JPWO2019208131A1 - Product storage rack and product storage device - Google Patents

Abstract

A plurality of product storage columns 14 for storing products in a line along the extending direction of the product storage passage 14a, and each product storage column 14 are provided and driven in the product storage passage 14a extending in a straight line. In this case, the product storage column 14 is arranged side by side with a payout mechanism 20 for paying out the most downstream product arranged in the most downstream side among the products stored in the corresponding product storage passage 14a from the product storage passage 14a. In the case of the product storage rack 11, when a driving force applying means for applying a common driving force for operating each payout mechanism 20 and a payout command for the products stored in an arbitrary product storage column 14 are given. In addition, a driving force transmitting means for transmitting the driving force of the driving force applying means is provided only to the corresponding payout mechanism 20.

Description

The present invention relates to a product storage rack and a product storage device, and more specifically, a product storage rack and a product storage applied to a vending machine that sells beverages and the like contained in containers such as cans and PET bottles as products. It is about the device.

Conventionally, vending machines that sell beverages and the like contained in containers such as cans and PET bottles as products are known to be provided with a so-called slant truck.

This product storage rack has a plurality of product storage columns along the vertical direction for storing products in a row in a sideways posture in a product storage aisle that is inclined and extended in a manner of gradually lowering from the upstream side to the downstream side. Each product storage column is provided with a first stopper member, a second stopper member, and a linking member.

The first stopper member is oscillatingly arranged so as to move back and forth in the product storage passage. This first stopper member abuts on the most downstream product when it moves forward to the product storage aisle and regulates that the product is paid out, while when it moves backward from the product storage passage, the product is paid out. It is permissible to be The second stopper member is oscillatingly arranged so as to move back and forth in the product storage passage. This second stopper member comes into contact with the second product from the most downstream side when it moves forward to the product storage passage and regulates the movement of the product to the downstream side, while it moves backward from the product storage passage. Allows the movement of the goods.

The linking member links the first stopper member and the second stopper member, and is arranged so as to be slidable between the standby position and the payout position. This linking member is located at a standby position when the solenoid, which is a drive source, is driven and stopped, and moves the first stopper member forward and moves the second stopper member backward. Then, when the solenoid is driven to move from the standby position to the payout position, the first stopper member is moved backward and the second stopper member is moved forward.

In such a product storage rack, when a payout command for a product to be stored in one of the product storage columns is given, a solenoid corresponding to the product storage column is driven to move the linking member from the standby position to the payout position. As a result, the first stopper member moves backward from the product storage passage and the second stopper member moves forward to the product storage passage, so that the most downstream product of the product storage passage is paid out (for example, Patent Document). 1).

Japanese Unexamined Patent Publication No. 2012-194977

By the way, in the product storage rack as proposed in Patent Document 1 described above, the first stopper member, the second stopper member and the linking member provided in one product storage column are provided in another product storage column. It is driven independently of the first stopper member, the second stopper member, and the linking member, and the drive source is also different.

Therefore, when a plurality of product storage columns are arranged side by side to form a product storage rack, a drive source is required for each product storage column, and the product payout operations can be synchronized between arbitrary product storage columns. It was difficult to plan.

In view of the above circumstances, it is an object of the present invention to provide a product storage rack and a product storage device capable of satisfactorily synchronizing product payout operations between arbitrary product storage columns.

In order to achieve the above object, the product storage rack according to the present invention stores a plurality of products in a linearly extending product storage passage so that the products are lined up in a line along the extending direction of the product storage passage. A storage column and a payout that is provided for each of the product storage columns and, when driven, pays out the most downstream product arranged on the most downstream side among the products stored in the corresponding product storage passage from the product storage passage. It is a product storage rack provided with a mechanism and in which the product storage columns are arranged side by side, and is stored in an arbitrary product storage column and a driving force applying means for imparting a common driving force for operating each payout mechanism. When a delivery command for a product is given, only the corresponding payout mechanism is provided with a driving force transmitting means for transmitting the driving force of the driving force applying means.

Further, according to the present invention, in the product storage rack, the plurality of product storage columns store products in a line in a product storage passage that is inclined and extended in a manner of gradually lowering from the upstream side to the downstream side. The left and right widths of the products can be changed, and the payout mechanism is provided on the downstream side of the product storage passage, and in the standby state, the products stored in the product storage passage are the products stored in the product storage passage. While restricting the withdrawal from the product, the most downstream product is discharged from the product storage passage when the product operates, and the product is further displaceable in the left-right direction.

Further, according to the present invention, in the product storage rack, the product storage column is configured so that the product storage passage is merged with the product storage passage of the other product storage column and can be connected to the other product storage column. It is a feature.

Further, the product storage device according to the present invention is a product storage device configured by providing the product storage racks in a plurality of stages along the vertical direction, and the driving force applying means constitutes another product storage rack. It is characterized in that power given from a power source common to other driving force applying means is applied as the driving force.

Further, according to the present invention, in the product storage device, the payout mechanism has a lever member provided so as to be swingable in a manner of advancing and retreating with respect to the payout passage where the goods paid out from the product storage passage fall. A plurality of guide protrusions are provided along the vertical direction so as to project from the payout passage on the surface facing the payout mechanism while forming the payout passage, and the lever member drops the payout passage. When the product comes into contact with the product, the product is guided to a guide protrusion directly below the product while swinging in a manner of retreating from the payout passage.

Further, according to the present invention, in the product storage rack, the payout mechanism is stretched endlessly between a pair of front and rear pulleys that rotate around its own central axis and the pulleys, and extends itself by the rotation of the pulleys. A transport belt that is displaced in the direction is provided, and an upper extending portion of the transport belt between the pulleys constitutes the product storage passage, and the products are placed and stored so as to be lined up in the front-rear direction. When a payout command is given, the pulley is rotated to displace the transport belt so that the most downstream product is paid out.

Further, the product storage device according to the present invention is a product storage device configured by providing the product storage racks in a plurality of stages along the vertical direction, and the driving force applying means constitutes another product storage rack. It is characterized in that power given from a power source common to other driving force applying means is applied as the driving force.

According to the present invention, the driving force applying means imparts a common driving force for operating each payout mechanism constituting the side-by-side product storage columns, and the driving force transmitting means can be applied to any product storage column. When a payout command for stored products is given, the driving force of the driving force applying means is transmitted only to the corresponding payout mechanism, so that a drive source is not required for each product storage column and the number of parts is reduced. It is possible to reduce the manufacturing cost by the above. Moreover, not only a single payout mechanism but also a plurality of payout mechanisms can be synchronously driven. Therefore, there is an effect that the product payout operations can be well synchronized between the arbitrary product storage columns.

Further, according to the present invention, a plurality of product storage columns are provided so as to be arranged in the left-right direction, the left-right widths of the columns can be changed, and the payout mechanism is provided so as to be displaceable in the left-right direction. The payout mechanism can be displaced while changing the left-right width of the product storage column according to the size of the product to be used, and products having various sizes can be paid out while being stored while minimizing the empty space. Therefore, it is possible to efficiently store and pay out products having various sizes without any gaps.

FIG. 1 is a cross-sectional side view schematically showing a configuration of a vending machine to which the product storage device according to the embodiment of the present invention is applied. FIG. 2 is a schematic view schematically showing the product storage device shown in FIG. FIG. 3 is a perspective view showing one product storage rack shown in FIGS. 1 and 2. FIG. 4 is an exploded perspective view showing one product storage rack shown in FIGS. 1 and 2. FIG. 5 is a perspective view showing the shelves shown in FIGS. 3 and 4. FIG. 6 is a perspective view showing the payout mechanism shown in FIGS. 3 and 4. FIG. 7 is a perspective view showing the payout mechanism shown in FIGS. 3 and 4. FIG. 8 is a perspective view showing one payout mechanism shown in FIGS. 6 and 7. FIG. 9 is a perspective view showing one payout mechanism shown in FIGS. 6 and 7. FIG. 10 is a cross-sectional side view showing one payout mechanism shown in FIGS. 6 and 7. FIG. 11 is an exploded perspective view showing one payout mechanism shown in FIGS. 6 and 7. FIG. 12-1 is a perspective view showing the main body mechanism portion shown in FIGS. 8 to 11. 12-2 is a perspective view showing the main body mechanism portion shown in FIGS. 8 to 11. 13-1 is a perspective view showing the lever members shown in FIGS. 8 to 11. 13-2 is a perspective view showing the lever members shown in FIGS. 8 to 11. 14-1 is a perspective view showing the stopper members shown in FIGS. 8 to 11. 14-2 is a perspective view showing the stopper members shown in FIGS. 8 to 11. FIG. 15-1 is a perspective view showing the pedal members shown in FIGS. 8 to 11. 15-2 is a perspective view showing the pedal members shown in FIGS. 8 to 11. FIG. 16-1 is a perspective view showing a slider constituting the transmission mechanism shown in FIG. FIG. 16-2 is a perspective view showing a slider constituting the transmission mechanism shown in FIG. FIG. 17-1 is a perspective view showing a dock clutch constituting the transmission mechanism shown in FIG. FIG. 17-2 is a perspective view showing a dock clutch constituting the transmission mechanism shown in FIG. FIG. 18 is a perspective view showing a payout mechanism in a standby state. FIG. 19 is a schematic view showing a product storage passage when the payout mechanism is in the standby state. FIG. 20 is a perspective view of the payout mechanism showing the case where the slider slides. FIG. 21 is a perspective view of the payout mechanism showing the case where the slider slides. FIG. 22 is a perspective view of the payout mechanism showing a state in which the pedal member swings upward. FIG. 23 is a perspective view of the payout mechanism showing a state in which the pedal member swings upward. FIG. 24 is a schematic view showing a product storage passage when the pedal member swings upward. FIG. 25 is a schematic view showing a product storage passage when the pedal member swings further upward. FIG. 26 is an explanatory diagram showing the operation of the product paid out in the payout passage. FIG. 27 is a plan view of the product storage rack. FIG. 28 is a plan view of the product storage rack. FIG. 29 is a perspective view showing an external configuration of a modified example of the product storage rack according to the embodiment of the present invention. FIG. 30 is an enlarged perspective view showing a main part of the product storage rack shown in FIG. 29. FIG. 31 is an exploded perspective view of a main part of the product storage rack shown in FIG. FIG. 32 is an exploded perspective view of a main part of the product storage rack shown in FIG. FIG. 33 is an explanatory view showing the operation of the transmission mechanism shown in FIG. 30 in a cross section. FIG. 34 is an explanatory view showing the operation of the transmission mechanism shown in FIG. 30 in cross section. FIG. 35 is a perspective view showing a product storage device in which the product storage rack shown in FIG. 29 is provided in a plurality of stages.

Hereinafter, preferred embodiments of the product storage rack and the product storage device according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a cross-sectional side view schematically showing a configuration of a vending machine to which the product storage device according to the embodiment of the present invention is applied. The vending machine illustrated here sells a beverage contained in a container such as a PET bottle or a can as a product, and includes a main body cabinet 1 which is a main body of the vending machine.

The main body cabinet 1 is formed by appropriately combining a plurality of metal plates, and is formed in a rectangular parallelepiped shape having an opening (hereinafter, also referred to as a front opening) 1a on the front surface. Inside the main body cabinet 1, a storage chamber 2 having a heat insulating structure is defined so as to face the front opening 1a.

An outer door 3 and an inner door 4 are provided in the front portion of the main body cabinet 1. The outer door 3 opens and closes the front opening 1a of the main body cabinet 1. The inner door 4 is a door body having a heat insulating structure, and opens and closes the front surface of the accommodation chamber 2.

The storage room 2 is provided with a product storage device 10 and a product shooter 5. Although the details will be described later, the product storage device 10 stores the products and pays out the corresponding products in accordance with the payout order (sales order). The product shooter 5 is provided in the lower region of the product storage device 10, and is inclined so as to gradually decrease from the rear to the front. The product shooter 5 is for guiding the product paid out from the product storage device 10 to the product outlet 3a provided in the outer door 3 through the product carry-out port 4a provided in the inner door 4. The product delivery port 4a is opened and closed by the product delivery door 4b, and the product outlet 3a is opened and closed by the product delivery door 3b. The internal atmosphere of the storage chamber 2 is adjusted to a desired temperature by a cooling means or a heating means (not shown).

As shown in FIG. 2, the product storage device 10 is configured such that a plurality of product storage racks 11 are provided along the vertical direction between a pair of left and right base side plates 10a.

3 and 4 show one product storage rack 11 shown in FIGS. 1 and 2, respectively, FIG. 3 is a perspective view, and FIG. 4 is an exploded perspective view. As shown in FIGS. 3 and 4, the product storage rack 11 includes a shelf plate 12, a partition plate 13, and a payout mechanism 20.

The shelf plate 12 is formed by processing, for example, a sheet metal, and is provided so as to be inclined between the base side plates 10a so as to gradually decrease from the front to the rear. As shown in FIG. 5, the shelf board 12 has shelf side wall portions 12a extending upward at both left and right end portions. Further, the shelf board 12 is formed with a plurality of partition locking holes 12b having a longitudinal direction in the front-rear direction at predetermined intervals of, for example, about 20 mm along the left-right direction. Further, in the rear end portion of the shelf board 12, a plurality of mechanical locking holes 12c are formed along the left-right direction at predetermined intervals similar to the partition locking holes 12b.

The partition plate 13 is formed by processing, for example, a sheet metal, and is a long plate-shaped member having a longitudinal direction in the front-rear direction. A plurality of locking pieces 13a are formed on the partition plate 13 so as to project downward from the lower end portion.

By inserting the locking piece 13a of the partition plate 13 into an arbitrary partition locking hole 12b from above, the partition plate 13 extends to the upper surface of the shelf plate 12 in the front-rear direction. It is locked to the plate 12. By locking a plurality of such partition plates 13 between the shelf side wall portions 12a of the shelf plate 12, as shown in FIG. 3, a plurality of (four in the illustrated example) product storage columns are placed on the upper surface of the shelf plate 12. 14 can be configured in such a manner that they are arranged side by side.

These product storage columns 14 have a product storage passage 14a that is inclined and extended in a manner that gradually lowers from the front side, which is the upstream side, to the rear side, which is the downstream side, and the product is placed sideways in the product storage passage 14a. It is for storing so that they are lined up in a row.

A plurality of payout mechanisms 20 (four in the illustrated example) are provided along the left-right direction. As shown in FIGS. 6 and 7, these payout mechanisms 20 are provided in a state of being penetrated by a rotary drive shaft 30 which is a long rod-shaped member extending in the left-right direction.

The rotation drive shaft 30 has a polygonal column shape such as a hexagonal column, and the left end portion is connected to the central portion of the rotation transmission member 31 having a substantially disk shape. The rotation transmission member 31 is provided so as to be rotatable around its own central axis, which will be described in detail later, so that the rotation drive shaft 30 can also rotate around its own central axis. is there.

Next, the configuration of the payout mechanism 20 will be described. Although a plurality of payout mechanisms 20 are shown in FIGS. 6 and 7, since these payout mechanisms 20 have a common configuration, the configuration of one payout mechanism 20 will be described below, and others. The explanation of the payout mechanism 20 of the above is omitted.

8 to 11 show the payout mechanism 20 shown in FIGS. 6 and 7, respectively. FIGS. 8 and 9 are perspective views, FIG. 10 is a cross-sectional side view, and FIG. 11 is an exploded perspective view. As shown in FIGS. 8 to 11, the payout mechanism 20 includes a mechanism main body 21. The mechanism main body 21 is, for example, a housing made of a resin material, and houses a lever member 22, a stopper member 23, a pedal member 24, a transmission mechanism 40, and a sold-out detection unit 25.

As shown in FIGS. 12-1 and 12-2, such a mechanism main body 21 has a main body engaging portion 211 and a main body penetrating portion 212. In the following, the mechanism main body 21, the lever member 22, the stopper member 23, the pedal member 24, and the transmission mechanism 40 will be described in the directions shown in FIG.

The main body engaging portion 211 is formed at the front end portion of the mechanism main body portion 21, and is a resin spring-like portion that can be elastically deformed. The main body engaging portion 211 is formed with a locking projection 211a projecting forward and a pair of left and right locking hook portions 211b projecting forward below the locking projection 211a. is there. The locking projection 211a can be inserted into the mechanical locking hole 12c of the shelf plate 12, and the locking hook portion 211b is inserted when the locking projection 211a is inserted into any of the mechanical locking holes 12c. It can be locked to the lower end of the rear end of the shelf board 12.

The main body penetrating portion 212 is formed in a pair on the left and right at the rear end portions of the left and right side portions of the mechanism main body portion 21. A circular body through hole 212a having an inner diameter slightly larger than the maximum width of the rotation drive shaft 30 is formed in the body penetration portion 212, and the rotation drive shaft 30 penetrates the body through hole 212a. There is.

The lever member 22 is made of, for example, a resin material, and has a lever acting portion 221 and a lever penetrating portion 222 as shown in FIGS. 13-1 and 13-2. The lever acting portion 221 is a substantially flat plate-shaped portion.

The lever penetrating portion 222 is a pair of left and right portions formed so as to project forward from both left and right end portions on the front side of the lever acting portion 221. The lever penetrating portion 222 is formed with a circular lever penetrating hole 222a having an inner diameter slightly larger than the maximum width of the rotary drive shaft 30.

In such a lever member 22, the lever penetrating portion 222 is installed inside the main body penetrating portion 212 in such a manner that the lever acting portion 221 protrudes rearward from the mechanism main body portion 21, and the lever penetrating hole 222a is provided. It is housed in the mechanism main body 21 by penetrating the rotation drive shaft 30. Further, the lever penetrating portion 222 is provided with a lever regulating protrusion 222b that projects downward. The lever regulation protrusion 222b is inserted from above into the first regulation elongated hole 213 (see FIG. 9) formed in the lower part of the rear end of the mechanism main body 21. The first regulated elongated hole 213 is a hole having a longitudinal direction in the front-rear direction. As a result, the lever member 22 can swing around the central axis of the rotary drive shaft 30 within a range in which the lever regulating protrusion 222b abuts on the front edge portion and the trailing edge portion of the first regulated elongated hole 213.

The stopper member 23 is made of, for example, a resin material, and has a stopper acting portion 231 and a stopper arm portion 232 and a stopper penetrating portion 233 as shown in FIGS. 14-1 and 14-2. The stopper acting portion 231 is a portion extending along the left-right direction, and a stopper acting surface 231a is formed at the front end thereof. Further, a pedestal portion 231b slightly recessed from the upper surface of the stopper acting portion 231 is formed at the rear end portion of the stopper acting portion 231. The stopper arm portion 232 is a pair of left and right portions extending rearward from both left and right end portions of the stopper acting portion 231.

The stopper penetrating portion 233 is a pair of left and right formed so as to project rearward from the rear end portion of the stopper arm portion 232. The stopper penetrating portion 233 is formed with a circular stopper penetrating hole 233a having an inner diameter slightly larger than the maximum width of the rotary drive shaft 30.

In such a stopper member 23, each stopper penetrating portion 233 is installed inside the lever penetrating portion 222 in such a manner that the stopper acting portion 231 is inserted into the stopper opening 214 formed in the mechanism main body portion 21 from above. The rotary drive shaft 30 penetrates each stopper through hole 233a and is housed in the mechanism main body 21. Further, the stopper penetrating portion 233 is provided with a stopper regulating protrusion 233b that projects downward. The stopper regulation protrusion 233b is inserted from above into the second regulation elongated hole 215 (see FIG. 9) formed in the lower part of the rear end of the mechanism main body 21. The second regulated elongated hole 215 is a hole having a longitudinal direction in the front-rear direction. As a result, the stopper member 23 can swing around the central axis of the rotary drive shaft 30 within a range in which the stopper regulating protrusion 233b abuts on the front edge portion and the trailing edge portion of the second regulated elongated hole 215.

By the way, a spring member 26 is provided between the stopper member 23 and the lever member 22. The spring member 26 urges the stopper member 23 in the direction in which the stopper regulating protrusion 233b abuts on the front edge portion of the second regulating elongated hole 215, that is, upward. Further, the spring member 26 urges the lever member 22 in the direction in which the lever regulating protrusion 222b abuts on the trailing edge portion of the first regulated elongated hole 213, that is, upward.

The pedal member 24 is made of, for example, a resin material, and has a pedal base portion 241, a pedal body portion 242, and a pedal acting portion 243 as shown in FIGS. 15-1 and 15-2. The pedal base 241 is a columnar portion whose left-right direction is the longitudinal direction, and has a circular pedal through hole 241a having an inner diameter slightly larger than the maximum width of the rotary drive shaft 30. Further, the pedal base portion 241 is formed with an insertion portion 241b formed by cutting out a central region portion in the left-right direction thereof, and a plurality of transmission recesses 241c are formed so as to be arranged in an arc shape on the left side portion of the insertion portion 241b. There is.

The pedal body portion 242 is a substantially flat plate-shaped portion extending from the pedal base portion 241 to the outside in the radial direction of the pedal through hole 241a, that is, toward the front. A pedal hook portion 242a is formed on the lower surface of the pedal body portion 242 so as to project downward.

The pedal acting portion 243 is a flat plate-shaped portion formed so as to extend outward in the radial direction of the pedal through hole 241a from the pedal base portion 241. The pedal action portion 243 is formed so that its left-right width is larger than the left-right width of the pedal base portion 241 and the left-right width of the pedal body portion 242.

Such a pedal member 24 is housed in the mechanism main body 21 by the rotation drive shaft 30 penetrating the pedal through hole 241a of the pedal base 241 between the stopper penetrating portions 233 of the stopper member 23. That is, the pedal member 24 is housed in the mechanism main body 21 in such a manner that it can swing around the central axis of the rotary drive shaft 30.

The transmission mechanism 40 includes a clutch motor 41, a slider 42, and a dock clutch 43. The clutch motor 41 is housed in the mechanism main body 21 by being held by the motor holding portion 216 (see FIGS. 9 and 12-2) of the mechanism main body 21, and is housed in the mechanism main body 21 via a harness 44 (see FIG. 11). The forward rotation drive or the reverse rotation drive is performed according to a command given from the control unit 60 (see FIG. 1).

The slider 42 is made of, for example, a resin material, and is provided so as to be slidable in the left-right direction in the mechanism main body 21. As shown in FIGS. 16-1 and 16-2, such a slider 42 has a slider main body portion 421 and a slider holding portion 422.

The slider main body portion 421 is configured to have a notch formed in a substantially rectangular parallelepiped, and has a motor engaging portion 421a and a hook locking portion 421b. The motor engaging portion 421a has a female screw formed therein, and is a portion that engages with the clutch motor 41 by being screwed with a male screw 411 connected to the clutch motor 41. As a result, when the male screw 411 rotates in one direction due to the forward rotation drive of the clutch motor 41, the slider 42 slides to the left in a manner close to the clutch motor 41, while the clutch motor 41 reverses. When the male screw 411 rotates in the other direction by driving, it slides to the right in a manner of separating from the clutch motor 41.

The hook locking portion 421b is a flat plate-shaped portion formed as an opening edge portion of the slider recess 423 formed in the upper part on the right side of the motor engaging portion 421a. The hook locking portion 421b can be locked with the pedal hook portion 242a when the pedal hook portion 242a enters the slider recess 423.

The slider holding portion 422 is provided at the rear end of the flat plate that projects rearward from the slider main body portion 421. The slider holding portion 422 has a cylindrical shape due to the holding hole 422a being formed inside.

The dock clutch 43 is made of, for example, a resin material, and has a clutch base 431, a clutch engaging portion 432, and a clutch transmitting portion 433, as shown in FIGS. 17-1 and 17-2. The clutch base portion 431 is a cylindrical portion, and its outer diameter is larger than the inner diameter of the holding hole 422a of the slider holding portion 422.

The clutch engaging portion 432 is a cylindrical portion formed so as to project to the right from the right end surface of the clutch base portion 431. A hexagonal connecting hole 434 that matches the outer shape of the rotary drive shaft 30 is formed inside the clutch base portion 431 and the clutch engaging portion 432. The outer diameter of the clutch engaging portion 432 is smaller than the outer diameter of the clutch base portion 431 and slightly smaller than the inner diameter of the holding hole 422a of the slider holding portion 422. Further, the extending length of the clutch engaging portion 432 in the left-right direction is larger than the length of the slider holding portion 422 in the left-right direction, and the clutch hook portion 432a is formed at the right end portion of the clutch engaging portion 432.

The clutch transmission portion 433 is a portion extending in an arc shape on a part of the outer end surface of the clutch base portion 431. On the left surface of the clutch transmission portion 433, transmission convex portions 433a are formed so as to be arranged in an arc shape so as to project to the left. These transmission protrusions 433a are capable of entering the transmission recess 241c.

In such a dock clutch 43, the clutch engaging portion 432 enters the holding hole 422a of the slider holding portion 422 from the left, and the clutch hook portion 432a is locked to the right end portion of the slider holding portion 422, thereby engaging the slider 42. It is held rotatably. The dock clutch 43 is housed in the mechanism main body 21 with the rotation drive shaft 30 penetrating the connecting hole 434 in a state of being inserted into the insertion portion 241b of the pedal base portion 241 of the pedal member 24.

The sold-out detection unit 25 (see FIG. 8) is a mechanism main body in such a manner that the sold-out contact 251 can appear and disappear upward from the arm opening 232a formed in the stopper arm portion 232 on the right side of the stopper member 23. It is housed in part 21. When the sold-out contact 251 is pressed and placed below the arm opening 232a, the sold-out detection unit 25 detects the presence of a product, while the sold-out contact 251 is placed above the arm opening 232a. If so, it detects that there is no product. The sold-out detection unit 25 gives the detection result to the control unit 60 as a detection signal.

In the payout mechanism 20 having such a configuration, the locking projection 211a constituting the main body engaging portion 211 of the mechanism main body portion 21 is inserted into an arbitrary mechanical locking hole 12c of the shelf plate 12, and the locking hook portion 211b is inserted. Is attached to the shelf board 12 by locking to the lower edge portion of the rear end portion of the shelf board 12, and is provided on the downstream side of the product storage passage 14a of the product storage column 14.

In the standby state as shown in FIGS. 8 to 10, the payout mechanism 20 is arranged at a position where the slider 42 is separated from the clutch motor 41, and the pedal hook portion 242a of the pedal member 24 is the slider recess 423. Is locked to the hook locking portion 421b. Therefore, the pedal member 24 is in a state in which the pedal acting portion 243 protrudes upward from the mechanism main body portion 21 and moves into the product storage passage 14a. By arranging the slider 42 at a position separated from the clutch motor 41, the dock clutch 43 held by the slider holding portion 422 and the pedal member 24 are separated from each other as shown in FIG. ..

Further, in the stopper member 23, the pedestal portion 231b is pressed by the pedal body portion 242 of the pedal member 24 and swings downward against the urging force of the spring member 26, and the stopper acting portion 231 enters the stopper opening 214 from above. By entering, it is in a state of regressing from the product storage passage 14a. As a result, the upper surfaces of the stopper acting portion 231 of the stopper member 23, the stopper arm portion 232, and the pedal main body portion 242 form the same flat surface as the upper surface of the mechanism main body portion 21.

By the way, the lever member 22 is in a posture of swinging upward until the lever regulation protrusion 222b abuts on the trailing edge portion of the first regulation elongated hole 213 by the action of only the urging force of the spring member 26. As shown in FIG. 2, it is in a state of advancing and moving to the payout passage 50 extending in the vertical direction provided on the rear side of the product storage rack 11.

The base back plate 10b of the product storage device 10 constituting the back surface of the payout aisle 50 is provided with a plurality of guide protrusions 51 protruding from the payout aisle 50. The guide protrusions 51 are provided so as to extend in the left-right direction to a portion below the height level of the payout mechanism 20 of each product storage rack 11, and more specifically, the product storage adjacent to the top and bottom. The rack 11 is provided at an intermediate height level between the height level of the payout mechanism 20 of the product storage rack 11 on the upper side and the height level of the payout mechanism 20 of the product storage rack 11 on the lower side.

Further, as shown in FIG. 2, the rotation transmission member 31 connected to the rotation drive shaft 30 meshes with a part of the transmission cord body 32 whose outer end surface is connected endlessly. The transmission cord 32 is partially meshed with the drive pulley 33, and the drive pulley 33 is rotated around the central axis by the drive of the drive motor 34, so that the transmission cord body 32 is displaced along the extending direction thereof. Is. That is, as a result of the transmission cord 32 being displaced with the rotation of the drive pulley 33, the rotation transmission member 31 also rotates around its own central axis, whereby the rotation drive shaft 30 also has its own central axis as its axis. It will rotate around the axis. The drive motor 34 is driven in the forward direction or in the reverse direction according to a command given from the electrically connected control unit 60. Then, the control unit 60 can detect the rotation angle of the rotation transmission member 31 based on the detection result given from a rotation detection unit (not shown) such as an encoder provided in the vicinity of each rotation transmission member 31.

Next, the product payout operation by the product storage device 10 will be described. In the following, for convenience of explanation, one product storage column 14 will be described as an example.

When the payout mechanism 20 is in the standby state, only the pedal member 24 is in the state of advancing and moving into the product storage passage 14a as described above. Therefore, as shown in FIG. 19, the pedal acting unit 243 moves to the product storage passage 14a. It abuts on the most downstream product W1 of. As a result, the products in the product storage column 14 are stored in a row along the product storage passage 14a, and it is restricted from leaving the product storage passage 14a.

Then, a control unit to which a vending machine control unit (not shown) that comprehensively controls the operation of the vending machine by the user selecting a product gives a payout command for the product stored in the product storage column 14. Reference numeral 60 denotes a forward rotation drive of the clutch motor 41 of the payout mechanism 20 installed on the rear side of the product storage column 14. As a result, the male screw 411 rotates in one direction, and as shown in FIG. 20, the slider 42 slides to the left in a manner close to the clutch motor 41. As the slider 42 slides to the left in this way, the dock clutch 43 held by the slider 42 also slides to the left. As a result, as shown in FIG. 21, the dock clutch 43 is connected to the pedal member 24 by the transmission protrusions 433a entering the transmission recesses 241c of the pedal member 24. Further, by sliding the slider 42 to the left, the locked state between the hook locking portion 421b and the pedal hook portion 242a is released.

When the dock clutch 43 and the pedal member 24 are connected in this way, the control unit 60 drives the drive motor 34 in the forward rotation. As a result, the drive pulley 33 rotates clockwise when viewed from the right, and the transmission cord 32 is displaced, so that the rotation transmission member 31 also rotates clockwise when viewed from the right.

By rotating the rotation transmission member 31 in this way, the rotation drive shaft 30 also rotates clockwise around the central axis when viewed from the right. As the rotary drive shaft 30 rotates in this way, the dock clutch 43 that fits the rotary drive shaft 30 also rotates clockwise when viewed from the right. Then, the pedal member 24 connected to the dock clutch 43 swings rearward as shown in FIG. 22.

When the pedal member 24 swings rearward, the stopper member 23 whose pedestal portion 231b has been pressed by the pedal body portion 242 of the pedal member 24 is released from the pressing by the pedal member 24, and FIG. 23 As shown in the above, the stopper regulating protrusion 233b swings upward until it comes into contact with the front edge portion of the second regulated elongated hole 215, and the stopper acting portion 231 protrudes upward from the stopper opening 214 and moves into the product storage passage 14a. It will be in the state of.

When the stopper member 23 is in the state of advancing and moving into the product storage passage 14a in this way, as shown in FIG. 24, the stopper acting surface 231a of the stopper acting portion 231 is the second product from the downstream side in the product storage passage 14a. It comes into contact with W2 and restricts the product W2 from moving toward the downstream side of the product storage passage 14a. That is, only the most downstream product W1 can be separated from other products.

The rotation of the rotation drive shaft 30 is maintained by the rotation of the rotation transmission member 31 accompanying the drive of the drive motor 34, and the pedal member 24 connected to the dock clutch 43 that rotates by the rotation of the rotation drive shaft 30 Continue swinging backwards.

After that, as shown in FIG. 25, the rotation angle of the rotation transmission member 31 is that the pedal member 24 swings backward to a posture in which the most downstream product W1 can be delivered to the payout passage 50 through the detection result of the rotation detection unit. When detected, the control unit 60 temporarily stops the drive motor 34.

As a result, the most downstream product W1 is paid out to the payout passage 50 and comes into contact with the lever member 22. The lever member 22 swings downward in a manner of regressing from the payout passage 50 against the urging force of the spring member 26, and guides the contacted product to the guide protrusion 51 directly below. As shown in FIG. 26, the product guided to the guide protrusion 51 directly below in this way is the product storage rack 11 below the product storage rack 11 having the product storage column 14 after coming into contact with the guide protrusion 51. By contacting the lever member 22 of any of the payout mechanisms 20 constituting the above and being guided by the guide protrusion 51 directly below the lever member 22, the payout passage 50 falls in a meandering manner. The product that has fallen in the payout passage 50 in a meandering manner then rolls the product shooter 5 and is guided to the product outlet 3a through the product carry-out port 4a.

When the guide protrusion 51 comes into contact with the falling product W1 in the payout passage 50, it is preferable to guide the product W1 to the vicinity of the lever penetrating portion 222 of the lever member 22 directly below the guide protrusion 51. The reaction force (urging force) of the spring member 26 that urges the lever member 22 is larger as it is closer to the lever penetrating portion 222 side through which the rotation drive shaft 30 that is the swing axis of the lever member 22 penetrates, and the product W1 is effectively used. It becomes possible to attenuate the falling speed of.

Further, the guide protrusion 51 is provided so that the protrusion height toward the payout passage 50 is arranged on the upper side of the payout passage 50 in order to more effectively attenuate the impact of the product W1 that has fallen on the product shooter 5. It is preferable that the size is larger and the size is smaller as it is arranged on the lower side of the payout passage 50.

By the way, the control unit 60 that temporarily stops the drive motor 34 reversely drives the drive motor 34. When the drive motor 34 is driven in the reverse direction in this way, the drive pulley 33 rotates counterclockwise when viewed from the right, and the transmission cord 32 is displaced so that the rotation transmission member 31 is also counterclockwise when viewed from the right. Rotate clockwise. By rotating the rotation transmission member 31 in this way, the rotation drive shaft 30 also rotates around the central axis in a manner that is counterclockwise when viewed from the right. As the rotary drive shaft 30 rotates, the dock clutch 43 that fits the rotary drive shaft 30 also rotates counterclockwise when viewed from the right, and the pedal member 24 connected to the dock clutch 43 faces forward. Swing.

When the pedal member 24 swings forward, the stopper member 23 whose pedestal portion 231b is pressed by the pedal body portion 242 of the pedal member 24 swings downward against the urging force of the spring member 26. After that, the stopper acting portion 231 enters the stopper opening 214 and moves backward to the product storage passage 14a, and as a result, the pedal member 24 returns to the standby state. At this time, the pedal hook portion 242a of the pedal member 24 enters the slider recess 423 of the slider 42.

When the pedal member 24 returns to the standby state in this way, the control unit 60 reversely drives the clutch motor 41 and slides the slider 42 to the right to arrange the clutch motor 41 at a position separated from the clutch motor 41. As a result, the hook locking portion 421b of the slider 42 and the pedal hook portion 242a are locked, and the pedal member 24 is restricted from swinging even if the product that is newly the most downstream abuts on the pedal acting portion 243. , The product is stored in the product storage passage 14a.

By the way, since all the rotation transmission members 31 are linked to the drive pulley 33 through the transmission cord 32, they rotate with the drive of the drive motor 34. Therefore, all the rotation drive shafts 30 will rotate. When the rotary drive shaft 30 rotates in this way, the dock clutch 43 also rotates. However, in the other payout mechanism 20 other than the above-mentioned payout mechanism 20, the pedal hook portion 242a of the pedal member 24 is a hook locking portion. Since the dock clutch 43 and the pedal member 24 are not connected while the state of being locked to the 421b is maintained, the standby state of the payout mechanism 20 is maintained, and the goods are paid out from the other product storage columns 14. Absent.

In the product storage rack 11 as described above, the shelf board 12 is formed with a plurality of partition locking holes 12b at predetermined intervals along the left-right direction, and can be formed in any partition locking holes 12b. Since the product storage column 14 is formed by inserting the locking piece 13a of the partition plate 13 and locking the partition plate 13 to the shelf plate 12, the locking piece 13a of the partition plate 13 is inserted into the locking piece 13a for partitioning. By changing the position of the hole 12b, the left-right width of the product storage column 14 can be changed. Moreover, the payout mechanism 20 can be displaced along the left-right direction while being penetrated by the rotary drive shaft 30, and can be provided on the downstream side of the product storage passage 14a constituting any product storage column 14.

Therefore, according to the product storage rack 11, a plurality of product storage columns 14 are provided so as to be arranged in the left-right direction, the left-right widths of the respective product storage columns 14 can be changed, and the payout mechanism 20 is provided so as to be displaceable in the left-right direction. Therefore, it is possible to store and pay out products having various sizes.

In the product storage rack 11, the product is stored by inserting the locking piece 13a of the partition plate 13 into an arbitrary partition locking hole 12b of the shelf plate 12 and locking the partition plate 13 to the shelf plate 12. Since the column 14 is configured, as shown in FIG. 27, by removing the partition plate 13 arranged at the center in the state where the four product storage columns 14 are arranged side by side as shown in FIG. 27, as shown in FIG. In addition, the product storage passage 14a of one of the product storage columns 14 adjacent to each other and the product storage passage 14a of the other product storage column 14 can be merged to connect these product storage columns 14, and three in the left-right direction. The product storage columns 14 can be configured to be lined up. In this case, the connected new product storage column 14 can store the product W3 having a product height larger than the product W stored in the other product storage column 14, and the products have various sizes. Can be paid out while minimizing the empty space and storing it. Therefore, products having various sizes can be efficiently stored and paid out without any gaps.

In the product storage rack 11, the rotation transmission member 31 and the rotation drive shaft 30 constitute a driving force applying means for applying a common driving force for operating each of the payout mechanisms 20 to the payout mechanism 20, and the transmission mechanism. The driving force transmitting means for transmitting the driving force of the driving force applying means is configured only to the payout mechanism 20 to which the 40 corresponds. According to such a product storage rack 11, the driving force source of each of the payout mechanisms 20 constituting the product storage rack 11 can be shared, and the manufacturing cost can be reduced by reducing the number of parts. it can. Moreover, depending on the number of driving the transmission mechanism 40, not only the single payout mechanism 20 but also a plurality of payout mechanisms 20 can be synchronously driven in the same product storage rack 11, and the products are simultaneously paid from the plurality of product storage columns 14. In addition to being able to take out, when a plurality of payout mechanisms 20 are provided in one product storage column 14, these payout mechanisms 20 can be synchronously driven to satisfactorily pay out the products stored in the product storage column 14. it can. Therefore, it is possible to satisfactorily synchronize the product payout operations between the arbitrary product storage columns 14.

According to the product storage device 10, the rotation transmission member 31 provided corresponding to each product storage rack 11 is rotated by the drive of the drive motor 34, which is a common power source, so that the power source is unified. By doing so, it is possible to reduce the manufacturing cost by reducing the number of parts.

According to the product storage device 10, a plurality of guide protrusions 51 projecting forward toward the product storage rack 11 are provided on the base back plate 10b constituting the payout aisle 50 into which the products paid out by the payout mechanism 20 fall. Since it is provided below the height level of the payout mechanism 20 of each product storage rack 11, the lever member 22 of the payout mechanism 20 comes into contact with the falling product and guides it to the guide protrusion 51 directly below. The payout aisle 50 can be dropped while the product is meandering. As a result, it is possible to prevent the container of the product from being damaged, and it is possible to prevent the beverage from foaming and forming when the product is a strongly carbonated beverage containing a relatively large amount of carbonic acid. be able to.

Next, a modified example of the product storage rack will be described. FIG. 29 is a perspective view showing an external configuration of a modified example of the product storage rack according to the embodiment of the present invention.

The product storage rack 70 illustrated here is configured such that a plurality of product storage columns 70a are arranged side by side in a manner of arranging them side by side. Since the plurality of product storage columns 70a constituting the product storage rack 70 have the same configuration, one product storage column 70a will be described below.

The product storage column 70a is configured to include a payout mechanism 80. The payout mechanism 80 is configured by extending a transport belt 82 in an endless manner between pulleys 81 provided in a paired front-rear manner.

As shown in FIGS. 30 to 32, the pulley 81a on the front side has a cylindrical shape, and the hollow portion 811 penetrates the rotary drive shaft 71. The rotation drive shaft 71 has a polygonal column shape such as a hexagonal column, and is connected to the central portion of the rotation transmission member 72 whose right end portion has a substantially disk shape. The rotation transmission member 72 is linked to a drive motor 73, which is a drive source, and can rotate around its own central axis by applying a driving force from the drive motor 73. As a result, the rotation drive shaft 71 can also rotate around its own center axis with its own center axis as the axis. The pulley 81 on the rear side is rotatably provided around the axis of the rotating shaft 74 extending along the left-right direction.

The transport belt 82 is displaced along its own extending direction by rotating the pulley 81. Specifically, the transport belt 82 is displaced in such a manner that the upper extending portion 82a between the pulleys 81 moves forward. It is something to do. The upper extending portion 82a is a portion on which a product is placed, and forms a product storage passage 75 extending linearly in the front-rear direction.

Such a payout mechanism 80 is provided with a transmission mechanism 90. The transmission mechanism 90 includes a clutch motor 91, a slider 92, and a dock clutch 93. The clutch motor 91 has a through hole 90b formed in the clutch motor 91 housed in a mechanism main body 90a penetrating the rotation drive shaft 71, and is driven forward or reversely in response to a command given from a control unit (not shown). To do.

The slider 92 is made of, for example, a resin material, and is provided so as to be slidable in the left-right direction in the mechanism main body 90a. Such a slider 92 has a motor engaging portion 921 and a slider holding portion 922.

The motor engaging portion 921 has a female screw (not shown) formed inside, and engages with the clutch motor 91 by being screwed with a male screw 91b linked to the output shaft 91a of the clutch motor 91. It is a part. As a result, when the male screw 91b rotates in one direction due to the forward rotation drive of the clutch motor 91, the slider 92 slides to the right in a manner close to the clutch motor 91, while the clutch motor 91 reverses. When the male screw 91b rotates in the other direction by driving, it slides to the left in a manner of separating from the clutch motor 91.

The slider holding portion 922 is provided at the front end of a portion that protrudes forward from the slider 92 main body portion. The slider holding portion 922 has a cylindrical shape due to the holding hole 922a being formed inside.

The dock clutch 93 is made of, for example, a resin material, and has a clutch base 931 and a clutch engaging portion 932. The clutch base 931 is a cylindrical portion, and its outer diameter is larger than the inner diameter of the holding hole 922a of the slider holding portion 922.

The clutch engaging portion 932 is a cylindrical portion formed so as to project to the left from the left end surface of the clutch base 931. The clutch base 931 and the clutch engaging portion 932 are internally formed with a hexagonal connecting hole 933 that matches the outer shape of the rotary drive shaft 71. The outer diameter of the clutch engaging portion 932 is smaller than the outer diameter of the clutch base portion 931 and slightly smaller than the inner diameter of the holding hole 922a of the slider holding portion 922. Further, the extending length of the clutch engaging portion 932 in the left-right direction is formed to be larger than the length of the slider holding portion 922 in the left-right direction.

The clutch base 931 is provided with a plurality of transmission protrusions 931a on the right surface. Each of these transmission convex portions 931a is formed so as to be arranged in a circumferential shape so as to project from the right surface of the clutch base portion 931 to the right. These transmission protrusions 931a can enter the transmission recess 811a formed in the pulley 81a on the front side.

In such a dock clutch 93, the clutch engaging portion 932 enters the holding hole 922a of the slider holding portion 922 from the right side and is rotatably held by the slider 92.

In the product storage rack 70 having such a configuration, products can be paid out from an arbitrary product storage column 70a as follows. As a premise, the drive motor 73 is driven, and it is assumed that the rotary drive shaft 71 is rotating counterclockwise when viewed from the right. Further, it is assumed that the slider 92 slides to the left so as to be separated from the clutch motor 91.

The dock clutch 93 is rotated by the rotation of the rotary drive shaft 71, but the slider 92 is slid to the left. Therefore, as shown in FIG. 33, the dock clutch 93 and the pulley 81a on the front side are separated from each other. As a result, the pulley 81a on the front side is not rotating. In this state, the transport belt 82 is not displaced, and only the product is placed on the upward extending portion 82a.

Then, when a payout command for the products stored in the arbitrary product storage column 70a is given, the control unit drives the corresponding clutch motor 91 in the forward rotation. As a result, the male screw 91b rotates in one direction, and as shown in FIG. 34, the slider 92 slides to the right in a manner close to the clutch motor 91. As the slider 92 slides to the right in this way, the dock clutch 93 held by the slider 92 also slides to the right. As a result, in the dock clutch 93, each transmission convex portion 931a enters each transmission recess 811a of the front pulley 81a and is connected to the front pulley 81a.

When the dock clutch 93 and the front pulley 81a are connected in this way, the driving force of the drive motor 73 is applied to the front pulley 81a through the rotary drive shaft 71 and the dock clutch 93, and the driving force of the drive motor 73 is applied from the right side. As you can see, it rotates counterclockwise, and the transport belt 82 is displaced. That is, the transport belt 82 is displaced in such a manner that the upper extending portion 82a moves forward. As a result, the most downstream product arranged in the foreground, which is the most downstream side of the upper extending portion 82a, moves forward and is paid out from the product storage passage 75.

After the most downstream product is paid out, the control unit reversely drives the clutch motor 91. As a result, the male screw 91b rotates in the other direction, and as shown in FIG. 33, the slider 92 slides to the left in a manner of separating from the clutch motor 91. As the slider 92 slides to the left in this way, the dock clutch 93 held by the slider 92 also slides to the left. As a result, in the dock clutch 93, each transmission convex portion 931a is disengaged from each transmission recess 811a, and the connection with the pulley 81a on the front side is released. When the dock clutch 93 and the front pulley 81a are disconnected from each other in this way, the front pulley 81a stops rotating and the displacement of the transport belt 82 stops.

In the product storage rack 70 as described above, the rotation transmission member 72 and the rotation drive shaft 71 constitute a driving force applying means for applying a common driving force to the payout mechanism 80 to operate each of the payout mechanisms 80. Then, the transmission mechanism 90 constitutes a driving force transmitting means for transmitting the driving force of the driving force applying means only to the corresponding payout mechanism 80. According to such a product storage rack 70, the driving force source of each of the payout mechanisms 80 constituting the product storage rack 70 can be shared, and the manufacturing cost can be reduced by reducing the number of parts. it can. Moreover, depending on the number of driving the transmission mechanisms 90, not only the single payout mechanism 80 but also a plurality of payout mechanisms 80 can be synchronously driven in the same product storage rack 70, and the products are simultaneously paid from the plurality of product storage columns 70a. Can be put out. Therefore, it is possible to satisfactorily synchronize the product payout operations between the arbitrary product storage columns 70a.

In this way, since the product payout operation can be synchronized between the arbitrary product storage columns 70a, the payout operation can be synchronized between the product storage columns 70a adjacent to each other. In this case, the adjacent product storage passages can be synchronized. A product such as a lunch box can be placed in a manner straddling 75, and the product can be satisfactorily paid out.

By the way, in the product storage device 100 in which such product storage racks 70 are provided in a plurality of stages along the vertical direction, as shown in FIG. 35, the rotation transmission members 72 are linked to each other by the transmission cord body 76. By doing so, the drive motor 73 can be used as a common power source for the drive force applying means (rotation transmission member 72 and rotation drive shaft 71) of each product storage rack 70. That is, the driving force applying means can apply the power given from the power source common to the other driving force applying means constituting the other product storage rack 70 as the driving force.

Therefore, according to such a product storage device 100, the rotation transmission member 72 provided corresponding to each product storage rack 70 is rotated by the drive of the drive motor 73, which is a common power source. By unifying the sources, it is possible to reduce the manufacturing cost by reducing the number of parts.

Although preferred embodiments and modifications of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made.

In the above-described embodiment, the rotation transmission members 31 and 72 are driven by the common drive motors 34 and 73 via the transmission cords 32 and 76, but in the present invention, each rotation transmission member is individually driven. It may be driven.

In the above-described embodiment, the clutch motors 41 and 91 constituting the transmission mechanisms 40 and 90 slide the sliders 42 and 92 by driving them in the forward or reverse direction, but the actuator that slides the sliders 42 and 92 is It is not necessary to limit the clutch motors 41 and 91, and for example, a solenoid or the like may be used.

In the above-described embodiment, the product storage device 10 is applied to the vending machine, but in the present invention, the product storage device may be applied to the showcase.

10 Product storage device 11 Product storage rack 12 Shelf board 13 Partition plate 14 Product storage column 14a Product storage passage 20 Payout mechanism 21 Mechanism main body 22 Lever member 23 Stopper member 24 Pedal member 25 Sold out detection unit 30 Rotation drive shaft 31 Rotation transmission Member 33 Drive pulley 34 Drive motor 40 Transmission mechanism 50 Discharge passage 51 Guide protrusion 60 Control unit

Claims (7)

A plurality of product storage columns for storing products in a straight line extending in a line along the extending direction of the product storage passage, and a plurality of product storage columns.
It is provided for each product storage column, and when driven, it is provided with a payout mechanism for paying out the most downstream product arranged on the most downstream side among the products stored in the corresponding product storage aisle from the product storage aisle. , A product storage rack in which the product storage columns are arranged side by side.
A driving force applying means for applying a common driving force for operating each payout mechanism, and
When a payout command for a product stored in an arbitrary product storage column is given, only the corresponding payout mechanism is provided with a driving force transmitting means for transmitting the driving force of the driving force applying means. Product storage rack. The plurality of product storage columns store products in a row in a product storage aisle that is inclined and extended in a manner that gradually lowers from the upstream side to the downstream side, and the left and right widths of the respective product storage columns can be changed. Has been
The payout mechanism is provided on the downstream side of the product storage aisle, and regulates that the product stored in the product storage passage is separated from the product storage passage in the standby state. The product storage rack according to claim 1, wherein the downstream product is discharged from the product storage passage, and further, the product storage rack is provided so as to be displaceable in the left-right direction. The product storage according to claim 2, wherein the product storage column is configured such that the product storage passage is merged with the product storage passage of the other product storage column and can be connected to the other product storage column. rack. A product storage device configured by providing the product storage rack according to claim 1 in a plurality of stages along the vertical direction.
The product storage device is characterized in that the driving force applying means applies power given as the driving force from a power source common to other driving force applying means constituting another product storage rack. The payout mechanism has a lever member provided so as to be swingable so as to move forward and backward with respect to the payout passage in which the goods paid out from the product storage passage fall.
On the surface facing the payout mechanism while forming the payout passage, a plurality of guide protrusions provided along the vertical direction so as to project into the payout passage are provided.
The lever member is characterized in that when a product falling in the payout passage comes into contact with the lever member, the lever member guides the product to a guide protrusion directly below the product while swinging in a manner of regressing from the payout passage. The product storage device according to claim 4. The payout mechanism
A pair of front and rear pulleys that rotate around their own central axis,
It is provided with a transport belt that is stretched endlessly between the pulleys and is displaced in the extending direction by the rotation of the pulleys.
The upper extending portion of the transport belt between the pulleys constitutes the product storage passage, and the products are placed and stored so as to be lined up in the front-rear direction, and when a payout command is given, the products are placed and stored. The product storage rack according to claim 1, wherein the pulley is rotated to displace the transport belt so that the most downstream product is discharged. A product storage device configured by providing the product storage rack according to claim 6 in a plurality of stages along the vertical direction.
The product storage device is characterized in that the driving force applying means applies power given as the driving force from a power source common to other driving force applying means constituting another product storage rack.

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