JP2007267768A - Pin interval gage for game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pin interval gage for a game machine capable of easily changing a gage width of a gage part and retaining the gage width after the change when a user adjusts the pin interval. <P>SOLUTION: This pin interval gage for the game machine includes a grip part 102 gripped by the user when measuring the interval of pins 11 driven in the game machine 1, and a gage part 104 disposed at the tip side of the grip part, being inserted between the pins and measuring the pin interval; and is characterized in that the gage part includes a fixed part 106 fixed to the grip part and a movable part 108 movable in the width direction of the gage part relative to the fixed part, and the grip part includes a movable part operation means 110 movingly operating the movable part in the width direction to the fixed part, and a movable part fixing means 126a, when the gage part becomes an intended gage width, fixing the movable part. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a nail gap gauge for a gaming machine that is used when adjusting a gap between nails driven into a game board of a gaming machine such as a pachinko machine.

  A pachinko machine called a ball and ball machine is equipped with a wooden game board, on which a central prize-winning device called a so-called accessory, prize-winning holes having various structures, etc. are attached, and a number of nails. Has been driven in. These nails are intended to regulate the fall path of the fired pachinko balls, and the size of the gap between a certain nail and another nail greatly affects the passing rate of the pachinko balls. In particular, the nail spacing located in the pachinko ball path to the above-described center winning device and each winning hole greatly affects the payout rate of the pachinko machine. Therefore, careful attention is paid to the adjustment between the nails of the pachinko gaming machine.

  The following is necessary to adjust the distance between nails of a pachinko machine. First, in order to know whether or not there is a need for inter-nail adjustment, it is necessary to accurately measure the current nail interval. Next, when it is necessary to adjust the distance between the nails, it is necessary to accurately adjust the distance between the nails so as to match the desired distance. For this reason, in order to set the nail interval of the pachinko machine to an appropriate value, a nail interval gauge has been conventionally used when driving the nail.

The nail interval gauge is configured such that a plurality of plate gauge members formed by bending a substantially rectangular elongated plate-like stainless steel into a dogleg shape at a predetermined angle are bundled as a set. Each plate gauge member has a grip portion as a grip portion to be gripped by a user who measures the nail interval during the measurement work, and a plate as a gauge portion for contacting the nail and measuring the nail interval with such a bend as a boundary. The contact portion is configured. The plate-like contact portions of each plate gauge member have different gauge widths, for example, in increments of 0.1 to 0.5 mm, and when adjusting the nail interval, a plate gauge member having a desired gauge width by the user Select the nail interval, insert the plate-shaped contact part of the plate gauge member between the nails, and hit the nail in the desired direction using a tool such as a hammer to achieve the desired nail interval. It is adjusted by bending (for example, see Patent Document 1).
JP 2003-47704 A

  However, the above-described nail interval gauge has a plate gauge member comprising a plurality of plate gauge members each having a gauge portion having a gauge width capable of adjusting the nail interval when adjusting a desired nail interval. Each time it is selected, it takes time to replace the plate gauge member, which is inconvenient for the user. For this reason, it has been a problem that the work efficiency of adjusting the nail interval of the pachinko machine is lowered.

  Therefore, the present invention has been made in view of the above-mentioned problems of conventional nail gap gauges for gaming machines, and the object of the present invention is to make it easier for the user to set the gauge width of the gauge portion during the nail gap adjustment work. Therefore, it is possible to provide a new and improved nail interval gauge for a gaming machine that can improve the workability of adjusting the nail interval in a gaming machine.

  In order to solve the above-described problems, according to an embodiment of the present invention, a gripping portion that is gripped by a user when measuring the interval between nails driven into a gaming machine, and a distal end side of the gripping portion are provided. In a nail interval gauge for a gaming machine that includes a gauge portion that is inserted between nails and measures a nail interval, the gauge portion is fixed to the grip portion, and the fixed portion A movable portion movable in the width direction of the gauge portion, and a movable portion operating means for moving the movable portion in the width direction with respect to the fixed portion, and a gauge portion having a desired gauge width. There is provided a nail gap gauge for a gaming machine, comprising a movable part fixing means for fixing the movable part at the time.

  With such a configuration, the user can easily adjust the gauge width of the gauge part with one hand by operating the movable part operating means with a finger or the like holding the grip part during the operation of adjusting the nail interval of the pachinko machine. Can be changed. For this reason, when changing the gauge width of the gauge part used for the nail interval adjustment, it is possible to omit the trouble of replacing the plate gauge member as in the prior art, so that the work efficiency of the nail interval adjustment of the gaming machine is improved.

  Also, after changing the gauge part to the desired gauge width, the desired gauge width is maintained by the movable part fixing means, so the gauge width is reduced by impact when hitting the nail with a hammer or the like during the nail interval adjustment work. The change can be prevented, and the accuracy of the nail interval in the operation of adjusting the nail interval can be increased.

  At this time, in the above-described embodiment, the movable part fixing means is a switching means for switching the movable part operating means from the operating state in which the movable part can move the movable part in the width direction to the non-operating state incapable of moving. It is good also as comprising.

  With this configuration, when the user adjusts the nail interval, the gauge width of the gauge portion is changed, and when the desired gauge width is reached, the movable portion of the gauge portion can be held with one hand relative to the fixed portion. Can be easily fixed.

  At this time, in the above embodiment, at least one of the gripping part and the movable part operating means is provided with a gauge width display means for displaying the gauge width of the gauge part corresponding to the moving amount of the movable part. It is good to be.

  With this configuration, the user can easily set the gauge portion to a desired width, and the gauge width set by the user can be easily confirmed even during nail adjustment work.

  Further, at this time, in the above embodiment, the grip portion may be provided with a grip portion having a substantially cylindrical shape whose diameter is larger than the gauge width of the gauge portion.

  By adopting such a configuration, when a user such as an operator adjusts the nail interval, the user can easily apply a desired force to the gauge portion on the tip side of the grip portion while gripping the grip portion. This makes the nail interval gauge easy to use and improves the efficiency of adjusting the nail interval.

  As described above, according to the present invention, the user operates the movable part operating means with a finger or the like holding the grip part of the nail gap gauge for the gaming machine during the operation of adjusting the nail gap of the pachinko machine. Since the gauge width of the gauge part can be easily changed with one hand, the work efficiency of adjusting the nail interval of the gaming machine is improved.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  First, a schematic configuration of a pachinko machine that is a gaming machine into which nails are driven will be described with reference to the drawings. FIG. 1 is a front view showing a schematic structure of a pachinko machine having a nail as a gaming machine. The pachinko machine 1 includes a wooden game board 3 and a circular frame 5 attached to the game board 3.

  On the upper surface of the game board 3 surrounded by the circular frame 5, a central winning device 7 called a so-called accessory, a winning hole 9 having various structures, and the like are attached, and a number of nails 11 are driven. These nails 11 are intended to regulate the fall path of the fired pachinko balls, and the size of the gap between a certain nail 11 and another nail 11 greatly affects the passing rate of the pachinko balls.

  In particular, the spacing between the nails located in the pachinko ball path to the central winning device 7 and each winning hole 9 described above greatly affects the payout rate of the pachinko machine 1. Therefore, in order to set the nail interval to an appropriate value, a gaming machine nail interval gauge 100 described below is used.

  As shown in FIG. 2, the nail 11 includes a head portion 13, a shaft portion 15, and a neck lower portion 17 formed at the root of both. Further, the pachinko machine 1 described above is a game machine of a type that plays with pachinko balls supplied from the outside, but also includes a pachinko machine of a type that circulates and uses pachinko balls enclosed inside (so-called encapsulated pachinko machine). It goes without saying that it is included.

  Next, the configuration of the first embodiment of the nail gap gauge for gaming machines of the present invention will be described with reference to the drawings. FIG. 3 is an external perspective view of the gaming machine nail gap gauge according to the first embodiment of the present invention, and FIG. 4 is an external plan view of the gaming machine nail gap gauge according to the present embodiment. FIG. 5 is a front view from the gauge part side of the nail gap gauge for gaming machines of the present embodiment.

  As shown in FIG. 3, the nail gap gauge 100 for gaming machine in the present embodiment is a front end side of a grip part 102 that serves as a grip part that a user grips when measuring the distance between nails 11 driven into the pachinko machine 1. Further, a gauge portion 104 is provided which is inserted between the nails of the pachinko machine 1 and measures the distance between the nails 11.

  The gauge unit 104 includes a fixed unit 106 that is fixed to the grip unit 102 and a movable unit 108 that is movable with respect to the fixed unit 106 in the width direction of the gauge unit 104. The movable portion 108 is configured so that the width of the gauge portion 104 is fixed with respect to the fixed portion 106 by the gauge width operation portion 110 serving as a movable portion operation means disposed on the distal end side of the grip portion 102, that is, on the gauge portion side of the grip portion 102. Moved in the direction. As described above, since the gauge width operation unit 110 is provided on the front end side of the grip part 102, the gauge width operation is performed with a finger or the like that the user is holding the grip part 102 during the nail interval adjustment work of the pachinko machine 1. By operating the section 110, the gauge width of the gauge section 104 can be easily changed with one hand.

  In the present embodiment, the gauge width operation unit 110 includes a gripping unit 102 that has a substantially arrow-shaped instruction unit 114 provided by engraving or the like on the surface side of the operation knob 112 while rotating the operation knob 112 that is a rotary operation member. The gauge section 104 is set to a desired gauge width by matching with a scale 116 indicating the gauge width of the gauge section 104 provided around the operation knob 112 provided on the distal end portion 102a provided on the distal end side.

  As described above, in the present embodiment, as a gauge width display means for displaying the gauge width of the gauge portion 104 in accordance with the amount of movement of the movable portion 108, the movable portion is provided around the operation knob 112 at the distal end portion 102a of the grip portion 102. As a gauge width display means for displaying the gauge width of the gauge unit 104 corresponding to the amount of movement 108, a scale 116 with a corresponding gauge width value is provided. For this reason, it becomes easy for the user to set the gauge portion 104 to a desired width, and the gauge width set by the user can be easily confirmed even during nail adjustment work. Note that the gauge width display means is not limited to the mode of the present embodiment. For example, the gauge width value of the gauge portion 104 corresponding to the amount of movement of the movable portion 108 on the surface side of the operation knob 112 is set. It is also possible to provide a display portion for digital display.

  The gauge portion 104 includes the fixed portion 106 and the movable portion 108, and is formed, for example, by bending an elongated plate-shaped stainless steel into a substantially square shape at a predetermined angle. The distal end side is an inter-nail contact portion 104a composed of a fixed portion distal end 106a and a movable portion distal end 108a that become thinner toward the distal end so as to be easily inserted between the nails. In the present embodiment, the reason why the gauge portion 104 is formed of stainless steel is that it has moderate hardness and is resistant to rust, so it can withstand long-term use and the expansion coefficient is relatively small. This is because it is considered that it is difficult for the dimensions to be distorted depending on the use environment. Therefore, as long as the material satisfies these points, metals other than stainless steel, synthetic resins, and the like can be substituted.

  As described above, the gage width operation unit 110 that moves the movable unit 108 in the width direction of the gage unit 104 with respect to the fixed unit 106 is provided at the front end portion 102 a that is provided on the front end side of the grip unit 102. In the present embodiment, as shown in FIG. 4, the base end portion 108b of the movable portion 108 slides in the width direction of the gauge portion 104 so as to be interlocked with the turning operation of the operation knob 112 provided in the gauge width operation portion 110. Is connected to the sliding cylinder 120.

  Further, as shown in FIGS. 4 and 5, a movable support shaft 122 is provided at the distal end portion 108a of the movable portion 108 so as to be connected substantially perpendicular to the movable portion distal end 108a. On the other hand, the distal end portion 106 a of the fixed portion 106 has a storage hole portion 125 that is substantially the same diameter as the movable support shaft 122 and can accommodate the movable support shaft 122 in the distal end portion 106 a of the fixed portion 106. It is formed in substantially the same direction as the movable support shaft 122. As described above, by providing the movable support shaft 122 and the storage hole 125 in the inter-nail contact portion 104a provided on the distal end side of the gauge portion 104, the movable portion 108 is movable when the movable portion 108 is moved with respect to the fixed portion 106. The part 108 does not shake with respect to the fixed part 106, and the gauge width of the gauge part 104 is maintained in a stable state.

  As shown in FIG. 4, the movable portion 108 includes a movable gauge portion 108c provided substantially parallel to the fixed portion 106 of the gauge portion 104 including the movable portion tip 108a, and a grip provided substantially perpendicular to the movable gauge portion 108c. A slide gauge portion 108d that contacts the tip end side of the portion 102 and slides in the width direction with respect to the grip portion 102, and a base that is provided substantially perpendicular to the slide gauge portion 108d and connected to the above-described sliding cylinder portion 120. And an end gauge portion (base end portion) 108b. In the present embodiment, the movable portion 108 is a single plate-like member made of stainless steel or the like so that the movable gauge portion 108c, the slide gauge portion 108d, and the proximal end gauge portion 108b are in a substantially vertical positional relationship. However, the gage portions 108c, 108d, 108b formed separately may be connected by an adhesive means such as an adhesive.

  Thus, the base end portion 108b and the slide gauge portion 108d connected to the sliding cylinder portion 120 that slides in the width direction of the gauge portion 104 so as to be interlocked with the turning operation of the operation knob 112 of the gauge width operation portion 110. Since the movable gauge portion 108 c is connected via the movable knob 108, the movable portion 108 moves in the width direction of the gauge portion 104 with respect to the fixed portion 106 according to the turning operation of the operation knob 112, and the tip of the gauge portion 104 The gauge width of the inter-nail contact portion 104a on the side is adjusted to a desired size.

  In the present embodiment, the gauge width of the inter-nail contact portion 104a at the tip of the gauge portion 104 is set to a desired size of 11.00 millimeters or more, which is the same size as the diameter of a general pachinko ball. A value between ˜15.00 millimeters can be set. At this time, for example, the interval is set so as to be in increments of 0.1 millimeters between 11 and 12 millimeters and 0.5 millimeters in increments of 12 millimeters or more. The interval is basically arbitrary. Details of the configuration of the gauge width operation unit 110 will be described later.

  Further, in the present embodiment, the gripping portion of the nail spacing gauge 100 for gaming machines that the user grips when performing the nail spacing adjustment work is configured in a substantially cylindrical shape whose diameter is larger than the gauge width of the gauge portion 104. A grip portion 102 is provided. For example, the grip portion 102 is formed with a diameter of 20 to 30 millimeters and a diameter larger than the gauge width of the gauge portion 104, and the outer contour of the grip portion 102 is, for example, a smooth curve. When the nail interval is adjusted, it is easy to apply a desired force to the gauge portion 104 provided on the distal end side of the grip portion 102 while gripping the grip portion 102. For this reason, it becomes a nail interval gauge that is easy for the user to use, and the work efficiency of nail interval adjustment is improved. In the present embodiment, the grip portion 102 is integrally formed with the gauge portion 104. However, any other material may be used as long as the gauge portion 104 is fixed to the grip portion 102. It is possible to use and form it separately, and it does not preclude changing the shape of the grip portion 102 or configuring the portion with another material.

  Next, a configuration of the gauge width operation unit 110 provided in the gaming machine nail interval gauge 100 according to the present embodiment will be described with reference to the drawings. 6 is a cross-sectional view taken along line AA of the external perspective view of the nail gap gauge 100 for gaming machines in the present embodiment shown in FIG.

  An operation knob 112 provided at the distal end portion 102 a of the grip 102 is supported by a drive shaft 126 inserted through a hole 124 formed in the distal end portion 102 a, and is rotated around the drive shaft 126. The At the tip of the drive shaft 126, a thread groove is formed in the slope portion, and an operation portion side bevel gear 128 that meshes with a movable portion side bevel gear 130 described later is provided. In addition, an annular locking convex portion 126a formed of an elastic member such as synthetic rubber is provided in a part of the portion that slides with the hole portion 124 of the drive shaft 126 so as to be provided around the drive shaft 126. It has been. On the other hand, a locking recess 124 a is formed on the inner peripheral surface of the hole 124 in an annular shape along the inner peripheral surface of the hole 124 so as to engage with the locking protrusion 126 a. The outer diameter of the locking projection 126a in the radial direction of the drive shaft 126 is somewhat larger than the outer diameter of the outer surface side edge portion 124b of the hole 124. However, due to the elastic deformation of the locking projection 126a, these outer diameters are Can be almost identical. In the present embodiment, the locking projection 126a serves as a movable portion fixing means for fixing the movable portion 108 when the gauge portion 104 is adjusted to a desired gauge width. The details of the operation of fixing the movable portion 108 after setting the gauge portion 104 to a desired gauge width will be described later.

  The base end portion 108b of the movable portion 108 is disposed on the side surface of the front end portion 102a of the grip 102 with respect to the surface on which the gauge width operation portion 110 is provided, and the base end portion 108b has the gauge portion 104 as described above. The sliding cylinder 120 that slides in the width direction is connected substantially vertically. On the other hand, a sliding cylinder housing hole 132 having a diameter substantially the same as that of the sliding cylinder 120 and capable of accommodating the sliding cylinder 120 in the distal section 102 a is provided at the distal end portion 102 a of the grip portion 102. Are formed in substantially the same direction as the width direction of the sliding cylinder portion 120, that is, the length direction of the sliding cylinder portion 120.

  In addition, the inside of the sliding cylinder portion 120 is an operating shaft housing in which a female screw portion 136a meshing with a male screw portion 134a formed on a movable portion operating shaft 134 having a movable portion side bevel gear 130 at the tip is formed on the inner peripheral surface. A hole 136 is provided. Further, a chamber 138 in which the operation unit side bevel gear 128 and the movable unit side bevel gear 130 are engaged is provided inside the distal end portion 102 a of the grip unit 102. They are divided by a fixed wall portion 140 that is fixedly provided inside the distal end portion 102a. The fixed wall portion 140 is formed with an insertion hole 140a through which the movable portion operating shaft 134 having the movable portion side bevel gear 130 at one end is inserted, and between the movable portion side bevel gear 130 of the movable portion operating shaft 134 and the male screw portion 134a. The part 134b is pivotally supported by the insertion hole 138a. In other words, the movable portion operating shaft 134 is configured not to move in the width direction of the gauge portion 104, and does not come off the fixed wall portion 140.

  By configuring the gauge width operation unit 110 as described above, when the operation knob 112 is rotated, the operation unit side bevel gear 128 is rotated via the drive shaft 126 in conjunction therewith, The movable portion side bevel gear 130 that meshes with the operation portion side bevel gear 128 rotates. Then, when the movable part working shaft 134 provided with the movable part side bevel gear 130 at one end rotates, the working shaft housing in which the female screw part 136a meshing with the male screw part 134a formed on the movable part working shaft 134 is formed. The sliding cylinder part 120 having the hole 136 moves in the width direction of the gauge part 104 along the sliding cylinder part accommodation hole part 132. Since the sliding cylinder portion 120 is connected to the base end portion 108 b of the movable portion 108, when the operation knob 112 of the gauge width operation portion 110 is rotated, the base end portion 108 b of the movable portion 108 is changed to the gauge portion 104. It moves in the width direction. Therefore, the movable portion distal end 108a formed integrally with the base end portion 108b of the movable portion 108 and the slide gauge portion 108d moves in the width direction of the gauge portion 104 with respect to the fixed portion distal end 106a.

  In other words, when the operation knob 112 is turned, the rotational force is transmitted to the movable portion operating shaft 134 through the operation portion side bevel gear 128 and the movable portion side bevel gear 130. Since the movable portion operating shaft 134 is rotatably held by the sliding cylinder portion 120, the base end portion 108 b of the movable portion 106 is interposed via the sliding cylinder portion 120 with the rotation of the movable portion operating shaft 134. Moves in the width direction of the gauge portion 104.

  That is, in this embodiment, when the operation knob 112 of the gauge width operation section 110 and the movable section 108 are connected via the gear mechanism as described above, the operation knob 112 is rotated. The movable part 108 provided in the gauge part 104 moves in the width direction of the gauge part 104 with respect to the fixed part 106. Therefore, when adjusting the nail interval, the user can adjust the gauge portion 104 to a desired gauge width by operating the operation knob 112 with fingers or the like while holding the grip portion 102.

  Further, as described above, the movable portion operating shaft 134 is configured not to move in the width direction of the gauge portion 104, and therefore, when the movable portion side bevel gear 130 does not rotate, the movable portion operating shaft 134. Does not rotate, the sliding cylinder portion 120 having the female screw portion 136a meshing with the male screw portion 134a of the movable portion operating shaft 134 does not move in the width direction of the gauge portion 104 and remains stationary, and the movable portion is operated. The sliding cylinder 120 is fixed to the shaft 134. Further, since the male threaded portion 134a of the movable part operating shaft 134 and the female threaded part 136a of the sliding cylinder part 120 are engaged with each other, the sliding cylindrical part 120 does not move in the gauge width direction with respect to the movable part operating shaft 134. Is maintained. For this reason, the movable part 108 in which the base end part 108 b is connected to the sliding cylinder part 120 is not moved with respect to the fixed part 106, but is fixed.

  That is, when the gauge section 104 has a desired gauge width and it is desired to maintain such a gauge width, the operation section side bevel gear 128 is moved by pulling the operation knob 112 outward from the grip section 102 after the gauge width adjustment. It moves away from the movable part side bevel gear 130. Therefore, the power when the operation knob 112 is rotated is not transmitted to the movable portion operating shaft 134 via the movable portion bevel gear 130, and the movable portion 108 is fixed without moving relative to the fixed portion 106. Will come to be. As described above, in this embodiment, since the gauge width is maintained after the gauge portion 104 is changed to a desired gauge width, the nail is hit with a hammer or the like during the nail interval adjustment operation. Since it is possible to prevent the gauge width of the gauge portion 104 from being changed due to a shock at the time, the accuracy of the nail interval in the operation of adjusting the nail interval can be improved.

  At this time, when the operation knob 112 is pulled and the locking projection 126a formed on the drive shaft 126 comes out to the outer edge 124b of the hole 124 provided in the tip end portion 102a of the grip 102, it passes through the hole 124. The locking projection 126a that has been elastically deformed returns to its original inelastic state. For this reason, the outer diameter of the locking convex portion 126a is larger than the outer diameter of the outer surface side edge portion 124b of the hole portion 124, and the locking convex portion 126a is locked to the outer surface side edge portion 124b. The bevel gear 128 is kept away from the movable part side bevel gear 130. Therefore, in the present embodiment, the operation of fixing the movable portion 108 to the fixed portion 106 when the gauge portion 104 has a desired gauge width is performed by pulling the operation knob 112 to the outside of the grip portion 102. By moving the side bevel gear 128 away from the movable part side bevel gear 130, the movable part 108 is switched from the operating state movable in the width direction with respect to the fixed part 106 to the non-movable non-operating state. The

  Note that the gear mechanism that transmits the power of the rotation operation of the operation knob 112 of the gauge width operation unit 110 to the movable unit 108 in the present embodiment is not limited to the above-described aspect of the present embodiment. That is, as long as the operation knob 112 is rotated, the rotational force is transmitted through various power transmission mechanisms so that the movable portion 108 can be moved in the gauge width direction. In addition to the bevel gear, for example, another gear mechanism such as a flat gear or another power transmission mechanism may be substituted.

  Next, an operation of adjusting the gauge width by the gauge width operation unit 110 provided in the gaming machine nail interval gauge 100 according to the present embodiment will be described with reference to the drawings. FIG. 7 is a simplified view of the cross section of the gauge width operation portion provided in the gaming machine nail interval gauge 100 according to the present embodiment, and (a) is a cross section of the gauge width operation portion before the gauge width change operation. (B) shows a cross section of the gauge width operation part during the gauge width change operation, and (c) shows a cross section of the gauge width operation part after the gauge width change operation. 8 shows the vicinity of the gauge portion in FIG. 7 in order to explain the position of the movable portion 104 with respect to the fixed portion 106 when the gauge width operation portion provided in the nail gap gauge 100 for gaming machines in the present embodiment is operated. It is the top view simplified correspondingly, (a) is a top view of the gauge width operation part periphery before a gauge width change operation, (b) is the gauge width operation part periphery during a gauge width change operation. It is a top view, (c) is a top view of the gauge width operation part periphery after a gauge width change operation.

  First, as shown in FIG. 8A, in the state where the gauge width of the gauge portion 104 provided in the nail gap gauge 100 for gaming machines is minimum, the movable portion 108 is not separated from the fixed portion 106. It is the closed state which contact | abutted to. At this time, the sliding cylinder part 120 connected to the base end part 108b of the movable part 108 is accommodated in the sliding cylinder part formed at the distal end portion 102a of the grip part 102 as shown in FIG. The movable portion operating shaft 134 is housed in the working shaft housing hole 136 formed inside the sliding cylinder portion 120. At this time, the locking projection 126 a formed on the drive shaft 126 is engaged with the locking recess 124 a formed on the inner peripheral surface of the hole 124.

  Next, when the operation knob 112 is rotated in order to change the gauge width of the gauge section 104, the rotational force of the operation knob 112 is operated through the operation section side bevel gear 128 and the movable section side bevel gear 130. It is transmitted to the shaft 134. Since the movable portion operating shaft 134 is rotatably held through the operating shaft accommodating hole 136 formed in the sliding cylinder portion 120, the movable portion operating shaft 134 is rotated as the movable portion operating shaft 134 rotates. ), The sliding cylinder portion 120 moves in the width direction of the gauge portion 104. For this reason, the movable portion base end portion 108b connected to the sliding cylinder portion 120 also moves in the width direction of the gauge portion 104 in conjunction with each other. Therefore, as shown in FIG. It moves in a direction away from the fixed part 106. For this reason, the gauge width of the gauge part 104 is expanded.

  Thereafter, when the gauge width of the gauge portion 108 has been set to a desired value, the operation knob 112 is driven by pulling the operation knob 112 as shown in FIG. 7C in order to maintain the gauge width after the setting. The operation unit side bevel gear 128 is separated from the movable unit side bevel gear 130 via the shaft 126. By pulling the operation knob 112 in this way, the power when the operation knob 112 is rotated is not transmitted to the movable portion operating shaft 134 via the operation portion side bevel gear 128 and the movable portion bevel gear 130. As shown in FIG. 8C, the movable part 108 is fixed without moving with respect to the fixed part 106. At this time, as described above, the operating projection side bevel gear 128 is moved to the movable portion by the locking convex portion 126a detached from the locking concave portion 124a by being pulled by the operating knob 112 being locked to the outer surface side edge portion 124b. Since the state apart from the side bevel gear 130 is maintained, the movable portion 108 is fixed without moving with respect to the fixed portion 106.

  Further, as described above, the movable support shaft 122 is provided at the tip of the movable portion 108 so as to be connected substantially perpendicular to the movable portion 108 as shown in FIGS. 8B and 8C. . On the other hand, at the distal end of the fixed portion 106, a storage hole 125 that has substantially the same diameter as the movable support shaft 122 and can accommodate the movable support shaft 122 with respect to the distal end of the fixed portion 106 is a width direction of the gauge portion 104, that is, movable It is formed in substantially the same direction as the support shaft 122. Therefore, by providing the movable support shaft 122 and the storage hole 125 at the tip of the gauge unit 104, when the movable unit 108 is moved with respect to the fixed unit 106, the movable unit 108 is moved relative to the fixed unit 106. As a result, the gauge width of the gauge portion 104 is maintained in a stable state.

  As described above, by operating the gauge width operation unit 110 provided in the nail gap gauge 100 for gaming machines in the present embodiment as the above-described configuration, the user can adjust the nail gap of the pachinko machine 1 during the work of adjusting the nail gap. By turning the operation knob 112 with a finger or the like holding the grip portion 102, the gauge width of the gauge portion 104 can be easily changed with one hand. For this reason, when changing the gauge width of the gauge part 104 used for nail space | interval adjustment, since the effort which replace | exchanges a plate gauge member conventionally can be omitted, the work efficiency of nail space | gap adjustment improves.

  In addition, after changing the gauge portion 104 to a desired gauge width, the operation knob 112 is pulled and locked, so that the power when the operation knob 112 is rotated is operated by the operation portion side bevel gear 128 and the movable portion side bevel gear 130. Therefore, the set desired gauge width is maintained, and it is possible to prevent the gauge width from being changed due to an impact when hitting the nail with a hammer or the like during the nail interval adjustment operation. It becomes like this.

  Next, the operation of adjusting the nail interval using the gaming machine nail interval gauge 100 of the present embodiment will be described with reference to the drawings. FIG. 9 is a diagram for explaining the operation when the gaming machine nail spacing gauge 100 of the present embodiment is inserted between the nails, and FIG. 10 shows the nail spacing gauge 100 for the gaming machine of the present embodiment. It is a front view from the gauge part side at the time of inserting between them. In the following description, it is assumed that the nail interval (under-bump interval) is set to 11.2 millimeters.

  First, a user such as a measurer who adjusts the nail interval adjusts the gauge width of the gauge portion 104 to 11.2 millimeters while operating the gauge width operation portion 110 of the nail interval gauge 100 for gaming machines. Then, the inter-nail contact portion 104 a held on the tip side of the gauge portion 104 by gripping the grip portion 102 is positioned in the lower region of the nail 11 so as to be substantially parallel to the game board 3.

  Next, the nail interval gauge 100 is moved in the direction indicated by the arrow A1 in FIG. 9 as it is, and the inter-nail contact portion 104a of the gauge portion 104 is inserted between the nails. When there is a gap between one or both sides of the inter-nail contact portion 104a and the nail 11 when inserted, the nail gap gauge 100 for gaming machines is slightly in front of the user (FIG. 9). 10 in the direction indicated by arrow A2), as shown in FIG. 10, the contact between the upper surface side of the inter-nail contact portion 104a and the lower surface side of the head 13 of the nail 11 is confirmed. When the nail 11 is in contact with the lower surface side of the head 13 at the time of insertion, the under-bump interval between the nails is approximately 11.2 millimeters. The nail contact portion 104a does not move. On the other hand, when the inter-nail contact portion 104a cannot be inserted between the nails, the nail interval is narrower than 11.2 millimeters. Therefore, the nail interval can be reduced by hitting and bending the nail 11 in a desired direction with a tool such as a hammer. To spread. Alternatively, the inter-nail contact portion 104a having a gauge width of 11.0 mm, for example, and a narrower gauge width is inserted to determine whether insertion is possible and, if possible, how much margin (gap) is present. You may make it spread after confirming.

  Once expanded, the inter-nail contact portion 104a whose gauge width is adjusted to 11.2 millimeters is inserted between the nails in the same procedure as described above. In this case as well, whether or not insertion is possible, that is, whether the interval is sufficiently wide, Further, the nail interval is adjusted while subtly determining how much resistance is received from the nail 11 when inserted and pulled, and how large the gap is when inserted. If it is too wide, the nail 11 is struck from the opposite direction to narrow the distance between them. When adjusting, if the nail contact portion 104a is inserted in small increments, such as tapping to insert and tapping to insert, efficient nail interval adjustment can be performed. When the temporary adjustment is completed, it is preferable to confirm that the inter-nail contact portion 104a adjusted to 11.4 millimeters having a gauge width wider than 11.2 millimeters is inserted between the nails and not spread too much.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to the example which concerns. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  That is, the configuration of the gauge width operation unit provided in the nail gap gauge for gaming machines according to the present invention is such that the movable unit 108 of the gauge unit 104 is fixed by rotating the operation knob 112 as in the first embodiment. Although the gauge width is adjusted by moving it in the gauge width direction with respect to 106, the configuration of the gauge width operation unit is not limited to such a configuration.

  For example, a gage width operation unit 210 that changes the gage width of the gage unit 204 may be replaced with a slider 212 that slides in the gage width direction, such as a gaming machine nail interval gauge 200 shown in FIG. At this time, the slider 212 provided at the distal end portion 202a of the grip portion 202 is slidably fitted in a guide groove 218 formed so as to move in the gauge width direction. Further, a proximal end portion 208b of the movable portion 208 is disposed on a side surface of the distal end portion 202a of the grip portion 202 with respect to the surface on which the gauge width operation portion 210 is provided. A sliding member 220 that slides in the direction is connected substantially vertically. By sticking or integrally molding the slider 212 to the sliding member 220, the sliding member 220 simultaneously moves in the gauge width direction in accordance with the moving operation of the slider 212. With this configuration, the movable portion 208 moves in the gauge width direction with respect to the fixed portion 206, so that the gauge width of the gauge portion 204 can be changed.

  At this time, a locking recess 218a that engages with a locking protrusion 212a provided on the side of the slider 212 in the length direction is provided on either side of the guide groove 218 in the length direction. When the gauge part 204 reaches a desired gauge width, it becomes a movable part fixing means for fixing the movable part 208 so as not to move in the gauge width direction. Further, as a gauge width display means for displaying the gauge width of the gauge portion 204 corresponding to the moving amount of the movable portion 206, a scale 216 is provided at the tip portion 202a so as to correspond to the locking recess 218a.

  Further, as in the first embodiment, as shown in FIG. 11, the movable support shaft 222 is provided at the distal end portion 208a of the movable portion 208 so as to be connected substantially perpendicular to the movable portion distal end 208a. It is done. On the other hand, the distal end portion 206 a of the fixed portion 206 has a storage hole portion 224 having a diameter substantially the same as that of the movable support shaft 222 and capable of accommodating the movable support shaft 222 in the distal end portion 206 a of the fixed portion 206. It is formed in the direction, that is, in substantially the same direction as the movable support shaft 222. In this manner, by providing the movable support shaft 222 and the storage hole 224 in the inter-nail contact portion 204a provided on the distal end side of the gauge portion 204, the movable portion is movable with respect to the fixed portion 206 as in the first embodiment. When the portion 208 is moved, the movable portion 208 does not shake with respect to the fixed portion 206, and the gauge width of the gauge portion 204 is maintained in a stable state.

It is a front view which shows schematic structure of the pachinko machine provided with the nail which is a game machine. It is an enlarged view around the head of a nail provided in a gaming machine. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective view of a nail gap gauge for gaming machines according to a first embodiment of the present invention. It is an external appearance top view of the nail space gauge for game machines of the embodiment. It is a front view from the gauge part side of the nail gap gauge for gaming machines of the embodiment. FIG. 4 is a cross-sectional view taken along line AA of the external perspective view of the nail gap gauge for gaming machines in the same embodiment shown in FIG. 3. It is the figure which showed simply the cross section of the gauge width operation part with which the nail space gauge for gaming machines in the same embodiment is equipped, (a) shows the cross section of the gauge width operation part before the gauge width change operation, (b ) Shows a cross section of the gauge width operation section during the gauge width change operation, and (c) shows a cross section of the gauge width operation section after the gauge width change operation. FIG. 7 is a plan view schematically showing the periphery of the gauge portion corresponding to FIG. 7 in order to explain the position of the movable portion with respect to the fixed portion when the gauge width operation portion provided in the nail gap gauge for gaming machines in the same embodiment is operated. (A) is a plan view around the gauge width operation unit before the gauge width change operation, (b) is a plan view around the gauge width operation unit during the gauge width change operation, (c) It is a top view of the gauge width operation part periphery after a gauge width change operation. It is a figure explaining the operation | movement at the time of inserting the nail space | gap gauge for game machines of the same embodiment between nails. It is a front view from the gauge part side at the time of inserting the nail gap gauge for gaming machines of the embodiment in between the nails. It is an external appearance top view which shows the modification of the gauge width operation part with which the nail space | gap for game machines in the same embodiment is equipped.

Explanation of symbols

1 Pachislot machines (pachinko machines)
11 Nail 100 Nail spacing gauge 102 for gaming machines Grip 104 Gauge portion 106 Fixed portion 108 Movable portion 110 Movable portion operating means (gauge width operating portion)
112 Movable part operation means (operation knob)
114 Gauge width display means (instruction part)
116 Gauge width display means (scale)
126 switching means (drive shaft)
126a Movable part fixing means (convex part)

Claims (4)

A gripping portion that is gripped by a user when measuring the interval between nails driven into the gaming machine, and a gauge portion that is disposed on the distal end side of the gripping portion and is inserted between the nails to measure the nail interval. In the nail gap gauge for gaming machines,
The gauge part includes a fixed part fixed to the grip part, and a movable part movable with respect to the fixed part in the width direction of the gauge part,
The gripping part includes a movable part operating means for moving the movable part in the width direction with respect to the fixed part, and a movable part for fixing the movable part when the gauge part reaches a desired gauge width. Fixing means;
A nail interval gauge for gaming machines, comprising:   The movable part fixing means includes switching means for switching the movable part so that the movable part moves from the operating state in which the movable part can move in the width direction relative to the fixed part to the inoperable state incapable of moving. The nail gap gauge for a gaming machine according to claim 1.   At least one of the gripping part and the movable part operating means is provided with a gauge width display means for displaying the gauge width of the gauge part corresponding to the amount of movement of the movable part. The nail gap gauge for gaming machines according to claim 1 or 2.   The game according to any one of claims 1 to 3, wherein the grip portion is provided with a grip portion having a substantially cylindrical shape whose diameter is larger than the gauge width of the gauge portion. Machine nail interval gauge.

Images