JP5637262B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine.

  A bullet ball game machine, which is a type of gaming machine, includes, for example, an operation handle operated by a player, a game ball launching device that launches and fires a game ball based on the operation of the operation handle, and the launched game ball Is provided with a ball path for guiding the game to a predetermined game area, and each game component arranged in the game area. The game ball launcher has, for example, a linear drive type configuration in which an electromagnetic attraction force is generated by applying electric power to the coil, thereby causing the movable body to reciprocate linearly to fire the game ball. The thing is known (for example, patent document 1).

JP 2000-271275 A

  Some of the above-described linearly driven game ball launching devices include a bearing that comes into contact with the outer periphery of the movable body. By adopting the bearing, it is possible to suppress shaking of the movable body when the movable body reciprocates, to reduce variation in launch accuracy in the game ball launcher and to extend the dynamic special life.

  However, in the configuration adopting the bearing as described above, it is assumed that the following inconvenience occurs due to an increase in the number of components and a complicated mounting structure. That is, the positional variation (for example, misalignment, inclination, etc.) between the central axis of the coil and the central axis of the movable body occurs due to accumulation of dimensional tolerances, etc., and the movable body intersects the central axis of the movable body by the above-described suction force. There is concern about being drawn in the direction. Such an action of the attractive force is not preferable because it causes a loss of power consumption and the like, and may cause a decrease in launch efficiency.

  The present invention has been made in view of the above-described circumstances and the like, and an object thereof is to provide a gaming machine capable of increasing the launch efficiency of a game ball.

The present invention
A launch device that launches a game ball based on a predetermined launch operation,
The launcher is
A movable body capable of linear reciprocation;
A coil that forms a magnetic field by being energized and supplies power to the movable body, and an insertion portion through which the movable body is inserted, and a bobbin around which the coil is wound are provided around the insertion portion. A drive unit;
A housing for accommodating the drive unit;
Provided at both ends of the bobbin, and provided with a defining portion that regulates the moving direction of the movable body to be the same direction as the axial direction of the insertion portion by contacting the movable body,
Each of the defining parts is
A cylindrical main body extending in the same direction as the insertion portion;
A bearing portion provided at an end of the main body portion opposite to the bobbin, through which the movable body is inserted;
A flange portion that is formed at an end portion of the main body portion on the bobbin side and abuts on an end portion of the bobbin;
The housing has a first housing component and a second housing component as a pair of housing components provided so as to sandwich the main body from both sides in the axial direction.
The first housing component is:
A first opening through which the main body is inserted;
Provided around the first opening, and a first contact portion that contacts the opposite side of the bobbin to the flange portion and the body portion to the first opening in the insertion state,
The second housing component is:
A second opening through which the main body is inserted;
A second contact portion provided around the second opening and contacting the flange portion from a side opposite to the bobbin in a state where the main body portion is inserted through the second opening;
Have
By the first housing component and the second housing member is fixed, said flange portion provided on one of the defining portion is sandwiched between the bobbin and the first contact portion and the The flange portion provided on the other of the defining portions is configured to be sandwiched between the bobbin and the second contact portion ,
The bobbin and each contact portion are formed with a fitting recess that fits into the flange portion,
In the sandwiched state, the flange portion is fitted into the fitting recess, so that the relative position of the defining portion, the drive portion, and the housing in a direction different from the moving direction of the movable body changes. Regulated ,
The first housing component is provided with a first extension that extends from the first contact portion in the axial direction and forms an insertion portion into which the drive unit and the second housing component are inserted. And
The second housing component is provided with a second extending portion extending from the second contact portion in the same direction as the first extending portion,
The second extension part is configured to face the first extension part from the inside of the insertion part when the second housing component is inserted into the insertion part.
A screw for fixing the first extension part and the second extension part;
The housing is configured such that the screw is attached in the same direction as the overlapping direction of the first extending portion and the second extending portion .

  The launch efficiency of game balls can be increased.

The perspective view which looked at the structure of the pachinko machine from the front. The disassembled perspective view which decomposes | disassembles and shows the main structures of a game machine main body. The front view which shows the structure of an inner frame. The front view which shows the structure of a game board. The rear view which shows the structure of an inner frame. The front view which shows the structure of a back pack unit. The elements on larger scale of FIG. 3 which show a game ball | bowl launching apparatus and the structure accompanying it. (A) The top view which shows the structure of a game ball launcher, (b) The side view which shows the structure of a game ball launcher. The disassembled perspective view which decomposes | disassembles and shows the main structures of a game ball | bowl launcher. FIG. 9 is a partial sectional view taken along line AA in FIG. (A) The top view of a 1st housing structure, (b) The top view of a 2nd housing structure. (A) Front view of 1st housing structure, (b) Front view of 2nd housing structure. Schematic which shows the mode of assembly | attachment of a game ball | bowl launcher. The block diagram which shows the electrical constitution of a pachinko machine. Schematic which shows the modification of a game ball | bowl launching apparatus.

  Hereinafter, an embodiment of a pachinko gaming machine (hereinafter referred to as “pachinko machine”), which is a type of gaming machine, will be described in detail with reference to the drawings. FIG. 1 is a perspective view of the pachinko machine 10 viewed from the front, and FIG. 2 is an exploded perspective view of the pachinko machine 10 disassembled for each main configuration. In FIG. 2, the configuration in the game area of the pachinko machine 10 is omitted for convenience.

  The pachinko machine 10 includes an outer frame 11 that forms an outer shell of the pachinko machine 10, and a gaming machine body 12 that is attached to the outer frame 11 so as to be pivotable forward (openable and closable). . In the pachinko machine 10, the outer frame 11 is not an essential configuration, and the outer frame 11 may be provided on the island facility of the game arcade.

  The outer frame 11 has a rectangular frame shape, the upper and lower frames are made of wood, and the left and right frames are made of metal such as aluminum. The pachinko machine 10 is installed in the game hall by attaching and fixing the outer frame 11 to the island facility. In addition, the material which forms the outer frame 11 is not limited to the above, and is arbitrary.

  A gaming machine body 12 is rotatably supported on one side of the outer frame 11. Specifically, as shown in FIG. 1, an upper support bracket 21 is fixed to a connecting portion between the upper frame portion and the left frame portion in the outer frame 11, and the lower frame portion and the left frame in the outer frame 11 are further fixed. A lower support metal fitting 22 is provided at a connection portion with the portion. The upper support bracket 21 and the lower support bracket 22 constitute a support mechanism, and the gaming machine body 12 is rotatably supported with respect to the outer frame 11 by the support mechanism.

  Further, as shown in FIG. 2, the gaming machine main body 12 is provided with a locking device 23 at its rotating tip, and when the gaming machine main body 12 is closed with respect to the outer frame 11, the gaming machine main body 12 is locked. The saddle member 24 of the device 23 is received by the saddle receiving portion provided on the inner side surface of the right frame portion of the outer frame 11, and the opening of the gaming machine main body 12 is prevented. On the other hand, the hook member 24 is received by the hook receiving portion of the outer frame 11 by performing the unlocking operation using the unlock key on the cylinder lock 25 provided exposed at the front surface of the pachinko machine 10. The state is released and the gaming machine body 12 can be released from the outer frame 11. The locking device 23 also has a function of locking an inner frame 13 and a front door frame 14 described later.

  The gaming machine main body 12 includes an inner frame 13 as a base body, a front door frame 14 disposed in front of the inner frame 13, and a back pack unit 15 disposed behind the inner frame 13. The inner frame 13 of the gaming machine main body 12 is supported so as to be rotatable (openable and closable) with respect to the outer frame 11. Specifically, the inner frame 13 can be rotated forward with the left side as the rotation base end side (opening / closing base end side) and the right side as the rotation front end side (opening / closing front end side) in front view.

  A front door frame 14 is supported by the inner frame 13 so as to be rotatable (openable and closable), and in the front view, the left side is a rotation base end side (opening / closing base end side) and the right side is a rotation front end side (opening / closing front end). Side) and can be rotated forward. Further, the back pack unit 15 is supported by the inner frame 13 so as to be rotatable (openable and closable), and in the front view, the left side is the rotation base end side (opening / closing base end side) and the right side is the rotation front end side ( It can be rotated backward as the opening / closing tip side.

  Next, the configuration of the front side of the gaming machine body 12 will be described. FIG. 3 is a front view of the inner frame 13.

  The inner frame 13 is mainly composed of a resin base 31 whose outer shape is substantially the same as that of the outer frame 11. A substantially elliptical window hole 32 is formed at the center of the resin base 31. A game board 33 is detachably attached to the resin base 31. The game board 33 is made of plywood, and a game area 33 a formed on the front surface of the game board 33 is exposed to the front surface side of the inner frame 13 through the window hole 32 of the resin base 31.

  Here, the structure of the game board 33 is demonstrated based on FIG. The game board 33 has a plurality of large and small openings penetrating in the front-rear direction by being subjected to router processing. Each opening is provided with a general winning port 34, a variable winning device 35, an operating port 36, a through gate 37, a variable display unit 38, and the like. A total of four general winning openings 34 are provided on each of the left and right sides. When a game ball enters the general winning opening 34, the variable winning device 35, and the operation opening 36, it is detected by a detection switch described later, and a predetermined number of winning balls are paid out based on the detection result. In addition, an out port 39 is provided at the lowermost part of the game board 33, and game balls that have not entered the various winning ports etc. are discharged from the game area 33 a through the out port 39. The game board 33 is provided with a large number of nails 40 for distributing and adjusting the falling direction of the game balls as appropriate, and various members (functions) such as a windmill.

  The variable display unit 38 is provided with a symbol display device 41 for variably displaying symbols with a winning at the operation port 36 as a trigger. The variable display unit 38 is provided with a center frame 42 so as to surround the symbol display device 41. A first specific lamp portion 43 and a second specific lamp portion 44 are provided on the center frame 42. Reservation lamp portions 45 and 46 are provided at the lower and upper portions of the center frame 42, respectively. The lower holding lamp unit 45 corresponds to the symbol display device 41 and the first specific lamp unit 43, and the number of times that the game ball has passed through the operation port 36 is held up to four times, and the holding lamp unit 45 is turned on by The number of holds is displayed. The upper holding lamp unit 46 corresponds to the second specific lamp unit 44, and the number of times that the game ball has passed through the through gate 37 is held up to four times, and the number of holdings is displayed by lighting the holding lamp unit 46. It is like that.

  The symbol display device 41 is configured as a liquid crystal display device including a liquid crystal display, and the display content is controlled by the display control device. On the symbol display device 41, for example, symbols are displayed side by side on the left, middle and right, and these symbols are variably displayed as they are scrolled up and down. When a predetermined combination of symbols is stopped and displayed on a preset active line, a special gaming state (hereinafter referred to as a jackpot) occurs.

  In the first specific lamp unit 43, the emission color is switched in a predetermined order using a winning at the operation port 36 as a trigger, and if the display is stopped in a predetermined color, a big hit occurs. Further, in the second specific lamp unit 44, the emission color is switched in a predetermined order triggered by the passage of the game ball through the through gate 37, and when the stop color is displayed in a predetermined color, the operation port 36 is displayed. The accompanying electric accessory is opened for a predetermined time. The control of the first specific lamp unit 43 and the second specific lamp unit 44 is performed by a main controller described later.

  The variable winning device 35 is normally in a closed state in which a game ball cannot be won or difficult to win, and is switched to a predetermined open state in which a game ball is easy to win in the case of a big win. As an opening mode of the variable winning device 35, the variable winning device 35 is repeated with a predetermined time (for example, 30 seconds) or a predetermined number (for example, 10) of winnings as one round and a plurality of rounds (for example, 15 rounds) as an upper limit. What is opened is common. The drive control of the variable winning device 35 is performed by a main control device described later.

  An inner rail 47 and an outer rail 48 are attached to the game board 33, and a guide rail 49 is configured by the inner rail 47 and the outer rail 48. A game ball launching device 100 is provided below the window hole 32 in the resin base 31, and the game balls launched from the game ball launching device 100 pass through an area partitioned by the guide rail 49 to play a game area. It is guided to the upper part of 33a (refer FIG. 3). A detailed description of the game ball launcher 100 and the configuration associated therewith will be described later.

  A front door frame 14 is provided so as to cover the entire front side of the inner frame 13. As shown in FIG. 1 and the like, the front door frame 14 is formed with a window portion 55 so that almost the entire game area 33a can be viewed from the front. The window portion 55 has a substantially elliptical shape, and a transparent glass 56 is fitted therein. Around the window 55, light emitting means such as various lamps are provided. In addition, at the upper left and upper right positions, speaker units are provided for outputting sound effects according to the gaming state.

  Below the window portion 55 in the front door frame 14, an upper bulging portion 57 and a lower bulging portion 58 that bulge to the near side are provided side by side. An upper plate 57a that opens upward is provided inside the upper bulge portion 57, and a lower plate 58a that also opens upward is provided inside the lower bulge portion 58. The upper plate 57a has a function of temporarily storing game balls paid out from a payout device, which will be described later, and guiding them to the game ball launching device 100 side while aligning them in a line. In addition, the lower tray 58a has a function of storing game balls that are surplus in the upper tray 57a.

  A handle device 59 is provided on the right side of the lower bulging portion 58 so as to protrude to the front side. By operating the handle device 59, a game ball is launched from the game ball launch device 100.

  Next, the configuration on the back side of the gaming machine main body 12 will be described. FIG. 5 is a rear view of the inner frame 13, and FIG. 6 is a front view of the back pack unit 15.

  As shown in FIG. 5, a main controller unit 61 and an audio lamp controller unit 65 are mounted on the back surface of the inner frame 13 (game board 33).

  The main controller unit 61 has a synthetic resin mount, and the main controller 63 is mounted on the mount. The main control device 63 includes a main control board having a function (main control circuit) that controls the main control of the game and a function (power failure monitoring circuit) that monitors the power source, and a board box 64 that houses the main control board. ing. The specific configuration of the main controller 63 will be described later in detail.

  The sound lamp control device unit 65 includes a sound lamp control device 66 and a mounting base, and the sound lamp control device 66 is mounted on the mounting base. The sound lamp control device 66 includes a sound lamp control board for controlling sound and lamp display and a display control device (not shown) in accordance with an instruction from the main control device 63. The sound lamp control board is made of a transparent resin material or the like. The board box 68 is configured to be accommodated.

  As shown in FIG. 6, the back pack unit 15 includes a back pack 71, and a payout mechanism 72 and a control device assembly unit 73 are attached to the back pack 71. The back pack 71 is formed of a synthetic resin having transparency, and includes a base portion 74 to which the payout mechanism portion 72 and the like are attached, and a protective cover portion 75 that protrudes rearward from the pachinko machine 10 and has a substantially rectangular parallelepiped shape.

  The base portion 74 is provided with an external terminal plate 76 at the upper right portion thereof. The external terminal board 76 is provided with various output terminals, and various signals are output to the management control device on the game hall side through these output terminals. The base portion 74 is provided with a payout mechanism portion 72 so as to bypass the protective cover portion 75. That is, a tank 77 opened upward is provided at the uppermost part of the back pack 71, and the game balls supplied from the island facility of the game hall are sequentially replenished to the tank 77. A tank rail that is gently inclined toward the downstream side is connected to the lower side of the tank 77, and a case rail extending in the vertical direction is connected to the downstream side of the tank rail. A payout device 78 is provided at the most downstream portion of the case rail. The game balls paid out from the payout device 78 are discharged to the upper plate 57a or the lower plate 58a through a payout passage (not shown) provided on the downstream side of the payout device 78.

  A backpack substrate 79 is installed in the payout mechanism 72. The back pack substrate 79 is supplied with, for example, an AC 24 volt main power, and is turned on or off by a power switch switching operation.

  A control device assembly unit 73 is attached to the lower end portion of the base portion 74. The control device assembly unit 73 has a horizontally long mounting base 81 on which a payout control device 82 and a power supply / launch control device 83 are mounted. The payout control device 82 and the power supply / launch control device 83 are arranged one behind the other so that the payout control device 82 is behind the pachinko machine 10.

  The payout control device 82 is configured such that a payout control board for controlling the payout device 78 is accommodated in the board box 84. The power source / launch control device 83 is configured by housing a power source / launch control board in a board box 85. The board generates and outputs predetermined power required by various control devices and the like. The launch control of the game ball accompanying the operation of the handle device 59 is performed. This pachinko machine 10 has a function to store and store various data so that even if a power failure occurs, it maintains the state at the time of the power failure, and when it recovers from the power failure, it can be restored to the state at the time of the power failure. It has become.

  Next, the above-described game ball launching apparatus 100 and the configuration associated therewith will be described based on FIGS. 3 and 7. FIG. 7 is a partially enlarged view of FIG. 3 showing an enlarged view of the game ball launching apparatus 100 and the configuration associated therewith. In addition, about the thing with little relation with the game ball | bowl launching apparatus 100, illustration is abbreviate | omitted.

  As shown in FIG. 7, the game ball launching apparatus 100 has an electromagnetic solenoid 110 that launches a game ball placed at a predetermined position (launch standby position), and a guide ball 49 ( A launch rail 120 that guides to a region sandwiched between the inner rail 47 and the outer rail 48, a ball feed mechanism 130 that supplies a game ball to the launch standby position, and a base plate 140 on which these various configurations are mounted. ing. The game ball launcher 100 is integrated with the gaming machine main body 12 by fixing the base plate 140 to the resin base 31 of the inner frame 13 with a fastener such as a screw.

  The firing rail 120 is fixed to the base plate 140 using a plurality of fixing tools so as to have a predetermined firing angle (launch angle). Specifically, the entrance portion 49a of the guide rail 49 is opened to the rotating front end side of the gaming machine main body 12, specifically, obliquely downward, and the launch rail 120 has its entrance portion 49a on an extension line in its own rail direction. Is positioned so as to face the inlet portion 49a (see FIG. 3).

  A predetermined gap is formed between the firing rail 120 and the entrance portion 49a of the guide rail 49, and a foul ball passage (not shown) is provided below the gap. If the game balls fired by the solenoid 110 do not reach the game area 33a and return to the inside of the guide rail 49 as foul balls, the foul balls are discharged to the lower plate 58a through the foul ball passage. Thereby, all of the foul balls are surely guided to the foul ball path, and interference between the foul balls and the game balls to be fired next is suppressed.

  At the end of the firing rail 120 opposite to the guide rail 49 (ie, the lower end), a game ball stopper 150 is provided that holds the game balls B supplied one by one from the ball feed mechanism 130 at the above-described firing standby position. Yes. The launch rail 120 is attached so as to incline so as to incline upward from the turning front end side to the turning base end side of the gaming machine main body 12 as described above, and the game ball stopper 150 is the same as the game ball B. By abutting from the downstream side of the launch rail 120, the game ball B supplied from the ball feed mechanism 130 can be held at the launch standby position.

  The solenoid 110 described above is disposed further downstream than the game ball stopper 150, that is, at a position on the rotation tip side of the gaming machine main body 12 with respect to the game ball stopper 150. The solenoid 110 has a metal movable body 160 that slides (reciprocates) based on the input of an electrical signal to the solenoid 110, and the movement direction of the movable body 160 is the firing rail 120. The trajectory PL along which the movable body 160 moves is disposed so as to pass through the center of the game ball B disposed at the launch standby position. Thereby, the game ball B pushed out by the movable body 160 is easy to move along the launch rail 120.

  Note that the above-described game ball stopper 150 is disposed such that a passage gap of the movable body 160 is formed between itself and the launch rail 120. Thereby, the game ball B held at a predetermined position by the game ball stopper 150 is exposed to the solenoid 110 side, and the game ball B can be launched by the movable body 160 of the solenoid 110.

  Here, the solenoid 110 will be described in detail with reference to FIGS. 8A is a plan view of the solenoid 110, FIG. 8B is a side view of the solenoid 110, FIG. 9 is an exploded perspective view showing the solenoid 110 disassembled for each main component, and FIG. 10 is FIG. It is an AA line fragmentary sectional view of).

  The solenoid 110 includes the movable body 160 described above, the solenoid drive unit 170 that constitutes the driving force generation source of the movable body 160, and the movable body 160 so that the movable body 160 moves in the same direction as the rail direction of the firing rail 120. A plurality of defining portions 210 and 230 for defining the moving direction of 160, and a housing 250 on which these various configurations are mounted (see FIG. 8).

  The solenoid drive unit 170 includes an excitation coil 171 made of copper wire and a synthetic resin (insulator) bobbin 181 to which the excitation coil 171 is attached. The bobbin 181 has a cylindrical portion 182 that has a cylindrical shape (hollow shape), and an exciting coil 171 is wound along an outer peripheral surface 182 a of the cylindrical portion 182. Both ends of the excitation coil 171 are connected to a relay board (not shown), and the excitation coil 171 and the power source / launch control device are electrically connected via the relay board. For convenience, the excitation coil 171 is indicated by dot hatching in FIG. 8, and the excitation coil 171 is indicated by a two-dot chain line in FIG.

  The movable body 160 is inserted into the cylindrical portion 182 of the bobbin 181. The movable body 160 includes a columnar shaft 161 that extends in the same direction as the central axis X <b> 1 of the cylindrical portion 182, and a cylindrical plunger 162 that extends in the same direction as the shaft 161. The shaft 161 and the plunger 162 are formed of a ferromagnetic material such as magnetic stainless steel, and are integrated in a state where the shaft 161 is press-fitted into the plunger 162. The plunger 162 is formed so that the center axis thereof overlaps (coincides with) the center axis X2 of the shaft 161, and is disposed substantially at the center of the shaft 161 (specifically, at a substantially intermediate position in the axial direction). That is, in a state where the shaft 161 and the plunger 162 are integrated, the shaft 161 protrudes from both sides of the plunger 162.

  The plunger 162 is formed such that its outer diameter is slightly smaller than the inner diameter of the bobbin 181 (specifically, the cylindrical portion 182) (see FIG. 10). That is, in a state where the plunger 162 is inserted into the bobbin 181, the outer peripheral surface of the plunger 162 and the inner peripheral surface 182 b of the cylindrical portion 182 face each other with a slight gap therebetween. This clearance secures an air escape path when the plunger 162 moves in the cylindrical portion 182 to reduce the air resistance when the solenoid 110 is driven.

  The bobbin 181 will be described again. As shown in FIGS. 9 and 10, flange portions 183 and 184 projecting in the radial direction of the central axis of the cylindrical portion 182 are integrally formed on both side portions of the cylindrical portion 182. . The flange portions 183 and 184 are formed over the entire edge portion of the cylindrical portion 182, and have a substantially disc shape in which openings 185 and 186 communicating with the internal space of the cylindrical portion 182 are formed at the center. When the exciting coil 171 is in contact with the flange portions 183 and 184, the falling of the exciting coil 171 from the bobbin 181 is suppressed.

  The above-described defining portions 210 and 230 are disposed at positions outside the flange portions 183 and 184 in the axial direction of the bobbin 181. In other words, the defining portions 201 and 230 are provided so as to sandwich the bobbin 180 therebetween. The defining portions 210 and 230 are configured by synthetic resin bearings 211 and 231 through which the shaft 161 of the movable body 160 is inserted, and metal holders 215 and 235 that hold the bearings 211 and 231.

  The holders 215 and 235 are formed with through holes 216 and 236 penetrating in the axial direction of the movable body 160, and both the holders 215 and 235 are formed in the through holes 216 and 236 of the holders 215 and 235 and the bobbin 181. The through holes 216 and 236 are arranged so as to be on the same axis. On the inner peripheral surfaces 216a and 236a that define the through holes 216 and 236, throttle portions 217 and 237 that project inward of the through holes 216 and 236 are provided in the middle of the through holes 216 and 236 in the axial direction. Yes.

  The throttle portions 217 and 237 have an annular shape (specifically, an annular shape), a surface facing the bobbin 181 (hereinafter referred to as inner surfaces 217a and 237a) and a surface facing the opposite side with respect to the bobbin 181 ( Hereinafter, the outer surfaces 217b and 237b are formed so as to form a substantially planar shape perpendicular to the axial direction of the holders 215 and 235 (see FIG. 10). Using the throttle portions 217 and 237 as a reference, the holders 215 and 235 include large-diameter portions 218 and 238 on the bobbin 181 side, and small-diameter portions 219 and 239 having an inner diameter smaller than the large-diameter portions 218 and 238 on the opposite side to the bobbin 181. And is roughly divided.

  The inner diameters of the throttle portions 217 and 237 are set to be smaller than the inner diameters of the small diameter portions 219 and 239. The bearings 211 and 231 are fitted in a space surrounded by the throttle portions 217 and 237 and the small diameter portions 219 and 239 (hereinafter referred to as the accommodation space HS). More specifically, the bearings 211 and 231 are pressed into the accommodation space HS.

  The small diameter portions 219 and 239 are caulked (not shown) for restricting the bearings 211 and 231 from coming off from the open portions of the small diameter portions 219 and 239 opposite to the throttle portions 217 and 237. These throttle parts 217, 237, small diameter parts 219, 239 and caulking restrict movement of the bearings 211, 231 such as displacement of the holding position and disengagement from the holders 215, 235.

  The openings 220 and 240 formed in the central portions of the throttle portions 217 and 237 are round holes that are coaxial with the bearing holes 212 and 232 of the bearings 211 and 231, and the bearings are provided inside the openings 220 and 240. 211 and 231 are partially fitted. The inner diameters of the bearing holes 212 and 232 are set to be equal to the outer diameter of the shaft 161. A shaft 161 is inserted into the bearing holes 212 and 232, and a moving direction of the shaft 161, that is, a moving direction of the movable body 160 is defined. The inner diameters of the openings 220 and 240 are set to be larger than the outer diameter of the shaft 161, and interference between the throttle portions 217 and 237 and the shaft 161 is avoided.

  The inner diameters of the large-diameter portions 218 and 238 described above are set to be substantially equal to the inner diameter of the bobbin 181. That is, the inner diameters of the large diameter portions 218 and 238 are set to be slightly larger than the outer shape of the plunger 162. The large diameter portions 218 and 238 and the bobbin 181 communicate with each other through the openings 185 and 186 of the bobbin 181, and the movement (movement) of the plunger 162 between the large diameter portions 218 and 238 and the bobbin 181 is allowed. Has been.

  The inner diameters of the openings 220 and 240 (that is, the inner diameters of the throttle portions 217 and 237) are set to be smaller than the outer diameter of the plunger 162. That is, the inner surfaces 217 a and 237 a of the throttle portions 217 and 237 face the end surfaces 163 and 164 of the plunger 162 in the movable body 160. A range (operation space MS) in which the movable body 160 is slidable is defined by the inner surfaces 217a and 237a. Note that portions of the bearings 211 and 231 that are fitted in the openings 220 and 240 are formed so as to avoid protrusion from the inner surfaces 217a and 237a of the throttle portions 217 and 237. Thereby, the contact between the bearings 211 and 231 and the plunger 162 is avoided.

  Flange portions 221 and 241 with respect to the bobbin 181 are integrally formed at the end portions of the large diameter portions 218 and 238 on the side facing the flange portions 183 and 184. The flange portions 221 and 241 are formed along the edges of the large diameter portions 218 and 238 and have an annular shape extending radially with respect to the central axes of the defining portions 210 and 230. Corresponding to these flange portions 221 and 241, installation portions 187 and 188 are formed on the flange portions 183 and 184 of the bobbin 181. The installation portions 187 and 188 are stepped so as to be lower than the outer surfaces 183a and 184a of the flange portions 183 and 184, and the flange portions 221 and 241 are fitted to the installation portions 187 and 188. It has become. When the installation portions 187 and 188 and the flange portions 221 and 241 are fitted, the bobbin 181 and the two defining portions 210 and 230 are combined.

  The depth dimensions of the installation parts 187 and 188 are set to be approximately half the thickness dimension of the flange parts 221 and 241. For this reason, in a state where the installation parts 187 and 188 and the flange parts 221 and 241 are fitted, a part of the flange parts 221 and 241 (specifically, about half of the thickness) is installed in the installation parts 187 and 188. That is, it is configured to project from the outer surfaces 183a and 184a of the flange portions 183 and 184.

  Note that the holders 215 and 235 do not necessarily have the large diameter portions 218 and 238 and the small diameter portions 219 and 239. That is, it is not necessary to make the inner diameters different from each other with respect to the throttle portions 217 and 237. For example, the holder may have a through hole formed so as to have a constant inner diameter, and the throttle portion may be formed on the inner peripheral surface thereof.

  The center axes X3 and X4 of the defining portions 210 and 230 (specifically, bearings 211 and 231) described in detail above are configured to overlap the central axis X1 of the solenoid drive unit 170 (specifically, the bobbin 181) described above. Thus, the moving direction of the movable body 160 (specifically, the shaft 161) is defined so as to be the same as the axial direction of the bobbin 181.

  Hereinafter, for convenience of description, the defining portion 210 on the firing rail 120 side of the defining portions 210 and 230 is referred to as a “first defining portion 210”, and the defining portion 230 on the opposite side of the firing rail 120 is referred to as a “second defining portion 230”. Similarly, the various configurations of the defining sections 210 and 230 are also appropriately distinguished as “first 1” and “second 2”.

  As shown in FIGS. 9 and 10, etc., the space defined by the first holder 215 of the first defining portion 210, the cylindrical portion 182 of the bobbin 181 and the plunger 162 of the movable body 160 (first partitioned space DS1) includes: A coil spring 169 is provided as an urging member that urges the movable body 160 toward the second defining portion 230 side. One end of the coil spring 169 is in contact with the throttle portion 217 (specifically, the inner surface 217a) of the first holder 215, and the other end is in contact with the end surface 163 of the plunger 162 on the first defining portion 210 side. It is in a state. When the solenoid driving unit 170 is not driven, the movable body 160 is configured to be in a standby state at a position (initial position) biased toward the second defining unit 230 by the biasing force of the coil spring 169. ing.

  On the other hand, the space defined by the second holder 235 of the second defining portion 230, the cylindrical portion 182 of the bobbin 181 and the plunger 162 of the movable body 160 (second partitioned space DS2) is on the second defining portion 230 side of the plunger 162. A rubber ring 168 is provided as a cushioning material to alleviate interference between the end surface 164 and the throttle portion 237 (specifically, the inner surface 237a) of the second holder 235. The rubber ring 168 is disposed between the end surface 164 and the inner surface 237a, and is specifically attached to the shaft 161. When the movable body 160 is pushed toward the second defining portion 230 by the coil spring 169 described above, the rubber ring 168 is sandwiched between the end surface 164 and the inner surface 237a. Thereby, generation | occurrence | production of the hit sound when the movable body 160 is arrange | positioned in the initial position is suppressed. That is, the rubber ring 168 also has a function as a sound deadening material.

  It is also possible to attach the rubber ring 168 to the second defining portion 230 side. The rubber ring 168 is not necessarily arranged in the second partition space DS2, and may be arranged outside the second partition space DS2, for example, outside the second defining portion 230.

  A contact member 167 that comes into contact with the game ball B is attached to a portion of the shaft 161 protruding from the first defining portion 210 as the game ball B held at the firing standby position is launched. The contact member 167 is made of a material softer than the shaft 161 (specifically, a synthetic resin material), and reduces the hitting sound and protects the game ball when the game body is launched by the movable body 160. It has been.

  The solenoid driving unit 170 and the defining units 210 and 230 described in detail above are sandwiched by the housing 250 from both sides in the axial direction of the bobbin 181 in a state where they are combined with each other. The housing 250 is formed of a ferromagnetic material such as magnetic stainless steel, and the first housing component 260 provided on the first defining portion 210 side and the second housing component provided on the second defining portion 230 side. 280. Hereinafter, the housing components 260 and 280 will be described with reference to FIGS. 11A is a plan view of the first housing component 260, FIG. 11B is a plan view of the second housing component 280, FIG. 12A is a front view of the first housing component 260, FIG. (B) is a front view of the second housing component 280. For convenience, the second housing component 280 will be described first.

  The second housing component 280 has a base portion 281 that is opposed to the base plate 140 and that constitutes a mounting portion for the base plate 140. The base portion 281 has a flat plate shape parallel to the base plate 140, and is formed so as to overlap at least the entire area of the solenoid driving portion 170 in a plan view of the solenoid 110 (a plan view of the second housing 280) (FIG. 11A). )reference). A holding portion 282 for holding the second defining portion 230 is integrally formed on one side portion of the base portion 281. The holding portion 282 has a plate shape that stands up against the base plate 140 side from the base portion 281, and the plate surface (inner surface 282 a) on the bobbin 181 side of the holding portion 282 faces the flange portion 184 of the bobbin 181. Is formed.

  An insertion hole 283 through which the large-diameter portion 238 of the second holder 235 is inserted is formed substantially at the center of the holding portion 282, and a part of the large-diameter portion 238 is outside the housing 250 through the insertion hole 283. It is in a protruding state.

  On the periphery of the insertion hole 283, a fitting portion 284 that fits with a portion of the flange portion 241 of the second holder 235 that protrudes from the outer surface 184a of the flange portion 184 is provided. The fitting portion 284 is recessed in a stepped shape so as to be lower than the inner surface 282a of the holding portion 282, and the depth dimension thereof is formed to be equal to the protruding amount of the flange portion 241 from the outer surface 184a. Has been.

  With the flange portion 241 fitted in the fitting portion 284, the inner surface 282a of the holding portion 282 and the outer surface 184a of the flange portion 184 are in surface contact. Thus, in the state where the holding portion 282 and the flange portion 184 are in surface contact, the flange portion 241 of the second defining portion 230 is formed by the holding portion 282 of the second housing component 280 and the installation portion 188 of the flange portion 184. A space for fitting is defined.

  At the end of the holding portion 282 opposite to the base portion 281, a facing portion 285 that faces the base portion 281 with the solenoid driving portion 170 interposed therebetween is provided. The facing portion 285 has a plate shape extending toward the first defining portion 210 with the holding portion 282 as a base end, and is formed so as to cover the entire solenoid driving portion 170 in a plan view of the solenoid 110. The first housing component 260 described above is arranged on the distal end side of the facing portion 285 so as to connect the base portion 281 and the facing portion 285. That is, the first housing component 260 is disposed on the opposite side of the second holding unit 282 with the solenoid driving unit 170 interposed therebetween.

  The first housing component 260 has a holding portion 261 that holds the first defining portion 210. The holding part 261 has a flat plate shape facing the holding part 282 of the second housing component 280 with the solenoid driving part 170 interposed therebetween. An insertion hole 262 through which the large-diameter portion 218 of the first holder 215 is inserted is formed at the approximate center of the holding portion 261, and a part of the large-diameter portion 218 is outside the housing 250 through the insertion hole 262. It is in a protruding state.

  On the periphery of the insertion hole 262, a fitting portion 263 that fits a portion of the flange portion 221 of the first holder 215 that protrudes from the outer surface 183a of the flange portion 183 is provided. The fitting portion 263 is recessed in a stepped shape so as to be lower than the plate surface (the inner surface 261 a) facing the flange portion 183 in the holding portion 261, and the depth dimension of the fitting portion 263 is an overhang of the flange portion 221. It is formed to be equivalent to the amount.

  In a state where the flange portion 221 is fitted in the fitting portion 263, the inner surface 261a of the holding portion 261 and the outer surface 183a of the flange portion 183 are in surface contact. In other words, in a state where the holding portion 261 and the flange portion 183 are in surface contact, the flange portion 241 of the second defining portion 230 is formed by the holding portion 261 of the first housing component 260 and the installation portion 187 of the flange portion 183. A space for fitting is defined.

  Here, a configuration related to the combination and fixation of the first housing component 260 and the second housing component 280 will be described with reference to FIGS.

  A flat plate-like extending portion 286 extending outward (from the firing rail 120 side) than the solenoid driving portion 170 is formed at the end of the base portion 281 of the second housing component 280 on the firing rail 120 side. The holding portion 261 of the housing 260 is integrally formed with a contact portion 264 that contacts the extension portion 286 from the inside. The contact portion 264 has a plate shape parallel to the extending portion 286, and the plate surface is in surface contact with the plate surface of the extending portion 286.

  On the other hand, a flat plate-like extending portion 287 extending to the outside (the firing rail 120 side) of the solenoid driving unit 170 is formed at the end on the firing rail 120 side of the facing portion 285 in the second housing structure 280. The holding portion 261 of the first housing 260 is integrally formed with a contact portion 265 that contacts the extension portion 287 from the inside. The contact portion 265 has a plate shape parallel to the extending portion 287, and the plate surface is in surface contact with the plate surface of the extending portion 287.

  As described in detail above, based on the fact that the contact portions 264 and 265 of the first housing component 260 abut on the extending portions 286 and 287 of the second housing component 280, the first housing component 260 is the same. The housing structure 260 is in a state of being sandwiched by the second housing structure 280, and a so-called “yoke” is formed by the housing structures 260 and 280.

  In addition, a pair of projecting portions 266 and 267 are formed at the end portion on the base portion 281 side of the holding portion 261 of the first housing component 260. The projecting portions 266 and 267 are arranged on both sides of the contact portion 264 so as to be spaced apart from each other, and on the edge of the extension portion 286 so as to sandwich the extension portion 286 of the second housing component 280. It is in contact. Similarly, a pair of projecting portions 268 and 269 are formed at the end of the holding portion 261 on the facing portion 285 side. The projecting portions 268 and 269 are spaced apart on both sides of the abutting portion 265, and the extending portion 287 of the second housing component 280 is sandwiched at the edge of the extending portion 287. It is in contact.

  Further, wall-shaped positioning portions 288 and 289 facing the axial direction of the movable body 160 are provided on both sides of the extending portion 286 in the base portion 281, and on both sides of the extending portion 287 in the facing portion 285. Wall-shaped positioning portions 290 and 291 facing the axial direction of the movable body 160 are provided. These positioning portions 288 to 291 are formed corresponding to the above-described protruding portions 266 to 269, and the first housing component 260 is brought into contact with the positioning portions 288 to 291 by contacting the protruding portions 266 to 269. And the relative position of the 2nd housing structural body 280, specifically, the relative position in the axial direction of the movable body 160 is specified.

  As described above, in a state where the first housing component 260 and the second housing are combined, both the housing components 260 and 280 are coupled by countersunk screws 296 and 297 as coupling means.

  Specifically, the contact portions 264 and 265 of the first housing component 260 are provided with screw holes 273 and 274 into which countersunk screws 296 and 297 are screwed, and the second housing component 280 is extended. The outlets 286 and 287 are provided with communication holes 293 and 294 communicating with the screw holes 273 and 274. The countersunk screws 296 and 297 are inserted from the outside of the housing 250 through the communication holes 293 and 294, and are attached to the screw holes 273 and 274, so that both housing components 260 and 280 are integrated. . As described above, the two housing components 260 and 280 are coupled to each other so that the solenoid driving portion 170 and the two defining portions 210 and 230 are sandwiched by the two housing components 260 and 280 from both sides in the axial direction of the solenoid 110. The solenoid drive unit 170 and the defining units 210 and 230 cannot be separated (removed).

  The screw holes 273 and 274 and the communication holes 293 and 294 are formed so that the central axes of the holes 273, 274, 293 and 294 extend in a direction intersecting (specifically, orthogonal) to the central axis X of the movable body 160. Has been. For this reason, the central axes of the countersunk screws 296 and 297 screwed into the screw holes 273 and 274 intersect (specifically, orthogonal) to the central axis X of the movable body 160. As described above, the countersunk screws 296 and 297 are attached so as to intersect with the sliding direction of the movable body 160 (specifically, so as to be perpendicular), and thus the solenoid 110 is driven. Inconveniences such as loosening of the countersunk screws 296, 297 due to vibration or the like are less likely to occur.

  As shown in the enlarged view of FIG. 11B, the communication holes 293 and 294 are formed larger than the screw holes 273 and 274. Specifically, the communication holes 293 and 294 have a long hole shape extending in a direction away from the solenoid driving unit 170 (specifically, in the axial direction of the movable body 160) with a position that is continuous with the screw holes 273 and 274 as a base end. Yes. The diameters of the communication holes 293 and 294 are formed so as to decrease with increasing distance from the screw holes 273 and 274 in the axial direction of the movable body 160. That is, the communication holes 293 and 294 are formed so as to be gradually reduced in diameter as they are separated from the screw holes 273 and 274.

  The heads 296a and 297a of the countersunk screws 296 and 297 have a tapered shape that gradually narrows toward the screw portions 296b and 297b. Further, the communication holes 293 and 294 extend from the heads 296a and 297a at any position within the communication holes 293 and 294 when the screw portions 296b and 297b are inserted into the communication holes 293 and 294, respectively. Engagement with the portions 286 and 287 (that is, overlap in the axial direction of the screw portions 296b and 297b) is ensured. For this reason, when the countersunk screws 296, 297 are screwed in the state of being inserted into the communication holes 293, 294, the countersunk screws 296 are formed on the side where the inner diameter is expanded in the communication holes 293, 294, that is, on the screw holes 273, 274 side. , 297 will be guided. That is, guide means for guiding the countersunk screws 296, 297 to a predetermined fastening position CP is configured by the inclination of the communication holes 293, 294 and the inclination of the heads 296a, 297a of the countersunk screws 296, 297.

  For example, when the first housing component 260 and the second housing component 280 are joined, the two housing components 260 and 280 are not arranged at the specific combination position described above due to work variation or the like. There is a possibility that the mounting work of the countersunk screws 296 and 297 may be performed. Even in such a case, a normal coupling operation can be performed by aligning the two housing components 260 and 280 based on the screwing operation of the countersunk screws 296 and 297.

  Specifically, the countersunk screws 296 and 297 are slid through the communication holes 293 and 297 by inserting the screw screws 296 and 297 into the extended portions of the communication holes 293 and 294 and performing screwing. When the screw portions 296b and 297b reach a position where the screw portions 296b and 297b fit into the screw holes 273 and 274 during the sliding movement, the screw portions 296b and 297b and the screw holes 273 and 274 are engaged with each other. In this state where the screw portions 296b and 297b and the screw holes 273 and 274 are engaged with each other, the countersunk screws 296 and 297 are further screwed in so that at least one of the first housing component 260 and the second housing component 280 becomes the solenoid 110. As a result, the relative positions of the two housing components 260 and 280 change. That is, based on the operation of screwing the countersunk screws 296, 297, the positional variation of both housing components 260, 280 is gradually corrected, and when the screwing operation is completed, the alignment of both housing components 260, 280 is completed. Completed state. Thereby, it is easy to tolerate the work variation of the combination work of the housing components 260 and 280, and the complication of the connecting work of the housing components 260 and 280 is suppressed.

  As described in detail above, in the state where the solenoid driving unit 170, the first defining unit 210, the second defining unit 230, the first housing component 260 and the second housing component 280 are integrated, both the defining units 210, 230 and the housing 250 constitute a magnetic circuit. Specifically, as already described, the defining portions 210 and 230 and the housing 250 are made of a magnetic material, and a magnetic circuit for passing the magnetism generated in the solenoid driving portion 170 (specifically, the exciting coil 171) is formed by these various configurations. Yes. That is, the defining portions 210 and 230 have both a function of restricting the moving direction of the movable body 160 and a function as a “yoke” that constitutes the magnetic circuit, and the housing 250 is a function of integrating various configurations. And a function as a “yoke” constituting the electromagnetic circuit. Focusing on the fact that a magnetic circuit is formed by the defining portions 210 and 230 and the housing 250 and the magnetic field generated in the solenoid driving portion 170 is reinforced, the solenoid driving portion 170 and the defining portions 210 and 230 and the housing 250 are movable. It can also be said that “driving means” for driving the body 160 is configured.

  Here, the magnetic circuit MC formed in the solenoid 110 will be described with reference to FIG. 10 again. In FIG. 10, an example of the magnetic circuit MC is indicated by a two-dot chain line.

  The magnetic circuit MC is formed so as to be symmetric with respect to the central axis X2 of the movable body 160, and the magnetic circuit MC having an annular shape on the base 281 side of the second housing component 280 and the second housing component The magnetic circuit MC is roughly divided into a ring-shaped magnetic circuit MC on the facing portion 285 side of the H.280. The boundary on the side of the central axis X in the magnetic circuit MC, that is, the shortest distance from the central axis X is defined by the position of the inner wall of the opening 239 in each of the defining portions 210 and 230. As described above, the restricting portions 217 and 237 are protruded toward the central axis X side, and the overlap between the magnetic circuit MC and the plunger 162 is defined by the distance between the central axis X and the openings 220 and 240, whereby the dynamic characteristics of the solenoid 110 are determined. The changes are made easy. The magnetic circuit MC is configured such that an attractive force is generated between the first defining portion 210 (specifically, the throttle portion 217) and the plunger 162 when the exciting coil 171 is energized to generate magnetism. Hereinafter, the operation of the solenoid 110 will be briefly described.

  When the exciting coil 171 is not energized, no attractive force is generated between the throttle 217 and the plunger 162. For this reason, the movable body 160 is in a state of being pressed against the aperture 237 of the second defining portion 230 by the urging force of the coil spring 169, that is, in a standby state at the initial position (see FIG. 10).

  When the exciting coil 171 is energized and magnetism is generated, the plunger 162 is attracted to the throttle part 217 side of the first defining part 210. In such a case, the movable body 160 moves to the first defining portion 210 side against the urging force of the coil spring 169.

  When the movable body 160 moves based on the above-described suction force, the coil spring 169 contracts, and the force that pushes the throttle portion 217 of the first defining portion 210 toward the firing rail 120 increases. That is, the load is increased with respect to the first defining portion 210 so as to displace the first defining portion 210 toward the firing rail 120 side.

  The flange portion 221 of the first defining portion 210 is in contact with the holding portion 261 of the first housing 260. For this reason, the force applied to the throttle portion 217 is transmitted to the first housing 260 via the large diameter portion 218 and the flange portion 221 of the first defining portion 210. The force transmitted to the first housing 260 in this way is transmitted to the second housing 280 via the countersunk screws 296 and 297. That is, the force generated when the movable body 160 moves based on the suction force acts to push the entire solenoid 110 toward the firing rail 120 side. As described above, the stress applied to the first defining portion 210 is distributed and received by the housing 250 or the like, so that the load is prevented from being concentrated on the first defining portion 210.

  Further, as described above, the second housing 280 is in contact with the flange portion 241 of the second defining portion 230 and the bobbin 181 of the solenoid driving portion 170. For this reason, the force transmitted to the second housing 280 is transmitted to the second defining portion 230 and the bobbin 181 of the solenoid driving portion 170 via the facing portion 285 of the second housing 280 and the holding portion 282 of the second housing 280. It becomes. That is, the second defining part 230 and the bobbin 181 are pushed toward the firing rail 120 by the holding part 282 of the second housing 280.

  As described above, when the second defining portion 230 and the bobbin 181 are moved to the same side as the side where the first defining portion 210 is pressed based on the movement of the movable body 160, the first defining portion 210 and the second defining portion 230 are moved. In addition, it is possible to suppress the relative position with respect to the bobbin 181 from changing. That is, due to the force generated with the movement of the movable body 160, the shift between the center axis X3 of the first defining portion 210 and the center axis X4 of the second defining portion 230, and the center axes of the defining portions 210 and 230 It is possible to suppress the deviation between X3 and X4 and the central axis X1 of the solenoid driving unit 170.

  When the supply of electric power to the exciting coil 171 is stopped, the above-described attractive force disappears. As the suction force disappears in this way, a force against the biasing force of the coil spring 169 does not act, and the movable body 160 moves to the second defining portion 230 side based on the biasing force of the coil spring 169. . When the movable body 160 reaches the initial position, the rubber ring 168 comes into contact with the throttle portion 237 of the second defining portion 230, and the movement of the movable body 160 stops (see FIG. 10).

  When the movable body 160 moves to the second defining portion 230 side based on the biasing force of the coil spring 169 described above, the throttle portion 237 of the second defining portion 230 and the rubber ring 168 of the movable body 160 come into contact with each other. The force which pushes the said narrowing part 237 to the opposite side to the firing rail 120 with respect to the narrowing part 237 of the 2nd prescription | regulation part 230 will be added. That is, a load is applied to the second defining portion 230 so as to displace the second defining portion 230 away from the firing rail 120.

  The flange portion 241 of the second defining portion 230 is in contact with the holding portion 282 of the second housing 280. For this reason, the force applied to the throttle portion 237 is transmitted to the second housing 280 via the large diameter portion 238 and the flange portion 241 of the second defining portion 230. The force transmitted to the second housing 280 in this way is transmitted to the first housing 260 via the facing portion 285, the countersunk screws 296, 297, and the like. That is, the force generated when the movable body 160 moves based on the biasing force of the coil spring 169 acts to push the entire solenoid 110 away from the firing rail 120. In this way, by receiving the force applied to the second defining portion 230 in a distributed manner by the housing 250 or the like, it is avoided that the load is concentrated on the second defining portion 230.

  Further, as described above, the first housing 260 is in contact with the flange portion 221 of the first defining portion 210 and the bobbin 181 of the solenoid driving portion 170. For this reason, the force transmitted to the first housing 260 is transmitted to the first defining portion 210 and the bobbin 181 of the solenoid driving portion 170 via the holding portion 261 of the first housing 260. In this case, the first defining part 210 and the bobbin 181 are pushed away from the firing rail 120. As described above, when the first defining portion 210 and the bobbin 181 are pushed on the same side as the side on which the second defining portion 230 is pushed based on the movement of the movable body 160, the first defining portion 210, the second defining portion 230, It is possible to prevent the relative position with respect to the bobbin 181 from changing. In other words, due to the force generated as the movable body 160 moves, the center axis line X3 of the first defining portion 210 and the center axis line X4 of the second defining portion 230 are shifted, and the center axis lines X3, X4 of the defining portions 210, 230. And the center axis line X1 of the solenoid drive unit 170 can be prevented from occurring.

  Next, the assembly work of the solenoid 110 will be described with reference to FIG. When assembling the solenoid 110, the work is performed in the order of FIG. 13 (a) → FIG. 13 (b) → FIG. 13 (c) → FIG. 13 (d).

  First, as shown in FIG. 13A, the movable body 160 is inserted into the cylindrical portion 182 of the solenoid driving portion 170. At this time, the coil spring 169 is inserted through the shaft 161 together.

  Thus, after combining the solenoid drive part 170 and the movable body 160, the 1st prescription | regulation part 210 and the 2nd prescription | regulation part 230 are installed with respect to the solenoid drive part 170 (specifically bobbin 181). Specifically, the shaft 161 of the movable body 160 is passed through the bearing hole 212 of the first defining portion 210, the first defining portion 210 is pushed in the axial direction of the movable body 160, and the bearing hole 232 of the second defining portion 230 is pushed. Through the shaft 161, and the second defining portion 230 is pushed in the axial direction of the movable body 160 (see FIG. 13B).

  When the two defining portions 210 and 230 are pushed to a position where they contact the bobbin 181, the flange portions 221 and 241 of the defining portions 210 and 230 are fitted into the installation portions 187 and 188 of the bobbin 181. In this state, the rubber ring 168 of the movable body 160 contacts the throttle portion 237 of the second defining portion 230, and the coil spring 169 is slightly compressed.

  Next, as shown in FIG. 13C, the integrated movable body 160, solenoid drive unit 170, first defining unit 210, and second defining unit 230 are mounted on the housing 250. Specifically, first, the second housing component 280 is pushed toward the bobbin 181 in a state where the large diameter portion 238 of the second defining portion 230 is fitted in the insertion hole 283. When the second housing component 280 is pushed to a predetermined mounting position, the flange portion 241 of the second defining portion 230 is fitted into the fitting portion 284 of the second housing component 280, and the holding portion of the second housing component 280 282 contacts the flange portion 184 of the bobbin 181. As a result, the second housing component 280 is combined with the solenoid driving unit 170 and the second defining unit 230.

  The first housing 250 is pushed into the bobbin 181 side with the large-diameter portion 218 of the first defining portion 210 fitted in the insertion hole 262. When such pushing is performed, the contact portions 264 and 265 of the first housing component 260 and the protrusions 266 to 269 are in contact with the extending portions 286 and 287 of the second housing component 280. Thus, the assembly variation of the first housing component 260 is suppressed. When the first housing component 260 is pushed to a predetermined mounting position, the protrusions 266 to 269 hit the positioning portions 288 to 291 of the second housing component 280. As a result, no further pushing operation is possible. As described above, when the first housing component 260 is pushed to a predetermined mounting position, the flange portion 221 of the first defining portion 210 is fitted into the fitting portion 263 of the first housing component 260, and the first housing component is assembled. The holding portion 261 of 260 is in contact with the flange portion 183 of the bobbin 181.

  After the various components are combined as shown in FIG. 13C, the first housing component 260 and the second housing component 280 are coupled by the countersunk screws 296 and 297. When performing such work, there is a concern that the relative positions of the first housing component 260 and the second housing component 280 are likely to deviate from a predetermined combination position due to the biasing force of the coil spring 169 and the like. In this respect, in the present embodiment, based on the screwing operation of the countersunk screws 296, 297, the positional displacement of the screw holes 273, 274 of the first housing component 260 and the communication holes 293, 294 of the second housing component 280 is achieved. Will be corrected. Accordingly, it is possible to avoid the positional deviation between the two housing components 260 and 280 as described above, and it is preferable to hold (clamp) various configurations using the two housing components 260 and 280. Can do. Finally, by attaching the contact member 167 to the tip of the shaft 161, the assembly work of the solenoid 110 is completed (see FIG. 13D).

  The game ball is fired in the game ball launching apparatus 100 described in detail above as follows. When the player operates the handle device 59, the handle operation amount is detected by a sensor or the like, and the detection signal is input to the launch control device 83. The firing control device 83 outputs a control signal corresponding to the detection signal to the solenoid driving unit 170, and the solenoid driving unit 170 generates an electromagnetic attractive force according to the control signal of the firing control device 83. The plunger 162 is pushed out to the game ball B side by this electromagnetic attractive force. When the movable body 160 is pushed out, the contact member 167 comes into contact with the game ball B held at the firing standby position. Thereby, the game ball B is launched along the launch rail 120. The launched game ball B moves on the launch rail 120 and is launched toward the game area. After the game ball B has been launched, the movable body 160 is pushed back to the initial position by the biasing force of the coil spring 169.

  Next, the electrical configuration of the pachinko machine 10 will be described based on the block diagram of FIG. In FIG. 14, a power supply line is indicated by a double line arrow, and a signal line is indicated by a solid line arrow.

  A main control board 300 provided in the main control device 63 incorporates a main control circuit 302 and a power failure monitoring circuit 303. The main control circuit 302 is equipped with an MPU 304. The MPU 304 is a ROM 305 that stores various control programs executed by the MPU 304 and fixed value data, and a memory that temporarily stores various data when the control program stored in the ROM 305 is executed. A certain RAM 306 and various circuits such as an interrupt circuit, a timer circuit, and a data input / output circuit are incorporated.

  The MPU 304 is provided with an input port and an output port. Connected to the input side of the MPU 304 are a power failure monitoring circuit 303 provided on the main control board 300, a payout control board 311 provided on the payout control device 82, and other switches not shown. In this case, a power / fire control board 315 provided in the power / fire control device 83 is connected to the power failure monitoring circuit 303, and power is supplied to the MPU 304 via the power failure monitoring circuit 303.

  On the other hand, a power failure monitoring circuit 303, a payout control board 311 and a relay terminal board 319 are connected to the output side of the MPU 304. Various commands such as a prize ball command are output to the payout control board 311. Various commands and the like are output from the main control circuit 302 to the sound lamp control board 321 provided in the sound lamp control device 66 via the relay terminal board 319.

  The power failure monitoring circuit 303 relays between the main control circuit 302 and the power / fire control board 315, and monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power / fire control board 315.

  The payout control board 311 performs payout control of prize balls and rental balls by the payout device 78. The MPU 312 that is an arithmetic unit includes a ROM 313 that stores a control program executed by the MPU 312, fixed value data, and the like, and a RAM 314 that is used as a work memory or the like.

  An input / output port is provided in the MPU 312 of the payout control board 311. The main control circuit 302, the power / fire control board 315, and the back pack board 79 are connected to the input side of the MPU 312. Further, the main control circuit 302 and the back pack substrate 79 are connected to the output side of the MPU 312.

  The power / launch control board 315 includes a power source unit 316 and a launch control unit 317. The power supply unit 316 is connected to, for example, a commercial power supply (external power supply) in a game hall or the like. Then, based on the external power supplied from the commercial power supply, necessary operating power is generated for each of the main control circuit 302, the payout control board 311 and the like, and the generated operating power is indicated by a double line arrow. This is supplied to the main control circuit 302, the payout control board 311 and the like through the route. The launch control unit 317 is responsible for launch control of the game ball launch device 100, and the game ball launch device 100 is driven when predetermined launch conditions are met.

  The sound lamp control board 321 controls the display control device 325. The MPU 322, which is an arithmetic unit, includes a ROM 323 that stores a control program executed by the MPU 322, fixed value data, and the like, and a RAM 324 that is used as a work memory or the like.

  An input / output port is provided in the MPU 322 of the sound lamp control board 321. A main control circuit 302 is connected to the input side of the MPU 322 through a relay terminal board 319 and controls the display control device 325 based on various commands output from the main control circuit 302. The display control device 325 controls the symbol display device 41 based on a display command input from the sound lamp control board 321.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The solenoid 110 is configured to have defining portions 210 and 230 that define the moving direction of the movable body 160. Thereby, the operation of the movable body 160 can be stabilized. Specifically, the gap (so-called air gap) between the magnetic circuit MC (specifically, the defining portions 210 and 230 and the housing 250) and the plunger 162 is prevented from varying every time the movable body 160 operates, thereby stabilizing the magnetic circuit MC. It is possible to obtain the magnetic characteristics (dynamic characteristics).

  The defining portions 210 and 230 (specifically, bearings 212 and 232) are configured to be installed on the bobbin 181 of the solenoid driving portion 170. Specifically, the flange portions 221 and 241 of the defining portions 210 and 230 are fitted to the installation portions 187 and 188 of the bobbin 181. As described above, the configuration in which the defining portions 210 and 230 are directly installed on the bobbin 181 is movable with the central axis X1 of the solenoid driving portion 170 (specifically, the exciting coil 171) due to accumulation of dimensional tolerances and the like. Occurrence of positional variations (center misalignment, inclination, etc.) with respect to the central axis X2 of the body 160 can be suppressed. Thereby, it can suppress that the movable body 160 is attracted | pulled in the direction which cross | intersects the central axis X2 of the said movable body 160 with the attraction | suction force which generate | occur | produces in the solenoid drive part 170 mentioned above. Therefore, it is possible to effectively use the power supplied to the coil to increase the launch efficiency of the game ball.

  The end surface 163 of the plunger 162 and the inner surface 217a of the throttle portion 217 are configured to form a plane perpendicular to the central axis X. Thereby, in a specific range including the position where it hits the game ball in the entire operation range of the movable body 160, it is possible to suppress a change in magnetic characteristics (dynamic characteristics).

  More specifically, for example, the end surface 163 of the plunger is changed to be convex toward the inner surface 217a side of the throttle portion 217, and the inner surface 217a of the throttle portion 217 is changed to be concave corresponding to the end surface 163 of the plunger. It is also possible. However, when such a change is made, in a specific range including the position where it hits the game ball in the entire operation range of the movable body 160, the magnetic characteristics gradually decrease as the game ball approaches. Become. This is not preferable because it can be difficult to make the voltage applied to the excitation coil 171 proportional to the attractive force generated in the solenoid driving unit 170. In this regard, by adopting a configuration that suppresses changes in dynamic characteristics depending on the position of the movable body 160 as described above, the voltage applied to the excitation coil 171 and the attractive force generated in the solenoid driving unit 170 can be easily made proportional. it can. Therefore, it is easy to realize a configuration in which the operation amount when the handle device 59 is operated and the firing speed have a certain proportional relationship.

  The first defining portion 210 is sandwiched between the flange portion 183 of the bobbin 181 and the holding portion 282 of the second housing component 280 when the assembly of the solenoid 110 is completed. Similarly, the second defining portion 230 is sandwiched between the flange portion 184 of the bobbin 181 and the holding portion 261 of the first housing component 260. In this way, by sandwiching the defining portions 210 and 230 by the bobbin 181 and the housing components 260 and 280, the movement of the defining portions 210 and 230 can be restricted with a simple structure. For example, by using fixing means such as caulking or adhesive, the work process related to the assembly can be simplified as compared with the configuration in which the defining portions 210 and 230 are fixed.

  In the present embodiment, the flange portions 221 and 241 of the defining portions 210 and 230 are fitted in the space defined by the fitting portions 263 and 284 of the housing components 260 and 280 and the installation portions 187 and 188 of the bobbin 181. Therefore, the relative position shifts are regulated, and the defining portions 210 and 230, the bobbin 181 and the housing components 260 and 280 are not completely fixed. For this reason, when the solenoid 110 is driven, the movable body 160 reciprocates, so that a load in the direction along the central axis X is applied to both the throttle portions 217 and 237. Even when the structural members 260 and 280 are deformed, it is possible to suppress the occurrence of inconvenience such as distortion of the defining portions 210 and 230 due to the deformation. Thereby, it is easy to secure the guide function of the shaft 161 by the defining portions 210 and 230.

  As described above, in the configuration in which the defining portions 210 and 230 and the housing structural bodies 260 and 280 are fitted, the influence of variations in the relative positions of the first housing structural body 260 and the second housing structural body 280 is affected by the defining portions 210 and 230. In addition, there is a concern that the coaxiality between the center axis X3 of the first defining portion 210 and the center axis X4 of the second defining portion 230 is lowered. Such inconvenience is caused, for example, by a deviation generated due to assembly variation between the two housing components 260 and 280 being transmitted to the bobbin 181 via the defining portions 210 and 230, and a stress such as torsion is applied to the bobbin 181. It is assumed that it occurs when it occurs. In this regard, in the present embodiment, since the combination direction of both housing components 260 and 280 is configured to be the same as the axial direction of the solenoid 110, the housing components 260 and 280 are temporarily arranged. Even if the assembly varies, it is difficult to cause the above-described inconveniences, and the center axis lines X3 and X4 of both the bearings 211 and 231 can be suppressed from shifting. That is, it is possible to suppress a decrease in the coaxiality of the central axes X3 and X4.

  Further, by arranging the combination direction of various components such as the housing component 260 so as to be the same as the axial direction of the solenoid 110, it contributes to simplification of the assembly work of the solenoid 110.

  By abutting against the movable body 160, a function as a “stopper portion” for stopping the movement of the movable body 160 in the axial direction is given to the defining portions 210 and 230, and the defining portion is connected to the bobbin 181 and the housing 250. Was provided separately. In this way, by providing a separate portion where the load is likely to be applied as the movable body 160 is driven, it is easy to reuse other peripheral parts when replacing parts accompanying wear or deformation. .

  Further, the defining portions 210 and 230 are configured to have the throttle portions 217 and 237 as the “stopper portions” and the bearings 211 and 231 together. By arranging the two close to each other in this way, it is easy to suppress shaking of the movable body 160 when the movable body 160 and the aperture portions 217 and 237 hit each other.

  The holding portion 261 of the first housing component 260 and the holding portion 282 of the second housing component 280 are connected via a base 281, an extending portion 286, an abutting portion 264, a countersunk screw 296, and the like. For this reason, when a load is applied to one of the holding portions 261 and 282 in the axial direction of the solenoid 110, a part of the load is transmitted to the other. A part of the load is transmitted to the bobbin 181 and the like that are in contact with the other side. As described above, the load applied to the contact portions (specifically, the fitting portions 263 and 284) between the defining portions 210 and 230 and the housing components 260 and 280 is distributed and received by the entire solenoid 110, thereby contacting the contact portions. The load is concentrated on the part.

  Both holding portions 261 and 282 are connected on both sides of the central axis X of the solenoid 110. For this reason, it is possible to suppress a bending moment from being generated with respect to the solenoid 110 as a load is transmitted from one of the holding portions 261 and 282 to the other. This makes it difficult for the bobbin 181 and the defining portions 210 and 230 to be distorted.

  In the configuration in which the defining portions 210 and 230 have the throttle portions 217 and 237 as “stoppers”, the defining portions 210 and 230 come off from the housing 250 (specifically, the fitting portions 263 and 284) when the load increases. Inconvenience can occur. In this respect, in the present embodiment, as described above, the load generated when the movable body 160 is driven is received in a distributed manner throughout the solenoid 110, so that such inconveniences are suitably suppressed. It is possible.

  In addition, it is not limited to the description content of embodiment mentioned above, For example, you may implement as follows. Incidentally, the configuration of the following different embodiment may be applied individually to the configuration in the above embodiment, or may be applied in combination with each other.

  (1) In the above embodiment, the first defining part 210 has the first bearing 211 and the first holder 215, but the present invention is not limited to this. For example, the first defining unit 210 may not have the first holder 215. When such a change is made, a configuration corresponding to the throttle unit 217 may be provided in the bobbin 181 or the first housing component 260. Similarly, the second holder 235 can be omitted for the second defining portion 230.

  (2) In the above embodiment, the housing 250 is constituted by the two parts of the first housing component 260 and the second housing component 280, but the number of members constituting the housing is not limited to two. . For example, the housing can be configured by using three or more parts. However, an increase in the number of parts can lead to complication of the assembly work of the solenoid 110 and easily cause a decrease in strength of the housing. In this respect, as shown in the above-described embodiment, by forming the housing 250 with two parts, it is possible to suppress the occurrence of the above-described disadvantages and realize a practically preferable configuration.

  (3) In the above-described embodiment, the solenoid drive unit 170 and the housing 250 are integrated to make it impossible to remove the defining portions 210 and 230. However, this may be changed as follows. Is possible. That is, it may be configured such that the respective defining portions 210 and 230 cannot be removed by coupling the defining portions 210 and 230 and the solenoid driving portion 170 (specifically, the bobbin 181). For example, it may be coupled using a fastener such as a screw or an adhering means such as an adhesive, or may be coupled using a coupling method such as caulking. However, if the defining portions 210 and 230 and the bobbin 181 are completely fixed as described above, it is assumed that if the torsion or the like occurs in the bobbin 181, the influence easily reaches the defining portions 210 and 230. This is not preferable because the friction between the movable body 160 and the shaft 161 is locally increased, and the wear of the shaft 161 and the like can be accelerated. Therefore, it is preferable that each of the defining portions 210 and 230 and the solenoid driving portion 170 is not coupled as shown in the present embodiment.

  (4) In the above embodiment, the bobbin 181 is provided with the concave installation portions 187 and 188, and the defining portions 210 and 230 are provided with the convex flange portions 221 and 241, and the installation portions 187 and 188 and the flange portion 221 are provided. , 241 are fitted to each other so that each of the defining portions 210, 230 is installed. You may change this as follows. In other words, the bobbin 181 may be provided with a convex installation portion, and the defining portions 210 and 230 may be provided with concave attachment portions corresponding to the installation portions. In other words, the installation portion is not limited to a concave shape, and is arbitrary, and any configuration that can install at least the defining portion at a predetermined installation location is sufficient.

  (5) In the above-described embodiment, the bearings 211 and 231 are disposed outside the cylindrical portion 182 of the bobbin 181, but it is also possible to change the bearings 211 and 231 within the cylindrical portion 182. . However, when such a change is made, it is difficult to secure spans of both bearings. This is not preferable because it may be a factor that hinders the improvement of the straight running stability of the movable body 160. Therefore, the bearings 211 and 231 are desirably arranged outside the cylindrical portion 182.

  (6) In the above-described embodiment, the defining portions 210 and 230 are sandwiched between the solenoid driving portion 170 (specifically, the bobbin 181) and the housing components 260 and 280. However, the present invention is not limited to this. It is only necessary that the defining portions 210 and 230 be restricted from moving (for example, being removed or displaced) from the state in which the bobbin 181 is installed with respect to the installation portions 187 and 188. It is not necessary to be pinched by 280.

  (7) In the above embodiment, the fitting parts 263 and 284 are provided in the housing components 260 and 280, and the fitting parts 263 and 284 and the flange parts 221 and 241 of the defining parts 210 and 230 are fitted. The configuration. That is, when the fitting portions 263 and 284 and the flange portions 221 and 241 are fitted, the relative movement of the defining portions 210 and 230 and the housing components 260 and 280 in the direction intersecting the moving direction of the movable body 160 is achieved. The configuration is regulated. You may change this as follows. That is, the flange portions 221 and 241 do not protrude from the installation portions 187 and 188 of the bobbin 181, and the fitting portions 263 and 284 are omitted, and instead of the defining portions 210 and 230 and the housing components 260 and 280. You may provide the control part which controls relative movement separately. For example, the above-described relative movement may be restricted by fitting the insertion holes 262 and 283 of the housing components 260 and 280 with the large-diameter portions 218 and 238 of the defining portions 210 and 230, respectively.

  (8) In the above embodiment, the first defining part 210 and the second defining part 230 are provided. However, either one of the two defining parts 210 and 230 can be omitted. However, when making such a change, in order to stabilize the operation of the movable body 160, it may be necessary to set the length of the contact portion between the bearing and the shaft 161 in the axial direction of the movable body 160 large. This is not preferable because it may be difficult to ensure the accuracy of the bearing and may promote uneven wear between the bearing and the movable body 160. Therefore, it is preferable that a plurality of defining portions be provided, and the respective defining portions be arranged apart from each other.

  (9) In the above embodiment, the installation portions for installing the defining portions 210 and 230 are provided on the flange portions 183 and 184 of the bobbin 181. However, the present invention is not limited to this. For example, it is possible to provide an installation part in the cylindrical part of the bobbin.

  (10) In the above embodiment, the combination direction of the first housing component 260 and the second housing component 280 is configured to be the same as the axial direction of the solenoid drive unit 170. However, the first housing and the second housing The combination direction is arbitrary. For example, as shown in FIG. 15A, the combination direction of the first housing 330 and the second housing 340 is a radial direction of the central axis X of the solenoid drive unit 170 (that is, a direction orthogonal to the central axis X). Also good.

  (11) In the above-described embodiment, the bearings 211 and 231 are integrated with the holders 215 and 235 by caulking and fixing the bearings 211 and 231 while being press-fitted into the holders 215 and 235. By changing this, both of them may be integrated by a fixing means such as adhesion, or may be integrally formed by injecting a synthetic resin material into the holders 215 and 235.

  Moreover, although both housing structure 260,280 was integrated by the countersunk | screw 296,297, it is also possible to integrate by welding etc., for example.

  (12) In the above embodiment, the first housing component 260 and the second housing component 280 are arranged so that the first housing component 260 is on the firing rail 120 side. However, the present invention is not limited to this. . As shown in FIG. 15B, the first housing component 260 and the second housing component 280 can be arranged such that the second housing component 280 is on the firing rail 120 side.

  (13) In the above embodiment, the coil spring 169 is disposed in the space defined by the first defining portion 210 and the bobbin 181 (specifically, the first partitioned space DS1). It is also possible to arrange it outside the space defined by the defining portion 210 and the bobbin 181.

  (14) In the above-described embodiment, the bearings 211 and 231 and the bobbin 181 are formed separately. However, the bearings 211 and 231 and the bobbin 181 may be integrally formed.

  (15) In the above embodiment, the second housing structural body 280 has the facing portion 285. However, the facing portion 285 can be omitted. That is, it is not necessary that the portions connecting the holding portion 261 of the first housing 260 and the holding portion 282 of the second housing 280 are on both sides of the central axis X of the solenoid 110. It is only necessary to provide at least a portion where the holding portions 261 and 282 are connected.

  (16) In the above embodiment, the two housing components 260 and 280 are coupled by the countersunk screws 296 and 297. However, this may be changed as follows. That is, the “joining means” for joining both of them is arbitrary. For example, an adhesive or the like may be used, or both of them may be provided by having a latching portion or the like hooked to each other. A configuration in which the housing components 260 and 280 are integrated may be employed.

  (17) In the above embodiment, the solenoid drive unit 170 is surrounded by the housing 250, but the present invention is not limited to this. For example, the solenoid drive unit 170 is not enclosed by the housing 250, but is provided separately and sandwiched from both sides in the axial direction of the solenoid drive unit 170 by a set of housing components. The portion 170 may be completely exposed in the radial direction of the central axis X. Furthermore, it is good also as a structure which avoids exposure of the solenoid drive part 170 by forming a housing in box shape and storing the solenoid drive part 170 in the inside.

  Further, the base portion 281, the facing portion 285, etc. so as to connect the holding portion 261 of the first housing component 260 and the holding portion 282 of the second housing component 280 on both sides of the central axis X of the solenoid driving unit 170. Various configurations were provided. It is good also as a structure which these both holding | maintenance parts 261 and 282 connect only on the one side of the central axis X by changing this. For example, the facing portion 285 and the extending portion 287 of the second housing component 280 may be omitted. However, when such a change is made, the first housing component 260 and the second housing component 280 are connected only on the base 281 side, so that one of the holding portions 261 and 282 is connected to the central axis X. When the load along is applied, the load is transmitted to the other of the holding portions 261 and 282 while generating a bending moment. The generation of such a bending moment is not preferable because it may cause a distortion or the like in the solenoid drive unit, the movable body 160, and the defining units 210 and 230 held between the two housing components 260 and 280. Therefore, it is preferable that the holding portions 261 and 282 are connected on both sides of the central axis X.

  (18) In the above embodiment, the defining portions 210 and 230 have the throttle portions 271 and 237 as “stoppers”, but the “stopper” can be moved to another configuration. For example, a portion corresponding to the stopper portion may be provided on the bobbin 181 or the housing components 260 and 280. However, if the distance between the stopper portion and the bearings 211 and 231 is increased, the movable body 160 may be easily shaken when the stopper portion and the movable body 160 contact each other. Such shaking of the movable body 160 is not preferable because it can cause a force (load) in a direction other than the axial direction applied to the bearings 211 and 231 to increase. Therefore, as shown in the above-described embodiment, it is preferable that the defining portions 210 and 230 have both the bearings 211 and 231 and the stopper portion.

  (19) In the above embodiment, the housing 250 is configured to have both a function of mounting various configurations such as the solenoid driving unit 170 and the defining units 210 and 230 and a function of forming a magnetic circuit. And a magnetic circuit structure forming a magnetic circuit may be provided separately and independently.

  (20) Other types of pachinko machines different from the above-described embodiments, such as pachinko machines in which an electric accessory is released a predetermined number of times when a game ball enters a specific area of a special device, or games in a specific area of a special device The present invention can also be applied to a pachinko machine that generates a big hit when a ball enters, a pachinko machine equipped with another accessory, an arrangement ball machine, a sparrow ball, and the like.

<Invention Group Extracted from the Embodiments>
Hereinafter, the features of the invention group extracted from the above-described embodiment will be described while showing effects and the like as necessary. In the following, for ease of understanding, the corresponding configuration in the above embodiment is appropriately shown in parentheses, but is not limited to the specific configuration shown in parentheses.

Feature A1. A movable body (movable body 160) capable of linear reciprocation;
It has a coil (excitation coil 171) that forms a magnetic field by being energized and applies power to the movable body, and an insertion portion (inside the cylindrical portion 182) through which the movable body is inserted, and the outer periphery of the insertion portion A drive unit (for example, solenoid drive unit 170 or housing 250) provided with a body (bobbin 181) around which the coil is wound;
A housing (housing 250) which is provided outside the driving unit and to which the driving unit is attached;
It is formed so as to come into contact with the movable body, and includes a defining portion (regulating portion 210, 230) that defines the moving direction of the movable body,
The game machine characterized in that the defining portion is held in a state of being sandwiched between the main body and the housing.

  According to the feature A1, it is possible to generate a magnetic field by energizing the coil and generate a power (for example, an attractive force) for moving the movable body by the magnetic field. For example, by placing a game ball on a trajectory along which the movable body moves, it is possible to realize the launch of the game ball by the movable body. Further, the moving direction of the movable body is determined by the defining portion. Thereby, it is possible to suppress the deviation of the relative position between the trajectory through which the movable body passes and the drive unit (specifically, the coil).

  When the movable body reciprocates, it is assumed that a load or the like based on vibration of the drive unit, the housing, or the like is generated. If the configuration in which the defining portion is coupled to the main body, the housing, etc. is adopted, it is assumed that if the displacement (deformation or misalignment) or the like occurs in the main body portion or the housing due to the above-described load, the influence will easily reach the defining portion. The This is considered not preferable from the viewpoint of ensuring the straight running stability of the movable body. In this regard, according to the present feature, since the defining portion is not coupled to the main body or the like but is sandwiched between the main body and the housing, it is possible to easily suppress the above-described influence on the defining portion. . Thereby, it can suppress that distortion etc. arise with respect to a prescription | regulation part, and can ensure the efficiency at the time of a movable body moving. Therefore, for example, it is possible to increase the launch efficiency of game balls.

  The “defining part” may be configured by a bearing or the like in which a movable body is inserted, for example, in a cylindrical shape.

Feature A2. The defining portions are respectively disposed on both sides of the main body in the axial direction of the insertion portion,
The housing is formed so as to sandwich the main body in the axial direction of the insertion portion,
Each said prescription | regulation part is hold | maintained in the state pinched | interposed by the said main body and the said housing, The game machine of A1 characterized by the above-mentioned.

  According to the feature A2, it is possible to widen the interval between the portions that define the movement of the movable body. Thereby, the straight running stability of the movable body in at least the insertion portion can be improved.

  Further, in the configuration in which the movable body reciprocates, it is assumed that any of the restricting portions is easily affected by the load as described above. In the configuration having a plurality of defining portions, it is possible to improve the straight running stability as described above, but it is assumed that the resistance accompanying the operation of the movable body is likely to increase due to the relative position of these defining portions changing. . In this respect, the configuration in which each defining portion is sandwiched by the combination with the feature A1 makes it easy to suppress the displacement of the relative position of each defining portion, which can contribute to the realization of a practically preferable configuration.

  In addition, when a configuration having a plurality of defining parts is adopted, the above-described excellent effects can be enjoyed, but on the other hand, work for individually regulating the removal of each of the defining parts is required, and the work becomes complicated. Then there is concern. In this regard, by adopting a configuration in which both the defining portions are sandwiched by the housing and the main body, the operation of restricting the removal of the defining portions can be simplified, and the above-described disadvantages can be eliminated.

Feature A3. The housing has a pair of housing structural bodies (first housing structural body 260 and second housing structural body 280) provided individually corresponding to the respective defining portions,
Each said prescription | regulation part is hold | maintained in the state pinched | interposed between each said housing structure and the said main body, The game machine of A2 characterized by the above-mentioned.

  It is assumed that the following inconvenience is likely to occur if a configuration is adopted in which a defining portion provided on both sides of the main body is held by one housing component while being sandwiched between the main body. That is, due to the accumulation of the dimensional tolerance of the housing, the dimensional tolerance of the main body, and the dimensional tolerance of each specified portion, the housing and the specified portion are supported and it becomes difficult to mount the same housing, or the housing and the main body are specified. It is assumed that it is difficult to secure the holding accuracy in the configuration in which the portion is sandwiched and held. In this regard, as shown in this feature, by constructing the housing with a pair of housing components, when the housing components are attached, the accumulated variation in the dimensional tolerance is allowed, and the above-described disadvantages are avoided. It can be difficult to occur. That is, it is possible to easily secure the holding function of the defining portion while facilitating the housing mounting operation.

  Feature A4. The gaming machine according to A3, wherein the two housing components are configured such that a combination direction of the housing components is the same as an axial direction of the insertion portion.

  In the configuration in which the drive unit and the defining unit are sandwiched by combining the housing components, it is possible to suppress complication of the assembling work by aligning the moving direction of the movable body and the combination direction of the housing.

  Further, the effect shown in the feature A3 can be made more remarkable. That is, by combining the housing components from both sides in the moving direction of the movable body, the relative positions of the two housing components can be corrected according to the variation in the accumulated dimensional tolerance when the two housing components are combined. It becomes even easier. Thereby, while ensuring the straight-running stability of the movable body, it is possible to more easily tolerate variations such as the dimensional tolerances described above, and a practically preferable configuration can be realized.

  Feature A5. A gaming machine according to A4, further comprising coupling means (such as countersunk screws 296, 297) for coupling the housing components.

  As shown in feature A5, the housing components are connected to each other, for example, compared to a case in which each housing component is individually connected to other parts and the like. It is possible to easily suppress the position from shifting in a direction other than the moving direction of the movable body.

  Moreover, when vibration etc. generate | occur | produce by the reciprocation of a movable body, it is thought that the load based on the vibration reaches a main body, each prescription | regulation part, and each housing structure. In particular, in such a load, it is assumed that the component in the same direction as the moving direction of the movable body (that is, the axial direction of the insertion member) tends to increase. If at least any one of the main body, each defining portion, and each housing component is displaced due to this component, the relative positions of these various components can easily vary in the above direction. Such a variation in relative position is not preferable because it may cause a decrease in the holding function of the defining portion by the main body and the housing structure, and may cause a stable stroke of the movable body.

  In this respect, in this feature, the housing components are coupled to each other by the coupling means, so that variations in the relative positions of the various configurations are suitably suppressed, and the clamping function is easily secured. Hereinafter, for the sake of convenience, the defining portion and the housing structure disposed on the front side in the direction in which the load is applied are referred to as a first defining portion and a first housing structure, respectively, and the other is a second defining portion and a second housing structure. Specific actions will be described. If a load directed to one side in the moving direction is applied to the main body or the first defining portion, at least a part of the load is transmitted to the first housing structure via the first defining portion. At least a part of the load transmitted to the first housing structure is transmitted to the second housing structure via the coupling means. If the main body or the first defining portion is displaced in a direction in which a load is applied, the first housing component and the second housing component are displaced in the same direction following the displacement. When the second housing is displaced in the same direction, the second defining portion is pushed in the same direction. In this way, the main body, each defining portion, and each housing component are integrally displaced in the same direction, so that the relative positions of the first defining portion, the main body, and the first housing component on the first defining portion side are changed. Not only the variation is suppressed, but also the relative positions of the second defining portion, the main body and the second housing component on the second defining portion side are also suppressed. Further, even when a load opposite to the above-described load is applied to the main body or the like, similarly, variations in relative positions of the various configurations on the first defining portion side, and the various types on the second defining portion side. Variation in the relative position of the configuration is suppressed. Thereby, a clamping function is ensured and it can contribute to realization of the stable reciprocation of a movable body. Moreover, it becomes possible to disperse | distribute the load mentioned above to various structures, and can suppress that load concentrates locally.

  Feature A6. The gaming machine according to A5, wherein the two housing components are coupled to each other on both sides of the central axis of the insertion portion by the coupling means.

  When a configuration in which the load generated based on the reciprocating motion of the movable body (for example, the load caused by the above vibration) is shared by both housing components is used, depending on the transmission path of the force (load), the drive unit, Bending moments that can distort the various configurations of the part and the housing can occur. Specifically, since the housing is disposed outside the drive unit, the force transmission path is separated from the central axis of the insertion unit. For this reason, it is assumed that a bending moment is likely to occur based on the transmission of force. The generation of such a bending moment is not preferable because it can be a factor that hinders the straight running stability of the movable body. In this respect, as shown in this feature, it is easy to suppress the generation of bending moment by connecting both housing components on both sides of the center axis of the insertion section, or the influence of the bending moment is affected by the main body and the specified section. Etc. can be made difficult.

  As the “coupling means”, for example, a fastener such as a screw, a coupling structure such as fitting, or a coupling method such as welding may be used.

Feature A7. A screw (a countersunk screw 296, 297) for connecting the two housing components;
The gaming machine according to any one of A3 to A6, wherein an attaching direction of the screw is set to be different from an axial direction of the insertion portion.

  According to the feature A7, the axial direction of the insertion portion and the mounting direction of the screw are different. For this reason, even if it is a case where the vibration and vibration to the same direction as the said axial direction generate | occur | produce by driving a movable body, it can suppress that a screw loosens by these vibrations. Moreover, even if it is a case where a screw loosens, it can suppress that the relative position of both the housing structural bodies in the axial direction of an insertion part changes. Thereby, the configuration shown in the feature A4 and the like can be suitably realized. That is, even when a configuration in which the defining portion is sandwiched between the housing component and the main body based on a combination of a plurality of housing components is secured, the holding function of the defining portion by the housing component and the main body is ensured. Easy to do.

  In combination with the feature A5 or the feature A6, the “screw” shown in this feature may be replaced with the “joining means” shown in the feature A5.

  Feature A8. When a force is applied to the housing to push the housing in the axial direction of the insertion hole, a transmission portion (for example, a base 281 or a countersunk screw 296) that transmits the force to the main body is provided. The gaming machine according to any one of A1 to A7.

  When vibration or the like is generated by the reciprocating motion of the movable body, it is considered that a load based on the vibration reaches the main body, each defining portion and the housing. In particular, in such a load, it is assumed that the component in the same direction as the moving direction of the movable body (that is, the axial direction of the insertion member) tends to increase. If at least one of the main body, each defining portion, and the housing is displaced due to this component, the relative positions of these various components can easily vary in the above-described direction. Such a variation in relative position is not preferable because it may cause a decrease in the holding function of the defining portion by the main body and the housing and may hinder a stable stroke of the movable body.

  In this respect, in this feature, the force (load) applied to the housing is transmitted to the main body by the transmission means. Thereby, the dispersion | variation in the relative position of various structures is suppressed suitably, and it is easy to ensure the clamping function. Specifically, if the load is applied to the defining portion, at least a part of the load is transmitted to the housing via the defining portion. Then, at least a part of the load transmitted to the housing is transmitted to the main body via the transmission unit. If the housing or the defining portion is displaced in a direction in which a load is applied, the main body is displaced in the same direction following the displacement. As described above, the main body, each defining portion, and each housing are integrally displaced in the same direction, thereby suppressing variations in relative positions of the defining portion, the main body, and the housing. Thereby, a clamping function is ensured and it can contribute to realization of the stable reciprocation of a movable body. Moreover, it becomes possible to disperse | distribute the load mentioned above to various structures, and can suppress that load concentrates locally.

  For example, the housing is formed so as to sandwich the main body from both sides in the axial direction of the insertion portion, and the housing is opposite to the side where the housing is in contact with the defining portion in the axial direction of the insertion portion with respect to the main body. It is good to make it contact from.

Feature A9. The housing is
A pair of abutting portions (holding portions 261 and 282) that abut against the respective defining portions from the outside in the axial direction of the insertion portion;
The gaming machine according to A2, further comprising a connecting portion (a base 281, a countersunk screw 296, or the like) that connects the abutting portions so that the relative positions of the abutting portions do not change.

  According to the feature A9, the same effect as the feature A5 is obtained. Hereinafter, for convenience, the defining portion and the abutting portion arranged on the front side in the direction in which the load is applied are referred to as a first defining portion and a first abutting portion, respectively, and the other is a second defining portion and a second abutting portion. Will be described briefly. If the load is applied to the main body or the first defining portion, at least a part of the load is transmitted to the first abutting portion via the first defining portion. And at least one part of the load transmitted to the 1st contact part is transmitted to a 2nd contact part via a connection part. If the main body or the first defining portion is displaced in the direction in which the load is applied, both the contact portion and the connecting portion are displaced in the same direction following the displacement. When the second contact portion is displaced in the same direction, the second defining portion is pushed in the same direction. In this way, the main body, each defining portion, and each contacting portion are integrally displaced in the same direction, so that the relative positions of the first defining portion, the main body, and the first contacting portion on the first defining portion side are changed. The variation is not only suppressed, but also the relative positions of the second defining portion, the main body, and the second contact portion on the second defining portion side are also suppressed. Further, even when a load opposite to the above-described load is applied to the main body or the like, similarly, variations in relative positions of the various configurations on the first defining portion side, and the various types on the second defining portion side. Variation in the relative position of the configuration is suppressed. Thereby, a clamping function is ensured and it can contribute to realization of the stable reciprocation of a movable body. Moreover, it becomes possible to disperse | distribute the load mentioned above to various structures, and can suppress that load concentrates locally.

  Further, the technical idea shown in the feature A6 is applied to this feature, and “the game machine according to A9, wherein the connecting portion is provided on both sides of the central axis of the insertion portion”. It is also possible. In this case, for example, the drive unit (main body) may be surrounded by the housing.

  In addition, it can be said that one of the “connecting portion” and the “contact portion” in this feature constitutes at least a part of the “transmission portion” shown in the feature A8 with respect to the other of the “contact portion”. .

Feature A10. One side portion of the main body is provided with a main body-side concave portion (installation portions 187 and 188) that is recessed in the moving direction of the movable body,
In the housing, a portion facing the main body side concave portion is provided with a housing side concave portion (fitting portion 263, 284) which is recessed on the opposite side to the main body side concave portion,
The defining portion has fitting portions (flange portions 221 and 241) that fit into a space defined by the main body side concave portion and the housing side concave portion,
By fitting the fitting portion with the main body side concave portion and the housing side concave portion, relative movement between the defining portion, the main body, and the housing in a direction different from the moving direction of the movable body is restricted. The gaming machine according to any one of A1 to A9, wherein the gaming machine is formed as described above.

  According to the feature A10, when the fitting portion is fitted in the space defined by the main body-side concave portion and the housing-side concave portion, the relative movement between the main body and the defining portion is restricted, and the relative movement between the housing and the defining portion is restricted. Is done. As described above, the relative movement of the various configurations is avoided by the fitting with the fitting portion, so that the relative positions of the various configurations can be prevented from shifting due to vibrations generated based on the reciprocating motion of the movable body. . As a result, a stable stroke can be realized, and the load generated on the movable body, the bearing, and the like can be reduced, and the operating life can be extended.

  In particular, in the combination with the features A3 to A6, the main body, the defining portion, and the housing are not connected to each other, and the various configurations are fitted to each other, and other than the moving direction of the movable body The relative movement in the direction is controlled by the fit. For this reason, even if a large load is applied in the moving direction, relative movement in the moving direction of the movable body is easily allowed. That is, even if the housing or the main body is distorted due to the above-described load, it is possible to suppress the influence of the distortion on the defining portion. As a result, it is possible to reduce the load generated on the movable body, the bearing and the like and extend the operation life.

Feature A11. At least one of the housing and the main body is provided with an installation portion (187, 188) for installing the defining portion,
Any one of A1 to A10 is characterized in that the defining portion is configured to be unmovable from the installation portion based on the integration of the housing and the driving portion. The gaming machine described in one.

  According to the feature A11, by providing the installation portion for installing the defining portion, the positioning accuracy of the defining portion can be improved in a configuration in which the defining portion is provided separately. Thereby, the shift | offset | difference of the relative position of a movable body and a drive part resulting from work dispersion | variation etc. can be suppressed suitably. Desirably, a configuration in which the installation portion is formed at least on the main body may be employed.

  In addition, when the configuration having the defining portion is employed, it is assumed that a separate operation for attaching the defining portion is required while the straight running stability of the movable body can be improved. This is not preferable because the manufacturing process can be complicated. In this regard, in the present feature, the defining portion is held in a state of being sandwiched between the main body and the housing by integrating the main body and the housing. That is, by attaching the drive unit to the housing, it is possible to make it impossible to remove the defining part without requiring fixing work of the defining part. Thereby, complication of a manufacturing process can be controlled suitably.

Feature B1. A movable body (movable body 160) capable of linear reciprocation;
It has a coil (excitation coil 171) that forms a magnetic field by being energized and applies power to the movable body, and an insertion portion (inside the cylindrical portion 182) through which the movable body is inserted, and the outer periphery of the insertion portion A drive unit (for example, solenoid drive unit 170 or housing 250) provided with a body (bobbin 181) around which the coil is wound;
A housing (housing 250) which is provided outside the driving unit and to which the driving unit is attached;
It is provided in the main body, is formed so as to contact the movable body, and includes a defining portion (regulating portions 210 and 230) that defines a moving direction of the movable body. A gaming machine.

  According to the feature B1, it is possible to generate a magnetic field by energizing the coil and generate power (for example, attractive force) that moves the movable body by the magnetic field. For example, by placing a game ball on a trajectory along which the movable body moves, it is possible to realize the launch of the game ball by the movable body.

  The moving direction of the movable body is determined by the defining portion. Thereby, it is possible to suppress the deviation of the relative position between the trajectory through which the movable body passes and the drive unit (specifically, the coil). Particularly in this feature, the defining portion is provided in the main body. For example, compared with the case where the defining part is provided on a part other than the main body (for example, a housing), the positional variation (center misalignment or inclination) between the central axis of the insertion part and the central axis of the movable body due to accumulation of dimensional tolerances, etc. Etc.) can be made difficult to occur. Thereby, when the motive power mentioned above generate | occur | produces, it becomes possible to suppress that a movable body is drawn near in the direction which cross | intersects the central axis of the said movable body, and it becomes possible to use effectively the electric power supplied to a coil. Therefore, for example, the launch efficiency of a game ball can be increased.

  The “defining part” may be configured by a bearing or the like in which a movable body is inserted, for example, in a cylindrical shape.

Feature B2. A movable body (movable body 160) capable of linear reciprocation;
It has a coil (excitation coil 171) that forms a magnetic field by being energized and applies power to the movable body, and an insertion portion (inside the cylindrical portion 182) through which the movable body is inserted, and the outer periphery of the insertion portion A drive unit (for example, solenoid drive unit 170 or housing 250) provided with a body (bobbin 181) around which the coil is wound;
A housing (housing 250) which is provided outside the driving unit and to which the driving unit is attached;
It is formed so as to abut against the movable body, and includes a defining portion (regulating portion 210, 230) that defines the moving direction of the movable body,
The defining portion is provided so as to be integrated with the main body, and is provided so that the housing is not interposed between the main body and the main body at the integrated portion. Gaming machine.

  According to the feature B2, the same effect as the feature B1 is achieved. That is, in the portion where the defining portion is provided in the main body, the main body and the defining portion are integrated so that the housing is not interposed between the main body and the defining portion. For example, compared with the case where the defining part is provided on a part other than the main body (for example, a housing), the positional variation (center misalignment or inclination) between the central axis of the insertion part and the central axis of the movable body due to accumulation of dimensional tolerances, etc. Etc.) can be made difficult to occur. In addition, the same advantage can be obtained when compared with the case where the main body and the defining portion are integrated so that the housing is interposed between the main body and the defining portion at the portion where the defining portion is provided in the main body. It is done. By suppressing the positional deviation between the central axes in this way, when the power described above is generated, the movable body is prevented from being drawn in the direction intersecting the central axis of the movable body, and the electric power supplied to the coil is reduced. It can be used effectively. Therefore, for example, the launch efficiency of a game ball can be increased.

  The “defining part” may be configured by a bearing or the like in which a movable body is inserted, for example, in a cylindrical shape.

  Incidentally, “the main body and the defining portion are integrated” means that the main body and the defining portion are integrally formed, the main body and the defining portion are coupled by a bonding means such as adhesion, It includes staying mechanically by fitting or the like.

  Feature B3. The gaming machine according to B1 or B2, wherein the defining portion is disposed on both sides of the main body in the axial direction of the insertion portion.

  According to the feature B3, it is possible to widen the interval between the portions that define the movement of the movable body. Thereby, the straight running stability of the movable body in at least the insertion portion can be improved. However, when a plurality of defining portions are provided and the interval between the defining portions is simply increased, it is assumed that the relative positions of the defining portions are likely to vary. In this regard, by applying the configuration shown in the feature B1 or the like and providing each defining portion on the main body, it is possible to suppress the displacement of the relative positions of the both defining portions, and to realize a practically preferable configuration.

Feature B4. The defining portion is provided separately from the main body,
The main body is provided with an installation part (installation part 187, 188) for installing the defining part,
The defining portion and the installation portion are configured such that the relative movement of the main body and the defining portion in a direction different from the axial direction of the insertion portion is restricted when one of the defining portion and the installation portion is fitted to the other. The gaming machine according to any one of B1 to B3, characterized by:

  For example, accumulation of the dimensional tolerances described above can be suppressed by integrally forming the defining portion with respect to the main body. However, if the defining portion is integrally formed with the main body, it becomes difficult to manage the size of the defining portion, or the drive portion needs to be replaced when the defining portion is replaced due to wear or the like. . This is not preferable from the viewpoint of simplifying the manufacturing process and improving the reusability of parts.

  In this regard, as shown in this feature, by providing the defining portion separately from the main body, the various inconveniences described above can be eliminated. In addition, when one of the defining portion and the installation portion is fitted to the other, relative movement of the main body and the defining portion in a direction different from the axial direction of the insertion portion is restricted. As a result, the displacement of the relative position of the drive unit (specifically, the main body) and the movable body (specifically, the passing trajectory) can be suppressed while reducing the complexity of the assembly work caused by the provision of the defining part as a separate body. It is possible to realize a preferable structure.

Feature B5. The defining portion is provided separately from the main body,
The main body is provided with an installation part (installation part 187, 188) for installing the defining part,
The defining part installed in the installation part is configured to be unable to move from the installation part based on the integration of the housing and the drive part. The gaming machine according to any one of B1 to B3.

  As shown in the feature B1 and the like, in the case of the configuration having the defining portion, it is possible to improve the magnetic characteristics (dynamic characteristics) by suppressing variations in the relative positions of the movable body and the drive section. However, if the fixing operation of the defining portion is necessary, it may be a factor that causes a complicated assembly process, which is not preferable. In this regard, according to the present feature, it is possible to contribute to simplification of the assembly process by combining the housing and main body integration work (for example, fixing work) and the work for restricting the movement of the defining portion. That is, it is possible to improve the efficiency of assembly work while improving the magnetic characteristics.

  Note that this feature can also be applied to the feature B4. Thus, when combined with the feature B4, this feature is described as follows: “The defining portion is provided separately from the main body, and the main portion is provided with an installing portion (installing portions 187 and 188). ) And the one of the defining portion and the installation portion is fitted to the other, so that relative movement of the main body and the defining portion in a direction different from the axial direction of the insertion portion is restricted. The defining portion installed in the installation portion is configured to be unable to move from the installation portion based on the integration of the housing and the drive unit. It is also possible to replace it with the “gaming machine according to any one of B1 to B3”.

  Feature B6. The gaming machine according to B4 or B5, wherein the defining portion is held in a state of being sandwiched between the main body and the housing.

  In order to realize the configuration shown in the features B4 and B5, the defining portion may be sandwiched between the main body and the housing shown in this feature. Thereby, a practically preferable configuration can be realized.

Feature B7. The defining portion is provided separately from the main body and the housing, and is individually disposed on both sides of the main body in the axial direction of the insertion portion,
The housing is provided so as to sandwich the main body from both sides in the axial direction of the insertion portion,
Each said prescription | regulation part is hold | maintained in the state pinched | interposed by the said main body and the said housing, The game machine as described in any one of B1 thru | or B6 characterized by the above-mentioned.

  For example, accumulation of the dimensional tolerances described above can be suppressed by integrally forming the defining portion with respect to the main body. However, if the defining portion is integrally formed with the main body, it becomes difficult to manage the size of the defining portion, or the drive portion needs to be replaced when the defining portion is replaced due to wear or the like. . This is not preferable from the viewpoint of simplifying the manufacturing process and improving the reusability of parts. In this regard, as shown in this feature, by providing the defining portion separately from the main body, the various inconveniences described above can be eliminated.

  Moreover, the straight running stability of the movable body can be easily ensured by arranging the pair of defining portions on both sides of the main body. However, there is a concern that by adopting a configuration including a plurality of defining portions in this way, the work of attaching each defining portion to the main body becomes complicated. In this regard, according to the present feature, by attaching the main body and the housing, the respective defining portions are held (clamped) in a state of being sandwiched between the main body and the housing. Thereby, the inconvenience described above can be eliminated, and a practically preferable configuration can be realized.

Feature B8. The installation portion is disposed on one side of the main body and has a concave shape that is recessed in the moving direction of the movable body.
In the housing, the portion facing the installation portion is provided with recesses (fitting portions 263, 264) that are recessed on the opposite side of the installation portion,
The defining portion has fitting portions (flange portions 221 and 241) that fit into a space defined by the installation portion and the concave portion,
The fitting portion is engaged with the installation portion and the concave portion, thereby restricting relative movement between the defining portion, the main body, and the housing in a direction different from the moving direction of the movable body. The gaming machine according to any one of B4 to B7, wherein the gaming machine is formed as described above.

  According to the feature B8, when the fitting portion is fitted in the space defined by the installation portion and the recess, the relative movement between the main body and the defining portion is restricted, and the relative movement between the housing and the defining portion is restricted. As described above, the relative movement of the various configurations is avoided by the fitting with the fitting portion, so that the relative positions of the various configurations can be prevented from shifting due to vibrations generated based on the reciprocating motion of the movable body. . As a result, a stable stroke can be realized, and the load generated on the movable body, the bearing, and the like can be reduced, and the operating life can be extended.

  In addition, if a magnetic circuit for passing a magnetic field generated in a coil by a housing is configured, magnetic characteristics (dynamic characteristics) are improved by suppressing positional deviation between the housing, the movable body, and the main body (specifically, a coil). be able to. This makes it possible to efficiently use the power supplied to the coil as the driving force of the movable body. For example, when a game ball is launched by the movable body, the launching efficiency can be improved.

Feature B9. The housing has a pair of housing structural bodies (first housing structural body 260 and second housing structural body 280) provided individually corresponding to the respective defining portions,
Each of the defining portions is held in a state of being sandwiched between each of the housing components and the main body,
The gaming machine according to B7, wherein the two housing components are configured such that a combination direction of the housing components is the same as an axial direction of the insertion portion.

  In the configuration in which the main body and the defining portion are sandwiched by combining the housing components, the assembly operation can be prevented from becoming complicated by aligning the moving direction of the movable body and the combination direction of the housing.

  Further, if the main body and the two defining portions are sandwiched by one housing component, it becomes difficult to allow variations in the accumulated dimensional tolerance of the defining portion and the main body, the dimensional tolerance of the housing, the distortion of the housing, and the like. That is, the above-described distortion or the like affects the main body or the defining portion, and the relative positions of the defining portions may be shifted or the relative positions of the defining portion and the main body may vary. For this reason, in the configuration in which the defining portion is sandwiched and held by the housing and the main body, it may be difficult to ensure the holding accuracy. In this regard, by combining the housing components from both sides in the moving direction of the movable member, the relative positions of the two housing components can be corrected when the two housing components are combined. Thereby, while ensuring the straight-running stability of the movable body, it is possible to easily allow the above-described variation in dimensional tolerance, distortion, and the like, and a practically preferable configuration can be realized.

Feature B10. The housing has a pair of housing structural bodies (first housing structural body 260 and second housing structural body 280) provided individually corresponding to the respective defining portions,
A screw (a countersunk screw 296, 297) for connecting the two housing components;
The gaming machine according to B7 or B9, wherein a mounting direction of the screw is set to be different from an axial direction of the insertion portion.

  According to the feature B10, the axial direction of the insertion portion and the mounting direction of the screw are different. For this reason, even if it is a case where the vibration and vibration to the same direction as the said axial direction generate | occur | produce by driving a movable body, it can suppress that a screw loosens by these vibrations. Thereby, the configuration shown in the feature B9 and the like can be suitably realized. That is, even when a configuration in which the defining portion is sandwiched between the housing component and the main body based on a combination of a plurality of housing components is secured, the holding function of the defining portion by the housing component and the main body is ensured. Easy to do.

Feature C1. A movable body (movable body 160) capable of linear reciprocation;
It has a coil (excitation coil 171) that forms a magnetic field by being energized and applies power to the movable body, and an insertion portion (inside the cylindrical portion 182) through which the movable body is inserted, and the outer periphery of the insertion portion A drive unit (for example, solenoid drive unit 170 or housing 250) provided with a body (bobbin 181) around which the coil is wound;
A stopper portion (regulating portion 210, 230) that is disposed at a specific position on the movement track of the movable body and regulates further movement of the movable body by contacting the movable body;
Support portions (for example, holding portions 261 and 282) that support the stopper by contacting the stopper disposed at the specific position from the front side in the moving direction of the movable body toward the stopper. When,
In addition to being provided outside the drive unit, when the movable body and the stopper part come into contact with each other and a force is generated to push the stopper part in the moving direction of the movable body, the force is applied to a part other than the support part. A gaming machine comprising a transmission portion (for example, a base 281 or a countersunk screw 296) that transmits to a part.

  According to the feature C1, it is possible to generate a magnetic field by energizing the coil and generate power (for example, attractive force) that moves the movable body by the magnetic field. For example, by placing a game ball on a trajectory along which the movable body moves, it is possible to realize the launch of the game ball by the movable body. Further, when the movable body reciprocates, further movement of the movable body is restricted based on the contact between the movable body and the stopper portion. The stopper portion is a portion that is susceptible to an impact caused by collision with the movable body. In this way, by providing a separate portion that is susceptible to impact, maintenance is improved and reusability is improved by replacing consumable parts.

  A load such as an impact generated by the contact between the movable body and the stopper portion is transmitted to the support portion that supports the stopper portion from the front side in the moving direction of the movable body. When the stopper portion is provided separately, it is assumed that the various advantages described above can be enjoyed, but the load is concentrated on the support portion and the deformation of the support portion is likely to occur. This is not preferable because it may cause a malfunction such as the stopper part falling off from the support part.

  In this feature, a part of the load described above is transmitted to a part other than the support part by the transmission part. That is, a part of the load applied to the stopper part and the support part can be received at other parts. Thus, by distributing the load to various configurations, it is possible to avoid the load from being concentrated on the stopper portion and the support portion. As a result, it is possible to suppress the occurrence of inconveniences such as falling off of the stopper portion, and to extend the operating life. In addition, by distributing the load as described above, it is possible to suppress the occurrence of distortion or the like in the stopper portion or the support portion. Thereby, when a movable body and a stopper contact | abut, it can suppress that the reaction force of the direction different from an axial direction is added with respect to a movable body. Therefore, the positional variation (center misalignment, inclination, etc.) between the central axis of the coil (insertion portion) and the central axis of the movable body can be suppressed, and a stable stroke of the movable body can be realized.

  Feature C2. The gaming machine according to C1, wherein the transmission unit transmits the force generated by the contact of the movable body and the stopper unit to the main body.

  According to the feature C2, the force (load) generated by the contact between the movable body and the stopper portion is transmitted to the main body via the transmission portion. The main body has a function of driving the movable body as described above. By giving a part of the function of distributing the load to such a configuration, it is possible to avoid the occurrence of concentrated load while simplifying the structure, and to realize a practically preferable configuration.

  Feature C3. The main body is formed so as to face the moving side of the movable body toward the stopper, and receives a force transmitted through the transmission portion (for example, outer surfaces of the flange portions 183 and 184). 183a, 184a) is provided, the gaming machine according to C1 or C2.

  According to the feature C3, the same effect as shown in the feature C2 is achieved. That is, the force (load) generated when the stopper portion hits the support portion is transmitted to the main body (specifically, the receiving surface) via the transmission portion. Thereby, it is possible to receive a part of the force by the main body or to transmit the force to another member or the like via the main body. Therefore, it is possible to avoid the concentrated load while simplifying the structure, and to realize a practically preferable configuration.

Feature C4. The drive unit is provided so as to be sandwiched from both sides in the axial direction of the insertion hole, and includes a housing (housing 250) having the support unit and the transmission unit,
Furthermore, the housing includes a contact portion (for example, a holding portion 261) formed so as to contact the main body from the side opposite to the support portion.
The gaming machine according to any one of C1 to C3, wherein the transmission unit connects the support unit and the contact unit.

  According to the feature C4, at least a part of the force transmitted from the stopper portion to the support portion is transmitted to the contact portion via the transmission portion. Since the contact portion is formed so as to contact the main body from the side opposite to the support portion, a part of the force transmitted to the contact portion is transmitted to the main body. By receiving the force transmitted to the main body by the main body or transmitting it to another member, the configuration shown in the feature C1 and the like can be suitably realized.

Feature C5. The transmission part is disposed on both sides across the central axis of the insertion part,
The gaming machine according to C4, wherein the support part and the contact part are connected to each other on both sides of the center axis of the insertion part by the transmission part.

  When adopting a configuration in which the load applied to the stopper portion is distributed and received by various configurations of the drive unit and the housing, a bending moment may be generated so as to distort these various configurations depending on the transmission path of the force. Specifically, since the housing is disposed outside the drive unit, the force transmission path is separated from the central axis of the insertion unit. For this reason, it is assumed that a bending moment is likely to occur based on the transmission of force. The generation of such a bending moment is not preferable because it can be a factor that hinders the straight running stability of the movable body. In this respect, as shown in this feature, it is easy to suppress the generation of a bending moment by connecting the support portion and the contact portion on both sides of the center axis of the insertion portion, or the body of the bending moment, etc. It can make it easier to suppress the impact.

Feature C6. A movable body (movable body 160) capable of linear reciprocation;
It has a coil (excitation coil 171) that forms a magnetic field by being energized and applies power to the movable body, and an insertion portion (inside the cylindrical portion 182) through which the movable body is inserted, and the outer periphery of the insertion portion A drive unit (for example, solenoid drive unit 170 or housing 250) provided with a body (bobbin 181) around which the coil is wound;
A first stopper portion (regulating portion 210) that is disposed on an operation track of the movable body and regulates movement of the movable body to one side by contacting the movable body;
A second stopper portion (regulating portion 230) that is disposed on an operation track of the movable body and regulates the movement of the movable body to the other side by contacting the movable body;
The drive unit is provided so as to be sandwiched from both sides in the axial direction of the drive unit, and includes a housing (housing 250) to which the drive unit is attached.
The housing is
A first contact portion that is in contact with one end of the main body from the outside and is in contact with the first stopper from the front side in the moving direction of the movable body toward the first stopper. (Holding part 282),
A second contact that is in contact with the other end of the main body from the outside, and that is in contact with the second stopper from the front side in the moving direction of the movable body toward the second stopper. Part (holding part 261);
A gaming machine having a connecting portion (for example, a base 281 or a countersunk screw 296) formed so as to connect the first contact portion and the second contact portion.

  According to the feature C6, the force (load) generated when the movable body hits the first stopper portion is transmitted to the first contact portion that is in contact with the first stopper. Since the first contact part is connected to the second contact part via the connecting part, at least a part of the load transmitted to the first contact part is transmitted to the second contact part. Since the second contact portion is in contact with the main body, at least a part of the load transmitted to the second contact portion is transmitted to the main body. The main body is in contact with the first contact portion, and by receiving a part of the load described above at the main body, the load can be prevented from concentrating on the stopper portion or the like.

  The force (load) generated when the movable body hits the second stopper portion is transmitted to the second abutting portion that abuts against the second stopper. Since the second contact portion is connected to the first contact portion via the connecting portion, at least a part of the load transmitted to the second contact portion is transmitted to the first contact portion. Since the first contact portion is in contact with the main body, at least part of the load transmitted to the first contact portion is transmitted to the main body. The main body is in contact with the second contact portion, and by receiving a part of the load described above at the main body, the load can be prevented from being concentrated on the stopper portion or the like.

  As described in detail above, the load generated with the movement of the movable body in both directions can be received by the stoppers, the housing, and the main body in a distributed manner to suppress local concentration of the load. It becomes possible. As a result, it is possible to suppress the occurrence of inconveniences such as falling off of the stopper portion, and to extend the operating life. In addition, by distributing the load as described above, it is possible to suppress the occurrence of distortion or the like in the stopper portion or the contact portion. Thereby, when a movable body and a stopper contact | abut, it can suppress that the reaction force of the direction different from an axial direction is added with respect to a movable body. Therefore, the positional variation (center misalignment, inclination, etc.) between the central axis of the coil (insertion portion) and the central axis of the movable body can be suppressed, and a stable stroke of the movable body can be realized.

  Feature C7. The game machine according to C6, wherein the main body is held in a state of being sandwiched from both sides in the moving direction of the movable body by the first contact portion and the second contact portion of the housing.

  As shown in the feature C6, in the configuration in which the force is transmitted through the transmission unit, it is assumed that the timing at which the force is applied to one end of the main body and the timing at which the force is applied to the other end are slightly shifted. The For this reason, if the housing and the main body are combined, there is a concern that the main body is likely to be distorted due to the timing shift described above. In this respect, as shown in this feature, if the main body is sandwiched between the first contact portion and the second contact portion of the housing, the influence of the timing delay as described above can be suppressed. On the other hand, the occurrence of distortion or the like can be suppressed. Thereby, the load generated with the operation of the movable body can be reduced, and the operating life can be extended.

  Feature C8. In a state where the main body is sandwiched between the first contact portion and the second contact portion, a restriction portion that restricts relative movement of the main body and the two contact portions in a direction different from the axial direction in the insertion portion. (The installation parts 187 and 188, the flange parts 221, 241 and the fitting parts 263 and 284) are provided, and the gaming machine according to C7,

  In the configuration in which the main body is sandwiched between both contact portions as shown in the feature C7, the relative position of the housing and the drive unit in the moving direction of the movable body is suppressed by the contact between the both contact portions and the main body. be able to. In such a configuration, it is necessary to increase a clamping force (clamping force) in order to suppress a shift in relative position to the rear that is different from the moving direction. That is, it is necessary to press the main body from both ends with a strong force. This is not preferable because it may cause a distortion of the main body. In this regard, as shown in this feature, if the structure is provided with a restricting portion that restricts the relative movement of the main body and both contact portions in a direction different from the moving direction, the above-described clamping force can be weakened, A practically preferable configuration can be realized.

Feature C9. The housing includes a first housing component (first housing component 260) having the first contact portion and a second housing component (second housing component 280) having the second contact portion. And at least the first housing structure and the second housing structure are combined with each other in a combined state,
C7 or C8, wherein the second housing component and the second housing component are configured such that a combination direction of both the housing components is the same as an axial direction of the insertion portion. Game machines.

  By combining the housing components, in the configuration in which the drive unit is sandwiched, the moving direction of the movable body and the combination direction of the housing are aligned, so that it is possible to suppress complication of assembly operations of these various configurations.

  Further, if the drive unit (specifically, the main body) is sandwiched by one housing component, it is difficult to allow variation between the dimensional tolerance of the main body and the dimensional tolerance of the housing. In other words, due to the above-described dimensional variations, it may be difficult to bring the respective contact portions into contact with the main body, that is, to ensure the holding accuracy. In this regard, by adopting a configuration in which the housing components are combined from both sides in the moving direction of the movable member, it is possible to correct the relative positions of the two housing components when the two housing components are combined. Thereby, while ensuring the straight-running stability of the movable body, it is possible to easily allow variations such as the above-described dimensional tolerances, and a practically preferable configuration can be realized.

  Feature C10. The gaming machine according to any one of C6 to C9, wherein the transmission unit is disposed on both sides of a center axis of the insertion unit.

  When adopting a configuration in which the load applied to the stopper portion is distributed and received by various configurations of the drive unit and the housing, a bending moment may be generated so as to distort these various configurations depending on the transmission path of the force. Specifically, since the housing is disposed outside the drive unit, the force transmission path is separated from the central axis of the insertion unit (that is, the track on which the stopper is disposed). For this reason, it is assumed that a bending moment is likely to occur based on the transmission of force. The generation of such a bending moment is not preferable because it can be a factor that hinders the straight running stability of the movable body. In this respect, as shown in this feature, it is easy to suppress the generation of bending moment by connecting both housing components on both sides of the center axis of the insertion section, or the influence of the bending moment is affected by the main body and the specified section. Etc. can be made difficult.

  For example, a practically preferable configuration can be realized by surrounding the main body using a housing. Specifically, when the main body is surrounded by the housing, it is easy to obtain the driving force of the movable body by providing the housing with a function of forming a magnetic circuit, and the load described above is preferably dispersed. Therefore, these two functions can be realized while suppressing the complexity of the configuration.

  In addition, it is also possible to replace “the axial direction of the insertion portion” shown in the above features with “the moving direction of the movable body defined by the defining portion”.

  Incidentally, any one of the features B1 to B10 may be applied to the features A1 to A11. Further, any one of the features C1 to C10 may be applied to the features A1 to A11 and the features B1 to B10.

  The basic configuration of the gaming machine to which the above features can be applied is shown below.

  Pachinko gaming machine: operation means operated by a player, game ball launching means for launching a game ball based on the operation of the operation means, a ball path for guiding the launched game ball to a predetermined game area, and a game A gaming machine that includes each gaming component arranged in an area, and gives a bonus to a player when a gaming ball passes through a predetermined passing portion of each gaming component.

  DESCRIPTION OF SYMBOLS 10 ... Pachinko machine, 100 ... Game ball launcher, 110 ... Solenoid, 160 ... Movable body, 161 ... Shaft, 162 ... Plunger, 170 ... Solenoid drive part as a drive part, 171 ... Excitation coil as a coil, 181 ... Main body Bobbin, 187, 188 ... installation portion, 210 ... first defining portion, 211 ... first bearing, 215 ... first holder, 221 ... flange portion as fitting portion, 230 ... second defining portion, 231 ... first Two bearings, 235 ... second holder, 241 ... flange as a fitting portion, 250 ... housing, 260 ... first housing component, 262 ... fitting portion as a recess, 280 ... second housing component, 283 ... A fitting part as a recess.

Claims (1)

A launch device that launches a game ball based on a predetermined launch operation,
The launcher is
A movable body capable of linear reciprocation;
A coil that forms a magnetic field by being energized and supplies power to the movable body, and an insertion portion through which the movable body is inserted, and a bobbin around which the coil is wound are provided around the insertion portion. A drive unit;
A housing for accommodating the drive unit;
Provided at both ends of the bobbin, and provided with a defining portion that regulates the moving direction of the movable body to be the same direction as the axial direction of the insertion portion by contacting the movable body,
Each of the defining parts is
A cylindrical main body extending in the same direction as the insertion portion;
A bearing portion provided at an end of the main body portion opposite to the bobbin, through which the movable body is inserted;
A flange portion that is formed at an end portion of the main body portion on the bobbin side and abuts on an end portion of the bobbin;
The housing has a first housing component and a second housing component as a pair of housing components provided so as to sandwich the main body from both sides in the axial direction.
The first housing component is:
A first opening through which the main body is inserted;
Provided around the first opening, and a first contact portion that contacts the opposite side of the bobbin to the flange portion and the body portion to the first opening in the insertion state,
The second housing component is:
A second opening through which the main body is inserted;
A second contact portion provided around the second opening and contacting the flange portion from a side opposite to the bobbin in a state where the main body portion is inserted through the second opening;
Have
By the first housing component and the second housing member is fixed, said flange portion provided on one of the defining portion is sandwiched between the bobbin and the first contact portion and the The flange portion provided on the other of the defining portions is configured to be sandwiched between the bobbin and the second contact portion ,
The bobbin and each contact portion are formed with a fitting recess that fits into the flange portion,
In the sandwiched state, the flange portion is fitted into the fitting recess, so that the relative position of the defining portion, the drive portion, and the housing in a direction different from the moving direction of the movable body changes. Regulated ,
The first housing component is provided with a first extension that extends from the first contact portion in the axial direction and forms an insertion portion into which the drive unit and the second housing component are inserted. And
The second housing component is provided with a second extending portion extending from the second contact portion in the same direction as the first extending portion,
The second extension part is configured to face the first extension part from the inside of the insertion part when the second housing component is inserted into the insertion part.
A screw for fixing the first extension part and the second extension part;
The gaming machine is characterized in that the housing is configured such that a direction in which the screw is attached is the same as an overlapping direction of the first extending portion and the second extending portion .

Images