JP3922612B2 - Pachinko ball lifting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a lifting device for lifting pachinko balls, that is, lifting from a low position to a high position (hereinafter referred to as “lifting device” as appropriate).
[0002]
[Prior art]
  As a conventional lifting device, for example, there is a lifting device (hereinafter referred to as “first conventional device”) disclosed in Japanese Patent Application No. 9-233397 filed by the present applicant. The first conventional apparatus includes a cylindrical body having a plurality of spiral grooves formed on the outer peripheral surface, a polishing member surrounding the outer peripheral surface of the cylindrical body, and an introducing means for introducing a pachinko ball into the spiral groove. The front guide member exerts a frictional force on the exposed portion of the pachinko ball received by the spiral groove, and the pachinko ball is lifted by this frictional force and rotation of the cylindrical body. Further, the introduction means of the first conventional apparatus is a short cylindrical body that is positioned below the guide member and concentrically surrounds the lower end portion of the cylindrical body while forming a gap through which the pachinko ball received by each spiral groove can pass. A plurality of introduction holes spaced circumferentially at the lower end portion of the short cylindrical body, and a guide piece protruding between the introduction holes on the wall surface of the short cylindrical body, and introducing pachinko balls from each introduction hole The pachinko balls received by the spiral grooves are raised to the position of the polishing member along the guide pieces by the rotation of the cylindrical body. The short cylindrical body has a structure that does not need to be rotated, but is rotated for reasons such as easy alignment of pachinko balls supplied to the introducing means.
[0003]
[Problems to be solved by the invention]
  The first conventional apparatus is a highly practical pumping apparatus that maintains satisfactory pumping efficiency. Although it is such a first conventional device, taking a replenishment system for replenishing pachinko balls as an example, there are various types of replenishment systems required depending on differences in the replenishment amount of pachinko balls, installation location, etc. Depending on the type of replenishment system, a higher pumping efficiency than that of the first conventional apparatus may be required. Therefore, the inventors who are developers and engineers repeated trial and error in search of higher transport efficiency. The inventors first focused on introduction means. As a result of rotating the introduction means of the first conventional apparatus for the reason described above, the pachinko ball which is about to be received from the introduction hole of the introduction means, although depending on the rotation speed of the short cylinder, There was a case where I played it without accepting it. The inventors thought that if the problem of playing such a pachinko ball was solved, the lifting efficiency could be further increased. In addition, the pachinko balls introduced by the introducing means are sometimes repelled by the cylindrical body without being introduced into the spiral groove. Furthermore, it is common that the spiral groove accepts one pachinko ball at a time as the cylindrical body rotates. The inventors also paid attention to the fact that it could be increased.
[0004]
  As a method for increasing the pumping efficiency, there is a method in which a pachinko ball near the introduction hole (facing the introduction hole) is pushed in or pulled in by some method. However, the inventors did not want to adopt a complicated mechanism. This is because, when a complicated mechanism is employed, it is generally easy to break down, resulting in an expensive lifting device. As a result of repeated experiments, the method developed by the inventors is a method of drawing a pachinko ball facing the introduction hole into a hollow portion surrounded by a short cylindrical body by a magnetic force. Furthermore, a method of drawing the drawn pachinko ball into the spiral groove by magnetic force has been devised. Accordingly, the inventors have investigated the prior art and found the prior art described below.
[0005]
  The prior art discovered by the inventors is an apparatus disclosed in Japanese Utility Model Publication No. 53-88286 (hereinafter referred to as “second conventional apparatus”). A second conventional apparatus includes a helical body (cylindrical body) having a spiral groove formed on the outer peripheral surface, a motor (cylindrical body rotating means) for rotating the cylindrical body, and a pachinko ball in the helical groove of the helical body. A cylindrical permanent magnet and a helical coil (introduction means) for introduction are provided. The cylindrical permanent magnet is disposed at the lower end portion of the helical body, and the helical coil surrounds the cylindrical permanent magnet. The helical coil rotates, and the pachinko balls attracted by the cylindrical permanent magnet are raised by the rotation, and the pachinko balls are introduced into the spiral groove. Moreover, the polishing member surrounding the intermediate part of the spiral body is provided, and the pachinko balls to be fed are polished. That is, the second conventional device is not a device having a short cylindrical body like the first conventional device, but the helical coil that rotates the adsorbed pachinko ball by adsorbing the pachinko ball to a stationary cylindrical permanent magnet. And is introduced into the helical groove of the helical body located at the top.
[0006]
  However, the introduction means employed by the second conventional apparatus is merely configured to push up the pachinko balls adsorbed on the cylindrical permanent magnet as described above by the rotating helical coil, so these pachinko balls Is not necessarily configured to be actively introduced into the spiral groove. That is, the helical coil is only received in the helical groove that passes through in a timely manner when pushed up to the upper end of the cylindrical permanent magnet among the many pachinko balls attracted by the cylindrical permanent magnet. If the timing of raising the pachinko ball by the spiral coil and the passage of the spiral groove is bad, the pachinko ball pushed up will not be accepted by the spiral groove, or will collide with the mountain part between the spiral groove and the spiral groove, etc. And is expected to fall. In addition, since the pachinko balls are not aligned and introduced into the spiral groove, there is a possibility that a plurality of pachinko balls may be received in one spiral groove at the same time and cause a ball engagement. This does not mean that the pumping efficiency is high. The problem to be solved by the present invention is to allow the supplied pachinko balls to be received in the spiral groove as efficiently as possible, thereby providing a lifting device having high lifting efficiency.
[0007]
[Means for Solving the Problems]
  In order to solve the problems of the second conventional apparatus described above, the inventor assumed that the basic function of the first conventional apparatus had the premise of using a magnetic force to introduce a pachinko ball into the spiral groove. We have improved this without sacrificing the benefits, and have succeeded in further increasing the efficiency of transportation. The section of the present invention will be described in detail again.
[0008]
Configuration of the invention described in claim 1
  A lifting device according to the invention described in claim 1 (hereinafter referred to as “lifting device of claim 1”) includes a spiral groove formed on an outer peripheral surface of a cylindrical body, and a cylinder for rotating the cylindrical body. Body rotation means, introduction means for introducing a pachinko ball into the spiral groove, insertion means for introducing the pachinko ball into the introduction means, and ascending guidance of the pachinko ball introduced into the spiral groove And a guide member.
[0009]
  The structure of the “input means” corresponds to any structure that can be adopted by those skilled in the art within the scope of the object of the present invention. The “guide member” corresponds to any form that can be adopted by those skilled in the art, and is generally arranged around a cylindrical body. The “spiral groove” may be at least one, and may be a plurality. When a plurality of spiral grooves are provided, more pachinko balls can be lifted per unit time as compared to a single cylindrical body under the same conditions. As long as the shape of the “spiral groove” is such that the pachinko ball is partially received, whether the cross section is an arc shape, a V shape, a trapezoidal shape, or any other shape It doesn't matter if it is.
[0010]
  The greatest feature of the lifting device according to claim 1 is that the introduction means has a short cylindrical body that concentrically surrounds the lower end portion of the cylindrical body while forming a gap through which the pachinko balls introduced into the spiral groove can pass. And an introduction hole group for introducing a pachinko ball that is circumferentially separated at a lower end of the short cylinder, and a guide piece group that protrudes from an inner wall surface of the short cylinder located between the adjacent introduction holes, A magnetic means having a magnetic force for drawing a pachinko ball facing the introduction hole into the hollow portion surrounded by the short cylindrical body is disposed in the hollow portion.The short cylinder is configured to be rotated by the cylinder rotating means in the same direction as the rotation of the cylinder and at a lower speed than the rotation speed of the cylinder.It is characterized by.
[0011]
  The reason why the cylindrical body is expressed as “short” is to clarify that the total length of the cylindrical body is shorter than the total length of the cylindrical body. “The gap through which the pachinko ball introduced into the spiral groove can pass” means that the exposed part of the pachinko ball once introduced into the cylindrical body (spiral groove) surrounded by the short cylindrical body remains in its receiving state. It means a gap between the inner wall surface of the short cylindrical body that can rotate with the rotation of the cylindrical body and the cylindrical body. “Concentrically enclose” means that the center of the cylindrical body and the center of the short cylindrical body are surrounded in a substantially matched state. Here, the expression “substantially” is intended to include “center misalignment” included in the “match” with parts (product) accuracy, play at the time of engagement between parts, and the like. Since the “introducing hole” is a hole for introducing a pachinko ball, it may be any shape hole as long as at least one pachinko ball can pass through. The introduction hole is a concept including not only “hole” but also “notch”. The form of the “guide piece” corresponds to any form that can be adopted by those skilled in the art within the scope of the object of the present invention. The method of forming the guide piece may be a method in which a corresponding portion of the wall portion of the short cylindrical body is raised, or a method of fixing another member constituting the guide piece at a corresponding location. The “magnetic means” may be any means as long as it has a magnetic force for drawing the pachinko ball facing the introduction hole into the hollow portion surrounded by the short cylindrical body. For example, a natural magnet, a member having a coercive force due to the action of a magnetic material such as magnetic rubber or magnetic resin, an electromagnet that softens magnetized and becomes a magnet only while an electric current is applied, correspond to this magnetic means. To do. The number of magnetic force means may be one or two or more. Further, although the method and position of arranging the magnetic means depends on the form of the magnetic means and the strength of the magnetic force, the pachinko balls facing the introduction hole can be drawn into the hollow portion of the short cylindrical body through the introduction hole. Any method and position may be used. The relative positional relationship among the cylindrical body (spiral groove), the short cylindrical body, the guide piece, and the like is optimal for raising the pachinko balls.
[0012]
The effect of the invention described in claim 1
  The effects of the lifting device of claim 1 are as follows. First, the cylindrical body rotating means rotates the cylindrical body. The input means inputs a pachinko ball into the introduction means. The pachinko ball that has faced the introduction hole of the introduction means when being introduced passes through this introduction hole by the interaction of the magnetic force of the magnetic means and the introduction means and the introduction means and enters the hollow portion of the short cylindrical body. Drawn in. If there is no magnetic force means by this drawing, a part or all of the pachinko ball that would have been repelled by the short cylinder at the time of insertion is drawn into the hollow part of the short cylinder, so the pulling efficiency of the short cylinder is increased. The efficiency of introducing pachinko balls will increase as the pull-in efficiency increases. The pachinko ball introduced into the short cylinder is introduced into a spiral groove that passes along with the rotation of the cylinder, and is lifted by the interaction between the rotation of the cylinder and the guide piece. The pachinko ball introduced into the spiral groove is moved by the further rotation of the cylindrical body and the action of the guide piece while being held in the spiral groove, and comes into contact with the guide member. By this contact, the pachinko balls are prevented from sliding down in each spiral groove toward the downstream, and the pachinko balls are lifted by the prevention of the sliding-down and further rotation of the cylindrical body.
[0013]
  In addition to the effects described in the previous section, the following effects are also produced. That is, due to the difference between the rotational speed of the cylindrical body and the rotational speed of the short cylindrical body, the relative speed of the cylindrical body viewed from the short cylindrical body becomes slow. Since it became late, the acceptance of a pachinko ball becomes easy, and as a result, the effect that improvement of the pumping efficiency of the whole apparatus is realized arises. That is, when the short cylinder is not rotated, the speed of the cylinder viewed from the pachinko ball to be introduced is the rotation speed of the cylinder itself, whereas the short cylinder is in the same direction as the rotation of the cylinder and By rotating at a low speed, the rotation speed of the short cylinder is subtracted from the rotation speed of the cylinder, and as a result, the relative speed of the cylinder viewed from the short cylinder is reduced.
[0014]
  When the short cylinder is rotated, it is pushed and moved by the moving introduction hole, and the pachinko ball moves at a constant speed. As a result, the relative speed of the cylinder viewed from the pachinko ball becomes slow. If the relative speed is slow, the pachinko balls can be easily received by the spiral groove as compared with the case where the short cylinder is not rotated. In other words, by rotating the short cylindrical body, the probability that the pachinko ball is bounced by the columnar body is lower than when not rotating. In addition, the pachinko balls may be bounced by colliding with the wall surface of the short cylindrical body, but since the force that is played by the rotation of the short cylindrical body is weakened, the pachinko ball from the wall surface of the short cylindrical body to the introduction hole is weakened. Becomes easier to introduce. In this way, the probability of the pachinko balls being bounced is reduced, or the pachinko ball lifting efficiency is increased by weakening the force when bounced. As apparent from the above, although depending on the form of the short cylindrical body, it is understood that if the short cylindrical body has the same form, rotating it is preferable to introduce the pachinko ball into the spiral groove rather than rotating it.
[0015]
Furthermore, the pachinko balls are supplied to the short cylinder in any state (rose state, aligned state, etc.) Depending on whether or not the pachinko balls are supplied in an aligned state, the pachinko balls gathered around the introduction hole are agitated by the rotation of the short cylindrical body. By this stirring, it is possible to prevent a stagnation phenomenon due to the pachinko ball bridge that would otherwise have occurred, that is, the pachinko balls meshing with each other. The fact that the bridged pachinko balls are not introduced into the introduction hole is a factor that lowers the lifting and polishing efficiency. In addition, the rotation of the short cylinder has a function of easily guiding the pachinko balls facing around the short cylinder to the respective introduction holes, and this function can increase the feeding efficiency.
0016]
Configuration of the invention described in claim 2
  The pachinko ball lifting device according to the invention described in claim 2 (hereinafter referred to as “lifting device of claim 2”) is limited to the configuration of the lifting device of claim 1, and the magnetic force means is: It is comprised by the magnet piece distribute | arranged to the inner wall of the said spiral groove, The said magnet piece is comprised so that the pachinko ball drawn in the said short cylindrical body may be drawn in in the said spiral groove. The “inner wall of the spiral groove” is the wall surface that forms the spiral groove, that is, the wall surface of the part that is recessed from the surface of the cylinder to introduce the pachinko balls, in other words, the side surface of the cylinder is raised spirally It means a portion lower than the protruding top formed so as to wrap a part of the pachinko ball. The “magnet piece” may take any form as long as it does not interfere with the introduction of the pachinko ball into the spiral groove.
0017]
The effect of the invention described in claim 2
  In addition to the operational effect of the lifting device of claim 1, the lifting device of claim 2 has an action of drawing a pachinko ball having a magnet piece facing the introduction hole into a spiral groove located in the short cylindrical body by its magnetic force. Produces an effect. As a result, if there is no magnet piece, part or all of the pachinko balls that would have been repelled by the cylindrical body at the time of introduction are introduced into the spiral groove, so that the introduction efficiency of the pachinko balls is increased accordingly.
0018]
Configuration of the invention described in claim 3
  The pachinko ball lifting device according to the invention described in claim 3 (hereinafter referred to as “lifting device of claim 3”) is limited to the configuration of the lifting device of claim 2, and the magnet piece is It has a magnetic force capable of adsorbing at least one subsequent pachinko ball through the previous pachinko ball drawn into the spiral groove, and each spiral groove accepts the subsequent pachinko ball together with the previous pachinko ball It is formed in the shape to be formed. The "shape" that can accept the pachinko ball with the previous pachinko ball is the shape of the spiral groove that can introduce multiple pachinko balls that are connected in a rosy state by magnetic force as it is, such as For example, there is a shape having a depth dimension and a width dimension sufficient for the spiral groove to receive both pachinko balls.
0019]
The effect of the invention described in claim 3
  The lifting device according to claim 3 has the following effects in addition to the effects of the lifting device according to claim 2. First, a pachinko ball (following pachinko ball) that follows the pachinko ball is adsorbed through the pachinko ball (the previous pachinko ball) already drawn into the spiral groove. When the previous pachinko ball moves due to the rotation of the cylindrical body, the adhering pachinko ball also moves together with the previous pachinko ball. In this way, the spiral groove accepts the first pachinko ball and the latter pachinko ball in a daisy chain state. As is clear from this action, as described above, when the magnetic force of the magnet piece is increased and the subsequent pachinko ball is adsorbed together with the previous pachinko ball, the latter is not adsorbed. The number of pachinko balls that can be accepted is increased, and the amount of lift is increased accordingly.
0020]
Structure of the invention described in claim 4
  The pachinko ball lifting device according to the configuration of the invention described in claim 4 (hereinafter referred to as “lifting device of claim 4”) is limited to the configuration of the lifting device of claim 2 or 3, Auxiliary magnet pieces separate from the magnet pieces are arranged on the inner wall of the spiral groove, and the auxiliary magnet pieces have pachinko balls different from the pachinko balls drawn by the magnet pieces in the spiral grooves where the auxiliary magnet pieces are arranged. It is configured to be retracted. The lifting device according to claim 4 may be configured to include a magnet piece other than the magnet piece and the auxiliary magnet piece, and the other magnet piece may produce the same effect as the auxiliary magnet piece. Good.
0021]
The effect of the invention described in claim 4
  The lifting device according to claim 4 is the spiral in which the auxiliary magnet piece is arranged with a pachinko ball separate from the pachinko ball to which the auxiliary magnet piece pulls in the magnet piece in addition to the function and effect of the lifting device according to claim 2 or 3. Since it pulls in in a groove | channel, the effect that the fall of the amount of pumping can be prevented is produced. That is, for example, the timing of the pachinko ball and the spiral groove inserted by the input means does not match, so the magnet piece fails to pull the pachinko ball into the spiral groove, or the pachinko ball once pulled into the spiral groove has centrifugal force or the like It is possible that there is no pachinko ball that should be in the spiral groove by jumping out due to the action of, but in such a case, the auxiliary magnet piece pulls the pachinko ball into this spiral groove to compensate for the lifting amount. Therefore, the amount of pachinko balls that can be lifted can be increased in the sense of preventing a decrease in the amount of lift. In addition, it is conceivable that the magnet piece and the auxiliary magnet piece separately pull the pachinko ball into the spiral groove, and in this case, as compared with the case where there is only the magnet piece corresponding to the pachinko ball with which the auxiliary magnet piece is drawn, The secondary effect of increasing the amount can be expected.
0022]
Configuration of the invention described in claim 5
  The pachinko ball lifting device according to the invention described in claim 5 (hereinafter, referred to as “lifting device of claim 5”) is limited to the configuration of the lifting device of claim 1, and the magnetic force means includes: It is an introduction magnet piece arranged near each introduction hole inside the short cylinder. The “introducing magnet piece” may be any magnet as long as it has a magnetic force and a form in which a pachinko ball is drawn into the short cylindrical body through the introducing hole. The pull-in of the pachinko balls by the magnetic force of the introduced magnet piece may be only the pull-in by this magnetic force, but may be an auxiliary function of pull-in by applying another force in addition to this magnetic force. The method of arranging the introduction magnet piece depends on the shape of the introduction magnet piece, the strength of the magnetic force, the presence or absence of a force other than the magnetic force, etc., for example, attached or embedded in the vicinity of each introduction hole inside the short cylinder There is a method of mounting on a member located in the lower region of the short cylinder.
0023]
The effect of the invention described in claim 5
  The lifting device according to the fifth aspect produces the following operational effects in addition to the operational effects of the lifting device according to the first aspect. That is, the pachinko ball facing the introduction hole is subjected to the magnetic force of the introduction magnet piece (magnetic force means) (when there is a force other than the magnetic force, both the magnetic force and the force). When the pachinko ball is drawn into the short cylindrical body by this magnetic force, the place where the pachinko ball before being drawn is emptied, and the subsequent pachinko ball flows into this place. By pulling in the preceding pachinko ball, the subsequent pachinko ball quickly waits at the introduction position. The quick waiting of the pachinko balls improves the pulling efficiency of the pachinko balls into the hollow part of the short cylindrical body, thus contributing to the improvement of the feeding efficiency.
0024]
Configuration of the invention described in claim 6
  The pachinko ball lifting device according to the invention described in claim 6 (hereinafter referred to as “lifting device of claim 6”) is limited in the configuration of the lifting device of claim 5, and the introduction magnet piece is And a magnetic force capable of adsorbing at least one subsequent pachinko ball through the previous pachinko ball drawn into the short cylindrical body, and each spiral groove together with the previous pachinko ball and the subsequent pachinko ball. It is formed in a shape that can accept a ball. The "shape" that can receive the pachinko ball after the pachinko ball together with the previous pachinko ball is a spiral that can introduce a plurality of pachinko balls that are connected by a magnetic force in the same state as in the lifting device of claim 3. The shape of the groove.
0025]
The effect of the invention described in claim 6
  The lifting device according to the sixth aspect of the present invention produces the following operational effects in addition to the operational effects of the lifting device according to the fifth aspect. First, a pachinko ball (following pachinko ball) that follows the pachinko ball is adsorbed (at least one) through the pachinko ball (the previous pachinko ball) already drawn into the short cylinder. When the previous pachinko ball is introduced into the spiral groove along with the rotation of the cylinder, the adsorbed pachinko ball is also introduced together with the previous pachinko ball. In this way, the pachinko balls introduced in comparison with the case where the previous pachinko balls in the rosary connected state and the subsequent pachinko balls are configured so that the subsequent pachinko balls are not adsorbed by introducing the spiral grooves one after another. Increases the amount of feed.
0026]
The structure of the invention described in claim 7
  Claim7The pachinko ball lifting device according to the invention described in (hereinafter referred to as “claims”)7Is referred to as a "lifting device").6A limitation is added to the configuration of any one of the above-described lifting apparatuses, and the cylindrical body is composed of a plurality of short cylindrical bodies connected in the axial direction by a connecting structure. The individual lengths of the “short cylinders” may be the same or different from each other. Any structure that can be adopted by those skilled in the art corresponds to the connection structure that connects the respective short cylindrical bodies. Examples of such a structure include a connection structure including a screw and a connection structure in which connection surfaces are cut together.
0027]
The effect of the invention described in claim 7
  Claim7The lifting device of claim 1 to6In addition to the operational effects of any of the above-mentioned lifting devices, the cylindrical body is composed of a plurality of short cylindrical bodies, so that the short short cylindrical body is easier to transport and store than the cylindrical body, as well as manufacturing, processing and assembly. This produces the effect of simplifying handling such as maintenance and maintenance. That is, when performing the machining operation of arranging the magnet pieces on the inner wall of the spiral groove, a relatively short short cylindrical body is easier to perform the processing of arranging the magnet pieces than a single cylindrical body having a corresponding length. Also, when remodeling an existing cylinder, it is only necessary to replace the short cylinder with the magnet pieces with the corresponding existing short cylinder, which is more efficient than replacing the entire cylinder. Existing facilities can be used.
0028]
DETAILED DESCRIPTION OF THE INVENTION
  Next, an embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described with reference to the drawings. FIG. 1 is a perspective view of the lift polishing apparatus, and FIG. 2 is a cross-sectional view including the AA line of the lift polishing apparatus shown in FIG. 3 is a plan view including the ZZ line of the lifting and polishing apparatus shown in FIG. 1, and FIGS. 4 and 5 are perspective views of a cylindrical body. FIG. 6 is a cross-sectional view of a cylindrical body including a rotating shaft, and FIG. 7 is a partially enlarged view showing the relationship between the spiral groove of the cylindrical body and the polishing member. FIG. 8 is a longitudinal sectional view of the upper end portion of the outer cylinder, and FIG. 9 is a partial sectional view of the lower end portion of the lifting and polishing apparatus. FIG. 10 is a perspective view and a sectional view of the introducing means, and FIG. 11 is a conceptual diagram for explaining the operation of the introducing means. FIG. 12 is a partially enlarged view of the drive transmission means. 13 and 14 are conceptual diagrams for explaining the operation of this embodiment, and FIGS. 15 and 16 are conceptual diagrams for explaining the operation of a modified example of the introducing means.
0029]
Basic structure of lift polishing machine
  The lift polishing apparatus 2 shown in FIG. 1A is for supplying pachinko balls arranged on the outer cylinder 4 standing in the vertical direction from the base 18 located at the lowermost end and the lower end of the outer cylinder 4 (the upper surface of the base 18). The peripheral box (input means) 20, the introduction means 16 located at the substantially central portion of the peripheral box 20, and a motor 30 as a drive source. As shown in FIGS. 1D and 2, the outer cylinder 4 includes an inner space portion 3 having a circular cross section, and a cylindrical body 8 is rotated in the inner space portion 3. The cylindrical body 8 is provided with a plurality of spiral grooves 10, 10... On its outer peripheral surface, and is rotated by a drive transmission means described later. FIG. 1 (d) shows an abrasive sheet (abrasive member) 12 disposed around the cylindrical body 8 between the inner peripheral surface of the outer cylinder 4 and the cylindrical body 8. The polishing sheet 12 of the present embodiment serves as a guide member for polishing and guiding the pachinko balls. The polishing sheet 12 is fixed to the outer cylinder 4 so that it can be easily removed, and the used used polishing sheet 12 that has been removed can be cleaned or replaced with another polishing sheet 12 so that it can be easily recycled.
0030]
Configuration of outer cylinder
  The outer cylinder 4 shown in FIGS. 1 (a) and 2 has an outer cylinder main body 4a and a single door 6 hinged to the outer cylinder main body 4a. The single door 6 can be partially opened and closed. It is divided into upper, middle, and lower three stages. The upper end of the outer cylinder 4 is fixed with bolts (not shown) so that the ball delivery unit 14 can be easily removed, and the cylindrical body 8 can be easily attached and detached (described later).
0031]
Configuration of ball delivery unit
  As shown in FIGS. 1B and 8, the ball delivery unit 14 is provided with a bearing 14a at the substantially central portion of the upper end thereof, and this bearing 14a has a rotating shaft 8a in the axial direction (shown in FIG. 8). It is supported so that it can slide in the vertical direction. The reason why the slide is configured will be described later. The ball delivery unit 14 includes an absorption space portion 14s between the upper end surface 8t of the cylindrical body 8 and the lower end surface of the bearing 14a. In this embodiment, the absorption space portion 14s has various functions. Yes. First, the absorption space portion 14s has a function of storing the pachinko balls P lifted by the cylindrical body 8 and pushed onto the upper end surface 8t until the pachinko balls P are discharged from the upper end outlet 14b. In this embodiment, as will be described later, a plurality of spiral grooves 10 are formed in the cylindrical body 8 for the purpose of improving the lifting and polishing efficiency. For this reason, the number of pachinko balls P to be lifted and polished per unit time is very large. If such a large number of pachinko balls P are to be discharged at the same time, a problem such as clogging in the vicinity of the upper end outlet 14b is expected. Therefore, in order to prevent this, an absorption space portion 14s is provided. In this embodiment, in order to prevent clogging of pachinko balls, the upper end outlet 14b is provided with a discharge promoting magnet piece (hereinafter referred to as “discharge magnet piece”) 14m. The discharge magnet piece 14m will be described later. The volume of the absorption space portion 14s is set in consideration of the required lifting and polishing ability.
0032]
  Secondly, the absorption space portion 14s has a function of improving workability such as maintenance and inspection. That is, when performing maintenance, inspection, or the like on the cylindrical body 8 shown in FIG. 1 or the introduction means 16 installed below the cylindrical body 8, the cylindrical body 8 may have to be lifted to remove pachinko balls remaining inside. is there. In this case, if it is necessary to remove the bolt and remove the ball delivery unit 14 one by one, it is very troublesome and lacks workability. Therefore, the absorption space portion 14s is used as a kind of “play space”, and allows the upper end portion of the lifted cylinder body 8 to be received, so that the cylinder body 8 can be lifted without removing the ball delivery unit 14. It was. Not only when a person who performs maintenance or the like lifts, but also when the cylindrical body 8 is lifted due to foreign matter entering the introduction means 16, for example, the absorption space portion 14 s absorbs the lifted portion to form a cylinder. Since an excessive load is not applied to the body 8 or the like, there is also a function of preventing the cylindrical body 8 or the like from being damaged. When the cylindrical body 8 is lifted, the rotary shaft 8a also rises along with this, but this rise is absorbed by the bearing 14a. This is the reason why the bearing 14a is supported so that the rotary shaft 8a can slide.
0033]
  Finally, the absorption space 14s has a function for absorbing the thermal expansion of the cylindrical body 8. As will be described later, the pachinko balls P to be lifted and polished are in contact with the inner wall of the spiral groove 10 and the polishing member 12 while rotating, and the frictional heat generated at this time causes the cylindrical body 8 to move in the axial direction (see FIG. 8). In some cases, the upper end portion of the cylindrical body 8 is raised. The absorption space portion 14s has a function of receiving this thermal expansion component together with the sliding function of the bearing 14a. The degree of thermal expansion of the cylindrical body 8 varies depending on the form and material of the cylindrical body 8, but if there is a volume sufficient to perform the first function of storing the pachinko balls described above, generally this thermal expansion component Sufficient for absorption. In the present embodiment, as shown in FIG. 1, the radial dimension of the cylindrical body 8 is determined to be extremely small compared to the length dimension, and thus thermal expansion in the radial direction can be ignored. In addition, the absorption space portion 14s also functions as a ventilation path for releasing generated heat.
0034]
Magnet piece for discharge
  The discharge magnet piece 14m will be described with reference to FIG. The discharge magnet piece 14 m is embedded in the vicinity of the upper end outlet 14 b of the ball delivery unit 14. The discharge magnet piece 14m serves to attract the pachinko ball lifted into the absorption space portion 14s and guide it to the upper end outlet 14b. That is, since the polishing member 12 is not arranged in the absorption space portion 14 s, the pachinko balls lifted up to the upper end of the columnar body 8 are pushed out by the pachinko balls that are pumped up from the lower end of the columnar body 8. To the absorption space 14s. The pachinko balls thus discharged are discharged out of the figure from the upper end outlet 14b by the rotation of the cylindrical body 8. Since the discharge magnet piece 14m is embedded in the vicinity of the upper end outlet 14b of the ball delivery unit 14, the absorption space portion 14s of the pachinko ball lifted up to the upper end of the cylindrical body 8 is used.InsideWhen there is no pachinko ball lifted from the lower end of the cylindrical body 8 for some reason, the pachinko ball at the upper end of the cylindrical body 8 is adsorbed in the absorption space portion 14s, and the upper end Guide to outlet 14b.
0035]
Configuration of lower end of outer cylinder
  As shown in FIG. 9, an introducing means 16 for taking in a pachinko ball is provided in a lower region of the outer cylinder 4, and a rectangular peripheral box 20 is disposed so as to surround the introducing means 16. The surrounding box 20 is fixed to the base 18 as shown in FIG. The peripheral box 20 includes a mortar-shaped bottom wall 20a that inclines toward the center, and the pachinko ball P that has entered the ball collecting chamber 22 by using this inclination is provided around the introduction means 16 located in the center. It comes to collect. The ball collecting chamber 22 is configured to guide the pachinko balls P discharged from a pachinko machine, a pachinko ball counting machine, and the like through the junction passage 26 shown in FIG.
0036]
  Returning to FIG. 1A, the description of the outer cylinder 4 will be continued. The outer cylinder 4 includes an air supply port 32 at an intermediate portion in the length direction and a first exhaust port 34 at a lower end portion, and each port passes through a ventilation path (not shown) penetrating the outer cylinder 4. And communicated with the internal space 3. Further, as shown in FIG. 8, the ball delivery unit 14 at the upper end is provided with a second exhaust port 36 and a third exhaust port 37, the former via the ventilation path 36p, and the latter via the ventilation path 37p and the upper end outlet. Each communicates with the internal space 3 via 14b. The air supply port 32 is a port for sending air into the internal space 3 of the outer cylinder 4 by forced ventilation using a blower or the like or by natural intake, and includes a first exhaust port 34, a second exhaust port 36, The exhaust port 37 of 3 is a port for removing dust in the internal space portion 3 by sucking the sent air with a suction cleaner (not shown). The first exhaust port 34 and the second exhaust port are mainly intended to remove dust floating in the internal space 3, and the third exhaust port 37 is formed from fibers of the polishing sheet 12 that are fed together with the pachinko balls. The main purpose is to remove cotton dust and the like. However, these air supply ports 32 and the like may be provided as necessary, and may be omitted if sufficient measures for dust removal can be achieved by using the polishing sheet 12 that efficiently adsorbs dust. . As shown in FIG. 8, the pachinko balls P lifted up to the upper end of the outer cylinder body 4a are temporarily stored in the ball delivery unit 14 as described above, and sent out through the outlet 14b.
0037]
Cylinder structure
  The cylindrical body 8 shown in FIG. 4 is made of hard synthetic resin, and includes a plurality of spiral grooves 10 and 10 on the outer peripheral surface thereof as described above. Each spiral groove 10 is generally formed by cutting (carving) the outer peripheral surface of the cylindrical body 8. However, by providing a mountain line on the outer periphery of the cylindrical body 8, the spiral groove 10 is formed between the mountain line and the mountain line. There is also a method of forming the spiral groove 10. The spiral “groove” may take any form as long as a part of the pachinko ball is exposed and a substantial passage for receiving the other part is formed. For example, you may comprise by the pin etc. which pierced the mountain line mentioned above through the fixed space | interval. The spiral grooves 10 are arranged in parallel in order to use the outer peripheral surface of the cylindrical body 8 without waste and to increase the feeding efficiency. This is because it is not necessary to make the spaces between the spiral grooves 10 unnecessarily large if they are arranged in parallel. In the present embodiment, the magnetic force of the magnet piece 10m described later is set to such an extent that two or more pachinko balls can be adsorbed in a daisy chain state. The lower end inlet 10a is formed in such a shape (width dimension). Specifically, as shown in FIG. 4, the lower end inlet 10a is formed with a width that is wider than a portion other than the lower end inlet 10a (a portion above the lower end inlet 10a).
0038]
Spiral groove magnet piece
  In this embodiment, the magnet piece 10m is arranged on the inner wall of the lower end inlet 10a of each spiral groove 10, and the magnetic force of the magnet piece (magnetic force means) 10m and the short cylindrical body 40 are arranged in order to make the acceptance of the pachinko balls smoother. The pachinko balls are drawn into the respective spiral grooves 10 by utilizing the interaction between the three means consisting of the introduction means 16 whose main member is the bottom wall (input means) 20a of the surrounding box 20. If constituted in this way, if there is no magnet piece 10m, a part or all of the pachinko ball that would have been repelled by the cylinder 8 can be drawn into the spiral groove 10. This is because the amount of lift can be increased. Each magnet piece 10m is a cylindrical magnet piece having a diameter of about 5 millimeters and a thickness of about 4 millimeters, and is embedded in the inner wall of each spiral groove 10 so that one surface thereof is slightly lower than the inner wall. ing.
0039]
  Two magnet pieces 10m of this embodiment are embedded in each spiral groove 10. In the following, in order to distinguish between these magnet pieces 10m and 10m, the lower magnet piece 10m will be referred to as a magnet piece 10m1, and the upper magnet piece 10m will be referred to as an auxiliary magnet piece 10m2, respectively. The reason why the two magnet pieces 10m embedded in each spiral groove 10 are two is that pachinko like the magnet piece 10m1 due to the interaction between the magnetic force of the auxiliary magnet piece 10m2 and the bottom wall 20a of the introducing means 16. This is because the ball is drawn into the spiral groove 10, and the amount of the pachinko ball that is lifted is increased by the amount that the auxiliary magnet piece 10m2 is drawn compared to the case where only the magnet piece 10m1 is provided. As a secondary effect configured as described above, when the magnet piece 10m1 cannot pull the pachinko ball into the spiral groove 10 for some reason, or the pachinko ball once pulled for some reason jumps out of the spiral groove 10 In addition, the spiral groove 10 becomes empty as it is, but if the auxiliary magnet piece 10m2 draws the pachinko ball into the spiral groove 10, the spiral groove 10 will not remain empty, and the lift amount Is compensated for. Although the number of the magnet pieces 10m in this embodiment is two, the number of the magnet pieces 10m is three after adjusting various conditions such as the form of the introducing means 16 and the torque of the drive transmission means 160 described later. It may be increased as described above to further improve the pumping efficiency.
0040]
Magnetic strength of magnet piece
  Since the strength of the magnetic force of the magnet piece 10m1 in the present embodiment is the same as the strength of the magnetic force of the auxiliary magnet piece 10m2, the following description will be given only for the magnet piece 10m1. The strength of the magnetic force of the magnet piece 10m1 is generally a force other than the magnetic force of the magnet piece 10m1 on the pachinko ball to be introduced from the introduction hole 44 and the positional relationship with the form of the magnet piece 10m1 and the introduction hole 44. Set in consideration of whether or not works. If the magnetic force of the magnet piece 10m1 is too weak, the pachinko balls will not be smoothly received into the respective spiral grooves 10, so care should be taken. In the present embodiment, the magnetic force of the magnet piece 10m1 is such that two pachinko balls can be adsorbed in a daisy chain, that is, after following the previous pachinko ball via the previous pachinko ball adsorbed by the magnet piece 10m1. By setting the lower end inlet 10a of the above-described spiral groove 10 to a shape (width dimension) that can receive the pachinko ball as well as the previous pachinko ball, it is set to such an extent that the pachinko ball can be adsorbed. The pachinko balls together with the pachinko balls are received in the spiral groove 10. When the magnetic force of the magnet piece 10m1 is set to the above-described level, the magnetic force reaches the outside of the short cylindrical body 40. Therefore, the magnetic piece 10m1 draws the pachinko ball facing the introduction hole 44 into the hollow portion 40i of the short cylindrical body 40. It also serves as a means. According to experiments conducted by the inventors, good results were obtained when a magnet piece 10m having a magnetic force of 1500 to 2500 gauss was used.
0041]
  As shown in FIGS. 4 and 5, the number of the spiral grooves 10 may be at least one. However, considering the diameter of the cylindrical body 8 and the inclination angle of the spiral grooves 10 together with the diameter of the pachinko balls, the most efficient lifting is achieved. Set to be higher. Although the spiral groove 10 of this embodiment is 10 strips, it can be said that it is common to use 6 to 14 strips. This number is a number calculated from the relationship between the length of the circumference derived from this diameter and the diameter of the pachinko ball, taking into account the installation space in the pachinko game hall, etc. is there. If the number of spiral grooves 10 is increased to increase the lifting capacity, the diameter of the cylindrical body 8 may be increased. On the other hand, if the installation space is reduced, the number of spiral grooves 10 is increased. And the diameter of the cylindrical body 8 may be reduced. By reducing the diameter of the cylindrical body 8, the lifting and polishing efficiency is lowered. In this case, it is preferable to make up for this by installing another cylindrical body 8 using another space. The cross-sectional shape of the spiral groove 10 of this embodiment is formed in a substantially semicircular shape having a width dimension substantially equal to the diameter D of the pachinko ball P, as shown in FIG. The distance S between the deep part of the spiral groove 10 and the surface (polishing surface) of the polishing sheet 12 is such that the polishing sheet 12 contacts an exposed portion of the pachinko ball received in each spiral groove 10 and an appropriate frictional force ( The dimension is set to be slightly smaller than the diameter D of the pachinko ball P so that the pressing force acts on the pachinko ball. In addition, the cross-sectional shape of the spiral groove 10 may be any shape as long as it can be received with a part of the pachinko ball exposed, and can be lifted and polished without hindering the rotation of the received pachinko ball. In addition to the semicircular shape employed in the present embodiment, the shape includes, for example, a triangular shape shown in FIG.
0042]
  The cylindrical body 8 may be formed by a single member. However, as shown in FIG. 6, in this embodiment, for the convenience of handling such as assembly and maintenance, and maintenance and inspection and embedding of the magnet piece 10m, etc. One cylindrical body 8 is divided into three short cylindrical bodies 8p in the upper, middle and lower stages. In order to increase the total length of the cylindrical body 8, for example, the length of each short cylindrical body 8p is increased, or the number of middle short cylindrical bodies 8p is two or more. A connection structure for connecting the respective short cylindrical bodies 8p will be described in the next section. In this embodiment, each short cylinder 8p is formed in the same length, and each short cylinder 8p is formed in a hollow shape in order to reduce the weight. Among each short cylinder 8p, the rotating shaft 8a protrudes upward from the upper end surface 8t of the short cylinder 8p used at the uppermost stage, and two coupling holes are formed at the lower end 8u of the short cylinder 8p used at the lowermost stage. Leave 8h (see FIG. 9) downward.
0043]
Connecting structure of short cylinders
  The connection structure 8r between the short cylindrical bodies 8p will be described with reference to FIGS. Among the three, the short cylindrical body 8p used for the middle step portion has four connecting pins 87, 87. . , Four receiving holes 89, 89. Formed to receive each connecting pin 87 when connecting each short cylindrical body 8p to the other connecting surface 8c. . Are provided. The lower end surface of the uppermost short cylindrical body 8p has four receiving holes 89, 89, similar to the other connecting surface 8c described above. . And each connecting pin 87 protruding from the one connecting surface 8b described above is received. On the other hand, the upper end surface of the shortest cylinder 8p at the lowermost end has four connection pins 87, 87. . And is received by each receiving hole 89 of the other connecting surface 8c.
0044]
  The “connecting pin” 87 described above may be provided not only by planting but also by protruding a part of the connecting surface 8b, for example. The form of the connecting pin 87 does not matter. The form of the “receiving hole” 89 is determined according to the form of the connecting pin 87. The connecting pin 87 and the receiving hole 89 may be a pair, but it is preferable that the connecting pin 87 and the receiving hole 89 are two or more pairs for the purpose of more effectively preventing the connection displacement between the short cylindrical bodies. A connection structure does not prevent including a member, structure, etc. other than a connection pin and a connection hole. Such a connection pin 87 and the receiving hole 89 become a part of the connection structure 8r, and positioning (positioning) when connecting the respective short cylindrical bodies 8p to each other, and a connection shift after connection, particularly a circle. The positioning structure is configured to prevent circumferential displacement.
0045]
  In addition, since the engaging members (structure) other than the connecting pin 87 and the receiving hole 89 described above, for example, the short cylindrical bodies 8p are connected to each other by being fitted to each other or hooked to each other, and a connection shift at that time can be prevented. It goes without saying that any member (structure) can be adopted as the positioning structure.
0046]
  Further, the connecting plates 83 and 83 are screwed and fixed to the one connecting surface 8b and the other connecting surface 8c, respectively, so that both connecting plates 83 and 83 can be screwed by the connecting screw 85 as shown in FIGS. It is composed. In the present embodiment, the screw member 81 is configured by the connection plates 83 and 83 and the connection screw 85 described above, but may be configured by another connection member (structure), or the screw member 81 may be configured as described later. It may be omitted. Conversely, members and structures other than the screw member 81 may be included as necessary. When the screw member 81 is omitted, the connection between the connection pin 87 and the receiving hole 89 can prevent the connection between the respective short cylinders, and the respective short cylinders 8 can be prevented from being easily disconnected.pIt is necessary to set the length of the connecting pin 87 and the depth of the receiving hole 89 in consideration of the weight of the receiving hole 89. The screw member 81 constitutes a part of the connection structure 8r. In this embodiment, the screw member is tightened by inserting a tightening tool through the hollow portion of each short cylindrical body 8p as shown by an arrow T pointing from the top to the bottom shown in FIG. The method of tightening was adopted.
0047]
Composition of polishing sheet
  The polishing sheet 12 will be described with reference to FIGS. The polishing sheet 12 of the present embodiment is a sheet-like member formed by weaving thin synthetic resin fibers in order to enhance the polishing effect, and has elasticity in the thickness direction. The elasticity shown in FIG. The frictional force (pressing force) from the polishing sheet 12 is sometimes applied to the pachinko balls. The polishing sheet 12 is integrally formed on one surface of an insertion plate 12a made of a synthetic resin harder than the polishing sheet 12, or by means such as heat welding. Alternatively, the polishing sheet 12 may be affixed to both surfaces of the insertion plate 12a, and if one of them becomes dirty due to use, it may be turned over and the other used. The insertion plate 12a is used because it is difficult to insert only the elastic abrasive sheet 12 when inserting it into a slight gap between the inner peripheral surface of the outer cylinder 4 and the outer peripheral surface of the cylindrical body 8. This is to improve the workability by fulfilling the guiding role. The air supply port 32 and the like described above are provided in the outer cylinder 4.InsideWhen it is configured to remove dust in the subspace 3, it is preferable to provide a ventilation hole 12 h at an appropriate position of the insertion plate 12 a so that dust attached to the polishing sheet 12 can be sucked from there (see FIG. 1 ( d)). In addition to the sheet used in the present embodiment, the polishing sheet 12 is, for example, a paper sheet or a cloth sheet on which an uneven surface is formed or an abrasive is applied, a brush as shown in FIG. Can be used. The polishing surface of one polishing sheet 12 may be formed by gathering different types of sheets as described above. In this way, if it is made up of multiple members (materials) of different materials and uses the characteristics of each member (for example, resistant to moisture, resistant to oil stains, etc.), it can respond appropriately to humidity and types of stains. There is also a method of efficiently lifting and polishing.
0048]
Basic configuration of introduction method
  The introduction means 16 will be described with reference to FIGS. The introduction means 16 of the present embodiment is a mechanism for aligning pachinko balls. In the present embodiment, the pachinko balls to be introduced into the respective spiral grooves 10 are aligned. Pachinko balls are sequentially introduced into the spiral groove 10. As shown in FIG. 9, the introduction means 16 includes a short cylindrical body 40 concentrically surrounding the lower end region of the outer cylinder 4, that is, the lower end part of the cylindrical body 8, and the circumferential direction of the lower end part of the short cylindrical body 40. A plurality of introduction holes 44, 44. As shown in FIG. 10 (9), the short cylinder 40 further includes guide pieces 45, 45... Projecting between the introduction holes 44 on the adjacent inner wall surfaces. Each introduction hole 44 is a hole for introducing the pachinko ball in the surrounding box 20 into each spiral groove 10, and each guide piece 45 guides the pachinko ball received by each spiral groove 10 to rise by the rotation of the cylindrical body 8. It is a member for doing. Hereinafter, each member will be described in detail.
0049]
Introduction hole
  As shown in FIGS. 9, 11, and 13, each introduction hole 44 has a vertical dimension that allows at least two pachinko balls P to pass in the vertical direction and a width that is slightly larger than the diameter of the pachinko balls P. And is inclined in the rotational direction of the short cylindrical body 40 from the lower end toward the upper end. In other words, each introduction hole 44 is inclined such that its upper end is located on the advance side of the short cylinder 40 in the rotational direction X shown in FIG. 9 and its lower end is located on the delay side. The reason why each introduction hole 44 is inclined is to secure a space for providing a guide piece 45 described later. If the distance between the introduction holes 44 is sufficient, it is not always necessary to incline the introduction holes 44. As shown in FIG. 14, the end surface 49 of each introduction hole 44 positioned on the rotation direction delay side of the short cylindrical body 40 introduces a pachinko ball into the pachinko ball to be introduced (inside the short cylindrical body 40 and the guide piece). 45 directions).
0050]
  That is, when attention is paid to the pachinko ball P shown in FIG. 14, the end face 49 collides with the pachinko ball P by the rotation of the short cylindrical body 40, and at this time, the component force is applied to cause the pachinko ball P to move into the spiral groove 10. To the direction of the guide piece 45. Originally, the pachinko ball P can be guided into the short cylindrical body 40 only by the rolling force using the inclination of the bottom wall 20a, but more reliable introduction is realized by using the inclination of the end face 49. did. Although at least one introduction hole 44 is sufficient, the introduction hole 44 in this embodiment has 17 spiral grooves 10 of the cylindrical body 8 that are more than 10 as described above (FIG. 10 ( b)). It is considered that the greater the number of introduction holes 44, the greater the probability that the introduction hole 44 and the spiral groove 10 will meet and the introduction efficiency of the pachinko balls will increase. However, if the number of introduction holes 44 is increased, the short cylindrical body 40 will be increased accordingly. Must also be larger. In the present embodiment, the number is 17 according to experiments conducted by the inventors while taking into consideration restrictions due to the installation area. Of course, it is not necessary to limit the number of introduction holes 44 to 17. However, if the number of spiral grooves 10 is larger than the number of introduction holes 44, the spiral grooves 10 that cannot receive pachinko balls introduced from the introduction holes 44 are used. Therefore, it is preferable that the number of the introduction holes 44 be larger than the number of the spiral grooves 10 of the cylindrical body 8 so as not to cause this.
0051]
  As described above, each introduction hole 44 is formed to have a vertical dimension that allows at least two pachinko balls to pass while overlapping in the vertical direction. For example, as shown in FIG. 13, one introduction hole includes a magnet piece 10m1 arranged in 10 and an auxiliary magnet piece 10m2 arranged in the other spiral groove 10m2 located above the magnet piece 10m1. This is to make it visible from 44. The reason for this is that each of the magnet piece 10m1 and the auxiliary magnet piece 10m2 described above can draw a pachinko ball from one introduction hole 44 at the same time. The auxiliary magnet piece 10m2 draws the pachinko ball through the other introduction hole 44 where the magnet piece 10m1 arranged in the other spiral groove 10 in which the auxiliary magnet piece 10m2 is arranged is located on the downstream side for some reason. This is a case where the pachinko ball is not pulled in. Because, if the magnet piece 10m1 of the other spiral groove 10 draws a pachinko ball, the pachinko ball is lifted with the rotation of the cylindrical body 8 and comes to the position of the auxiliary magnet piece 10m2, so that it interferes. This is because a new pachinko ball cannot be drawn. On the other hand, when the cylindrical body 8 starts to rotate, the magnet piece 10m1 arranged in one spiral groove 10 visible from the introduction hole 44 and the auxiliary magnet piece 10m2 arranged in the other spiral groove 10 simultaneously draw the pachinko balls. A secondary effect can also be expected.
0052]
  The other reason for setting the vertical dimension of each introduction hole 44 as described above is the same as when the magnet piece 10m1 arranged in the spiral groove 10 introduces the pachinko ball from the specific introduction hole 44. This is because the auxiliary magnet piece 10 m 2 arranged in the spiral groove 10 can introduce the pachinko ball from another introduction hole 44 different from the specific introduction hole 44. That is, since the auxiliary magnet piece 10m2 is located at a higher position than the magnet piece 10m1, the auxiliary magnet piece 10m2 can draw the pachinko ball from the introduction hole 44 by setting the vertical dimension of the introduction hole 44 as described above. It was.
0053]
Guide piece
  The guide piece 45 will be described with reference to FIGS. The imaginary line on the right side in FIG. 13 indicates the spiral grooves 10 and 10. The guide piece 45 of the present embodiment protrudes between the introduction holes 44 on the inner wall surface of the short cylinder 40 and extends to the upper end of the short cylinder 40 along the introduction hole 44. The guide piece 45 guides the pachinko ball upward by the rotation of the cylindrical body 8 while contacting the pachinko ball of the portion protruding from the spiral groove 10 (exposed portion). It is preferable that the guide piece 45 is formed in a direction intersecting the spiral groove 10 and an angle β formed by both of them is a right angle or an obtuse angle as shown in FIG. Depending on the friction coefficient of the spiral groove 10 and the guide piece 45 with respect to the pachinko ball, etc., generally speaking, if the angle β is an acute angle, the pachinko ball may slide between the guide piece 45 and the spiral groove 10. Since it could not be pinched and could become clogged, it was set at a right angle or an obtuse angle to prevent such clogging. The guide piece 45 may be formed integrally with the short cylindrical body 40 or may be formed by bonding to the inner wall. Although not adopted in the present embodiment, the guide piece 45 may be constituted by a plurality of protrusions arranged at a predetermined interval so as to be substantially one member instead of one member.
0054]
skirt
  The skirt 42 provided in the introducing means 16 will be described with reference to FIGS. The skirt 42 is formed in a skirt shape that extends downward, and is fixed to the upper end of the short cylindrical body 40. Therefore, the skirt 42 rotates together with the short cylindrical body 40. An interval (a shown in FIG. 11) is set between the lower end of the skirt 42 and the bottom wall 20a of the surrounding box 20 so that one pachinko ball can pass (two or more cannot overlap). The short cylindrical body 40 is rotationally driven in the same direction as the cylindrical body 8 together with the skirt 42 and at a lower speed than the cylindrical body 8 by drive transmission means described later. The distance between the skirt 42 and the short cylindrical body 40 is set to a dimension larger than the diameter of one pachinko ball and smaller than two (b shown in FIG. 11) so that the pachinko ball does not enter between the skirt 42 and the clogging. is doing.
0055]
roller
  As shown in FIGS. 10 (b), 11 and 13, the short cylindrical body 40 is provided with a string spring 48 provided in a state of being biased in the central direction in the vicinity of the upper end portion of each introduction hole 44 on the outer peripheral surface thereof. The string spring 48 supports the same number of rollers 46 as the introduction holes 44 in a substantially horizontal direction in a freely rotatable state. The string spring 48 is configured such that each roller 46 to be supported faces the upper end of each introduction hole 44. The rollers 46 are for preventing the pachinko balls P that have been stacked or bounced up as shown by imaginary lines in FIG. 11 from colliding with the upper end of the introduction hole 44 and damaging or clogging them. That is, the pachinko ball heading toward the upper end of the introduction hole 44 collides with the roller 46, and the roller 46 that has received this collision is dropped to the outside of the short cylindrical body 40 by its rotation to prevent breakage and clogging. As described above, in the present embodiment, the height of each introduction hole 44 is sufficient, so that countermeasures against clogging are sufficient, but this roller is used just in case to cope with unexpected pachinko ball movement. 46 was provided. If it is determined that it is unnecessary, there is no problem in omitting the roller 46. Further, the method for supporting each roller 46 is not limited to the method using the string spring 48. However, if supported by the string spring 48, each roller 46 can be displaced in any direction with respect to the short cylindrical body 40 (each introduction hole 44) by the expansion and contraction, so that the pachinko ball can be moved accordingly. It is effective because it can respond flexibly.
0056]
Configuration of drive transmission means
  The drive transmission means 160 will be described with reference to FIGS. The drive transmission means 160 of the present embodiment has the functions of a cylinder rotating means for rotating the cylinder 8 and a cylinder rotating means for rotating the short cylinder 40. First, as shown in FIG. 12, the first drive gear 50 is attached to the output shaft 30 a of the motor 30. Next, the coupling holes 8h and 8h formed in the lower end portion 8u of the cylindrical body 8 shown in FIG. 9 are inserted into coupling pins 43p and 43p protruding upward from the upper end surface of the coupling plate 43 to couple them together. The drive shaft A protruding downward from the lower end surface of the connecting plate 43 is attached to a first driven gear 52 (shown by a broken line) located on the back side of the second drive gear 56 shown in FIG. Next, the first service gear 52 and the first drive gear 50 are connected by a toothed belt or chain 54. A second drive gear 56 is attached to the upper stage in the axial direction of the first driven gear 52 (the front side in FIG. 12). A second driven gear 58 is formed on the inner peripheral surface of the rotary table 41 fixed to the lower end of the short cylindrical body 40 so that the rotary table 41 acts as an internal gear. The second driven gear (internal gear) 58 and the second drive gear 56 are connected via the first idle gear 60 and the second idle gear 61.
0057]
  Each gear described above is set so that the short cylindrical body 40 rotates in the same direction as the rotation direction of the columnar body 8 and at a lower speed than the rotation speed of the columnar body 8. Depending on the direction in which the spiral groove 10 is formed, the rotating direction of the short cylindrical body 40 relative to the rotating direction of the cylindrical body 8 may be the forward direction or the reverse direction. In particular, in the latter case, the rotational direction of the short cylindrical body 40 and the rotational direction of the cylindrical body 8 are reversed. Therefore, attention should be paid to the formation direction of the spiral groove 10 when setting. In the present embodiment, the ratio of the rotational speed of the short cylindrical body 40 to the rotational speed of the cylindrical body 8 is set to a value that cannot be divided. The reason why the numerical value is set so that it cannot be divided will be described in detail in the column of the operation of the present embodiment.
0058]
Effects of this embodiment
  The operation of this embodiment will be described with reference to FIGS. First, the operation of the introduction hole 44 and the guide piece 45 will be described with reference to FIGS. The cylindrical body 8 and the short cylinder 40 are rotated by the functions of the motor 30 and the drive transmission means 160 shown in FIG. The pachinko ball group P collected in the ball collecting chamber 22 (see FIG. 1) flows toward the short cylindrical body 40 constituting the introducing means 16 by the inclination of the bottom wall 20a. At this time, the overlapping pachinko balls Pu collide with the skirt 42 and are prevented from flowing in, and only the lowermost pachinko ball group P is allowed to flow in. The pachinko ball group P that passes through the lower end of the skirt 42 and arrives at the short cylindrical body 40 and faces the introduction hole group 44 is subjected to inertia due to inflow on the bottom wall 20a and the pressing force received from the pachinko ball following the pachinko ball. It joins and tries to enter into the introduction hole 44 passed. The pachinko ball facing the introduction hole 44 is affected by the magnetic force of the magnet piece 10m1, in other words, the pachinko ball is in the magnetic field of the magnet piece 10m1, and the magnetic force, the bottom wall 20a, and the short cylindrical body 40 are used by the three parties. Due to the interaction, the pachinko ball is drawn into the hollow portion 40 i of the short cylindrical body 40 through the introduction hole 44. The auxiliary magnet piece 10m2 also acts in the same manner as the magnet piece 10m1.
0059]
  On the other hand, the pachinko ball group P that has faced the introduction hole group 44 may be balanced and become a bridge state, and may be stuck before it does not pass through the introduction hole group 44. Such a bridge of the pachinko ball group P is mainly broken by the rotation of the short cylindrical body 40 described above. Even if the skirt 42 is not provided, the pachinko ball group bridge is broken by the rotation of the short cylindrical body 40 (including the bridge in the height direction), so that the pachinko ball group P is aligned. There is no.
0060]
  The pachinko ball P that has passed through the introduction hole group 44 and entered the hollow portion 40i of the short cylindrical body 40 is subjected to a drawing (adsorption) action by the magnetic force of the magnet piece 10m1 and the auxiliary magnet piece 10m2 arranged in the spiral groove 10. However, the spiral groove 10 is received in the lower end inlet 10a. The pachinko ball P moves as shown by an imaginary line in FIG. 14 with the subsequent rotation of the cylindrical body 8 and contacts the guide piece 45. As described above, the magnet piece 10m1 of the present embodiment has a magnetic force capable of attracting the pachinko ball after following the pachinko ball after the attracted previous pachinko ball. The subsequent pachinko balls Pf are adsorbed through the air. The subsequent pachinko ball Pf is dragged and moved by the previous pachinko ball P along with the subsequent rotation of the cylindrical body 8 and is received by the wide lower end inlet 10 a of the spiral groove 10.
0061]
  Next, the relationship between the introduction hole 44 and the spiral groove 10 will be described. The spiral groove 10 passing through the introduction hole 44 is always in a state where the pachinko ball P can be received, that is, empty. The spiral groove 10 is emptied because the guide piece 45 on the downstream side in the rotation direction of the cylindrical body 8 of the introduction hole 44 comes into contact with the pachinko ball received in the spiral groove 10 and the pachinko ball moves in the downstream direction. This is because sliding is prevented, and the pachinko balls are lifted and guided (lifted) in accordance with the prevention of sliding and the subsequent rotation of the cylindrical body 8. The raised pachinko ball P is pushed out from the upper end of the short cylindrical body 40 and pushed between the spiral groove 10 and the polishing sheet 12. Here, the ascending guiding action of the pachinko balls P performed by the guiding piece 45 is now inherited by the polishing sheet 12.
0062]
  Since the polishing sheet 12 is arranged so as to be in contact with the exposed portion of the pachinko ball group P, the frictional force generated by this contact and the rotation of the cylindrical body 8 are polished at the same time as the pachinko ball is lifted. Since the pachinko balls P in the spiral groove 10 come into contact with the polishing sheet 12 while rotating, the exposed portions (the portions to be polished) are switched from one to the next, and the whole is uniformly polished. When the pachinko ball P collides with the roller 46 (see FIG. 13) as a result of some overlap for some reason in the vicinity of the introduction hole 44 of the skirt 42, the roller 46 exposed to the collision rotates while the spring member 48 rotates. It is displaced inward and outward with respect to the short cylindrical body 40 by expansion and contraction. Depending on the mode of displacement, the pachinko ball P involved in the collision is fed into the spiral groove 10 or is ejected to the outside of the short cylindrical body 40. This feeding or ejecting prevents the pachinko ball P from colliding with the upper end of the introduction hole 44.
0063]
  The pachinko ball group P lifted and polished by the rotation of the cylindrical body 8 and the action of the polishing sheet 12 gathers primarily in the ball delivery unit as shown in FIG. 8, and the gathered pachinko ball group P is a discharge magnet piece. It is guided to the upper end outlet 14b by the action of 14m and discharged out of the figure. As shown in FIG. 8, when a suction cleaner is connected to the second exhaust port 36 or the like, the air fed into the inner space 3 of the outer cylinder 4 from the air supply port 32 shown in FIG. The air is exhausted from the second exhaust port 36 and the third exhaust port 37 together with the dust generated by the above.
0064]
Modified examples of introduction means
  Based on FIGS. 15 and 16, the introducing means 16 which is a modification of the introducing means 16.´Will be described. In FIGS. 15 and 16, the member names and symbols used in the present embodiment are used for members that are the same as those in the present embodiment unless otherwise specified. Introduction means 16´11 is basically provided with the same configuration as the introducing means 16 shown in FIG. 11, and is characterized in that it includes an introducing magnet piece 41m that the introducing means 16 does not have. The introduced magnet piece 41m may be used together with the magnet piece 10m arranged in the spiral groove 10 of the cylindrical body 8, but according to the experiments by the inventors, it is sufficiently lifted by using only one of the magnet pieces. It was confirmed that efficiency could be improved. Therefore, here, the introducing means 16 provided with the introducing magnet piece 41m is provided.´Is used instead of the introducing means 16, and instead of the cylindrical body 8, a cylindrical body 80 on which no magnet piece 10m is arranged is used.
0065]
  The introduction magnet pieces 41m, 41m,... Are embedded in the bottom portion 41 of the short cylindrical body 40 in the vicinity of each introduction hole 44. The positional relationship between the introduction magnet piece 41m and the introduction hole 44 includes the strength of the magnetic force of the introduction magnet piece 41m and the action of inertia of the pachinko balls rolling on the bottom wall 20a constituting the bottom of the surrounding box (input means) 20. However, the pachinko ball facing the introduction hole 44 must be set to be drawn into the hollow portion 40 i surrounded by the short cylindrical body 40 through the introduction hole 44.
0066]
Action of deformation introducing means
  Introduction means 16´The operation is basically the same as that of the introducing means 16, but differs in the following points. That is, the pachinko ball P introduced by the bottom wall 20a is introduced into the short cylindrical body 40 from a plurality of directions through a plurality of introduction holes 44, 44,. To be accepted. At this time, the pachinko ball P facing the introduction hole 44 is subjected to a three-way interaction between the magnetic force of the introduction magnet piece 41m, the inertia caused by rolling on the bottom wall 20a, and the function of the short cylindrical body 40. When the preceding pachinko ball P is drawn, the place where the pachinko ball P was present before being drawn becomes empty, and the subsequent pachinko ball Pf flows into this place. As the preceding pachinko ball P is retracted, the subsequent pachinko ball Pf quickly waits at the introduction position. The quick waiting of pachinko balls contributes to the improvement of the lifting efficiency. Furthermore, the magnetic force of the introduced magnet piece 41m is set to a strength (or higher) that can adsorb the pachinko ball Pf that follows the pachinko ball P through the pachinko ball P.Of spiral groove 100The lower end entrance of the cylinder 8Of the spiral groove 10Bottom entrance10a(See Figure 4)As well as the pachinko balls P, the pachinko balls Pf are also adsorbed byOf the spiral groove 100 of the cylindrical body 80Since it can be introduced into the lower end entrance, the amount of feed increases compared to the case where only the pachinko balls P can be drawn.
0067]
【The invention's effect】
  According to the invention described in each claim, these pachinko balls can be efficiently transported by causing the supplied pachinko balls to be received in the spiral groove as efficiently as possible.
[Brief description of the drawings]
FIG. 1 is a perspective view of a lift polishing apparatus.
FIG. 2 is a cross-sectional view including the AA line of the lift polishing apparatus shown in FIG.
FIG. 3 is a plan view including the ZZ line of the lift polishing apparatus shown in FIG. 1;
FIG. 4 is a perspective view of a cylindrical body.
FIG. 5 is a perspective view of a cylindrical body.
FIG. 6 is a cross-sectional view of a cylindrical body including a rotation axis.
FIG. 7 is a partially enlarged view showing a relationship between a spiral groove of a cylindrical body and a polishing member.
FIG. 8 is a longitudinal sectional view of an upper end portion of an outer cylinder.
FIG. 9 is a partial cross-sectional view of the lower end portion of the lift polishing apparatus.
FIG. 10 is a perspective view and a cross-sectional view of the introducing means.
FIG. 11 is a conceptual diagram for explaining the operation of the introducing means.
FIG. 12 is a partially enlarged view of drive transmission means.
FIG. 13 is a conceptual diagram for explaining the operation of the present embodiment.
FIG. 14 is a conceptual diagram for explaining the operation of the present embodiment.
FIG. 15 is a conceptual diagram for explaining the operation of a modified example of the introducing means.
FIG. 16 is a conceptual diagram for explaining the operation of a modified example of the introducing means.
[Explanation of symbols]
      2 Lift polishing machine
      3 Internal space
      4 outer cylinder
      8 cylinder
      8a Rotating shaft
      8p short cylinder
      8r connection structure
    10 Spiral groove
    10m magnet piece (magnetic means)
    12 Abrasive sheet (guide member)
    14m introduction magnet piece (magnetic means)
    14s absorption space
    16 Introduction means
    20a inclined surface
    40 Short cylinder
    40i hollow part
    42 Skirt
    44 Introduction hole
    45 Guide piece
    46 Laura
    49 End face
    81 Screw member
  126 Guide piece
  160 Drive transmission means (cylindrical body rotation means)

Claims (7)

A spiral groove formed on the outer peripheral surface of the cylindrical body;
A cylinder rotating means for rotating the cylinder,
Introducing means for introducing a pachinko ball into the spiral groove;
Throwing means for throwing pachinko balls into the introducing means;
In a pachinko ball lifting apparatus comprising a guide member for ascending and guiding a pachinko ball introduced into the spiral groove,
The introduction means includes a short cylinder that concentrically surrounds the lower end of the cylindrical body while forming a gap through which the pachinko balls introduced into the spiral groove can pass, and a circumferential direction at the lower end of the short cylinder An introduction hole group for introducing a pachinko ball that is spaced apart, and a guide piece group that protrudes from an inner wall surface of the short cylindrical body located between the adjacent introduction holes,
Magnetic means comprising a magnetic force for drawing a pachinko ball facing the introduction hole into the hollow part surrounded by the short cylindrical body is arranged in the hollow part ,
The short cylindrical body is configured to be rotated by a cylindrical rotating means in the same direction as the rotational direction of the cylindrical body and at a lower speed than the rotational speed of the cylindrical body . Lifting device.   The magnetic force means is constituted by a magnet piece disposed on the inner wall of the spiral groove, and the magnet piece is configured to draw a pachinko ball drawn into the short cylindrical body into the spiral groove. The pachinko ball lifting apparatus according to claim 1.   The magnet piece has a magnetic force capable of adsorbing at least one subsequent pachinko ball through the previous pachinko ball drawn into the spiral groove, and each of the spiral grooves together with the previous pachinko ball The pachinko ball lifting apparatus according to claim 2, wherein the pachinko ball is formed in a shape that can accept the pachinko ball. Auxiliary magnet piece separate from the magnet piece is disposed on the inner wall of the spiral groove,
The said auxiliary magnet piece is comprised so that the pachinko ball different from the pachinko ball with which the said magnet piece was drawn in may be drawn in in the said spiral groove where the said auxiliary piece was arrange | positioned. Pachinko ball lifting device.   2. The pachinko ball lifting apparatus according to claim 1, wherein the magnetic force means is an introduction magnet piece arranged in the vicinity of each introduction hole inside the short cylindrical body. The introduction magnet piece has a magnetic force capable of adsorbing at least one subsequent pachinko ball through the previous pachinko ball drawn into the short cylindrical body; and
6. The pachinko ball lifting apparatus according to claim 5, wherein each of the spiral grooves is formed in a shape capable of receiving the subsequent pachinko ball together with the previous pachinko ball. The pachinko ball feeding device according to any one of claims 1 to 6 , wherein the cylindrical body is composed of a plurality of short cylindrical bodies connected in the axial direction by a connecting structure.

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