified example, each of the symbols shown in FIG. 13 is translucent, and the area where no symbol is drawn is transparent or translucent. As a result, the reel tape STP3 Light emitted from the high-intensity light emitting diodes of the light emitting units RL1, GL1, BL1 and RL2, GL2, BL2 and RL3, GL3, BL3 located on the back surface side passes through the reel tape STP3 and is emitted to the observation surface side. To do.
[0228]
The rotation shaft 203 is provided with a detection pattern EC for causing the angle detection sensor DT to detect the rotation angles of the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, and RL3, GL3, BL3. That is, an optical rotary encoder is configured by the angle detection sensor DT and the detection pattern EC.
[0229]
Although details will be described later, the transmission signal generation unit 211b shown in FIG. 22 is based on the angle detection signal TM output from the angle detection sensor DT, and the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, and RL3. , GL3, BL3 are detected, and each light emitting unit is in contact with the display range on the observation surface (in other words, the second display window WD2) while the light emitting unit has a predetermined angle. By displaying an image based on the image signals S1 to Sm, an effect display by electrical display is performed.
[0230]
Next, referring to FIG. 22, in order to control the sub reel device 200 of this modification, an effect control circuit 211 provided on the effect circuit board 600 shown in FIG. 6 and the sub reel device 200 side are provided. The configuration of the display control unit 212 is described.
[0231]
For convenience of explanation, the effect control circuit 211 and the display control unit 212 related to the sub reel unit SU3 among the sub reel units SU1, SU2, and SU3 will be described as a representative.
[0232]
In FIG. 22, the production control circuit 211 includes a control unit 211a that inputs control data CNT supplied from the sub control board 300 according to an instruction from the main control board 700, a transmission signal generation unit 211b, an image data storage unit 211c, An oscillator 211d, a power supply device 211e, and a drive circuit 211f are provided.
[0233]
In the image data storage unit 211c, a large number of effect image data are stored under address management for the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, RL3, GL3, and BL3, respectively. As shown in FIG. 17A, the image data is stored as bitmap format data capable of displaying so-called m rows and n columns of three primary colors composed of one frame or many frames corresponding to still images and moving images. Has been.
[0234]
The control data CNT includes motor control data MCNT for controlling the start and stop of the stepping motor SM3 and the rotation speed, and effects on the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, RL3, GL3, BL3. Display control data VCNT for causing display is included.
[0235]
Then, the drive circuit 211f drives the stepping motor SM3 in accordance with the motor control data MCNT, and controls starting, stopping, and rotation speed. Further, the control unit 211a rotates the stepping motor SM3 at a rotation speed instructed from the sub-control board 300 side while performing feedback control based on the angle detection signal TM output from the angle detection sensor DT.
[0236]
The transmission signal generation unit 211b reads out the effect image data stored in the image data storage unit 211c in accordance with the instruction of the display control data VCNT, and performs PWM modulation on the read image data D1 to Dm, thereby emitting light. Time-series image signals S1 to Sm for lighting control of the units RL1, GL1, BL1, RL2, GL2, BL2, and RL3, GL3, BL3 are generated.
[0237]
However, in this modification, the data structure of the display control data VCNT and the configuration of the transmission signal generation unit 211b that performs the above-described PWM modulation are different from those shown in FIG. 18 and FIG. It has the characteristics described.
[0238]
In other words, the display control data VCNT of the present modification example includes the first effect designation item MODE1 for finely setting the display mode by the light emitting units RL1, GL1, and BL1 located in the first hierarchy, and the position in the second hierarchy. The second effect designation item MODE2 for finely setting the display form by the light emitting units RL2, GL2 and BL2 and the finely setting the display form by the light emitting units RL3, GL3 and BL3 located in the third hierarchy The third production designation item MODE3 is provided.
[0239]
Further, each of the effect designation items MODE1 to MODE3 includes address data ADR indicating the storage area of the image data storage unit 211c in which effect image data is stored, and red (R), green (G), and blue (B). Bitmap data corresponding to which pixel of the image data for rendering composed of color designation item COL for designating a color to be displayed among the three primary colors and bitmap data of m rows and n columns per frame The data configuration is such that each item of display pixel designation item PX for designating whether or not to effect display and display frame designation item FRM for designating a frame to be applied to the effect display can be set. .
[0240]
More specifically, the display control data VCNT includes Dmod {MODE1 [ON / OFF; ADR = address; COL = color; PX = m rows and n columns of pixels; FRM = frames], MODE2 [ON / OFF; ADR. = Address; COL = Color; PX = Pixel in m rows and n columns; FRM = Frame], MODE3 [ON / OFF; ADR = Address; COL = Color; PX = Pixels in m rows and n columns; FRM = Frame]} It consists of data in the description format.
[0241]
Note that data ON / OFF in the effect designation items MODE1 to MODE3 is flag data for setting a light emitting unit that performs effect display and a light emitting unit that does not perform effect display.
[0242]
According to the display control data VCNT having such a data structure, the address data ADR can be set for each of the effect designation items MODE1 to MODE3. Therefore, effect image data for effect display by the light emitting units RL1, GL1, and BL1. By separately setting effect image data for effect display on the light emitting units RL2, GL2, and BL2, and effect image data for effect display on the light emitting units RL3, GL3, and BL3, an image data storage unit Various effect displays can be performed by combining a large number of effect image data stored in 211c.
[0243]
Further, in each of the effect designation items MODE1 to MODE3, it is possible not only to individually set the address ADR but also to individually set the color designation item COL, the display pixel designation item PX, and the display frame designation item FRM. Therefore, it is possible to select an aspect of the effect display from an extremely large number of combinations.
[0244]
In addition, since the display pixel designation item PX and the display frame designation item FRM can be individually set for each of the production designation items MODE1 to MODE3, the production display can be performed from among a great number of combinations by these items PX and FRM. A mode can be selected.
[0245]
As an example, the display control data VCNT is Dmod {MODE1 [ON; ADR = 100-200; COL = R; PX = all; FRM = all], MODE2 [ON; ADR = 100-200; COL = G; PX = all; FRM = all], MODE3 [ON; ADR = 100-200; COL = B; PX = all; FRM = all]}, the light emitting units of all the first to third layers are used. In addition to performing effect display, effect display based on effect image data stored in the storage area from addresses “100” to “200” is designated, and in the first hierarchy, a red (R) light emitting unit is designated. RL1, effect display is performed by the green (G) light emitting unit GL2 in the second layer, and the blue (B) light emitting unit BL3 in the third layer. Address "100" to "200" to the effect that the effect display by applying the effect for image data of all the pixels and the frame stored in the storage area is designated.
[0246]
As another example, the display control data VCNT is Dmod {MODE1 [ON; ADR = 100-200; COL = R + G + B; PX = all; FRM = all], MODE2 [OFF], MODE3 [OFF]}. In this case, since only the effect designation item MODE1 is set to “ON” and the remaining effect designation items MODE2 and MODE3 are set to “OFF”, the effect is produced only by the light emitting units RL1, GL1, and BL1 located in the first hierarchy. Display is performed. Furthermore, since the color designation item COL in the first effect designation item MODE1 is COL = R + G + B, red (R), green (G), and blue (B) are emitted by the light emitting units RL1, GL1, and BL1. Three primary colors are displayed.
[0247]
As described above, when the light emitting unit to be displayed and the light emitting unit not to be displayed are set by the flag data ON / OFF, as illustrated in FIGS. 19A, 19B, and 19C, among the three layers, It is possible to perform effect display in any one of the layers.
[0248]
In addition, when the flag data ON / OFF of the effect designation items MODE1 to MODE3 is appropriately switched during the effect display, the light emitting units at each level located in the depth direction when viewed from the observation surface side are turned off or displayed. Thus, for example, it is possible to display an effect image that jumps forward from the back side or an effect image that retreats from the front side to the back side.
[0249]
In addition, when each item of the effect designation data Dmod is appropriately set, a stereoscopic effect image can be displayed by superimposing a plurality of images displayed in a plurality of layers.
[0250]
Then, the transmission signal generator 211b decodes (decodes) each item in the effect designation data Dmod, and performs PWM modulation on the image data D1 to Dm read from the image data storage unit 211c according to the designated item content. Then, processing for generating and transmitting the image signals S1 to Sm is performed.
[0251]
Next, a method for reading the image data D1 to Dm in the transmission signal generation unit 211b will be described.
[0252]
When the transmission signal generation unit 211b reads out the image data for production from the image data storage unit 211c, among the three production designation items MODE1 to MODE3, the production designation item whose flag data ON / OFF is set to “ON” is selected. The image data for effect to be read is specified based on the address data ADR included in the selected effect item. Further, the light-emitting unit related to the effect designation item for which the flag data ON / OFF is set to “ON”, that is, the light-emitting unit to be displayed for the effect is specified.
[0253]
Then, the image data storage unit 211c is memory-accessed based on the above-described conditions of flag data ON / OFF and address data ADR, and is synchronized with the angle detection signal TM from the angle detection sensor DT and the synchronization signal CLK from the oscillator 20. Then, the memory is accessed, and image data D1 to Dm to be used for effect display are read out.
[0254]
Here, when the flag data ON / OFF in the effect designation item MODE1 is “ON”, the transmission signal generation unit 211b displays the effect by the light emitting units RL1, GL1, and BL1 located in the first hierarchy. It is determined that
[0255]
And as shown to Fig.21 (a), when the transmission signal generation part 211b detects based on the angle detection signal TM that the light emission unit RL1 reached | attained the position corresponded to the reference position Y1, The red image data D1 to Dm to be displayed on the first horizontal line of the display range is read out for one column from the image data storage unit 211c, and the image data D1 to Dm is PWM-modulated to thereby generate a time-series image signal. S1 to Sm are generated, and the image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the light emitting unit RL1.
[0256]
Further, when the light emitting unit RL1 sequentially moves by one horizontal line from the reference position Y1 and moves to the last horizontal line (nth horizontal line) in the display range, the transmission signal generation unit 211b Each time the light emitting unit RL1 moves to a position corresponding to each horizontal line, red image data D1 to Dm for displaying each horizontal line is read from the image data storage unit 211c for one column, and the image data D1 to Dm is read. Are modulated, and time-series image signals S1 to Sm are generated, and the image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the light emitting unit RL1.
[0257]
In addition, the transmission signal generation unit 211b performs the same processing for the light emitting units GL1 and BL1 as for the above-described light emitting unit RL1.
[0258]
Next, when the flag data ON / OFF in the effect designation item MODE2 is “ON”, as shown in FIG. 21B, the transmission signal generation unit 211b is located in the second hierarchy. It is determined that the effect display by the light emitting units RL2, GL2, and BL2 should be performed.
[0259]
When the transmission signal generation unit 211b detects that the light emitting unit RL2 has reached the position corresponding to the reference position Y2 based on the angle detection signal TM, the transmission signal generation unit 211b displays the first horizontal line in the display range in one frame. The red image data D1 to Dm to be processed are read out for one column from the image data storage unit 211c, and the image data D1 to Dm are PWM-modulated to generate time-series image signals S1 to Sm, and the light emitting unit RL2 The image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the image.
[0260]
Further, when the light emitting unit RL2 sequentially moves by one horizontal line from the reference position Y2 and moves to the last horizontal line of the display range, the transmission signal generation unit 211b corresponds to each horizontal line. Each time the light emitting unit RL2 moves to a position, red image data D1 to Dm for displaying each horizontal line is read out from the image data storage unit 211c for one column, and the image data D1 to Dm are PWM-modulated. Then, time-series image signals S1 to Sm are generated, and the image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the light emitting unit RL2.
[0261]
In addition, the transmission signal generation unit 211b performs the same processing as that of the above-described light emitting unit RL2 for the light emitting units GL2 and BL2.
[0262]
Next, when the flag data ON / OFF in the production designation item MODE3 is “ON”, as shown in FIG. 21C, the transmission signal generation unit 211b is located in the third hierarchy. It is determined that the effect display by the light emitting units RL3, GL3, BL3 should be performed.
[0263]
When the transmission signal generation unit 211b detects that the light emitting unit RL3 has reached the position corresponding to the reference position Y3 based on the angle detection signal TM, the transmission signal generation unit 211b displays the first horizontal line in the display range in one frame. The red image data D1 to Dm to be processed are read for one column from the image data storage unit 211c, and the image data D1 to Dm are PWM-modulated to generate time-series image signals S1 to Sm, and the light emitting unit RL3 The image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the image.
[0264]
In addition, when the light emitting unit RL3 sequentially moves by one horizontal line from the reference position Y2 and moves to the last horizontal line in the display range, the transmission signal generation unit 211b corresponds to each horizontal line. Each time the light emitting unit RL3 moves to a position, red image data D1 to Dm for displaying each horizontal line is read from the image data storage unit 211c for one column, and the image data D1 to Dm are PWM-modulated. Then, time-series image signals S1 to Sm are generated, and the image signals S1 to Sm are sent to the display control unit 212 side together with the identification signal CS for identifying the light emitting unit RL3.
[0265]
In addition, the transmission signal generation unit 211b performs the same processing for the light emitting units GL3 and BL3 as in the case of the above-described light emitting unit RL3.
[0266]
As described above, the transmission signal generation unit 211b sends the image signals S1 to Sm for effect display to the display control unit 212 side in the hierarchy specified by the effect specification items MODE1 to MODE3, and the display control unit 212 side. By performing so-called dot-sequential scanning, effect display in each layer is realized.
[0267]
For convenience of explanation, the case where the effect display is performed by all the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, and RL3, GL3, BL3 has been described, but the transmission signal generation unit 211b is as described above. Based on the color designation item COL, the display pixel designation item PX, and the display frame designation item FRM, by generating the image signals S1 to Sm, various aspects of the effect display are changed.
[0268]
Next, the configuration of the display control unit 212 provided on the sub reel SR3 side will be described.
[0269]
In addition to the waveform shaping circuit 212a, the power supply circuit 212b, and the scanning control circuit 212c, the display control unit 212 includes switching circuits MW11, MW12, and MW13 connected to the light emitting units RL1, GL1, and BL1 located in the first layer. Switching circuits MW21, MW22, MW23 connected to the light emitting units RL2, GL2, BL2 located in the second hierarchy, and switching circuits MW31, MW32 connected to the light emitting units RL3, GL3, BL3 located in the third hierarchy , MW33.
[0270]
Then, the scan control circuit 212c transfers the image signals S1 to Sm supplied from the waveform shaping circuit 212a to the switching circuits MW11 to MW33. Further, the light emitting unit designated by the identification signal CS is identified, and an enable signal ENij is output to operate the designated light emitting unit. Furthermore, the scanning signal SELm synchronized with the image signals S1 to Sm is output to the switching circuits MW11 to MW33.
[0271]
For example, when the switching circuit MW11 is designated by the identification signal CS, the scanning control circuit 212c operates only the switching circuit MW11 by outputting the enable signal ENij (i = 1, j = 1), and further the image signal By switching each of S1 to Sm according to the scanning signal SELm, the image signals S1 to Sm are supplied corresponding to the light emitting diodes LDR11 to LDR1m.
[0272]
The suffix i, j attached to the enable signal ENij described above is used to designate the display units RL1, GL1, BL1, RL2, GL2, BL2, RL3, GL3, BL3. That is, when i = 1, display units RL1, GL1, and BL1 are designated, when i = 2, display units RL2, GL2, and BL2 are designated, and when i = 3, display units RL3, GL3, and BL3 are designated. Further, when j = 1, the display units RL1, RL2, and RL3 are displayed. When j = 2, the display units GL1, GL2, and GL3 are displayed. When j = 3, the display units BL1, BL2, and BL3 are displayed. Is specified. Therefore, one of nine light emitting units can be designated by the suffixes i and j.
[0273]
The switching circuits MW11 to MW33 are formed by a 1-input m-output type demultiplexer, and the image signals S1 to Sm transferred in series from the scanning control circuit 212c are synchronized with the scanning signal SELm, m Output sequentially to the output terminals. Further, each of the switching circuits MW11 to MW33 is set to an operable state in accordance with the enable signal ENij supplied from the scanning control circuit 212c.
[0274]
Then, based on the effect image data, various effect displays as exemplified in FIGS. 23 to 26 are performed by controlling the driving of the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, and RL3, GL3, BL3. It is possible to do.
[0275]
The sub reel unit SU3 has been described as a representative, but the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, and RL3, GL3 are also provided on the sub reels SR1, SR2 provided in the remaining sub reel units SU1, SU2. , BL3, and the light emitting units RL1, GL1, BL1 and RL2, GL2, BL2, and RL3, GL3, and BL3 of the sub reels SR1 and SR2 are also shown in FIG. By performing control using a circuit similar to 212, it is possible to display various effects as illustrated in FIGS.
[0276]
These three sub reels SR1, SR2, SR3 are individually controlled in rotation, and further, light emitting units RL1, GL1, BL1, RL2, GL2, BL2, BL2, RL3, GL3 provided on each of the sub reels SR1, SR2, SR3. , BL3 are also individually controlled to be turned on and blinking, thereby making it possible to display extremely various effects.
[0277]
In particular, when the rotation speed of each of the sub reels SR1, SR2, SR3 is adjusted, the illumination display is performed by the light emitting units RL1, GL1, BL1, RL2, GL2, BL2, RL3, GL3, BL3 provided respectively. By causing the afterimage phenomenon to occur in the player, for example, a three-dimensional still image or moving image, or various moving images in which the image moves in the depth direction can be expressed.
[0278]
As described above, according to the sub-reel device 200 of the present modification, it is possible to display an effect image having a depth, and to perform an effect display for further enjoying the game.
[0279]
Further, as illustrated in FIG. 19D, the image IMG0 is displayed on the liquid crystal display panel LCD, and the light emitting units RL1, GL1, BL1 and RL2, GL2 having the multilayer structure are rotated while rotating the sub reels SR1, SR2, SR3. , BL2 and RL3, GL3, BL3 can be displayed in combination with the image IMGS by the display and the above-mentioned image IMG0.
[0280]
Note that the sub-reel device 200 according to the present modification is configured to display effects in three layers in the depth direction, but may be configured to display effects in three or more layers. That is, it is good also as a structure which performs the effect display of three or more layers by arrange | positioning more light-emitting units in the position which differs in the depth direction on each sub reel SR1, SR2, SR3.
[0281]
In the present embodiment described above (including the modification), the small main reel device 100 is disposed above the large sub reel device 200 as shown in FIG. This does not mean that the main reel device 100 and the sub reel device 200 must be arranged in this positional relationship within the range of the front door 11.
[0282]
For example, the small main reel device 100 may be disposed in a region between the large sub reel device 200 and the operation unit 16 shown in FIG.
[0283]
Further, when the small main reel device 100 is disposed in the region between the large sub reel device 200 and the operation unit 16, another effect display device such as a liquid crystal display is disposed in the region of the effect panel 13f. Accordingly, a more effective effect display may be performed by the effect display device, the sub reel device 200, and the liquid crystal display panel LCD.
[0284]
In the present embodiment (including the modification), the effect panel 14a is provided with the transmissive liquid crystal display panel LCD, but may be a reflective liquid crystal display panel.
[0285]
Further, instead of the liquid crystal display panel LCD, an organic EL or other transmissive electroluminescence panel or a self-luminous electroluminescence panel may be provided.
[0286]
【The invention's effect】
As described above, according to the rotary type gaming machine of the present invention, the main reel device including the main reel that is smaller than the display range of the effect display device is disposed on the panel unit facing the player, As a result, the effect display area in the panel portion is relatively enlarged, and the effect display device is arranged in the enlarged area, so that effective effect display can be realized.
[0287]
In addition, an electroluminescence panel as a first display device, and a second effect device having a rotating body provided with one or more light-emitting means on the back side of a transparent window formed in the electroluminescence panel. Since the effect display is performed by the provided effect display device, a variety of effect display can be performed by the image by the electroluminescence panel and the electric decoration image formed by the light emitting means when the rotating body is rotated. .
[Brief description of the drawings]
FIG. 1 is a front view showing an external structure of a slot machine according to an embodiment.
2 is a view showing the internal structure of the slot machine shown in FIG.
FIG. 3 is an exploded perspective view showing a mounting structure of a liquid crystal display panel.
FIG. 4 is a diagram showing a structure of a liquid crystal display panel.
FIG. 5 is a schematic view showing the structure of a liquid crystal display panel.
6 is a block diagram showing a configuration of a control system provided in the slot machine shown in FIG. 1. FIG.
FIG. 7 is a perspective view showing an external structure of a main reel device.
8 is an exploded perspective view of the main reel device shown in FIG.
FIG. 9 is a diagram showing a structure of a main reel unit provided in the main reel device.
FIG. 10 is a cross-sectional view showing a main part structure of the main reel unit in a broken view.
FIG. 11 is a development view showing a reel tape mounted on a main reel.
FIG. 12 is a perspective view showing an external structure of a sub reel device.
FIG. 13 is a development view showing a reel tape mounted on a sub reel.
FIG. 14 is a side view showing the structure and function of a sub reel.
FIG. 15 is a cross-sectional view showing a principal structure of a sub reel unit in a cutaway manner.
FIG. 16 is a block diagram showing a configuration of an effect control circuit that causes the sub reel unit to display an effect and a display control unit;
FIG. 17 is a diagram for explaining the principle of effect display;
FIG. 18 is a diagram for further explaining the principle of effect display;
FIG. 19 is a diagram exemplifying an image displayed for effect.
FIG. 20 is a side view showing the structure of a sub reel for explaining a modification of the sub reel device.
21 is a side view showing the structure and function of the sub reel shown in FIG.
FIG. 22 is a block diagram showing a configuration of an effect control circuit for causing the sub reel unit to perform effect display and a display control unit in a modification of the sub reel device.
FIG. 23 is a diagram showing an example of an effect display image in a modification of the sub reel device.
FIG. 24 is a diagram illustrating another image that is effect-displayed in a modification of the sub-reel device.
FIG. 25 is a diagram exemplifying another image displayed in the effect in the modification of the sub reel device.
FIG. 26 is a diagram exemplifying another image that is effect-displayed in a modification of the sub-reel device.
[Explanation of symbols]
10 ... Slot machine
11 ... Front door
13f, 14a ... Production panel
100 ... Main reel device
200 ... Sub reel device
LCD ... Liquid crystal display panel
WD2 ... Second display window
MR1 to MR3 ... main reel
SR1 to SR3 ... Sub reel
RL1-RL3, GL1-GL3, BL1-BL3 ... Light emitting unit

Claims (6)

A reel type gaming machine in which a panel unit facing a player is provided with a main reel device including a plurality of main reels for presenting game results and an effect display device for effect display,
Each of the plurality of main reels has a relatively small diameter compared to the effect display range of the effect display device, and the outer peripheral surface facing the player is determined to have a vertical width of 25 mm or more and a horizontal width of 35 mm or more. A plurality of designs are formed,
The effect display device is disposed on a back side of the transparent window portion of the electroluminescence panel, the first display device including an electroluminescence panel in which a transparent window portion is formed in a region facing the player. And a second rendering device having a rotating body provided with one or more light emitting means.
A revolving game machine that displays an effect image by the electroluminescence panel and performs the effect display by causing the light-emitting means to perform an electrical display as the rotating body is rotated. . The rotating body is provided with the plurality of light emitting means at different positions in the radial direction, and the second effect display device uses the plurality of light emitting means to rotate the rotating body. The swivel type gaming machine according to claim 1, wherein an electric decoration display having a depth in a radial direction is performed. The spinning machine according to claim 1 or 2, wherein the light emitting means displays a color image as an electric decoration. The said light emission means is formed with the some light emitting diode, The swivel type game machine of any one of Claims 1-3 characterized by the above-mentioned. 5. The revolving game machine according to claim 1, wherein the main reel device is provided at a position above or below the effect display device in the panel portion. . The spinning machine according to claim 1, wherein the electroluminescence panel is a liquid crystal display panel.

Images